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// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2011 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
integer cyc=0;
reg [4095:0] crc;
// Test loop
always @ (posedge clk) begin
cyc <= cyc + 1;
crc <= {crc[4094:0], crc[63]^crc[2]^crc[0]}; // not a good crc :)
if (cyc==0) begin
// Setup
crc <= 4096'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;
end
else if (cyc==99) begin
$write("[%0t] cyc==%0d crc=%x%x%x%x\n",$time, cyc, crc[4095:3072], crc[2071:2048], crc[2047:1024], crc[1023:0]);
$write("[%0t] cyc==%0d crc=%b%b%b%b\n",$time, cyc, crc[4095:3072], crc[2071:2048], crc[2047:1024], crc[1023:0]);
//Unsupported: $write("[%0t] cyc==%0d crc=%x\n",$time, cyc, crc);
if (crc != 4096'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
) $stop;
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2011 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
integer cyc=0;
reg [4095:0] crc;
// Test loop
always @ (posedge clk) begin
cyc <= cyc + 1;
crc <= {crc[4094:0], crc[63]^crc[2]^crc[0]}; // not a good crc :)
if (cyc==0) begin
// Setup
crc <= 4096'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;
end
else if (cyc==99) begin
$write("[%0t] cyc==%0d crc=%x%x%x%x\n",$time, cyc, crc[4095:3072], crc[2071:2048], crc[2047:1024], crc[1023:0]);
$write("[%0t] cyc==%0d crc=%b%b%b%b\n",$time, cyc, crc[4095:3072], crc[2071:2048], crc[2047:1024], crc[1023:0]);
//Unsupported: $write("[%0t] cyc==%0d crc=%x\n",$time, cyc, crc);
if (crc != 4096'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
) $stop;
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
|
module spi_slave(
input clk,
input rst,
input ss,
input mosi,
output miso,
input sck,
output done,
input [7:0] din,
output [7:0] dout
);
reg mosi_d, mosi_q;
reg ss_d, ss_q;
reg sck_d, sck_q;
reg sck_old_d, sck_old_q;
reg [7:0] data_d, data_q;
reg done_d, done_q;
reg [2:0] bit_ct_d, bit_ct_q;
reg [7:0] dout_d, dout_q;
reg miso_d, miso_q;
assign miso = miso_q;
assign done = done_q;
assign dout = dout_q;
always @(*) begin
ss_d = ss;
mosi_d = mosi;
miso_d = miso_q;
sck_d = sck;
sck_old_d = sck_q;
data_d = data_q;
done_d = 1'b0;
bit_ct_d = bit_ct_q;
dout_d = dout_q;
if (ss_q) begin
bit_ct_d = 3'b0;
data_d = din;
miso_d = data_q[7];
end else begin
if (!sck_old_q && sck_q) begin // rising edge
data_d = {data_q[6:0], mosi_q};
bit_ct_d = bit_ct_q + 1'b1;
if (bit_ct_q == 3'b111) begin
dout_d = {data_q[6:0], mosi_q};
done_d = 1'b1;
data_d = din;
end
end else if (sck_old_q && !sck_q) begin // falling edge
miso_d = data_q[7];
end
end
end
always @(posedge clk) begin
if (rst) begin
done_q <= 1'b0;
bit_ct_q <= 3'b0;
dout_q <= 8'b0;
miso_q <= 1'b1;
end else begin
done_q <= done_d;
bit_ct_q <= bit_ct_d;
dout_q <= dout_d;
miso_q <= miso_d;
end
sck_q <= sck_d;
mosi_q <= mosi_d;
ss_q <= ss_d;
data_q <= data_d;
sck_old_q <= sck_old_d;
end
endmodule
|
module spi_slave(
input clk,
input rst,
input ss,
input mosi,
output miso,
input sck,
output done,
input [7:0] din,
output [7:0] dout
);
reg mosi_d, mosi_q;
reg ss_d, ss_q;
reg sck_d, sck_q;
reg sck_old_d, sck_old_q;
reg [7:0] data_d, data_q;
reg done_d, done_q;
reg [2:0] bit_ct_d, bit_ct_q;
reg [7:0] dout_d, dout_q;
reg miso_d, miso_q;
assign miso = miso_q;
assign done = done_q;
assign dout = dout_q;
always @(*) begin
ss_d = ss;
mosi_d = mosi;
miso_d = miso_q;
sck_d = sck;
sck_old_d = sck_q;
data_d = data_q;
done_d = 1'b0;
bit_ct_d = bit_ct_q;
dout_d = dout_q;
if (ss_q) begin
bit_ct_d = 3'b0;
data_d = din;
miso_d = data_q[7];
end else begin
if (!sck_old_q && sck_q) begin // rising edge
data_d = {data_q[6:0], mosi_q};
bit_ct_d = bit_ct_q + 1'b1;
if (bit_ct_q == 3'b111) begin
dout_d = {data_q[6:0], mosi_q};
done_d = 1'b1;
data_d = din;
end
end else if (sck_old_q && !sck_q) begin // falling edge
miso_d = data_q[7];
end
end
end
always @(posedge clk) begin
if (rst) begin
done_q <= 1'b0;
bit_ct_q <= 3'b0;
dout_q <= 8'b0;
miso_q <= 1'b1;
end else begin
done_q <= done_d;
bit_ct_q <= bit_ct_d;
dout_q <= dout_d;
miso_q <= miso_d;
end
sck_q <= sck_d;
mosi_q <= mosi_d;
ss_q <= ss_d;
data_q <= data_d;
sck_old_q <= sck_old_d;
end
endmodule
|
module spi_slave(
input clk,
input rst,
input ss,
input mosi,
output miso,
input sck,
output done,
input [7:0] din,
output [7:0] dout
);
reg mosi_d, mosi_q;
reg ss_d, ss_q;
reg sck_d, sck_q;
reg sck_old_d, sck_old_q;
reg [7:0] data_d, data_q;
reg done_d, done_q;
reg [2:0] bit_ct_d, bit_ct_q;
reg [7:0] dout_d, dout_q;
reg miso_d, miso_q;
assign miso = miso_q;
assign done = done_q;
assign dout = dout_q;
always @(*) begin
ss_d = ss;
mosi_d = mosi;
miso_d = miso_q;
sck_d = sck;
sck_old_d = sck_q;
data_d = data_q;
done_d = 1'b0;
bit_ct_d = bit_ct_q;
dout_d = dout_q;
if (ss_q) begin
bit_ct_d = 3'b0;
data_d = din;
miso_d = data_q[7];
end else begin
if (!sck_old_q && sck_q) begin // rising edge
data_d = {data_q[6:0], mosi_q};
bit_ct_d = bit_ct_q + 1'b1;
if (bit_ct_q == 3'b111) begin
dout_d = {data_q[6:0], mosi_q};
done_d = 1'b1;
data_d = din;
end
end else if (sck_old_q && !sck_q) begin // falling edge
miso_d = data_q[7];
end
end
end
always @(posedge clk) begin
if (rst) begin
done_q <= 1'b0;
bit_ct_q <= 3'b0;
dout_q <= 8'b0;
miso_q <= 1'b1;
end else begin
done_q <= done_d;
bit_ct_q <= bit_ct_d;
dout_q <= dout_d;
miso_q <= miso_d;
end
sck_q <= sck_d;
mosi_q <= mosi_d;
ss_q <= ss_d;
data_q <= data_d;
sck_old_q <= sck_old_d;
end
endmodule
|
/*
----------------------------------------------------------------------------------
Copyright (c) 2013-2014
Embedded and Network Computing Lab.
Open SSD Project
Hanyang University
All rights reserved.
----------------------------------------------------------------------------------
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. All advertising materials mentioning features or use of this source code
must display the following acknowledgement:
This product includes source code developed
by the Embedded and Network Computing Lab. and the Open SSD Project.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
----------------------------------------------------------------------------------
http://enclab.hanyang.ac.kr/
http://www.openssd-project.org/
http://www.hanyang.ac.kr/
----------------------------------------------------------------------------------
*/
`timescale 1ns / 1ps
module pcie_cntl_slave # (
parameter C_PCIE_DATA_WIDTH = 128,
parameter C_PCIE_ADDR_WIDTH = 36
)
(
input pcie_user_clk,
input pcie_user_rst_n,
output rx_np_ok,
output rx_np_req,
input mreq_fifo_wr_en,
input [C_PCIE_DATA_WIDTH-1:0] mreq_fifo_wr_data,
output tx_cpld_req,
output [7:0] tx_cpld_tag,
output [15:0] tx_cpld_req_id,
output [11:2] tx_cpld_len,
output [11:0] tx_cpld_bc,
output [6:0] tx_cpld_laddr,
output [63:0] tx_cpld_data,
input tx_cpld_req_ack,
output nvme_cc_en,
output [1:0] nvme_cc_shn,
input [1:0] nvme_csts_shst,
input nvme_csts_rdy,
output nvme_intms_ivms,
output nvme_intmc_ivmc,
input cq_irq_status,
input [8:0] sq_rst_n,
input [8:0] cq_rst_n,
output [C_PCIE_ADDR_WIDTH-1:2] admin_sq_bs_addr,
output [C_PCIE_ADDR_WIDTH-1:2] admin_cq_bs_addr,
output [7:0] admin_sq_size,
output [7:0] admin_cq_size,
output [7:0] admin_sq_tail_ptr,
output [7:0] io_sq1_tail_ptr,
output [7:0] io_sq2_tail_ptr,
output [7:0] io_sq3_tail_ptr,
output [7:0] io_sq4_tail_ptr,
output [7:0] io_sq5_tail_ptr,
output [7:0] io_sq6_tail_ptr,
output [7:0] io_sq7_tail_ptr,
output [7:0] io_sq8_tail_ptr,
output [7:0] admin_cq_head_ptr,
output [7:0] io_cq1_head_ptr,
output [7:0] io_cq2_head_ptr,
output [7:0] io_cq3_head_ptr,
output [7:0] io_cq4_head_ptr,
output [7:0] io_cq5_head_ptr,
output [7:0] io_cq6_head_ptr,
output [7:0] io_cq7_head_ptr,
output [7:0] io_cq8_head_ptr,
output [8:0] cq_head_update
);
wire w_mreq_fifo_rd_en;
wire [C_PCIE_DATA_WIDTH-1:0] w_mreq_fifo_rd_data;
wire w_mreq_fifo_empty_n;
pcie_cntl_reg # (
.C_PCIE_DATA_WIDTH (C_PCIE_DATA_WIDTH)
)
pcie_cntl_reg_inst0(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.rx_np_ok (),
.rx_np_req (rx_np_req),
.mreq_fifo_rd_en (w_mreq_fifo_rd_en),
.mreq_fifo_rd_data (w_mreq_fifo_rd_data),
.mreq_fifo_empty_n (w_mreq_fifo_empty_n),
.tx_cpld_req (tx_cpld_req),
.tx_cpld_tag (tx_cpld_tag),
.tx_cpld_req_id (tx_cpld_req_id),
.tx_cpld_len (tx_cpld_len),
.tx_cpld_bc (tx_cpld_bc),
.tx_cpld_laddr (tx_cpld_laddr),
.tx_cpld_data (tx_cpld_data),
.tx_cpld_req_ack (tx_cpld_req_ack),
.nvme_cc_en (nvme_cc_en),
.nvme_cc_shn (nvme_cc_shn),
.nvme_csts_shst (nvme_csts_shst),
.nvme_csts_rdy (nvme_csts_rdy),
.nvme_intms_ivms (nvme_intms_ivms),
.nvme_intmc_ivmc (nvme_intmc_ivmc),
.cq_irq_status (cq_irq_status),
.sq_rst_n (sq_rst_n),
.cq_rst_n (cq_rst_n),
.admin_sq_bs_addr (admin_sq_bs_addr),
.admin_cq_bs_addr (admin_cq_bs_addr),
.admin_sq_size (admin_sq_size),
.admin_cq_size (admin_cq_size),
.admin_sq_tail_ptr (admin_sq_tail_ptr),
.io_sq1_tail_ptr (io_sq1_tail_ptr),
.io_sq2_tail_ptr (io_sq2_tail_ptr),
.io_sq3_tail_ptr (io_sq3_tail_ptr),
.io_sq4_tail_ptr (io_sq4_tail_ptr),
.io_sq5_tail_ptr (io_sq5_tail_ptr),
.io_sq6_tail_ptr (io_sq6_tail_ptr),
.io_sq7_tail_ptr (io_sq7_tail_ptr),
.io_sq8_tail_ptr (io_sq8_tail_ptr),
.admin_cq_head_ptr (admin_cq_head_ptr),
.io_cq1_head_ptr (io_cq1_head_ptr),
.io_cq2_head_ptr (io_cq2_head_ptr),
.io_cq3_head_ptr (io_cq3_head_ptr),
.io_cq4_head_ptr (io_cq4_head_ptr),
.io_cq5_head_ptr (io_cq5_head_ptr),
.io_cq6_head_ptr (io_cq6_head_ptr),
.io_cq7_head_ptr (io_cq7_head_ptr),
.io_cq8_head_ptr (io_cq8_head_ptr),
.cq_head_update (cq_head_update)
);
pcie_cntl_rx_fifo
pcie_cntl_rx_fifo_inst0(
.clk (pcie_user_clk),
.rst_n (pcie_user_rst_n),
////////////////////////////////////////////////////////////////
//bram fifo write signals
.wr_en (mreq_fifo_wr_en),
.wr_data (mreq_fifo_wr_data),
.full_n (),
.almost_full_n (rx_np_ok),
////////////////////////////////////////////////////////////////
//bram fifo read signals
.rd_en (w_mreq_fifo_rd_en),
.rd_data (w_mreq_fifo_rd_data),
.empty_n (w_mreq_fifo_empty_n)
);
endmodule
|
/*
----------------------------------------------------------------------------------
Copyright (c) 2013-2014
Embedded and Network Computing Lab.
Open SSD Project
Hanyang University
All rights reserved.
----------------------------------------------------------------------------------
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. All advertising materials mentioning features or use of this source code
must display the following acknowledgement:
This product includes source code developed
by the Embedded and Network Computing Lab. and the Open SSD Project.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
----------------------------------------------------------------------------------
http://enclab.hanyang.ac.kr/
http://www.openssd-project.org/
http://www.hanyang.ac.kr/
----------------------------------------------------------------------------------
*/
`timescale 1ns / 1ps
module pcie_cntl_slave # (
parameter C_PCIE_DATA_WIDTH = 128,
parameter C_PCIE_ADDR_WIDTH = 36
)
(
input pcie_user_clk,
input pcie_user_rst_n,
output rx_np_ok,
output rx_np_req,
input mreq_fifo_wr_en,
input [C_PCIE_DATA_WIDTH-1:0] mreq_fifo_wr_data,
output tx_cpld_req,
output [7:0] tx_cpld_tag,
output [15:0] tx_cpld_req_id,
output [11:2] tx_cpld_len,
output [11:0] tx_cpld_bc,
output [6:0] tx_cpld_laddr,
output [63:0] tx_cpld_data,
input tx_cpld_req_ack,
output nvme_cc_en,
output [1:0] nvme_cc_shn,
input [1:0] nvme_csts_shst,
input nvme_csts_rdy,
output nvme_intms_ivms,
output nvme_intmc_ivmc,
input cq_irq_status,
input [8:0] sq_rst_n,
input [8:0] cq_rst_n,
output [C_PCIE_ADDR_WIDTH-1:2] admin_sq_bs_addr,
output [C_PCIE_ADDR_WIDTH-1:2] admin_cq_bs_addr,
output [7:0] admin_sq_size,
output [7:0] admin_cq_size,
output [7:0] admin_sq_tail_ptr,
output [7:0] io_sq1_tail_ptr,
output [7:0] io_sq2_tail_ptr,
output [7:0] io_sq3_tail_ptr,
output [7:0] io_sq4_tail_ptr,
output [7:0] io_sq5_tail_ptr,
output [7:0] io_sq6_tail_ptr,
output [7:0] io_sq7_tail_ptr,
output [7:0] io_sq8_tail_ptr,
output [7:0] admin_cq_head_ptr,
output [7:0] io_cq1_head_ptr,
output [7:0] io_cq2_head_ptr,
output [7:0] io_cq3_head_ptr,
output [7:0] io_cq4_head_ptr,
output [7:0] io_cq5_head_ptr,
output [7:0] io_cq6_head_ptr,
output [7:0] io_cq7_head_ptr,
output [7:0] io_cq8_head_ptr,
output [8:0] cq_head_update
);
wire w_mreq_fifo_rd_en;
wire [C_PCIE_DATA_WIDTH-1:0] w_mreq_fifo_rd_data;
wire w_mreq_fifo_empty_n;
pcie_cntl_reg # (
.C_PCIE_DATA_WIDTH (C_PCIE_DATA_WIDTH)
)
pcie_cntl_reg_inst0(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.rx_np_ok (),
.rx_np_req (rx_np_req),
.mreq_fifo_rd_en (w_mreq_fifo_rd_en),
.mreq_fifo_rd_data (w_mreq_fifo_rd_data),
.mreq_fifo_empty_n (w_mreq_fifo_empty_n),
.tx_cpld_req (tx_cpld_req),
.tx_cpld_tag (tx_cpld_tag),
.tx_cpld_req_id (tx_cpld_req_id),
.tx_cpld_len (tx_cpld_len),
.tx_cpld_bc (tx_cpld_bc),
.tx_cpld_laddr (tx_cpld_laddr),
.tx_cpld_data (tx_cpld_data),
.tx_cpld_req_ack (tx_cpld_req_ack),
.nvme_cc_en (nvme_cc_en),
.nvme_cc_shn (nvme_cc_shn),
.nvme_csts_shst (nvme_csts_shst),
.nvme_csts_rdy (nvme_csts_rdy),
.nvme_intms_ivms (nvme_intms_ivms),
.nvme_intmc_ivmc (nvme_intmc_ivmc),
.cq_irq_status (cq_irq_status),
.sq_rst_n (sq_rst_n),
.cq_rst_n (cq_rst_n),
.admin_sq_bs_addr (admin_sq_bs_addr),
.admin_cq_bs_addr (admin_cq_bs_addr),
.admin_sq_size (admin_sq_size),
.admin_cq_size (admin_cq_size),
.admin_sq_tail_ptr (admin_sq_tail_ptr),
.io_sq1_tail_ptr (io_sq1_tail_ptr),
.io_sq2_tail_ptr (io_sq2_tail_ptr),
.io_sq3_tail_ptr (io_sq3_tail_ptr),
.io_sq4_tail_ptr (io_sq4_tail_ptr),
.io_sq5_tail_ptr (io_sq5_tail_ptr),
.io_sq6_tail_ptr (io_sq6_tail_ptr),
.io_sq7_tail_ptr (io_sq7_tail_ptr),
.io_sq8_tail_ptr (io_sq8_tail_ptr),
.admin_cq_head_ptr (admin_cq_head_ptr),
.io_cq1_head_ptr (io_cq1_head_ptr),
.io_cq2_head_ptr (io_cq2_head_ptr),
.io_cq3_head_ptr (io_cq3_head_ptr),
.io_cq4_head_ptr (io_cq4_head_ptr),
.io_cq5_head_ptr (io_cq5_head_ptr),
.io_cq6_head_ptr (io_cq6_head_ptr),
.io_cq7_head_ptr (io_cq7_head_ptr),
.io_cq8_head_ptr (io_cq8_head_ptr),
.cq_head_update (cq_head_update)
);
pcie_cntl_rx_fifo
pcie_cntl_rx_fifo_inst0(
.clk (pcie_user_clk),
.rst_n (pcie_user_rst_n),
////////////////////////////////////////////////////////////////
//bram fifo write signals
.wr_en (mreq_fifo_wr_en),
.wr_data (mreq_fifo_wr_data),
.full_n (),
.almost_full_n (rx_np_ok),
////////////////////////////////////////////////////////////////
//bram fifo read signals
.rd_en (w_mreq_fifo_rd_en),
.rd_data (w_mreq_fifo_rd_data),
.empty_n (w_mreq_fifo_empty_n)
);
endmodule
|
module tx_buffer_inband
( //System
input wire usbclk, input wire bus_reset, input wire reset,
input wire [15:0] usbdata, output wire have_space, input wire [3:0] channels,
//output transmit signals
output wire [15:0] tx_i_0, output wire [15:0] tx_q_0,
output wire [15:0] tx_i_1, output wire [15:0] tx_q_1,
output wire [15:0] tx_i_2, output wire [15:0] tx_q_2,
output wire [15:0] tx_i_3, output wire [15:0] tx_q_3,
input wire txclk, input wire txstrobe, input wire WR,
input wire clear_status, output wire tx_empty, output wire [15:0] debugbus,
//command reader io
output wire [15:0] rx_databus, output wire rx_WR, output wire rx_WR_done,
input wire rx_WR_enabled,
//register io
output wire [1:0] reg_io_enable, output wire [31:0] reg_data_in, output wire [6:0] reg_addr,
input wire [31:0] reg_data_out,
//input characteristic signals
input wire [31:0] rssi_0, input wire [31:0] rssi_1, input wire [31:0] rssi_2,
input wire [31:0] rssi_3, input wire [31:0] rssi_wait, input wire [31:0] threshhold,
output wire [1:0] tx_underrun,
//system stop
output wire stop, output wire [15:0] stop_time, output wire test_bit0, output wire test_bit1);
/* Debug paramters */
parameter STROBE_RATE_0 = 8'd1 ;
parameter STROBE_RATE_1 = 8'd2 ;
parameter NUM_CHAN = 2 ;
/* To generate channel readers */
genvar i ;
/* These will eventually be external register */
reg [31:0] adc_time ;
wire datapattern_err;
wire [7:0] txstrobe_rate [NUM_CHAN-1:0] ;
wire [31:0] rssi [3:0];
assign rssi[0] = rssi_0;
assign rssi[1] = rssi_1;
assign rssi[2] = rssi_2;
assign rssi[3] = rssi_3;
always @(posedge txclk)
if (reset)
adc_time <= 0;
else if (txstrobe)
adc_time <= adc_time + 1;
/* Connections between tx_usb_fifo_reader and
cnannel/command processing blocks */
wire [31:0] tx_data_bus ;
wire [NUM_CHAN:0] chan_WR ;
wire [NUM_CHAN:0] chan_done ;
/* Connections between data block and the
FX2/TX chains */
wire [NUM_CHAN:0] chan_underrun;
wire [NUM_CHAN:0] chan_txempty;
/* Conections between tx_data_packet_fifo and
its reader + strobe generator */
wire [31:0] chan_fifodata [NUM_CHAN:0] ;
wire chan_pkt_waiting [NUM_CHAN:0] ;
wire chan_rdreq [NUM_CHAN:0] ;
wire chan_skip [NUM_CHAN:0] ;
wire chan_have_space [NUM_CHAN:0] ;
wire chan_txstrobe [NUM_CHAN-1:0] ;
wire [14:0] debug [NUM_CHAN:0];
/* Outputs to transmit chains */
wire [15:0] tx_i [NUM_CHAN-1:0] ;
wire [15:0] tx_q [NUM_CHAN-1:0] ;
/* TODO: Figure out how to write this genericly */
assign have_space = chan_have_space[0];// & chan_have_space[1];
assign tx_empty = chan_txempty[0];// & chan_txempty[1] ;
assign tx_i_0 = chan_txempty[0] ? 16'b0 : tx_i[0] ;
assign tx_q_0 = chan_txempty[0] ? 16'b0 : tx_q[0] ;
assign tx_i_1 = chan_txempty[1] ? 16'b0 : tx_i[1] ;
assign tx_q_1 = chan_txempty[1] ? 16'b0 : tx_q[1] ;
assign datapattern_err = ((tx_i_0 != 16'h0000) || (tx_q_0 != 16'hffff)) && !tx_empty;
assign test_bit0 = datapattern_err;
/* Debug statement */
assign txstrobe_rate[0] = STROBE_RATE_0 ;
assign txstrobe_rate[1] = STROBE_RATE_1 ;
assign tx_q_2 = 16'b0 ;
assign tx_i_2 = 16'b0 ;
assign tx_q_3 = 16'b0 ;
assign tx_i_3 = 16'b0 ;
assign tx_i_3 = 16'b0 ;
wire [31:0] usbdata_final;
wire WR_final;
assign debugbus = {have_space, txclk, WR, WR_final, chan_WR, chan_done,
chan_pkt_waiting[0], chan_pkt_waiting[1],
chan_rdreq[0], chan_rdreq[1], chan_txempty[0], chan_txempty[1]};
tx_packer tx_usb_packer
(.bus_reset(bus_reset), .usbclk(usbclk), .WR_fx2(WR),
.usbdata(usbdata), .reset(reset), .txclk(txclk),
.usbdata_final(usbdata_final), .WR_final(WR_final),
.test_bit0(), .test_bit1(test_bit1));
channel_demux channel_demuxer
(.usbdata_final(usbdata_final), .WR_final(WR_final),
.reset(reset), .txclk(txclk), .WR_channel(chan_WR),
.WR_done_channel(chan_done), .ram_data(tx_data_bus));
generate for (i = 0 ; i < NUM_CHAN; i = i + 1)
begin : generate_channel_readers
assign tx_underrun[i] = chan_underrun[i];
channel_ram tx_data_packet_fifo
(.reset(reset), .txclk(txclk), .datain(tx_data_bus),
.WR(chan_WR[i]), .WR_done(chan_done[i]),
.have_space(chan_have_space[i]), .dataout(chan_fifodata[i]),
.packet_waiting(chan_pkt_waiting[i]), .RD(chan_rdreq[i]),
.RD_done(chan_skip[i]));
chan_fifo_reader tx_chan_reader
(.reset(reset), .tx_clock(txclk), .tx_strobe(txstrobe),
.adc_time(adc_time), .samples_format(4'b0),
.tx_q(tx_q[i]), .tx_i(tx_i[i]), .underrun(chan_underrun[i]),
.skip(chan_skip[i]), .rdreq(chan_rdreq[i]),
.fifodata(chan_fifodata[i]), .pkt_waiting(chan_pkt_waiting[i]),
.tx_empty(chan_txempty[i]), .rssi(rssi[i]), .debug(debug[i]),
.threshhold(threshhold), .rssi_wait(rssi_wait));
end
endgenerate
channel_ram tx_cmd_packet_fifo
(.reset(reset), .txclk(txclk), .datain(tx_data_bus), .WR(chan_WR[NUM_CHAN]),
.WR_done(chan_done[NUM_CHAN]), .have_space(chan_have_space[NUM_CHAN]),
.dataout(chan_fifodata[NUM_CHAN]), .packet_waiting(chan_pkt_waiting[NUM_CHAN]),
.RD(chan_rdreq[NUM_CHAN]), .RD_done(chan_skip[NUM_CHAN]));
cmd_reader tx_cmd_reader
(.reset(reset), .txclk(txclk), .adc_time(adc_time), .skip(chan_skip[NUM_CHAN]),
.rdreq(chan_rdreq[NUM_CHAN]), .fifodata(chan_fifodata[NUM_CHAN]),
.pkt_waiting(chan_pkt_waiting[NUM_CHAN]), .rx_databus(rx_databus),
.rx_WR(rx_WR), .rx_WR_done(rx_WR_done), .rx_WR_enabled(rx_WR_enabled),
.reg_data_in(reg_data_in), .reg_data_out(reg_data_out), .reg_addr(reg_addr),
.reg_io_enable(reg_io_enable), .debug(debug[NUM_CHAN]), .stop(stop), .stop_time(stop_time));
endmodule // tx_buffer
|
module tx_buffer_inband
( //System
input wire usbclk, input wire bus_reset, input wire reset,
input wire [15:0] usbdata, output wire have_space, input wire [3:0] channels,
//output transmit signals
output wire [15:0] tx_i_0, output wire [15:0] tx_q_0,
output wire [15:0] tx_i_1, output wire [15:0] tx_q_1,
output wire [15:0] tx_i_2, output wire [15:0] tx_q_2,
output wire [15:0] tx_i_3, output wire [15:0] tx_q_3,
input wire txclk, input wire txstrobe, input wire WR,
input wire clear_status, output wire tx_empty, output wire [15:0] debugbus,
//command reader io
output wire [15:0] rx_databus, output wire rx_WR, output wire rx_WR_done,
input wire rx_WR_enabled,
//register io
output wire [1:0] reg_io_enable, output wire [31:0] reg_data_in, output wire [6:0] reg_addr,
input wire [31:0] reg_data_out,
//input characteristic signals
input wire [31:0] rssi_0, input wire [31:0] rssi_1, input wire [31:0] rssi_2,
input wire [31:0] rssi_3, input wire [31:0] rssi_wait, input wire [31:0] threshhold,
output wire [1:0] tx_underrun,
//system stop
output wire stop, output wire [15:0] stop_time, output wire test_bit0, output wire test_bit1);
/* Debug paramters */
parameter STROBE_RATE_0 = 8'd1 ;
parameter STROBE_RATE_1 = 8'd2 ;
parameter NUM_CHAN = 2 ;
/* To generate channel readers */
genvar i ;
/* These will eventually be external register */
reg [31:0] adc_time ;
wire datapattern_err;
wire [7:0] txstrobe_rate [NUM_CHAN-1:0] ;
wire [31:0] rssi [3:0];
assign rssi[0] = rssi_0;
assign rssi[1] = rssi_1;
assign rssi[2] = rssi_2;
assign rssi[3] = rssi_3;
always @(posedge txclk)
if (reset)
adc_time <= 0;
else if (txstrobe)
adc_time <= adc_time + 1;
/* Connections between tx_usb_fifo_reader and
cnannel/command processing blocks */
wire [31:0] tx_data_bus ;
wire [NUM_CHAN:0] chan_WR ;
wire [NUM_CHAN:0] chan_done ;
/* Connections between data block and the
FX2/TX chains */
wire [NUM_CHAN:0] chan_underrun;
wire [NUM_CHAN:0] chan_txempty;
/* Conections between tx_data_packet_fifo and
its reader + strobe generator */
wire [31:0] chan_fifodata [NUM_CHAN:0] ;
wire chan_pkt_waiting [NUM_CHAN:0] ;
wire chan_rdreq [NUM_CHAN:0] ;
wire chan_skip [NUM_CHAN:0] ;
wire chan_have_space [NUM_CHAN:0] ;
wire chan_txstrobe [NUM_CHAN-1:0] ;
wire [14:0] debug [NUM_CHAN:0];
/* Outputs to transmit chains */
wire [15:0] tx_i [NUM_CHAN-1:0] ;
wire [15:0] tx_q [NUM_CHAN-1:0] ;
/* TODO: Figure out how to write this genericly */
assign have_space = chan_have_space[0];// & chan_have_space[1];
assign tx_empty = chan_txempty[0];// & chan_txempty[1] ;
assign tx_i_0 = chan_txempty[0] ? 16'b0 : tx_i[0] ;
assign tx_q_0 = chan_txempty[0] ? 16'b0 : tx_q[0] ;
assign tx_i_1 = chan_txempty[1] ? 16'b0 : tx_i[1] ;
assign tx_q_1 = chan_txempty[1] ? 16'b0 : tx_q[1] ;
assign datapattern_err = ((tx_i_0 != 16'h0000) || (tx_q_0 != 16'hffff)) && !tx_empty;
assign test_bit0 = datapattern_err;
/* Debug statement */
assign txstrobe_rate[0] = STROBE_RATE_0 ;
assign txstrobe_rate[1] = STROBE_RATE_1 ;
assign tx_q_2 = 16'b0 ;
assign tx_i_2 = 16'b0 ;
assign tx_q_3 = 16'b0 ;
assign tx_i_3 = 16'b0 ;
assign tx_i_3 = 16'b0 ;
wire [31:0] usbdata_final;
wire WR_final;
assign debugbus = {have_space, txclk, WR, WR_final, chan_WR, chan_done,
chan_pkt_waiting[0], chan_pkt_waiting[1],
chan_rdreq[0], chan_rdreq[1], chan_txempty[0], chan_txempty[1]};
tx_packer tx_usb_packer
(.bus_reset(bus_reset), .usbclk(usbclk), .WR_fx2(WR),
.usbdata(usbdata), .reset(reset), .txclk(txclk),
.usbdata_final(usbdata_final), .WR_final(WR_final),
.test_bit0(), .test_bit1(test_bit1));
channel_demux channel_demuxer
(.usbdata_final(usbdata_final), .WR_final(WR_final),
.reset(reset), .txclk(txclk), .WR_channel(chan_WR),
.WR_done_channel(chan_done), .ram_data(tx_data_bus));
generate for (i = 0 ; i < NUM_CHAN; i = i + 1)
begin : generate_channel_readers
assign tx_underrun[i] = chan_underrun[i];
channel_ram tx_data_packet_fifo
(.reset(reset), .txclk(txclk), .datain(tx_data_bus),
.WR(chan_WR[i]), .WR_done(chan_done[i]),
.have_space(chan_have_space[i]), .dataout(chan_fifodata[i]),
.packet_waiting(chan_pkt_waiting[i]), .RD(chan_rdreq[i]),
.RD_done(chan_skip[i]));
chan_fifo_reader tx_chan_reader
(.reset(reset), .tx_clock(txclk), .tx_strobe(txstrobe),
.adc_time(adc_time), .samples_format(4'b0),
.tx_q(tx_q[i]), .tx_i(tx_i[i]), .underrun(chan_underrun[i]),
.skip(chan_skip[i]), .rdreq(chan_rdreq[i]),
.fifodata(chan_fifodata[i]), .pkt_waiting(chan_pkt_waiting[i]),
.tx_empty(chan_txempty[i]), .rssi(rssi[i]), .debug(debug[i]),
.threshhold(threshhold), .rssi_wait(rssi_wait));
end
endgenerate
channel_ram tx_cmd_packet_fifo
(.reset(reset), .txclk(txclk), .datain(tx_data_bus), .WR(chan_WR[NUM_CHAN]),
.WR_done(chan_done[NUM_CHAN]), .have_space(chan_have_space[NUM_CHAN]),
.dataout(chan_fifodata[NUM_CHAN]), .packet_waiting(chan_pkt_waiting[NUM_CHAN]),
.RD(chan_rdreq[NUM_CHAN]), .RD_done(chan_skip[NUM_CHAN]));
cmd_reader tx_cmd_reader
(.reset(reset), .txclk(txclk), .adc_time(adc_time), .skip(chan_skip[NUM_CHAN]),
.rdreq(chan_rdreq[NUM_CHAN]), .fifodata(chan_fifodata[NUM_CHAN]),
.pkt_waiting(chan_pkt_waiting[NUM_CHAN]), .rx_databus(rx_databus),
.rx_WR(rx_WR), .rx_WR_done(rx_WR_done), .rx_WR_enabled(rx_WR_enabled),
.reg_data_in(reg_data_in), .reg_data_out(reg_data_out), .reg_addr(reg_addr),
.reg_io_enable(reg_io_enable), .debug(debug[NUM_CHAN]), .stop(stop), .stop_time(stop_time));
endmodule // tx_buffer
|
/*
----------------------------------------------------------------------------------
Copyright (c) 2013-2014
Embedded and Network Computing Lab.
Open SSD Project
Hanyang University
All rights reserved.
----------------------------------------------------------------------------------
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. All advertising materials mentioning features or use of this source code
must display the following acknowledgement:
This product includes source code developed
by the Embedded and Network Computing Lab. and the Open SSD Project.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
----------------------------------------------------------------------------------
http://enclab.hanyang.ac.kr/
http://www.openssd-project.org/
http://www.hanyang.ac.kr/
----------------------------------------------------------------------------------
*/
`timescale 1ns / 1ps
module pcie_hcmd_sq # (
parameter C_PCIE_DATA_WIDTH = 128,
parameter C_PCIE_ADDR_WIDTH = 36
)
(
input pcie_user_clk,
input pcie_user_rst_n,
input [C_PCIE_ADDR_WIDTH-1:2] admin_sq_bs_addr,
input [7:0] admin_sq_size,
input [7:0] admin_sq_tail_ptr,
input [7:0] io_sq1_tail_ptr,
input [7:0] io_sq2_tail_ptr,
input [7:0] io_sq3_tail_ptr,
input [7:0] io_sq4_tail_ptr,
input [7:0] io_sq5_tail_ptr,
input [7:0] io_sq6_tail_ptr,
input [7:0] io_sq7_tail_ptr,
input [7:0] io_sq8_tail_ptr,
output [7:0] admin_sq_head_ptr,
output [7:0] io_sq1_head_ptr,
output [7:0] io_sq2_head_ptr,
output [7:0] io_sq3_head_ptr,
output [7:0] io_sq4_head_ptr,
output [7:0] io_sq5_head_ptr,
output [7:0] io_sq6_head_ptr,
output [7:0] io_sq7_head_ptr,
output [7:0] io_sq8_head_ptr,
input hcmd_slot_rdy,
input [6:0] hcmd_slot_tag,
output hcmd_slot_alloc_en,
input [7:0] cpld_sq_fifo_tag,
input [C_PCIE_DATA_WIDTH-1:0] cpld_sq_fifo_wr_data,
input cpld_sq_fifo_wr_en,
input cpld_sq_fifo_tag_last,
output tx_mrd_req,
output [7:0] tx_mrd_tag,
output [11:2] tx_mrd_len,
output [C_PCIE_ADDR_WIDTH-1:2] tx_mrd_addr,
input tx_mrd_req_ack,
output hcmd_table_wr_en,
output [8:0] hcmd_table_wr_addr,
output [C_PCIE_DATA_WIDTH-1:0] hcmd_table_wr_data,
output hcmd_cid_wr_en,
output [6:0] hcmd_cid_wr_addr,
output [19:0] hcmd_cid_wr_data,
output hcmd_prp_wr_en,
output [7:0] hcmd_prp_wr_addr,
output [44:0] hcmd_prp_wr_data,
output hcmd_nlb_wr0_en,
output [6:0] hcmd_nlb_wr0_addr,
output [18:0] hcmd_nlb_wr0_data,
input hcmd_nlb_wr0_rdy_n,
input cpu_bus_clk,
input cpu_bus_rst_n,
input [8:0] sq_rst_n,
input [8:0] sq_valid,
input [7:0] io_sq1_size,
input [7:0] io_sq2_size,
input [7:0] io_sq3_size,
input [7:0] io_sq4_size,
input [7:0] io_sq5_size,
input [7:0] io_sq6_size,
input [7:0] io_sq7_size,
input [7:0] io_sq8_size,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq1_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq2_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq3_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq4_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq5_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq6_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq7_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq8_bs_addr,
input hcmd_sq_rd_en,
output [18:0] hcmd_sq_rd_data,
output hcmd_sq_empty_n
);
wire w_arb_sq_rdy;
wire [3:0] w_sq_qid;
wire [C_PCIE_ADDR_WIDTH-1:2] w_hcmd_pcie_addr;
wire w_sq_hcmd_ack;
wire w_hcmd_sq_wr_en;
wire [18:0] w_hcmd_sq_wr_data;
wire w_hcmd_sq_full_n;
wire w_pcie_sq_cmd_fifo_wr_en;
wire [10:0] w_pcie_sq_cmd_fifo_wr_data;
wire w_pcie_sq_cmd_fifo_full_n;
wire w_pcie_sq_cmd_fifo_rd_en;
wire [10:0] w_pcie_sq_cmd_fifo_rd_data;
wire w_pcie_sq_cmd_fifo_empty_n;
wire w_pcie_sq_rx_tag_alloc;
wire [7:0] w_pcie_sq_rx_alloc_tag;
wire [6:4] w_pcie_sq_rx_tag_alloc_len;
wire w_pcie_sq_rx_tag_full_n;
wire w_pcie_sq_rx_fifo_wr_en;
wire [3:0] w_pcie_sq_rx_fifo_wr_addr;
wire [C_PCIE_DATA_WIDTH-1:0] w_pcie_sq_rx_fifo_wr_data;
wire [4:0] w_pcie_sq_rx_fifo_rear_full_addr;
wire [4:0] w_pcie_sq_rx_fifo_rear_addr;
wire w_pcie_sq_rx_fifo_full_n;
wire w_pcie_sq_rx_fifo_rd_en;
wire [C_PCIE_DATA_WIDTH-1:0] w_pcie_sq_rx_fifo_rd_data;
wire w_pcie_sq_rx_fifo_free_en;
wire [6:4] w_pcie_sq_rx_fifo_free_len;
wire w_pcie_sq_rx_fifo_empty_n;
pcie_hcmd_sq_fifo
pcie_hcmd_sq_fifo_inst0(
.wr_clk (pcie_user_clk),
.wr_rst_n (pcie_user_rst_n),
.wr_en (w_hcmd_sq_wr_en),
.wr_data (w_hcmd_sq_wr_data),
.full_n (w_hcmd_sq_full_n),
.rd_clk (cpu_bus_clk),
.rd_rst_n (pcie_user_rst_n),
.rd_en (hcmd_sq_rd_en),
.rd_data (hcmd_sq_rd_data),
.empty_n (hcmd_sq_empty_n)
);
pcie_sq_cmd_fifo
pcie_sq_cmd_fifo_inst0
(
.clk (pcie_user_clk),
.rst_n (pcie_user_rst_n),
.wr_en (w_pcie_sq_cmd_fifo_wr_en),
.wr_data (w_pcie_sq_cmd_fifo_wr_data),
.full_n (w_pcie_sq_cmd_fifo_full_n),
.rd_en (w_pcie_sq_cmd_fifo_rd_en),
.rd_data (w_pcie_sq_cmd_fifo_rd_data),
.empty_n (w_pcie_sq_cmd_fifo_empty_n)
);
pcie_sq_rx_fifo
pcie_sq_rx_fifo_inst0
(
.clk (pcie_user_clk),
.rst_n (pcie_user_rst_n),
.wr_en (w_pcie_sq_rx_fifo_wr_en),
.wr_addr (w_pcie_sq_rx_fifo_wr_addr),
.wr_data (w_pcie_sq_rx_fifo_wr_data),
.rear_full_addr (w_pcie_sq_rx_fifo_rear_full_addr),
.rear_addr (w_pcie_sq_rx_fifo_rear_addr),
.alloc_len (w_pcie_sq_rx_tag_alloc_len),
.full_n (w_pcie_sq_rx_fifo_full_n),
.rd_en (w_pcie_sq_rx_fifo_rd_en),
.rd_data (w_pcie_sq_rx_fifo_rd_data),
.free_en (w_pcie_sq_rx_fifo_free_en),
.free_len (w_pcie_sq_rx_fifo_free_len),
.empty_n (w_pcie_sq_rx_fifo_empty_n)
);
pcie_sq_rx_tag
pcie_sq_rx_tag_inst0
(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.pcie_tag_alloc (w_pcie_sq_rx_tag_alloc),
.pcie_alloc_tag (w_pcie_sq_rx_alloc_tag),
.pcie_tag_alloc_len (w_pcie_sq_rx_tag_alloc_len),
.pcie_tag_full_n (w_pcie_sq_rx_tag_full_n),
.cpld_fifo_tag (cpld_sq_fifo_tag),
.cpld_fifo_wr_data (cpld_sq_fifo_wr_data),
.cpld_fifo_wr_en (cpld_sq_fifo_wr_en),
.cpld_fifo_tag_last (cpld_sq_fifo_tag_last),
.fifo_wr_en (w_pcie_sq_rx_fifo_wr_en),
.fifo_wr_addr (w_pcie_sq_rx_fifo_wr_addr),
.fifo_wr_data (w_pcie_sq_rx_fifo_wr_data),
.rear_full_addr (w_pcie_sq_rx_fifo_rear_full_addr),
.rear_addr (w_pcie_sq_rx_fifo_rear_addr)
);
pcie_hcmd_sq_arb
pcie_hcmd_sq_arb_inst0
(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.sq_rst_n (sq_rst_n),
.sq_valid (sq_valid),
.admin_sq_size (admin_sq_size),
.io_sq1_size (io_sq1_size),
.io_sq2_size (io_sq2_size),
.io_sq3_size (io_sq3_size),
.io_sq4_size (io_sq4_size),
.io_sq5_size (io_sq5_size),
.io_sq6_size (io_sq6_size),
.io_sq7_size (io_sq7_size),
.io_sq8_size (io_sq8_size),
.admin_sq_bs_addr (admin_sq_bs_addr),
.io_sq1_bs_addr (io_sq1_bs_addr),
.io_sq2_bs_addr (io_sq2_bs_addr),
.io_sq3_bs_addr (io_sq3_bs_addr),
.io_sq4_bs_addr (io_sq4_bs_addr),
.io_sq5_bs_addr (io_sq5_bs_addr),
.io_sq6_bs_addr (io_sq6_bs_addr),
.io_sq7_bs_addr (io_sq7_bs_addr),
.io_sq8_bs_addr (io_sq8_bs_addr),
.admin_sq_tail_ptr (admin_sq_tail_ptr),
.io_sq1_tail_ptr (io_sq1_tail_ptr),
.io_sq2_tail_ptr (io_sq2_tail_ptr),
.io_sq3_tail_ptr (io_sq3_tail_ptr),
.io_sq4_tail_ptr (io_sq4_tail_ptr),
.io_sq5_tail_ptr (io_sq5_tail_ptr),
.io_sq6_tail_ptr (io_sq6_tail_ptr),
.io_sq7_tail_ptr (io_sq7_tail_ptr),
.io_sq8_tail_ptr (io_sq8_tail_ptr),
.arb_sq_rdy (w_arb_sq_rdy),
.sq_qid (w_sq_qid),
.hcmd_pcie_addr (w_hcmd_pcie_addr),
.sq_hcmd_ack (w_sq_hcmd_ack)
);
pcie_hcmd_sq_req # (
.C_PCIE_DATA_WIDTH (C_PCIE_DATA_WIDTH)
)
pcie_hcmd_sq_req_inst0(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.arb_sq_rdy (w_arb_sq_rdy),
.sq_qid (w_sq_qid),
.hcmd_pcie_addr (w_hcmd_pcie_addr),
.sq_hcmd_ack (w_sq_hcmd_ack),
.hcmd_slot_rdy (hcmd_slot_rdy),
.hcmd_slot_tag (hcmd_slot_tag),
.hcmd_slot_alloc_en (hcmd_slot_alloc_en),
.pcie_sq_cmd_fifo_wr_en (w_pcie_sq_cmd_fifo_wr_en),
.pcie_sq_cmd_fifo_wr_data (w_pcie_sq_cmd_fifo_wr_data),
.pcie_sq_cmd_fifo_full_n (w_pcie_sq_cmd_fifo_full_n),
.pcie_sq_rx_tag_alloc (w_pcie_sq_rx_tag_alloc),
.pcie_sq_rx_alloc_tag (w_pcie_sq_rx_alloc_tag),
.pcie_sq_rx_tag_alloc_len (w_pcie_sq_rx_tag_alloc_len),
.pcie_sq_rx_tag_full_n (w_pcie_sq_rx_tag_full_n),
.pcie_sq_rx_fifo_full_n (w_pcie_sq_rx_fifo_full_n),
.tx_mrd_req (tx_mrd_req),
.tx_mrd_tag (tx_mrd_tag),
.tx_mrd_len (tx_mrd_len),
.tx_mrd_addr (tx_mrd_addr),
.tx_mrd_req_ack (tx_mrd_req_ack)
);
pcie_hcmd_sq_recv
pcie_hcmd_sq_recv_inst0
(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.pcie_sq_cmd_fifo_rd_en (w_pcie_sq_cmd_fifo_rd_en),
.pcie_sq_cmd_fifo_rd_data (w_pcie_sq_cmd_fifo_rd_data),
.pcie_sq_cmd_fifo_empty_n (w_pcie_sq_cmd_fifo_empty_n),
.pcie_sq_rx_fifo_rd_en (w_pcie_sq_rx_fifo_rd_en),
.pcie_sq_rx_fifo_rd_data (w_pcie_sq_rx_fifo_rd_data),
.pcie_sq_rx_fifo_free_en (w_pcie_sq_rx_fifo_free_en),
.pcie_sq_rx_fifo_free_len (w_pcie_sq_rx_fifo_free_len),
.pcie_sq_rx_fifo_empty_n (w_pcie_sq_rx_fifo_empty_n),
.hcmd_table_wr_en (hcmd_table_wr_en),
.hcmd_table_wr_addr (hcmd_table_wr_addr),
.hcmd_table_wr_data (hcmd_table_wr_data),
.hcmd_cid_wr_en (hcmd_cid_wr_en),
.hcmd_cid_wr_addr (hcmd_cid_wr_addr),
.hcmd_cid_wr_data (hcmd_cid_wr_data),
.hcmd_prp_wr_en (hcmd_prp_wr_en),
.hcmd_prp_wr_addr (hcmd_prp_wr_addr),
.hcmd_prp_wr_data (hcmd_prp_wr_data),
.hcmd_nlb_wr0_en (hcmd_nlb_wr0_en),
.hcmd_nlb_wr0_addr (hcmd_nlb_wr0_addr),
.hcmd_nlb_wr0_data (hcmd_nlb_wr0_data),
.hcmd_nlb_wr0_rdy_n (hcmd_nlb_wr0_rdy_n),
.hcmd_sq_wr_en (w_hcmd_sq_wr_en),
.hcmd_sq_wr_data (w_hcmd_sq_wr_data),
.hcmd_sq_full_n (w_hcmd_sq_full_n),
.sq_rst_n (sq_rst_n),
.admin_sq_size (admin_sq_size),
.io_sq1_size (io_sq1_size),
.io_sq2_size (io_sq2_size),
.io_sq3_size (io_sq3_size),
.io_sq4_size (io_sq4_size),
.io_sq5_size (io_sq5_size),
.io_sq6_size (io_sq6_size),
.io_sq7_size (io_sq7_size),
.io_sq8_size (io_sq8_size),
.admin_sq_head_ptr (admin_sq_head_ptr),
.io_sq1_head_ptr (io_sq1_head_ptr),
.io_sq2_head_ptr (io_sq2_head_ptr),
.io_sq3_head_ptr (io_sq3_head_ptr),
.io_sq4_head_ptr (io_sq4_head_ptr),
.io_sq5_head_ptr (io_sq5_head_ptr),
.io_sq6_head_ptr (io_sq6_head_ptr),
.io_sq7_head_ptr (io_sq7_head_ptr),
.io_sq8_head_ptr (io_sq8_head_ptr)
);
endmodule
|
/*
----------------------------------------------------------------------------------
Copyright (c) 2013-2014
Embedded and Network Computing Lab.
Open SSD Project
Hanyang University
All rights reserved.
----------------------------------------------------------------------------------
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. All advertising materials mentioning features or use of this source code
must display the following acknowledgement:
This product includes source code developed
by the Embedded and Network Computing Lab. and the Open SSD Project.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
----------------------------------------------------------------------------------
http://enclab.hanyang.ac.kr/
http://www.openssd-project.org/
http://www.hanyang.ac.kr/
----------------------------------------------------------------------------------
*/
`timescale 1ns / 1ps
module pcie_hcmd_sq # (
parameter C_PCIE_DATA_WIDTH = 128,
parameter C_PCIE_ADDR_WIDTH = 36
)
(
input pcie_user_clk,
input pcie_user_rst_n,
input [C_PCIE_ADDR_WIDTH-1:2] admin_sq_bs_addr,
input [7:0] admin_sq_size,
input [7:0] admin_sq_tail_ptr,
input [7:0] io_sq1_tail_ptr,
input [7:0] io_sq2_tail_ptr,
input [7:0] io_sq3_tail_ptr,
input [7:0] io_sq4_tail_ptr,
input [7:0] io_sq5_tail_ptr,
input [7:0] io_sq6_tail_ptr,
input [7:0] io_sq7_tail_ptr,
input [7:0] io_sq8_tail_ptr,
output [7:0] admin_sq_head_ptr,
output [7:0] io_sq1_head_ptr,
output [7:0] io_sq2_head_ptr,
output [7:0] io_sq3_head_ptr,
output [7:0] io_sq4_head_ptr,
output [7:0] io_sq5_head_ptr,
output [7:0] io_sq6_head_ptr,
output [7:0] io_sq7_head_ptr,
output [7:0] io_sq8_head_ptr,
input hcmd_slot_rdy,
input [6:0] hcmd_slot_tag,
output hcmd_slot_alloc_en,
input [7:0] cpld_sq_fifo_tag,
input [C_PCIE_DATA_WIDTH-1:0] cpld_sq_fifo_wr_data,
input cpld_sq_fifo_wr_en,
input cpld_sq_fifo_tag_last,
output tx_mrd_req,
output [7:0] tx_mrd_tag,
output [11:2] tx_mrd_len,
output [C_PCIE_ADDR_WIDTH-1:2] tx_mrd_addr,
input tx_mrd_req_ack,
output hcmd_table_wr_en,
output [8:0] hcmd_table_wr_addr,
output [C_PCIE_DATA_WIDTH-1:0] hcmd_table_wr_data,
output hcmd_cid_wr_en,
output [6:0] hcmd_cid_wr_addr,
output [19:0] hcmd_cid_wr_data,
output hcmd_prp_wr_en,
output [7:0] hcmd_prp_wr_addr,
output [44:0] hcmd_prp_wr_data,
output hcmd_nlb_wr0_en,
output [6:0] hcmd_nlb_wr0_addr,
output [18:0] hcmd_nlb_wr0_data,
input hcmd_nlb_wr0_rdy_n,
input cpu_bus_clk,
input cpu_bus_rst_n,
input [8:0] sq_rst_n,
input [8:0] sq_valid,
input [7:0] io_sq1_size,
input [7:0] io_sq2_size,
input [7:0] io_sq3_size,
input [7:0] io_sq4_size,
input [7:0] io_sq5_size,
input [7:0] io_sq6_size,
input [7:0] io_sq7_size,
input [7:0] io_sq8_size,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq1_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq2_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq3_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq4_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq5_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq6_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq7_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq8_bs_addr,
input hcmd_sq_rd_en,
output [18:0] hcmd_sq_rd_data,
output hcmd_sq_empty_n
);
wire w_arb_sq_rdy;
wire [3:0] w_sq_qid;
wire [C_PCIE_ADDR_WIDTH-1:2] w_hcmd_pcie_addr;
wire w_sq_hcmd_ack;
wire w_hcmd_sq_wr_en;
wire [18:0] w_hcmd_sq_wr_data;
wire w_hcmd_sq_full_n;
wire w_pcie_sq_cmd_fifo_wr_en;
wire [10:0] w_pcie_sq_cmd_fifo_wr_data;
wire w_pcie_sq_cmd_fifo_full_n;
wire w_pcie_sq_cmd_fifo_rd_en;
wire [10:0] w_pcie_sq_cmd_fifo_rd_data;
wire w_pcie_sq_cmd_fifo_empty_n;
wire w_pcie_sq_rx_tag_alloc;
wire [7:0] w_pcie_sq_rx_alloc_tag;
wire [6:4] w_pcie_sq_rx_tag_alloc_len;
wire w_pcie_sq_rx_tag_full_n;
wire w_pcie_sq_rx_fifo_wr_en;
wire [3:0] w_pcie_sq_rx_fifo_wr_addr;
wire [C_PCIE_DATA_WIDTH-1:0] w_pcie_sq_rx_fifo_wr_data;
wire [4:0] w_pcie_sq_rx_fifo_rear_full_addr;
wire [4:0] w_pcie_sq_rx_fifo_rear_addr;
wire w_pcie_sq_rx_fifo_full_n;
wire w_pcie_sq_rx_fifo_rd_en;
wire [C_PCIE_DATA_WIDTH-1:0] w_pcie_sq_rx_fifo_rd_data;
wire w_pcie_sq_rx_fifo_free_en;
wire [6:4] w_pcie_sq_rx_fifo_free_len;
wire w_pcie_sq_rx_fifo_empty_n;
pcie_hcmd_sq_fifo
pcie_hcmd_sq_fifo_inst0(
.wr_clk (pcie_user_clk),
.wr_rst_n (pcie_user_rst_n),
.wr_en (w_hcmd_sq_wr_en),
.wr_data (w_hcmd_sq_wr_data),
.full_n (w_hcmd_sq_full_n),
.rd_clk (cpu_bus_clk),
.rd_rst_n (pcie_user_rst_n),
.rd_en (hcmd_sq_rd_en),
.rd_data (hcmd_sq_rd_data),
.empty_n (hcmd_sq_empty_n)
);
pcie_sq_cmd_fifo
pcie_sq_cmd_fifo_inst0
(
.clk (pcie_user_clk),
.rst_n (pcie_user_rst_n),
.wr_en (w_pcie_sq_cmd_fifo_wr_en),
.wr_data (w_pcie_sq_cmd_fifo_wr_data),
.full_n (w_pcie_sq_cmd_fifo_full_n),
.rd_en (w_pcie_sq_cmd_fifo_rd_en),
.rd_data (w_pcie_sq_cmd_fifo_rd_data),
.empty_n (w_pcie_sq_cmd_fifo_empty_n)
);
pcie_sq_rx_fifo
pcie_sq_rx_fifo_inst0
(
.clk (pcie_user_clk),
.rst_n (pcie_user_rst_n),
.wr_en (w_pcie_sq_rx_fifo_wr_en),
.wr_addr (w_pcie_sq_rx_fifo_wr_addr),
.wr_data (w_pcie_sq_rx_fifo_wr_data),
.rear_full_addr (w_pcie_sq_rx_fifo_rear_full_addr),
.rear_addr (w_pcie_sq_rx_fifo_rear_addr),
.alloc_len (w_pcie_sq_rx_tag_alloc_len),
.full_n (w_pcie_sq_rx_fifo_full_n),
.rd_en (w_pcie_sq_rx_fifo_rd_en),
.rd_data (w_pcie_sq_rx_fifo_rd_data),
.free_en (w_pcie_sq_rx_fifo_free_en),
.free_len (w_pcie_sq_rx_fifo_free_len),
.empty_n (w_pcie_sq_rx_fifo_empty_n)
);
pcie_sq_rx_tag
pcie_sq_rx_tag_inst0
(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.pcie_tag_alloc (w_pcie_sq_rx_tag_alloc),
.pcie_alloc_tag (w_pcie_sq_rx_alloc_tag),
.pcie_tag_alloc_len (w_pcie_sq_rx_tag_alloc_len),
.pcie_tag_full_n (w_pcie_sq_rx_tag_full_n),
.cpld_fifo_tag (cpld_sq_fifo_tag),
.cpld_fifo_wr_data (cpld_sq_fifo_wr_data),
.cpld_fifo_wr_en (cpld_sq_fifo_wr_en),
.cpld_fifo_tag_last (cpld_sq_fifo_tag_last),
.fifo_wr_en (w_pcie_sq_rx_fifo_wr_en),
.fifo_wr_addr (w_pcie_sq_rx_fifo_wr_addr),
.fifo_wr_data (w_pcie_sq_rx_fifo_wr_data),
.rear_full_addr (w_pcie_sq_rx_fifo_rear_full_addr),
.rear_addr (w_pcie_sq_rx_fifo_rear_addr)
);
pcie_hcmd_sq_arb
pcie_hcmd_sq_arb_inst0
(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.sq_rst_n (sq_rst_n),
.sq_valid (sq_valid),
.admin_sq_size (admin_sq_size),
.io_sq1_size (io_sq1_size),
.io_sq2_size (io_sq2_size),
.io_sq3_size (io_sq3_size),
.io_sq4_size (io_sq4_size),
.io_sq5_size (io_sq5_size),
.io_sq6_size (io_sq6_size),
.io_sq7_size (io_sq7_size),
.io_sq8_size (io_sq8_size),
.admin_sq_bs_addr (admin_sq_bs_addr),
.io_sq1_bs_addr (io_sq1_bs_addr),
.io_sq2_bs_addr (io_sq2_bs_addr),
.io_sq3_bs_addr (io_sq3_bs_addr),
.io_sq4_bs_addr (io_sq4_bs_addr),
.io_sq5_bs_addr (io_sq5_bs_addr),
.io_sq6_bs_addr (io_sq6_bs_addr),
.io_sq7_bs_addr (io_sq7_bs_addr),
.io_sq8_bs_addr (io_sq8_bs_addr),
.admin_sq_tail_ptr (admin_sq_tail_ptr),
.io_sq1_tail_ptr (io_sq1_tail_ptr),
.io_sq2_tail_ptr (io_sq2_tail_ptr),
.io_sq3_tail_ptr (io_sq3_tail_ptr),
.io_sq4_tail_ptr (io_sq4_tail_ptr),
.io_sq5_tail_ptr (io_sq5_tail_ptr),
.io_sq6_tail_ptr (io_sq6_tail_ptr),
.io_sq7_tail_ptr (io_sq7_tail_ptr),
.io_sq8_tail_ptr (io_sq8_tail_ptr),
.arb_sq_rdy (w_arb_sq_rdy),
.sq_qid (w_sq_qid),
.hcmd_pcie_addr (w_hcmd_pcie_addr),
.sq_hcmd_ack (w_sq_hcmd_ack)
);
pcie_hcmd_sq_req # (
.C_PCIE_DATA_WIDTH (C_PCIE_DATA_WIDTH)
)
pcie_hcmd_sq_req_inst0(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.arb_sq_rdy (w_arb_sq_rdy),
.sq_qid (w_sq_qid),
.hcmd_pcie_addr (w_hcmd_pcie_addr),
.sq_hcmd_ack (w_sq_hcmd_ack),
.hcmd_slot_rdy (hcmd_slot_rdy),
.hcmd_slot_tag (hcmd_slot_tag),
.hcmd_slot_alloc_en (hcmd_slot_alloc_en),
.pcie_sq_cmd_fifo_wr_en (w_pcie_sq_cmd_fifo_wr_en),
.pcie_sq_cmd_fifo_wr_data (w_pcie_sq_cmd_fifo_wr_data),
.pcie_sq_cmd_fifo_full_n (w_pcie_sq_cmd_fifo_full_n),
.pcie_sq_rx_tag_alloc (w_pcie_sq_rx_tag_alloc),
.pcie_sq_rx_alloc_tag (w_pcie_sq_rx_alloc_tag),
.pcie_sq_rx_tag_alloc_len (w_pcie_sq_rx_tag_alloc_len),
.pcie_sq_rx_tag_full_n (w_pcie_sq_rx_tag_full_n),
.pcie_sq_rx_fifo_full_n (w_pcie_sq_rx_fifo_full_n),
.tx_mrd_req (tx_mrd_req),
.tx_mrd_tag (tx_mrd_tag),
.tx_mrd_len (tx_mrd_len),
.tx_mrd_addr (tx_mrd_addr),
.tx_mrd_req_ack (tx_mrd_req_ack)
);
pcie_hcmd_sq_recv
pcie_hcmd_sq_recv_inst0
(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.pcie_sq_cmd_fifo_rd_en (w_pcie_sq_cmd_fifo_rd_en),
.pcie_sq_cmd_fifo_rd_data (w_pcie_sq_cmd_fifo_rd_data),
.pcie_sq_cmd_fifo_empty_n (w_pcie_sq_cmd_fifo_empty_n),
.pcie_sq_rx_fifo_rd_en (w_pcie_sq_rx_fifo_rd_en),
.pcie_sq_rx_fifo_rd_data (w_pcie_sq_rx_fifo_rd_data),
.pcie_sq_rx_fifo_free_en (w_pcie_sq_rx_fifo_free_en),
.pcie_sq_rx_fifo_free_len (w_pcie_sq_rx_fifo_free_len),
.pcie_sq_rx_fifo_empty_n (w_pcie_sq_rx_fifo_empty_n),
.hcmd_table_wr_en (hcmd_table_wr_en),
.hcmd_table_wr_addr (hcmd_table_wr_addr),
.hcmd_table_wr_data (hcmd_table_wr_data),
.hcmd_cid_wr_en (hcmd_cid_wr_en),
.hcmd_cid_wr_addr (hcmd_cid_wr_addr),
.hcmd_cid_wr_data (hcmd_cid_wr_data),
.hcmd_prp_wr_en (hcmd_prp_wr_en),
.hcmd_prp_wr_addr (hcmd_prp_wr_addr),
.hcmd_prp_wr_data (hcmd_prp_wr_data),
.hcmd_nlb_wr0_en (hcmd_nlb_wr0_en),
.hcmd_nlb_wr0_addr (hcmd_nlb_wr0_addr),
.hcmd_nlb_wr0_data (hcmd_nlb_wr0_data),
.hcmd_nlb_wr0_rdy_n (hcmd_nlb_wr0_rdy_n),
.hcmd_sq_wr_en (w_hcmd_sq_wr_en),
.hcmd_sq_wr_data (w_hcmd_sq_wr_data),
.hcmd_sq_full_n (w_hcmd_sq_full_n),
.sq_rst_n (sq_rst_n),
.admin_sq_size (admin_sq_size),
.io_sq1_size (io_sq1_size),
.io_sq2_size (io_sq2_size),
.io_sq3_size (io_sq3_size),
.io_sq4_size (io_sq4_size),
.io_sq5_size (io_sq5_size),
.io_sq6_size (io_sq6_size),
.io_sq7_size (io_sq7_size),
.io_sq8_size (io_sq8_size),
.admin_sq_head_ptr (admin_sq_head_ptr),
.io_sq1_head_ptr (io_sq1_head_ptr),
.io_sq2_head_ptr (io_sq2_head_ptr),
.io_sq3_head_ptr (io_sq3_head_ptr),
.io_sq4_head_ptr (io_sq4_head_ptr),
.io_sq5_head_ptr (io_sq5_head_ptr),
.io_sq6_head_ptr (io_sq6_head_ptr),
.io_sq7_head_ptr (io_sq7_head_ptr),
.io_sq8_head_ptr (io_sq8_head_ptr)
);
endmodule
|
/*
----------------------------------------------------------------------------------
Copyright (c) 2013-2014
Embedded and Network Computing Lab.
Open SSD Project
Hanyang University
All rights reserved.
----------------------------------------------------------------------------------
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. All advertising materials mentioning features or use of this source code
must display the following acknowledgement:
This product includes source code developed
by the Embedded and Network Computing Lab. and the Open SSD Project.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
----------------------------------------------------------------------------------
http://enclab.hanyang.ac.kr/
http://www.openssd-project.org/
http://www.hanyang.ac.kr/
----------------------------------------------------------------------------------
*/
`timescale 1ns / 1ps
module pcie_hcmd_sq # (
parameter C_PCIE_DATA_WIDTH = 128,
parameter C_PCIE_ADDR_WIDTH = 36
)
(
input pcie_user_clk,
input pcie_user_rst_n,
input [C_PCIE_ADDR_WIDTH-1:2] admin_sq_bs_addr,
input [7:0] admin_sq_size,
input [7:0] admin_sq_tail_ptr,
input [7:0] io_sq1_tail_ptr,
input [7:0] io_sq2_tail_ptr,
input [7:0] io_sq3_tail_ptr,
input [7:0] io_sq4_tail_ptr,
input [7:0] io_sq5_tail_ptr,
input [7:0] io_sq6_tail_ptr,
input [7:0] io_sq7_tail_ptr,
input [7:0] io_sq8_tail_ptr,
output [7:0] admin_sq_head_ptr,
output [7:0] io_sq1_head_ptr,
output [7:0] io_sq2_head_ptr,
output [7:0] io_sq3_head_ptr,
output [7:0] io_sq4_head_ptr,
output [7:0] io_sq5_head_ptr,
output [7:0] io_sq6_head_ptr,
output [7:0] io_sq7_head_ptr,
output [7:0] io_sq8_head_ptr,
input hcmd_slot_rdy,
input [6:0] hcmd_slot_tag,
output hcmd_slot_alloc_en,
input [7:0] cpld_sq_fifo_tag,
input [C_PCIE_DATA_WIDTH-1:0] cpld_sq_fifo_wr_data,
input cpld_sq_fifo_wr_en,
input cpld_sq_fifo_tag_last,
output tx_mrd_req,
output [7:0] tx_mrd_tag,
output [11:2] tx_mrd_len,
output [C_PCIE_ADDR_WIDTH-1:2] tx_mrd_addr,
input tx_mrd_req_ack,
output hcmd_table_wr_en,
output [8:0] hcmd_table_wr_addr,
output [C_PCIE_DATA_WIDTH-1:0] hcmd_table_wr_data,
output hcmd_cid_wr_en,
output [6:0] hcmd_cid_wr_addr,
output [19:0] hcmd_cid_wr_data,
output hcmd_prp_wr_en,
output [7:0] hcmd_prp_wr_addr,
output [44:0] hcmd_prp_wr_data,
output hcmd_nlb_wr0_en,
output [6:0] hcmd_nlb_wr0_addr,
output [18:0] hcmd_nlb_wr0_data,
input hcmd_nlb_wr0_rdy_n,
input cpu_bus_clk,
input cpu_bus_rst_n,
input [8:0] sq_rst_n,
input [8:0] sq_valid,
input [7:0] io_sq1_size,
input [7:0] io_sq2_size,
input [7:0] io_sq3_size,
input [7:0] io_sq4_size,
input [7:0] io_sq5_size,
input [7:0] io_sq6_size,
input [7:0] io_sq7_size,
input [7:0] io_sq8_size,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq1_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq2_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq3_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq4_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq5_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq6_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq7_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq8_bs_addr,
input hcmd_sq_rd_en,
output [18:0] hcmd_sq_rd_data,
output hcmd_sq_empty_n
);
wire w_arb_sq_rdy;
wire [3:0] w_sq_qid;
wire [C_PCIE_ADDR_WIDTH-1:2] w_hcmd_pcie_addr;
wire w_sq_hcmd_ack;
wire w_hcmd_sq_wr_en;
wire [18:0] w_hcmd_sq_wr_data;
wire w_hcmd_sq_full_n;
wire w_pcie_sq_cmd_fifo_wr_en;
wire [10:0] w_pcie_sq_cmd_fifo_wr_data;
wire w_pcie_sq_cmd_fifo_full_n;
wire w_pcie_sq_cmd_fifo_rd_en;
wire [10:0] w_pcie_sq_cmd_fifo_rd_data;
wire w_pcie_sq_cmd_fifo_empty_n;
wire w_pcie_sq_rx_tag_alloc;
wire [7:0] w_pcie_sq_rx_alloc_tag;
wire [6:4] w_pcie_sq_rx_tag_alloc_len;
wire w_pcie_sq_rx_tag_full_n;
wire w_pcie_sq_rx_fifo_wr_en;
wire [3:0] w_pcie_sq_rx_fifo_wr_addr;
wire [C_PCIE_DATA_WIDTH-1:0] w_pcie_sq_rx_fifo_wr_data;
wire [4:0] w_pcie_sq_rx_fifo_rear_full_addr;
wire [4:0] w_pcie_sq_rx_fifo_rear_addr;
wire w_pcie_sq_rx_fifo_full_n;
wire w_pcie_sq_rx_fifo_rd_en;
wire [C_PCIE_DATA_WIDTH-1:0] w_pcie_sq_rx_fifo_rd_data;
wire w_pcie_sq_rx_fifo_free_en;
wire [6:4] w_pcie_sq_rx_fifo_free_len;
wire w_pcie_sq_rx_fifo_empty_n;
pcie_hcmd_sq_fifo
pcie_hcmd_sq_fifo_inst0(
.wr_clk (pcie_user_clk),
.wr_rst_n (pcie_user_rst_n),
.wr_en (w_hcmd_sq_wr_en),
.wr_data (w_hcmd_sq_wr_data),
.full_n (w_hcmd_sq_full_n),
.rd_clk (cpu_bus_clk),
.rd_rst_n (pcie_user_rst_n),
.rd_en (hcmd_sq_rd_en),
.rd_data (hcmd_sq_rd_data),
.empty_n (hcmd_sq_empty_n)
);
pcie_sq_cmd_fifo
pcie_sq_cmd_fifo_inst0
(
.clk (pcie_user_clk),
.rst_n (pcie_user_rst_n),
.wr_en (w_pcie_sq_cmd_fifo_wr_en),
.wr_data (w_pcie_sq_cmd_fifo_wr_data),
.full_n (w_pcie_sq_cmd_fifo_full_n),
.rd_en (w_pcie_sq_cmd_fifo_rd_en),
.rd_data (w_pcie_sq_cmd_fifo_rd_data),
.empty_n (w_pcie_sq_cmd_fifo_empty_n)
);
pcie_sq_rx_fifo
pcie_sq_rx_fifo_inst0
(
.clk (pcie_user_clk),
.rst_n (pcie_user_rst_n),
.wr_en (w_pcie_sq_rx_fifo_wr_en),
.wr_addr (w_pcie_sq_rx_fifo_wr_addr),
.wr_data (w_pcie_sq_rx_fifo_wr_data),
.rear_full_addr (w_pcie_sq_rx_fifo_rear_full_addr),
.rear_addr (w_pcie_sq_rx_fifo_rear_addr),
.alloc_len (w_pcie_sq_rx_tag_alloc_len),
.full_n (w_pcie_sq_rx_fifo_full_n),
.rd_en (w_pcie_sq_rx_fifo_rd_en),
.rd_data (w_pcie_sq_rx_fifo_rd_data),
.free_en (w_pcie_sq_rx_fifo_free_en),
.free_len (w_pcie_sq_rx_fifo_free_len),
.empty_n (w_pcie_sq_rx_fifo_empty_n)
);
pcie_sq_rx_tag
pcie_sq_rx_tag_inst0
(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.pcie_tag_alloc (w_pcie_sq_rx_tag_alloc),
.pcie_alloc_tag (w_pcie_sq_rx_alloc_tag),
.pcie_tag_alloc_len (w_pcie_sq_rx_tag_alloc_len),
.pcie_tag_full_n (w_pcie_sq_rx_tag_full_n),
.cpld_fifo_tag (cpld_sq_fifo_tag),
.cpld_fifo_wr_data (cpld_sq_fifo_wr_data),
.cpld_fifo_wr_en (cpld_sq_fifo_wr_en),
.cpld_fifo_tag_last (cpld_sq_fifo_tag_last),
.fifo_wr_en (w_pcie_sq_rx_fifo_wr_en),
.fifo_wr_addr (w_pcie_sq_rx_fifo_wr_addr),
.fifo_wr_data (w_pcie_sq_rx_fifo_wr_data),
.rear_full_addr (w_pcie_sq_rx_fifo_rear_full_addr),
.rear_addr (w_pcie_sq_rx_fifo_rear_addr)
);
pcie_hcmd_sq_arb
pcie_hcmd_sq_arb_inst0
(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.sq_rst_n (sq_rst_n),
.sq_valid (sq_valid),
.admin_sq_size (admin_sq_size),
.io_sq1_size (io_sq1_size),
.io_sq2_size (io_sq2_size),
.io_sq3_size (io_sq3_size),
.io_sq4_size (io_sq4_size),
.io_sq5_size (io_sq5_size),
.io_sq6_size (io_sq6_size),
.io_sq7_size (io_sq7_size),
.io_sq8_size (io_sq8_size),
.admin_sq_bs_addr (admin_sq_bs_addr),
.io_sq1_bs_addr (io_sq1_bs_addr),
.io_sq2_bs_addr (io_sq2_bs_addr),
.io_sq3_bs_addr (io_sq3_bs_addr),
.io_sq4_bs_addr (io_sq4_bs_addr),
.io_sq5_bs_addr (io_sq5_bs_addr),
.io_sq6_bs_addr (io_sq6_bs_addr),
.io_sq7_bs_addr (io_sq7_bs_addr),
.io_sq8_bs_addr (io_sq8_bs_addr),
.admin_sq_tail_ptr (admin_sq_tail_ptr),
.io_sq1_tail_ptr (io_sq1_tail_ptr),
.io_sq2_tail_ptr (io_sq2_tail_ptr),
.io_sq3_tail_ptr (io_sq3_tail_ptr),
.io_sq4_tail_ptr (io_sq4_tail_ptr),
.io_sq5_tail_ptr (io_sq5_tail_ptr),
.io_sq6_tail_ptr (io_sq6_tail_ptr),
.io_sq7_tail_ptr (io_sq7_tail_ptr),
.io_sq8_tail_ptr (io_sq8_tail_ptr),
.arb_sq_rdy (w_arb_sq_rdy),
.sq_qid (w_sq_qid),
.hcmd_pcie_addr (w_hcmd_pcie_addr),
.sq_hcmd_ack (w_sq_hcmd_ack)
);
pcie_hcmd_sq_req # (
.C_PCIE_DATA_WIDTH (C_PCIE_DATA_WIDTH)
)
pcie_hcmd_sq_req_inst0(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.arb_sq_rdy (w_arb_sq_rdy),
.sq_qid (w_sq_qid),
.hcmd_pcie_addr (w_hcmd_pcie_addr),
.sq_hcmd_ack (w_sq_hcmd_ack),
.hcmd_slot_rdy (hcmd_slot_rdy),
.hcmd_slot_tag (hcmd_slot_tag),
.hcmd_slot_alloc_en (hcmd_slot_alloc_en),
.pcie_sq_cmd_fifo_wr_en (w_pcie_sq_cmd_fifo_wr_en),
.pcie_sq_cmd_fifo_wr_data (w_pcie_sq_cmd_fifo_wr_data),
.pcie_sq_cmd_fifo_full_n (w_pcie_sq_cmd_fifo_full_n),
.pcie_sq_rx_tag_alloc (w_pcie_sq_rx_tag_alloc),
.pcie_sq_rx_alloc_tag (w_pcie_sq_rx_alloc_tag),
.pcie_sq_rx_tag_alloc_len (w_pcie_sq_rx_tag_alloc_len),
.pcie_sq_rx_tag_full_n (w_pcie_sq_rx_tag_full_n),
.pcie_sq_rx_fifo_full_n (w_pcie_sq_rx_fifo_full_n),
.tx_mrd_req (tx_mrd_req),
.tx_mrd_tag (tx_mrd_tag),
.tx_mrd_len (tx_mrd_len),
.tx_mrd_addr (tx_mrd_addr),
.tx_mrd_req_ack (tx_mrd_req_ack)
);
pcie_hcmd_sq_recv
pcie_hcmd_sq_recv_inst0
(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.pcie_sq_cmd_fifo_rd_en (w_pcie_sq_cmd_fifo_rd_en),
.pcie_sq_cmd_fifo_rd_data (w_pcie_sq_cmd_fifo_rd_data),
.pcie_sq_cmd_fifo_empty_n (w_pcie_sq_cmd_fifo_empty_n),
.pcie_sq_rx_fifo_rd_en (w_pcie_sq_rx_fifo_rd_en),
.pcie_sq_rx_fifo_rd_data (w_pcie_sq_rx_fifo_rd_data),
.pcie_sq_rx_fifo_free_en (w_pcie_sq_rx_fifo_free_en),
.pcie_sq_rx_fifo_free_len (w_pcie_sq_rx_fifo_free_len),
.pcie_sq_rx_fifo_empty_n (w_pcie_sq_rx_fifo_empty_n),
.hcmd_table_wr_en (hcmd_table_wr_en),
.hcmd_table_wr_addr (hcmd_table_wr_addr),
.hcmd_table_wr_data (hcmd_table_wr_data),
.hcmd_cid_wr_en (hcmd_cid_wr_en),
.hcmd_cid_wr_addr (hcmd_cid_wr_addr),
.hcmd_cid_wr_data (hcmd_cid_wr_data),
.hcmd_prp_wr_en (hcmd_prp_wr_en),
.hcmd_prp_wr_addr (hcmd_prp_wr_addr),
.hcmd_prp_wr_data (hcmd_prp_wr_data),
.hcmd_nlb_wr0_en (hcmd_nlb_wr0_en),
.hcmd_nlb_wr0_addr (hcmd_nlb_wr0_addr),
.hcmd_nlb_wr0_data (hcmd_nlb_wr0_data),
.hcmd_nlb_wr0_rdy_n (hcmd_nlb_wr0_rdy_n),
.hcmd_sq_wr_en (w_hcmd_sq_wr_en),
.hcmd_sq_wr_data (w_hcmd_sq_wr_data),
.hcmd_sq_full_n (w_hcmd_sq_full_n),
.sq_rst_n (sq_rst_n),
.admin_sq_size (admin_sq_size),
.io_sq1_size (io_sq1_size),
.io_sq2_size (io_sq2_size),
.io_sq3_size (io_sq3_size),
.io_sq4_size (io_sq4_size),
.io_sq5_size (io_sq5_size),
.io_sq6_size (io_sq6_size),
.io_sq7_size (io_sq7_size),
.io_sq8_size (io_sq8_size),
.admin_sq_head_ptr (admin_sq_head_ptr),
.io_sq1_head_ptr (io_sq1_head_ptr),
.io_sq2_head_ptr (io_sq2_head_ptr),
.io_sq3_head_ptr (io_sq3_head_ptr),
.io_sq4_head_ptr (io_sq4_head_ptr),
.io_sq5_head_ptr (io_sq5_head_ptr),
.io_sq6_head_ptr (io_sq6_head_ptr),
.io_sq7_head_ptr (io_sq7_head_ptr),
.io_sq8_head_ptr (io_sq8_head_ptr)
);
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2003 by Wilson Snyder.
module t (clk);
input clk;
reg [7:0] a,b;
wire [7:0] z;
mytop u0 ( a, b, clk, z );
integer cyc; initial cyc=1;
always @ (posedge clk) begin
if (cyc!=0) begin
cyc <= cyc + 1;
//$write("%d %x\n", cyc, z);
if (cyc==1) begin
a <= 8'h07;
b <= 8'h20;
end
if (cyc==2) begin
a <= 8'h8a;
b <= 8'h12;
end
if (cyc==3) begin
if (z !== 8'hdf) $stop;
a <= 8'h71;
b <= 8'hb2;
end
if (cyc==4) begin
if (z !== 8'hed) $stop;
end
if (cyc==5) begin
if (z !== 8'h4d) $stop;
end
if (cyc==9) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
end
endmodule // mytop
module inv(
input [ 7:0 ] a,
output [ 7:0 ] z
);
wire [7:0] z = ~a;
endmodule
module ftest(
input [ 7:0 ] a,
b, // Test legal syntax
input clk,
output [ 7:0 ] z
);
wire [7:0] zi;
reg [7:0] z;
inv u1 (.a(myadd(a,b)),
.z(zi));
always @ ( posedge clk ) begin
z <= myadd( a, zi );
end
function [ 7:0 ] myadd;
input [7:0] ina;
input [7:0] inb;
begin
myadd = ina + inb;
end
endfunction // myadd
endmodule // ftest
module mytop (
input [ 7:0 ] a,
b,
input clk,
output [ 7:0 ] z
);
ftest u0( a, b, clk, z );
endmodule // mytop
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2003 by Wilson Snyder.
module t (clk);
input clk;
reg [7:0] a,b;
wire [7:0] z;
mytop u0 ( a, b, clk, z );
integer cyc; initial cyc=1;
always @ (posedge clk) begin
if (cyc!=0) begin
cyc <= cyc + 1;
//$write("%d %x\n", cyc, z);
if (cyc==1) begin
a <= 8'h07;
b <= 8'h20;
end
if (cyc==2) begin
a <= 8'h8a;
b <= 8'h12;
end
if (cyc==3) begin
if (z !== 8'hdf) $stop;
a <= 8'h71;
b <= 8'hb2;
end
if (cyc==4) begin
if (z !== 8'hed) $stop;
end
if (cyc==5) begin
if (z !== 8'h4d) $stop;
end
if (cyc==9) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
end
endmodule // mytop
module inv(
input [ 7:0 ] a,
output [ 7:0 ] z
);
wire [7:0] z = ~a;
endmodule
module ftest(
input [ 7:0 ] a,
b, // Test legal syntax
input clk,
output [ 7:0 ] z
);
wire [7:0] zi;
reg [7:0] z;
inv u1 (.a(myadd(a,b)),
.z(zi));
always @ ( posedge clk ) begin
z <= myadd( a, zi );
end
function [ 7:0 ] myadd;
input [7:0] ina;
input [7:0] inb;
begin
myadd = ina + inb;
end
endfunction // myadd
endmodule // ftest
module mytop (
input [ 7:0 ] a,
b,
input clk,
output [ 7:0 ] z
);
ftest u0( a, b, clk, z );
endmodule // mytop
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2008 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
integer cyc=0;
reg [63:0] crc;
reg [63:0] sum;
/*AUTOWIRE*/
// Beginning of automatic wires (for undeclared instantiated-module outputs)
wire [2:0] q; // From test of Test.v
// End of automatics
Test test (
// Outputs
.q (q[2:0]),
// Inputs
.clk (clk),
.reset_l (crc[0]),
.enable (crc[2]),
.q_var0 (crc[19:10]),
.q_var2 (crc[29:20]),
.q_var4 (crc[39:30]),
.q_var6 (crc[49:40])
/*AUTOINST*/);
// Aggregate outputs into a single result vector
wire [63:0] result = {61'h0,q};
// Test loop
always @ (posedge clk) begin
`ifdef TEST_VERBOSE
$write("[%0t] cyc==%0d crc=%x result=%x\n",$time, cyc, crc, result);
`endif
cyc <= cyc + 1;
crc <= {crc[62:0], crc[63]^crc[2]^crc[0]};
sum <= result ^ {sum[62:0],sum[63]^sum[2]^sum[0]};
if (cyc==0) begin
// Setup
crc <= 64'h5aef0c8d_d70a4497;
end
else if (cyc<10) begin
sum <= 64'h0;
end
else if (cyc<90) begin
end
else if (cyc==99) begin
$write("[%0t] cyc==%0d crc=%x sum=%x\n",$time, cyc, crc, sum);
if (crc !== 64'hc77bb9b3784ea091) $stop;
`define EXPECTED_SUM 64'h58b162c58d6e35ba
if (sum !== `EXPECTED_SUM) $stop;
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
module Test
(
input clk,
input reset_l,
input enable,
input [ 9:0] q_var0,
input [ 9:0] q_var2,
input [ 9:0] q_var4,
input [ 9:0] q_var6,
output reg [2:0] q
);
reg [7:0] p1_r [6:0];
always @(posedge clk) begin
if (!reset_l) begin
p1_r[0] <= 'b0;
p1_r[1] <= 'b0;
p1_r[2] <= 'b0;
p1_r[3] <= 'b0;
p1_r[4] <= 'b0;
p1_r[5] <= 'b0;
p1_r[6] <= 'b0;
end
else if (enable) begin : pass1
match(q_var0, q_var2, q_var4, q_var6);
end
end
// verilator lint_off WIDTH
always @(posedge clk) begin : l
reg [10:0] bd;
reg [3:0] idx;
q = 0;
bd = 0;
for (idx=0; idx<7; idx=idx+1) begin
q = idx+1;
bd = bd + p1_r[idx];
end
end
task match;
input [9:0] p0, p1, p2, p3;
reg [9:0] p[3:0];
begin
p[0] = p0;
p[1] = p1;
p[2] = p2;
p[3] = p3;
p1_r[0] = p[0];
p1_r[1] = p[1];
end
endtask
endmodule
|
//------------------------------------------------------------------------------
// This confidential and proprietary software may be used only as authorized by
// a licensing agreement from Altera Corporation.
//
// Legal Notice: (C)2010 Altera Corporation. All rights reserved. Your
// use of Altera Corporation's design tools, logic functions and other
// software and tools, and its AMPP partner logic functions, and any
// output files any of the foregoing (including device programming or
// simulation files), and any associated documentation or information are
// expressly subject to the terms and conditions of the Altera Program
// License Subscription Agreement or other applicable license agreement,
// including, without limitation, that your use is for the sole purpose
// of programming logic devices manufactured by Altera and sold by Altera
// or its authorized distributors. Please refer to the applicable
// agreement for further details.
//
// The entire notice above must be reproduced on all authorized copies and any
// such reproduction must be pursuant to a licensing agreement from Altera.
//
// Title : Example top level testbench for ddr3_int DDR/2/3 SDRAM High Performance Controller
// Project : DDR/2/3 SDRAM High Performance Controller
//
// File : ddr3_int_example_top_tb.v
//
// Revision : V10.0
//
// Abstract:
// Automatically generated testbench for the example top level design to allow
// functional and timing simulation.
//
//------------------------------------------------------------------------------
//
// *************** This is a MegaWizard generated file ****************
//
// If you need to edit this file make sure the edits are not inside any 'MEGAWIZARD'
// text insertion areas.
// (between "<< START MEGAWIZARD INSERT" and "<< END MEGAWIZARD INSERT" comments)
//
// Any edits inside these delimiters will be overwritten by the megawizard if you
// re-run it.
//
// If you really need to make changes inside these delimiters then delete
// both 'START' and 'END' delimiters. This will stop the megawizard updating this
// section again.
//
//----------------------------------------------------------------------------------
// << START MEGAWIZARD INSERT PARAMETER_LIST
// Parameters:
//
// Device Family : arria ii gx
// local Interface Data Width : 128
// MEM_CHIPSELS : 1
// MEM_CS_PER_RANK : 1
// MEM_BANK_BITS : 3
// MEM_ROW_BITS : 13
// MEM_COL_BITS : 10
// LOCAL_DATA_BITS : 128
// NUM_CLOCK_PAIRS : 1
// CLOCK_TICK_IN_PS : 3333
// REGISTERED_DIMM : false
// TINIT_CLOCKS : 75008
// Data_Width_Ratio : 4
// << END MEGAWIZARD INSERT PARAMETER_LIST
//----------------------------------------------------------------------------------
// << MEGAWIZARD PARSE FILE DDR10.0
`timescale 1 ps/1 ps
// << START MEGAWIZARD INSERT MODULE
module ddr3_int_example_top_tb ();
// << END MEGAWIZARD INSERT MODULE
// << START MEGAWIZARD INSERT PARAMS
parameter gMEM_CHIPSELS = 1;
parameter gMEM_CS_PER_RANK = 1;
parameter gMEM_NUM_RANKS = 1 / 1;
parameter gMEM_BANK_BITS = 3;
parameter gMEM_ROW_BITS = 13;
parameter gMEM_COL_BITS = 10;
parameter gMEM_ADDR_BITS = 13;
parameter gMEM_DQ_PER_DQS = 8;
parameter DM_DQS_WIDTH = 4;
parameter gLOCAL_DATA_BITS = 128;
parameter gLOCAL_IF_DWIDTH_AFTER_ECC = 128;
parameter gNUM_CLOCK_PAIRS = 1;
parameter RTL_ROUNDTRIP_CLOCKS = 0.0;
parameter CLOCK_TICK_IN_PS = 3333;
parameter REGISTERED_DIMM = 1'b0;
parameter BOARD_DQS_DELAY = 0;
parameter BOARD_CLK_DELAY = 0;
parameter DWIDTH_RATIO = 4;
parameter TINIT_CLOCKS = 75008;
parameter REF_CLOCK_TICK_IN_PS = 40000;
// Parameters below are for generic memory model
parameter gMEM_TQHS_PS = 300;
parameter gMEM_TAC_PS = 400;
parameter gMEM_TDQSQ_PS = 125;
parameter gMEM_IF_TRCD_NS = 13.5;
parameter gMEM_IF_TWTR_CK = 4;
parameter gMEM_TDSS_CK = 0.2;
parameter gMEM_IF_TRFC_NS = 110.0;
parameter gMEM_IF_TRP_NS = 13.5;
parameter gMEM_IF_TRCD_PS = gMEM_IF_TRCD_NS * 1000.0;
parameter gMEM_IF_TWTR_PS = gMEM_IF_TWTR_CK * CLOCK_TICK_IN_PS;
parameter gMEM_IF_TRFC_PS = gMEM_IF_TRFC_NS * 1000.0;
parameter gMEM_IF_TRP_PS = gMEM_IF_TRP_NS * 1000.0;
parameter CLOCK_TICK_IN_NS = CLOCK_TICK_IN_PS / 1000.0;
parameter gMEM_TDQSQ_NS = gMEM_TDQSQ_PS / 1000.0;
parameter gMEM_TDSS_NS = gMEM_TDSS_CK * CLOCK_TICK_IN_NS;
// << END MEGAWIZARD INSERT PARAMS
// set to zero for Gatelevel
parameter RTL_DELAYS = 1;
parameter USE_GENERIC_MEMORY_MODEL = 1'b0;
// The round trip delay is now modeled inside the datapath (<your core name>_auk_ddr_dqs_group.v/vhd) for RTL simulation.
parameter D90_DEG_DELAY = 0; //RTL only
parameter GATE_BOARD_DQS_DELAY = BOARD_DQS_DELAY * (RTL_DELAYS ? 0 : 1); // Gate level timing only
parameter GATE_BOARD_CLK_DELAY = BOARD_CLK_DELAY * (RTL_DELAYS ? 0 : 1); // Gate level timing only
// Below 5 lines for SPR272543:
// Testbench workaround for tests with "dedicated memory clock phase shift" failing,
// because dqs delay isnt' being modelled in simulations
parameter gMEM_CLK_PHASE_EN = "false";
parameter real gMEM_CLK_PHASE = 0;
parameter real MEM_CLK_RATIO = ((360.0-gMEM_CLK_PHASE)/360.0);
parameter MEM_CLK_DELAY = MEM_CLK_RATIO*CLOCK_TICK_IN_PS * ((gMEM_CLK_PHASE_EN=="true") ? 1 : 0);
wire clk_to_ram0, clk_to_ram1, clk_to_ram2;
wire cmd_bus_watcher_enabled;
reg clk;
reg clk_n;
reg reset_n;
wire mem_reset_n;
wire[gMEM_ADDR_BITS - 1:0] a;
wire[gMEM_BANK_BITS - 1:0] ba;
wire[gMEM_CHIPSELS - 1:0] cs_n;
wire[gMEM_NUM_RANKS - 1:0] cke;
wire[gMEM_NUM_RANKS - 1:0] odt; //DDR2 only
wire ras_n;
wire cas_n;
wire we_n;
wire[gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] dm;
//wire[gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] dqs;
//wire[gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] dqs_n;
//wire stratix_dqs_ref_clk; // only used on stratix to provide external dll reference clock
wire[gNUM_CLOCK_PAIRS - 1:0] clk_to_sdram;
wire[gNUM_CLOCK_PAIRS - 1:0] clk_to_sdram_n;
wire #(GATE_BOARD_CLK_DELAY * 1) clk_to_ram;
wire clk_to_ram_n;
wire[gMEM_ROW_BITS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) a_delayed;
wire[gMEM_BANK_BITS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) ba_delayed;
wire[gMEM_NUM_RANKS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) cke_delayed;
wire[gMEM_NUM_RANKS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) odt_delayed; //DDR2 only
wire[gMEM_NUM_RANKS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) cs_n_delayed;
wire #(GATE_BOARD_CLK_DELAY * 1 + 1) ras_n_delayed;
wire #(GATE_BOARD_CLK_DELAY * 1 + 1) cas_n_delayed;
wire #(GATE_BOARD_CLK_DELAY * 1 + 1) we_n_delayed;
wire[gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] dm_delayed;
// DDR3 parity only
wire ac_parity;
wire mem_err_out_n;
assign mem_err_out_n = 1'b1;
// pulldown (dm);
assign (weak1, weak0) dm = 0;
tri [gLOCAL_DATA_BITS / DWIDTH_RATIO - 1:0] mem_dq = 100'bz;
tri [gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] mem_dqs = 100'bz;
tri [gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] mem_dqs_n = 100'bz;
assign (weak1, weak0) mem_dq = 0;
assign (weak1, weak0) mem_dqs = 0;
assign (weak1, weak0) mem_dqs_n = 1;
wire [gMEM_BANK_BITS - 1:0] zero_one; //"01";
assign zero_one = 1;
wire test_complete;
wire [7:0] test_status;
// counter to count the number of sucessful read and write loops
integer test_complete_count;
wire pnf;
wire [gLOCAL_IF_DWIDTH_AFTER_ECC / 8 - 1:0] pnf_per_byte;
assign cmd_bus_watcher_enabled = 1'b0;
// Below 5 lines for SPR272543:
// Testbench workaround for tests with "dedicated memory clock phase shift" failing,
// because dqs delay isnt' being modelled in simulations
assign #(MEM_CLK_DELAY/4.0) clk_to_ram2 = clk_to_sdram[0];
assign #(MEM_CLK_DELAY/4.0) clk_to_ram1 = clk_to_ram2;
assign #(MEM_CLK_DELAY/4.0) clk_to_ram0 = clk_to_ram1;
assign #((MEM_CLK_DELAY/4.0)) clk_to_ram = clk_to_ram0;
assign clk_to_ram_n = ~clk_to_ram ; // mem model ignores clk_n ?
// ddr sdram interface
// << START MEGAWIZARD INSERT ENTITY
ddr3_int_example_top dut (
// << END MEGAWIZARD INSERT ENTITY
.clock_source(clk),
.global_reset_n(reset_n),
// << START MEGAWIZARD INSERT PORT_MAP
.mem_clk(clk_to_sdram),
.mem_clk_n(clk_to_sdram_n),
.mem_odt(odt),
.mem_dqsn(mem_dqs_n),
.mem_reset_n(mem_reset_n),
.mem_cke(cke),
.mem_cs_n(cs_n),
.mem_ras_n(ras_n),
.mem_cas_n(cas_n),
.mem_we_n(we_n),
.mem_ba(ba),
.mem_addr(a),
.mem_dq(mem_dq),
.mem_dqs(mem_dqs),
.mem_dm(dm),
// << END MEGAWIZARD INSERT PORT_MAP
.test_complete(test_complete),
.test_status(test_status),
.pnf_per_byte(pnf_per_byte),
.pnf(pnf)
);
// << START MEGAWIZARD INSERT MEMORY_ARRAY
// This will need updating to match the memory models you are using.
// Instantiate a generated DDR memory model to match the datawidth & chipselect requirements
ddr3_int_mem_model mem (
.mem_rst_n (mem_reset_n),
.mem_dq (mem_dq),
.mem_dqs (mem_dqs),
.mem_dqs_n (mem_dqs_n),
.mem_addr (a_delayed),
.mem_ba (ba_delayed),
.mem_clk (clk_to_ram),
.mem_clk_n (clk_to_ram_n),
.mem_cke (cke_delayed),
.mem_cs_n (cs_n_delayed),
.mem_ras_n (ras_n_delayed),
.mem_cas_n (cas_n_delayed),
.mem_we_n (we_n_delayed),
.mem_dm (dm_delayed),
.mem_odt (odt_delayed)
);
// << END MEGAWIZARD INSERT MEMORY_ARRAY
always
begin
clk <= 1'b0 ;
clk_n <= 1'b1 ;
while (1'b1)
begin
#((REF_CLOCK_TICK_IN_PS / 2) * 1);
clk <= ~clk ;
clk_n <= ~clk_n ;
end
end
initial
begin
reset_n <= 1'b0 ;
@(clk);
@(clk);
@(clk);
@(clk);
@(clk);
@(clk);
reset_n <= 1'b1 ;
end
// control and data lines = 3 inches
assign a_delayed = a[gMEM_ROW_BITS - 1:0] ;
assign ba_delayed = ba ;
assign cke_delayed = cke ;
assign odt_delayed = odt ;
assign cs_n_delayed = cs_n ;
assign ras_n_delayed = ras_n ;
assign cas_n_delayed = cas_n ;
assign we_n_delayed = we_n ;
assign dm_delayed = dm ;
// ---------------------------------------------------------------
initial
begin : endit
integer count;
reg ln;
count = 0;
// Stop simulation after test_complete or TINIT + 600000 clocks
while ((count < (TINIT_CLOCKS + 600000)) & (test_complete !== 1))
begin
count = count + 1;
@(negedge clk_to_sdram[0]);
end
if (test_complete === 1)
begin
if (pnf)
begin
$write($time);
$write(" --- SIMULATION PASSED --- ");
$stop;
end
else
begin
$write($time);
$write(" --- SIMULATION FAILED --- ");
$stop;
end
end
else
begin
$write($time);
$write(" --- SIMULATION FAILED, DID NOT COMPLETE --- ");
$stop;
end
end
always @(clk_to_sdram[0] or reset_n)
begin
if (!reset_n)
begin
test_complete_count <= 0 ;
end
else if ((clk_to_sdram[0]))
begin
if (test_complete)
begin
test_complete_count <= test_complete_count + 1 ;
end
end
end
reg[2:0] cmd_bus;
//***********************************************************
// Watch the SDRAM command bus
always @(clk_to_ram)
begin
if (clk_to_ram)
begin
if (1'b1)
begin
cmd_bus = {ras_n_delayed, cas_n_delayed, we_n_delayed};
case (cmd_bus)
3'b000 :
begin
// LMR command
$write($time);
if (ba_delayed == zero_one)
begin
$write(" ELMR settings = ");
if (!(a_delayed[0]))
begin
$write("DLL enable");
end
end
else
begin
$write(" LMR settings = ");
case (a_delayed[1:0])
3'b00 : $write("BL = 8,");
3'b01 : $write("BL = On The Fly,");
3'b10 : $write("BL = 4,");
default : $write("BL = ??,");
endcase
case (a_delayed[6:4])
3'b001 : $write(" CL = 5.0,");
3'b010 : $write(" CL = 6.0,");
3'b011 : $write(" CL = 7.0,");
3'b100 : $write(" CL = 8.0,");
3'b101 : $write(" CL = 9.0,");
3'b110 : $write(" CL = 10.0,");
default : $write(" CL = ??,");
endcase
if ((a_delayed[8])) $write(" DLL reset");
end
$write("\n");
end
3'b001 :
begin
// ARF command
$write($time);
$write(" ARF\n");
end
3'b010 :
begin
// PCH command
$write($time);
$write(" PCH");
if ((a_delayed[10]))
begin
$write(" all banks \n");
end
else
begin
$write(" bank ");
$write("%H\n", ba_delayed);
end
end
3'b011 :
begin
// ACT command
$write($time);
$write(" ACT row address ");
$write("%H", a_delayed);
$write(" bank ");
$write("%H\n", ba_delayed);
end
3'b100 :
begin
// WR command
$write($time);
$write(" WR to col address ");
$write("%H", a_delayed);
$write(" bank ");
$write("%H\n", ba_delayed);
end
3'b101 :
begin
// RD command
$write($time);
$write(" RD from col address ");
$write("%H", a_delayed);
$write(" bank ");
$write("%H\n", ba_delayed);
end
3'b110 :
begin
// BT command
$write($time);
$write(" BT ");
end
3'b111 :
begin
// NOP command
end
endcase
end
else
begin
end // if enabled
end
end
endmodule
|
//------------------------------------------------------------------------------
// This confidential and proprietary software may be used only as authorized by
// a licensing agreement from Altera Corporation.
//
// Legal Notice: (C)2010 Altera Corporation. All rights reserved. Your
// use of Altera Corporation's design tools, logic functions and other
// software and tools, and its AMPP partner logic functions, and any
// output files any of the foregoing (including device programming or
// simulation files), and any associated documentation or information are
// expressly subject to the terms and conditions of the Altera Program
// License Subscription Agreement or other applicable license agreement,
// including, without limitation, that your use is for the sole purpose
// of programming logic devices manufactured by Altera and sold by Altera
// or its authorized distributors. Please refer to the applicable
// agreement for further details.
//
// The entire notice above must be reproduced on all authorized copies and any
// such reproduction must be pursuant to a licensing agreement from Altera.
//
// Title : Example top level testbench for ddr3_int DDR/2/3 SDRAM High Performance Controller
// Project : DDR/2/3 SDRAM High Performance Controller
//
// File : ddr3_int_example_top_tb.v
//
// Revision : V10.0
//
// Abstract:
// Automatically generated testbench for the example top level design to allow
// functional and timing simulation.
//
//------------------------------------------------------------------------------
//
// *************** This is a MegaWizard generated file ****************
//
// If you need to edit this file make sure the edits are not inside any 'MEGAWIZARD'
// text insertion areas.
// (between "<< START MEGAWIZARD INSERT" and "<< END MEGAWIZARD INSERT" comments)
//
// Any edits inside these delimiters will be overwritten by the megawizard if you
// re-run it.
//
// If you really need to make changes inside these delimiters then delete
// both 'START' and 'END' delimiters. This will stop the megawizard updating this
// section again.
//
//----------------------------------------------------------------------------------
// << START MEGAWIZARD INSERT PARAMETER_LIST
// Parameters:
//
// Device Family : arria ii gx
// local Interface Data Width : 128
// MEM_CHIPSELS : 1
// MEM_CS_PER_RANK : 1
// MEM_BANK_BITS : 3
// MEM_ROW_BITS : 13
// MEM_COL_BITS : 10
// LOCAL_DATA_BITS : 128
// NUM_CLOCK_PAIRS : 1
// CLOCK_TICK_IN_PS : 3333
// REGISTERED_DIMM : false
// TINIT_CLOCKS : 75008
// Data_Width_Ratio : 4
// << END MEGAWIZARD INSERT PARAMETER_LIST
//----------------------------------------------------------------------------------
// << MEGAWIZARD PARSE FILE DDR10.0
`timescale 1 ps/1 ps
// << START MEGAWIZARD INSERT MODULE
module ddr3_int_example_top_tb ();
// << END MEGAWIZARD INSERT MODULE
// << START MEGAWIZARD INSERT PARAMS
parameter gMEM_CHIPSELS = 1;
parameter gMEM_CS_PER_RANK = 1;
parameter gMEM_NUM_RANKS = 1 / 1;
parameter gMEM_BANK_BITS = 3;
parameter gMEM_ROW_BITS = 13;
parameter gMEM_COL_BITS = 10;
parameter gMEM_ADDR_BITS = 13;
parameter gMEM_DQ_PER_DQS = 8;
parameter DM_DQS_WIDTH = 4;
parameter gLOCAL_DATA_BITS = 128;
parameter gLOCAL_IF_DWIDTH_AFTER_ECC = 128;
parameter gNUM_CLOCK_PAIRS = 1;
parameter RTL_ROUNDTRIP_CLOCKS = 0.0;
parameter CLOCK_TICK_IN_PS = 3333;
parameter REGISTERED_DIMM = 1'b0;
parameter BOARD_DQS_DELAY = 0;
parameter BOARD_CLK_DELAY = 0;
parameter DWIDTH_RATIO = 4;
parameter TINIT_CLOCKS = 75008;
parameter REF_CLOCK_TICK_IN_PS = 40000;
// Parameters below are for generic memory model
parameter gMEM_TQHS_PS = 300;
parameter gMEM_TAC_PS = 400;
parameter gMEM_TDQSQ_PS = 125;
parameter gMEM_IF_TRCD_NS = 13.5;
parameter gMEM_IF_TWTR_CK = 4;
parameter gMEM_TDSS_CK = 0.2;
parameter gMEM_IF_TRFC_NS = 110.0;
parameter gMEM_IF_TRP_NS = 13.5;
parameter gMEM_IF_TRCD_PS = gMEM_IF_TRCD_NS * 1000.0;
parameter gMEM_IF_TWTR_PS = gMEM_IF_TWTR_CK * CLOCK_TICK_IN_PS;
parameter gMEM_IF_TRFC_PS = gMEM_IF_TRFC_NS * 1000.0;
parameter gMEM_IF_TRP_PS = gMEM_IF_TRP_NS * 1000.0;
parameter CLOCK_TICK_IN_NS = CLOCK_TICK_IN_PS / 1000.0;
parameter gMEM_TDQSQ_NS = gMEM_TDQSQ_PS / 1000.0;
parameter gMEM_TDSS_NS = gMEM_TDSS_CK * CLOCK_TICK_IN_NS;
// << END MEGAWIZARD INSERT PARAMS
// set to zero for Gatelevel
parameter RTL_DELAYS = 1;
parameter USE_GENERIC_MEMORY_MODEL = 1'b0;
// The round trip delay is now modeled inside the datapath (<your core name>_auk_ddr_dqs_group.v/vhd) for RTL simulation.
parameter D90_DEG_DELAY = 0; //RTL only
parameter GATE_BOARD_DQS_DELAY = BOARD_DQS_DELAY * (RTL_DELAYS ? 0 : 1); // Gate level timing only
parameter GATE_BOARD_CLK_DELAY = BOARD_CLK_DELAY * (RTL_DELAYS ? 0 : 1); // Gate level timing only
// Below 5 lines for SPR272543:
// Testbench workaround for tests with "dedicated memory clock phase shift" failing,
// because dqs delay isnt' being modelled in simulations
parameter gMEM_CLK_PHASE_EN = "false";
parameter real gMEM_CLK_PHASE = 0;
parameter real MEM_CLK_RATIO = ((360.0-gMEM_CLK_PHASE)/360.0);
parameter MEM_CLK_DELAY = MEM_CLK_RATIO*CLOCK_TICK_IN_PS * ((gMEM_CLK_PHASE_EN=="true") ? 1 : 0);
wire clk_to_ram0, clk_to_ram1, clk_to_ram2;
wire cmd_bus_watcher_enabled;
reg clk;
reg clk_n;
reg reset_n;
wire mem_reset_n;
wire[gMEM_ADDR_BITS - 1:0] a;
wire[gMEM_BANK_BITS - 1:0] ba;
wire[gMEM_CHIPSELS - 1:0] cs_n;
wire[gMEM_NUM_RANKS - 1:0] cke;
wire[gMEM_NUM_RANKS - 1:0] odt; //DDR2 only
wire ras_n;
wire cas_n;
wire we_n;
wire[gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] dm;
//wire[gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] dqs;
//wire[gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] dqs_n;
//wire stratix_dqs_ref_clk; // only used on stratix to provide external dll reference clock
wire[gNUM_CLOCK_PAIRS - 1:0] clk_to_sdram;
wire[gNUM_CLOCK_PAIRS - 1:0] clk_to_sdram_n;
wire #(GATE_BOARD_CLK_DELAY * 1) clk_to_ram;
wire clk_to_ram_n;
wire[gMEM_ROW_BITS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) a_delayed;
wire[gMEM_BANK_BITS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) ba_delayed;
wire[gMEM_NUM_RANKS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) cke_delayed;
wire[gMEM_NUM_RANKS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) odt_delayed; //DDR2 only
wire[gMEM_NUM_RANKS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) cs_n_delayed;
wire #(GATE_BOARD_CLK_DELAY * 1 + 1) ras_n_delayed;
wire #(GATE_BOARD_CLK_DELAY * 1 + 1) cas_n_delayed;
wire #(GATE_BOARD_CLK_DELAY * 1 + 1) we_n_delayed;
wire[gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] dm_delayed;
// DDR3 parity only
wire ac_parity;
wire mem_err_out_n;
assign mem_err_out_n = 1'b1;
// pulldown (dm);
assign (weak1, weak0) dm = 0;
tri [gLOCAL_DATA_BITS / DWIDTH_RATIO - 1:0] mem_dq = 100'bz;
tri [gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] mem_dqs = 100'bz;
tri [gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] mem_dqs_n = 100'bz;
assign (weak1, weak0) mem_dq = 0;
assign (weak1, weak0) mem_dqs = 0;
assign (weak1, weak0) mem_dqs_n = 1;
wire [gMEM_BANK_BITS - 1:0] zero_one; //"01";
assign zero_one = 1;
wire test_complete;
wire [7:0] test_status;
// counter to count the number of sucessful read and write loops
integer test_complete_count;
wire pnf;
wire [gLOCAL_IF_DWIDTH_AFTER_ECC / 8 - 1:0] pnf_per_byte;
assign cmd_bus_watcher_enabled = 1'b0;
// Below 5 lines for SPR272543:
// Testbench workaround for tests with "dedicated memory clock phase shift" failing,
// because dqs delay isnt' being modelled in simulations
assign #(MEM_CLK_DELAY/4.0) clk_to_ram2 = clk_to_sdram[0];
assign #(MEM_CLK_DELAY/4.0) clk_to_ram1 = clk_to_ram2;
assign #(MEM_CLK_DELAY/4.0) clk_to_ram0 = clk_to_ram1;
assign #((MEM_CLK_DELAY/4.0)) clk_to_ram = clk_to_ram0;
assign clk_to_ram_n = ~clk_to_ram ; // mem model ignores clk_n ?
// ddr sdram interface
// << START MEGAWIZARD INSERT ENTITY
ddr3_int_example_top dut (
// << END MEGAWIZARD INSERT ENTITY
.clock_source(clk),
.global_reset_n(reset_n),
// << START MEGAWIZARD INSERT PORT_MAP
.mem_clk(clk_to_sdram),
.mem_clk_n(clk_to_sdram_n),
.mem_odt(odt),
.mem_dqsn(mem_dqs_n),
.mem_reset_n(mem_reset_n),
.mem_cke(cke),
.mem_cs_n(cs_n),
.mem_ras_n(ras_n),
.mem_cas_n(cas_n),
.mem_we_n(we_n),
.mem_ba(ba),
.mem_addr(a),
.mem_dq(mem_dq),
.mem_dqs(mem_dqs),
.mem_dm(dm),
// << END MEGAWIZARD INSERT PORT_MAP
.test_complete(test_complete),
.test_status(test_status),
.pnf_per_byte(pnf_per_byte),
.pnf(pnf)
);
// << START MEGAWIZARD INSERT MEMORY_ARRAY
// This will need updating to match the memory models you are using.
// Instantiate a generated DDR memory model to match the datawidth & chipselect requirements
ddr3_int_mem_model mem (
.mem_rst_n (mem_reset_n),
.mem_dq (mem_dq),
.mem_dqs (mem_dqs),
.mem_dqs_n (mem_dqs_n),
.mem_addr (a_delayed),
.mem_ba (ba_delayed),
.mem_clk (clk_to_ram),
.mem_clk_n (clk_to_ram_n),
.mem_cke (cke_delayed),
.mem_cs_n (cs_n_delayed),
.mem_ras_n (ras_n_delayed),
.mem_cas_n (cas_n_delayed),
.mem_we_n (we_n_delayed),
.mem_dm (dm_delayed),
.mem_odt (odt_delayed)
);
// << END MEGAWIZARD INSERT MEMORY_ARRAY
always
begin
clk <= 1'b0 ;
clk_n <= 1'b1 ;
while (1'b1)
begin
#((REF_CLOCK_TICK_IN_PS / 2) * 1);
clk <= ~clk ;
clk_n <= ~clk_n ;
end
end
initial
begin
reset_n <= 1'b0 ;
@(clk);
@(clk);
@(clk);
@(clk);
@(clk);
@(clk);
reset_n <= 1'b1 ;
end
// control and data lines = 3 inches
assign a_delayed = a[gMEM_ROW_BITS - 1:0] ;
assign ba_delayed = ba ;
assign cke_delayed = cke ;
assign odt_delayed = odt ;
assign cs_n_delayed = cs_n ;
assign ras_n_delayed = ras_n ;
assign cas_n_delayed = cas_n ;
assign we_n_delayed = we_n ;
assign dm_delayed = dm ;
// ---------------------------------------------------------------
initial
begin : endit
integer count;
reg ln;
count = 0;
// Stop simulation after test_complete or TINIT + 600000 clocks
while ((count < (TINIT_CLOCKS + 600000)) & (test_complete !== 1))
begin
count = count + 1;
@(negedge clk_to_sdram[0]);
end
if (test_complete === 1)
begin
if (pnf)
begin
$write($time);
$write(" --- SIMULATION PASSED --- ");
$stop;
end
else
begin
$write($time);
$write(" --- SIMULATION FAILED --- ");
$stop;
end
end
else
begin
$write($time);
$write(" --- SIMULATION FAILED, DID NOT COMPLETE --- ");
$stop;
end
end
always @(clk_to_sdram[0] or reset_n)
begin
if (!reset_n)
begin
test_complete_count <= 0 ;
end
else if ((clk_to_sdram[0]))
begin
if (test_complete)
begin
test_complete_count <= test_complete_count + 1 ;
end
end
end
reg[2:0] cmd_bus;
//***********************************************************
// Watch the SDRAM command bus
always @(clk_to_ram)
begin
if (clk_to_ram)
begin
if (1'b1)
begin
cmd_bus = {ras_n_delayed, cas_n_delayed, we_n_delayed};
case (cmd_bus)
3'b000 :
begin
// LMR command
$write($time);
if (ba_delayed == zero_one)
begin
$write(" ELMR settings = ");
if (!(a_delayed[0]))
begin
$write("DLL enable");
end
end
else
begin
$write(" LMR settings = ");
case (a_delayed[1:0])
3'b00 : $write("BL = 8,");
3'b01 : $write("BL = On The Fly,");
3'b10 : $write("BL = 4,");
default : $write("BL = ??,");
endcase
case (a_delayed[6:4])
3'b001 : $write(" CL = 5.0,");
3'b010 : $write(" CL = 6.0,");
3'b011 : $write(" CL = 7.0,");
3'b100 : $write(" CL = 8.0,");
3'b101 : $write(" CL = 9.0,");
3'b110 : $write(" CL = 10.0,");
default : $write(" CL = ??,");
endcase
if ((a_delayed[8])) $write(" DLL reset");
end
$write("\n");
end
3'b001 :
begin
// ARF command
$write($time);
$write(" ARF\n");
end
3'b010 :
begin
// PCH command
$write($time);
$write(" PCH");
if ((a_delayed[10]))
begin
$write(" all banks \n");
end
else
begin
$write(" bank ");
$write("%H\n", ba_delayed);
end
end
3'b011 :
begin
// ACT command
$write($time);
$write(" ACT row address ");
$write("%H", a_delayed);
$write(" bank ");
$write("%H\n", ba_delayed);
end
3'b100 :
begin
// WR command
$write($time);
$write(" WR to col address ");
$write("%H", a_delayed);
$write(" bank ");
$write("%H\n", ba_delayed);
end
3'b101 :
begin
// RD command
$write($time);
$write(" RD from col address ");
$write("%H", a_delayed);
$write(" bank ");
$write("%H\n", ba_delayed);
end
3'b110 :
begin
// BT command
$write($time);
$write(" BT ");
end
3'b111 :
begin
// NOP command
end
endcase
end
else
begin
end // if enabled
end
end
endmodule
|
// -*- verilog -*-
//
// USRP - Universal Software Radio Peripheral
//
// Copyright (C) 2003,2004 Matt Ettus
// Copyright 2007 Free Software Foundation, Inc.
//
// This program 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 2 of the License, or
// (at your option) any later version.
//
// This program 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, write to the Free Software
// Foundation, Inc., 51 Franklin Street, Boston, MA 02110-1301 USA
//
`define TX_IN_BAND
`define RX_IN_BAND
`include "config.vh"
`include "../../../firmware/include/fpga_regs_common.v"
`include "../../../firmware/include/fpga_regs_standard.v"
module usrp_inband_usb
(output MYSTERY_SIGNAL,
input master_clk,
input SCLK,
input SDI,
inout SDO,
input SEN_FPGA,
input FX2_1,
output FX2_2,
output FX2_3,
input wire [11:0] rx_a_a,
input wire [11:0] rx_b_a,
//input wire [11:0] rx_a_b,
//input wire [11:0] rx_b_b,
output wire [13:0] tx_a,
//output wire [13:0] tx_b,
output wire TXSYNC_A,
//output wire TXSYNC_B,
// USB interface
input usbclk,
input wire [5:0] usbctl,
output wire [1:0] usbrdy,
input wire [3:0] usbrdy2,
inout [15:0] usbdata, // NB Careful, inout
// These are the general purpose i/o's that go to the daughterboard slots
inout wire [15:0] io_tx_a,
//inout wire [15:0] io_tx_b,
inout wire [15:0] io_rx_a,
//inout wire [15:0] io_rx_b
output wire test_bit0,
output wire test_bit1
);
wire [15:0] debugdata,debugctrl;
assign MYSTERY_SIGNAL = 1'b0;
wire clk64;
assign clk64 = master_clk;
wire WR = usbctl[0];
wire RD = usbctl[1];
wire OE = usbctl[2];
wire have_space, have_pkt_rdy;
assign usbrdy[0] = have_space;
assign usbrdy[1] = have_pkt_rdy;
wire rx_overrun;
wire clear_status = FX2_1;
assign FX2_2 = rx_overrun;
assign FX2_3 = (tx_underrun == 0);
wire [15:0] usbdata_out;
wire [3:0] dac0mux,dac1mux,dac2mux,dac3mux;
wire tx_realsignals;
wire [3:0] rx_numchan;
wire [2:0] tx_numchan;
wire [7:0] interp_rate, decim_rate;
wire [15:0] tx_debugbus, rx_debugbus;
wire enable_tx, enable_rx;
wire tx_dsp_reset, rx_dsp_reset, tx_bus_reset, rx_bus_reset;
wire [7:0] settings;
// Tri-state bus macro
bustri bustri( .data(usbdata_out),.enabledt(OE),.tridata(usbdata) );
wire [15:0] ch0tx,ch1tx,ch2tx,ch3tx; //,ch4tx,ch5tx,ch6tx,ch7tx;
wire [15:0] ch0rx,ch1rx,ch2rx,ch3rx,ch4rx,ch5rx,ch6rx,ch7rx;
// TX
wire [15:0] i_out_0,i_out_1,q_out_0,q_out_1;
wire [15:0] bb_tx_i0,bb_tx_q0,bb_tx_i1,bb_tx_q1; // bb_tx_i2,bb_tx_q2,bb_tx_i3,bb_tx_q3;
wire strobe_interp, tx_sample_strobe;
wire tx_empty;
wire serial_strobe;
wire [6:0] serial_addr;
wire [31:0] serial_data;
reg [15:0] debug_counter;
reg [15:0] loopback_i_0,loopback_q_0;
//Connection RX inband <-> TX inband
wire rx_WR;
wire [15:0] rx_databus;
wire rx_WR_done;
wire rx_WR_enabled;
wire [31:0] rssi_0,rssi_1,rssi_2,rssi_3;
wire [15:0] reg_0,reg_1,reg_2,reg_3;
wire [6:0] reg_addr;
wire [31:0] reg_data_out;
wire [31:0] reg_data_in;
wire [1:0] reg_io_enable;
wire [31:0] rssi_threshhold;
wire [31:0] rssi_wait;
wire [6:0] addr_wr;
wire [31:0] data_wr;
wire strobe_wr;
wire [6:0] addr_db;
wire [31:0] data_db;
wire strobe_db;
assign serial_strobe = strobe_db | strobe_wr;
assign serial_addr = (strobe_db)? (addr_db) : (addr_wr);
assign serial_data = (strobe_db)? (data_db) : (data_wr);
//assign serial_strobe = strobe_db;
//assign serial_data = data_db;
//assign serial_addr = addr_db;
//wires for register connection
wire [11:0] atr_tx_delay;
wire [11:0] atr_rx_delay;
wire [7:0] master_controls;
wire [3:0] debug_en;
wire [15:0] atr_mask_0;
wire [15:0] atr_txval_0;
wire [15:0] atr_rxval_0;
wire [15:0] atr_mask_1;
wire [15:0] atr_txval_1;
wire [15:0] atr_rxval_1;
wire [15:0] atr_mask_2;
wire [15:0] atr_txval_2;
wire [15:0] atr_rxval_2;
wire [15:0] atr_mask_3;
wire [15:0] atr_txval_3;
wire [15:0] atr_rxval_3;
wire [7:0] txa_refclk;
wire [7:0] txb_refclk;
wire [7:0] rxa_refclk;
wire [7:0] rxb_refclk;
register_io register_control
(.clk(clk64),.reset(1'b0),.enable(reg_io_enable),.addr(reg_addr),.datain(reg_data_in),
.dataout(reg_data_out), .data_wr(data_wr), .addr_wr(addr_wr), .strobe_wr(strobe_wr),
.rssi_0(rssi_0), .rssi_1(rssi_1), .rssi_2(rssi_2),
.rssi_3(rssi_3), .threshhold(rssi_threshhold), .rssi_wait(rssi_wait),
.reg_0(reg_0),.reg_1(reg_1),.reg_2(reg_2),.reg_3(reg_3),
.interp_rate(interp_rate), .decim_rate(decim_rate), .misc(settings),
.txmux({dac3mux,dac2mux,dac1mux,dac0mux,tx_realsignals,tx_numchan}),
.atr_tx_delay(atr_tx_delay), .atr_rx_delay(atr_rx_delay), .master_controls(master_controls),
.debug_en(debug_en), .atr_mask_0(atr_mask_0), .atr_txval_0(atr_txval_0), .atr_rxval_0(atr_rxval_0),
.atr_mask_1(atr_mask_1), .atr_txval_1(atr_txval_1), .atr_rxval_1(atr_rxval_1),
.atr_mask_2(atr_mask_2), .atr_txval_2(atr_txval_2), .atr_rxval_2(atr_rxval_2),
.atr_mask_3(atr_mask_3), .atr_txval_3(atr_txval_3), .atr_rxval_3(atr_rxval_3),
.txa_refclk(txa_refclk), .txb_refclk(txb_refclk), .rxa_refclk(rxa_refclk), .rxb_refclk(rxb_refclk));
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Transmit Side
`ifdef TX_ON
assign bb_tx_i0 = ch0tx;
assign bb_tx_q0 = ch1tx;
assign bb_tx_i1 = ch2tx;
assign bb_tx_q1 = ch3tx;
wire [1:0] tx_underrun;
wire stop;
wire [15:0] stop_time;
`ifdef TX_IN_BAND
tx_buffer_inband tx_buffer
( .usbclk(usbclk),.bus_reset(tx_bus_reset),.reset(tx_dsp_reset),
.usbdata(usbdata),.WR(WR),.have_space(have_space),
.tx_underrun(tx_underrun),.channels({tx_numchan,1'b0}),
.tx_i_0(ch0tx),.tx_q_0(ch1tx),
.tx_i_1(ch2tx),.tx_q_1(ch3tx),
.tx_i_2(),.tx_q_2(),
.tx_i_3(),.tx_q_3(),
.txclk(clk64),.txstrobe(strobe_interp),
.clear_status(clear_status),
.tx_empty(tx_empty),
.rx_WR(rx_WR),
.rx_databus(rx_databus),
.rx_WR_done(rx_WR_done),
.rx_WR_enabled(rx_WR_enabled),
.reg_addr(reg_addr),
.reg_data_out(reg_data_out),
.reg_data_in(reg_data_in),
.reg_io_enable(reg_io_enable),
.debugbus(tx_debugbus),
.rssi_0(rssi_0), .rssi_1(rssi_1), .rssi_2(rssi_2),
.rssi_3(rssi_3), .threshhold(rssi_threshhold), .rssi_wait(rssi_wait),
.stop(stop), .stop_time(stop_time),
.test_bit0(test_bit0),
.test_bit1(test_bit1));
`else
tx_buffer tx_buffer
( .usbclk(usbclk),.bus_reset(tx_bus_reset),.reset(tx_dsp_reset),
.usbdata(usbdata),.WR(WR),.have_space(have_space),.tx_underrun(tx_underrun),
.channels({tx_numchan,1'b0}),
.tx_i_0(ch0tx),.tx_q_0(ch1tx),
.tx_i_1(ch2tx),.tx_q_1(ch3tx),
.tx_i_2(),.tx_q_2(),
.tx_i_3(),.tx_q_3(),
.txclk(clk64),.txstrobe(strobe_interp),
.clear_status(clear_status),
.tx_empty(tx_empty));
`endif
`ifdef TX_EN_0
tx_chain tx_chain_0
( .clock(clk64),.reset(tx_dsp_reset),.enable(enable_tx),
.interp_rate(interp_rate),.sample_strobe(tx_sample_strobe),
.interpolator_strobe(strobe_interp),.freq(),
.i_in(bb_tx_i0),.q_in(bb_tx_q0),.i_out(i_out_0),.q_out(q_out_0) );
`else
assign i_out_0=16'd0;
assign q_out_0=16'd0;
`endif
`ifdef TX_EN_1
tx_chain tx_chain_1
( .clock(clk64),.reset(tx_dsp_reset),.enable(enable_tx),
.interp_rate(interp_rate),.sample_strobe(tx_sample_strobe),
.interpolator_strobe(strobe_interp),.freq(),
.i_in(bb_tx_i1),.q_in(bb_tx_q1),.i_out(i_out_1),.q_out(q_out_1) );
`else
assign i_out_1=16'd0;
assign q_out_1=16'd0;
`endif
setting_reg #(`FR_TX_MUX)
sr_txmux(.clock(clk64),.reset(tx_dsp_reset),.strobe(serial_strobe),.addr(serial_addr),.in(serial_data),
.out({dac3mux,dac2mux,dac1mux,dac0mux,tx_realsignals,tx_numchan}));
wire [15:0] tx_a_a = dac0mux[3] ? (dac0mux[1] ? (dac0mux[0] ? q_out_1 : i_out_1) : (dac0mux[0] ? q_out_0 : i_out_0)) : 16'b0011111111111111;
wire [15:0] tx_b_a = dac1mux[3] ? (dac1mux[1] ? (dac1mux[0] ? q_out_1 : i_out_1) : (dac1mux[0] ? q_out_0 : i_out_0)) : 16'b0011111111111111;
//wire [15:0] tx_a_b = dac2mux[3] ? (dac2mux[1] ? (dac2mux[0] ? q_out_1 : i_out_1) : (dac2mux[0] ? q_out_0 : i_out_0)) : 16'b0;
//wire [15:0] tx_b_b = dac3mux[3] ? (dac3mux[1] ? (dac3mux[0] ? q_out_1 : i_out_1) : (dac3mux[0] ? q_out_0 : i_out_0)) : 16'b0;
wire txsync = tx_sample_strobe;
assign TXSYNC_A = txsync;
//assign TXSYNC_B = txsync;
assign tx_a = txsync ? tx_b_a[15:2] : tx_a_a[15:2];
//assign tx_b = txsync ? tx_b_b[15:2] : tx_a_b[15:2];
`endif // `ifdef TX_ON
/////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Receive Side
`ifdef RX_ON
wire rx_sample_strobe,strobe_decim,hb_strobe;
wire [15:0] bb_rx_i0,bb_rx_q0,bb_rx_i1,bb_rx_q1,
bb_rx_i2,bb_rx_q2,bb_rx_i3,bb_rx_q3;
wire loopback = settings[0];
wire counter = settings[1];
always @(posedge clk64)
if(rx_dsp_reset)
debug_counter <= #1 16'd0;
else if(~enable_rx)
debug_counter <= #1 16'd0;
else if(hb_strobe)
debug_counter <=#1 debug_counter + 16'd2;
always @(posedge clk64)
if(strobe_interp)
begin
loopback_i_0 <= #1 ch0tx;
loopback_q_0 <= #1 ch1tx;
end
assign ch0rx = bb_rx_i0;
assign ch1rx = bb_rx_q0;
assign ch2rx = bb_rx_i1;
assign ch3rx = bb_rx_q1;
assign ch4rx = bb_rx_i2;
assign ch5rx = bb_rx_q2;
assign ch6rx = bb_rx_i3;
assign ch7rx = bb_rx_q3;
wire [15:0] ddc0_in_i,ddc0_in_q,ddc1_in_i,ddc1_in_q,ddc2_in_i,ddc2_in_q,ddc3_in_i,ddc3_in_q;
adc_interface adc_interface(.clock(clk64),.reset(rx_dsp_reset),.enable(1'b1),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe),
.rx_a_a(rx_a_a),.rx_b_a(rx_b_a),.rx_a_b(rx_a_a),.rx_b_b(rx_b_a),
.rssi_0(rssi_0),.rssi_1(rssi_1),.rssi_2(rssi_2),.rssi_3(rssi_3),
.ddc0_in_i(ddc0_in_i),.ddc0_in_q(ddc0_in_q),
.ddc1_in_i(ddc1_in_i),.ddc1_in_q(ddc1_in_q),
.ddc2_in_i(ddc2_in_i),.ddc2_in_q(ddc2_in_q),
.ddc3_in_i(ddc3_in_i),.ddc3_in_q(ddc3_in_q),.rx_numchan(rx_numchan));
`ifdef RX_IN_BAND
rx_buffer_inband rx_buffer
( .usbclk(usbclk),.bus_reset(rx_bus_reset),.reset(rx_dsp_reset),
.reset_regs(rx_dsp_reset),
.usbdata(usbdata_out),.RD(RD),.have_pkt_rdy(have_pkt_rdy),.rx_overrun(rx_overrun),
.channels(rx_numchan),
.ch_0(ch0rx),.ch_1(ch1rx),
.ch_2(ch2rx),.ch_3(ch3rx),
.ch_4(ch4rx),.ch_5(ch5rx),
.ch_6(ch6rx),.ch_7(ch7rx),
.rxclk(clk64),.rxstrobe(hb_strobe),
.clear_status(clear_status),
.rx_WR(rx_WR),
.rx_databus(rx_databus),
.rx_WR_done(rx_WR_done),
.rx_WR_enabled(rx_WR_enabled),
.debugbus(rx_debugbus),
.rssi_0(rssi_0), .rssi_1(rssi_1), .rssi_2(rssi_2), .rssi_3(rssi_3),
.tx_underrun(tx_underrun));
`else
rx_buffer rx_buffer
( .usbclk(usbclk),.bus_reset(rx_bus_reset),.reset(rx_dsp_reset),
.reset_regs(rx_dsp_reset),
.usbdata(usbdata_out),.RD(RD),.have_pkt_rdy(have_pkt_rdy),.rx_overrun(rx_overrun),
.channels(rx_numchan),
.ch_0(ch0rx),.ch_1(ch1rx),
.ch_2(ch2rx),.ch_3(ch3rx),
.ch_4(ch4rx),.ch_5(ch5rx),
.ch_6(ch6rx),.ch_7(ch7rx),
.rxclk(clk64),.rxstrobe(hb_strobe),
.clear_status(clear_status),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe));
`endif
`ifdef RX_EN_0
rx_chain #(`FR_RX_FREQ_0,`FR_RX_PHASE_0) rx_chain_0
( .clock(clk64),.reset(1'b0),.enable(enable_rx),
.decim_rate(decim_rate),.sample_strobe(rx_sample_strobe),.decimator_strobe(strobe_decim),.hb_strobe(hb_strobe),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe),
.i_in(ddc0_in_i),.q_in(ddc0_in_q),.i_out(bb_rx_i0),.q_out(bb_rx_q0),.debugdata(debugdata),.debugctrl(debugctrl));
`else
assign bb_rx_i0=16'd0;
assign bb_rx_q0=16'd0;
`endif
`ifdef RX_EN_1
rx_chain #(`FR_RX_FREQ_1,`FR_RX_PHASE_1) rx_chain_1
( .clock(clk64),.reset(1'b0),.enable(enable_rx),
.decim_rate(decim_rate),.sample_strobe(rx_sample_strobe),.decimator_strobe(strobe_decim),.hb_strobe(),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe),
.i_in(ddc1_in_i),.q_in(ddc1_in_q),.i_out(bb_rx_i1),.q_out(bb_rx_q1));
`else
assign bb_rx_i1=16'd0;
assign bb_rx_q1=16'd0;
`endif
`ifdef RX_EN_2
rx_chain #(`FR_RX_FREQ_2,`FR_RX_PHASE_2) rx_chain_2
( .clock(clk64),.reset(1'b0),.enable(enable_rx),
.decim_rate(decim_rate),.sample_strobe(rx_sample_strobe),.decimator_strobe(strobe_decim),.hb_strobe(),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe),
.i_in(ddc2_in_i),.q_in(ddc2_in_q),.i_out(bb_rx_i2),.q_out(bb_rx_q2));
`else
assign bb_rx_i2=16'd0;
assign bb_rx_q2=16'd0;
`endif
`ifdef RX_EN_3
rx_chain #(`FR_RX_FREQ_3,`FR_RX_PHASE_3) rx_chain_3
( .clock(clk64),.reset(1'b0),.enable(enable_rx),
.decim_rate(decim_rate),.sample_strobe(rx_sample_strobe),.decimator_strobe(strobe_decim),.hb_strobe(),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe),
.i_in(ddc3_in_i),.q_in(ddc3_in_q),.i_out(bb_rx_i3),.q_out(bb_rx_q3));
`else
assign bb_rx_i3=16'd0;
assign bb_rx_q3=16'd0;
`endif
`endif // `ifdef RX_ON
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Control Functions
wire [31:0] capabilities;
assign capabilities[7] = `TX_CAP_HB;
assign capabilities[6:4] = `TX_CAP_NCHAN;
assign capabilities[3] = `RX_CAP_HB;
assign capabilities[2:0] = `RX_CAP_NCHAN;
serial_io serial_io
( .master_clk(clk64),.serial_clock(SCLK),.serial_data_in(SDI),
.enable(SEN_FPGA),.reset(1'b0),.serial_data_out(SDO),
.serial_addr(addr_db),.serial_data(data_db),.serial_strobe(strobe_db),
.readback_0({io_rx_a,io_tx_a}),.readback_1({io_rx_a,io_tx_a}),.readback_2(capabilities),.readback_3(32'hf0f0931a),
.readback_4(rssi_0),.readback_5(rssi_1),.readback_6(rssi_2),.readback_7(rssi_3)
);
//implementing freeze mode
/*
reg [15:0] timestop;
wire stop;
wire [15:0] stop_time;
assign clk64 = (timestop == 0) ? master_clk : 0;
always @(posedge master_clk)
if (timestop[15:0] != 0)
timestop <= timestop - 16'd1;
else if (stop)
timestop <= stop_time;
*/
master_control master_control
( .master_clk(clk64),.usbclk(usbclk),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe),
.tx_bus_reset(tx_bus_reset),.rx_bus_reset(rx_bus_reset),
.tx_dsp_reset(tx_dsp_reset),.rx_dsp_reset(rx_dsp_reset),
.enable_tx(enable_tx),.enable_rx(enable_rx),
.interp_rate(interp_rate),.decim_rate(decim_rate),
.tx_sample_strobe(tx_sample_strobe),.strobe_interp(strobe_interp),
.rx_sample_strobe(rx_sample_strobe),.strobe_decim(strobe_decim),
.tx_empty(tx_empty), .reg_0(reg_0),.reg_1(reg_1),.reg_2(reg_2),.reg_3(reg_3),
.atr_tx_delay(atr_tx_delay), .atr_rx_delay(atr_rx_delay),
.master_controls(master_controls), .debug_en(debug_en),
.atr_mask_0(atr_mask_0), .atr_txval_0(atr_txval_0), .atr_rxval_0(atr_rxval_0),
.atr_mask_1(atr_mask_1), .atr_txval_1(atr_txval_1), .atr_rxval_1(atr_rxval_1),
.atr_mask_2(atr_mask_2), .atr_txval_2(atr_txval_2), .atr_rxval_2(atr_rxval_2),
.atr_mask_3(atr_mask_3), .atr_txval_3(atr_txval_3), .atr_rxval_3(atr_rxval_3),
.txa_refclk(txa_refclk), .txb_refclk(txb_refclk), .rxa_refclk(rxa_refclk), .rxb_refclk(rxb_refclk),
.debug_0(tx_debugbus), .debug_1(rx_debugbus));
io_pins io_pins
(.io_0(io_tx_a),.io_1(io_rx_a),
.reg_0(reg_0),.reg_1(reg_1),
.clock(clk64),.rx_reset(rx_dsp_reset),.tx_reset(tx_dsp_reset),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe));
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Misc Settings
setting_reg #(`FR_MODE) sr_misc(.clock(clk64),.reset(rx_dsp_reset),.strobe(serial_strobe),.addr(serial_addr),.in(serial_data),.out(settings));
reg forb;
always @(posedge usbclk)
begin
if (strobe_db) forb <= 1;
end
endmodule // usrp_inband_usb
|
// -*- verilog -*-
//
// USRP - Universal Software Radio Peripheral
//
// Copyright (C) 2003,2004 Matt Ettus
// Copyright 2007 Free Software Foundation, Inc.
//
// This program 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 2 of the License, or
// (at your option) any later version.
//
// This program 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, write to the Free Software
// Foundation, Inc., 51 Franklin Street, Boston, MA 02110-1301 USA
//
`define TX_IN_BAND
`define RX_IN_BAND
`include "config.vh"
`include "../../../firmware/include/fpga_regs_common.v"
`include "../../../firmware/include/fpga_regs_standard.v"
module usrp_inband_usb
(output MYSTERY_SIGNAL,
input master_clk,
input SCLK,
input SDI,
inout SDO,
input SEN_FPGA,
input FX2_1,
output FX2_2,
output FX2_3,
input wire [11:0] rx_a_a,
input wire [11:0] rx_b_a,
//input wire [11:0] rx_a_b,
//input wire [11:0] rx_b_b,
output wire [13:0] tx_a,
//output wire [13:0] tx_b,
output wire TXSYNC_A,
//output wire TXSYNC_B,
// USB interface
input usbclk,
input wire [5:0] usbctl,
output wire [1:0] usbrdy,
input wire [3:0] usbrdy2,
inout [15:0] usbdata, // NB Careful, inout
// These are the general purpose i/o's that go to the daughterboard slots
inout wire [15:0] io_tx_a,
//inout wire [15:0] io_tx_b,
inout wire [15:0] io_rx_a,
//inout wire [15:0] io_rx_b
output wire test_bit0,
output wire test_bit1
);
wire [15:0] debugdata,debugctrl;
assign MYSTERY_SIGNAL = 1'b0;
wire clk64;
assign clk64 = master_clk;
wire WR = usbctl[0];
wire RD = usbctl[1];
wire OE = usbctl[2];
wire have_space, have_pkt_rdy;
assign usbrdy[0] = have_space;
assign usbrdy[1] = have_pkt_rdy;
wire rx_overrun;
wire clear_status = FX2_1;
assign FX2_2 = rx_overrun;
assign FX2_3 = (tx_underrun == 0);
wire [15:0] usbdata_out;
wire [3:0] dac0mux,dac1mux,dac2mux,dac3mux;
wire tx_realsignals;
wire [3:0] rx_numchan;
wire [2:0] tx_numchan;
wire [7:0] interp_rate, decim_rate;
wire [15:0] tx_debugbus, rx_debugbus;
wire enable_tx, enable_rx;
wire tx_dsp_reset, rx_dsp_reset, tx_bus_reset, rx_bus_reset;
wire [7:0] settings;
// Tri-state bus macro
bustri bustri( .data(usbdata_out),.enabledt(OE),.tridata(usbdata) );
wire [15:0] ch0tx,ch1tx,ch2tx,ch3tx; //,ch4tx,ch5tx,ch6tx,ch7tx;
wire [15:0] ch0rx,ch1rx,ch2rx,ch3rx,ch4rx,ch5rx,ch6rx,ch7rx;
// TX
wire [15:0] i_out_0,i_out_1,q_out_0,q_out_1;
wire [15:0] bb_tx_i0,bb_tx_q0,bb_tx_i1,bb_tx_q1; // bb_tx_i2,bb_tx_q2,bb_tx_i3,bb_tx_q3;
wire strobe_interp, tx_sample_strobe;
wire tx_empty;
wire serial_strobe;
wire [6:0] serial_addr;
wire [31:0] serial_data;
reg [15:0] debug_counter;
reg [15:0] loopback_i_0,loopback_q_0;
//Connection RX inband <-> TX inband
wire rx_WR;
wire [15:0] rx_databus;
wire rx_WR_done;
wire rx_WR_enabled;
wire [31:0] rssi_0,rssi_1,rssi_2,rssi_3;
wire [15:0] reg_0,reg_1,reg_2,reg_3;
wire [6:0] reg_addr;
wire [31:0] reg_data_out;
wire [31:0] reg_data_in;
wire [1:0] reg_io_enable;
wire [31:0] rssi_threshhold;
wire [31:0] rssi_wait;
wire [6:0] addr_wr;
wire [31:0] data_wr;
wire strobe_wr;
wire [6:0] addr_db;
wire [31:0] data_db;
wire strobe_db;
assign serial_strobe = strobe_db | strobe_wr;
assign serial_addr = (strobe_db)? (addr_db) : (addr_wr);
assign serial_data = (strobe_db)? (data_db) : (data_wr);
//assign serial_strobe = strobe_db;
//assign serial_data = data_db;
//assign serial_addr = addr_db;
//wires for register connection
wire [11:0] atr_tx_delay;
wire [11:0] atr_rx_delay;
wire [7:0] master_controls;
wire [3:0] debug_en;
wire [15:0] atr_mask_0;
wire [15:0] atr_txval_0;
wire [15:0] atr_rxval_0;
wire [15:0] atr_mask_1;
wire [15:0] atr_txval_1;
wire [15:0] atr_rxval_1;
wire [15:0] atr_mask_2;
wire [15:0] atr_txval_2;
wire [15:0] atr_rxval_2;
wire [15:0] atr_mask_3;
wire [15:0] atr_txval_3;
wire [15:0] atr_rxval_3;
wire [7:0] txa_refclk;
wire [7:0] txb_refclk;
wire [7:0] rxa_refclk;
wire [7:0] rxb_refclk;
register_io register_control
(.clk(clk64),.reset(1'b0),.enable(reg_io_enable),.addr(reg_addr),.datain(reg_data_in),
.dataout(reg_data_out), .data_wr(data_wr), .addr_wr(addr_wr), .strobe_wr(strobe_wr),
.rssi_0(rssi_0), .rssi_1(rssi_1), .rssi_2(rssi_2),
.rssi_3(rssi_3), .threshhold(rssi_threshhold), .rssi_wait(rssi_wait),
.reg_0(reg_0),.reg_1(reg_1),.reg_2(reg_2),.reg_3(reg_3),
.interp_rate(interp_rate), .decim_rate(decim_rate), .misc(settings),
.txmux({dac3mux,dac2mux,dac1mux,dac0mux,tx_realsignals,tx_numchan}),
.atr_tx_delay(atr_tx_delay), .atr_rx_delay(atr_rx_delay), .master_controls(master_controls),
.debug_en(debug_en), .atr_mask_0(atr_mask_0), .atr_txval_0(atr_txval_0), .atr_rxval_0(atr_rxval_0),
.atr_mask_1(atr_mask_1), .atr_txval_1(atr_txval_1), .atr_rxval_1(atr_rxval_1),
.atr_mask_2(atr_mask_2), .atr_txval_2(atr_txval_2), .atr_rxval_2(atr_rxval_2),
.atr_mask_3(atr_mask_3), .atr_txval_3(atr_txval_3), .atr_rxval_3(atr_rxval_3),
.txa_refclk(txa_refclk), .txb_refclk(txb_refclk), .rxa_refclk(rxa_refclk), .rxb_refclk(rxb_refclk));
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Transmit Side
`ifdef TX_ON
assign bb_tx_i0 = ch0tx;
assign bb_tx_q0 = ch1tx;
assign bb_tx_i1 = ch2tx;
assign bb_tx_q1 = ch3tx;
wire [1:0] tx_underrun;
wire stop;
wire [15:0] stop_time;
`ifdef TX_IN_BAND
tx_buffer_inband tx_buffer
( .usbclk(usbclk),.bus_reset(tx_bus_reset),.reset(tx_dsp_reset),
.usbdata(usbdata),.WR(WR),.have_space(have_space),
.tx_underrun(tx_underrun),.channels({tx_numchan,1'b0}),
.tx_i_0(ch0tx),.tx_q_0(ch1tx),
.tx_i_1(ch2tx),.tx_q_1(ch3tx),
.tx_i_2(),.tx_q_2(),
.tx_i_3(),.tx_q_3(),
.txclk(clk64),.txstrobe(strobe_interp),
.clear_status(clear_status),
.tx_empty(tx_empty),
.rx_WR(rx_WR),
.rx_databus(rx_databus),
.rx_WR_done(rx_WR_done),
.rx_WR_enabled(rx_WR_enabled),
.reg_addr(reg_addr),
.reg_data_out(reg_data_out),
.reg_data_in(reg_data_in),
.reg_io_enable(reg_io_enable),
.debugbus(tx_debugbus),
.rssi_0(rssi_0), .rssi_1(rssi_1), .rssi_2(rssi_2),
.rssi_3(rssi_3), .threshhold(rssi_threshhold), .rssi_wait(rssi_wait),
.stop(stop), .stop_time(stop_time),
.test_bit0(test_bit0),
.test_bit1(test_bit1));
`else
tx_buffer tx_buffer
( .usbclk(usbclk),.bus_reset(tx_bus_reset),.reset(tx_dsp_reset),
.usbdata(usbdata),.WR(WR),.have_space(have_space),.tx_underrun(tx_underrun),
.channels({tx_numchan,1'b0}),
.tx_i_0(ch0tx),.tx_q_0(ch1tx),
.tx_i_1(ch2tx),.tx_q_1(ch3tx),
.tx_i_2(),.tx_q_2(),
.tx_i_3(),.tx_q_3(),
.txclk(clk64),.txstrobe(strobe_interp),
.clear_status(clear_status),
.tx_empty(tx_empty));
`endif
`ifdef TX_EN_0
tx_chain tx_chain_0
( .clock(clk64),.reset(tx_dsp_reset),.enable(enable_tx),
.interp_rate(interp_rate),.sample_strobe(tx_sample_strobe),
.interpolator_strobe(strobe_interp),.freq(),
.i_in(bb_tx_i0),.q_in(bb_tx_q0),.i_out(i_out_0),.q_out(q_out_0) );
`else
assign i_out_0=16'd0;
assign q_out_0=16'd0;
`endif
`ifdef TX_EN_1
tx_chain tx_chain_1
( .clock(clk64),.reset(tx_dsp_reset),.enable(enable_tx),
.interp_rate(interp_rate),.sample_strobe(tx_sample_strobe),
.interpolator_strobe(strobe_interp),.freq(),
.i_in(bb_tx_i1),.q_in(bb_tx_q1),.i_out(i_out_1),.q_out(q_out_1) );
`else
assign i_out_1=16'd0;
assign q_out_1=16'd0;
`endif
setting_reg #(`FR_TX_MUX)
sr_txmux(.clock(clk64),.reset(tx_dsp_reset),.strobe(serial_strobe),.addr(serial_addr),.in(serial_data),
.out({dac3mux,dac2mux,dac1mux,dac0mux,tx_realsignals,tx_numchan}));
wire [15:0] tx_a_a = dac0mux[3] ? (dac0mux[1] ? (dac0mux[0] ? q_out_1 : i_out_1) : (dac0mux[0] ? q_out_0 : i_out_0)) : 16'b0011111111111111;
wire [15:0] tx_b_a = dac1mux[3] ? (dac1mux[1] ? (dac1mux[0] ? q_out_1 : i_out_1) : (dac1mux[0] ? q_out_0 : i_out_0)) : 16'b0011111111111111;
//wire [15:0] tx_a_b = dac2mux[3] ? (dac2mux[1] ? (dac2mux[0] ? q_out_1 : i_out_1) : (dac2mux[0] ? q_out_0 : i_out_0)) : 16'b0;
//wire [15:0] tx_b_b = dac3mux[3] ? (dac3mux[1] ? (dac3mux[0] ? q_out_1 : i_out_1) : (dac3mux[0] ? q_out_0 : i_out_0)) : 16'b0;
wire txsync = tx_sample_strobe;
assign TXSYNC_A = txsync;
//assign TXSYNC_B = txsync;
assign tx_a = txsync ? tx_b_a[15:2] : tx_a_a[15:2];
//assign tx_b = txsync ? tx_b_b[15:2] : tx_a_b[15:2];
`endif // `ifdef TX_ON
/////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Receive Side
`ifdef RX_ON
wire rx_sample_strobe,strobe_decim,hb_strobe;
wire [15:0] bb_rx_i0,bb_rx_q0,bb_rx_i1,bb_rx_q1,
bb_rx_i2,bb_rx_q2,bb_rx_i3,bb_rx_q3;
wire loopback = settings[0];
wire counter = settings[1];
always @(posedge clk64)
if(rx_dsp_reset)
debug_counter <= #1 16'd0;
else if(~enable_rx)
debug_counter <= #1 16'd0;
else if(hb_strobe)
debug_counter <=#1 debug_counter + 16'd2;
always @(posedge clk64)
if(strobe_interp)
begin
loopback_i_0 <= #1 ch0tx;
loopback_q_0 <= #1 ch1tx;
end
assign ch0rx = bb_rx_i0;
assign ch1rx = bb_rx_q0;
assign ch2rx = bb_rx_i1;
assign ch3rx = bb_rx_q1;
assign ch4rx = bb_rx_i2;
assign ch5rx = bb_rx_q2;
assign ch6rx = bb_rx_i3;
assign ch7rx = bb_rx_q3;
wire [15:0] ddc0_in_i,ddc0_in_q,ddc1_in_i,ddc1_in_q,ddc2_in_i,ddc2_in_q,ddc3_in_i,ddc3_in_q;
adc_interface adc_interface(.clock(clk64),.reset(rx_dsp_reset),.enable(1'b1),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe),
.rx_a_a(rx_a_a),.rx_b_a(rx_b_a),.rx_a_b(rx_a_a),.rx_b_b(rx_b_a),
.rssi_0(rssi_0),.rssi_1(rssi_1),.rssi_2(rssi_2),.rssi_3(rssi_3),
.ddc0_in_i(ddc0_in_i),.ddc0_in_q(ddc0_in_q),
.ddc1_in_i(ddc1_in_i),.ddc1_in_q(ddc1_in_q),
.ddc2_in_i(ddc2_in_i),.ddc2_in_q(ddc2_in_q),
.ddc3_in_i(ddc3_in_i),.ddc3_in_q(ddc3_in_q),.rx_numchan(rx_numchan));
`ifdef RX_IN_BAND
rx_buffer_inband rx_buffer
( .usbclk(usbclk),.bus_reset(rx_bus_reset),.reset(rx_dsp_reset),
.reset_regs(rx_dsp_reset),
.usbdata(usbdata_out),.RD(RD),.have_pkt_rdy(have_pkt_rdy),.rx_overrun(rx_overrun),
.channels(rx_numchan),
.ch_0(ch0rx),.ch_1(ch1rx),
.ch_2(ch2rx),.ch_3(ch3rx),
.ch_4(ch4rx),.ch_5(ch5rx),
.ch_6(ch6rx),.ch_7(ch7rx),
.rxclk(clk64),.rxstrobe(hb_strobe),
.clear_status(clear_status),
.rx_WR(rx_WR),
.rx_databus(rx_databus),
.rx_WR_done(rx_WR_done),
.rx_WR_enabled(rx_WR_enabled),
.debugbus(rx_debugbus),
.rssi_0(rssi_0), .rssi_1(rssi_1), .rssi_2(rssi_2), .rssi_3(rssi_3),
.tx_underrun(tx_underrun));
`else
rx_buffer rx_buffer
( .usbclk(usbclk),.bus_reset(rx_bus_reset),.reset(rx_dsp_reset),
.reset_regs(rx_dsp_reset),
.usbdata(usbdata_out),.RD(RD),.have_pkt_rdy(have_pkt_rdy),.rx_overrun(rx_overrun),
.channels(rx_numchan),
.ch_0(ch0rx),.ch_1(ch1rx),
.ch_2(ch2rx),.ch_3(ch3rx),
.ch_4(ch4rx),.ch_5(ch5rx),
.ch_6(ch6rx),.ch_7(ch7rx),
.rxclk(clk64),.rxstrobe(hb_strobe),
.clear_status(clear_status),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe));
`endif
`ifdef RX_EN_0
rx_chain #(`FR_RX_FREQ_0,`FR_RX_PHASE_0) rx_chain_0
( .clock(clk64),.reset(1'b0),.enable(enable_rx),
.decim_rate(decim_rate),.sample_strobe(rx_sample_strobe),.decimator_strobe(strobe_decim),.hb_strobe(hb_strobe),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe),
.i_in(ddc0_in_i),.q_in(ddc0_in_q),.i_out(bb_rx_i0),.q_out(bb_rx_q0),.debugdata(debugdata),.debugctrl(debugctrl));
`else
assign bb_rx_i0=16'd0;
assign bb_rx_q0=16'd0;
`endif
`ifdef RX_EN_1
rx_chain #(`FR_RX_FREQ_1,`FR_RX_PHASE_1) rx_chain_1
( .clock(clk64),.reset(1'b0),.enable(enable_rx),
.decim_rate(decim_rate),.sample_strobe(rx_sample_strobe),.decimator_strobe(strobe_decim),.hb_strobe(),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe),
.i_in(ddc1_in_i),.q_in(ddc1_in_q),.i_out(bb_rx_i1),.q_out(bb_rx_q1));
`else
assign bb_rx_i1=16'd0;
assign bb_rx_q1=16'd0;
`endif
`ifdef RX_EN_2
rx_chain #(`FR_RX_FREQ_2,`FR_RX_PHASE_2) rx_chain_2
( .clock(clk64),.reset(1'b0),.enable(enable_rx),
.decim_rate(decim_rate),.sample_strobe(rx_sample_strobe),.decimator_strobe(strobe_decim),.hb_strobe(),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe),
.i_in(ddc2_in_i),.q_in(ddc2_in_q),.i_out(bb_rx_i2),.q_out(bb_rx_q2));
`else
assign bb_rx_i2=16'd0;
assign bb_rx_q2=16'd0;
`endif
`ifdef RX_EN_3
rx_chain #(`FR_RX_FREQ_3,`FR_RX_PHASE_3) rx_chain_3
( .clock(clk64),.reset(1'b0),.enable(enable_rx),
.decim_rate(decim_rate),.sample_strobe(rx_sample_strobe),.decimator_strobe(strobe_decim),.hb_strobe(),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe),
.i_in(ddc3_in_i),.q_in(ddc3_in_q),.i_out(bb_rx_i3),.q_out(bb_rx_q3));
`else
assign bb_rx_i3=16'd0;
assign bb_rx_q3=16'd0;
`endif
`endif // `ifdef RX_ON
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Control Functions
wire [31:0] capabilities;
assign capabilities[7] = `TX_CAP_HB;
assign capabilities[6:4] = `TX_CAP_NCHAN;
assign capabilities[3] = `RX_CAP_HB;
assign capabilities[2:0] = `RX_CAP_NCHAN;
serial_io serial_io
( .master_clk(clk64),.serial_clock(SCLK),.serial_data_in(SDI),
.enable(SEN_FPGA),.reset(1'b0),.serial_data_out(SDO),
.serial_addr(addr_db),.serial_data(data_db),.serial_strobe(strobe_db),
.readback_0({io_rx_a,io_tx_a}),.readback_1({io_rx_a,io_tx_a}),.readback_2(capabilities),.readback_3(32'hf0f0931a),
.readback_4(rssi_0),.readback_5(rssi_1),.readback_6(rssi_2),.readback_7(rssi_3)
);
//implementing freeze mode
/*
reg [15:0] timestop;
wire stop;
wire [15:0] stop_time;
assign clk64 = (timestop == 0) ? master_clk : 0;
always @(posedge master_clk)
if (timestop[15:0] != 0)
timestop <= timestop - 16'd1;
else if (stop)
timestop <= stop_time;
*/
master_control master_control
( .master_clk(clk64),.usbclk(usbclk),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe),
.tx_bus_reset(tx_bus_reset),.rx_bus_reset(rx_bus_reset),
.tx_dsp_reset(tx_dsp_reset),.rx_dsp_reset(rx_dsp_reset),
.enable_tx(enable_tx),.enable_rx(enable_rx),
.interp_rate(interp_rate),.decim_rate(decim_rate),
.tx_sample_strobe(tx_sample_strobe),.strobe_interp(strobe_interp),
.rx_sample_strobe(rx_sample_strobe),.strobe_decim(strobe_decim),
.tx_empty(tx_empty), .reg_0(reg_0),.reg_1(reg_1),.reg_2(reg_2),.reg_3(reg_3),
.atr_tx_delay(atr_tx_delay), .atr_rx_delay(atr_rx_delay),
.master_controls(master_controls), .debug_en(debug_en),
.atr_mask_0(atr_mask_0), .atr_txval_0(atr_txval_0), .atr_rxval_0(atr_rxval_0),
.atr_mask_1(atr_mask_1), .atr_txval_1(atr_txval_1), .atr_rxval_1(atr_rxval_1),
.atr_mask_2(atr_mask_2), .atr_txval_2(atr_txval_2), .atr_rxval_2(atr_rxval_2),
.atr_mask_3(atr_mask_3), .atr_txval_3(atr_txval_3), .atr_rxval_3(atr_rxval_3),
.txa_refclk(txa_refclk), .txb_refclk(txb_refclk), .rxa_refclk(rxa_refclk), .rxb_refclk(rxb_refclk),
.debug_0(tx_debugbus), .debug_1(rx_debugbus));
io_pins io_pins
(.io_0(io_tx_a),.io_1(io_rx_a),
.reg_0(reg_0),.reg_1(reg_1),
.clock(clk64),.rx_reset(rx_dsp_reset),.tx_reset(tx_dsp_reset),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe));
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Misc Settings
setting_reg #(`FR_MODE) sr_misc(.clock(clk64),.reset(rx_dsp_reset),.strobe(serial_strobe),.addr(serial_addr),.in(serial_data),.out(settings));
reg forb;
always @(posedge usbclk)
begin
if (strobe_db) forb <= 1;
end
endmodule // usrp_inband_usb
|
// -*- verilog -*-
//
// USRP - Universal Software Radio Peripheral
//
// Copyright (C) 2003,2004 Matt Ettus
// Copyright 2007 Free Software Foundation, Inc.
//
// This program 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 2 of the License, or
// (at your option) any later version.
//
// This program 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, write to the Free Software
// Foundation, Inc., 51 Franklin Street, Boston, MA 02110-1301 USA
//
`define TX_IN_BAND
`define RX_IN_BAND
`include "config.vh"
`include "../../../firmware/include/fpga_regs_common.v"
`include "../../../firmware/include/fpga_regs_standard.v"
module usrp_inband_usb
(output MYSTERY_SIGNAL,
input master_clk,
input SCLK,
input SDI,
inout SDO,
input SEN_FPGA,
input FX2_1,
output FX2_2,
output FX2_3,
input wire [11:0] rx_a_a,
input wire [11:0] rx_b_a,
//input wire [11:0] rx_a_b,
//input wire [11:0] rx_b_b,
output wire [13:0] tx_a,
//output wire [13:0] tx_b,
output wire TXSYNC_A,
//output wire TXSYNC_B,
// USB interface
input usbclk,
input wire [5:0] usbctl,
output wire [1:0] usbrdy,
input wire [3:0] usbrdy2,
inout [15:0] usbdata, // NB Careful, inout
// These are the general purpose i/o's that go to the daughterboard slots
inout wire [15:0] io_tx_a,
//inout wire [15:0] io_tx_b,
inout wire [15:0] io_rx_a,
//inout wire [15:0] io_rx_b
output wire test_bit0,
output wire test_bit1
);
wire [15:0] debugdata,debugctrl;
assign MYSTERY_SIGNAL = 1'b0;
wire clk64;
assign clk64 = master_clk;
wire WR = usbctl[0];
wire RD = usbctl[1];
wire OE = usbctl[2];
wire have_space, have_pkt_rdy;
assign usbrdy[0] = have_space;
assign usbrdy[1] = have_pkt_rdy;
wire rx_overrun;
wire clear_status = FX2_1;
assign FX2_2 = rx_overrun;
assign FX2_3 = (tx_underrun == 0);
wire [15:0] usbdata_out;
wire [3:0] dac0mux,dac1mux,dac2mux,dac3mux;
wire tx_realsignals;
wire [3:0] rx_numchan;
wire [2:0] tx_numchan;
wire [7:0] interp_rate, decim_rate;
wire [15:0] tx_debugbus, rx_debugbus;
wire enable_tx, enable_rx;
wire tx_dsp_reset, rx_dsp_reset, tx_bus_reset, rx_bus_reset;
wire [7:0] settings;
// Tri-state bus macro
bustri bustri( .data(usbdata_out),.enabledt(OE),.tridata(usbdata) );
wire [15:0] ch0tx,ch1tx,ch2tx,ch3tx; //,ch4tx,ch5tx,ch6tx,ch7tx;
wire [15:0] ch0rx,ch1rx,ch2rx,ch3rx,ch4rx,ch5rx,ch6rx,ch7rx;
// TX
wire [15:0] i_out_0,i_out_1,q_out_0,q_out_1;
wire [15:0] bb_tx_i0,bb_tx_q0,bb_tx_i1,bb_tx_q1; // bb_tx_i2,bb_tx_q2,bb_tx_i3,bb_tx_q3;
wire strobe_interp, tx_sample_strobe;
wire tx_empty;
wire serial_strobe;
wire [6:0] serial_addr;
wire [31:0] serial_data;
reg [15:0] debug_counter;
reg [15:0] loopback_i_0,loopback_q_0;
//Connection RX inband <-> TX inband
wire rx_WR;
wire [15:0] rx_databus;
wire rx_WR_done;
wire rx_WR_enabled;
wire [31:0] rssi_0,rssi_1,rssi_2,rssi_3;
wire [15:0] reg_0,reg_1,reg_2,reg_3;
wire [6:0] reg_addr;
wire [31:0] reg_data_out;
wire [31:0] reg_data_in;
wire [1:0] reg_io_enable;
wire [31:0] rssi_threshhold;
wire [31:0] rssi_wait;
wire [6:0] addr_wr;
wire [31:0] data_wr;
wire strobe_wr;
wire [6:0] addr_db;
wire [31:0] data_db;
wire strobe_db;
assign serial_strobe = strobe_db | strobe_wr;
assign serial_addr = (strobe_db)? (addr_db) : (addr_wr);
assign serial_data = (strobe_db)? (data_db) : (data_wr);
//assign serial_strobe = strobe_db;
//assign serial_data = data_db;
//assign serial_addr = addr_db;
//wires for register connection
wire [11:0] atr_tx_delay;
wire [11:0] atr_rx_delay;
wire [7:0] master_controls;
wire [3:0] debug_en;
wire [15:0] atr_mask_0;
wire [15:0] atr_txval_0;
wire [15:0] atr_rxval_0;
wire [15:0] atr_mask_1;
wire [15:0] atr_txval_1;
wire [15:0] atr_rxval_1;
wire [15:0] atr_mask_2;
wire [15:0] atr_txval_2;
wire [15:0] atr_rxval_2;
wire [15:0] atr_mask_3;
wire [15:0] atr_txval_3;
wire [15:0] atr_rxval_3;
wire [7:0] txa_refclk;
wire [7:0] txb_refclk;
wire [7:0] rxa_refclk;
wire [7:0] rxb_refclk;
register_io register_control
(.clk(clk64),.reset(1'b0),.enable(reg_io_enable),.addr(reg_addr),.datain(reg_data_in),
.dataout(reg_data_out), .data_wr(data_wr), .addr_wr(addr_wr), .strobe_wr(strobe_wr),
.rssi_0(rssi_0), .rssi_1(rssi_1), .rssi_2(rssi_2),
.rssi_3(rssi_3), .threshhold(rssi_threshhold), .rssi_wait(rssi_wait),
.reg_0(reg_0),.reg_1(reg_1),.reg_2(reg_2),.reg_3(reg_3),
.interp_rate(interp_rate), .decim_rate(decim_rate), .misc(settings),
.txmux({dac3mux,dac2mux,dac1mux,dac0mux,tx_realsignals,tx_numchan}),
.atr_tx_delay(atr_tx_delay), .atr_rx_delay(atr_rx_delay), .master_controls(master_controls),
.debug_en(debug_en), .atr_mask_0(atr_mask_0), .atr_txval_0(atr_txval_0), .atr_rxval_0(atr_rxval_0),
.atr_mask_1(atr_mask_1), .atr_txval_1(atr_txval_1), .atr_rxval_1(atr_rxval_1),
.atr_mask_2(atr_mask_2), .atr_txval_2(atr_txval_2), .atr_rxval_2(atr_rxval_2),
.atr_mask_3(atr_mask_3), .atr_txval_3(atr_txval_3), .atr_rxval_3(atr_rxval_3),
.txa_refclk(txa_refclk), .txb_refclk(txb_refclk), .rxa_refclk(rxa_refclk), .rxb_refclk(rxb_refclk));
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Transmit Side
`ifdef TX_ON
assign bb_tx_i0 = ch0tx;
assign bb_tx_q0 = ch1tx;
assign bb_tx_i1 = ch2tx;
assign bb_tx_q1 = ch3tx;
wire [1:0] tx_underrun;
wire stop;
wire [15:0] stop_time;
`ifdef TX_IN_BAND
tx_buffer_inband tx_buffer
( .usbclk(usbclk),.bus_reset(tx_bus_reset),.reset(tx_dsp_reset),
.usbdata(usbdata),.WR(WR),.have_space(have_space),
.tx_underrun(tx_underrun),.channels({tx_numchan,1'b0}),
.tx_i_0(ch0tx),.tx_q_0(ch1tx),
.tx_i_1(ch2tx),.tx_q_1(ch3tx),
.tx_i_2(),.tx_q_2(),
.tx_i_3(),.tx_q_3(),
.txclk(clk64),.txstrobe(strobe_interp),
.clear_status(clear_status),
.tx_empty(tx_empty),
.rx_WR(rx_WR),
.rx_databus(rx_databus),
.rx_WR_done(rx_WR_done),
.rx_WR_enabled(rx_WR_enabled),
.reg_addr(reg_addr),
.reg_data_out(reg_data_out),
.reg_data_in(reg_data_in),
.reg_io_enable(reg_io_enable),
.debugbus(tx_debugbus),
.rssi_0(rssi_0), .rssi_1(rssi_1), .rssi_2(rssi_2),
.rssi_3(rssi_3), .threshhold(rssi_threshhold), .rssi_wait(rssi_wait),
.stop(stop), .stop_time(stop_time),
.test_bit0(test_bit0),
.test_bit1(test_bit1));
`else
tx_buffer tx_buffer
( .usbclk(usbclk),.bus_reset(tx_bus_reset),.reset(tx_dsp_reset),
.usbdata(usbdata),.WR(WR),.have_space(have_space),.tx_underrun(tx_underrun),
.channels({tx_numchan,1'b0}),
.tx_i_0(ch0tx),.tx_q_0(ch1tx),
.tx_i_1(ch2tx),.tx_q_1(ch3tx),
.tx_i_2(),.tx_q_2(),
.tx_i_3(),.tx_q_3(),
.txclk(clk64),.txstrobe(strobe_interp),
.clear_status(clear_status),
.tx_empty(tx_empty));
`endif
`ifdef TX_EN_0
tx_chain tx_chain_0
( .clock(clk64),.reset(tx_dsp_reset),.enable(enable_tx),
.interp_rate(interp_rate),.sample_strobe(tx_sample_strobe),
.interpolator_strobe(strobe_interp),.freq(),
.i_in(bb_tx_i0),.q_in(bb_tx_q0),.i_out(i_out_0),.q_out(q_out_0) );
`else
assign i_out_0=16'd0;
assign q_out_0=16'd0;
`endif
`ifdef TX_EN_1
tx_chain tx_chain_1
( .clock(clk64),.reset(tx_dsp_reset),.enable(enable_tx),
.interp_rate(interp_rate),.sample_strobe(tx_sample_strobe),
.interpolator_strobe(strobe_interp),.freq(),
.i_in(bb_tx_i1),.q_in(bb_tx_q1),.i_out(i_out_1),.q_out(q_out_1) );
`else
assign i_out_1=16'd0;
assign q_out_1=16'd0;
`endif
setting_reg #(`FR_TX_MUX)
sr_txmux(.clock(clk64),.reset(tx_dsp_reset),.strobe(serial_strobe),.addr(serial_addr),.in(serial_data),
.out({dac3mux,dac2mux,dac1mux,dac0mux,tx_realsignals,tx_numchan}));
wire [15:0] tx_a_a = dac0mux[3] ? (dac0mux[1] ? (dac0mux[0] ? q_out_1 : i_out_1) : (dac0mux[0] ? q_out_0 : i_out_0)) : 16'b0011111111111111;
wire [15:0] tx_b_a = dac1mux[3] ? (dac1mux[1] ? (dac1mux[0] ? q_out_1 : i_out_1) : (dac1mux[0] ? q_out_0 : i_out_0)) : 16'b0011111111111111;
//wire [15:0] tx_a_b = dac2mux[3] ? (dac2mux[1] ? (dac2mux[0] ? q_out_1 : i_out_1) : (dac2mux[0] ? q_out_0 : i_out_0)) : 16'b0;
//wire [15:0] tx_b_b = dac3mux[3] ? (dac3mux[1] ? (dac3mux[0] ? q_out_1 : i_out_1) : (dac3mux[0] ? q_out_0 : i_out_0)) : 16'b0;
wire txsync = tx_sample_strobe;
assign TXSYNC_A = txsync;
//assign TXSYNC_B = txsync;
assign tx_a = txsync ? tx_b_a[15:2] : tx_a_a[15:2];
//assign tx_b = txsync ? tx_b_b[15:2] : tx_a_b[15:2];
`endif // `ifdef TX_ON
/////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Receive Side
`ifdef RX_ON
wire rx_sample_strobe,strobe_decim,hb_strobe;
wire [15:0] bb_rx_i0,bb_rx_q0,bb_rx_i1,bb_rx_q1,
bb_rx_i2,bb_rx_q2,bb_rx_i3,bb_rx_q3;
wire loopback = settings[0];
wire counter = settings[1];
always @(posedge clk64)
if(rx_dsp_reset)
debug_counter <= #1 16'd0;
else if(~enable_rx)
debug_counter <= #1 16'd0;
else if(hb_strobe)
debug_counter <=#1 debug_counter + 16'd2;
always @(posedge clk64)
if(strobe_interp)
begin
loopback_i_0 <= #1 ch0tx;
loopback_q_0 <= #1 ch1tx;
end
assign ch0rx = bb_rx_i0;
assign ch1rx = bb_rx_q0;
assign ch2rx = bb_rx_i1;
assign ch3rx = bb_rx_q1;
assign ch4rx = bb_rx_i2;
assign ch5rx = bb_rx_q2;
assign ch6rx = bb_rx_i3;
assign ch7rx = bb_rx_q3;
wire [15:0] ddc0_in_i,ddc0_in_q,ddc1_in_i,ddc1_in_q,ddc2_in_i,ddc2_in_q,ddc3_in_i,ddc3_in_q;
adc_interface adc_interface(.clock(clk64),.reset(rx_dsp_reset),.enable(1'b1),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe),
.rx_a_a(rx_a_a),.rx_b_a(rx_b_a),.rx_a_b(rx_a_a),.rx_b_b(rx_b_a),
.rssi_0(rssi_0),.rssi_1(rssi_1),.rssi_2(rssi_2),.rssi_3(rssi_3),
.ddc0_in_i(ddc0_in_i),.ddc0_in_q(ddc0_in_q),
.ddc1_in_i(ddc1_in_i),.ddc1_in_q(ddc1_in_q),
.ddc2_in_i(ddc2_in_i),.ddc2_in_q(ddc2_in_q),
.ddc3_in_i(ddc3_in_i),.ddc3_in_q(ddc3_in_q),.rx_numchan(rx_numchan));
`ifdef RX_IN_BAND
rx_buffer_inband rx_buffer
( .usbclk(usbclk),.bus_reset(rx_bus_reset),.reset(rx_dsp_reset),
.reset_regs(rx_dsp_reset),
.usbdata(usbdata_out),.RD(RD),.have_pkt_rdy(have_pkt_rdy),.rx_overrun(rx_overrun),
.channels(rx_numchan),
.ch_0(ch0rx),.ch_1(ch1rx),
.ch_2(ch2rx),.ch_3(ch3rx),
.ch_4(ch4rx),.ch_5(ch5rx),
.ch_6(ch6rx),.ch_7(ch7rx),
.rxclk(clk64),.rxstrobe(hb_strobe),
.clear_status(clear_status),
.rx_WR(rx_WR),
.rx_databus(rx_databus),
.rx_WR_done(rx_WR_done),
.rx_WR_enabled(rx_WR_enabled),
.debugbus(rx_debugbus),
.rssi_0(rssi_0), .rssi_1(rssi_1), .rssi_2(rssi_2), .rssi_3(rssi_3),
.tx_underrun(tx_underrun));
`else
rx_buffer rx_buffer
( .usbclk(usbclk),.bus_reset(rx_bus_reset),.reset(rx_dsp_reset),
.reset_regs(rx_dsp_reset),
.usbdata(usbdata_out),.RD(RD),.have_pkt_rdy(have_pkt_rdy),.rx_overrun(rx_overrun),
.channels(rx_numchan),
.ch_0(ch0rx),.ch_1(ch1rx),
.ch_2(ch2rx),.ch_3(ch3rx),
.ch_4(ch4rx),.ch_5(ch5rx),
.ch_6(ch6rx),.ch_7(ch7rx),
.rxclk(clk64),.rxstrobe(hb_strobe),
.clear_status(clear_status),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe));
`endif
`ifdef RX_EN_0
rx_chain #(`FR_RX_FREQ_0,`FR_RX_PHASE_0) rx_chain_0
( .clock(clk64),.reset(1'b0),.enable(enable_rx),
.decim_rate(decim_rate),.sample_strobe(rx_sample_strobe),.decimator_strobe(strobe_decim),.hb_strobe(hb_strobe),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe),
.i_in(ddc0_in_i),.q_in(ddc0_in_q),.i_out(bb_rx_i0),.q_out(bb_rx_q0),.debugdata(debugdata),.debugctrl(debugctrl));
`else
assign bb_rx_i0=16'd0;
assign bb_rx_q0=16'd0;
`endif
`ifdef RX_EN_1
rx_chain #(`FR_RX_FREQ_1,`FR_RX_PHASE_1) rx_chain_1
( .clock(clk64),.reset(1'b0),.enable(enable_rx),
.decim_rate(decim_rate),.sample_strobe(rx_sample_strobe),.decimator_strobe(strobe_decim),.hb_strobe(),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe),
.i_in(ddc1_in_i),.q_in(ddc1_in_q),.i_out(bb_rx_i1),.q_out(bb_rx_q1));
`else
assign bb_rx_i1=16'd0;
assign bb_rx_q1=16'd0;
`endif
`ifdef RX_EN_2
rx_chain #(`FR_RX_FREQ_2,`FR_RX_PHASE_2) rx_chain_2
( .clock(clk64),.reset(1'b0),.enable(enable_rx),
.decim_rate(decim_rate),.sample_strobe(rx_sample_strobe),.decimator_strobe(strobe_decim),.hb_strobe(),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe),
.i_in(ddc2_in_i),.q_in(ddc2_in_q),.i_out(bb_rx_i2),.q_out(bb_rx_q2));
`else
assign bb_rx_i2=16'd0;
assign bb_rx_q2=16'd0;
`endif
`ifdef RX_EN_3
rx_chain #(`FR_RX_FREQ_3,`FR_RX_PHASE_3) rx_chain_3
( .clock(clk64),.reset(1'b0),.enable(enable_rx),
.decim_rate(decim_rate),.sample_strobe(rx_sample_strobe),.decimator_strobe(strobe_decim),.hb_strobe(),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe),
.i_in(ddc3_in_i),.q_in(ddc3_in_q),.i_out(bb_rx_i3),.q_out(bb_rx_q3));
`else
assign bb_rx_i3=16'd0;
assign bb_rx_q3=16'd0;
`endif
`endif // `ifdef RX_ON
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Control Functions
wire [31:0] capabilities;
assign capabilities[7] = `TX_CAP_HB;
assign capabilities[6:4] = `TX_CAP_NCHAN;
assign capabilities[3] = `RX_CAP_HB;
assign capabilities[2:0] = `RX_CAP_NCHAN;
serial_io serial_io
( .master_clk(clk64),.serial_clock(SCLK),.serial_data_in(SDI),
.enable(SEN_FPGA),.reset(1'b0),.serial_data_out(SDO),
.serial_addr(addr_db),.serial_data(data_db),.serial_strobe(strobe_db),
.readback_0({io_rx_a,io_tx_a}),.readback_1({io_rx_a,io_tx_a}),.readback_2(capabilities),.readback_3(32'hf0f0931a),
.readback_4(rssi_0),.readback_5(rssi_1),.readback_6(rssi_2),.readback_7(rssi_3)
);
//implementing freeze mode
/*
reg [15:0] timestop;
wire stop;
wire [15:0] stop_time;
assign clk64 = (timestop == 0) ? master_clk : 0;
always @(posedge master_clk)
if (timestop[15:0] != 0)
timestop <= timestop - 16'd1;
else if (stop)
timestop <= stop_time;
*/
master_control master_control
( .master_clk(clk64),.usbclk(usbclk),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe),
.tx_bus_reset(tx_bus_reset),.rx_bus_reset(rx_bus_reset),
.tx_dsp_reset(tx_dsp_reset),.rx_dsp_reset(rx_dsp_reset),
.enable_tx(enable_tx),.enable_rx(enable_rx),
.interp_rate(interp_rate),.decim_rate(decim_rate),
.tx_sample_strobe(tx_sample_strobe),.strobe_interp(strobe_interp),
.rx_sample_strobe(rx_sample_strobe),.strobe_decim(strobe_decim),
.tx_empty(tx_empty), .reg_0(reg_0),.reg_1(reg_1),.reg_2(reg_2),.reg_3(reg_3),
.atr_tx_delay(atr_tx_delay), .atr_rx_delay(atr_rx_delay),
.master_controls(master_controls), .debug_en(debug_en),
.atr_mask_0(atr_mask_0), .atr_txval_0(atr_txval_0), .atr_rxval_0(atr_rxval_0),
.atr_mask_1(atr_mask_1), .atr_txval_1(atr_txval_1), .atr_rxval_1(atr_rxval_1),
.atr_mask_2(atr_mask_2), .atr_txval_2(atr_txval_2), .atr_rxval_2(atr_rxval_2),
.atr_mask_3(atr_mask_3), .atr_txval_3(atr_txval_3), .atr_rxval_3(atr_rxval_3),
.txa_refclk(txa_refclk), .txb_refclk(txb_refclk), .rxa_refclk(rxa_refclk), .rxb_refclk(rxb_refclk),
.debug_0(tx_debugbus), .debug_1(rx_debugbus));
io_pins io_pins
(.io_0(io_tx_a),.io_1(io_rx_a),
.reg_0(reg_0),.reg_1(reg_1),
.clock(clk64),.rx_reset(rx_dsp_reset),.tx_reset(tx_dsp_reset),
.serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe));
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Misc Settings
setting_reg #(`FR_MODE) sr_misc(.clock(clk64),.reset(rx_dsp_reset),.strobe(serial_strobe),.addr(serial_addr),.in(serial_data),.out(settings));
reg forb;
always @(posedge usbclk)
begin
if (strobe_db) forb <= 1;
end
endmodule // usrp_inband_usb
|
/*
----------------------------------------------------------------------------------
Copyright (c) 2013-2014
Embedded and Network Computing Lab.
Open SSD Project
Hanyang University
All rights reserved.
----------------------------------------------------------------------------------
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. All advertising materials mentioning features or use of this source code
must display the following acknowledgement:
This product includes source code developed
by the Embedded and Network Computing Lab. and the Open SSD Project.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
----------------------------------------------------------------------------------
http://enclab.hanyang.ac.kr/
http://www.openssd-project.org/
http://www.hanyang.ac.kr/
----------------------------------------------------------------------------------
*/
`timescale 1ns / 1ps
module pcie_hcmd_slot_mgt
(
input pcie_user_clk,
input pcie_user_rst_n,
output hcmd_slot_rdy,
output [6:0] hcmd_slot_tag,
input hcmd_slot_alloc_en,
input hcmd_slot_free_en,
input [6:0] hcmd_slot_invalid_tag
);
localparam S_RESET_SEARCH_SLOT = 5'b00001;
localparam S_SEARCH_L1_SLOT = 5'b00010;
localparam S_SEARCH_L2_SLOT = 5'b00100;
localparam S_GNT_VAILD_SLOT = 5'b01000;
localparam S_VAILD_SLOT = 5'b10000;
reg [4:0] cur_state;
reg [4:0] next_state;
reg [127:0] r_slot_valid;
reg [127:0] r_slot_search_mask;
reg [127:0] r_slot_valid_mask;
reg [6:0] r_slot_tag;
reg r_slot_rdy;
reg [15:0] r_slot_l1_valid;
wire [7:0] w_slot_l1_mask;
wire r_slot_l1_ok;
//wire [7:0] w_slot_l2_valid;
wire [127:0] w_slot_l2_mask;
wire w_slot_l2_ok;
reg r_slot_free_en;
reg [6:0] r_slot_invalid_tag;
reg [127:0] r_slot_invalid_mask;
wire [127:0] w_slot_invalid_mask;
assign hcmd_slot_rdy = r_slot_rdy;
assign hcmd_slot_tag = r_slot_tag;
assign w_slot_l1_mask = { r_slot_search_mask[95],
r_slot_search_mask[79],
r_slot_search_mask[63],
r_slot_search_mask[47],
r_slot_search_mask[31],
r_slot_search_mask[15],
r_slot_search_mask[127],
r_slot_search_mask[111]};
always @ (*)
begin
case(w_slot_l1_mask) // synthesis parallel_case full_case
8'b00000001: r_slot_l1_valid <= r_slot_valid[15:0];
8'b00000010: r_slot_l1_valid <= r_slot_valid[31:16];
8'b00000100: r_slot_l1_valid <= r_slot_valid[47:32];
8'b00001000: r_slot_l1_valid <= r_slot_valid[63:48];
8'b00010000: r_slot_l1_valid <= r_slot_valid[79:64];
8'b00100000: r_slot_l1_valid <= r_slot_valid[95:80];
8'b01000000: r_slot_l1_valid <= r_slot_valid[111:96];
8'b10000000: r_slot_l1_valid <= r_slot_valid[127:112];
endcase
end
assign r_slot_l1_ok = (r_slot_l1_valid != 16'hFFFF);
assign w_slot_l2_mask = {r_slot_search_mask[126:0], r_slot_search_mask[127]};
assign w_slot_l2_ok = ((r_slot_valid & w_slot_l2_mask) == 0);
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0)
cur_state <= S_RESET_SEARCH_SLOT;
else
cur_state <= next_state;
end
always @ (*)
begin
case(cur_state)
S_RESET_SEARCH_SLOT: begin
next_state <= S_SEARCH_L1_SLOT;
end
S_SEARCH_L1_SLOT: begin
if(r_slot_l1_ok == 1)
next_state <= S_SEARCH_L2_SLOT;
else
next_state <= S_SEARCH_L1_SLOT;
end
S_SEARCH_L2_SLOT: begin
if(w_slot_l2_ok == 1)
next_state <= S_GNT_VAILD_SLOT;
else
next_state <= S_SEARCH_L2_SLOT;
end
S_GNT_VAILD_SLOT: begin
if(hcmd_slot_alloc_en == 1)
next_state <= S_VAILD_SLOT;
else
next_state <= S_GNT_VAILD_SLOT;
end
S_VAILD_SLOT: begin
next_state <= S_RESET_SEARCH_SLOT;
end
default: begin
next_state <= S_RESET_SEARCH_SLOT;
end
endcase
end
always @ (posedge pcie_user_clk)
begin
case(cur_state)
S_RESET_SEARCH_SLOT: begin
r_slot_search_mask[127:112] <= 0;
r_slot_search_mask[111] <= 1'b1;
r_slot_search_mask[110:0] <= 0;
r_slot_tag <= 7'h6F;
end
S_SEARCH_L1_SLOT: begin
r_slot_search_mask[111] <= w_slot_l1_mask[7];
r_slot_search_mask[95] <= w_slot_l1_mask[6];
r_slot_search_mask[79] <= w_slot_l1_mask[5];
r_slot_search_mask[63] <= w_slot_l1_mask[4];
r_slot_search_mask[47] <= w_slot_l1_mask[3];
r_slot_search_mask[31] <= w_slot_l1_mask[2];
r_slot_search_mask[15] <= w_slot_l1_mask[1];
r_slot_search_mask[127] <= w_slot_l1_mask[0];
r_slot_tag <= r_slot_tag + 16;
end
S_SEARCH_L2_SLOT: begin
r_slot_search_mask <= w_slot_l2_mask;
r_slot_tag <= r_slot_tag + 1;
end
S_GNT_VAILD_SLOT: begin
end
S_VAILD_SLOT: begin
end
default: begin
end
endcase
end
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0) begin
r_slot_valid <= 0;
end
else begin
r_slot_valid <= (r_slot_valid | r_slot_valid_mask) & r_slot_invalid_mask;
//r_slot_valid <= (r_slot_valid | r_slot_valid_mask);
end
end
always @ (*)
begin
case(cur_state)
S_RESET_SEARCH_SLOT: begin
r_slot_rdy <= 0;
r_slot_valid_mask <= 0;
end
S_SEARCH_L1_SLOT: begin
r_slot_rdy <= 0;
r_slot_valid_mask <= 0;
end
S_SEARCH_L2_SLOT: begin
r_slot_rdy <= 0;
r_slot_valid_mask <= 0;
end
S_GNT_VAILD_SLOT: begin
r_slot_rdy <= 1;
r_slot_valid_mask <= 0;
end
S_VAILD_SLOT: begin
r_slot_rdy <= 0;
r_slot_valid_mask <= r_slot_search_mask;
end
default: begin
r_slot_rdy <= 0;
r_slot_valid_mask <= 0;
end
endcase
end
always @ (posedge pcie_user_clk)
begin
r_slot_free_en <= hcmd_slot_free_en;
r_slot_invalid_tag <= hcmd_slot_invalid_tag;
if(r_slot_free_en == 1)
r_slot_invalid_mask <= w_slot_invalid_mask;
else
r_slot_invalid_mask <= {128{1'b1}};
end
genvar i;
generate
for(i = 0; i < 128; i = i + 1)
begin : INVALID_TAG
assign w_slot_invalid_mask[i] = (r_slot_invalid_tag != i);
end
endgenerate
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2009 by Wilson Snyder.
module t (/*AUTOARG*/);
// IEEE: integer_atom_type
byte d_byte;
shortint d_shortint;
int d_int;
longint d_longint;
integer d_integer;
time d_time;
chandle d_chandle;
// IEEE: integer_atom_type
bit d_bit;
logic d_logic;
reg d_reg;
bit [0:0] d_bit1;
logic [0:0] d_logic1;
reg [0:0] d_reg1;
bit d_bitz;
logic d_logicz;
reg d_regz;
// IEEE: non_integer_type
//UNSUP shortreal d_shortreal;
real d_real;
realtime d_realtime;
initial begin
// below errors might cause spurious warnings
// verilator lint_off WIDTH
d_bitz[0] = 1'b1; // Illegal range
d_logicz[0] = 1'b1; // Illegal range
d_regz[0] = 1'b1; // Illegal range
`ifndef VERILATOR //UNSUPPORTED, it's just a 64 bit int right now
d_chandle[0] = 1'b1; // Illegal
`endif
d_real[0] = 1'b1; // Illegal
d_realtime[0] = 1'b1; // Illegal
// verilator lint_on WIDTH
d_byte[0] = 1'b1; // OK
d_shortint[0] = 1'b1; // OK
d_int[0] = 1'b1; // OK
d_longint[0] = 1'b1; // OK
d_integer[0] = 1'b1; // OK
d_time[0] = 1'b1; // OK
d_bit1[0] = 1'b1; // OK
d_logic1[0] = 1'b1; // OK
d_reg1[0] = 1'b1; // OK
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2009 by Wilson Snyder.
module t (/*AUTOARG*/);
// IEEE: integer_atom_type
byte d_byte;
shortint d_shortint;
int d_int;
longint d_longint;
integer d_integer;
time d_time;
chandle d_chandle;
// IEEE: integer_atom_type
bit d_bit;
logic d_logic;
reg d_reg;
bit [0:0] d_bit1;
logic [0:0] d_logic1;
reg [0:0] d_reg1;
bit d_bitz;
logic d_logicz;
reg d_regz;
// IEEE: non_integer_type
//UNSUP shortreal d_shortreal;
real d_real;
realtime d_realtime;
initial begin
// below errors might cause spurious warnings
// verilator lint_off WIDTH
d_bitz[0] = 1'b1; // Illegal range
d_logicz[0] = 1'b1; // Illegal range
d_regz[0] = 1'b1; // Illegal range
`ifndef VERILATOR //UNSUPPORTED, it's just a 64 bit int right now
d_chandle[0] = 1'b1; // Illegal
`endif
d_real[0] = 1'b1; // Illegal
d_realtime[0] = 1'b1; // Illegal
// verilator lint_on WIDTH
d_byte[0] = 1'b1; // OK
d_shortint[0] = 1'b1; // OK
d_int[0] = 1'b1; // OK
d_longint[0] = 1'b1; // OK
d_integer[0] = 1'b1; // OK
d_time[0] = 1'b1; // OK
d_bit1[0] = 1'b1; // OK
d_logic1[0] = 1'b1; // OK
d_reg1[0] = 1'b1; // OK
end
endmodule
|
/*
----------------------------------------------------------------------------------
Copyright (c) 2013-2014
Embedded and Network Computing Lab.
Open SSD Project
Hanyang University
All rights reserved.
----------------------------------------------------------------------------------
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. All advertising materials mentioning features or use of this source code
must display the following acknowledgement:
This product includes source code developed
by the Embedded and Network Computing Lab. and the Open SSD Project.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
----------------------------------------------------------------------------------
http://enclab.hanyang.ac.kr/
http://www.openssd-project.org/
http://www.hanyang.ac.kr/
----------------------------------------------------------------------------------
*/
`timescale 1ns / 1ps
module pcie_fc_cntl
(
//PCIe user clock
input pcie_user_clk,
input pcie_user_rst_n,
// Flow Control
input [11:0] fc_cpld,
input [7:0] fc_cplh,
input [11:0] fc_npd,
input [7:0] fc_nph,
input [11:0] fc_pd,
input [7:0] fc_ph,
output [2:0] fc_sel,
input tx_cfg_req,
output tx_cfg_gnt,
input [5:0] tx_buf_av,
output tx_cpld_gnt,
output tx_mrd_gnt,
output tx_mwr_gnt
);
parameter P_RX_CONSTRAINT_FC_CPLD = 32;
parameter P_RX_CONSTRAINT_FC_CPLH = 8;
parameter P_TX_CONSTRAINT_FC_CPLD = 1;
parameter P_TX_CONSTRAINT_FC_CPLH = 1;
parameter P_TX_CONSTRAINT_FC_NPD = 1;
parameter P_TX_CONSTRAINT_FC_NPH = 1;
parameter P_TX_CONSTRAINT_FC_PD = 32;
parameter P_TX_CONSTRAINT_FC_PH = 1;
localparam S_RX_AVAILABLE_FC_SEL = 2'b01;
localparam S_TX_AVAILABLE_FC_SEL = 2'b10;
reg [1:0] cur_state;
reg [1:0] next_state;
reg [11:0] r_rx_available_fc_cpld;
reg [7:0] r_rx_available_fc_cplh;
reg [11:0] r_rx_available_fc_npd;
reg [7:0] r_rx_available_fc_nph;
reg [11:0] r_rx_available_fc_pd;
reg [7:0] r_rx_available_fc_ph;
reg [11:0] r_tx_available_fc_cpld;
reg [7:0] r_tx_available_fc_cplh;
reg [11:0] r_tx_available_fc_npd;
reg [7:0] r_tx_available_fc_nph;
reg [11:0] r_tx_available_fc_pd;
reg [7:0] r_tx_available_fc_ph;
wire w_rx_available_fc_cpld;
wire w_rx_available_fc_cplh;
wire w_tx_available_fc_cpld;
wire w_tx_available_fc_cplh;
wire w_tx_available_fc_npd;
wire w_tx_available_fc_nph;
wire w_tx_available_fc_pd;
wire w_tx_available_fc_ph;
reg [2:0] r_fc_sel;
reg [1:0] r_rd_fc_sel;
reg [1:0] r_rd_fc_sel_d1;
reg [1:0] r_rd_fc_sel_d2;
reg r_tx_cpld_gnt;
reg r_tx_mrd_gnt;
reg r_tx_mwr_gnt;
assign fc_sel = r_fc_sel;
assign tx_cfg_gnt = 1'b1;
assign tx_cpld_gnt = r_tx_cpld_gnt;
assign tx_mrd_gnt = r_tx_mrd_gnt;
assign tx_mwr_gnt = r_tx_mwr_gnt;
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0)
cur_state <= S_RX_AVAILABLE_FC_SEL;
else
cur_state <= next_state;
end
always @ (*)
begin
case(cur_state)
S_RX_AVAILABLE_FC_SEL: begin
next_state <= S_TX_AVAILABLE_FC_SEL;
end
S_TX_AVAILABLE_FC_SEL: begin
next_state <= S_RX_AVAILABLE_FC_SEL;
end
default: begin
next_state <= S_RX_AVAILABLE_FC_SEL;
end
endcase
end
always @ (*)
begin
case(cur_state)
S_RX_AVAILABLE_FC_SEL: begin
r_fc_sel <= 3'b000;
r_rd_fc_sel <= 2'b01;
end
S_TX_AVAILABLE_FC_SEL: begin
r_fc_sel <= 3'b100;
r_rd_fc_sel <= 2'b10;
end
default: begin
r_fc_sel <= 3'b000;
r_rd_fc_sel <= 2'b00;
end
endcase
end
assign w_rx_available_fc_cpld = (r_rx_available_fc_cpld > P_RX_CONSTRAINT_FC_CPLD);
assign w_rx_available_fc_cplh = (r_rx_available_fc_cplh > P_RX_CONSTRAINT_FC_CPLH);
assign w_tx_available_fc_cpld = (r_tx_available_fc_cpld > P_TX_CONSTRAINT_FC_CPLD);
assign w_tx_available_fc_cplh = (r_tx_available_fc_cplh > P_TX_CONSTRAINT_FC_CPLH);
assign w_tx_available_fc_npd = (r_tx_available_fc_npd > P_TX_CONSTRAINT_FC_NPD);
assign w_tx_available_fc_nph = (r_tx_available_fc_nph > P_TX_CONSTRAINT_FC_NPH);
assign w_tx_available_fc_pd = (r_tx_available_fc_pd > P_TX_CONSTRAINT_FC_PD);
assign w_tx_available_fc_ph = (r_tx_available_fc_ph > P_TX_CONSTRAINT_FC_PH);
always @ (posedge pcie_user_clk)
begin
r_tx_cpld_gnt <= w_tx_available_fc_cpld & w_tx_available_fc_cplh;
r_tx_mrd_gnt <= (w_tx_available_fc_npd & w_tx_available_fc_nph) & (w_rx_available_fc_cpld & w_rx_available_fc_cplh);
r_tx_mwr_gnt <= w_tx_available_fc_pd & w_tx_available_fc_ph;
end
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0) begin
r_rd_fc_sel_d1 <= 0;
r_rd_fc_sel_d2 <= 0;
end
else begin
r_rd_fc_sel_d1 <= r_rd_fc_sel;
r_rd_fc_sel_d2 <= r_rd_fc_sel_d1;
end
end
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0) begin
r_rx_available_fc_cpld <= 0;
r_rx_available_fc_cplh <= 0;
r_rx_available_fc_npd <= 0;
r_rx_available_fc_nph <= 0;
r_rx_available_fc_pd <= 0;
r_rx_available_fc_ph <= 0;
r_tx_available_fc_cpld <= 0;
r_tx_available_fc_cplh <= 0;
r_tx_available_fc_npd <= 0;
r_tx_available_fc_nph <= 0;
r_tx_available_fc_pd <= 0;
r_tx_available_fc_ph <= 0;
end
else begin
if(r_rd_fc_sel_d2[0] == 1) begin
r_rx_available_fc_cpld <= fc_cpld;
r_rx_available_fc_cplh <= fc_cplh;
r_rx_available_fc_npd <= fc_npd;
r_rx_available_fc_nph <= fc_nph;
r_rx_available_fc_pd <= fc_pd;
r_rx_available_fc_ph <= fc_ph;
end
if(r_rd_fc_sel_d2[1] == 1) begin
r_tx_available_fc_cpld <= fc_cpld;
r_tx_available_fc_cplh <= fc_cplh;
r_tx_available_fc_npd <= fc_npd;
r_tx_available_fc_nph <= fc_nph;
r_tx_available_fc_pd <= fc_pd;
r_tx_available_fc_ph <= fc_ph;
end
end
end
/*
parameter P_RX_AVAILABLE_FC_CPLD = 36;
parameter P_RX_AVAILABLE_FC_CPLH = 36;
parameter P_TX_AVAILABLE_FC_CPLD = 36;
parameter P_TX_AVAILABLE_FC_CPLH = 36;
parameter P_TX_AVAILABLE_FC_NPD = 36;
parameter P_TX_AVAILABLE_FC_NPH = 36;
parameter P_TX_AVAILABLE_FC_PD = 36;
parameter P_TX_AVAILABLE_FC_PH = 36;
reg [11:0] r_rx_available_fc_cpld;
reg [7:0] r_rx_available_fc_cplh;
reg [11:0] r_rx_available_fc_npd;
reg [7:0] r_rx_available_fc_nph;
reg [11:0] r_rx_available_fc_pd;
reg [7:0] r_rx_available_fc_ph;
reg [11:0] r_rx_limit_fc_cpld;
reg [7:0] r_rx_limit_fc_cplh;
reg [11:0] r_rx_limit_fc_npd;
reg [7:0] r_rx_limit_fc_nph;
reg [11:0] r_rx_limit_fc_pd;
reg [7:0] r_rx_limit_fc_ph;
reg [11:0] r_rx_consumed_fc_cpld;
reg [7:0] r_rx_consumed_fc_cplh;
reg [11:0] r_rx_consumed_fc_npd;
reg [7:0] r_rx_consumed_fc_nph;
reg [11:0] r_rx_consumed_fc_pd;
reg [7:0] r_rx_consumed_fc_ph;
reg [11:0] r_tx_available_fc_cpld;
reg [7:0] r_tx_available_fc_cplh;
reg [11:0] r_tx_available_fc_npd;
reg [7:0] r_tx_available_fc_nph;
reg [11:0] r_tx_available_fc_pd;
reg [7:0] r_tx_available_fc_ph;
reg [11:0] r_tx_limit_fc_cpld;
reg [7:0] r_tx_limit_fc_cplh;
reg [11:0] r_tx_limit_fc_npd;
reg [7:0] r_tx_limit_fc_nph;
reg [11:0] r_tx_limit_fc_pd;
reg [7:0] r_tx_limit_fc_ph;
reg [11:0] r_tx_consumed_fc_cpld;
reg [7:0] r_tx_consumed_fc_cplh;
reg [11:0] r_tx_consumed_fc_npd;
reg [7:0] r_tx_consumed_fc_nph;
reg [11:0] r_tx_consumed_fc_pd;
reg [7:0] r_tx_consumed_fc_ph;
reg [2:0] r_fc_sel;
reg [5:0] r_rd_fc_sel;
reg [5:0] r_rd_fc_sel_d1;
reg [5:0] r_rd_fc_sel_d2;
reg r_tx_cpld_gnt;
reg r_tx_mrd_gnt;
reg r_tx_mwr_gnt;
assign tx_cfg_gnt = 1'b1;
assign tx_cpld_gnt = r_tx_cpld_gnt;
assign tx_mrd_gnt = r_tx_mrd_gnt;
assign tx_mwr_gnt = r_tx_mwr_gnt;
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0)
cur_state <= S_RX_AVAILABLE_FC_SEL;
else
cur_state <= next_state;
end
always @ (*)
begin
case(cur_state)
S_RX_AVAILABLE_FC_SEL: begin
next_state <= S_RX_LITMIT_FC_SEL;
end
S_RX_LITMIT_FC_SEL: begin
next_state <= S_RX_CONSUMED_FC_SEL;
end
S_RX_CONSUMED_FC_SEL: begin
next_state <= S_TX_AVAILABLE_FC_SEL;
end
S_TX_AVAILABLE_FC_SEL: begin
next_state <= S_TX_LITMIT_FC_SEL;
end
S_TX_LITMIT_FC_SEL: begin
next_state <= S_TX_CONSUMED_FC_SEL;
end
S_TX_CONSUMED_FC_SEL: begin
next_state <= S_RX_AVAILABLE_FC_SEL;
end
default: begin
next_state <= S_RX_AVAILABLE_FC_SEL;
end
endcase
end
always @ (*)
begin
case(cur_state)
S_RX_AVAILABLE_FC_SEL: begin
r_fc_sel <= 3'b000;
r_rd_fc_sel <= 6'b000001;
end
S_RX_LITMIT_FC_SEL: begin
r_fc_sel <= 3'b001;
r_rd_fc_sel <= 6'b000010;
end
S_RX_CONSUMED_FC_SEL: begin
r_fc_sel <= 3'b010;
r_rd_fc_sel <= 6'b000100;
end
S_TX_AVAILABLE_FC_SEL: begi
r_fc_sel <= 3'b100;
r_rd_fc_sel <= 6'b001000;
end
S_TX_LITMIT_FC_SEL: begin
r_fc_sel <= 3'b101;
r_rd_fc_sel <= 6'b010000;
end
S_TX_CONSUMED_FC_SEL: begin
r_fc_sel <= 3'b110;
r_rd_fc_sel <= 6'b100000;
end
default: begin
r_fc_sel <= 3'b000;
r_rd_fc_sel <= 6'b000000;
end
endcase
end
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
r_tx_cpld_gnt;
r_tx_mrd_gnt;
r_tx_mwr_gnt;
end
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0) begin
r_rd_fc_sel_d1 <= 0;
r_rd_fc_sel_d2 <= 0;
end
else begin
r_rd_fc_sel_d1 <= r_rd_fc_sel;
r_rd_fc_sel_d2 <= r_rd_fc_sel_d1;
end
end
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0) begin
r_rx_available_fc_cpld <= 0;
r_rx_available_fc_cplh <= 0;
r_rx_available_fc_npd <= 0;
r_rx_available_fc_nph <= 0;
r_rx_available_fc_pd <= 0;
r_rx_available_fc_ph <= 0;
r_rx_limit_fc_cpld <= 0;
r_rx_limit_fc_cplh <= 0;
r_rx_limit_fc_npd <= 0;
r_rx_limit_fc_nph <= 0;
r_rx_limit_fc_pd <= 0;
r_rx_limit_fc_ph <= 0;
r_rx_consumed_fc_cpld <= 0;
r_rx_consumed_fc_cplh <= 0;
r_rx_consumed_fc_npd <= 0;
r_rx_consumed_fc_nph <= 0;
r_rx_consumed_fc_pd <= 0;
r_rx_consumed_fc_ph <= 0;
r_tx_available_fc_cpld <= 0;
r_tx_available_fc_cplh <= 0;
r_tx_available_fc_npd <= 0;
r_tx_available_fc_nph <= 0;
r_tx_available_fc_pd <= 0;
r_tx_available_fc_ph <= 0;
r_tx_limit_fc_cpld <= 0;
r_tx_limit_fc_cplh <= 0;
r_tx_limit_fc_npd <= 0;
r_tx_limit_fc_nph <= 0;
r_tx_limit_fc_pd <= 0;
r_tx_limit_fc_ph <= 0;
r_tx_consumed_fc_cpld <= 0;
r_tx_consumed_fc_cplh <= 0;
r_tx_consumed_fc_npd <= 0;
r_tx_consumed_fc_nph <= 0;
r_tx_consumed_fc_pd <= 0;
r_tx_consumed_fc_ph <= 0;
end
else begin
if(r_rd_fc_sel_d2[0] == 1) begin
r_rx_available_fc_cpld <= fc_cpld;
r_rx_available_fc_cplh <= fc_cplh;
r_rx_available_fc_npd <= fc_npd;
r_rx_available_fc_nph <= fc_nph;
r_rx_available_fc_pd <= fc_pd;
r_rx_available_fc_ph <= fc_ph;
end
if(r_rd_fc_sel_d2[1] == 1) begin
r_rx_limit_fc_cpld <= fc_cpld;
r_rx_limit_fc_cplh <= fc_cplh;
r_rx_limit_fc_npd <= fc_npd;
r_rx_limit_fc_nph <= fc_nph;
r_rx_limit_fc_pd <= fc_pd;
r_rx_limit_fc_ph <= fc_ph;
end
if(r_rd_fc_sel_d2[2] == 1) begin
r_rx_consumed_fc_cpld <= fc_cpld;
r_rx_consumed_fc_cplh <= fc_cplh;
r_rx_consumed_fc_npd <= fc_npd;
r_rx_consumed_fc_nph <= fc_nph;
r_rx_consumed_fc_pd <= fc_pd;
r_rx_consumed_fc_ph <= fc_ph;
end
if(r_rd_fc_sel_d2[3] == 1) begin
r_tx_available_fc_cpld <= fc_cpld;
r_tx_available_fc_cplh <= fc_cplh;
r_tx_available_fc_npd <= fc_npd;
r_tx_available_fc_nph <= fc_nph;
r_tx_available_fc_pd <= fc_pd;
r_tx_available_fc_ph <= fc_ph;
end
if(r_rd_fc_sel_d2[4] == 1) begin
r_tx_limit_fc_cpld <= fc_cpld;
r_tx_limit_fc_cplh <= fc_cplh;
r_tx_limit_fc_npd <= fc_npd;
r_tx_limit_fc_nph <= fc_nph;
r_tx_limit_fc_pd <= fc_pd;
r_tx_limit_fc_ph <= fc_ph;
end
if(r_rd_fc_sel_d2[5] == 1) begin
r_tx_consumed_fc_cpld <= fc_cpld;
r_tx_consumed_fc_cplh <= fc_cplh;
r_tx_consumed_fc_npd <= fc_npd;
r_tx_consumed_fc_nph <= fc_nph;
r_tx_consumed_fc_pd <= fc_pd;
r_tx_consumed_fc_ph <= fc_ph;
end
end
end
*/
endmodule
|
/*
----------------------------------------------------------------------------------
Copyright (c) 2013-2014
Embedded and Network Computing Lab.
Open SSD Project
Hanyang University
All rights reserved.
----------------------------------------------------------------------------------
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. All advertising materials mentioning features or use of this source code
must display the following acknowledgement:
This product includes source code developed
by the Embedded and Network Computing Lab. and the Open SSD Project.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
----------------------------------------------------------------------------------
http://enclab.hanyang.ac.kr/
http://www.openssd-project.org/
http://www.hanyang.ac.kr/
----------------------------------------------------------------------------------
*/
`timescale 1ns / 1ps
module pcie_fc_cntl
(
//PCIe user clock
input pcie_user_clk,
input pcie_user_rst_n,
// Flow Control
input [11:0] fc_cpld,
input [7:0] fc_cplh,
input [11:0] fc_npd,
input [7:0] fc_nph,
input [11:0] fc_pd,
input [7:0] fc_ph,
output [2:0] fc_sel,
input tx_cfg_req,
output tx_cfg_gnt,
input [5:0] tx_buf_av,
output tx_cpld_gnt,
output tx_mrd_gnt,
output tx_mwr_gnt
);
parameter P_RX_CONSTRAINT_FC_CPLD = 32;
parameter P_RX_CONSTRAINT_FC_CPLH = 8;
parameter P_TX_CONSTRAINT_FC_CPLD = 1;
parameter P_TX_CONSTRAINT_FC_CPLH = 1;
parameter P_TX_CONSTRAINT_FC_NPD = 1;
parameter P_TX_CONSTRAINT_FC_NPH = 1;
parameter P_TX_CONSTRAINT_FC_PD = 32;
parameter P_TX_CONSTRAINT_FC_PH = 1;
localparam S_RX_AVAILABLE_FC_SEL = 2'b01;
localparam S_TX_AVAILABLE_FC_SEL = 2'b10;
reg [1:0] cur_state;
reg [1:0] next_state;
reg [11:0] r_rx_available_fc_cpld;
reg [7:0] r_rx_available_fc_cplh;
reg [11:0] r_rx_available_fc_npd;
reg [7:0] r_rx_available_fc_nph;
reg [11:0] r_rx_available_fc_pd;
reg [7:0] r_rx_available_fc_ph;
reg [11:0] r_tx_available_fc_cpld;
reg [7:0] r_tx_available_fc_cplh;
reg [11:0] r_tx_available_fc_npd;
reg [7:0] r_tx_available_fc_nph;
reg [11:0] r_tx_available_fc_pd;
reg [7:0] r_tx_available_fc_ph;
wire w_rx_available_fc_cpld;
wire w_rx_available_fc_cplh;
wire w_tx_available_fc_cpld;
wire w_tx_available_fc_cplh;
wire w_tx_available_fc_npd;
wire w_tx_available_fc_nph;
wire w_tx_available_fc_pd;
wire w_tx_available_fc_ph;
reg [2:0] r_fc_sel;
reg [1:0] r_rd_fc_sel;
reg [1:0] r_rd_fc_sel_d1;
reg [1:0] r_rd_fc_sel_d2;
reg r_tx_cpld_gnt;
reg r_tx_mrd_gnt;
reg r_tx_mwr_gnt;
assign fc_sel = r_fc_sel;
assign tx_cfg_gnt = 1'b1;
assign tx_cpld_gnt = r_tx_cpld_gnt;
assign tx_mrd_gnt = r_tx_mrd_gnt;
assign tx_mwr_gnt = r_tx_mwr_gnt;
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0)
cur_state <= S_RX_AVAILABLE_FC_SEL;
else
cur_state <= next_state;
end
always @ (*)
begin
case(cur_state)
S_RX_AVAILABLE_FC_SEL: begin
next_state <= S_TX_AVAILABLE_FC_SEL;
end
S_TX_AVAILABLE_FC_SEL: begin
next_state <= S_RX_AVAILABLE_FC_SEL;
end
default: begin
next_state <= S_RX_AVAILABLE_FC_SEL;
end
endcase
end
always @ (*)
begin
case(cur_state)
S_RX_AVAILABLE_FC_SEL: begin
r_fc_sel <= 3'b000;
r_rd_fc_sel <= 2'b01;
end
S_TX_AVAILABLE_FC_SEL: begin
r_fc_sel <= 3'b100;
r_rd_fc_sel <= 2'b10;
end
default: begin
r_fc_sel <= 3'b000;
r_rd_fc_sel <= 2'b00;
end
endcase
end
assign w_rx_available_fc_cpld = (r_rx_available_fc_cpld > P_RX_CONSTRAINT_FC_CPLD);
assign w_rx_available_fc_cplh = (r_rx_available_fc_cplh > P_RX_CONSTRAINT_FC_CPLH);
assign w_tx_available_fc_cpld = (r_tx_available_fc_cpld > P_TX_CONSTRAINT_FC_CPLD);
assign w_tx_available_fc_cplh = (r_tx_available_fc_cplh > P_TX_CONSTRAINT_FC_CPLH);
assign w_tx_available_fc_npd = (r_tx_available_fc_npd > P_TX_CONSTRAINT_FC_NPD);
assign w_tx_available_fc_nph = (r_tx_available_fc_nph > P_TX_CONSTRAINT_FC_NPH);
assign w_tx_available_fc_pd = (r_tx_available_fc_pd > P_TX_CONSTRAINT_FC_PD);
assign w_tx_available_fc_ph = (r_tx_available_fc_ph > P_TX_CONSTRAINT_FC_PH);
always @ (posedge pcie_user_clk)
begin
r_tx_cpld_gnt <= w_tx_available_fc_cpld & w_tx_available_fc_cplh;
r_tx_mrd_gnt <= (w_tx_available_fc_npd & w_tx_available_fc_nph) & (w_rx_available_fc_cpld & w_rx_available_fc_cplh);
r_tx_mwr_gnt <= w_tx_available_fc_pd & w_tx_available_fc_ph;
end
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0) begin
r_rd_fc_sel_d1 <= 0;
r_rd_fc_sel_d2 <= 0;
end
else begin
r_rd_fc_sel_d1 <= r_rd_fc_sel;
r_rd_fc_sel_d2 <= r_rd_fc_sel_d1;
end
end
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0) begin
r_rx_available_fc_cpld <= 0;
r_rx_available_fc_cplh <= 0;
r_rx_available_fc_npd <= 0;
r_rx_available_fc_nph <= 0;
r_rx_available_fc_pd <= 0;
r_rx_available_fc_ph <= 0;
r_tx_available_fc_cpld <= 0;
r_tx_available_fc_cplh <= 0;
r_tx_available_fc_npd <= 0;
r_tx_available_fc_nph <= 0;
r_tx_available_fc_pd <= 0;
r_tx_available_fc_ph <= 0;
end
else begin
if(r_rd_fc_sel_d2[0] == 1) begin
r_rx_available_fc_cpld <= fc_cpld;
r_rx_available_fc_cplh <= fc_cplh;
r_rx_available_fc_npd <= fc_npd;
r_rx_available_fc_nph <= fc_nph;
r_rx_available_fc_pd <= fc_pd;
r_rx_available_fc_ph <= fc_ph;
end
if(r_rd_fc_sel_d2[1] == 1) begin
r_tx_available_fc_cpld <= fc_cpld;
r_tx_available_fc_cplh <= fc_cplh;
r_tx_available_fc_npd <= fc_npd;
r_tx_available_fc_nph <= fc_nph;
r_tx_available_fc_pd <= fc_pd;
r_tx_available_fc_ph <= fc_ph;
end
end
end
/*
parameter P_RX_AVAILABLE_FC_CPLD = 36;
parameter P_RX_AVAILABLE_FC_CPLH = 36;
parameter P_TX_AVAILABLE_FC_CPLD = 36;
parameter P_TX_AVAILABLE_FC_CPLH = 36;
parameter P_TX_AVAILABLE_FC_NPD = 36;
parameter P_TX_AVAILABLE_FC_NPH = 36;
parameter P_TX_AVAILABLE_FC_PD = 36;
parameter P_TX_AVAILABLE_FC_PH = 36;
reg [11:0] r_rx_available_fc_cpld;
reg [7:0] r_rx_available_fc_cplh;
reg [11:0] r_rx_available_fc_npd;
reg [7:0] r_rx_available_fc_nph;
reg [11:0] r_rx_available_fc_pd;
reg [7:0] r_rx_available_fc_ph;
reg [11:0] r_rx_limit_fc_cpld;
reg [7:0] r_rx_limit_fc_cplh;
reg [11:0] r_rx_limit_fc_npd;
reg [7:0] r_rx_limit_fc_nph;
reg [11:0] r_rx_limit_fc_pd;
reg [7:0] r_rx_limit_fc_ph;
reg [11:0] r_rx_consumed_fc_cpld;
reg [7:0] r_rx_consumed_fc_cplh;
reg [11:0] r_rx_consumed_fc_npd;
reg [7:0] r_rx_consumed_fc_nph;
reg [11:0] r_rx_consumed_fc_pd;
reg [7:0] r_rx_consumed_fc_ph;
reg [11:0] r_tx_available_fc_cpld;
reg [7:0] r_tx_available_fc_cplh;
reg [11:0] r_tx_available_fc_npd;
reg [7:0] r_tx_available_fc_nph;
reg [11:0] r_tx_available_fc_pd;
reg [7:0] r_tx_available_fc_ph;
reg [11:0] r_tx_limit_fc_cpld;
reg [7:0] r_tx_limit_fc_cplh;
reg [11:0] r_tx_limit_fc_npd;
reg [7:0] r_tx_limit_fc_nph;
reg [11:0] r_tx_limit_fc_pd;
reg [7:0] r_tx_limit_fc_ph;
reg [11:0] r_tx_consumed_fc_cpld;
reg [7:0] r_tx_consumed_fc_cplh;
reg [11:0] r_tx_consumed_fc_npd;
reg [7:0] r_tx_consumed_fc_nph;
reg [11:0] r_tx_consumed_fc_pd;
reg [7:0] r_tx_consumed_fc_ph;
reg [2:0] r_fc_sel;
reg [5:0] r_rd_fc_sel;
reg [5:0] r_rd_fc_sel_d1;
reg [5:0] r_rd_fc_sel_d2;
reg r_tx_cpld_gnt;
reg r_tx_mrd_gnt;
reg r_tx_mwr_gnt;
assign tx_cfg_gnt = 1'b1;
assign tx_cpld_gnt = r_tx_cpld_gnt;
assign tx_mrd_gnt = r_tx_mrd_gnt;
assign tx_mwr_gnt = r_tx_mwr_gnt;
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0)
cur_state <= S_RX_AVAILABLE_FC_SEL;
else
cur_state <= next_state;
end
always @ (*)
begin
case(cur_state)
S_RX_AVAILABLE_FC_SEL: begin
next_state <= S_RX_LITMIT_FC_SEL;
end
S_RX_LITMIT_FC_SEL: begin
next_state <= S_RX_CONSUMED_FC_SEL;
end
S_RX_CONSUMED_FC_SEL: begin
next_state <= S_TX_AVAILABLE_FC_SEL;
end
S_TX_AVAILABLE_FC_SEL: begin
next_state <= S_TX_LITMIT_FC_SEL;
end
S_TX_LITMIT_FC_SEL: begin
next_state <= S_TX_CONSUMED_FC_SEL;
end
S_TX_CONSUMED_FC_SEL: begin
next_state <= S_RX_AVAILABLE_FC_SEL;
end
default: begin
next_state <= S_RX_AVAILABLE_FC_SEL;
end
endcase
end
always @ (*)
begin
case(cur_state)
S_RX_AVAILABLE_FC_SEL: begin
r_fc_sel <= 3'b000;
r_rd_fc_sel <= 6'b000001;
end
S_RX_LITMIT_FC_SEL: begin
r_fc_sel <= 3'b001;
r_rd_fc_sel <= 6'b000010;
end
S_RX_CONSUMED_FC_SEL: begin
r_fc_sel <= 3'b010;
r_rd_fc_sel <= 6'b000100;
end
S_TX_AVAILABLE_FC_SEL: begi
r_fc_sel <= 3'b100;
r_rd_fc_sel <= 6'b001000;
end
S_TX_LITMIT_FC_SEL: begin
r_fc_sel <= 3'b101;
r_rd_fc_sel <= 6'b010000;
end
S_TX_CONSUMED_FC_SEL: begin
r_fc_sel <= 3'b110;
r_rd_fc_sel <= 6'b100000;
end
default: begin
r_fc_sel <= 3'b000;
r_rd_fc_sel <= 6'b000000;
end
endcase
end
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
r_tx_cpld_gnt;
r_tx_mrd_gnt;
r_tx_mwr_gnt;
end
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0) begin
r_rd_fc_sel_d1 <= 0;
r_rd_fc_sel_d2 <= 0;
end
else begin
r_rd_fc_sel_d1 <= r_rd_fc_sel;
r_rd_fc_sel_d2 <= r_rd_fc_sel_d1;
end
end
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0) begin
r_rx_available_fc_cpld <= 0;
r_rx_available_fc_cplh <= 0;
r_rx_available_fc_npd <= 0;
r_rx_available_fc_nph <= 0;
r_rx_available_fc_pd <= 0;
r_rx_available_fc_ph <= 0;
r_rx_limit_fc_cpld <= 0;
r_rx_limit_fc_cplh <= 0;
r_rx_limit_fc_npd <= 0;
r_rx_limit_fc_nph <= 0;
r_rx_limit_fc_pd <= 0;
r_rx_limit_fc_ph <= 0;
r_rx_consumed_fc_cpld <= 0;
r_rx_consumed_fc_cplh <= 0;
r_rx_consumed_fc_npd <= 0;
r_rx_consumed_fc_nph <= 0;
r_rx_consumed_fc_pd <= 0;
r_rx_consumed_fc_ph <= 0;
r_tx_available_fc_cpld <= 0;
r_tx_available_fc_cplh <= 0;
r_tx_available_fc_npd <= 0;
r_tx_available_fc_nph <= 0;
r_tx_available_fc_pd <= 0;
r_tx_available_fc_ph <= 0;
r_tx_limit_fc_cpld <= 0;
r_tx_limit_fc_cplh <= 0;
r_tx_limit_fc_npd <= 0;
r_tx_limit_fc_nph <= 0;
r_tx_limit_fc_pd <= 0;
r_tx_limit_fc_ph <= 0;
r_tx_consumed_fc_cpld <= 0;
r_tx_consumed_fc_cplh <= 0;
r_tx_consumed_fc_npd <= 0;
r_tx_consumed_fc_nph <= 0;
r_tx_consumed_fc_pd <= 0;
r_tx_consumed_fc_ph <= 0;
end
else begin
if(r_rd_fc_sel_d2[0] == 1) begin
r_rx_available_fc_cpld <= fc_cpld;
r_rx_available_fc_cplh <= fc_cplh;
r_rx_available_fc_npd <= fc_npd;
r_rx_available_fc_nph <= fc_nph;
r_rx_available_fc_pd <= fc_pd;
r_rx_available_fc_ph <= fc_ph;
end
if(r_rd_fc_sel_d2[1] == 1) begin
r_rx_limit_fc_cpld <= fc_cpld;
r_rx_limit_fc_cplh <= fc_cplh;
r_rx_limit_fc_npd <= fc_npd;
r_rx_limit_fc_nph <= fc_nph;
r_rx_limit_fc_pd <= fc_pd;
r_rx_limit_fc_ph <= fc_ph;
end
if(r_rd_fc_sel_d2[2] == 1) begin
r_rx_consumed_fc_cpld <= fc_cpld;
r_rx_consumed_fc_cplh <= fc_cplh;
r_rx_consumed_fc_npd <= fc_npd;
r_rx_consumed_fc_nph <= fc_nph;
r_rx_consumed_fc_pd <= fc_pd;
r_rx_consumed_fc_ph <= fc_ph;
end
if(r_rd_fc_sel_d2[3] == 1) begin
r_tx_available_fc_cpld <= fc_cpld;
r_tx_available_fc_cplh <= fc_cplh;
r_tx_available_fc_npd <= fc_npd;
r_tx_available_fc_nph <= fc_nph;
r_tx_available_fc_pd <= fc_pd;
r_tx_available_fc_ph <= fc_ph;
end
if(r_rd_fc_sel_d2[4] == 1) begin
r_tx_limit_fc_cpld <= fc_cpld;
r_tx_limit_fc_cplh <= fc_cplh;
r_tx_limit_fc_npd <= fc_npd;
r_tx_limit_fc_nph <= fc_nph;
r_tx_limit_fc_pd <= fc_pd;
r_tx_limit_fc_ph <= fc_ph;
end
if(r_rd_fc_sel_d2[5] == 1) begin
r_tx_consumed_fc_cpld <= fc_cpld;
r_tx_consumed_fc_cplh <= fc_cplh;
r_tx_consumed_fc_npd <= fc_npd;
r_tx_consumed_fc_nph <= fc_nph;
r_tx_consumed_fc_pd <= fc_pd;
r_tx_consumed_fc_ph <= fc_ph;
end
end
end
*/
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2008 by Wilson Snyder.
module t;
wire d1 = 1'b1;
wire d2 = 1'b1;
wire d3 = 1'b1;
wire o1,o2,o3;
add1 add1 (d1,o1);
add2 add2 (d2,o2);
`define ls left_side
`define rs right_side
`define noarg na//note extra space
`define thru(x) x
`define thruthru `ls `rs // Doesn't expand
`define msg(x,y) `"x: `\`"y`\`"`"
`define left(m,left) m // The 'left' as the variable name shouldn't match the "left" in the `" string
initial begin
//$display(`msg( \`, \`)); // Illegal
$display(`msg(pre `thru(thrupre `thru(thrumid) thrupost) post,right side));
$display(`msg(left side,right side));
$display(`msg( left side , right side ));
$display(`msg( `ls , `rs ));
$display(`msg( `noarg , `rs ));
$display(`msg( prep ( midp1 `ls midp2 ( outp ) ) , `rs ));
$display(`msg(`noarg,`noarg`noarg));
$display(`msg( `thruthru , `thruthru )); // Results vary between simulators
$display(`left(`msg( left side , right side ), left_replaced));
//$display(`msg( `"tickquoted_left`", `"tickquoted_right`" )); // Syntax error
`ifndef VCS // Sim bug - wrong number of arguments, but we're right
$display(`msg(`thru(),)); // Empty
`endif
$display(`msg(`thru(left side),`thru(right side)));
$display(`msg( `thru( left side ) , `thru( right side ) ));
`ifndef NC
$display(`"standalone`");
`endif
`ifdef VERILATOR
// Illegal on some simulators, as the "..." crosses two lines
`define twoline first \
second
$display(`msg(twoline, `twoline));
`endif
$display("Line %0d File \"%s\"",`__LINE__,`__FILE__);
//$display(`msg(left side, \ right side \ )); // Not sure \{space} is legal.
$write("*-* All Finished *-*\n");
$finish;
end
endmodule
`define ADD_UP(a,c) \
wire tmp_``a = a; \
wire tmp_``c = tmp_``a + 1; \
assign c = tmp_``c ;
module add1 ( input wire d1, output wire o1);
`ADD_UP(d1,o1) // expansion is OK
endmodule
module add2 ( input wire d2, output wire o2);
`ADD_UP( d2 , o2 ) // expansion is bad
endmodule
// `ADD_UP( \d3 , \o3 ) // This really is illegal
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2008 by Wilson Snyder.
module t;
wire d1 = 1'b1;
wire d2 = 1'b1;
wire d3 = 1'b1;
wire o1,o2,o3;
add1 add1 (d1,o1);
add2 add2 (d2,o2);
`define ls left_side
`define rs right_side
`define noarg na//note extra space
`define thru(x) x
`define thruthru `ls `rs // Doesn't expand
`define msg(x,y) `"x: `\`"y`\`"`"
`define left(m,left) m // The 'left' as the variable name shouldn't match the "left" in the `" string
initial begin
//$display(`msg( \`, \`)); // Illegal
$display(`msg(pre `thru(thrupre `thru(thrumid) thrupost) post,right side));
$display(`msg(left side,right side));
$display(`msg( left side , right side ));
$display(`msg( `ls , `rs ));
$display(`msg( `noarg , `rs ));
$display(`msg( prep ( midp1 `ls midp2 ( outp ) ) , `rs ));
$display(`msg(`noarg,`noarg`noarg));
$display(`msg( `thruthru , `thruthru )); // Results vary between simulators
$display(`left(`msg( left side , right side ), left_replaced));
//$display(`msg( `"tickquoted_left`", `"tickquoted_right`" )); // Syntax error
`ifndef VCS // Sim bug - wrong number of arguments, but we're right
$display(`msg(`thru(),)); // Empty
`endif
$display(`msg(`thru(left side),`thru(right side)));
$display(`msg( `thru( left side ) , `thru( right side ) ));
`ifndef NC
$display(`"standalone`");
`endif
`ifdef VERILATOR
// Illegal on some simulators, as the "..." crosses two lines
`define twoline first \
second
$display(`msg(twoline, `twoline));
`endif
$display("Line %0d File \"%s\"",`__LINE__,`__FILE__);
//$display(`msg(left side, \ right side \ )); // Not sure \{space} is legal.
$write("*-* All Finished *-*\n");
$finish;
end
endmodule
`define ADD_UP(a,c) \
wire tmp_``a = a; \
wire tmp_``c = tmp_``a + 1; \
assign c = tmp_``c ;
module add1 ( input wire d1, output wire o1);
`ADD_UP(d1,o1) // expansion is OK
endmodule
module add2 ( input wire d2, output wire o2);
`ADD_UP( d2 , o2 ) // expansion is bad
endmodule
// `ADD_UP( \d3 , \o3 ) // This really is illegal
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2008 by Wilson Snyder.
module t;
wire d1 = 1'b1;
wire d2 = 1'b1;
wire d3 = 1'b1;
wire o1,o2,o3;
add1 add1 (d1,o1);
add2 add2 (d2,o2);
`define ls left_side
`define rs right_side
`define noarg na//note extra space
`define thru(x) x
`define thruthru `ls `rs // Doesn't expand
`define msg(x,y) `"x: `\`"y`\`"`"
`define left(m,left) m // The 'left' as the variable name shouldn't match the "left" in the `" string
initial begin
//$display(`msg( \`, \`)); // Illegal
$display(`msg(pre `thru(thrupre `thru(thrumid) thrupost) post,right side));
$display(`msg(left side,right side));
$display(`msg( left side , right side ));
$display(`msg( `ls , `rs ));
$display(`msg( `noarg , `rs ));
$display(`msg( prep ( midp1 `ls midp2 ( outp ) ) , `rs ));
$display(`msg(`noarg,`noarg`noarg));
$display(`msg( `thruthru , `thruthru )); // Results vary between simulators
$display(`left(`msg( left side , right side ), left_replaced));
//$display(`msg( `"tickquoted_left`", `"tickquoted_right`" )); // Syntax error
`ifndef VCS // Sim bug - wrong number of arguments, but we're right
$display(`msg(`thru(),)); // Empty
`endif
$display(`msg(`thru(left side),`thru(right side)));
$display(`msg( `thru( left side ) , `thru( right side ) ));
`ifndef NC
$display(`"standalone`");
`endif
`ifdef VERILATOR
// Illegal on some simulators, as the "..." crosses two lines
`define twoline first \
second
$display(`msg(twoline, `twoline));
`endif
$display("Line %0d File \"%s\"",`__LINE__,`__FILE__);
//$display(`msg(left side, \ right side \ )); // Not sure \{space} is legal.
$write("*-* All Finished *-*\n");
$finish;
end
endmodule
`define ADD_UP(a,c) \
wire tmp_``a = a; \
wire tmp_``c = tmp_``a + 1; \
assign c = tmp_``c ;
module add1 ( input wire d1, output wire o1);
`ADD_UP(d1,o1) // expansion is OK
endmodule
module add2 ( input wire d2, output wire o2);
`ADD_UP( d2 , o2 ) // expansion is bad
endmodule
// `ADD_UP( \d3 , \o3 ) // This really is illegal
|
// file: clk_wiz_v3_2.v
//
// (c) Copyright 2008 - 2011 Xilinx, Inc. All rights reserved.
//
// This file contains confidential and proprietary information
// of Xilinx, Inc. and is protected under U.S. and
// international copyright and other intellectual property
// laws.
//
// DISCLAIMER
// This disclaimer is not a license and does not grant any
// rights to the materials distributed herewith. Except as
// otherwise provided in a valid license issued to you by
// Xilinx, and to the maximum extent permitted by applicable
// law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// (2) Xilinx shall not be liable (whether in contract or tort,
// including negligence, or under any other theory of
// liability) for any loss or damage of any kind or nature
// related to, arising under or in connection with these
// materials, including for any direct, or any indirect,
// special, incidental, or consequential loss or damage
// (including loss of data, profits, goodwill, or any type of
// loss or damage suffered as a result of any action brought
// by a third party) even if such damage or loss was
// reasonably foreseeable or Xilinx had been advised of the
// possibility of the same.
//
// CRITICAL APPLICATIONS
// Xilinx products are not designed or intended to be fail-
// safe, or for use in any application requiring fail-safe
// performance, such as life-support or safety devices or
// systems, Class III medical devices, nuclear facilities,
// applications related to the deployment of airbags, or any
// other applications that could lead to death, personal
// injury, or severe property or environmental damage
// (individually and collectively, "Critical
// Applications"). Customer assumes the sole risk and
// liability of any use of Xilinx products in Critical
// Applications, subject only to applicable laws and
// regulations governing limitations on product liability.
//
// THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// PART OF THIS FILE AT ALL TIMES.
//
//----------------------------------------------------------------------------
// User entered comments
//----------------------------------------------------------------------------
// None
//
//----------------------------------------------------------------------------
// "Output Output Phase Duty Pk-to-Pk Phase"
// "Clock Freq (MHz) (degrees) Cycle (%) Jitter (ps) Error (ps)"
//----------------------------------------------------------------------------
// CLK_OUT1___200.000______0.000_______N/A______220.000________N/A
//
//----------------------------------------------------------------------------
// "Input Clock Freq (MHz) Input Jitter (UI)"
//----------------------------------------------------------------------------
// __primary_________100.000_____________0.01
`timescale 1ps/1ps
// Please set INPUT_FREQUENCY to the MHz of the incoming clock!!
// WARNING: This module will currently NOT handle anything other than a 100MHz
// clock because the CLKIN_PERIOD is not properly calculated.
//
// SYNTHESIS_FREQUENCY is used to determine at what frequency the design is
// synthesized for.
//
//
// NOTE: Internally, the divider is set to half of
// INPUT_FREQUENCY. This allows a greater range of output frequencies.
// So when you look at the COMM code, you'll see that it takes the requested
// frequency and divides by 2 to get the proper multiplier.
module dynamic_clock # (
parameter INPUT_FREQUENCY = 100,
parameter SYNTHESIS_FREQUENCY = 200
) (
input CLK_IN1,
output CLK_OUT1,
input PROGCLK,
input PROGDATA,
input PROGEN,
output PROGDONE
);
// Input buffering
//------------------------------------
/*IBUFG clkin1_buf
(.O (clkin1),
.I (CLK_IN1));*/
// Clocking primitive
//------------------------------------
// Instantiation of the DCM primitive
// * Unused inputs are tied off
wire clkfx;
DCM_CLKGEN
#(.CLKFXDV_DIVIDE (2),
.CLKFX_DIVIDE (INPUT_FREQUENCY >> 1),
.CLKFX_MULTIPLY (SYNTHESIS_FREQUENCY >> 1),
.SPREAD_SPECTRUM ("NONE"),
.STARTUP_WAIT ("FALSE"),
.CLKIN_PERIOD (10.0),
.CLKFX_MD_MAX (0.000))
dcm_clkgen_inst
// Input clock
(.CLKIN (CLK_IN1),
// Output clocks
.CLKFX (clkfx),
.CLKFX180 (),
.CLKFXDV (),
// Ports for dynamic reconfiguration
.PROGCLK (PROGCLK),
.PROGDATA (PROGDATA),
.PROGEN (PROGEN),
.PROGDONE (PROGDONE),
// Other control and status signals
.FREEZEDCM (1'b0),
.LOCKED (),
.STATUS (),
.RST (1'b0));
// Output buffering
//-----------------------------------
BUFG clkout1_buf
(.O (CLK_OUT1),
.I (clkfx));
endmodule
|
// file: clk_wiz_v3_2.v
//
// (c) Copyright 2008 - 2011 Xilinx, Inc. All rights reserved.
//
// This file contains confidential and proprietary information
// of Xilinx, Inc. and is protected under U.S. and
// international copyright and other intellectual property
// laws.
//
// DISCLAIMER
// This disclaimer is not a license and does not grant any
// rights to the materials distributed herewith. Except as
// otherwise provided in a valid license issued to you by
// Xilinx, and to the maximum extent permitted by applicable
// law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
// WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
// AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
// BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
// INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
// (2) Xilinx shall not be liable (whether in contract or tort,
// including negligence, or under any other theory of
// liability) for any loss or damage of any kind or nature
// related to, arising under or in connection with these
// materials, including for any direct, or any indirect,
// special, incidental, or consequential loss or damage
// (including loss of data, profits, goodwill, or any type of
// loss or damage suffered as a result of any action brought
// by a third party) even if such damage or loss was
// reasonably foreseeable or Xilinx had been advised of the
// possibility of the same.
//
// CRITICAL APPLICATIONS
// Xilinx products are not designed or intended to be fail-
// safe, or for use in any application requiring fail-safe
// performance, such as life-support or safety devices or
// systems, Class III medical devices, nuclear facilities,
// applications related to the deployment of airbags, or any
// other applications that could lead to death, personal
// injury, or severe property or environmental damage
// (individually and collectively, "Critical
// Applications"). Customer assumes the sole risk and
// liability of any use of Xilinx products in Critical
// Applications, subject only to applicable laws and
// regulations governing limitations on product liability.
//
// THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
// PART OF THIS FILE AT ALL TIMES.
//
//----------------------------------------------------------------------------
// User entered comments
//----------------------------------------------------------------------------
// None
//
//----------------------------------------------------------------------------
// "Output Output Phase Duty Pk-to-Pk Phase"
// "Clock Freq (MHz) (degrees) Cycle (%) Jitter (ps) Error (ps)"
//----------------------------------------------------------------------------
// CLK_OUT1___200.000______0.000_______N/A______220.000________N/A
//
//----------------------------------------------------------------------------
// "Input Clock Freq (MHz) Input Jitter (UI)"
//----------------------------------------------------------------------------
// __primary_________100.000_____________0.01
`timescale 1ps/1ps
// Please set INPUT_FREQUENCY to the MHz of the incoming clock!!
// WARNING: This module will currently NOT handle anything other than a 100MHz
// clock because the CLKIN_PERIOD is not properly calculated.
//
// SYNTHESIS_FREQUENCY is used to determine at what frequency the design is
// synthesized for.
//
//
// NOTE: Internally, the divider is set to half of
// INPUT_FREQUENCY. This allows a greater range of output frequencies.
// So when you look at the COMM code, you'll see that it takes the requested
// frequency and divides by 2 to get the proper multiplier.
module dynamic_clock # (
parameter INPUT_FREQUENCY = 100,
parameter SYNTHESIS_FREQUENCY = 200
) (
input CLK_IN1,
output CLK_OUT1,
input PROGCLK,
input PROGDATA,
input PROGEN,
output PROGDONE
);
// Input buffering
//------------------------------------
/*IBUFG clkin1_buf
(.O (clkin1),
.I (CLK_IN1));*/
// Clocking primitive
//------------------------------------
// Instantiation of the DCM primitive
// * Unused inputs are tied off
wire clkfx;
DCM_CLKGEN
#(.CLKFXDV_DIVIDE (2),
.CLKFX_DIVIDE (INPUT_FREQUENCY >> 1),
.CLKFX_MULTIPLY (SYNTHESIS_FREQUENCY >> 1),
.SPREAD_SPECTRUM ("NONE"),
.STARTUP_WAIT ("FALSE"),
.CLKIN_PERIOD (10.0),
.CLKFX_MD_MAX (0.000))
dcm_clkgen_inst
// Input clock
(.CLKIN (CLK_IN1),
// Output clocks
.CLKFX (clkfx),
.CLKFX180 (),
.CLKFXDV (),
// Ports for dynamic reconfiguration
.PROGCLK (PROGCLK),
.PROGDATA (PROGDATA),
.PROGEN (PROGEN),
.PROGDONE (PROGDONE),
// Other control and status signals
.FREEZEDCM (1'b0),
.LOCKED (),
.STATUS (),
.RST (1'b0));
// Output buffering
//-----------------------------------
BUFG clkout1_buf
(.O (CLK_OUT1),
.I (clkfx));
endmodule
|
/*
----------------------------------------------------------------------------------
Copyright (c) 2013-2014
Embedded and Network Computing Lab.
Open SSD Project
Hanyang University
All rights reserved.
----------------------------------------------------------------------------------
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. All advertising materials mentioning features or use of this source code
must display the following acknowledgement:
This product includes source code developed
by the Embedded and Network Computing Lab. and the Open SSD Project.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
----------------------------------------------------------------------------------
http://enclab.hanyang.ac.kr/
http://www.openssd-project.org/
http://www.hanyang.ac.kr/
----------------------------------------------------------------------------------
*/
`timescale 1ns / 1ps
module sys_rst
(
input cpu_bus_clk,
input cpu_bus_rst_n,
input pcie_perst_n,
input user_reset_out,
input pcie_pl_hot_rst,
input pcie_user_logic_rst,
output pcie_sys_rst_n,
output pcie_user_rst_n
);
localparam LP_PCIE_RST_CNT_WIDTH = 9;
localparam LP_PCIE_RST_CNT = 380;
localparam LP_PCIE_HOT_RST_CNT = 50;
localparam S_RESET = 6'b000001;
localparam S_RESET_CNT = 6'b000010;
localparam S_HOT_RESET = 6'b000100;
localparam S_HOT_RESET_CNT = 6'b001000;
localparam S_HOT_RESET_WAIT = 6'b010000;
localparam S_IDLE = 6'b100000;
reg [5:0] cur_state;
reg [5:0] next_state;
(* KEEP = "TRUE", SHIFT_EXTRACT = "NO" *) reg r_pcie_perst_n;
(* KEEP = "TRUE", SHIFT_EXTRACT = "NO" *) reg r_pcie_perst_n_sync;
(* KEEP = "TRUE", SHIFT_EXTRACT = "NO" *) reg r_pcie_pl_hot_rst;
(* KEEP = "TRUE", SHIFT_EXTRACT = "NO" *) reg r_pcie_pl_hot_rst_sync;
reg [LP_PCIE_RST_CNT_WIDTH-1:0] r_rst_cnt;
reg r_pcie_sys_rst_n;
reg r_pcie_hot_rst;
assign pcie_user_rst_n = ~(user_reset_out | r_pcie_hot_rst);
//assign pcie_user_rst_n = ~(user_reset_out);
assign pcie_sys_rst_n = r_pcie_sys_rst_n;
always @ (posedge cpu_bus_clk)
begin
r_pcie_perst_n_sync <= pcie_perst_n;
r_pcie_perst_n <= r_pcie_perst_n_sync;
r_pcie_pl_hot_rst_sync <= pcie_pl_hot_rst;
r_pcie_pl_hot_rst <= r_pcie_pl_hot_rst_sync;
end
always @ (posedge cpu_bus_clk or negedge cpu_bus_rst_n)
begin
if(cpu_bus_rst_n == 0)
cur_state <= S_RESET;
else
cur_state <= next_state;
end
always @ (*)
begin
case(cur_state)
S_RESET: begin
next_state <= S_RESET_CNT;
end
S_RESET_CNT: begin
if(r_pcie_perst_n == 0)
next_state <= S_RESET;
else if(r_rst_cnt == 0)
next_state <= S_IDLE;
else
next_state <= S_RESET_CNT;
end
S_HOT_RESET: begin
next_state <= S_HOT_RESET_CNT;
end
S_HOT_RESET_CNT: begin
if(r_pcie_perst_n == 0)
next_state <= S_RESET;
else if(r_rst_cnt == 0)
next_state <= S_HOT_RESET_WAIT;
else
next_state <= S_HOT_RESET_CNT;
end
S_HOT_RESET_WAIT: begin
if(r_pcie_perst_n == 0)
next_state <= S_RESET;
else if(r_pcie_pl_hot_rst == 1)
next_state <= S_HOT_RESET_WAIT;
else
next_state <= S_IDLE;
end
S_IDLE: begin
if(r_pcie_perst_n == 0)
next_state <= S_RESET;
else if(r_pcie_pl_hot_rst == 1 || pcie_user_logic_rst == 1)
next_state <= S_HOT_RESET;
else
next_state <= S_IDLE;
end
default: begin
next_state <= S_RESET;
end
endcase
end
always @ (posedge cpu_bus_clk)
begin
case(cur_state)
S_RESET: begin
r_rst_cnt <= LP_PCIE_RST_CNT;
end
S_RESET_CNT: begin
r_rst_cnt <= r_rst_cnt - 1'b1;
end
S_HOT_RESET: begin
r_rst_cnt <= LP_PCIE_HOT_RST_CNT;
end
S_HOT_RESET_CNT: begin
r_rst_cnt <= r_rst_cnt - 1'b1;
end
S_HOT_RESET_WAIT: begin
end
S_IDLE: begin
end
default: begin
end
endcase
end
always @ (*)
begin
case(cur_state)
S_RESET: begin
r_pcie_sys_rst_n <= 0;
r_pcie_hot_rst <= 0;
end
S_RESET_CNT: begin
r_pcie_sys_rst_n <= 0;
r_pcie_hot_rst <= 0;
end
S_HOT_RESET: begin
r_pcie_sys_rst_n <= 1;
r_pcie_hot_rst <= 1;
end
S_HOT_RESET_CNT: begin
r_pcie_sys_rst_n <= 1;
r_pcie_hot_rst <= 1;
end
S_HOT_RESET_WAIT: begin
r_pcie_sys_rst_n <= 1;
r_pcie_hot_rst <= 1;
end
S_IDLE: begin
r_pcie_sys_rst_n <= 1;
r_pcie_hot_rst <= 0;
end
default: begin
r_pcie_sys_rst_n <= 0;
r_pcie_hot_rst <= 0;
end
endcase
end
endmodule
|
/*
----------------------------------------------------------------------------------
Copyright (c) 2013-2014
Embedded and Network Computing Lab.
Open SSD Project
Hanyang University
All rights reserved.
----------------------------------------------------------------------------------
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. All advertising materials mentioning features or use of this source code
must display the following acknowledgement:
This product includes source code developed
by the Embedded and Network Computing Lab. and the Open SSD Project.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
----------------------------------------------------------------------------------
http://enclab.hanyang.ac.kr/
http://www.openssd-project.org/
http://www.hanyang.ac.kr/
----------------------------------------------------------------------------------
*/
`timescale 1ns / 1ps
module nvme_cq_check # (
parameter C_PCIE_DATA_WIDTH = 128,
parameter C_PCIE_ADDR_WIDTH = 36
)
(
input pcie_user_clk,
input pcie_user_rst_n,
input pcie_msi_en,
input cq_rst_n,
input cq_valid,
input io_cq_irq_en,
input [7:0] cq_tail_ptr,
input [7:0] cq_head_ptr,
input cq_head_update,
output cq_legacy_irq_req,
output cq_msi_irq_req,
input cq_msi_irq_ack
);
localparam LP_CQ_IRQ_DELAY_TIME = 8'h01;
localparam S_IDLE = 4'b0001;
localparam S_CQ_MSI_IRQ_REQ = 4'b0010;
localparam S_CQ_MSI_HEAD_SET = 4'b0100;
localparam S_CQ_MSI_IRQ_TIMER = 4'b1000;
reg [3:0] cur_state;
reg [3:0] next_state;
reg [7:0] r_cq_tail_ptr;
reg [7:0] r_cq_msi_irq_head_ptr;
reg [7:0] r_irq_timer;
reg r_cq_legacy_irq_req;
reg r_cq_msi_irq_req;
wire w_cq_rst_n;
assign cq_legacy_irq_req = r_cq_legacy_irq_req;
assign cq_msi_irq_req = r_cq_msi_irq_req;
assign w_cq_rst_n = pcie_user_rst_n & cq_rst_n;
always @ (posedge pcie_user_clk)
begin
r_cq_tail_ptr <= cq_tail_ptr;
r_cq_legacy_irq_req <= ((cq_head_ptr != r_cq_tail_ptr) && ((cq_valid & io_cq_irq_en) == 1));
end
always @ (posedge pcie_user_clk or negedge w_cq_rst_n)
begin
if(w_cq_rst_n == 0)
cur_state <= S_IDLE;
else
cur_state <= next_state;
end
always @ (*)
begin
case(cur_state)
S_IDLE: begin
if(((r_cq_msi_irq_head_ptr != r_cq_tail_ptr) & (pcie_msi_en & cq_valid & io_cq_irq_en)) == 1)
next_state <= S_CQ_MSI_IRQ_REQ;
else
next_state <= S_IDLE;
end
S_CQ_MSI_IRQ_REQ: begin
if(cq_msi_irq_ack == 1)
next_state <= S_CQ_MSI_HEAD_SET;
else
next_state <= S_CQ_MSI_IRQ_REQ;
end
S_CQ_MSI_HEAD_SET: begin
/*
if(cq_head_update == 1 || (cq_head_ptr == r_cq_tail_ptr))
next_state <= S_CQ_MSI_IRQ_TIMER;
else
next_state <= S_CQ_MSI_HEAD_SET;
*/
next_state <= S_CQ_MSI_IRQ_TIMER;
end
S_CQ_MSI_IRQ_TIMER: begin
if(r_irq_timer == 0)
next_state <= S_IDLE;
else
next_state <= S_CQ_MSI_IRQ_TIMER;
end
default: begin
next_state <= S_IDLE;
end
endcase
end
always @ (posedge pcie_user_clk)
begin
case(cur_state)
S_IDLE: begin
end
S_CQ_MSI_IRQ_REQ: begin
end
S_CQ_MSI_HEAD_SET: begin
r_irq_timer <= LP_CQ_IRQ_DELAY_TIME;
end
S_CQ_MSI_IRQ_TIMER: begin
r_irq_timer <= r_irq_timer - 1;
end
default: begin
end
endcase
end
always @ (posedge pcie_user_clk or negedge w_cq_rst_n)
begin
if(w_cq_rst_n == 0) begin
r_cq_msi_irq_head_ptr <= 0;
end
else begin
case(cur_state)
S_IDLE: begin
if((pcie_msi_en & cq_valid & io_cq_irq_en) == 0)
r_cq_msi_irq_head_ptr <= r_cq_tail_ptr;
end
S_CQ_MSI_IRQ_REQ: begin
end
S_CQ_MSI_HEAD_SET: begin
r_cq_msi_irq_head_ptr <= r_cq_tail_ptr;
end
S_CQ_MSI_IRQ_TIMER: begin
end
default: begin
end
endcase
end
end
always @ (*)
begin
case(cur_state)
S_IDLE: begin
r_cq_msi_irq_req <= 0;
end
S_CQ_MSI_IRQ_REQ: begin
r_cq_msi_irq_req <= 1;
end
S_CQ_MSI_HEAD_SET: begin
r_cq_msi_irq_req <= 0;
end
S_CQ_MSI_IRQ_TIMER: begin
r_cq_msi_irq_req <= 0;
end
default: begin
r_cq_msi_irq_req <= 0;
end
endcase
end
endmodule
|
`timescale 1ns/1ps
module tx_packer
( //FX2 Side
input bus_reset,
input usbclk,
input WR_fx2,
input [15:0]usbdata,
// TX Side
input reset,
input txclk,
output reg [31:0] usbdata_final,
output reg WR_final,
output wire test_bit0,
output reg test_bit1
);
reg [8:0] write_count;
/* Fix FX2 bug */
always @(posedge usbclk)
begin
if(bus_reset) // Use bus reset because this is on usbclk
write_count <= #1 0;
else if(WR_fx2 & ~write_count[8])
write_count <= #1 write_count + 9'd1;
else
write_count <= #1 WR_fx2 ? write_count : 9'b0;
end
reg WR_fx2_fixed;
reg [15:0]usbdata_fixed;
always @(posedge usbclk)
begin
WR_fx2_fixed <= WR_fx2 & ~write_count[8];
usbdata_fixed <= usbdata;
end
/* Used to convert 16 bits bus_data to the 32 bits wide fifo */
reg word_complete ;
reg [15:0] usbdata_delayed ;
reg writing ;
wire [31:0] usbdata_packed ;
wire WR_packed ;
//////////////////////////////////////////////test code
// assign usbdata_xor = ((usbdata_fixed[15] ^ usbdata_fixed[14]) | (usbdata_fixed[13] ^ usbdata_fixed[12]) |
// (usbdata_fixed[11] ^ usbdata_fixed[10]) | (usbdata_fixed[9] ^ usbdata_fixed[8]) |
// (usbdata_fixed[7] ^ usbdata_fixed[6]) | (usbdata_fixed[5] ^ usbdata_fixed[4]) |
// (usbdata_fixed[3] ^ usbdata_fixed[2]) | (usbdata_fixed[1] ^ usbdata_fixed[0]) |
// (usbdata_fixed[15] ^ usbdata_fixed[11]) | (usbdata_fixed[7] ^ usbdata_fixed[3]) |
// (usbdata_fixed[13] ^ usbdata_fixed[9]) | (usbdata_fixed[5] ^ usbdata_fixed[1]) )
// & WR_fx2_fixed;
assign usbdata_xor = ((usbdata_fixed[15] & usbdata_fixed[14]) & (usbdata_fixed[13] & usbdata_fixed[12]) &
(usbdata_fixed[11] & usbdata_fixed[10]) & (usbdata_fixed[9] & usbdata_fixed[8]) &
(usbdata_fixed[7] & usbdata_fixed[6]) & (usbdata_fixed[5] & usbdata_fixed[4]) &
(usbdata_fixed[3] & usbdata_fixed[2]) & (usbdata_fixed[1] & usbdata_fixed[0]) &
WR_fx2_fixed);
assign test_bit0 = txclk ;
//always @(posedge usbclk)
// begin
// test_bit0 <= usbdata_xor;
// end
//////////////////////////////////////////////test code
always @(posedge usbclk)
begin
if (bus_reset)
begin
word_complete <= 0 ;
writing <= 0 ;
end
else if (WR_fx2_fixed)
begin
writing <= 1 ;
if (word_complete)
word_complete <= 0 ;
else
begin
usbdata_delayed <= usbdata_fixed ;
word_complete <= 1 ;
end
end
else
writing <= 0 ;
end
assign usbdata_packed = {usbdata_fixed, usbdata_delayed} ;
assign WR_packed = word_complete & writing ;
/* Make sure data are sync with usbclk */
reg [31:0]usbdata_usbclk;
reg WR_usbclk;
always @(posedge usbclk)
begin
if (WR_packed)
usbdata_usbclk <= usbdata_packed;
WR_usbclk <= WR_packed;
end
/* Cross clock boundaries */
reg [31:0] usbdata_tx ;
reg WR_tx;
reg WR_1;
reg WR_2;
always @(posedge txclk) usbdata_tx <= usbdata_usbclk;
always @(posedge txclk)
if (reset)
WR_1 <= 0;
else
WR_1 <= WR_usbclk;
always @(posedge txclk)
if (reset)
WR_2 <= 0;
else
WR_2 <= WR_1;
always @(posedge txclk)
begin
if (reset)
WR_tx <= 0;
else
WR_tx <= WR_1 & ~WR_2;
end
always @(posedge txclk)
begin
if (reset)
WR_final <= 0;
else
begin
WR_final <= WR_tx;
if (WR_tx)
usbdata_final <= usbdata_tx;
end
end
///////////////////test output
always @(posedge txclk)
begin
if (reset)
test_bit1 <= 0;
else if (!WR_final)
test_bit1 <= test_bit1;
else if ((usbdata_final == 32'hffff0000))
test_bit1 <= 0;
else
test_bit1 <= 1;
end
///////////////////////////////
// always @(posedge usbclk)
// begin
// if (bus_reset)
// begin
// test_bit0 <= 1'b0;
// end
// else if (usbdata_packed[0] ^ usbdata_packed[16])
// test_bit0 <= 1'b1;
// else
// test_bit0 <= 1'b0;
// end
// Test comparator for 16 bit hi & low data
// add new test bit
// wire [15:0] usbpkd_low;
// wire [15:0] usbpkd_hi;
//
// assign usbpkd_low = usbdata_delayed;
// assign usbpkd_hi = usbdata_fixed;
//
// always @(posedge usbclk)
// begin
// if (bus_reset)
// begin
// test_bit1 <= 1'b0;
// end
// else
// begin
// // test_bit1 <= (usbpkd_low === usbpkd_hi) ? 1'b1 : 1'b0;
// if (usbpkd_low == usbpkd_hi)
// test_bit1 <= 1'b1;
// else
// test_bit1 <= 1'b0;
// end
// end
endmodule
|
/*
----------------------------------------------------------------------------------
Copyright (c) 2013-2014
Embedded and Network Computing Lab.
Open SSD Project
Hanyang University
All rights reserved.
----------------------------------------------------------------------------------
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. All advertising materials mentioning features or use of this source code
must display the following acknowledgement:
This product includes source code developed
by the Embedded and Network Computing Lab. and the Open SSD Project.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
----------------------------------------------------------------------------------
http://enclab.hanyang.ac.kr/
http://www.openssd-project.org/
http://www.hanyang.ac.kr/
----------------------------------------------------------------------------------
*/
`timescale 1ns / 1ps
module pcie_hcmd # (
parameter C_PCIE_DATA_WIDTH = 128,
parameter C_PCIE_ADDR_WIDTH = 36
)
(
input pcie_user_clk,
input pcie_user_rst_n,
input [C_PCIE_ADDR_WIDTH-1:2] admin_sq_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] admin_cq_bs_addr,
input [7:0] admin_sq_size,
input [7:0] admin_cq_size,
input [7:0] admin_sq_tail_ptr,
input [7:0] io_sq1_tail_ptr,
input [7:0] io_sq2_tail_ptr,
input [7:0] io_sq3_tail_ptr,
input [7:0] io_sq4_tail_ptr,
input [7:0] io_sq5_tail_ptr,
input [7:0] io_sq6_tail_ptr,
input [7:0] io_sq7_tail_ptr,
input [7:0] io_sq8_tail_ptr,
input [7:0] cpld_sq_fifo_tag,
input [C_PCIE_DATA_WIDTH-1:0] cpld_sq_fifo_wr_data,
input cpld_sq_fifo_wr_en,
input cpld_sq_fifo_tag_last,
output tx_mrd_req,
output [7:0] tx_mrd_tag,
output [11:2] tx_mrd_len,
output [C_PCIE_ADDR_WIDTH-1:2] tx_mrd_addr,
input tx_mrd_req_ack,
output [7:0] admin_cq_tail_ptr,
output [7:0] io_cq1_tail_ptr,
output [7:0] io_cq2_tail_ptr,
output [7:0] io_cq3_tail_ptr,
output [7:0] io_cq4_tail_ptr,
output [7:0] io_cq5_tail_ptr,
output [7:0] io_cq6_tail_ptr,
output [7:0] io_cq7_tail_ptr,
output [7:0] io_cq8_tail_ptr,
output tx_cq_mwr_req,
output [7:0] tx_cq_mwr_tag,
output [11:2] tx_cq_mwr_len,
output [C_PCIE_ADDR_WIDTH-1:2] tx_cq_mwr_addr,
input tx_cq_mwr_req_ack,
input tx_cq_mwr_rd_en,
output [C_PCIE_DATA_WIDTH-1:0] tx_cq_mwr_rd_data,
input tx_cq_mwr_data_last,
input [7:0] hcmd_prp_rd_addr,
output [44:0] hcmd_prp_rd_data,
input hcmd_nlb_wr1_en,
input [6:0] hcmd_nlb_wr1_addr,
input [18:0] hcmd_nlb_wr1_data,
output hcmd_nlb_wr1_rdy_n,
input [6:0] hcmd_nlb_rd_addr,
output [18:0] hcmd_nlb_rd_data,
input hcmd_cq_wr0_en,
input [34:0] hcmd_cq_wr0_data0,
input [34:0] hcmd_cq_wr0_data1,
output hcmd_cq_wr0_rdy_n,
input cpu_bus_clk,
input cpu_bus_rst_n,
input [8:0] sq_rst_n,
input [8:0] sq_valid,
input [7:0] io_sq1_size,
input [7:0] io_sq2_size,
input [7:0] io_sq3_size,
input [7:0] io_sq4_size,
input [7:0] io_sq5_size,
input [7:0] io_sq6_size,
input [7:0] io_sq7_size,
input [7:0] io_sq8_size,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq1_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq2_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq3_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq4_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq5_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq6_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq7_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq8_bs_addr,
input [3:0] io_sq1_cq_vec,
input [3:0] io_sq2_cq_vec,
input [3:0] io_sq3_cq_vec,
input [3:0] io_sq4_cq_vec,
input [3:0] io_sq5_cq_vec,
input [3:0] io_sq6_cq_vec,
input [3:0] io_sq7_cq_vec,
input [3:0] io_sq8_cq_vec,
input [8:0] cq_rst_n,
input [8:0] cq_valid,
input [7:0] io_cq1_size,
input [7:0] io_cq2_size,
input [7:0] io_cq3_size,
input [7:0] io_cq4_size,
input [7:0] io_cq5_size,
input [7:0] io_cq6_size,
input [7:0] io_cq7_size,
input [7:0] io_cq8_size,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq1_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq2_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq3_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq4_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq5_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq6_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq7_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq8_bs_addr,
input hcmd_sq_rd_en,
output [18:0] hcmd_sq_rd_data,
output hcmd_sq_empty_n,
input [10:0] hcmd_table_rd_addr,
output [31:0] hcmd_table_rd_data,
input hcmd_cq_wr1_en,
input [34:0] hcmd_cq_wr1_data0,
input [34:0] hcmd_cq_wr1_data1,
output hcmd_cq_wr1_rdy_n
);
wire w_hcmd_table_wr_en;
wire [8:0] w_hcmd_table_wr_addr;
wire [127:0] w_hcmd_table_wr_data;
wire w_hcmd_cid_wr_en;
wire [6:0] w_hcmd_cid_wr_addr;
wire [19:0] w_hcmd_cid_wr_data;
wire [6:0] w_hcmd_cid_rd_addr;
wire [19:0] w_hcmd_cid_rd_data;
wire w_hcmd_prp_wr_en;
wire [7:0] w_hcmd_prp_wr_addr;
wire [44:0] w_hcmd_prp_wr_data;
wire w_hcmd_nlb_wr0_en;
wire [6:0] w_hcmd_nlb_wr0_addr;
wire [18:0] w_hcmd_nlb_wr0_data;
wire w_hcmd_nlb_wr0_rdy_n;
wire w_hcmd_slot_rdy;
wire [6:0] w_hcmd_slot_tag;
wire w_hcmd_slot_alloc_en;
wire w_hcmd_slot_free_en;
wire [6:0] w_hcmd_slot_invalid_tag;
wire [7:0] w_admin_sq_head_ptr;
wire [7:0] w_io_sq1_head_ptr;
wire [7:0] w_io_sq2_head_ptr;
wire [7:0] w_io_sq3_head_ptr;
wire [7:0] w_io_sq4_head_ptr;
wire [7:0] w_io_sq5_head_ptr;
wire [7:0] w_io_sq6_head_ptr;
wire [7:0] w_io_sq7_head_ptr;
wire [7:0] w_io_sq8_head_ptr;
pcie_hcmd_table
pcie_hcmd_table_inst0(
.wr_clk (pcie_user_clk),
.wr_en (w_hcmd_table_wr_en),
.wr_addr (w_hcmd_table_wr_addr),
.wr_data (w_hcmd_table_wr_data),
.rd_clk (cpu_bus_clk),
.rd_addr (hcmd_table_rd_addr),
.rd_data (hcmd_table_rd_data)
);
pcie_hcmd_table_cid
pcie_hcmd_table_cid_isnt0(
.clk (pcie_user_clk),
.wr_en (w_hcmd_cid_wr_en),
.wr_addr (w_hcmd_cid_wr_addr),
.wr_data (w_hcmd_cid_wr_data),
.rd_addr (w_hcmd_cid_rd_addr),
.rd_data (w_hcmd_cid_rd_data)
);
pcie_hcmd_table_prp
pcie_hcmd_table_prp_isnt0(
.clk (pcie_user_clk),
.wr_en (w_hcmd_prp_wr_en),
.wr_addr (w_hcmd_prp_wr_addr),
.wr_data (w_hcmd_prp_wr_data),
.rd_addr (hcmd_prp_rd_addr),
.rd_data (hcmd_prp_rd_data)
);
pcie_hcmd_nlb
pcie_hcmd_nlb_inst0
(
.clk (pcie_user_clk),
.rst_n (pcie_user_rst_n),
.wr0_en (w_hcmd_nlb_wr0_en),
.wr0_addr (w_hcmd_nlb_wr0_addr),
.wr0_data (w_hcmd_nlb_wr0_data),
.wr0_rdy_n (w_hcmd_nlb_wr0_rdy_n),
.wr1_en (hcmd_nlb_wr1_en),
.wr1_addr (hcmd_nlb_wr1_addr),
.wr1_data (hcmd_nlb_wr1_data),
.wr1_rdy_n (hcmd_nlb_wr1_rdy_n),
.rd_addr (hcmd_nlb_rd_addr),
.rd_data (hcmd_nlb_rd_data)
);
pcie_hcmd_slot_mgt
pcie_hcmd_slot_mgt_inst0
(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.hcmd_slot_rdy (w_hcmd_slot_rdy),
.hcmd_slot_tag (w_hcmd_slot_tag),
.hcmd_slot_alloc_en (w_hcmd_slot_alloc_en),
.hcmd_slot_free_en (w_hcmd_slot_free_en),
.hcmd_slot_invalid_tag (w_hcmd_slot_invalid_tag)
);
pcie_hcmd_sq # (
.C_PCIE_DATA_WIDTH (C_PCIE_DATA_WIDTH)
)
pcie_hcmd_sq_inst0(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.admin_sq_bs_addr (admin_sq_bs_addr),
.admin_sq_size (admin_sq_size),
.admin_sq_tail_ptr (admin_sq_tail_ptr),
.io_sq1_tail_ptr (io_sq1_tail_ptr),
.io_sq2_tail_ptr (io_sq2_tail_ptr),
.io_sq3_tail_ptr (io_sq3_tail_ptr),
.io_sq4_tail_ptr (io_sq4_tail_ptr),
.io_sq5_tail_ptr (io_sq5_tail_ptr),
.io_sq6_tail_ptr (io_sq6_tail_ptr),
.io_sq7_tail_ptr (io_sq7_tail_ptr),
.io_sq8_tail_ptr (io_sq8_tail_ptr),
.admin_sq_head_ptr (w_admin_sq_head_ptr),
.io_sq1_head_ptr (w_io_sq1_head_ptr),
.io_sq2_head_ptr (w_io_sq2_head_ptr),
.io_sq3_head_ptr (w_io_sq3_head_ptr),
.io_sq4_head_ptr (w_io_sq4_head_ptr),
.io_sq5_head_ptr (w_io_sq5_head_ptr),
.io_sq6_head_ptr (w_io_sq6_head_ptr),
.io_sq7_head_ptr (w_io_sq7_head_ptr),
.io_sq8_head_ptr (w_io_sq8_head_ptr),
.hcmd_slot_rdy (w_hcmd_slot_rdy),
.hcmd_slot_tag (w_hcmd_slot_tag),
.hcmd_slot_alloc_en (w_hcmd_slot_alloc_en),
.cpld_sq_fifo_tag (cpld_sq_fifo_tag),
.cpld_sq_fifo_wr_data (cpld_sq_fifo_wr_data),
.cpld_sq_fifo_wr_en (cpld_sq_fifo_wr_en),
.cpld_sq_fifo_tag_last (cpld_sq_fifo_tag_last),
.tx_mrd_req (tx_mrd_req),
.tx_mrd_tag (tx_mrd_tag),
.tx_mrd_len (tx_mrd_len),
.tx_mrd_addr (tx_mrd_addr),
.tx_mrd_req_ack (tx_mrd_req_ack),
.hcmd_table_wr_en (w_hcmd_table_wr_en),
.hcmd_table_wr_addr (w_hcmd_table_wr_addr),
.hcmd_table_wr_data (w_hcmd_table_wr_data),
.hcmd_cid_wr_en (w_hcmd_cid_wr_en),
.hcmd_cid_wr_addr (w_hcmd_cid_wr_addr),
.hcmd_cid_wr_data (w_hcmd_cid_wr_data),
.hcmd_prp_wr_en (w_hcmd_prp_wr_en),
.hcmd_prp_wr_addr (w_hcmd_prp_wr_addr),
.hcmd_prp_wr_data (w_hcmd_prp_wr_data),
.hcmd_nlb_wr0_en (w_hcmd_nlb_wr0_en),
.hcmd_nlb_wr0_addr (w_hcmd_nlb_wr0_addr),
.hcmd_nlb_wr0_data (w_hcmd_nlb_wr0_data),
.hcmd_nlb_wr0_rdy_n (w_hcmd_nlb_wr0_rdy_n),
.cpu_bus_clk (cpu_bus_clk),
.cpu_bus_rst_n (cpu_bus_rst_n),
.sq_rst_n (sq_rst_n),
.sq_valid (sq_valid),
.io_sq1_size (io_sq1_size),
.io_sq2_size (io_sq2_size),
.io_sq3_size (io_sq3_size),
.io_sq4_size (io_sq4_size),
.io_sq5_size (io_sq5_size),
.io_sq6_size (io_sq6_size),
.io_sq7_size (io_sq7_size),
.io_sq8_size (io_sq8_size),
.io_sq1_bs_addr (io_sq1_bs_addr),
.io_sq2_bs_addr (io_sq2_bs_addr),
.io_sq3_bs_addr (io_sq3_bs_addr),
.io_sq4_bs_addr (io_sq4_bs_addr),
.io_sq5_bs_addr (io_sq5_bs_addr),
.io_sq6_bs_addr (io_sq6_bs_addr),
.io_sq7_bs_addr (io_sq7_bs_addr),
.io_sq8_bs_addr (io_sq8_bs_addr),
.hcmd_sq_rd_en (hcmd_sq_rd_en),
.hcmd_sq_rd_data (hcmd_sq_rd_data),
.hcmd_sq_empty_n (hcmd_sq_empty_n)
);
pcie_hcmd_cq # (
.C_PCIE_DATA_WIDTH (C_PCIE_DATA_WIDTH)
)
pcie_hcmd_cq_inst0(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.hcmd_cid_rd_addr (w_hcmd_cid_rd_addr),
.hcmd_cid_rd_data (w_hcmd_cid_rd_data),
.admin_cq_bs_addr (admin_cq_bs_addr),
.admin_cq_size (admin_cq_size),
.admin_cq_tail_ptr (admin_cq_tail_ptr),
.io_cq1_tail_ptr (io_cq1_tail_ptr),
.io_cq2_tail_ptr (io_cq2_tail_ptr),
.io_cq3_tail_ptr (io_cq3_tail_ptr),
.io_cq4_tail_ptr (io_cq4_tail_ptr),
.io_cq5_tail_ptr (io_cq5_tail_ptr),
.io_cq6_tail_ptr (io_cq6_tail_ptr),
.io_cq7_tail_ptr (io_cq7_tail_ptr),
.io_cq8_tail_ptr (io_cq8_tail_ptr),
.admin_sq_head_ptr (w_admin_sq_head_ptr),
.io_sq1_head_ptr (w_io_sq1_head_ptr),
.io_sq2_head_ptr (w_io_sq2_head_ptr),
.io_sq3_head_ptr (w_io_sq3_head_ptr),
.io_sq4_head_ptr (w_io_sq4_head_ptr),
.io_sq5_head_ptr (w_io_sq5_head_ptr),
.io_sq6_head_ptr (w_io_sq6_head_ptr),
.io_sq7_head_ptr (w_io_sq7_head_ptr),
.io_sq8_head_ptr (w_io_sq8_head_ptr),
.hcmd_slot_free_en (w_hcmd_slot_free_en),
.hcmd_slot_invalid_tag (w_hcmd_slot_invalid_tag),
.tx_cq_mwr_req (tx_cq_mwr_req),
.tx_cq_mwr_tag (tx_cq_mwr_tag),
.tx_cq_mwr_len (tx_cq_mwr_len),
.tx_cq_mwr_addr (tx_cq_mwr_addr),
.tx_cq_mwr_req_ack (tx_cq_mwr_req_ack),
.tx_cq_mwr_rd_en (tx_cq_mwr_rd_en),
.tx_cq_mwr_rd_data (tx_cq_mwr_rd_data),
.tx_cq_mwr_data_last (tx_cq_mwr_data_last),
.hcmd_cq_wr0_en (hcmd_cq_wr0_en),
.hcmd_cq_wr0_data0 (hcmd_cq_wr0_data0),
.hcmd_cq_wr0_data1 (hcmd_cq_wr0_data1),
.hcmd_cq_wr0_rdy_n (hcmd_cq_wr0_rdy_n),
.cpu_bus_clk (cpu_bus_clk),
.cpu_bus_rst_n (cpu_bus_rst_n),
.io_sq1_cq_vec (io_sq1_cq_vec),
.io_sq2_cq_vec (io_sq2_cq_vec),
.io_sq3_cq_vec (io_sq3_cq_vec),
.io_sq4_cq_vec (io_sq4_cq_vec),
.io_sq5_cq_vec (io_sq5_cq_vec),
.io_sq6_cq_vec (io_sq6_cq_vec),
.io_sq7_cq_vec (io_sq7_cq_vec),
.io_sq8_cq_vec (io_sq8_cq_vec),
.sq_valid (sq_valid),
.cq_rst_n (cq_rst_n),
.cq_valid (cq_valid),
.io_cq1_size (io_cq1_size),
.io_cq2_size (io_cq2_size),
.io_cq3_size (io_cq3_size),
.io_cq4_size (io_cq4_size),
.io_cq5_size (io_cq5_size),
.io_cq6_size (io_cq6_size),
.io_cq7_size (io_cq7_size),
.io_cq8_size (io_cq8_size),
.io_cq1_bs_addr (io_cq1_bs_addr),
.io_cq2_bs_addr (io_cq2_bs_addr),
.io_cq3_bs_addr (io_cq3_bs_addr),
.io_cq4_bs_addr (io_cq4_bs_addr),
.io_cq5_bs_addr (io_cq5_bs_addr),
.io_cq6_bs_addr (io_cq6_bs_addr),
.io_cq7_bs_addr (io_cq7_bs_addr),
.io_cq8_bs_addr (io_cq8_bs_addr),
.hcmd_cq_wr1_en (hcmd_cq_wr1_en),
.hcmd_cq_wr1_data0 (hcmd_cq_wr1_data0),
.hcmd_cq_wr1_data1 (hcmd_cq_wr1_data1),
.hcmd_cq_wr1_rdy_n (hcmd_cq_wr1_rdy_n)
);
endmodule
|
/*
----------------------------------------------------------------------------------
Copyright (c) 2013-2014
Embedded and Network Computing Lab.
Open SSD Project
Hanyang University
All rights reserved.
----------------------------------------------------------------------------------
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. All advertising materials mentioning features or use of this source code
must display the following acknowledgement:
This product includes source code developed
by the Embedded and Network Computing Lab. and the Open SSD Project.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
----------------------------------------------------------------------------------
http://enclab.hanyang.ac.kr/
http://www.openssd-project.org/
http://www.hanyang.ac.kr/
----------------------------------------------------------------------------------
*/
`timescale 1ns / 1ps
module pcie_hcmd # (
parameter C_PCIE_DATA_WIDTH = 128,
parameter C_PCIE_ADDR_WIDTH = 36
)
(
input pcie_user_clk,
input pcie_user_rst_n,
input [C_PCIE_ADDR_WIDTH-1:2] admin_sq_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] admin_cq_bs_addr,
input [7:0] admin_sq_size,
input [7:0] admin_cq_size,
input [7:0] admin_sq_tail_ptr,
input [7:0] io_sq1_tail_ptr,
input [7:0] io_sq2_tail_ptr,
input [7:0] io_sq3_tail_ptr,
input [7:0] io_sq4_tail_ptr,
input [7:0] io_sq5_tail_ptr,
input [7:0] io_sq6_tail_ptr,
input [7:0] io_sq7_tail_ptr,
input [7:0] io_sq8_tail_ptr,
input [7:0] cpld_sq_fifo_tag,
input [C_PCIE_DATA_WIDTH-1:0] cpld_sq_fifo_wr_data,
input cpld_sq_fifo_wr_en,
input cpld_sq_fifo_tag_last,
output tx_mrd_req,
output [7:0] tx_mrd_tag,
output [11:2] tx_mrd_len,
output [C_PCIE_ADDR_WIDTH-1:2] tx_mrd_addr,
input tx_mrd_req_ack,
output [7:0] admin_cq_tail_ptr,
output [7:0] io_cq1_tail_ptr,
output [7:0] io_cq2_tail_ptr,
output [7:0] io_cq3_tail_ptr,
output [7:0] io_cq4_tail_ptr,
output [7:0] io_cq5_tail_ptr,
output [7:0] io_cq6_tail_ptr,
output [7:0] io_cq7_tail_ptr,
output [7:0] io_cq8_tail_ptr,
output tx_cq_mwr_req,
output [7:0] tx_cq_mwr_tag,
output [11:2] tx_cq_mwr_len,
output [C_PCIE_ADDR_WIDTH-1:2] tx_cq_mwr_addr,
input tx_cq_mwr_req_ack,
input tx_cq_mwr_rd_en,
output [C_PCIE_DATA_WIDTH-1:0] tx_cq_mwr_rd_data,
input tx_cq_mwr_data_last,
input [7:0] hcmd_prp_rd_addr,
output [44:0] hcmd_prp_rd_data,
input hcmd_nlb_wr1_en,
input [6:0] hcmd_nlb_wr1_addr,
input [18:0] hcmd_nlb_wr1_data,
output hcmd_nlb_wr1_rdy_n,
input [6:0] hcmd_nlb_rd_addr,
output [18:0] hcmd_nlb_rd_data,
input hcmd_cq_wr0_en,
input [34:0] hcmd_cq_wr0_data0,
input [34:0] hcmd_cq_wr0_data1,
output hcmd_cq_wr0_rdy_n,
input cpu_bus_clk,
input cpu_bus_rst_n,
input [8:0] sq_rst_n,
input [8:0] sq_valid,
input [7:0] io_sq1_size,
input [7:0] io_sq2_size,
input [7:0] io_sq3_size,
input [7:0] io_sq4_size,
input [7:0] io_sq5_size,
input [7:0] io_sq6_size,
input [7:0] io_sq7_size,
input [7:0] io_sq8_size,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq1_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq2_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq3_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq4_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq5_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq6_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq7_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq8_bs_addr,
input [3:0] io_sq1_cq_vec,
input [3:0] io_sq2_cq_vec,
input [3:0] io_sq3_cq_vec,
input [3:0] io_sq4_cq_vec,
input [3:0] io_sq5_cq_vec,
input [3:0] io_sq6_cq_vec,
input [3:0] io_sq7_cq_vec,
input [3:0] io_sq8_cq_vec,
input [8:0] cq_rst_n,
input [8:0] cq_valid,
input [7:0] io_cq1_size,
input [7:0] io_cq2_size,
input [7:0] io_cq3_size,
input [7:0] io_cq4_size,
input [7:0] io_cq5_size,
input [7:0] io_cq6_size,
input [7:0] io_cq7_size,
input [7:0] io_cq8_size,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq1_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq2_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq3_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq4_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq5_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq6_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq7_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq8_bs_addr,
input hcmd_sq_rd_en,
output [18:0] hcmd_sq_rd_data,
output hcmd_sq_empty_n,
input [10:0] hcmd_table_rd_addr,
output [31:0] hcmd_table_rd_data,
input hcmd_cq_wr1_en,
input [34:0] hcmd_cq_wr1_data0,
input [34:0] hcmd_cq_wr1_data1,
output hcmd_cq_wr1_rdy_n
);
wire w_hcmd_table_wr_en;
wire [8:0] w_hcmd_table_wr_addr;
wire [127:0] w_hcmd_table_wr_data;
wire w_hcmd_cid_wr_en;
wire [6:0] w_hcmd_cid_wr_addr;
wire [19:0] w_hcmd_cid_wr_data;
wire [6:0] w_hcmd_cid_rd_addr;
wire [19:0] w_hcmd_cid_rd_data;
wire w_hcmd_prp_wr_en;
wire [7:0] w_hcmd_prp_wr_addr;
wire [44:0] w_hcmd_prp_wr_data;
wire w_hcmd_nlb_wr0_en;
wire [6:0] w_hcmd_nlb_wr0_addr;
wire [18:0] w_hcmd_nlb_wr0_data;
wire w_hcmd_nlb_wr0_rdy_n;
wire w_hcmd_slot_rdy;
wire [6:0] w_hcmd_slot_tag;
wire w_hcmd_slot_alloc_en;
wire w_hcmd_slot_free_en;
wire [6:0] w_hcmd_slot_invalid_tag;
wire [7:0] w_admin_sq_head_ptr;
wire [7:0] w_io_sq1_head_ptr;
wire [7:0] w_io_sq2_head_ptr;
wire [7:0] w_io_sq3_head_ptr;
wire [7:0] w_io_sq4_head_ptr;
wire [7:0] w_io_sq5_head_ptr;
wire [7:0] w_io_sq6_head_ptr;
wire [7:0] w_io_sq7_head_ptr;
wire [7:0] w_io_sq8_head_ptr;
pcie_hcmd_table
pcie_hcmd_table_inst0(
.wr_clk (pcie_user_clk),
.wr_en (w_hcmd_table_wr_en),
.wr_addr (w_hcmd_table_wr_addr),
.wr_data (w_hcmd_table_wr_data),
.rd_clk (cpu_bus_clk),
.rd_addr (hcmd_table_rd_addr),
.rd_data (hcmd_table_rd_data)
);
pcie_hcmd_table_cid
pcie_hcmd_table_cid_isnt0(
.clk (pcie_user_clk),
.wr_en (w_hcmd_cid_wr_en),
.wr_addr (w_hcmd_cid_wr_addr),
.wr_data (w_hcmd_cid_wr_data),
.rd_addr (w_hcmd_cid_rd_addr),
.rd_data (w_hcmd_cid_rd_data)
);
pcie_hcmd_table_prp
pcie_hcmd_table_prp_isnt0(
.clk (pcie_user_clk),
.wr_en (w_hcmd_prp_wr_en),
.wr_addr (w_hcmd_prp_wr_addr),
.wr_data (w_hcmd_prp_wr_data),
.rd_addr (hcmd_prp_rd_addr),
.rd_data (hcmd_prp_rd_data)
);
pcie_hcmd_nlb
pcie_hcmd_nlb_inst0
(
.clk (pcie_user_clk),
.rst_n (pcie_user_rst_n),
.wr0_en (w_hcmd_nlb_wr0_en),
.wr0_addr (w_hcmd_nlb_wr0_addr),
.wr0_data (w_hcmd_nlb_wr0_data),
.wr0_rdy_n (w_hcmd_nlb_wr0_rdy_n),
.wr1_en (hcmd_nlb_wr1_en),
.wr1_addr (hcmd_nlb_wr1_addr),
.wr1_data (hcmd_nlb_wr1_data),
.wr1_rdy_n (hcmd_nlb_wr1_rdy_n),
.rd_addr (hcmd_nlb_rd_addr),
.rd_data (hcmd_nlb_rd_data)
);
pcie_hcmd_slot_mgt
pcie_hcmd_slot_mgt_inst0
(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.hcmd_slot_rdy (w_hcmd_slot_rdy),
.hcmd_slot_tag (w_hcmd_slot_tag),
.hcmd_slot_alloc_en (w_hcmd_slot_alloc_en),
.hcmd_slot_free_en (w_hcmd_slot_free_en),
.hcmd_slot_invalid_tag (w_hcmd_slot_invalid_tag)
);
pcie_hcmd_sq # (
.C_PCIE_DATA_WIDTH (C_PCIE_DATA_WIDTH)
)
pcie_hcmd_sq_inst0(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.admin_sq_bs_addr (admin_sq_bs_addr),
.admin_sq_size (admin_sq_size),
.admin_sq_tail_ptr (admin_sq_tail_ptr),
.io_sq1_tail_ptr (io_sq1_tail_ptr),
.io_sq2_tail_ptr (io_sq2_tail_ptr),
.io_sq3_tail_ptr (io_sq3_tail_ptr),
.io_sq4_tail_ptr (io_sq4_tail_ptr),
.io_sq5_tail_ptr (io_sq5_tail_ptr),
.io_sq6_tail_ptr (io_sq6_tail_ptr),
.io_sq7_tail_ptr (io_sq7_tail_ptr),
.io_sq8_tail_ptr (io_sq8_tail_ptr),
.admin_sq_head_ptr (w_admin_sq_head_ptr),
.io_sq1_head_ptr (w_io_sq1_head_ptr),
.io_sq2_head_ptr (w_io_sq2_head_ptr),
.io_sq3_head_ptr (w_io_sq3_head_ptr),
.io_sq4_head_ptr (w_io_sq4_head_ptr),
.io_sq5_head_ptr (w_io_sq5_head_ptr),
.io_sq6_head_ptr (w_io_sq6_head_ptr),
.io_sq7_head_ptr (w_io_sq7_head_ptr),
.io_sq8_head_ptr (w_io_sq8_head_ptr),
.hcmd_slot_rdy (w_hcmd_slot_rdy),
.hcmd_slot_tag (w_hcmd_slot_tag),
.hcmd_slot_alloc_en (w_hcmd_slot_alloc_en),
.cpld_sq_fifo_tag (cpld_sq_fifo_tag),
.cpld_sq_fifo_wr_data (cpld_sq_fifo_wr_data),
.cpld_sq_fifo_wr_en (cpld_sq_fifo_wr_en),
.cpld_sq_fifo_tag_last (cpld_sq_fifo_tag_last),
.tx_mrd_req (tx_mrd_req),
.tx_mrd_tag (tx_mrd_tag),
.tx_mrd_len (tx_mrd_len),
.tx_mrd_addr (tx_mrd_addr),
.tx_mrd_req_ack (tx_mrd_req_ack),
.hcmd_table_wr_en (w_hcmd_table_wr_en),
.hcmd_table_wr_addr (w_hcmd_table_wr_addr),
.hcmd_table_wr_data (w_hcmd_table_wr_data),
.hcmd_cid_wr_en (w_hcmd_cid_wr_en),
.hcmd_cid_wr_addr (w_hcmd_cid_wr_addr),
.hcmd_cid_wr_data (w_hcmd_cid_wr_data),
.hcmd_prp_wr_en (w_hcmd_prp_wr_en),
.hcmd_prp_wr_addr (w_hcmd_prp_wr_addr),
.hcmd_prp_wr_data (w_hcmd_prp_wr_data),
.hcmd_nlb_wr0_en (w_hcmd_nlb_wr0_en),
.hcmd_nlb_wr0_addr (w_hcmd_nlb_wr0_addr),
.hcmd_nlb_wr0_data (w_hcmd_nlb_wr0_data),
.hcmd_nlb_wr0_rdy_n (w_hcmd_nlb_wr0_rdy_n),
.cpu_bus_clk (cpu_bus_clk),
.cpu_bus_rst_n (cpu_bus_rst_n),
.sq_rst_n (sq_rst_n),
.sq_valid (sq_valid),
.io_sq1_size (io_sq1_size),
.io_sq2_size (io_sq2_size),
.io_sq3_size (io_sq3_size),
.io_sq4_size (io_sq4_size),
.io_sq5_size (io_sq5_size),
.io_sq6_size (io_sq6_size),
.io_sq7_size (io_sq7_size),
.io_sq8_size (io_sq8_size),
.io_sq1_bs_addr (io_sq1_bs_addr),
.io_sq2_bs_addr (io_sq2_bs_addr),
.io_sq3_bs_addr (io_sq3_bs_addr),
.io_sq4_bs_addr (io_sq4_bs_addr),
.io_sq5_bs_addr (io_sq5_bs_addr),
.io_sq6_bs_addr (io_sq6_bs_addr),
.io_sq7_bs_addr (io_sq7_bs_addr),
.io_sq8_bs_addr (io_sq8_bs_addr),
.hcmd_sq_rd_en (hcmd_sq_rd_en),
.hcmd_sq_rd_data (hcmd_sq_rd_data),
.hcmd_sq_empty_n (hcmd_sq_empty_n)
);
pcie_hcmd_cq # (
.C_PCIE_DATA_WIDTH (C_PCIE_DATA_WIDTH)
)
pcie_hcmd_cq_inst0(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.hcmd_cid_rd_addr (w_hcmd_cid_rd_addr),
.hcmd_cid_rd_data (w_hcmd_cid_rd_data),
.admin_cq_bs_addr (admin_cq_bs_addr),
.admin_cq_size (admin_cq_size),
.admin_cq_tail_ptr (admin_cq_tail_ptr),
.io_cq1_tail_ptr (io_cq1_tail_ptr),
.io_cq2_tail_ptr (io_cq2_tail_ptr),
.io_cq3_tail_ptr (io_cq3_tail_ptr),
.io_cq4_tail_ptr (io_cq4_tail_ptr),
.io_cq5_tail_ptr (io_cq5_tail_ptr),
.io_cq6_tail_ptr (io_cq6_tail_ptr),
.io_cq7_tail_ptr (io_cq7_tail_ptr),
.io_cq8_tail_ptr (io_cq8_tail_ptr),
.admin_sq_head_ptr (w_admin_sq_head_ptr),
.io_sq1_head_ptr (w_io_sq1_head_ptr),
.io_sq2_head_ptr (w_io_sq2_head_ptr),
.io_sq3_head_ptr (w_io_sq3_head_ptr),
.io_sq4_head_ptr (w_io_sq4_head_ptr),
.io_sq5_head_ptr (w_io_sq5_head_ptr),
.io_sq6_head_ptr (w_io_sq6_head_ptr),
.io_sq7_head_ptr (w_io_sq7_head_ptr),
.io_sq8_head_ptr (w_io_sq8_head_ptr),
.hcmd_slot_free_en (w_hcmd_slot_free_en),
.hcmd_slot_invalid_tag (w_hcmd_slot_invalid_tag),
.tx_cq_mwr_req (tx_cq_mwr_req),
.tx_cq_mwr_tag (tx_cq_mwr_tag),
.tx_cq_mwr_len (tx_cq_mwr_len),
.tx_cq_mwr_addr (tx_cq_mwr_addr),
.tx_cq_mwr_req_ack (tx_cq_mwr_req_ack),
.tx_cq_mwr_rd_en (tx_cq_mwr_rd_en),
.tx_cq_mwr_rd_data (tx_cq_mwr_rd_data),
.tx_cq_mwr_data_last (tx_cq_mwr_data_last),
.hcmd_cq_wr0_en (hcmd_cq_wr0_en),
.hcmd_cq_wr0_data0 (hcmd_cq_wr0_data0),
.hcmd_cq_wr0_data1 (hcmd_cq_wr0_data1),
.hcmd_cq_wr0_rdy_n (hcmd_cq_wr0_rdy_n),
.cpu_bus_clk (cpu_bus_clk),
.cpu_bus_rst_n (cpu_bus_rst_n),
.io_sq1_cq_vec (io_sq1_cq_vec),
.io_sq2_cq_vec (io_sq2_cq_vec),
.io_sq3_cq_vec (io_sq3_cq_vec),
.io_sq4_cq_vec (io_sq4_cq_vec),
.io_sq5_cq_vec (io_sq5_cq_vec),
.io_sq6_cq_vec (io_sq6_cq_vec),
.io_sq7_cq_vec (io_sq7_cq_vec),
.io_sq8_cq_vec (io_sq8_cq_vec),
.sq_valid (sq_valid),
.cq_rst_n (cq_rst_n),
.cq_valid (cq_valid),
.io_cq1_size (io_cq1_size),
.io_cq2_size (io_cq2_size),
.io_cq3_size (io_cq3_size),
.io_cq4_size (io_cq4_size),
.io_cq5_size (io_cq5_size),
.io_cq6_size (io_cq6_size),
.io_cq7_size (io_cq7_size),
.io_cq8_size (io_cq8_size),
.io_cq1_bs_addr (io_cq1_bs_addr),
.io_cq2_bs_addr (io_cq2_bs_addr),
.io_cq3_bs_addr (io_cq3_bs_addr),
.io_cq4_bs_addr (io_cq4_bs_addr),
.io_cq5_bs_addr (io_cq5_bs_addr),
.io_cq6_bs_addr (io_cq6_bs_addr),
.io_cq7_bs_addr (io_cq7_bs_addr),
.io_cq8_bs_addr (io_cq8_bs_addr),
.hcmd_cq_wr1_en (hcmd_cq_wr1_en),
.hcmd_cq_wr1_data0 (hcmd_cq_wr1_data0),
.hcmd_cq_wr1_data1 (hcmd_cq_wr1_data1),
.hcmd_cq_wr1_rdy_n (hcmd_cq_wr1_rdy_n)
);
endmodule
|
/*
----------------------------------------------------------------------------------
Copyright (c) 2013-2014
Embedded and Network Computing Lab.
Open SSD Project
Hanyang University
All rights reserved.
----------------------------------------------------------------------------------
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. All advertising materials mentioning features or use of this source code
must display the following acknowledgement:
This product includes source code developed
by the Embedded and Network Computing Lab. and the Open SSD Project.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
----------------------------------------------------------------------------------
http://enclab.hanyang.ac.kr/
http://www.openssd-project.org/
http://www.hanyang.ac.kr/
----------------------------------------------------------------------------------
*/
`timescale 1ns / 1ps
module pcie_hcmd # (
parameter C_PCIE_DATA_WIDTH = 128,
parameter C_PCIE_ADDR_WIDTH = 36
)
(
input pcie_user_clk,
input pcie_user_rst_n,
input [C_PCIE_ADDR_WIDTH-1:2] admin_sq_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] admin_cq_bs_addr,
input [7:0] admin_sq_size,
input [7:0] admin_cq_size,
input [7:0] admin_sq_tail_ptr,
input [7:0] io_sq1_tail_ptr,
input [7:0] io_sq2_tail_ptr,
input [7:0] io_sq3_tail_ptr,
input [7:0] io_sq4_tail_ptr,
input [7:0] io_sq5_tail_ptr,
input [7:0] io_sq6_tail_ptr,
input [7:0] io_sq7_tail_ptr,
input [7:0] io_sq8_tail_ptr,
input [7:0] cpld_sq_fifo_tag,
input [C_PCIE_DATA_WIDTH-1:0] cpld_sq_fifo_wr_data,
input cpld_sq_fifo_wr_en,
input cpld_sq_fifo_tag_last,
output tx_mrd_req,
output [7:0] tx_mrd_tag,
output [11:2] tx_mrd_len,
output [C_PCIE_ADDR_WIDTH-1:2] tx_mrd_addr,
input tx_mrd_req_ack,
output [7:0] admin_cq_tail_ptr,
output [7:0] io_cq1_tail_ptr,
output [7:0] io_cq2_tail_ptr,
output [7:0] io_cq3_tail_ptr,
output [7:0] io_cq4_tail_ptr,
output [7:0] io_cq5_tail_ptr,
output [7:0] io_cq6_tail_ptr,
output [7:0] io_cq7_tail_ptr,
output [7:0] io_cq8_tail_ptr,
output tx_cq_mwr_req,
output [7:0] tx_cq_mwr_tag,
output [11:2] tx_cq_mwr_len,
output [C_PCIE_ADDR_WIDTH-1:2] tx_cq_mwr_addr,
input tx_cq_mwr_req_ack,
input tx_cq_mwr_rd_en,
output [C_PCIE_DATA_WIDTH-1:0] tx_cq_mwr_rd_data,
input tx_cq_mwr_data_last,
input [7:0] hcmd_prp_rd_addr,
output [44:0] hcmd_prp_rd_data,
input hcmd_nlb_wr1_en,
input [6:0] hcmd_nlb_wr1_addr,
input [18:0] hcmd_nlb_wr1_data,
output hcmd_nlb_wr1_rdy_n,
input [6:0] hcmd_nlb_rd_addr,
output [18:0] hcmd_nlb_rd_data,
input hcmd_cq_wr0_en,
input [34:0] hcmd_cq_wr0_data0,
input [34:0] hcmd_cq_wr0_data1,
output hcmd_cq_wr0_rdy_n,
input cpu_bus_clk,
input cpu_bus_rst_n,
input [8:0] sq_rst_n,
input [8:0] sq_valid,
input [7:0] io_sq1_size,
input [7:0] io_sq2_size,
input [7:0] io_sq3_size,
input [7:0] io_sq4_size,
input [7:0] io_sq5_size,
input [7:0] io_sq6_size,
input [7:0] io_sq7_size,
input [7:0] io_sq8_size,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq1_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq2_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq3_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq4_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq5_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq6_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq7_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq8_bs_addr,
input [3:0] io_sq1_cq_vec,
input [3:0] io_sq2_cq_vec,
input [3:0] io_sq3_cq_vec,
input [3:0] io_sq4_cq_vec,
input [3:0] io_sq5_cq_vec,
input [3:0] io_sq6_cq_vec,
input [3:0] io_sq7_cq_vec,
input [3:0] io_sq8_cq_vec,
input [8:0] cq_rst_n,
input [8:0] cq_valid,
input [7:0] io_cq1_size,
input [7:0] io_cq2_size,
input [7:0] io_cq3_size,
input [7:0] io_cq4_size,
input [7:0] io_cq5_size,
input [7:0] io_cq6_size,
input [7:0] io_cq7_size,
input [7:0] io_cq8_size,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq1_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq2_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq3_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq4_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq5_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq6_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq7_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq8_bs_addr,
input hcmd_sq_rd_en,
output [18:0] hcmd_sq_rd_data,
output hcmd_sq_empty_n,
input [10:0] hcmd_table_rd_addr,
output [31:0] hcmd_table_rd_data,
input hcmd_cq_wr1_en,
input [34:0] hcmd_cq_wr1_data0,
input [34:0] hcmd_cq_wr1_data1,
output hcmd_cq_wr1_rdy_n
);
wire w_hcmd_table_wr_en;
wire [8:0] w_hcmd_table_wr_addr;
wire [127:0] w_hcmd_table_wr_data;
wire w_hcmd_cid_wr_en;
wire [6:0] w_hcmd_cid_wr_addr;
wire [19:0] w_hcmd_cid_wr_data;
wire [6:0] w_hcmd_cid_rd_addr;
wire [19:0] w_hcmd_cid_rd_data;
wire w_hcmd_prp_wr_en;
wire [7:0] w_hcmd_prp_wr_addr;
wire [44:0] w_hcmd_prp_wr_data;
wire w_hcmd_nlb_wr0_en;
wire [6:0] w_hcmd_nlb_wr0_addr;
wire [18:0] w_hcmd_nlb_wr0_data;
wire w_hcmd_nlb_wr0_rdy_n;
wire w_hcmd_slot_rdy;
wire [6:0] w_hcmd_slot_tag;
wire w_hcmd_slot_alloc_en;
wire w_hcmd_slot_free_en;
wire [6:0] w_hcmd_slot_invalid_tag;
wire [7:0] w_admin_sq_head_ptr;
wire [7:0] w_io_sq1_head_ptr;
wire [7:0] w_io_sq2_head_ptr;
wire [7:0] w_io_sq3_head_ptr;
wire [7:0] w_io_sq4_head_ptr;
wire [7:0] w_io_sq5_head_ptr;
wire [7:0] w_io_sq6_head_ptr;
wire [7:0] w_io_sq7_head_ptr;
wire [7:0] w_io_sq8_head_ptr;
pcie_hcmd_table
pcie_hcmd_table_inst0(
.wr_clk (pcie_user_clk),
.wr_en (w_hcmd_table_wr_en),
.wr_addr (w_hcmd_table_wr_addr),
.wr_data (w_hcmd_table_wr_data),
.rd_clk (cpu_bus_clk),
.rd_addr (hcmd_table_rd_addr),
.rd_data (hcmd_table_rd_data)
);
pcie_hcmd_table_cid
pcie_hcmd_table_cid_isnt0(
.clk (pcie_user_clk),
.wr_en (w_hcmd_cid_wr_en),
.wr_addr (w_hcmd_cid_wr_addr),
.wr_data (w_hcmd_cid_wr_data),
.rd_addr (w_hcmd_cid_rd_addr),
.rd_data (w_hcmd_cid_rd_data)
);
pcie_hcmd_table_prp
pcie_hcmd_table_prp_isnt0(
.clk (pcie_user_clk),
.wr_en (w_hcmd_prp_wr_en),
.wr_addr (w_hcmd_prp_wr_addr),
.wr_data (w_hcmd_prp_wr_data),
.rd_addr (hcmd_prp_rd_addr),
.rd_data (hcmd_prp_rd_data)
);
pcie_hcmd_nlb
pcie_hcmd_nlb_inst0
(
.clk (pcie_user_clk),
.rst_n (pcie_user_rst_n),
.wr0_en (w_hcmd_nlb_wr0_en),
.wr0_addr (w_hcmd_nlb_wr0_addr),
.wr0_data (w_hcmd_nlb_wr0_data),
.wr0_rdy_n (w_hcmd_nlb_wr0_rdy_n),
.wr1_en (hcmd_nlb_wr1_en),
.wr1_addr (hcmd_nlb_wr1_addr),
.wr1_data (hcmd_nlb_wr1_data),
.wr1_rdy_n (hcmd_nlb_wr1_rdy_n),
.rd_addr (hcmd_nlb_rd_addr),
.rd_data (hcmd_nlb_rd_data)
);
pcie_hcmd_slot_mgt
pcie_hcmd_slot_mgt_inst0
(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.hcmd_slot_rdy (w_hcmd_slot_rdy),
.hcmd_slot_tag (w_hcmd_slot_tag),
.hcmd_slot_alloc_en (w_hcmd_slot_alloc_en),
.hcmd_slot_free_en (w_hcmd_slot_free_en),
.hcmd_slot_invalid_tag (w_hcmd_slot_invalid_tag)
);
pcie_hcmd_sq # (
.C_PCIE_DATA_WIDTH (C_PCIE_DATA_WIDTH)
)
pcie_hcmd_sq_inst0(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.admin_sq_bs_addr (admin_sq_bs_addr),
.admin_sq_size (admin_sq_size),
.admin_sq_tail_ptr (admin_sq_tail_ptr),
.io_sq1_tail_ptr (io_sq1_tail_ptr),
.io_sq2_tail_ptr (io_sq2_tail_ptr),
.io_sq3_tail_ptr (io_sq3_tail_ptr),
.io_sq4_tail_ptr (io_sq4_tail_ptr),
.io_sq5_tail_ptr (io_sq5_tail_ptr),
.io_sq6_tail_ptr (io_sq6_tail_ptr),
.io_sq7_tail_ptr (io_sq7_tail_ptr),
.io_sq8_tail_ptr (io_sq8_tail_ptr),
.admin_sq_head_ptr (w_admin_sq_head_ptr),
.io_sq1_head_ptr (w_io_sq1_head_ptr),
.io_sq2_head_ptr (w_io_sq2_head_ptr),
.io_sq3_head_ptr (w_io_sq3_head_ptr),
.io_sq4_head_ptr (w_io_sq4_head_ptr),
.io_sq5_head_ptr (w_io_sq5_head_ptr),
.io_sq6_head_ptr (w_io_sq6_head_ptr),
.io_sq7_head_ptr (w_io_sq7_head_ptr),
.io_sq8_head_ptr (w_io_sq8_head_ptr),
.hcmd_slot_rdy (w_hcmd_slot_rdy),
.hcmd_slot_tag (w_hcmd_slot_tag),
.hcmd_slot_alloc_en (w_hcmd_slot_alloc_en),
.cpld_sq_fifo_tag (cpld_sq_fifo_tag),
.cpld_sq_fifo_wr_data (cpld_sq_fifo_wr_data),
.cpld_sq_fifo_wr_en (cpld_sq_fifo_wr_en),
.cpld_sq_fifo_tag_last (cpld_sq_fifo_tag_last),
.tx_mrd_req (tx_mrd_req),
.tx_mrd_tag (tx_mrd_tag),
.tx_mrd_len (tx_mrd_len),
.tx_mrd_addr (tx_mrd_addr),
.tx_mrd_req_ack (tx_mrd_req_ack),
.hcmd_table_wr_en (w_hcmd_table_wr_en),
.hcmd_table_wr_addr (w_hcmd_table_wr_addr),
.hcmd_table_wr_data (w_hcmd_table_wr_data),
.hcmd_cid_wr_en (w_hcmd_cid_wr_en),
.hcmd_cid_wr_addr (w_hcmd_cid_wr_addr),
.hcmd_cid_wr_data (w_hcmd_cid_wr_data),
.hcmd_prp_wr_en (w_hcmd_prp_wr_en),
.hcmd_prp_wr_addr (w_hcmd_prp_wr_addr),
.hcmd_prp_wr_data (w_hcmd_prp_wr_data),
.hcmd_nlb_wr0_en (w_hcmd_nlb_wr0_en),
.hcmd_nlb_wr0_addr (w_hcmd_nlb_wr0_addr),
.hcmd_nlb_wr0_data (w_hcmd_nlb_wr0_data),
.hcmd_nlb_wr0_rdy_n (w_hcmd_nlb_wr0_rdy_n),
.cpu_bus_clk (cpu_bus_clk),
.cpu_bus_rst_n (cpu_bus_rst_n),
.sq_rst_n (sq_rst_n),
.sq_valid (sq_valid),
.io_sq1_size (io_sq1_size),
.io_sq2_size (io_sq2_size),
.io_sq3_size (io_sq3_size),
.io_sq4_size (io_sq4_size),
.io_sq5_size (io_sq5_size),
.io_sq6_size (io_sq6_size),
.io_sq7_size (io_sq7_size),
.io_sq8_size (io_sq8_size),
.io_sq1_bs_addr (io_sq1_bs_addr),
.io_sq2_bs_addr (io_sq2_bs_addr),
.io_sq3_bs_addr (io_sq3_bs_addr),
.io_sq4_bs_addr (io_sq4_bs_addr),
.io_sq5_bs_addr (io_sq5_bs_addr),
.io_sq6_bs_addr (io_sq6_bs_addr),
.io_sq7_bs_addr (io_sq7_bs_addr),
.io_sq8_bs_addr (io_sq8_bs_addr),
.hcmd_sq_rd_en (hcmd_sq_rd_en),
.hcmd_sq_rd_data (hcmd_sq_rd_data),
.hcmd_sq_empty_n (hcmd_sq_empty_n)
);
pcie_hcmd_cq # (
.C_PCIE_DATA_WIDTH (C_PCIE_DATA_WIDTH)
)
pcie_hcmd_cq_inst0(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.hcmd_cid_rd_addr (w_hcmd_cid_rd_addr),
.hcmd_cid_rd_data (w_hcmd_cid_rd_data),
.admin_cq_bs_addr (admin_cq_bs_addr),
.admin_cq_size (admin_cq_size),
.admin_cq_tail_ptr (admin_cq_tail_ptr),
.io_cq1_tail_ptr (io_cq1_tail_ptr),
.io_cq2_tail_ptr (io_cq2_tail_ptr),
.io_cq3_tail_ptr (io_cq3_tail_ptr),
.io_cq4_tail_ptr (io_cq4_tail_ptr),
.io_cq5_tail_ptr (io_cq5_tail_ptr),
.io_cq6_tail_ptr (io_cq6_tail_ptr),
.io_cq7_tail_ptr (io_cq7_tail_ptr),
.io_cq8_tail_ptr (io_cq8_tail_ptr),
.admin_sq_head_ptr (w_admin_sq_head_ptr),
.io_sq1_head_ptr (w_io_sq1_head_ptr),
.io_sq2_head_ptr (w_io_sq2_head_ptr),
.io_sq3_head_ptr (w_io_sq3_head_ptr),
.io_sq4_head_ptr (w_io_sq4_head_ptr),
.io_sq5_head_ptr (w_io_sq5_head_ptr),
.io_sq6_head_ptr (w_io_sq6_head_ptr),
.io_sq7_head_ptr (w_io_sq7_head_ptr),
.io_sq8_head_ptr (w_io_sq8_head_ptr),
.hcmd_slot_free_en (w_hcmd_slot_free_en),
.hcmd_slot_invalid_tag (w_hcmd_slot_invalid_tag),
.tx_cq_mwr_req (tx_cq_mwr_req),
.tx_cq_mwr_tag (tx_cq_mwr_tag),
.tx_cq_mwr_len (tx_cq_mwr_len),
.tx_cq_mwr_addr (tx_cq_mwr_addr),
.tx_cq_mwr_req_ack (tx_cq_mwr_req_ack),
.tx_cq_mwr_rd_en (tx_cq_mwr_rd_en),
.tx_cq_mwr_rd_data (tx_cq_mwr_rd_data),
.tx_cq_mwr_data_last (tx_cq_mwr_data_last),
.hcmd_cq_wr0_en (hcmd_cq_wr0_en),
.hcmd_cq_wr0_data0 (hcmd_cq_wr0_data0),
.hcmd_cq_wr0_data1 (hcmd_cq_wr0_data1),
.hcmd_cq_wr0_rdy_n (hcmd_cq_wr0_rdy_n),
.cpu_bus_clk (cpu_bus_clk),
.cpu_bus_rst_n (cpu_bus_rst_n),
.io_sq1_cq_vec (io_sq1_cq_vec),
.io_sq2_cq_vec (io_sq2_cq_vec),
.io_sq3_cq_vec (io_sq3_cq_vec),
.io_sq4_cq_vec (io_sq4_cq_vec),
.io_sq5_cq_vec (io_sq5_cq_vec),
.io_sq6_cq_vec (io_sq6_cq_vec),
.io_sq7_cq_vec (io_sq7_cq_vec),
.io_sq8_cq_vec (io_sq8_cq_vec),
.sq_valid (sq_valid),
.cq_rst_n (cq_rst_n),
.cq_valid (cq_valid),
.io_cq1_size (io_cq1_size),
.io_cq2_size (io_cq2_size),
.io_cq3_size (io_cq3_size),
.io_cq4_size (io_cq4_size),
.io_cq5_size (io_cq5_size),
.io_cq6_size (io_cq6_size),
.io_cq7_size (io_cq7_size),
.io_cq8_size (io_cq8_size),
.io_cq1_bs_addr (io_cq1_bs_addr),
.io_cq2_bs_addr (io_cq2_bs_addr),
.io_cq3_bs_addr (io_cq3_bs_addr),
.io_cq4_bs_addr (io_cq4_bs_addr),
.io_cq5_bs_addr (io_cq5_bs_addr),
.io_cq6_bs_addr (io_cq6_bs_addr),
.io_cq7_bs_addr (io_cq7_bs_addr),
.io_cq8_bs_addr (io_cq8_bs_addr),
.hcmd_cq_wr1_en (hcmd_cq_wr1_en),
.hcmd_cq_wr1_data0 (hcmd_cq_wr1_data0),
.hcmd_cq_wr1_data1 (hcmd_cq_wr1_data1),
.hcmd_cq_wr1_rdy_n (hcmd_cq_wr1_rdy_n)
);
endmodule
|
/*
----------------------------------------------------------------------------------
Copyright (c) 2013-2014
Embedded and Network Computing Lab.
Open SSD Project
Hanyang University
All rights reserved.
----------------------------------------------------------------------------------
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. All advertising materials mentioning features or use of this source code
must display the following acknowledgement:
This product includes source code developed
by the Embedded and Network Computing Lab. and the Open SSD Project.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
----------------------------------------------------------------------------------
http://enclab.hanyang.ac.kr/
http://www.openssd-project.org/
http://www.hanyang.ac.kr/
----------------------------------------------------------------------------------
*/
`timescale 1ns / 1ps
module pcie_hcmd # (
parameter C_PCIE_DATA_WIDTH = 128,
parameter C_PCIE_ADDR_WIDTH = 36
)
(
input pcie_user_clk,
input pcie_user_rst_n,
input [C_PCIE_ADDR_WIDTH-1:2] admin_sq_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] admin_cq_bs_addr,
input [7:0] admin_sq_size,
input [7:0] admin_cq_size,
input [7:0] admin_sq_tail_ptr,
input [7:0] io_sq1_tail_ptr,
input [7:0] io_sq2_tail_ptr,
input [7:0] io_sq3_tail_ptr,
input [7:0] io_sq4_tail_ptr,
input [7:0] io_sq5_tail_ptr,
input [7:0] io_sq6_tail_ptr,
input [7:0] io_sq7_tail_ptr,
input [7:0] io_sq8_tail_ptr,
input [7:0] cpld_sq_fifo_tag,
input [C_PCIE_DATA_WIDTH-1:0] cpld_sq_fifo_wr_data,
input cpld_sq_fifo_wr_en,
input cpld_sq_fifo_tag_last,
output tx_mrd_req,
output [7:0] tx_mrd_tag,
output [11:2] tx_mrd_len,
output [C_PCIE_ADDR_WIDTH-1:2] tx_mrd_addr,
input tx_mrd_req_ack,
output [7:0] admin_cq_tail_ptr,
output [7:0] io_cq1_tail_ptr,
output [7:0] io_cq2_tail_ptr,
output [7:0] io_cq3_tail_ptr,
output [7:0] io_cq4_tail_ptr,
output [7:0] io_cq5_tail_ptr,
output [7:0] io_cq6_tail_ptr,
output [7:0] io_cq7_tail_ptr,
output [7:0] io_cq8_tail_ptr,
output tx_cq_mwr_req,
output [7:0] tx_cq_mwr_tag,
output [11:2] tx_cq_mwr_len,
output [C_PCIE_ADDR_WIDTH-1:2] tx_cq_mwr_addr,
input tx_cq_mwr_req_ack,
input tx_cq_mwr_rd_en,
output [C_PCIE_DATA_WIDTH-1:0] tx_cq_mwr_rd_data,
input tx_cq_mwr_data_last,
input [7:0] hcmd_prp_rd_addr,
output [44:0] hcmd_prp_rd_data,
input hcmd_nlb_wr1_en,
input [6:0] hcmd_nlb_wr1_addr,
input [18:0] hcmd_nlb_wr1_data,
output hcmd_nlb_wr1_rdy_n,
input [6:0] hcmd_nlb_rd_addr,
output [18:0] hcmd_nlb_rd_data,
input hcmd_cq_wr0_en,
input [34:0] hcmd_cq_wr0_data0,
input [34:0] hcmd_cq_wr0_data1,
output hcmd_cq_wr0_rdy_n,
input cpu_bus_clk,
input cpu_bus_rst_n,
input [8:0] sq_rst_n,
input [8:0] sq_valid,
input [7:0] io_sq1_size,
input [7:0] io_sq2_size,
input [7:0] io_sq3_size,
input [7:0] io_sq4_size,
input [7:0] io_sq5_size,
input [7:0] io_sq6_size,
input [7:0] io_sq7_size,
input [7:0] io_sq8_size,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq1_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq2_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq3_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq4_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq5_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq6_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq7_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_sq8_bs_addr,
input [3:0] io_sq1_cq_vec,
input [3:0] io_sq2_cq_vec,
input [3:0] io_sq3_cq_vec,
input [3:0] io_sq4_cq_vec,
input [3:0] io_sq5_cq_vec,
input [3:0] io_sq6_cq_vec,
input [3:0] io_sq7_cq_vec,
input [3:0] io_sq8_cq_vec,
input [8:0] cq_rst_n,
input [8:0] cq_valid,
input [7:0] io_cq1_size,
input [7:0] io_cq2_size,
input [7:0] io_cq3_size,
input [7:0] io_cq4_size,
input [7:0] io_cq5_size,
input [7:0] io_cq6_size,
input [7:0] io_cq7_size,
input [7:0] io_cq8_size,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq1_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq2_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq3_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq4_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq5_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq6_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq7_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq8_bs_addr,
input hcmd_sq_rd_en,
output [18:0] hcmd_sq_rd_data,
output hcmd_sq_empty_n,
input [10:0] hcmd_table_rd_addr,
output [31:0] hcmd_table_rd_data,
input hcmd_cq_wr1_en,
input [34:0] hcmd_cq_wr1_data0,
input [34:0] hcmd_cq_wr1_data1,
output hcmd_cq_wr1_rdy_n
);
wire w_hcmd_table_wr_en;
wire [8:0] w_hcmd_table_wr_addr;
wire [127:0] w_hcmd_table_wr_data;
wire w_hcmd_cid_wr_en;
wire [6:0] w_hcmd_cid_wr_addr;
wire [19:0] w_hcmd_cid_wr_data;
wire [6:0] w_hcmd_cid_rd_addr;
wire [19:0] w_hcmd_cid_rd_data;
wire w_hcmd_prp_wr_en;
wire [7:0] w_hcmd_prp_wr_addr;
wire [44:0] w_hcmd_prp_wr_data;
wire w_hcmd_nlb_wr0_en;
wire [6:0] w_hcmd_nlb_wr0_addr;
wire [18:0] w_hcmd_nlb_wr0_data;
wire w_hcmd_nlb_wr0_rdy_n;
wire w_hcmd_slot_rdy;
wire [6:0] w_hcmd_slot_tag;
wire w_hcmd_slot_alloc_en;
wire w_hcmd_slot_free_en;
wire [6:0] w_hcmd_slot_invalid_tag;
wire [7:0] w_admin_sq_head_ptr;
wire [7:0] w_io_sq1_head_ptr;
wire [7:0] w_io_sq2_head_ptr;
wire [7:0] w_io_sq3_head_ptr;
wire [7:0] w_io_sq4_head_ptr;
wire [7:0] w_io_sq5_head_ptr;
wire [7:0] w_io_sq6_head_ptr;
wire [7:0] w_io_sq7_head_ptr;
wire [7:0] w_io_sq8_head_ptr;
pcie_hcmd_table
pcie_hcmd_table_inst0(
.wr_clk (pcie_user_clk),
.wr_en (w_hcmd_table_wr_en),
.wr_addr (w_hcmd_table_wr_addr),
.wr_data (w_hcmd_table_wr_data),
.rd_clk (cpu_bus_clk),
.rd_addr (hcmd_table_rd_addr),
.rd_data (hcmd_table_rd_data)
);
pcie_hcmd_table_cid
pcie_hcmd_table_cid_isnt0(
.clk (pcie_user_clk),
.wr_en (w_hcmd_cid_wr_en),
.wr_addr (w_hcmd_cid_wr_addr),
.wr_data (w_hcmd_cid_wr_data),
.rd_addr (w_hcmd_cid_rd_addr),
.rd_data (w_hcmd_cid_rd_data)
);
pcie_hcmd_table_prp
pcie_hcmd_table_prp_isnt0(
.clk (pcie_user_clk),
.wr_en (w_hcmd_prp_wr_en),
.wr_addr (w_hcmd_prp_wr_addr),
.wr_data (w_hcmd_prp_wr_data),
.rd_addr (hcmd_prp_rd_addr),
.rd_data (hcmd_prp_rd_data)
);
pcie_hcmd_nlb
pcie_hcmd_nlb_inst0
(
.clk (pcie_user_clk),
.rst_n (pcie_user_rst_n),
.wr0_en (w_hcmd_nlb_wr0_en),
.wr0_addr (w_hcmd_nlb_wr0_addr),
.wr0_data (w_hcmd_nlb_wr0_data),
.wr0_rdy_n (w_hcmd_nlb_wr0_rdy_n),
.wr1_en (hcmd_nlb_wr1_en),
.wr1_addr (hcmd_nlb_wr1_addr),
.wr1_data (hcmd_nlb_wr1_data),
.wr1_rdy_n (hcmd_nlb_wr1_rdy_n),
.rd_addr (hcmd_nlb_rd_addr),
.rd_data (hcmd_nlb_rd_data)
);
pcie_hcmd_slot_mgt
pcie_hcmd_slot_mgt_inst0
(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.hcmd_slot_rdy (w_hcmd_slot_rdy),
.hcmd_slot_tag (w_hcmd_slot_tag),
.hcmd_slot_alloc_en (w_hcmd_slot_alloc_en),
.hcmd_slot_free_en (w_hcmd_slot_free_en),
.hcmd_slot_invalid_tag (w_hcmd_slot_invalid_tag)
);
pcie_hcmd_sq # (
.C_PCIE_DATA_WIDTH (C_PCIE_DATA_WIDTH)
)
pcie_hcmd_sq_inst0(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.admin_sq_bs_addr (admin_sq_bs_addr),
.admin_sq_size (admin_sq_size),
.admin_sq_tail_ptr (admin_sq_tail_ptr),
.io_sq1_tail_ptr (io_sq1_tail_ptr),
.io_sq2_tail_ptr (io_sq2_tail_ptr),
.io_sq3_tail_ptr (io_sq3_tail_ptr),
.io_sq4_tail_ptr (io_sq4_tail_ptr),
.io_sq5_tail_ptr (io_sq5_tail_ptr),
.io_sq6_tail_ptr (io_sq6_tail_ptr),
.io_sq7_tail_ptr (io_sq7_tail_ptr),
.io_sq8_tail_ptr (io_sq8_tail_ptr),
.admin_sq_head_ptr (w_admin_sq_head_ptr),
.io_sq1_head_ptr (w_io_sq1_head_ptr),
.io_sq2_head_ptr (w_io_sq2_head_ptr),
.io_sq3_head_ptr (w_io_sq3_head_ptr),
.io_sq4_head_ptr (w_io_sq4_head_ptr),
.io_sq5_head_ptr (w_io_sq5_head_ptr),
.io_sq6_head_ptr (w_io_sq6_head_ptr),
.io_sq7_head_ptr (w_io_sq7_head_ptr),
.io_sq8_head_ptr (w_io_sq8_head_ptr),
.hcmd_slot_rdy (w_hcmd_slot_rdy),
.hcmd_slot_tag (w_hcmd_slot_tag),
.hcmd_slot_alloc_en (w_hcmd_slot_alloc_en),
.cpld_sq_fifo_tag (cpld_sq_fifo_tag),
.cpld_sq_fifo_wr_data (cpld_sq_fifo_wr_data),
.cpld_sq_fifo_wr_en (cpld_sq_fifo_wr_en),
.cpld_sq_fifo_tag_last (cpld_sq_fifo_tag_last),
.tx_mrd_req (tx_mrd_req),
.tx_mrd_tag (tx_mrd_tag),
.tx_mrd_len (tx_mrd_len),
.tx_mrd_addr (tx_mrd_addr),
.tx_mrd_req_ack (tx_mrd_req_ack),
.hcmd_table_wr_en (w_hcmd_table_wr_en),
.hcmd_table_wr_addr (w_hcmd_table_wr_addr),
.hcmd_table_wr_data (w_hcmd_table_wr_data),
.hcmd_cid_wr_en (w_hcmd_cid_wr_en),
.hcmd_cid_wr_addr (w_hcmd_cid_wr_addr),
.hcmd_cid_wr_data (w_hcmd_cid_wr_data),
.hcmd_prp_wr_en (w_hcmd_prp_wr_en),
.hcmd_prp_wr_addr (w_hcmd_prp_wr_addr),
.hcmd_prp_wr_data (w_hcmd_prp_wr_data),
.hcmd_nlb_wr0_en (w_hcmd_nlb_wr0_en),
.hcmd_nlb_wr0_addr (w_hcmd_nlb_wr0_addr),
.hcmd_nlb_wr0_data (w_hcmd_nlb_wr0_data),
.hcmd_nlb_wr0_rdy_n (w_hcmd_nlb_wr0_rdy_n),
.cpu_bus_clk (cpu_bus_clk),
.cpu_bus_rst_n (cpu_bus_rst_n),
.sq_rst_n (sq_rst_n),
.sq_valid (sq_valid),
.io_sq1_size (io_sq1_size),
.io_sq2_size (io_sq2_size),
.io_sq3_size (io_sq3_size),
.io_sq4_size (io_sq4_size),
.io_sq5_size (io_sq5_size),
.io_sq6_size (io_sq6_size),
.io_sq7_size (io_sq7_size),
.io_sq8_size (io_sq8_size),
.io_sq1_bs_addr (io_sq1_bs_addr),
.io_sq2_bs_addr (io_sq2_bs_addr),
.io_sq3_bs_addr (io_sq3_bs_addr),
.io_sq4_bs_addr (io_sq4_bs_addr),
.io_sq5_bs_addr (io_sq5_bs_addr),
.io_sq6_bs_addr (io_sq6_bs_addr),
.io_sq7_bs_addr (io_sq7_bs_addr),
.io_sq8_bs_addr (io_sq8_bs_addr),
.hcmd_sq_rd_en (hcmd_sq_rd_en),
.hcmd_sq_rd_data (hcmd_sq_rd_data),
.hcmd_sq_empty_n (hcmd_sq_empty_n)
);
pcie_hcmd_cq # (
.C_PCIE_DATA_WIDTH (C_PCIE_DATA_WIDTH)
)
pcie_hcmd_cq_inst0(
.pcie_user_clk (pcie_user_clk),
.pcie_user_rst_n (pcie_user_rst_n),
.hcmd_cid_rd_addr (w_hcmd_cid_rd_addr),
.hcmd_cid_rd_data (w_hcmd_cid_rd_data),
.admin_cq_bs_addr (admin_cq_bs_addr),
.admin_cq_size (admin_cq_size),
.admin_cq_tail_ptr (admin_cq_tail_ptr),
.io_cq1_tail_ptr (io_cq1_tail_ptr),
.io_cq2_tail_ptr (io_cq2_tail_ptr),
.io_cq3_tail_ptr (io_cq3_tail_ptr),
.io_cq4_tail_ptr (io_cq4_tail_ptr),
.io_cq5_tail_ptr (io_cq5_tail_ptr),
.io_cq6_tail_ptr (io_cq6_tail_ptr),
.io_cq7_tail_ptr (io_cq7_tail_ptr),
.io_cq8_tail_ptr (io_cq8_tail_ptr),
.admin_sq_head_ptr (w_admin_sq_head_ptr),
.io_sq1_head_ptr (w_io_sq1_head_ptr),
.io_sq2_head_ptr (w_io_sq2_head_ptr),
.io_sq3_head_ptr (w_io_sq3_head_ptr),
.io_sq4_head_ptr (w_io_sq4_head_ptr),
.io_sq5_head_ptr (w_io_sq5_head_ptr),
.io_sq6_head_ptr (w_io_sq6_head_ptr),
.io_sq7_head_ptr (w_io_sq7_head_ptr),
.io_sq8_head_ptr (w_io_sq8_head_ptr),
.hcmd_slot_free_en (w_hcmd_slot_free_en),
.hcmd_slot_invalid_tag (w_hcmd_slot_invalid_tag),
.tx_cq_mwr_req (tx_cq_mwr_req),
.tx_cq_mwr_tag (tx_cq_mwr_tag),
.tx_cq_mwr_len (tx_cq_mwr_len),
.tx_cq_mwr_addr (tx_cq_mwr_addr),
.tx_cq_mwr_req_ack (tx_cq_mwr_req_ack),
.tx_cq_mwr_rd_en (tx_cq_mwr_rd_en),
.tx_cq_mwr_rd_data (tx_cq_mwr_rd_data),
.tx_cq_mwr_data_last (tx_cq_mwr_data_last),
.hcmd_cq_wr0_en (hcmd_cq_wr0_en),
.hcmd_cq_wr0_data0 (hcmd_cq_wr0_data0),
.hcmd_cq_wr0_data1 (hcmd_cq_wr0_data1),
.hcmd_cq_wr0_rdy_n (hcmd_cq_wr0_rdy_n),
.cpu_bus_clk (cpu_bus_clk),
.cpu_bus_rst_n (cpu_bus_rst_n),
.io_sq1_cq_vec (io_sq1_cq_vec),
.io_sq2_cq_vec (io_sq2_cq_vec),
.io_sq3_cq_vec (io_sq3_cq_vec),
.io_sq4_cq_vec (io_sq4_cq_vec),
.io_sq5_cq_vec (io_sq5_cq_vec),
.io_sq6_cq_vec (io_sq6_cq_vec),
.io_sq7_cq_vec (io_sq7_cq_vec),
.io_sq8_cq_vec (io_sq8_cq_vec),
.sq_valid (sq_valid),
.cq_rst_n (cq_rst_n),
.cq_valid (cq_valid),
.io_cq1_size (io_cq1_size),
.io_cq2_size (io_cq2_size),
.io_cq3_size (io_cq3_size),
.io_cq4_size (io_cq4_size),
.io_cq5_size (io_cq5_size),
.io_cq6_size (io_cq6_size),
.io_cq7_size (io_cq7_size),
.io_cq8_size (io_cq8_size),
.io_cq1_bs_addr (io_cq1_bs_addr),
.io_cq2_bs_addr (io_cq2_bs_addr),
.io_cq3_bs_addr (io_cq3_bs_addr),
.io_cq4_bs_addr (io_cq4_bs_addr),
.io_cq5_bs_addr (io_cq5_bs_addr),
.io_cq6_bs_addr (io_cq6_bs_addr),
.io_cq7_bs_addr (io_cq7_bs_addr),
.io_cq8_bs_addr (io_cq8_bs_addr),
.hcmd_cq_wr1_en (hcmd_cq_wr1_en),
.hcmd_cq_wr1_data0 (hcmd_cq_wr1_data0),
.hcmd_cq_wr1_data1 (hcmd_cq_wr1_data1),
.hcmd_cq_wr1_rdy_n (hcmd_cq_wr1_rdy_n)
);
endmodule
|
//Legal Notice: (C)2016 Altera Corporation. All rights reserved. Your
//use of Altera Corporation's design tools, logic functions and other
//software and tools, and its AMPP partner logic functions, and any
//output files any of the foregoing (including device programming or
//simulation files), and any associated documentation or information are
//expressly subject to the terms and conditions of the Altera Program
//License Subscription Agreement or other applicable license agreement,
//including, without limitation, that your use is for the sole purpose
//of programming logic devices manufactured by Altera and sold by Altera
//or its authorized distributors. Please refer to the applicable
//agreement for further details.
// synthesis translate_off
`timescale 1ns / 1ps
// synthesis translate_on
// turn off superfluous verilog processor warnings
// altera message_level Level1
// altera message_off 10034 10035 10036 10037 10230 10240 10030
module niosii_nios2_gen2_0_cpu_debug_slave_wrapper (
// inputs:
MonDReg,
break_readreg,
clk,
dbrk_hit0_latch,
dbrk_hit1_latch,
dbrk_hit2_latch,
dbrk_hit3_latch,
debugack,
monitor_error,
monitor_ready,
reset_n,
resetlatch,
tracemem_on,
tracemem_trcdata,
tracemem_tw,
trc_im_addr,
trc_on,
trc_wrap,
trigbrktype,
trigger_state_1,
// outputs:
jdo,
jrst_n,
st_ready_test_idle,
take_action_break_a,
take_action_break_b,
take_action_break_c,
take_action_ocimem_a,
take_action_ocimem_b,
take_action_tracectrl,
take_no_action_break_a,
take_no_action_break_b,
take_no_action_break_c,
take_no_action_ocimem_a
)
;
output [ 37: 0] jdo;
output jrst_n;
output st_ready_test_idle;
output take_action_break_a;
output take_action_break_b;
output take_action_break_c;
output take_action_ocimem_a;
output take_action_ocimem_b;
output take_action_tracectrl;
output take_no_action_break_a;
output take_no_action_break_b;
output take_no_action_break_c;
output take_no_action_ocimem_a;
input [ 31: 0] MonDReg;
input [ 31: 0] break_readreg;
input clk;
input dbrk_hit0_latch;
input dbrk_hit1_latch;
input dbrk_hit2_latch;
input dbrk_hit3_latch;
input debugack;
input monitor_error;
input monitor_ready;
input reset_n;
input resetlatch;
input tracemem_on;
input [ 35: 0] tracemem_trcdata;
input tracemem_tw;
input [ 6: 0] trc_im_addr;
input trc_on;
input trc_wrap;
input trigbrktype;
input trigger_state_1;
wire [ 37: 0] jdo;
wire jrst_n;
wire [ 37: 0] sr;
wire st_ready_test_idle;
wire take_action_break_a;
wire take_action_break_b;
wire take_action_break_c;
wire take_action_ocimem_a;
wire take_action_ocimem_b;
wire take_action_tracectrl;
wire take_no_action_break_a;
wire take_no_action_break_b;
wire take_no_action_break_c;
wire take_no_action_ocimem_a;
wire vji_cdr;
wire [ 1: 0] vji_ir_in;
wire [ 1: 0] vji_ir_out;
wire vji_rti;
wire vji_sdr;
wire vji_tck;
wire vji_tdi;
wire vji_tdo;
wire vji_udr;
wire vji_uir;
//Change the sld_virtual_jtag_basic's defparams to
//switch between a regular Nios II or an internally embedded Nios II.
//For a regular Nios II, sld_mfg_id = 70, sld_type_id = 34.
//For an internally embedded Nios II, slf_mfg_id = 110, sld_type_id = 135.
niosii_nios2_gen2_0_cpu_debug_slave_tck the_niosii_nios2_gen2_0_cpu_debug_slave_tck
(
.MonDReg (MonDReg),
.break_readreg (break_readreg),
.dbrk_hit0_latch (dbrk_hit0_latch),
.dbrk_hit1_latch (dbrk_hit1_latch),
.dbrk_hit2_latch (dbrk_hit2_latch),
.dbrk_hit3_latch (dbrk_hit3_latch),
.debugack (debugack),
.ir_in (vji_ir_in),
.ir_out (vji_ir_out),
.jrst_n (jrst_n),
.jtag_state_rti (vji_rti),
.monitor_error (monitor_error),
.monitor_ready (monitor_ready),
.reset_n (reset_n),
.resetlatch (resetlatch),
.sr (sr),
.st_ready_test_idle (st_ready_test_idle),
.tck (vji_tck),
.tdi (vji_tdi),
.tdo (vji_tdo),
.tracemem_on (tracemem_on),
.tracemem_trcdata (tracemem_trcdata),
.tracemem_tw (tracemem_tw),
.trc_im_addr (trc_im_addr),
.trc_on (trc_on),
.trc_wrap (trc_wrap),
.trigbrktype (trigbrktype),
.trigger_state_1 (trigger_state_1),
.vs_cdr (vji_cdr),
.vs_sdr (vji_sdr),
.vs_uir (vji_uir)
);
niosii_nios2_gen2_0_cpu_debug_slave_sysclk the_niosii_nios2_gen2_0_cpu_debug_slave_sysclk
(
.clk (clk),
.ir_in (vji_ir_in),
.jdo (jdo),
.sr (sr),
.take_action_break_a (take_action_break_a),
.take_action_break_b (take_action_break_b),
.take_action_break_c (take_action_break_c),
.take_action_ocimem_a (take_action_ocimem_a),
.take_action_ocimem_b (take_action_ocimem_b),
.take_action_tracectrl (take_action_tracectrl),
.take_no_action_break_a (take_no_action_break_a),
.take_no_action_break_b (take_no_action_break_b),
.take_no_action_break_c (take_no_action_break_c),
.take_no_action_ocimem_a (take_no_action_ocimem_a),
.vs_udr (vji_udr),
.vs_uir (vji_uir)
);
//synthesis translate_off
//////////////// SIMULATION-ONLY CONTENTS
assign vji_tck = 1'b0;
assign vji_tdi = 1'b0;
assign vji_sdr = 1'b0;
assign vji_cdr = 1'b0;
assign vji_rti = 1'b0;
assign vji_uir = 1'b0;
assign vji_udr = 1'b0;
assign vji_ir_in = 2'b0;
//////////////// END SIMULATION-ONLY CONTENTS
//synthesis translate_on
//synthesis read_comments_as_HDL on
// sld_virtual_jtag_basic niosii_nios2_gen2_0_cpu_debug_slave_phy
// (
// .ir_in (vji_ir_in),
// .ir_out (vji_ir_out),
// .jtag_state_rti (vji_rti),
// .tck (vji_tck),
// .tdi (vji_tdi),
// .tdo (vji_tdo),
// .virtual_state_cdr (vji_cdr),
// .virtual_state_sdr (vji_sdr),
// .virtual_state_udr (vji_udr),
// .virtual_state_uir (vji_uir)
// );
//
// defparam niosii_nios2_gen2_0_cpu_debug_slave_phy.sld_auto_instance_index = "YES",
// niosii_nios2_gen2_0_cpu_debug_slave_phy.sld_instance_index = 0,
// niosii_nios2_gen2_0_cpu_debug_slave_phy.sld_ir_width = 2,
// niosii_nios2_gen2_0_cpu_debug_slave_phy.sld_mfg_id = 70,
// niosii_nios2_gen2_0_cpu_debug_slave_phy.sld_sim_action = "",
// niosii_nios2_gen2_0_cpu_debug_slave_phy.sld_sim_n_scan = 0,
// niosii_nios2_gen2_0_cpu_debug_slave_phy.sld_sim_total_length = 0,
// niosii_nios2_gen2_0_cpu_debug_slave_phy.sld_type_id = 34,
// niosii_nios2_gen2_0_cpu_debug_slave_phy.sld_version = 3;
//
//synthesis read_comments_as_HDL off
endmodule
|
//Legal Notice: (C)2016 Altera Corporation. All rights reserved. Your
//use of Altera Corporation's design tools, logic functions and other
//software and tools, and its AMPP partner logic functions, and any
//output files any of the foregoing (including device programming or
//simulation files), and any associated documentation or information are
//expressly subject to the terms and conditions of the Altera Program
//License Subscription Agreement or other applicable license agreement,
//including, without limitation, that your use is for the sole purpose
//of programming logic devices manufactured by Altera and sold by Altera
//or its authorized distributors. Please refer to the applicable
//agreement for further details.
// synthesis translate_off
`timescale 1ns / 1ps
// synthesis translate_on
// turn off superfluous verilog processor warnings
// altera message_level Level1
// altera message_off 10034 10035 10036 10037 10230 10240 10030
module niosii_nios2_gen2_0_cpu_debug_slave_wrapper (
// inputs:
MonDReg,
break_readreg,
clk,
dbrk_hit0_latch,
dbrk_hit1_latch,
dbrk_hit2_latch,
dbrk_hit3_latch,
debugack,
monitor_error,
monitor_ready,
reset_n,
resetlatch,
tracemem_on,
tracemem_trcdata,
tracemem_tw,
trc_im_addr,
trc_on,
trc_wrap,
trigbrktype,
trigger_state_1,
// outputs:
jdo,
jrst_n,
st_ready_test_idle,
take_action_break_a,
take_action_break_b,
take_action_break_c,
take_action_ocimem_a,
take_action_ocimem_b,
take_action_tracectrl,
take_no_action_break_a,
take_no_action_break_b,
take_no_action_break_c,
take_no_action_ocimem_a
)
;
output [ 37: 0] jdo;
output jrst_n;
output st_ready_test_idle;
output take_action_break_a;
output take_action_break_b;
output take_action_break_c;
output take_action_ocimem_a;
output take_action_ocimem_b;
output take_action_tracectrl;
output take_no_action_break_a;
output take_no_action_break_b;
output take_no_action_break_c;
output take_no_action_ocimem_a;
input [ 31: 0] MonDReg;
input [ 31: 0] break_readreg;
input clk;
input dbrk_hit0_latch;
input dbrk_hit1_latch;
input dbrk_hit2_latch;
input dbrk_hit3_latch;
input debugack;
input monitor_error;
input monitor_ready;
input reset_n;
input resetlatch;
input tracemem_on;
input [ 35: 0] tracemem_trcdata;
input tracemem_tw;
input [ 6: 0] trc_im_addr;
input trc_on;
input trc_wrap;
input trigbrktype;
input trigger_state_1;
wire [ 37: 0] jdo;
wire jrst_n;
wire [ 37: 0] sr;
wire st_ready_test_idle;
wire take_action_break_a;
wire take_action_break_b;
wire take_action_break_c;
wire take_action_ocimem_a;
wire take_action_ocimem_b;
wire take_action_tracectrl;
wire take_no_action_break_a;
wire take_no_action_break_b;
wire take_no_action_break_c;
wire take_no_action_ocimem_a;
wire vji_cdr;
wire [ 1: 0] vji_ir_in;
wire [ 1: 0] vji_ir_out;
wire vji_rti;
wire vji_sdr;
wire vji_tck;
wire vji_tdi;
wire vji_tdo;
wire vji_udr;
wire vji_uir;
//Change the sld_virtual_jtag_basic's defparams to
//switch between a regular Nios II or an internally embedded Nios II.
//For a regular Nios II, sld_mfg_id = 70, sld_type_id = 34.
//For an internally embedded Nios II, slf_mfg_id = 110, sld_type_id = 135.
niosii_nios2_gen2_0_cpu_debug_slave_tck the_niosii_nios2_gen2_0_cpu_debug_slave_tck
(
.MonDReg (MonDReg),
.break_readreg (break_readreg),
.dbrk_hit0_latch (dbrk_hit0_latch),
.dbrk_hit1_latch (dbrk_hit1_latch),
.dbrk_hit2_latch (dbrk_hit2_latch),
.dbrk_hit3_latch (dbrk_hit3_latch),
.debugack (debugack),
.ir_in (vji_ir_in),
.ir_out (vji_ir_out),
.jrst_n (jrst_n),
.jtag_state_rti (vji_rti),
.monitor_error (monitor_error),
.monitor_ready (monitor_ready),
.reset_n (reset_n),
.resetlatch (resetlatch),
.sr (sr),
.st_ready_test_idle (st_ready_test_idle),
.tck (vji_tck),
.tdi (vji_tdi),
.tdo (vji_tdo),
.tracemem_on (tracemem_on),
.tracemem_trcdata (tracemem_trcdata),
.tracemem_tw (tracemem_tw),
.trc_im_addr (trc_im_addr),
.trc_on (trc_on),
.trc_wrap (trc_wrap),
.trigbrktype (trigbrktype),
.trigger_state_1 (trigger_state_1),
.vs_cdr (vji_cdr),
.vs_sdr (vji_sdr),
.vs_uir (vji_uir)
);
niosii_nios2_gen2_0_cpu_debug_slave_sysclk the_niosii_nios2_gen2_0_cpu_debug_slave_sysclk
(
.clk (clk),
.ir_in (vji_ir_in),
.jdo (jdo),
.sr (sr),
.take_action_break_a (take_action_break_a),
.take_action_break_b (take_action_break_b),
.take_action_break_c (take_action_break_c),
.take_action_ocimem_a (take_action_ocimem_a),
.take_action_ocimem_b (take_action_ocimem_b),
.take_action_tracectrl (take_action_tracectrl),
.take_no_action_break_a (take_no_action_break_a),
.take_no_action_break_b (take_no_action_break_b),
.take_no_action_break_c (take_no_action_break_c),
.take_no_action_ocimem_a (take_no_action_ocimem_a),
.vs_udr (vji_udr),
.vs_uir (vji_uir)
);
//synthesis translate_off
//////////////// SIMULATION-ONLY CONTENTS
assign vji_tck = 1'b0;
assign vji_tdi = 1'b0;
assign vji_sdr = 1'b0;
assign vji_cdr = 1'b0;
assign vji_rti = 1'b0;
assign vji_uir = 1'b0;
assign vji_udr = 1'b0;
assign vji_ir_in = 2'b0;
//////////////// END SIMULATION-ONLY CONTENTS
//synthesis translate_on
//synthesis read_comments_as_HDL on
// sld_virtual_jtag_basic niosii_nios2_gen2_0_cpu_debug_slave_phy
// (
// .ir_in (vji_ir_in),
// .ir_out (vji_ir_out),
// .jtag_state_rti (vji_rti),
// .tck (vji_tck),
// .tdi (vji_tdi),
// .tdo (vji_tdo),
// .virtual_state_cdr (vji_cdr),
// .virtual_state_sdr (vji_sdr),
// .virtual_state_udr (vji_udr),
// .virtual_state_uir (vji_uir)
// );
//
// defparam niosii_nios2_gen2_0_cpu_debug_slave_phy.sld_auto_instance_index = "YES",
// niosii_nios2_gen2_0_cpu_debug_slave_phy.sld_instance_index = 0,
// niosii_nios2_gen2_0_cpu_debug_slave_phy.sld_ir_width = 2,
// niosii_nios2_gen2_0_cpu_debug_slave_phy.sld_mfg_id = 70,
// niosii_nios2_gen2_0_cpu_debug_slave_phy.sld_sim_action = "",
// niosii_nios2_gen2_0_cpu_debug_slave_phy.sld_sim_n_scan = 0,
// niosii_nios2_gen2_0_cpu_debug_slave_phy.sld_sim_total_length = 0,
// niosii_nios2_gen2_0_cpu_debug_slave_phy.sld_type_id = 34,
// niosii_nios2_gen2_0_cpu_debug_slave_phy.sld_version = 3;
//
//synthesis read_comments_as_HDL off
endmodule
|
/*
----------------------------------------------------------------------------------
Copyright (c) 2013-2014
Embedded and Network Computing Lab.
Open SSD Project
Hanyang University
All rights reserved.
----------------------------------------------------------------------------------
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. All advertising materials mentioning features or use of this source code
must display the following acknowledgement:
This product includes source code developed
by the Embedded and Network Computing Lab. and the Open SSD Project.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
----------------------------------------------------------------------------------
http://enclab.hanyang.ac.kr/
http://www.openssd-project.org/
http://www.hanyang.ac.kr/
----------------------------------------------------------------------------------
*/
`timescale 1ns / 1ps
`include "def_pcie.vh"
module pcie_tx_arb # (
parameter C_PCIE_DATA_WIDTH = 128,
parameter C_PCIE_ADDR_WIDTH = 36
)
(
input pcie_user_clk,
input pcie_user_rst_n,
input [15:0] pcie_dev_id,
input tx_cpld_gnt,
input tx_mrd_gnt,
input tx_mwr_gnt,
input tx_cpld_req,
input [7:0] tx_cpld_tag,
input [15:0] tx_cpld_req_id,
input [11:2] tx_cpld_len,
input [11:0] tx_cpld_bc,
input [6:0] tx_cpld_laddr,
input [63:0] tx_cpld_data,
output tx_cpld_req_ack,
input tx_mrd0_req,
input [7:0] tx_mrd0_tag,
input [11:2] tx_mrd0_len,
input [C_PCIE_ADDR_WIDTH-1:2] tx_mrd0_addr,
output tx_mrd0_req_ack,
input tx_mrd1_req,
input [7:0] tx_mrd1_tag,
input [11:2] tx_mrd1_len,
input [C_PCIE_ADDR_WIDTH-1:2] tx_mrd1_addr,
output tx_mrd1_req_ack,
input tx_mrd2_req,
input [7:0] tx_mrd2_tag,
input [11:2] tx_mrd2_len,
input [C_PCIE_ADDR_WIDTH-1:2] tx_mrd2_addr,
output tx_mrd2_req_ack,
input tx_mwr0_req,
input [7:0] tx_mwr0_tag,
input [11:2] tx_mwr0_len,
input [C_PCIE_ADDR_WIDTH-1:2] tx_mwr0_addr,
output tx_mwr0_req_ack,
input tx_mwr1_req,
input [7:0] tx_mwr1_tag,
input [11:2] tx_mwr1_len,
input [C_PCIE_ADDR_WIDTH-1:2] tx_mwr1_addr,
output tx_mwr1_req_ack,
output tx_arb_valid,
output [5:0] tx_arb_gnt,
output [2:0] tx_arb_type,
output [11:2] tx_pcie_len,
output [127:0] tx_pcie_head,
output [31:0] tx_cpld_udata,
input tx_arb_rdy
);
reg [5:0] r_tx_req;
reg [5:0] r_tx_req_en;
wire [5:0] w_tx_req_en;
wire [5:0] w_tx_req_gnt;
reg [5:0] r_tx_req_ack;
wire [5:0] w_tx_req_ack;
reg [2:0] r_tx_type;
reg [5:0] r_tx_arb;
reg [5:0] r_tx_arb_cur;
reg [2:0] r_tx_arb_type;
reg [31:0] r_tx_pcie_head0;
reg [31:0] r_tx_pcie_head1;
reg [31:0] r_tx_pcie_head2;
reg [31:0] r_tx_pcie_head3;
assign tx_arb_valid = (r_tx_arb_cur[5] | r_tx_arb_cur[4]) | (r_tx_arb_cur[3] | r_tx_arb_cur[2]) | (r_tx_arb_cur[1] | r_tx_arb_cur[0]);
assign tx_arb_gnt = r_tx_arb_cur;
assign tx_arb_type = r_tx_arb_type;
assign tx_pcie_len = r_tx_pcie_head0[9:0];
assign tx_pcie_head = {r_tx_pcie_head3, r_tx_pcie_head2, r_tx_pcie_head1, r_tx_pcie_head0};
assign tx_cpld_udata = tx_cpld_data[63:32];
assign tx_cpld_req_ack = r_tx_req_ack[0];
assign tx_mrd0_req_ack = r_tx_req_ack[1];
assign tx_mrd1_req_ack = r_tx_req_ack[2];
assign tx_mrd2_req_ack = r_tx_req_ack[3];
assign tx_mwr0_req_ack = r_tx_req_ack[4];
assign tx_mwr1_req_ack = r_tx_req_ack[5];
assign w_tx_req_ack[0] = tx_arb_rdy & r_tx_arb_cur[0];
assign w_tx_req_ack[1] = tx_arb_rdy & r_tx_arb_cur[1];
assign w_tx_req_ack[2] = tx_arb_rdy & r_tx_arb_cur[2];
assign w_tx_req_ack[3] = tx_arb_rdy & r_tx_arb_cur[3];
assign w_tx_req_ack[4] = tx_arb_rdy & r_tx_arb_cur[4];
assign w_tx_req_ack[5] = tx_arb_rdy & r_tx_arb_cur[5];
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0) begin
r_tx_req <= 0;
end
else begin
if(tx_cpld_req == 1)
r_tx_req[0] <= 1;
else if(w_tx_req_ack[0] == 1)
r_tx_req[0] <= 0;
if(tx_mrd0_req == 1)
r_tx_req[1] <= 1;
else if(w_tx_req_ack[1] == 1)
r_tx_req[1] <= 0;
if(tx_mrd1_req == 1)
r_tx_req[2] <= 1;
else if(w_tx_req_ack[2] == 1)
r_tx_req[2] <= 0;
if(tx_mrd2_req == 1)
r_tx_req[3] <= 1;
else if(w_tx_req_ack[3] == 1)
r_tx_req[3] <= 0;
if(tx_mwr0_req == 1)
r_tx_req[4] <= 1;
else if(w_tx_req_ack[4] == 1)
r_tx_req[4] <= 0;
if(tx_mwr1_req == 1)
r_tx_req[5] <= 1;
else if(w_tx_req_ack[5] == 1)
r_tx_req[5] <= 0;
end
end
always @ (*)
begin
if(tx_arb_rdy == 1)
r_tx_req_en <= r_tx_req & ~r_tx_arb_cur;
else
r_tx_req_en <= r_tx_req;
end
assign w_tx_req_gnt[0] = tx_cpld_gnt;
assign w_tx_req_gnt[1] = tx_mrd_gnt;
assign w_tx_req_gnt[2] = tx_mrd_gnt;
assign w_tx_req_gnt[3] = tx_mrd_gnt;
assign w_tx_req_gnt[4] = tx_mwr_gnt;
assign w_tx_req_gnt[5] = tx_mwr_gnt;
assign w_tx_req_en = r_tx_req_en & w_tx_req_gnt;
always @ (*)
begin
if(w_tx_req_en[0] == 1) begin
r_tx_type <= 3'b001;
r_tx_arb <= 6'b000001;
end
else if(w_tx_req_en[1] == 1) begin
r_tx_type <= 3'b010;
r_tx_arb <= 6'b000010;
end
else if(w_tx_req_en[2] == 1) begin
r_tx_type <= 3'b010;
r_tx_arb <= 6'b000100;
end
else if(w_tx_req_en[4] == 1) begin
r_tx_type <= 3'b100;
r_tx_arb <= 6'b010000;
end
else if(w_tx_req_en[3] == 1) begin
r_tx_type <= 3'b010;
r_tx_arb <= 6'b001000;
end
else if(w_tx_req_en[5] == 1) begin
r_tx_type <= 3'b100;
r_tx_arb <= 6'b100000;
end
else begin
r_tx_type <= 3'b000;
r_tx_arb <= 6'b000000;
end
end
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0)
r_tx_arb_cur <= 0;
else
r_tx_arb_cur <= r_tx_arb;
end
always @ (posedge pcie_user_clk)
begin
r_tx_arb_type <= r_tx_type;
r_tx_req_ack <= w_tx_req_ack;
end
always @ (*)
begin
case(r_tx_arb_cur) // synthesis parallel_case full_case
6'b000001: begin
r_tx_pcie_head0 <= {`D_CPLD_FMT, `D_CPLD_TYPE, 1'b0, `D_CPLD_TC, 1'b0, `D_CPLD_ATTR1, 1'b0, `D_CPLD_TH, `D_CPLD_TD, `D_CPLD_EP, `D_CPLD_ATTR2, `D_CPLD_AT, tx_cpld_len};
r_tx_pcie_head1 <= {pcie_dev_id, `D_CPLD_CS, `D_CPLD_BCM, tx_cpld_bc};
r_tx_pcie_head2 <= {tx_cpld_req_id, tx_cpld_tag, 1'b0, tx_cpld_laddr};
r_tx_pcie_head3 <= tx_cpld_data[31:0];
end
6'b000010: begin
r_tx_pcie_head0 <= {`D_MRD_FMT, `D_MRD_TYPE, 1'b0, `D_MRD_TC, 1'b0, `D_MRD_ATTR1, 1'b0, `D_MRD_TH, `D_MRD_TD, `D_MRD_EP, `D_MRD_ATTR2, `D_MRD_AT, tx_mrd0_len};
r_tx_pcie_head1 <= {pcie_dev_id, tx_mrd0_tag, `D_MRD_LAST_BE, `D_MRD_1ST_BE};
r_tx_pcie_head2 <= {28'b0, tx_mrd0_addr[C_PCIE_ADDR_WIDTH-1:32]};
r_tx_pcie_head3 <= {tx_mrd0_addr[31:2], 2'b0};
end
6'b000100: begin
r_tx_pcie_head0 <= {`D_MRD_FMT, `D_MRD_TYPE, 1'b0, `D_MRD_TC, 1'b0, `D_MRD_ATTR1, 1'b0, `D_MRD_TH, `D_MRD_TD, `D_MRD_EP, `D_MRD_ATTR2, `D_MRD_AT, tx_mrd1_len};
r_tx_pcie_head1 <= {pcie_dev_id, tx_mrd1_tag, `D_MRD_LAST_BE, `D_MRD_1ST_BE};
r_tx_pcie_head2 <= {28'b0, tx_mrd1_addr[C_PCIE_ADDR_WIDTH-1:32]};
r_tx_pcie_head3 <= {tx_mrd1_addr[31:2], 2'b0};
end
6'b001000: begin
r_tx_pcie_head0 <= {`D_MRD_FMT, `D_MRD_TYPE, 1'b0, `D_MRD_TC, 1'b0, `D_MRD_ATTR1, 1'b0, `D_MRD_TH, `D_MRD_TD, `D_MRD_EP, `D_MRD_ATTR2, `D_MRD_AT, tx_mrd2_len};
r_tx_pcie_head1 <= {pcie_dev_id, tx_mrd2_tag, `D_MRD_LAST_BE, `D_MRD_1ST_BE};
r_tx_pcie_head2 <= {28'b0, tx_mrd2_addr[C_PCIE_ADDR_WIDTH-1:32]};
r_tx_pcie_head3 <= {tx_mrd2_addr[31:2], 2'b0};
end
6'b010000: begin
r_tx_pcie_head0 <= {`D_MWR_FMT, `D_MWR_TYPE, 1'b0, `D_MWR_TC, 1'b0, `D_MWR_ATTR1, 1'b0, `D_MWR_TH, `D_MWR_TD, `D_MWR_EP, `D_MWR_ATTR2, `D_MWR_AT, tx_mwr0_len};
r_tx_pcie_head1 <= {pcie_dev_id, tx_mwr0_tag, `D_MWR_LAST_BE, `D_MWR_1ST_BE};
r_tx_pcie_head2 <= {28'b0, tx_mwr0_addr[C_PCIE_ADDR_WIDTH-1:32]};
r_tx_pcie_head3 <= {tx_mwr0_addr[31:2], 2'b0};
end
6'b100000: begin
r_tx_pcie_head0 <= {`D_MWR_FMT, `D_MWR_TYPE, 1'b0, `D_MWR_TC, 1'b0, `D_MWR_ATTR1, 1'b0, `D_MWR_TH, `D_MWR_TD, `D_MWR_EP, `D_MWR_ATTR2, `D_MWR_AT, tx_mwr1_len};
r_tx_pcie_head1 <= {pcie_dev_id, tx_mwr1_tag, `D_MWR_LAST_BE, `D_MWR_1ST_BE};
r_tx_pcie_head2 <= {28'b0, tx_mwr1_addr[C_PCIE_ADDR_WIDTH-1:32]};
r_tx_pcie_head3 <= {tx_mwr1_addr[31:2], 2'b0};
end
endcase
end
endmodule
|
/*
----------------------------------------------------------------------------------
Copyright (c) 2013-2014
Embedded and Network Computing Lab.
Open SSD Project
Hanyang University
All rights reserved.
----------------------------------------------------------------------------------
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. All advertising materials mentioning features or use of this source code
must display the following acknowledgement:
This product includes source code developed
by the Embedded and Network Computing Lab. and the Open SSD Project.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
----------------------------------------------------------------------------------
http://enclab.hanyang.ac.kr/
http://www.openssd-project.org/
http://www.hanyang.ac.kr/
----------------------------------------------------------------------------------
*/
`timescale 1ns / 1ps
`include "def_pcie.vh"
module pcie_tx_arb # (
parameter C_PCIE_DATA_WIDTH = 128,
parameter C_PCIE_ADDR_WIDTH = 36
)
(
input pcie_user_clk,
input pcie_user_rst_n,
input [15:0] pcie_dev_id,
input tx_cpld_gnt,
input tx_mrd_gnt,
input tx_mwr_gnt,
input tx_cpld_req,
input [7:0] tx_cpld_tag,
input [15:0] tx_cpld_req_id,
input [11:2] tx_cpld_len,
input [11:0] tx_cpld_bc,
input [6:0] tx_cpld_laddr,
input [63:0] tx_cpld_data,
output tx_cpld_req_ack,
input tx_mrd0_req,
input [7:0] tx_mrd0_tag,
input [11:2] tx_mrd0_len,
input [C_PCIE_ADDR_WIDTH-1:2] tx_mrd0_addr,
output tx_mrd0_req_ack,
input tx_mrd1_req,
input [7:0] tx_mrd1_tag,
input [11:2] tx_mrd1_len,
input [C_PCIE_ADDR_WIDTH-1:2] tx_mrd1_addr,
output tx_mrd1_req_ack,
input tx_mrd2_req,
input [7:0] tx_mrd2_tag,
input [11:2] tx_mrd2_len,
input [C_PCIE_ADDR_WIDTH-1:2] tx_mrd2_addr,
output tx_mrd2_req_ack,
input tx_mwr0_req,
input [7:0] tx_mwr0_tag,
input [11:2] tx_mwr0_len,
input [C_PCIE_ADDR_WIDTH-1:2] tx_mwr0_addr,
output tx_mwr0_req_ack,
input tx_mwr1_req,
input [7:0] tx_mwr1_tag,
input [11:2] tx_mwr1_len,
input [C_PCIE_ADDR_WIDTH-1:2] tx_mwr1_addr,
output tx_mwr1_req_ack,
output tx_arb_valid,
output [5:0] tx_arb_gnt,
output [2:0] tx_arb_type,
output [11:2] tx_pcie_len,
output [127:0] tx_pcie_head,
output [31:0] tx_cpld_udata,
input tx_arb_rdy
);
reg [5:0] r_tx_req;
reg [5:0] r_tx_req_en;
wire [5:0] w_tx_req_en;
wire [5:0] w_tx_req_gnt;
reg [5:0] r_tx_req_ack;
wire [5:0] w_tx_req_ack;
reg [2:0] r_tx_type;
reg [5:0] r_tx_arb;
reg [5:0] r_tx_arb_cur;
reg [2:0] r_tx_arb_type;
reg [31:0] r_tx_pcie_head0;
reg [31:0] r_tx_pcie_head1;
reg [31:0] r_tx_pcie_head2;
reg [31:0] r_tx_pcie_head3;
assign tx_arb_valid = (r_tx_arb_cur[5] | r_tx_arb_cur[4]) | (r_tx_arb_cur[3] | r_tx_arb_cur[2]) | (r_tx_arb_cur[1] | r_tx_arb_cur[0]);
assign tx_arb_gnt = r_tx_arb_cur;
assign tx_arb_type = r_tx_arb_type;
assign tx_pcie_len = r_tx_pcie_head0[9:0];
assign tx_pcie_head = {r_tx_pcie_head3, r_tx_pcie_head2, r_tx_pcie_head1, r_tx_pcie_head0};
assign tx_cpld_udata = tx_cpld_data[63:32];
assign tx_cpld_req_ack = r_tx_req_ack[0];
assign tx_mrd0_req_ack = r_tx_req_ack[1];
assign tx_mrd1_req_ack = r_tx_req_ack[2];
assign tx_mrd2_req_ack = r_tx_req_ack[3];
assign tx_mwr0_req_ack = r_tx_req_ack[4];
assign tx_mwr1_req_ack = r_tx_req_ack[5];
assign w_tx_req_ack[0] = tx_arb_rdy & r_tx_arb_cur[0];
assign w_tx_req_ack[1] = tx_arb_rdy & r_tx_arb_cur[1];
assign w_tx_req_ack[2] = tx_arb_rdy & r_tx_arb_cur[2];
assign w_tx_req_ack[3] = tx_arb_rdy & r_tx_arb_cur[3];
assign w_tx_req_ack[4] = tx_arb_rdy & r_tx_arb_cur[4];
assign w_tx_req_ack[5] = tx_arb_rdy & r_tx_arb_cur[5];
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0) begin
r_tx_req <= 0;
end
else begin
if(tx_cpld_req == 1)
r_tx_req[0] <= 1;
else if(w_tx_req_ack[0] == 1)
r_tx_req[0] <= 0;
if(tx_mrd0_req == 1)
r_tx_req[1] <= 1;
else if(w_tx_req_ack[1] == 1)
r_tx_req[1] <= 0;
if(tx_mrd1_req == 1)
r_tx_req[2] <= 1;
else if(w_tx_req_ack[2] == 1)
r_tx_req[2] <= 0;
if(tx_mrd2_req == 1)
r_tx_req[3] <= 1;
else if(w_tx_req_ack[3] == 1)
r_tx_req[3] <= 0;
if(tx_mwr0_req == 1)
r_tx_req[4] <= 1;
else if(w_tx_req_ack[4] == 1)
r_tx_req[4] <= 0;
if(tx_mwr1_req == 1)
r_tx_req[5] <= 1;
else if(w_tx_req_ack[5] == 1)
r_tx_req[5] <= 0;
end
end
always @ (*)
begin
if(tx_arb_rdy == 1)
r_tx_req_en <= r_tx_req & ~r_tx_arb_cur;
else
r_tx_req_en <= r_tx_req;
end
assign w_tx_req_gnt[0] = tx_cpld_gnt;
assign w_tx_req_gnt[1] = tx_mrd_gnt;
assign w_tx_req_gnt[2] = tx_mrd_gnt;
assign w_tx_req_gnt[3] = tx_mrd_gnt;
assign w_tx_req_gnt[4] = tx_mwr_gnt;
assign w_tx_req_gnt[5] = tx_mwr_gnt;
assign w_tx_req_en = r_tx_req_en & w_tx_req_gnt;
always @ (*)
begin
if(w_tx_req_en[0] == 1) begin
r_tx_type <= 3'b001;
r_tx_arb <= 6'b000001;
end
else if(w_tx_req_en[1] == 1) begin
r_tx_type <= 3'b010;
r_tx_arb <= 6'b000010;
end
else if(w_tx_req_en[2] == 1) begin
r_tx_type <= 3'b010;
r_tx_arb <= 6'b000100;
end
else if(w_tx_req_en[4] == 1) begin
r_tx_type <= 3'b100;
r_tx_arb <= 6'b010000;
end
else if(w_tx_req_en[3] == 1) begin
r_tx_type <= 3'b010;
r_tx_arb <= 6'b001000;
end
else if(w_tx_req_en[5] == 1) begin
r_tx_type <= 3'b100;
r_tx_arb <= 6'b100000;
end
else begin
r_tx_type <= 3'b000;
r_tx_arb <= 6'b000000;
end
end
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0)
r_tx_arb_cur <= 0;
else
r_tx_arb_cur <= r_tx_arb;
end
always @ (posedge pcie_user_clk)
begin
r_tx_arb_type <= r_tx_type;
r_tx_req_ack <= w_tx_req_ack;
end
always @ (*)
begin
case(r_tx_arb_cur) // synthesis parallel_case full_case
6'b000001: begin
r_tx_pcie_head0 <= {`D_CPLD_FMT, `D_CPLD_TYPE, 1'b0, `D_CPLD_TC, 1'b0, `D_CPLD_ATTR1, 1'b0, `D_CPLD_TH, `D_CPLD_TD, `D_CPLD_EP, `D_CPLD_ATTR2, `D_CPLD_AT, tx_cpld_len};
r_tx_pcie_head1 <= {pcie_dev_id, `D_CPLD_CS, `D_CPLD_BCM, tx_cpld_bc};
r_tx_pcie_head2 <= {tx_cpld_req_id, tx_cpld_tag, 1'b0, tx_cpld_laddr};
r_tx_pcie_head3 <= tx_cpld_data[31:0];
end
6'b000010: begin
r_tx_pcie_head0 <= {`D_MRD_FMT, `D_MRD_TYPE, 1'b0, `D_MRD_TC, 1'b0, `D_MRD_ATTR1, 1'b0, `D_MRD_TH, `D_MRD_TD, `D_MRD_EP, `D_MRD_ATTR2, `D_MRD_AT, tx_mrd0_len};
r_tx_pcie_head1 <= {pcie_dev_id, tx_mrd0_tag, `D_MRD_LAST_BE, `D_MRD_1ST_BE};
r_tx_pcie_head2 <= {28'b0, tx_mrd0_addr[C_PCIE_ADDR_WIDTH-1:32]};
r_tx_pcie_head3 <= {tx_mrd0_addr[31:2], 2'b0};
end
6'b000100: begin
r_tx_pcie_head0 <= {`D_MRD_FMT, `D_MRD_TYPE, 1'b0, `D_MRD_TC, 1'b0, `D_MRD_ATTR1, 1'b0, `D_MRD_TH, `D_MRD_TD, `D_MRD_EP, `D_MRD_ATTR2, `D_MRD_AT, tx_mrd1_len};
r_tx_pcie_head1 <= {pcie_dev_id, tx_mrd1_tag, `D_MRD_LAST_BE, `D_MRD_1ST_BE};
r_tx_pcie_head2 <= {28'b0, tx_mrd1_addr[C_PCIE_ADDR_WIDTH-1:32]};
r_tx_pcie_head3 <= {tx_mrd1_addr[31:2], 2'b0};
end
6'b001000: begin
r_tx_pcie_head0 <= {`D_MRD_FMT, `D_MRD_TYPE, 1'b0, `D_MRD_TC, 1'b0, `D_MRD_ATTR1, 1'b0, `D_MRD_TH, `D_MRD_TD, `D_MRD_EP, `D_MRD_ATTR2, `D_MRD_AT, tx_mrd2_len};
r_tx_pcie_head1 <= {pcie_dev_id, tx_mrd2_tag, `D_MRD_LAST_BE, `D_MRD_1ST_BE};
r_tx_pcie_head2 <= {28'b0, tx_mrd2_addr[C_PCIE_ADDR_WIDTH-1:32]};
r_tx_pcie_head3 <= {tx_mrd2_addr[31:2], 2'b0};
end
6'b010000: begin
r_tx_pcie_head0 <= {`D_MWR_FMT, `D_MWR_TYPE, 1'b0, `D_MWR_TC, 1'b0, `D_MWR_ATTR1, 1'b0, `D_MWR_TH, `D_MWR_TD, `D_MWR_EP, `D_MWR_ATTR2, `D_MWR_AT, tx_mwr0_len};
r_tx_pcie_head1 <= {pcie_dev_id, tx_mwr0_tag, `D_MWR_LAST_BE, `D_MWR_1ST_BE};
r_tx_pcie_head2 <= {28'b0, tx_mwr0_addr[C_PCIE_ADDR_WIDTH-1:32]};
r_tx_pcie_head3 <= {tx_mwr0_addr[31:2], 2'b0};
end
6'b100000: begin
r_tx_pcie_head0 <= {`D_MWR_FMT, `D_MWR_TYPE, 1'b0, `D_MWR_TC, 1'b0, `D_MWR_ATTR1, 1'b0, `D_MWR_TH, `D_MWR_TD, `D_MWR_EP, `D_MWR_ATTR2, `D_MWR_AT, tx_mwr1_len};
r_tx_pcie_head1 <= {pcie_dev_id, tx_mwr1_tag, `D_MWR_LAST_BE, `D_MWR_1ST_BE};
r_tx_pcie_head2 <= {28'b0, tx_mwr1_addr[C_PCIE_ADDR_WIDTH-1:32]};
r_tx_pcie_head3 <= {tx_mwr1_addr[31:2], 2'b0};
end
endcase
end
endmodule
|
/*
----------------------------------------------------------------------------------
Copyright (c) 2013-2014
Embedded and Network Computing Lab.
Open SSD Project
Hanyang University
All rights reserved.
----------------------------------------------------------------------------------
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. All advertising materials mentioning features or use of this source code
must display the following acknowledgement:
This product includes source code developed
by the Embedded and Network Computing Lab. and the Open SSD Project.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
----------------------------------------------------------------------------------
http://enclab.hanyang.ac.kr/
http://www.openssd-project.org/
http://www.hanyang.ac.kr/
----------------------------------------------------------------------------------
*/
`timescale 1ns / 1ps
`include "def_pcie.vh"
module pcie_tx_arb # (
parameter C_PCIE_DATA_WIDTH = 128,
parameter C_PCIE_ADDR_WIDTH = 36
)
(
input pcie_user_clk,
input pcie_user_rst_n,
input [15:0] pcie_dev_id,
input tx_cpld_gnt,
input tx_mrd_gnt,
input tx_mwr_gnt,
input tx_cpld_req,
input [7:0] tx_cpld_tag,
input [15:0] tx_cpld_req_id,
input [11:2] tx_cpld_len,
input [11:0] tx_cpld_bc,
input [6:0] tx_cpld_laddr,
input [63:0] tx_cpld_data,
output tx_cpld_req_ack,
input tx_mrd0_req,
input [7:0] tx_mrd0_tag,
input [11:2] tx_mrd0_len,
input [C_PCIE_ADDR_WIDTH-1:2] tx_mrd0_addr,
output tx_mrd0_req_ack,
input tx_mrd1_req,
input [7:0] tx_mrd1_tag,
input [11:2] tx_mrd1_len,
input [C_PCIE_ADDR_WIDTH-1:2] tx_mrd1_addr,
output tx_mrd1_req_ack,
input tx_mrd2_req,
input [7:0] tx_mrd2_tag,
input [11:2] tx_mrd2_len,
input [C_PCIE_ADDR_WIDTH-1:2] tx_mrd2_addr,
output tx_mrd2_req_ack,
input tx_mwr0_req,
input [7:0] tx_mwr0_tag,
input [11:2] tx_mwr0_len,
input [C_PCIE_ADDR_WIDTH-1:2] tx_mwr0_addr,
output tx_mwr0_req_ack,
input tx_mwr1_req,
input [7:0] tx_mwr1_tag,
input [11:2] tx_mwr1_len,
input [C_PCIE_ADDR_WIDTH-1:2] tx_mwr1_addr,
output tx_mwr1_req_ack,
output tx_arb_valid,
output [5:0] tx_arb_gnt,
output [2:0] tx_arb_type,
output [11:2] tx_pcie_len,
output [127:0] tx_pcie_head,
output [31:0] tx_cpld_udata,
input tx_arb_rdy
);
reg [5:0] r_tx_req;
reg [5:0] r_tx_req_en;
wire [5:0] w_tx_req_en;
wire [5:0] w_tx_req_gnt;
reg [5:0] r_tx_req_ack;
wire [5:0] w_tx_req_ack;
reg [2:0] r_tx_type;
reg [5:0] r_tx_arb;
reg [5:0] r_tx_arb_cur;
reg [2:0] r_tx_arb_type;
reg [31:0] r_tx_pcie_head0;
reg [31:0] r_tx_pcie_head1;
reg [31:0] r_tx_pcie_head2;
reg [31:0] r_tx_pcie_head3;
assign tx_arb_valid = (r_tx_arb_cur[5] | r_tx_arb_cur[4]) | (r_tx_arb_cur[3] | r_tx_arb_cur[2]) | (r_tx_arb_cur[1] | r_tx_arb_cur[0]);
assign tx_arb_gnt = r_tx_arb_cur;
assign tx_arb_type = r_tx_arb_type;
assign tx_pcie_len = r_tx_pcie_head0[9:0];
assign tx_pcie_head = {r_tx_pcie_head3, r_tx_pcie_head2, r_tx_pcie_head1, r_tx_pcie_head0};
assign tx_cpld_udata = tx_cpld_data[63:32];
assign tx_cpld_req_ack = r_tx_req_ack[0];
assign tx_mrd0_req_ack = r_tx_req_ack[1];
assign tx_mrd1_req_ack = r_tx_req_ack[2];
assign tx_mrd2_req_ack = r_tx_req_ack[3];
assign tx_mwr0_req_ack = r_tx_req_ack[4];
assign tx_mwr1_req_ack = r_tx_req_ack[5];
assign w_tx_req_ack[0] = tx_arb_rdy & r_tx_arb_cur[0];
assign w_tx_req_ack[1] = tx_arb_rdy & r_tx_arb_cur[1];
assign w_tx_req_ack[2] = tx_arb_rdy & r_tx_arb_cur[2];
assign w_tx_req_ack[3] = tx_arb_rdy & r_tx_arb_cur[3];
assign w_tx_req_ack[4] = tx_arb_rdy & r_tx_arb_cur[4];
assign w_tx_req_ack[5] = tx_arb_rdy & r_tx_arb_cur[5];
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0) begin
r_tx_req <= 0;
end
else begin
if(tx_cpld_req == 1)
r_tx_req[0] <= 1;
else if(w_tx_req_ack[0] == 1)
r_tx_req[0] <= 0;
if(tx_mrd0_req == 1)
r_tx_req[1] <= 1;
else if(w_tx_req_ack[1] == 1)
r_tx_req[1] <= 0;
if(tx_mrd1_req == 1)
r_tx_req[2] <= 1;
else if(w_tx_req_ack[2] == 1)
r_tx_req[2] <= 0;
if(tx_mrd2_req == 1)
r_tx_req[3] <= 1;
else if(w_tx_req_ack[3] == 1)
r_tx_req[3] <= 0;
if(tx_mwr0_req == 1)
r_tx_req[4] <= 1;
else if(w_tx_req_ack[4] == 1)
r_tx_req[4] <= 0;
if(tx_mwr1_req == 1)
r_tx_req[5] <= 1;
else if(w_tx_req_ack[5] == 1)
r_tx_req[5] <= 0;
end
end
always @ (*)
begin
if(tx_arb_rdy == 1)
r_tx_req_en <= r_tx_req & ~r_tx_arb_cur;
else
r_tx_req_en <= r_tx_req;
end
assign w_tx_req_gnt[0] = tx_cpld_gnt;
assign w_tx_req_gnt[1] = tx_mrd_gnt;
assign w_tx_req_gnt[2] = tx_mrd_gnt;
assign w_tx_req_gnt[3] = tx_mrd_gnt;
assign w_tx_req_gnt[4] = tx_mwr_gnt;
assign w_tx_req_gnt[5] = tx_mwr_gnt;
assign w_tx_req_en = r_tx_req_en & w_tx_req_gnt;
always @ (*)
begin
if(w_tx_req_en[0] == 1) begin
r_tx_type <= 3'b001;
r_tx_arb <= 6'b000001;
end
else if(w_tx_req_en[1] == 1) begin
r_tx_type <= 3'b010;
r_tx_arb <= 6'b000010;
end
else if(w_tx_req_en[2] == 1) begin
r_tx_type <= 3'b010;
r_tx_arb <= 6'b000100;
end
else if(w_tx_req_en[4] == 1) begin
r_tx_type <= 3'b100;
r_tx_arb <= 6'b010000;
end
else if(w_tx_req_en[3] == 1) begin
r_tx_type <= 3'b010;
r_tx_arb <= 6'b001000;
end
else if(w_tx_req_en[5] == 1) begin
r_tx_type <= 3'b100;
r_tx_arb <= 6'b100000;
end
else begin
r_tx_type <= 3'b000;
r_tx_arb <= 6'b000000;
end
end
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0)
r_tx_arb_cur <= 0;
else
r_tx_arb_cur <= r_tx_arb;
end
always @ (posedge pcie_user_clk)
begin
r_tx_arb_type <= r_tx_type;
r_tx_req_ack <= w_tx_req_ack;
end
always @ (*)
begin
case(r_tx_arb_cur) // synthesis parallel_case full_case
6'b000001: begin
r_tx_pcie_head0 <= {`D_CPLD_FMT, `D_CPLD_TYPE, 1'b0, `D_CPLD_TC, 1'b0, `D_CPLD_ATTR1, 1'b0, `D_CPLD_TH, `D_CPLD_TD, `D_CPLD_EP, `D_CPLD_ATTR2, `D_CPLD_AT, tx_cpld_len};
r_tx_pcie_head1 <= {pcie_dev_id, `D_CPLD_CS, `D_CPLD_BCM, tx_cpld_bc};
r_tx_pcie_head2 <= {tx_cpld_req_id, tx_cpld_tag, 1'b0, tx_cpld_laddr};
r_tx_pcie_head3 <= tx_cpld_data[31:0];
end
6'b000010: begin
r_tx_pcie_head0 <= {`D_MRD_FMT, `D_MRD_TYPE, 1'b0, `D_MRD_TC, 1'b0, `D_MRD_ATTR1, 1'b0, `D_MRD_TH, `D_MRD_TD, `D_MRD_EP, `D_MRD_ATTR2, `D_MRD_AT, tx_mrd0_len};
r_tx_pcie_head1 <= {pcie_dev_id, tx_mrd0_tag, `D_MRD_LAST_BE, `D_MRD_1ST_BE};
r_tx_pcie_head2 <= {28'b0, tx_mrd0_addr[C_PCIE_ADDR_WIDTH-1:32]};
r_tx_pcie_head3 <= {tx_mrd0_addr[31:2], 2'b0};
end
6'b000100: begin
r_tx_pcie_head0 <= {`D_MRD_FMT, `D_MRD_TYPE, 1'b0, `D_MRD_TC, 1'b0, `D_MRD_ATTR1, 1'b0, `D_MRD_TH, `D_MRD_TD, `D_MRD_EP, `D_MRD_ATTR2, `D_MRD_AT, tx_mrd1_len};
r_tx_pcie_head1 <= {pcie_dev_id, tx_mrd1_tag, `D_MRD_LAST_BE, `D_MRD_1ST_BE};
r_tx_pcie_head2 <= {28'b0, tx_mrd1_addr[C_PCIE_ADDR_WIDTH-1:32]};
r_tx_pcie_head3 <= {tx_mrd1_addr[31:2], 2'b0};
end
6'b001000: begin
r_tx_pcie_head0 <= {`D_MRD_FMT, `D_MRD_TYPE, 1'b0, `D_MRD_TC, 1'b0, `D_MRD_ATTR1, 1'b0, `D_MRD_TH, `D_MRD_TD, `D_MRD_EP, `D_MRD_ATTR2, `D_MRD_AT, tx_mrd2_len};
r_tx_pcie_head1 <= {pcie_dev_id, tx_mrd2_tag, `D_MRD_LAST_BE, `D_MRD_1ST_BE};
r_tx_pcie_head2 <= {28'b0, tx_mrd2_addr[C_PCIE_ADDR_WIDTH-1:32]};
r_tx_pcie_head3 <= {tx_mrd2_addr[31:2], 2'b0};
end
6'b010000: begin
r_tx_pcie_head0 <= {`D_MWR_FMT, `D_MWR_TYPE, 1'b0, `D_MWR_TC, 1'b0, `D_MWR_ATTR1, 1'b0, `D_MWR_TH, `D_MWR_TD, `D_MWR_EP, `D_MWR_ATTR2, `D_MWR_AT, tx_mwr0_len};
r_tx_pcie_head1 <= {pcie_dev_id, tx_mwr0_tag, `D_MWR_LAST_BE, `D_MWR_1ST_BE};
r_tx_pcie_head2 <= {28'b0, tx_mwr0_addr[C_PCIE_ADDR_WIDTH-1:32]};
r_tx_pcie_head3 <= {tx_mwr0_addr[31:2], 2'b0};
end
6'b100000: begin
r_tx_pcie_head0 <= {`D_MWR_FMT, `D_MWR_TYPE, 1'b0, `D_MWR_TC, 1'b0, `D_MWR_ATTR1, 1'b0, `D_MWR_TH, `D_MWR_TD, `D_MWR_EP, `D_MWR_ATTR2, `D_MWR_AT, tx_mwr1_len};
r_tx_pcie_head1 <= {pcie_dev_id, tx_mwr1_tag, `D_MWR_LAST_BE, `D_MWR_1ST_BE};
r_tx_pcie_head2 <= {28'b0, tx_mwr1_addr[C_PCIE_ADDR_WIDTH-1:32]};
r_tx_pcie_head3 <= {tx_mwr1_addr[31:2], 2'b0};
end
endcase
end
endmodule
|
// soc_design_mm_interconnect_0_avalon_st_adapter.v
// This file was auto-generated from altera_avalon_st_adapter_hw.tcl. If you edit it your changes
// will probably be lost.
//
// Generated using ACDS version 16.0 211
`timescale 1 ps / 1 ps
module soc_design_mm_interconnect_0_avalon_st_adapter #(
parameter inBitsPerSymbol = 34,
parameter inUsePackets = 0,
parameter inDataWidth = 34,
parameter inChannelWidth = 0,
parameter inErrorWidth = 0,
parameter inUseEmptyPort = 0,
parameter inUseValid = 1,
parameter inUseReady = 1,
parameter inReadyLatency = 0,
parameter outDataWidth = 34,
parameter outChannelWidth = 0,
parameter outErrorWidth = 1,
parameter outUseEmptyPort = 0,
parameter outUseValid = 1,
parameter outUseReady = 1,
parameter outReadyLatency = 0
) (
input wire in_clk_0_clk, // in_clk_0.clk
input wire in_rst_0_reset, // in_rst_0.reset
input wire [33:0] in_0_data, // in_0.data
input wire in_0_valid, // .valid
output wire in_0_ready, // .ready
output wire [33:0] out_0_data, // out_0.data
output wire out_0_valid, // .valid
input wire out_0_ready, // .ready
output wire [0:0] out_0_error // .error
);
generate
// If any of the display statements (or deliberately broken
// instantiations) within this generate block triggers then this module
// has been instantiated this module with a set of parameters different
// from those it was generated for. This will usually result in a
// non-functioning system.
if (inBitsPerSymbol != 34)
begin
initial begin
$display("Generated module instantiated with wrong parameters");
$stop;
end
instantiated_with_wrong_parameters_error_see_comment_above
inbitspersymbol_check ( .error(1'b1) );
end
if (inUsePackets != 0)
begin
initial begin
$display("Generated module instantiated with wrong parameters");
$stop;
end
instantiated_with_wrong_parameters_error_see_comment_above
inusepackets_check ( .error(1'b1) );
end
if (inDataWidth != 34)
begin
initial begin
$display("Generated module instantiated with wrong parameters");
$stop;
end
instantiated_with_wrong_parameters_error_see_comment_above
indatawidth_check ( .error(1'b1) );
end
if (inChannelWidth != 0)
begin
initial begin
$display("Generated module instantiated with wrong parameters");
$stop;
end
instantiated_with_wrong_parameters_error_see_comment_above
inchannelwidth_check ( .error(1'b1) );
end
if (inErrorWidth != 0)
begin
initial begin
$display("Generated module instantiated with wrong parameters");
$stop;
end
instantiated_with_wrong_parameters_error_see_comment_above
inerrorwidth_check ( .error(1'b1) );
end
if (inUseEmptyPort != 0)
begin
initial begin
$display("Generated module instantiated with wrong parameters");
$stop;
end
instantiated_with_wrong_parameters_error_see_comment_above
inuseemptyport_check ( .error(1'b1) );
end
if (inUseValid != 1)
begin
initial begin
$display("Generated module instantiated with wrong parameters");
$stop;
end
instantiated_with_wrong_parameters_error_see_comment_above
inusevalid_check ( .error(1'b1) );
end
if (inUseReady != 1)
begin
initial begin
$display("Generated module instantiated with wrong parameters");
$stop;
end
instantiated_with_wrong_parameters_error_see_comment_above
inuseready_check ( .error(1'b1) );
end
if (inReadyLatency != 0)
begin
initial begin
$display("Generated module instantiated with wrong parameters");
$stop;
end
instantiated_with_wrong_parameters_error_see_comment_above
inreadylatency_check ( .error(1'b1) );
end
if (outDataWidth != 34)
begin
initial begin
$display("Generated module instantiated with wrong parameters");
$stop;
end
instantiated_with_wrong_parameters_error_see_comment_above
outdatawidth_check ( .error(1'b1) );
end
if (outChannelWidth != 0)
begin
initial begin
$display("Generated module instantiated with wrong parameters");
$stop;
end
instantiated_with_wrong_parameters_error_see_comment_above
outchannelwidth_check ( .error(1'b1) );
end
if (outErrorWidth != 1)
begin
initial begin
$display("Generated module instantiated with wrong parameters");
$stop;
end
instantiated_with_wrong_parameters_error_see_comment_above
outerrorwidth_check ( .error(1'b1) );
end
if (outUseEmptyPort != 0)
begin
initial begin
$display("Generated module instantiated with wrong parameters");
$stop;
end
instantiated_with_wrong_parameters_error_see_comment_above
outuseemptyport_check ( .error(1'b1) );
end
if (outUseValid != 1)
begin
initial begin
$display("Generated module instantiated with wrong parameters");
$stop;
end
instantiated_with_wrong_parameters_error_see_comment_above
outusevalid_check ( .error(1'b1) );
end
if (outUseReady != 1)
begin
initial begin
$display("Generated module instantiated with wrong parameters");
$stop;
end
instantiated_with_wrong_parameters_error_see_comment_above
outuseready_check ( .error(1'b1) );
end
if (outReadyLatency != 0)
begin
initial begin
$display("Generated module instantiated with wrong parameters");
$stop;
end
instantiated_with_wrong_parameters_error_see_comment_above
outreadylatency_check ( .error(1'b1) );
end
endgenerate
soc_design_mm_interconnect_0_avalon_st_adapter_error_adapter_0 error_adapter_0 (
.clk (in_clk_0_clk), // clk.clk
.reset_n (~in_rst_0_reset), // reset.reset_n
.in_data (in_0_data), // in.data
.in_valid (in_0_valid), // .valid
.in_ready (in_0_ready), // .ready
.out_data (out_0_data), // out.data
.out_valid (out_0_valid), // .valid
.out_ready (out_0_ready), // .ready
.out_error (out_0_error) // .error
);
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2011 by Wilson Snyder.
//
// bug354
typedef logic [5:0] data_t;
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
integer cyc=0;
reg [63:0] crc;
reg [63:0] sum;
// Take CRC data and apply to testblock inputs
wire rst;
data_t iii_in = crc[5:0];
data_t jjj_in = crc[11:6];
data_t iii_out;
data_t jjj_out;
logic [1:0] ctl0 = crc[63:62];
aaa aaa (.*);
// Aggregate outputs into a single result vector
wire [63:0] result = {64'h0};
// Test loop
always @ (posedge clk) begin
`ifdef TEST_VERBOSE
$write("[%0t] cyc==%0d crc=%x result=%x\n",$time, cyc, crc, result);
`endif
cyc <= cyc + 1;
crc <= {crc[62:0], crc[63]^crc[2]^crc[0]};
sum <= result ^ {sum[62:0],sum[63]^sum[2]^sum[0]};
if (cyc==0) begin
// Setup
crc <= 64'h5aef0c8d_d70a4497;
sum <= 64'h0;
rst <= 1'b0;
end
else if (cyc<10) begin
sum <= 64'h0;
rst <= 1'b1;
end
else if (cyc<90) begin
rst <= 1'b0;
end
else if (cyc==99) begin
$write("[%0t] cyc==%0d crc=%x sum=%x\n",$time, cyc, crc, sum);
if (crc !== 64'hc77bb9b3784ea091) $stop;
// What checksum will we end up with (above print should match)
`define EXPECTED_SUM 64'h4afe43fb79d7b71e
if (sum !== `EXPECTED_SUM) $stop;
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
module bbb
(
output data_t ggg_out[1:0],
input data_t ggg_in [1:0],
input [1:0] [1:0] ctl,
input logic clk,
input logic rst
);
genvar i;
generate
for (i=0; i<2; i++) begin: PPP
always_ff @(posedge clk) begin
if (rst) begin
ggg_out[i] <= 6'b0;
end
else begin
if (ctl[i][0]) begin
if (ctl[i][1]) begin
ggg_out[i] <= ~ggg_in[i];
end else begin
ggg_out[i] <= ggg_in[i];
end
end
end
end
end
endgenerate
endmodule
module aaa
(
input data_t iii_in,
input data_t jjj_in,
input [1:0] ctl0,
output data_t iii_out,
output data_t jjj_out,
input logic clk,
input logic rst
);
// Below is a bug; {} concat isn't used to make arrays
bbb bbb (
.ggg_in ({jjj_in, iii_in}),
.ggg_out ({jjj_out, iii_out}),
.ctl ({{1'b1,ctl0[1]}, {1'b0,ctl0[0]}}),
.*);
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2011 by Wilson Snyder.
//
// bug354
typedef logic [5:0] data_t;
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
integer cyc=0;
reg [63:0] crc;
reg [63:0] sum;
// Take CRC data and apply to testblock inputs
wire rst;
data_t iii_in = crc[5:0];
data_t jjj_in = crc[11:6];
data_t iii_out;
data_t jjj_out;
logic [1:0] ctl0 = crc[63:62];
aaa aaa (.*);
// Aggregate outputs into a single result vector
wire [63:0] result = {64'h0};
// Test loop
always @ (posedge clk) begin
`ifdef TEST_VERBOSE
$write("[%0t] cyc==%0d crc=%x result=%x\n",$time, cyc, crc, result);
`endif
cyc <= cyc + 1;
crc <= {crc[62:0], crc[63]^crc[2]^crc[0]};
sum <= result ^ {sum[62:0],sum[63]^sum[2]^sum[0]};
if (cyc==0) begin
// Setup
crc <= 64'h5aef0c8d_d70a4497;
sum <= 64'h0;
rst <= 1'b0;
end
else if (cyc<10) begin
sum <= 64'h0;
rst <= 1'b1;
end
else if (cyc<90) begin
rst <= 1'b0;
end
else if (cyc==99) begin
$write("[%0t] cyc==%0d crc=%x sum=%x\n",$time, cyc, crc, sum);
if (crc !== 64'hc77bb9b3784ea091) $stop;
// What checksum will we end up with (above print should match)
`define EXPECTED_SUM 64'h4afe43fb79d7b71e
if (sum !== `EXPECTED_SUM) $stop;
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
module bbb
(
output data_t ggg_out[1:0],
input data_t ggg_in [1:0],
input [1:0] [1:0] ctl,
input logic clk,
input logic rst
);
genvar i;
generate
for (i=0; i<2; i++) begin: PPP
always_ff @(posedge clk) begin
if (rst) begin
ggg_out[i] <= 6'b0;
end
else begin
if (ctl[i][0]) begin
if (ctl[i][1]) begin
ggg_out[i] <= ~ggg_in[i];
end else begin
ggg_out[i] <= ggg_in[i];
end
end
end
end
end
endgenerate
endmodule
module aaa
(
input data_t iii_in,
input data_t jjj_in,
input [1:0] ctl0,
output data_t iii_out,
output data_t jjj_out,
input logic clk,
input logic rst
);
// Below is a bug; {} concat isn't used to make arrays
bbb bbb (
.ggg_in ({jjj_in, iii_in}),
.ggg_out ({jjj_out, iii_out}),
.ctl ({{1'b1,ctl0[1]}, {1'b0,ctl0[0]}}),
.*);
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2008 by Mahesh Kumashikar
module t_math_synmul_mul ( /*AUTOARG*/
// Outputs
product_d4,
// Inputs
clk, enable, negate, datA, datB
);
input clk;
input enable;
input negate;
input [31:0] datA;
input [31:0] datB;
// verilator lint_off UNOPTFLAT
output reg [64:0] product_d4;
reg [33:0] datA_d1r;
reg [33:0] datB_d1r;
always @ (posedge clk) begin
if (enable) begin
datA_d1r <= {2'b0,datA};
datB_d1r <= {2'b0,datB};
// The extra multiplier bits were for signed, for this
// test we've ripped that out
if (negate) $stop;
end
end
reg en_d1;
reg en_d2;
reg en_d3;
always @ (posedge clk) begin
en_d1 <= enable;
en_d2 <= en_d1;
en_d3 <= en_d2;
end
wire [63:0] prod_d3;
smmultiplier_34_34 mul (.OPA(datA_d1r),
.OPB(datB_d1r),
.RESULT(prod_d3),
/*AUTOINST*/
// Inputs
.clk (clk),
.en_d1 (en_d1),
.en_d2 (en_d2));
always @ (posedge clk) begin
if (en_d3) begin
product_d4 <= {1'b0,prod_d3};
end
end
endmodule
// The below was originally generated by the "Synthesizable Arithmetic Module Generator"
// at http://modgen.fysel.ntnu.no/~pihl/iwlas98/ then cleaned up by hand.
// Unfortunately the generator no longer appears available. Please contact
// us if you know otherwise.
module smmultiplier_34_34
(
input clk,
input en_d1,
input en_d2,
input [33:0] OPA,
input [33:0] OPB,
output [63:0] RESULT
);
wire [628:0] PPBIT;
wire [66:0] INT_CARRY;
wire [66:0] INT_SUM;
smboothcoder_34_34 db (.OPA(OPA[33:0]), .OPB(OPB[33:0]), .SUMMAND(PPBIT[628:0]) );
smwallace_34_34 dw (.SUMMAND(PPBIT[628:0]), .CARRY(INT_CARRY[66:1]), .SUM(INT_SUM[66:0]),
/*AUTOINST*/
// Inputs
.clk (clk),
.en_d1 (en_d1),
.en_d2 (en_d2));
assign INT_CARRY[0] = 1'b0;
smdblcadder_128_128 dd (.OPA(INT_SUM[63:0]), .OPB(INT_CARRY[63:0]), .CIN (1'b0), .SUM(RESULT));
endmodule
module smdblcadder_128_128 ( OPA, OPB, CIN, SUM );
input [63:0] OPA;
input [63:0] OPB;
input CIN;
output [63:0] SUM;
wire [63:0] INTPROP;
wire [63:0] INTGEN;
wire [0:0] PBIT;
wire [63:0] CARRY;
smprestage_128 dp (OPA[63:0], OPB[63:0], CIN, INTPROP, INTGEN );
smdblctree_128 dd (INTPROP[63:0], INTGEN[63:0], CARRY[63:0], PBIT );
smxorstage_128 dx (OPA[63:0], OPB[63:0], PBIT[0], CARRY[63:0], SUM );
endmodule
module smdblctree_128 ( PIN, GIN, GOUT, POUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] GOUT;
output [0:0] POUT;
wire [63:0] INTPROP_0;
wire [63:0] INTGEN_0;
wire [63:0] INTPROP_1;
wire [63:0] INTGEN_1;
wire [63:0] INTPROP_2;
wire [63:0] INTGEN_2;
wire [63:0] INTPROP_3;
wire [63:0] INTGEN_3;
wire [63:0] INTPROP_4;
wire [63:0] INTGEN_4;
wire [63:0] INTPROP_5;
wire [63:0] INTGEN_5;
smdblc_0_128 ddb0 (.PIN(PIN), .GIN(GIN), .POUT(INTPROP_0), .GOUT(INTGEN_0) );
smdblc_1_128 ddb1 (.PIN(INTPROP_0), .GIN(INTGEN_0), .POUT(INTPROP_1), .GOUT(INTGEN_1) );
smdblc_2_128 ddb2 (.PIN(INTPROP_1), .GIN(INTGEN_1), .POUT(INTPROP_2), .GOUT(INTGEN_2) );
smdblc_3_128 ddb3 (.PIN(INTPROP_2), .GIN(INTGEN_2), .POUT(INTPROP_3), .GOUT(INTGEN_3) );
smdblc_4_128 ddb4 (.PIN(INTPROP_3), .GIN(INTGEN_3), .POUT(INTPROP_4), .GOUT(INTGEN_4) );
smdblc_5_128 ddb5 (.PIN(INTPROP_4), .GIN(INTGEN_4), .POUT(INTPROP_5), .GOUT(INTGEN_5) );
smdblc_6_128 ddb6 (.PIN(INTPROP_5), .GIN(INTGEN_5), .POUT(POUT), .GOUT(GOUT) );
endmodule
module smwallace_34_34
(
input clk,
input en_d1,
input en_d2,
input [628:0] SUMMAND,
output [65:0] CARRY,
output [66:0] SUM
);
wire [628:0] LATCHED_PP;
wire [551:0] INT_CARRY;
wire [687:0] INT_SUM;
smffa dla0 (.D(SUMMAND[0]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[0]) );
smffa dla1 (.D(SUMMAND[1]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[1]) );
smhalfadder dha0 (.DATA_A (LATCHED_PP[0]), .DATA_B (LATCHED_PP[1]), .SAVE (INT_SUM[0]), .CARRY (INT_CARRY[0]) );
smffb dla2 (.D(INT_SUM[0]), .clk(clk), .en_d2(en_d2), .Q(SUM[0]) );
smffb dla3 (.D(INT_CARRY[0]), .clk(clk), .en_d2(en_d2), .Q(CARRY[0]) );
smffa dla4 (.D(SUMMAND[2]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[2]) );
assign INT_SUM[1] = LATCHED_PP[2];
assign CARRY[1] = 1'b0;
smffb dla5 (.D(INT_SUM[1]), .clk(clk), .en_d2(en_d2), .Q(SUM[1]) );
smffa dla6 (.D(SUMMAND[3]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[3]) );
smffa dla7 (.D(SUMMAND[4]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[4]) );
smffa dla8 (.D(SUMMAND[5]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[5]) );
smfulladder dfa0 (.DATA_A (LATCHED_PP[3]), .DATA_B (LATCHED_PP[4]), .DATA_C (LATCHED_PP[5]), .SAVE (INT_SUM[2]), .CARRY (INT_CARRY[1]) );
smffb dla9 (.D(INT_SUM[2]), .clk(clk), .en_d2(en_d2), .Q(SUM[2]) );
smffb dla10 (.D(INT_CARRY[1]), .clk(clk), .en_d2(en_d2), .Q(CARRY[2]) );
smffa dla11 (.D(SUMMAND[6]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[6]) );
smffa dla12 (.D(SUMMAND[7]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[7]) );
smhalfadder dha1 (.DATA_A (LATCHED_PP[6]), .DATA_B (LATCHED_PP[7]), .SAVE (INT_SUM[3]), .CARRY (INT_CARRY[2]) );
smffb dla13 (.D(INT_SUM[3]), .clk(clk), .en_d2(en_d2), .Q(SUM[3]) );
smffb dla14 (.D(INT_CARRY[2]), .clk(clk), .en_d2(en_d2), .Q(CARRY[3]) );
smffa dla15 (.D(SUMMAND[8]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[8]) );
smffa dla16 (.D(SUMMAND[9]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[9]) );
smffa dla17 (.D(SUMMAND[10]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[10]) );
smfulladder dfa1 (.DATA_A (LATCHED_PP[8]), .DATA_B (LATCHED_PP[9]), .DATA_C (LATCHED_PP[10]), .SAVE (INT_SUM[4]), .CARRY (INT_CARRY[4]) );
smffa dla18 (.D(SUMMAND[11]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[11]) );
assign INT_SUM[5] = LATCHED_PP[11];
smhalfadder dha2 (.DATA_A (INT_SUM[4]), .DATA_B (INT_SUM[5]), .SAVE (INT_SUM[6]), .CARRY (INT_CARRY[3]) );
smffb dla19 (.D(INT_SUM[6]), .clk(clk), .en_d2(en_d2), .Q(SUM[4]) );
smffb dla20 (.D(INT_CARRY[3]), .clk(clk), .en_d2(en_d2), .Q(CARRY[4]) );
smffa dla21 (.D(SUMMAND[12]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[12]) );
smffa dla22 (.D(SUMMAND[13]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[13]) );
smffa dla23 (.D(SUMMAND[14]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[14]) );
smfulladder dfa2 (.DATA_A (LATCHED_PP[12]), .DATA_B (LATCHED_PP[13]), .DATA_C (LATCHED_PP[14]), .SAVE (INT_SUM[7]), .CARRY (INT_CARRY[6]) );
smhalfadder dha3 (.DATA_A (INT_SUM[7]), .DATA_B (INT_CARRY[4]), .SAVE (INT_SUM[8]), .CARRY (INT_CARRY[5]) );
smffb dla24 (.D(INT_SUM[8]), .clk(clk), .en_d2(en_d2), .Q(SUM[5]) );
smffb dla25 (.D(INT_CARRY[5]), .clk(clk), .en_d2(en_d2), .Q(CARRY[5]) );
smffa dla26 (.D(SUMMAND[15]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[15]) );
smffa dla27 (.D(SUMMAND[16]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[16]) );
smffa dla28 (.D(SUMMAND[17]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[17]) );
smfulladder dfa3 (.DATA_A (LATCHED_PP[15]), .DATA_B (LATCHED_PP[16]), .DATA_C (LATCHED_PP[17]), .SAVE (INT_SUM[9]), .CARRY (INT_CARRY[8]) );
smffa dla29 (.D(SUMMAND[18]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[18]) );
smffa dla30 (.D(SUMMAND[19]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[19]) );
smhalfadder dha4 (.DATA_A (LATCHED_PP[18]), .DATA_B (LATCHED_PP[19]), .SAVE (INT_SUM[10]), .CARRY (INT_CARRY[9]) );
smfulladder dfa4 (.DATA_A (INT_SUM[9]), .DATA_B (INT_SUM[10]), .DATA_C (INT_CARRY[6]), .SAVE (INT_SUM[11]), .CARRY (INT_CARRY[7]) );
smffb dla31 (.D(INT_SUM[11]), .clk(clk), .en_d2(en_d2), .Q(SUM[6]) );
smffb dla32 (.D(INT_CARRY[7]), .clk(clk), .en_d2(en_d2), .Q(CARRY[6]) );
smffa dla33 (.D(SUMMAND[20]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[20]) );
smffa dla34 (.D(SUMMAND[21]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[21]) );
smffa dla35 (.D(SUMMAND[22]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[22]) );
smfulladder dfa5 (.DATA_A (LATCHED_PP[20]), .DATA_B (LATCHED_PP[21]), .DATA_C (LATCHED_PP[22]), .SAVE (INT_SUM[12]), .CARRY (INT_CARRY[11]) );
smffa dla36 (.D(SUMMAND[23]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[23]) );
assign INT_SUM[13] = LATCHED_PP[23];
smfulladder dfa6 (.DATA_A (INT_SUM[12]), .DATA_B (INT_SUM[13]), .DATA_C (INT_CARRY[8]), .SAVE (INT_SUM[14]), .CARRY (INT_CARRY[12]) );
assign INT_SUM[15] = INT_CARRY[9];
smhalfadder dha5 (.DATA_A (INT_SUM[14]), .DATA_B (INT_SUM[15]), .SAVE (INT_SUM[16]), .CARRY (INT_CARRY[10]) );
smffb dla37 (.D(INT_SUM[16]), .clk(clk), .en_d2(en_d2), .Q(SUM[7]) );
smffb dla38 (.D(INT_CARRY[10]), .clk(clk), .en_d2(en_d2), .Q(CARRY[7]) );
smffa dla39 (.D(SUMMAND[24]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[24]) );
smffa dla40 (.D(SUMMAND[25]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[25]) );
smffa dla41 (.D(SUMMAND[26]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[26]) );
smfulladder dfa7 (.DATA_A (LATCHED_PP[24]), .DATA_B (LATCHED_PP[25]), .DATA_C (LATCHED_PP[26]), .SAVE (INT_SUM[17]), .CARRY (INT_CARRY[14]) );
smffa dla42 (.D(SUMMAND[27]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[27]) );
smffa dla43 (.D(SUMMAND[28]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[28]) );
smffa dla44 (.D(SUMMAND[29]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[29]) );
smfulladder dfa8 (.DATA_A (LATCHED_PP[27]), .DATA_B (LATCHED_PP[28]), .DATA_C (LATCHED_PP[29]), .SAVE (INT_SUM[18]), .CARRY (INT_CARRY[15]) );
smfulladder dfa9 (.DATA_A (INT_SUM[17]), .DATA_B (INT_SUM[18]), .DATA_C (INT_CARRY[11]), .SAVE (INT_SUM[19]), .CARRY (INT_CARRY[16]) );
smhalfadder dha6 (.DATA_A (INT_SUM[19]), .DATA_B (INT_CARRY[12]), .SAVE (INT_SUM[20]), .CARRY (INT_CARRY[13]) );
smffb dla45 (.D(INT_SUM[20]), .clk(clk), .en_d2(en_d2), .Q(SUM[8]) );
smffb dla46 (.D(INT_CARRY[13]), .clk(clk), .en_d2(en_d2), .Q(CARRY[8]) );
smffa dla47 (.D(SUMMAND[30]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[30]) );
smffa dla48 (.D(SUMMAND[31]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[31]) );
smffa dla49 (.D(SUMMAND[32]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[32]) );
smfulladder dfa10 (.DATA_A (LATCHED_PP[30]), .DATA_B (LATCHED_PP[31]), .DATA_C (LATCHED_PP[32]), .SAVE (INT_SUM[21]), .CARRY (INT_CARRY[18]) );
smffa dla50 (.D(SUMMAND[33]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[33]) );
smffa dla51 (.D(SUMMAND[34]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[34]) );
smhalfadder dha7 (.DATA_A (LATCHED_PP[33]), .DATA_B (LATCHED_PP[34]), .SAVE (INT_SUM[22]), .CARRY (INT_CARRY[19]) );
smfulladder dfa11 (.DATA_A (INT_SUM[21]), .DATA_B (INT_SUM[22]), .DATA_C (INT_CARRY[14]), .SAVE (INT_SUM[23]), .CARRY (INT_CARRY[20]) );
assign INT_SUM[24] = INT_CARRY[15];
smfulladder dfa12 (.DATA_A (INT_SUM[23]), .DATA_B (INT_SUM[24]), .DATA_C (INT_CARRY[16]), .SAVE (INT_SUM[25]), .CARRY (INT_CARRY[17]) );
smffb dla52 (.D(INT_SUM[25]), .clk(clk), .en_d2(en_d2), .Q(SUM[9]) );
smffb dla53 (.D(INT_CARRY[17]), .clk(clk), .en_d2(en_d2), .Q(CARRY[9]) );
smffa dla54 (.D(SUMMAND[35]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[35]) );
smffa dla55 (.D(SUMMAND[36]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[36]) );
smffa dla56 (.D(SUMMAND[37]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[37]) );
smfulladder dfa13 (.DATA_A (LATCHED_PP[35]), .DATA_B (LATCHED_PP[36]), .DATA_C (LATCHED_PP[37]), .SAVE (INT_SUM[26]), .CARRY (INT_CARRY[22]) );
smffa dla57 (.D(SUMMAND[38]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[38]) );
smffa dla58 (.D(SUMMAND[39]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[39]) );
smffa dla59 (.D(SUMMAND[40]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[40]) );
smfulladder dfa14 (.DATA_A (LATCHED_PP[38]), .DATA_B (LATCHED_PP[39]), .DATA_C (LATCHED_PP[40]), .SAVE (INT_SUM[27]), .CARRY (INT_CARRY[23]) );
smffa dla60 (.D(SUMMAND[41]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[41]) );
assign INT_SUM[28] = LATCHED_PP[41];
smfulladder dfa15 (.DATA_A (INT_SUM[26]), .DATA_B (INT_SUM[27]), .DATA_C (INT_SUM[28]), .SAVE (INT_SUM[29]), .CARRY (INT_CARRY[24]) );
smhalfadder dha8 (.DATA_A (INT_CARRY[18]), .DATA_B (INT_CARRY[19]), .SAVE (INT_SUM[30]), .CARRY (INT_CARRY[25]) );
smfulladder dfa16 (.DATA_A (INT_SUM[29]), .DATA_B (INT_SUM[30]), .DATA_C (INT_CARRY[20]), .SAVE (INT_SUM[31]), .CARRY (INT_CARRY[21]) );
smffb dla61 (.D(INT_SUM[31]), .clk(clk), .en_d2(en_d2), .Q(SUM[10]) );
smffb dla62 (.D(INT_CARRY[21]), .clk(clk), .en_d2(en_d2), .Q(CARRY[10]) );
smffa dla63 (.D(SUMMAND[42]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[42]) );
smffa dla64 (.D(SUMMAND[43]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[43]) );
smffa dla65 (.D(SUMMAND[44]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[44]) );
smfulladder dfa17 (.DATA_A (LATCHED_PP[42]), .DATA_B (LATCHED_PP[43]), .DATA_C (LATCHED_PP[44]), .SAVE (INT_SUM[32]), .CARRY (INT_CARRY[27]) );
smffa dla66 (.D(SUMMAND[45]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[45]) );
smffa dla67 (.D(SUMMAND[46]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[46]) );
smffa dla68 (.D(SUMMAND[47]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[47]) );
smfulladder dfa18 (.DATA_A (LATCHED_PP[45]), .DATA_B (LATCHED_PP[46]), .DATA_C (LATCHED_PP[47]), .SAVE (INT_SUM[33]), .CARRY (INT_CARRY[28]) );
smfulladder dfa19 (.DATA_A (INT_SUM[32]), .DATA_B (INT_SUM[33]), .DATA_C (INT_CARRY[22]), .SAVE (INT_SUM[34]), .CARRY (INT_CARRY[29]) );
assign INT_SUM[35] = INT_CARRY[23];
smfulladder dfa20 (.DATA_A (INT_SUM[34]), .DATA_B (INT_SUM[35]), .DATA_C (INT_CARRY[24]), .SAVE (INT_SUM[36]), .CARRY (INT_CARRY[30]) );
assign INT_SUM[37] = INT_CARRY[25];
smhalfadder dha9 (.DATA_A (INT_SUM[36]), .DATA_B (INT_SUM[37]), .SAVE (INT_SUM[38]), .CARRY (INT_CARRY[26]) );
smffb dla69 (.D(INT_SUM[38]), .clk(clk), .en_d2(en_d2), .Q(SUM[11]) );
smffb dla70 (.D(INT_CARRY[26]), .clk(clk), .en_d2(en_d2), .Q(CARRY[11]) );
smffa dla71 (.D(SUMMAND[48]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[48]) );
smffa dla72 (.D(SUMMAND[49]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[49]) );
smffa dla73 (.D(SUMMAND[50]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[50]) );
smfulladder dfa21 (.DATA_A (LATCHED_PP[48]), .DATA_B (LATCHED_PP[49]), .DATA_C (LATCHED_PP[50]), .SAVE (INT_SUM[39]), .CARRY (INT_CARRY[32]) );
smffa dla74 (.D(SUMMAND[51]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[51]) );
smffa dla75 (.D(SUMMAND[52]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[52]) );
smffa dla76 (.D(SUMMAND[53]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[53]) );
smfulladder dfa22 (.DATA_A (LATCHED_PP[51]), .DATA_B (LATCHED_PP[52]), .DATA_C (LATCHED_PP[53]), .SAVE (INT_SUM[40]), .CARRY (INT_CARRY[33]) );
smffa dla77 (.D(SUMMAND[54]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[54]) );
assign INT_SUM[41] = LATCHED_PP[54];
smffa dla78 (.D(SUMMAND[55]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[55]) );
assign INT_SUM[42] = LATCHED_PP[55];
smfulladder dfa23 (.DATA_A (INT_SUM[39]), .DATA_B (INT_SUM[40]), .DATA_C (INT_SUM[41]), .SAVE (INT_SUM[43]), .CARRY (INT_CARRY[34]) );
smfulladder dfa24 (.DATA_A (INT_SUM[42]), .DATA_B (INT_CARRY[27]), .DATA_C (INT_CARRY[28]), .SAVE (INT_SUM[44]), .CARRY (INT_CARRY[35]) );
smfulladder dfa25 (.DATA_A (INT_SUM[43]), .DATA_B (INT_SUM[44]), .DATA_C (INT_CARRY[29]), .SAVE (INT_SUM[45]), .CARRY (INT_CARRY[36]) );
smhalfadder dha10 (.DATA_A (INT_SUM[45]), .DATA_B (INT_CARRY[30]), .SAVE (INT_SUM[46]), .CARRY (INT_CARRY[31]) );
smffb dla79 (.D(INT_SUM[46]), .clk(clk), .en_d2(en_d2), .Q(SUM[12]) );
smffb dla80 (.D(INT_CARRY[31]), .clk(clk), .en_d2(en_d2), .Q(CARRY[12]) );
smffa dla81 (.D(SUMMAND[56]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[56]) );
smffa dla82 (.D(SUMMAND[57]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[57]) );
smffa dla83 (.D(SUMMAND[58]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[58]) );
smfulladder dfa26 (.DATA_A (LATCHED_PP[56]), .DATA_B (LATCHED_PP[57]), .DATA_C (LATCHED_PP[58]), .SAVE (INT_SUM[47]), .CARRY (INT_CARRY[38]) );
smffa dla84 (.D(SUMMAND[59]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[59]) );
smffa dla85 (.D(SUMMAND[60]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[60]) );
smffa dla86 (.D(SUMMAND[61]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[61]) );
smfulladder dfa27 (.DATA_A (LATCHED_PP[59]), .DATA_B (LATCHED_PP[60]), .DATA_C (LATCHED_PP[61]), .SAVE (INT_SUM[48]), .CARRY (INT_CARRY[39]) );
smffa dla87 (.D(SUMMAND[62]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[62]) );
assign INT_SUM[49] = LATCHED_PP[62];
smfulladder dfa28 (.DATA_A (INT_SUM[47]), .DATA_B (INT_SUM[48]), .DATA_C (INT_SUM[49]), .SAVE (INT_SUM[50]), .CARRY (INT_CARRY[40]) );
smhalfadder dha11 (.DATA_A (INT_CARRY[32]), .DATA_B (INT_CARRY[33]), .SAVE (INT_SUM[51]), .CARRY (INT_CARRY[41]) );
smfulladder dfa29 (.DATA_A (INT_SUM[50]), .DATA_B (INT_SUM[51]), .DATA_C (INT_CARRY[34]), .SAVE (INT_SUM[52]), .CARRY (INT_CARRY[42]) );
assign INT_SUM[53] = INT_CARRY[35];
smfulladder dfa30 (.DATA_A (INT_SUM[52]), .DATA_B (INT_SUM[53]), .DATA_C (INT_CARRY[36]), .SAVE (INT_SUM[54]), .CARRY (INT_CARRY[37]) );
smffb dla88 (.D(INT_SUM[54]), .clk(clk), .en_d2(en_d2), .Q(SUM[13]) );
smffb dla89 (.D(INT_CARRY[37]), .clk(clk), .en_d2(en_d2), .Q(CARRY[13]) );
smffa dla90 (.D(SUMMAND[63]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[63]) );
smffa dla91 (.D(SUMMAND[64]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[64]) );
smffa dla92 (.D(SUMMAND[65]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[65]) );
smfulladder dfa31 (.DATA_A (LATCHED_PP[63]), .DATA_B (LATCHED_PP[64]), .DATA_C (LATCHED_PP[65]), .SAVE (INT_SUM[55]), .CARRY (INT_CARRY[44]) );
smffa dla93 (.D(SUMMAND[66]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[66]) );
smffa dla94 (.D(SUMMAND[67]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[67]) );
smffa dla95 (.D(SUMMAND[68]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[68]) );
smfulladder dfa32 (.DATA_A (LATCHED_PP[66]), .DATA_B (LATCHED_PP[67]), .DATA_C (LATCHED_PP[68]), .SAVE (INT_SUM[56]), .CARRY (INT_CARRY[45]) );
smffa dla96 (.D(SUMMAND[69]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[69]) );
smffa dla97 (.D(SUMMAND[70]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[70]) );
smffa dla98 (.D(SUMMAND[71]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[71]) );
smfulladder dfa33 (.DATA_A (LATCHED_PP[69]), .DATA_B (LATCHED_PP[70]), .DATA_C (LATCHED_PP[71]), .SAVE (INT_SUM[57]), .CARRY (INT_CARRY[46]) );
smfulladder dfa34 (.DATA_A (INT_SUM[55]), .DATA_B (INT_SUM[56]), .DATA_C (INT_SUM[57]), .SAVE (INT_SUM[58]), .CARRY (INT_CARRY[47]) );
smhalfadder dha12 (.DATA_A (INT_CARRY[38]), .DATA_B (INT_CARRY[39]), .SAVE (INT_SUM[59]), .CARRY (INT_CARRY[48]) );
smfulladder dfa35 (.DATA_A (INT_SUM[58]), .DATA_B (INT_SUM[59]), .DATA_C (INT_CARRY[40]), .SAVE (INT_SUM[60]), .CARRY (INT_CARRY[49]) );
assign INT_SUM[61] = INT_CARRY[41];
smfulladder dfa36 (.DATA_A (INT_SUM[60]), .DATA_B (INT_SUM[61]), .DATA_C (INT_CARRY[42]), .SAVE (INT_SUM[62]), .CARRY (INT_CARRY[43]) );
smffb dla99 (.D(INT_SUM[62]), .clk(clk), .en_d2(en_d2), .Q(SUM[14]) );
smffb dla100 (.D(INT_CARRY[43]), .clk(clk), .en_d2(en_d2), .Q(CARRY[14]) );
smffa dla101 (.D(SUMMAND[72]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[72]) );
smffa dla102 (.D(SUMMAND[73]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[73]) );
smffa dla103 (.D(SUMMAND[74]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[74]) );
smfulladder dfa37 (.DATA_A (LATCHED_PP[72]), .DATA_B (LATCHED_PP[73]), .DATA_C (LATCHED_PP[74]), .SAVE (INT_SUM[63]), .CARRY (INT_CARRY[51]) );
smffa dla104 (.D(SUMMAND[75]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[75]) );
smffa dla105 (.D(SUMMAND[76]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[76]) );
smffa dla106 (.D(SUMMAND[77]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[77]) );
smfulladder dfa38 (.DATA_A (LATCHED_PP[75]), .DATA_B (LATCHED_PP[76]), .DATA_C (LATCHED_PP[77]), .SAVE (INT_SUM[64]), .CARRY (INT_CARRY[52]) );
smffa dla107 (.D(SUMMAND[78]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[78]) );
smffa dla108 (.D(SUMMAND[79]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[79]) );
smhalfadder dha13 (.DATA_A (LATCHED_PP[78]), .DATA_B (LATCHED_PP[79]), .SAVE (INT_SUM[65]), .CARRY (INT_CARRY[53]) );
smfulladder dfa39 (.DATA_A (INT_SUM[63]), .DATA_B (INT_SUM[64]), .DATA_C (INT_SUM[65]), .SAVE (INT_SUM[66]), .CARRY (INT_CARRY[54]) );
smfulladder dfa40 (.DATA_A (INT_CARRY[44]), .DATA_B (INT_CARRY[45]), .DATA_C (INT_CARRY[46]), .SAVE (INT_SUM[67]), .CARRY (INT_CARRY[55]) );
smfulladder dfa41 (.DATA_A (INT_SUM[66]), .DATA_B (INT_SUM[67]), .DATA_C (INT_CARRY[47]), .SAVE (INT_SUM[68]), .CARRY (INT_CARRY[56]) );
assign INT_SUM[69] = INT_CARRY[48];
smfulladder dfa42 (.DATA_A (INT_SUM[68]), .DATA_B (INT_SUM[69]), .DATA_C (INT_CARRY[49]), .SAVE (INT_SUM[70]), .CARRY (INT_CARRY[50]) );
smffb dla109 (.D(INT_SUM[70]), .clk(clk), .en_d2(en_d2), .Q(SUM[15]) );
smffb dla110 (.D(INT_CARRY[50]), .clk(clk), .en_d2(en_d2), .Q(CARRY[15]) );
smffa dla111 (.D(SUMMAND[80]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[80]) );
smffa dla112 (.D(SUMMAND[81]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[81]) );
smffa dla113 (.D(SUMMAND[82]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[82]) );
smfulladder dfa43 (.DATA_A (LATCHED_PP[80]), .DATA_B (LATCHED_PP[81]), .DATA_C (LATCHED_PP[82]), .SAVE (INT_SUM[71]), .CARRY (INT_CARRY[58]) );
smffa dla114 (.D(SUMMAND[83]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[83]) );
smffa dla115 (.D(SUMMAND[84]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[84]) );
smffa dla116 (.D(SUMMAND[85]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[85]) );
smfulladder dfa44 (.DATA_A (LATCHED_PP[83]), .DATA_B (LATCHED_PP[84]), .DATA_C (LATCHED_PP[85]), .SAVE (INT_SUM[72]), .CARRY (INT_CARRY[59]) );
smffa dla117 (.D(SUMMAND[86]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[86]) );
smffa dla118 (.D(SUMMAND[87]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[87]) );
smffa dla119 (.D(SUMMAND[88]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[88]) );
smfulladder dfa45 (.DATA_A (LATCHED_PP[86]), .DATA_B (LATCHED_PP[87]), .DATA_C (LATCHED_PP[88]), .SAVE (INT_SUM[73]), .CARRY (INT_CARRY[60]) );
smffa dla120 (.D(SUMMAND[89]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[89]) );
assign INT_SUM[74] = LATCHED_PP[89];
smfulladder dfa46 (.DATA_A (INT_SUM[71]), .DATA_B (INT_SUM[72]), .DATA_C (INT_SUM[73]), .SAVE (INT_SUM[75]), .CARRY (INT_CARRY[61]) );
smfulladder dfa47 (.DATA_A (INT_SUM[74]), .DATA_B (INT_CARRY[51]), .DATA_C (INT_CARRY[52]), .SAVE (INT_SUM[76]), .CARRY (INT_CARRY[62]) );
assign INT_SUM[77] = INT_CARRY[53];
smfulladder dfa48 (.DATA_A (INT_SUM[75]), .DATA_B (INT_SUM[76]), .DATA_C (INT_SUM[77]), .SAVE (INT_SUM[78]), .CARRY (INT_CARRY[63]) );
smhalfadder dha14 (.DATA_A (INT_CARRY[54]), .DATA_B (INT_CARRY[55]), .SAVE (INT_SUM[79]), .CARRY (INT_CARRY[64]) );
smfulladder dfa49 (.DATA_A (INT_SUM[78]), .DATA_B (INT_SUM[79]), .DATA_C (INT_CARRY[56]), .SAVE (INT_SUM[80]), .CARRY (INT_CARRY[57]) );
smffb dla121 (.D(INT_SUM[80]), .clk(clk), .en_d2(en_d2), .Q(SUM[16]) );
smffb dla122 (.D(INT_CARRY[57]), .clk(clk), .en_d2(en_d2), .Q(CARRY[16]) );
smffa dla123 (.D(SUMMAND[90]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[90]) );
smffa dla124 (.D(SUMMAND[91]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[91]) );
smffa dla125 (.D(SUMMAND[92]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[92]) );
smfulladder dfa50 (.DATA_A (LATCHED_PP[90]), .DATA_B (LATCHED_PP[91]), .DATA_C (LATCHED_PP[92]), .SAVE (INT_SUM[81]), .CARRY (INT_CARRY[66]) );
smffa dla126 (.D(SUMMAND[93]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[93]) );
smffa dla127 (.D(SUMMAND[94]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[94]) );
smffa dla128 (.D(SUMMAND[95]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[95]) );
smfulladder dfa51 (.DATA_A (LATCHED_PP[93]), .DATA_B (LATCHED_PP[94]), .DATA_C (LATCHED_PP[95]), .SAVE (INT_SUM[82]), .CARRY (INT_CARRY[67]) );
smffa dla129 (.D(SUMMAND[96]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[96]) );
smffa dla130 (.D(SUMMAND[97]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[97]) );
smffa dla131 (.D(SUMMAND[98]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[98]) );
smfulladder dfa52 (.DATA_A (LATCHED_PP[96]), .DATA_B (LATCHED_PP[97]), .DATA_C (LATCHED_PP[98]), .SAVE (INT_SUM[83]), .CARRY (INT_CARRY[68]) );
smfulladder dfa53 (.DATA_A (INT_SUM[81]), .DATA_B (INT_SUM[82]), .DATA_C (INT_SUM[83]), .SAVE (INT_SUM[84]), .CARRY (INT_CARRY[69]) );
smfulladder dfa54 (.DATA_A (INT_CARRY[58]), .DATA_B (INT_CARRY[59]), .DATA_C (INT_CARRY[60]), .SAVE (INT_SUM[85]), .CARRY (INT_CARRY[70]) );
smfulladder dfa55 (.DATA_A (INT_SUM[84]), .DATA_B (INT_SUM[85]), .DATA_C (INT_CARRY[61]), .SAVE (INT_SUM[86]), .CARRY (INT_CARRY[71]) );
assign INT_SUM[87] = INT_CARRY[62];
smfulladder dfa56 (.DATA_A (INT_SUM[86]), .DATA_B (INT_SUM[87]), .DATA_C (INT_CARRY[63]), .SAVE (INT_SUM[88]), .CARRY (INT_CARRY[72]) );
assign INT_SUM[89] = INT_CARRY[64];
smhalfadder dha15 (.DATA_A (INT_SUM[88]), .DATA_B (INT_SUM[89]), .SAVE (INT_SUM[90]), .CARRY (INT_CARRY[65]) );
smffb dla132 (.D(INT_SUM[90]), .clk(clk), .en_d2(en_d2), .Q(SUM[17]) );
smffb dla133 (.D(INT_CARRY[65]), .clk(clk), .en_d2(en_d2), .Q(CARRY[17]) );
smffa dla134 (.D(SUMMAND[99]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[99]) );
smffa dla135 (.D(SUMMAND[100]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[100]) );
smffa dla136 (.D(SUMMAND[101]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[101]) );
smfulladder dfa57 (.DATA_A (LATCHED_PP[99]), .DATA_B (LATCHED_PP[100]), .DATA_C (LATCHED_PP[101]), .SAVE (INT_SUM[91]), .CARRY (INT_CARRY[74]) );
smffa dla137 (.D(SUMMAND[102]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[102]) );
smffa dla138 (.D(SUMMAND[103]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[103]) );
smffa dla139 (.D(SUMMAND[104]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[104]) );
smfulladder dfa58 (.DATA_A (LATCHED_PP[102]), .DATA_B (LATCHED_PP[103]), .DATA_C (LATCHED_PP[104]), .SAVE (INT_SUM[92]), .CARRY (INT_CARRY[75]) );
smffa dla140 (.D(SUMMAND[105]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[105]) );
smffa dla141 (.D(SUMMAND[106]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[106]) );
smffa dla142 (.D(SUMMAND[107]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[107]) );
smfulladder dfa59 (.DATA_A (LATCHED_PP[105]), .DATA_B (LATCHED_PP[106]), .DATA_C (LATCHED_PP[107]), .SAVE (INT_SUM[93]), .CARRY (INT_CARRY[76]) );
smffa dla143 (.D(SUMMAND[108]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[108]) );
assign INT_SUM[94] = LATCHED_PP[108];
smffa dla144 (.D(SUMMAND[109]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[109]) );
assign INT_SUM[95] = LATCHED_PP[109];
smfulladder dfa60 (.DATA_A (INT_SUM[91]), .DATA_B (INT_SUM[92]), .DATA_C (INT_SUM[93]), .SAVE (INT_SUM[96]), .CARRY (INT_CARRY[77]) );
smfulladder dfa61 (.DATA_A (INT_SUM[94]), .DATA_B (INT_SUM[95]), .DATA_C (INT_CARRY[66]), .SAVE (INT_SUM[97]), .CARRY (INT_CARRY[78]) );
assign INT_SUM[98] = INT_CARRY[67];
assign INT_SUM[99] = INT_CARRY[68];
smfulladder dfa62 (.DATA_A (INT_SUM[96]), .DATA_B (INT_SUM[97]), .DATA_C (INT_SUM[98]), .SAVE (INT_SUM[100]), .CARRY (INT_CARRY[79]) );
smfulladder dfa63 (.DATA_A (INT_SUM[99]), .DATA_B (INT_CARRY[69]), .DATA_C (INT_CARRY[70]), .SAVE (INT_SUM[101]), .CARRY (INT_CARRY[80]) );
smfulladder dfa64 (.DATA_A (INT_SUM[100]), .DATA_B (INT_SUM[101]), .DATA_C (INT_CARRY[71]), .SAVE (INT_SUM[102]), .CARRY (INT_CARRY[81]) );
smhalfadder dha16 (.DATA_A (INT_SUM[102]), .DATA_B (INT_CARRY[72]), .SAVE (INT_SUM[103]), .CARRY (INT_CARRY[73]) );
smffb dla145 (.D(INT_SUM[103]), .clk(clk), .en_d2(en_d2), .Q(SUM[18]) );
smffb dla146 (.D(INT_CARRY[73]), .clk(clk), .en_d2(en_d2), .Q(CARRY[18]) );
smffa dla147 (.D(SUMMAND[110]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[110]) );
smffa dla148 (.D(SUMMAND[111]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[111]) );
smffa dla149 (.D(SUMMAND[112]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[112]) );
smfulladder dfa65 (.DATA_A (LATCHED_PP[110]), .DATA_B (LATCHED_PP[111]), .DATA_C (LATCHED_PP[112]), .SAVE (INT_SUM[104]), .CARRY (INT_CARRY[83]) );
smffa dla150 (.D(SUMMAND[113]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[113]) );
smffa dla151 (.D(SUMMAND[114]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[114]) );
smffa dla152 (.D(SUMMAND[115]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[115]) );
smfulladder dfa66 (.DATA_A (LATCHED_PP[113]), .DATA_B (LATCHED_PP[114]), .DATA_C (LATCHED_PP[115]), .SAVE (INT_SUM[105]), .CARRY (INT_CARRY[84]) );
smffa dla153 (.D(SUMMAND[116]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[116]) );
smffa dla154 (.D(SUMMAND[117]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[117]) );
smffa dla155 (.D(SUMMAND[118]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[118]) );
smfulladder dfa67 (.DATA_A (LATCHED_PP[116]), .DATA_B (LATCHED_PP[117]), .DATA_C (LATCHED_PP[118]), .SAVE (INT_SUM[106]), .CARRY (INT_CARRY[85]) );
smffa dla156 (.D(SUMMAND[119]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[119]) );
assign INT_SUM[107] = LATCHED_PP[119];
smfulladder dfa68 (.DATA_A (INT_SUM[104]), .DATA_B (INT_SUM[105]), .DATA_C (INT_SUM[106]), .SAVE (INT_SUM[108]), .CARRY (INT_CARRY[86]) );
smfulladder dfa69 (.DATA_A (INT_SUM[107]), .DATA_B (INT_CARRY[74]), .DATA_C (INT_CARRY[75]), .SAVE (INT_SUM[109]), .CARRY (INT_CARRY[87]) );
assign INT_SUM[110] = INT_CARRY[76];
smfulladder dfa70 (.DATA_A (INT_SUM[108]), .DATA_B (INT_SUM[109]), .DATA_C (INT_SUM[110]), .SAVE (INT_SUM[111]), .CARRY (INT_CARRY[88]) );
smhalfadder dha17 (.DATA_A (INT_CARRY[77]), .DATA_B (INT_CARRY[78]), .SAVE (INT_SUM[112]), .CARRY (INT_CARRY[89]) );
smfulladder dfa71 (.DATA_A (INT_SUM[111]), .DATA_B (INT_SUM[112]), .DATA_C (INT_CARRY[79]), .SAVE (INT_SUM[113]), .CARRY (INT_CARRY[90]) );
assign INT_SUM[114] = INT_CARRY[80];
smfulladder dfa72 (.DATA_A (INT_SUM[113]), .DATA_B (INT_SUM[114]), .DATA_C (INT_CARRY[81]), .SAVE (INT_SUM[115]), .CARRY (INT_CARRY[82]) );
smffb dla157 (.D(INT_SUM[115]), .clk(clk), .en_d2(en_d2), .Q(SUM[19]) );
smffb dla158 (.D(INT_CARRY[82]), .clk(clk), .en_d2(en_d2), .Q(CARRY[19]) );
smffa dla159 (.D(SUMMAND[120]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[120]) );
smffa dla160 (.D(SUMMAND[121]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[121]) );
smffa dla161 (.D(SUMMAND[122]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[122]) );
smfulladder dfa73 (.DATA_A (LATCHED_PP[120]), .DATA_B (LATCHED_PP[121]), .DATA_C (LATCHED_PP[122]), .SAVE (INT_SUM[116]), .CARRY (INT_CARRY[92]) );
smffa dla162 (.D(SUMMAND[123]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[123]) );
smffa dla163 (.D(SUMMAND[124]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[124]) );
smffa dla164 (.D(SUMMAND[125]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[125]) );
smfulladder dfa74 (.DATA_A (LATCHED_PP[123]), .DATA_B (LATCHED_PP[124]), .DATA_C (LATCHED_PP[125]), .SAVE (INT_SUM[117]), .CARRY (INT_CARRY[93]) );
smffa dla165 (.D(SUMMAND[126]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[126]) );
smffa dla166 (.D(SUMMAND[127]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[127]) );
smffa dla167 (.D(SUMMAND[128]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[128]) );
smfulladder dfa75 (.DATA_A (LATCHED_PP[126]), .DATA_B (LATCHED_PP[127]), .DATA_C (LATCHED_PP[128]), .SAVE (INT_SUM[118]), .CARRY (INT_CARRY[94]) );
smffa dla168 (.D(SUMMAND[129]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[129]) );
smffa dla169 (.D(SUMMAND[130]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[130]) );
smffa dla170 (.D(SUMMAND[131]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[131]) );
smfulladder dfa76 (.DATA_A (LATCHED_PP[129]), .DATA_B (LATCHED_PP[130]), .DATA_C (LATCHED_PP[131]), .SAVE (INT_SUM[119]), .CARRY (INT_CARRY[95]) );
smfulladder dfa77 (.DATA_A (INT_SUM[116]), .DATA_B (INT_SUM[117]), .DATA_C (INT_SUM[118]), .SAVE (INT_SUM[120]), .CARRY (INT_CARRY[96]) );
smfulladder dfa78 (.DATA_A (INT_SUM[119]), .DATA_B (INT_CARRY[83]), .DATA_C (INT_CARRY[84]), .SAVE (INT_SUM[121]), .CARRY (INT_CARRY[97]) );
assign INT_SUM[122] = INT_CARRY[85];
smfulladder dfa79 (.DATA_A (INT_SUM[120]), .DATA_B (INT_SUM[121]), .DATA_C (INT_SUM[122]), .SAVE (INT_SUM[123]), .CARRY (INT_CARRY[98]) );
smhalfadder dha18 (.DATA_A (INT_CARRY[86]), .DATA_B (INT_CARRY[87]), .SAVE (INT_SUM[124]), .CARRY (INT_CARRY[99]) );
smfulladder dfa80 (.DATA_A (INT_SUM[123]), .DATA_B (INT_SUM[124]), .DATA_C (INT_CARRY[88]), .SAVE (INT_SUM[125]), .CARRY (INT_CARRY[100]) );
assign INT_SUM[126] = INT_CARRY[89];
smfulladder dfa81 (.DATA_A (INT_SUM[125]), .DATA_B (INT_SUM[126]), .DATA_C (INT_CARRY[90]), .SAVE (INT_SUM[127]), .CARRY (INT_CARRY[91]) );
smffb dla171 (.D(INT_SUM[127]), .clk(clk), .en_d2(en_d2), .Q(SUM[20]) );
smffb dla172 (.D(INT_CARRY[91]), .clk(clk), .en_d2(en_d2), .Q(CARRY[20]) );
smffa dla173 (.D(SUMMAND[132]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[132]) );
smffa dla174 (.D(SUMMAND[133]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[133]) );
smffa dla175 (.D(SUMMAND[134]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[134]) );
smfulladder dfa82 (.DATA_A (LATCHED_PP[132]), .DATA_B (LATCHED_PP[133]), .DATA_C (LATCHED_PP[134]), .SAVE (INT_SUM[128]), .CARRY (INT_CARRY[102]) );
smffa dla176 (.D(SUMMAND[135]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[135]) );
smffa dla177 (.D(SUMMAND[136]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[136]) );
smffa dla178 (.D(SUMMAND[137]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[137]) );
smfulladder dfa83 (.DATA_A (LATCHED_PP[135]), .DATA_B (LATCHED_PP[136]), .DATA_C (LATCHED_PP[137]), .SAVE (INT_SUM[129]), .CARRY (INT_CARRY[103]) );
smffa dla179 (.D(SUMMAND[138]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[138]) );
smffa dla180 (.D(SUMMAND[139]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[139]) );
smffa dla181 (.D(SUMMAND[140]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[140]) );
smfulladder dfa84 (.DATA_A (LATCHED_PP[138]), .DATA_B (LATCHED_PP[139]), .DATA_C (LATCHED_PP[140]), .SAVE (INT_SUM[130]), .CARRY (INT_CARRY[104]) );
smffa dla182 (.D(SUMMAND[141]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[141]) );
assign INT_SUM[131] = LATCHED_PP[141];
smffa dla183 (.D(SUMMAND[142]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[142]) );
assign INT_SUM[132] = LATCHED_PP[142];
smfulladder dfa85 (.DATA_A (INT_SUM[128]), .DATA_B (INT_SUM[129]), .DATA_C (INT_SUM[130]), .SAVE (INT_SUM[133]), .CARRY (INT_CARRY[105]) );
smfulladder dfa86 (.DATA_A (INT_SUM[131]), .DATA_B (INT_SUM[132]), .DATA_C (INT_CARRY[92]), .SAVE (INT_SUM[134]), .CARRY (INT_CARRY[106]) );
smfulladder dfa87 (.DATA_A (INT_CARRY[93]), .DATA_B (INT_CARRY[94]), .DATA_C (INT_CARRY[95]), .SAVE (INT_SUM[135]), .CARRY (INT_CARRY[107]) );
smfulladder dfa88 (.DATA_A (INT_SUM[133]), .DATA_B (INT_SUM[134]), .DATA_C (INT_SUM[135]), .SAVE (INT_SUM[136]), .CARRY (INT_CARRY[108]) );
smhalfadder dha19 (.DATA_A (INT_CARRY[96]), .DATA_B (INT_CARRY[97]), .SAVE (INT_SUM[137]), .CARRY (INT_CARRY[109]) );
smfulladder dfa89 (.DATA_A (INT_SUM[136]), .DATA_B (INT_SUM[137]), .DATA_C (INT_CARRY[98]), .SAVE (INT_SUM[138]), .CARRY (INT_CARRY[110]) );
assign INT_SUM[139] = INT_CARRY[99];
smfulladder dfa90 (.DATA_A (INT_SUM[138]), .DATA_B (INT_SUM[139]), .DATA_C (INT_CARRY[100]), .SAVE (INT_SUM[140]), .CARRY (INT_CARRY[101]) );
smffb dla184 (.D(INT_SUM[140]), .clk(clk), .en_d2(en_d2), .Q(SUM[21]) );
smffb dla185 (.D(INT_CARRY[101]), .clk(clk), .en_d2(en_d2), .Q(CARRY[21]) );
smffa dla186 (.D(SUMMAND[143]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[143]) );
smffa dla187 (.D(SUMMAND[144]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[144]) );
smffa dla188 (.D(SUMMAND[145]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[145]) );
smfulladder dfa91 (.DATA_A (LATCHED_PP[143]), .DATA_B (LATCHED_PP[144]), .DATA_C (LATCHED_PP[145]), .SAVE (INT_SUM[141]), .CARRY (INT_CARRY[112]) );
smffa dla189 (.D(SUMMAND[146]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[146]) );
smffa dla190 (.D(SUMMAND[147]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[147]) );
smffa dla191 (.D(SUMMAND[148]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[148]) );
smfulladder dfa92 (.DATA_A (LATCHED_PP[146]), .DATA_B (LATCHED_PP[147]), .DATA_C (LATCHED_PP[148]), .SAVE (INT_SUM[142]), .CARRY (INT_CARRY[113]) );
smffa dla192 (.D(SUMMAND[149]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[149]) );
smffa dla193 (.D(SUMMAND[150]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[150]) );
smffa dla194 (.D(SUMMAND[151]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[151]) );
smfulladder dfa93 (.DATA_A (LATCHED_PP[149]), .DATA_B (LATCHED_PP[150]), .DATA_C (LATCHED_PP[151]), .SAVE (INT_SUM[143]), .CARRY (INT_CARRY[114]) );
smffa dla195 (.D(SUMMAND[152]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[152]) );
smffa dla196 (.D(SUMMAND[153]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[153]) );
smffa dla197 (.D(SUMMAND[154]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[154]) );
smfulladder dfa94 (.DATA_A (LATCHED_PP[152]), .DATA_B (LATCHED_PP[153]), .DATA_C (LATCHED_PP[154]), .SAVE (INT_SUM[144]), .CARRY (INT_CARRY[115]) );
smffa dla198 (.D(SUMMAND[155]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[155]) );
assign INT_SUM[145] = LATCHED_PP[155];
smfulladder dfa95 (.DATA_A (INT_SUM[141]), .DATA_B (INT_SUM[142]), .DATA_C (INT_SUM[143]), .SAVE (INT_SUM[146]), .CARRY (INT_CARRY[116]) );
smfulladder dfa96 (.DATA_A (INT_SUM[144]), .DATA_B (INT_SUM[145]), .DATA_C (INT_CARRY[102]), .SAVE (INT_SUM[147]), .CARRY (INT_CARRY[117]) );
smhalfadder dha20 (.DATA_A (INT_CARRY[103]), .DATA_B (INT_CARRY[104]), .SAVE (INT_SUM[148]), .CARRY (INT_CARRY[118]) );
smfulladder dfa97 (.DATA_A (INT_SUM[146]), .DATA_B (INT_SUM[147]), .DATA_C (INT_SUM[148]), .SAVE (INT_SUM[149]), .CARRY (INT_CARRY[119]) );
smfulladder dfa98 (.DATA_A (INT_CARRY[105]), .DATA_B (INT_CARRY[106]), .DATA_C (INT_CARRY[107]), .SAVE (INT_SUM[150]), .CARRY (INT_CARRY[120]) );
smfulladder dfa99 (.DATA_A (INT_SUM[149]), .DATA_B (INT_SUM[150]), .DATA_C (INT_CARRY[108]), .SAVE (INT_SUM[151]), .CARRY (INT_CARRY[121]) );
assign INT_SUM[152] = INT_CARRY[109];
smfulladder dfa100 (.DATA_A (INT_SUM[151]), .DATA_B (INT_SUM[152]), .DATA_C (INT_CARRY[110]), .SAVE (INT_SUM[153]), .CARRY (INT_CARRY[111]) );
smffb dla199 (.D(INT_SUM[153]), .clk(clk), .en_d2(en_d2), .Q(SUM[22]) );
smffb dla200 (.D(INT_CARRY[111]), .clk(clk), .en_d2(en_d2), .Q(CARRY[22]) );
smffa dla201 (.D(SUMMAND[156]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[156]) );
smffa dla202 (.D(SUMMAND[157]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[157]) );
smffa dla203 (.D(SUMMAND[158]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[158]) );
smfulladder dfa101 (.DATA_A (LATCHED_PP[156]), .DATA_B (LATCHED_PP[157]), .DATA_C (LATCHED_PP[158]), .SAVE (INT_SUM[154]), .CARRY (INT_CARRY[123]) );
smffa dla204 (.D(SUMMAND[159]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[159]) );
smffa dla205 (.D(SUMMAND[160]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[160]) );
smffa dla206 (.D(SUMMAND[161]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[161]) );
smfulladder dfa102 (.DATA_A (LATCHED_PP[159]), .DATA_B (LATCHED_PP[160]), .DATA_C (LATCHED_PP[161]), .SAVE (INT_SUM[155]), .CARRY (INT_CARRY[124]) );
smffa dla207 (.D(SUMMAND[162]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[162]) );
smffa dla208 (.D(SUMMAND[163]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[163]) );
smffa dla209 (.D(SUMMAND[164]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[164]) );
smfulladder dfa103 (.DATA_A (LATCHED_PP[162]), .DATA_B (LATCHED_PP[163]), .DATA_C (LATCHED_PP[164]), .SAVE (INT_SUM[156]), .CARRY (INT_CARRY[125]) );
smffa dla210 (.D(SUMMAND[165]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[165]) );
smffa dla211 (.D(SUMMAND[166]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[166]) );
smffa dla212 (.D(SUMMAND[167]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[167]) );
smfulladder dfa104 (.DATA_A (LATCHED_PP[165]), .DATA_B (LATCHED_PP[166]), .DATA_C (LATCHED_PP[167]), .SAVE (INT_SUM[157]), .CARRY (INT_CARRY[126]) );
smfulladder dfa105 (.DATA_A (INT_SUM[154]), .DATA_B (INT_SUM[155]), .DATA_C (INT_SUM[156]), .SAVE (INT_SUM[158]), .CARRY (INT_CARRY[127]) );
smfulladder dfa106 (.DATA_A (INT_SUM[157]), .DATA_B (INT_CARRY[112]), .DATA_C (INT_CARRY[113]), .SAVE (INT_SUM[159]), .CARRY (INT_CARRY[128]) );
smhalfadder dha21 (.DATA_A (INT_CARRY[114]), .DATA_B (INT_CARRY[115]), .SAVE (INT_SUM[160]), .CARRY (INT_CARRY[129]) );
smfulladder dfa107 (.DATA_A (INT_SUM[158]), .DATA_B (INT_SUM[159]), .DATA_C (INT_SUM[160]), .SAVE (INT_SUM[161]), .CARRY (INT_CARRY[130]) );
smfulladder dfa108 (.DATA_A (INT_CARRY[116]), .DATA_B (INT_CARRY[117]), .DATA_C (INT_CARRY[118]), .SAVE (INT_SUM[162]), .CARRY (INT_CARRY[131]) );
smfulladder dfa109 (.DATA_A (INT_SUM[161]), .DATA_B (INT_SUM[162]), .DATA_C (INT_CARRY[119]), .SAVE (INT_SUM[163]), .CARRY (INT_CARRY[132]) );
assign INT_SUM[164] = INT_CARRY[120];
smfulladder dfa110 (.DATA_A (INT_SUM[163]), .DATA_B (INT_SUM[164]), .DATA_C (INT_CARRY[121]), .SAVE (INT_SUM[165]), .CARRY (INT_CARRY[122]) );
smffb dla213 (.D(INT_SUM[165]), .clk(clk), .en_d2(en_d2), .Q(SUM[23]) );
smffb dla214 (.D(INT_CARRY[122]), .clk(clk), .en_d2(en_d2), .Q(CARRY[23]) );
smffa dla215 (.D(SUMMAND[168]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[168]) );
smffa dla216 (.D(SUMMAND[169]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[169]) );
smffa dla217 (.D(SUMMAND[170]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[170]) );
smfulladder dfa111 (.DATA_A (LATCHED_PP[168]), .DATA_B (LATCHED_PP[169]), .DATA_C (LATCHED_PP[170]), .SAVE (INT_SUM[166]), .CARRY (INT_CARRY[134]) );
smffa dla218 (.D(SUMMAND[171]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[171]) );
smffa dla219 (.D(SUMMAND[172]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[172]) );
smffa dla220 (.D(SUMMAND[173]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[173]) );
smfulladder dfa112 (.DATA_A (LATCHED_PP[171]), .DATA_B (LATCHED_PP[172]), .DATA_C (LATCHED_PP[173]), .SAVE (INT_SUM[167]), .CARRY (INT_CARRY[135]) );
smffa dla221 (.D(SUMMAND[174]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[174]) );
smffa dla222 (.D(SUMMAND[175]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[175]) );
smffa dla223 (.D(SUMMAND[176]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[176]) );
smfulladder dfa113 (.DATA_A (LATCHED_PP[174]), .DATA_B (LATCHED_PP[175]), .DATA_C (LATCHED_PP[176]), .SAVE (INT_SUM[168]), .CARRY (INT_CARRY[136]) );
smffa dla224 (.D(SUMMAND[177]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[177]) );
smffa dla225 (.D(SUMMAND[178]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[178]) );
smffa dla226 (.D(SUMMAND[179]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[179]) );
smfulladder dfa114 (.DATA_A (LATCHED_PP[177]), .DATA_B (LATCHED_PP[178]), .DATA_C (LATCHED_PP[179]), .SAVE (INT_SUM[169]), .CARRY (INT_CARRY[137]) );
smffa dla227 (.D(SUMMAND[180]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[180]) );
smffa dla228 (.D(SUMMAND[181]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[181]) );
smhalfadder dha22 (.DATA_A (LATCHED_PP[180]), .DATA_B (LATCHED_PP[181]), .SAVE (INT_SUM[170]), .CARRY (INT_CARRY[138]) );
smfulladder dfa115 (.DATA_A (INT_SUM[166]), .DATA_B (INT_SUM[167]), .DATA_C (INT_SUM[168]), .SAVE (INT_SUM[171]), .CARRY (INT_CARRY[139]) );
smfulladder dfa116 (.DATA_A (INT_SUM[169]), .DATA_B (INT_SUM[170]), .DATA_C (INT_CARRY[123]), .SAVE (INT_SUM[172]), .CARRY (INT_CARRY[140]) );
smfulladder dfa117 (.DATA_A (INT_CARRY[124]), .DATA_B (INT_CARRY[125]), .DATA_C (INT_CARRY[126]), .SAVE (INT_SUM[173]), .CARRY (INT_CARRY[141]) );
smfulladder dfa118 (.DATA_A (INT_SUM[171]), .DATA_B (INT_SUM[172]), .DATA_C (INT_SUM[173]), .SAVE (INT_SUM[174]), .CARRY (INT_CARRY[142]) );
smfulladder dfa119 (.DATA_A (INT_CARRY[127]), .DATA_B (INT_CARRY[128]), .DATA_C (INT_CARRY[129]), .SAVE (INT_SUM[175]), .CARRY (INT_CARRY[143]) );
smfulladder dfa120 (.DATA_A (INT_SUM[174]), .DATA_B (INT_SUM[175]), .DATA_C (INT_CARRY[130]), .SAVE (INT_SUM[176]), .CARRY (INT_CARRY[144]) );
assign INT_SUM[177] = INT_CARRY[131];
smfulladder dfa121 (.DATA_A (INT_SUM[176]), .DATA_B (INT_SUM[177]), .DATA_C (INT_CARRY[132]), .SAVE (INT_SUM[178]), .CARRY (INT_CARRY[133]) );
smffb dla229 (.D(INT_SUM[178]), .clk(clk), .en_d2(en_d2), .Q(SUM[24]) );
smffb dla230 (.D(INT_CARRY[133]), .clk(clk), .en_d2(en_d2), .Q(CARRY[24]) );
smffa dla231 (.D(SUMMAND[182]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[182]) );
smffa dla232 (.D(SUMMAND[183]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[183]) );
smffa dla233 (.D(SUMMAND[184]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[184]) );
smfulladder dfa122 (.DATA_A (LATCHED_PP[182]), .DATA_B (LATCHED_PP[183]), .DATA_C (LATCHED_PP[184]), .SAVE (INT_SUM[179]), .CARRY (INT_CARRY[146]) );
smffa dla234 (.D(SUMMAND[185]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[185]) );
smffa dla235 (.D(SUMMAND[186]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[186]) );
smffa dla236 (.D(SUMMAND[187]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[187]) );
smfulladder dfa123 (.DATA_A (LATCHED_PP[185]), .DATA_B (LATCHED_PP[186]), .DATA_C (LATCHED_PP[187]), .SAVE (INT_SUM[180]), .CARRY (INT_CARRY[147]) );
smffa dla237 (.D(SUMMAND[188]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[188]) );
smffa dla238 (.D(SUMMAND[189]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[189]) );
smffa dla239 (.D(SUMMAND[190]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[190]) );
smfulladder dfa124 (.DATA_A (LATCHED_PP[188]), .DATA_B (LATCHED_PP[189]), .DATA_C (LATCHED_PP[190]), .SAVE (INT_SUM[181]), .CARRY (INT_CARRY[148]) );
smffa dla240 (.D(SUMMAND[191]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[191]) );
smffa dla241 (.D(SUMMAND[192]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[192]) );
smffa dla242 (.D(SUMMAND[193]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[193]) );
smfulladder dfa125 (.DATA_A (LATCHED_PP[191]), .DATA_B (LATCHED_PP[192]), .DATA_C (LATCHED_PP[193]), .SAVE (INT_SUM[182]), .CARRY (INT_CARRY[149]) );
smffa dla243 (.D(SUMMAND[194]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[194]) );
assign INT_SUM[183] = LATCHED_PP[194];
smfulladder dfa126 (.DATA_A (INT_SUM[179]), .DATA_B (INT_SUM[180]), .DATA_C (INT_SUM[181]), .SAVE (INT_SUM[184]), .CARRY (INT_CARRY[150]) );
smfulladder dfa127 (.DATA_A (INT_SUM[182]), .DATA_B (INT_SUM[183]), .DATA_C (INT_CARRY[134]), .SAVE (INT_SUM[185]), .CARRY (INT_CARRY[151]) );
smfulladder dfa128 (.DATA_A (INT_CARRY[135]), .DATA_B (INT_CARRY[136]), .DATA_C (INT_CARRY[137]), .SAVE (INT_SUM[186]), .CARRY (INT_CARRY[152]) );
assign INT_SUM[187] = INT_CARRY[138];
smfulladder dfa129 (.DATA_A (INT_SUM[184]), .DATA_B (INT_SUM[185]), .DATA_C (INT_SUM[186]), .SAVE (INT_SUM[188]), .CARRY (INT_CARRY[153]) );
smfulladder dfa130 (.DATA_A (INT_SUM[187]), .DATA_B (INT_CARRY[139]), .DATA_C (INT_CARRY[140]), .SAVE (INT_SUM[189]), .CARRY (INT_CARRY[154]) );
assign INT_SUM[190] = INT_CARRY[141];
smfulladder dfa131 (.DATA_A (INT_SUM[188]), .DATA_B (INT_SUM[189]), .DATA_C (INT_SUM[190]), .SAVE (INT_SUM[191]), .CARRY (INT_CARRY[155]) );
smhalfadder dha23 (.DATA_A (INT_CARRY[142]), .DATA_B (INT_CARRY[143]), .SAVE (INT_SUM[192]), .CARRY (INT_CARRY[156]) );
smfulladder dfa132 (.DATA_A (INT_SUM[191]), .DATA_B (INT_SUM[192]), .DATA_C (INT_CARRY[144]), .SAVE (INT_SUM[193]), .CARRY (INT_CARRY[145]) );
smffb dla244 (.D(INT_SUM[193]), .clk(clk), .en_d2(en_d2), .Q(SUM[25]) );
smffb dla245 (.D(INT_CARRY[145]), .clk(clk), .en_d2(en_d2), .Q(CARRY[25]) );
smffa dla246 (.D(SUMMAND[195]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[195]) );
smffa dla247 (.D(SUMMAND[196]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[196]) );
smffa dla248 (.D(SUMMAND[197]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[197]) );
smfulladder dfa133 (.DATA_A (LATCHED_PP[195]), .DATA_B (LATCHED_PP[196]), .DATA_C (LATCHED_PP[197]), .SAVE (INT_SUM[194]), .CARRY (INT_CARRY[158]) );
smffa dla249 (.D(SUMMAND[198]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[198]) );
smffa dla250 (.D(SUMMAND[199]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[199]) );
smffa dla251 (.D(SUMMAND[200]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[200]) );
smfulladder dfa134 (.DATA_A (LATCHED_PP[198]), .DATA_B (LATCHED_PP[199]), .DATA_C (LATCHED_PP[200]), .SAVE (INT_SUM[195]), .CARRY (INT_CARRY[159]) );
smffa dla252 (.D(SUMMAND[201]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[201]) );
smffa dla253 (.D(SUMMAND[202]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[202]) );
smffa dla254 (.D(SUMMAND[203]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[203]) );
smfulladder dfa135 (.DATA_A (LATCHED_PP[201]), .DATA_B (LATCHED_PP[202]), .DATA_C (LATCHED_PP[203]), .SAVE (INT_SUM[196]), .CARRY (INT_CARRY[160]) );
smffa dla255 (.D(SUMMAND[204]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[204]) );
smffa dla256 (.D(SUMMAND[205]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[205]) );
smffa dla257 (.D(SUMMAND[206]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[206]) );
smfulladder dfa136 (.DATA_A (LATCHED_PP[204]), .DATA_B (LATCHED_PP[205]), .DATA_C (LATCHED_PP[206]), .SAVE (INT_SUM[197]), .CARRY (INT_CARRY[161]) );
smffa dla258 (.D(SUMMAND[207]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[207]) );
smffa dla259 (.D(SUMMAND[208]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[208]) );
smffa dla260 (.D(SUMMAND[209]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[209]) );
smfulladder dfa137 (.DATA_A (LATCHED_PP[207]), .DATA_B (LATCHED_PP[208]), .DATA_C (LATCHED_PP[209]), .SAVE (INT_SUM[198]), .CARRY (INT_CARRY[162]) );
smfulladder dfa138 (.DATA_A (INT_SUM[194]), .DATA_B (INT_SUM[195]), .DATA_C (INT_SUM[196]), .SAVE (INT_SUM[199]), .CARRY (INT_CARRY[163]) );
smfulladder dfa139 (.DATA_A (INT_SUM[197]), .DATA_B (INT_SUM[198]), .DATA_C (INT_CARRY[146]), .SAVE (INT_SUM[200]), .CARRY (INT_CARRY[164]) );
smfulladder dfa140 (.DATA_A (INT_CARRY[147]), .DATA_B (INT_CARRY[148]), .DATA_C (INT_CARRY[149]), .SAVE (INT_SUM[201]), .CARRY (INT_CARRY[165]) );
smfulladder dfa141 (.DATA_A (INT_SUM[199]), .DATA_B (INT_SUM[200]), .DATA_C (INT_SUM[201]), .SAVE (INT_SUM[202]), .CARRY (INT_CARRY[166]) );
smfulladder dfa142 (.DATA_A (INT_CARRY[150]), .DATA_B (INT_CARRY[151]), .DATA_C (INT_CARRY[152]), .SAVE (INT_SUM[203]), .CARRY (INT_CARRY[167]) );
smfulladder dfa143 (.DATA_A (INT_SUM[202]), .DATA_B (INT_SUM[203]), .DATA_C (INT_CARRY[153]), .SAVE (INT_SUM[204]), .CARRY (INT_CARRY[168]) );
assign INT_SUM[205] = INT_CARRY[154];
smfulladder dfa144 (.DATA_A (INT_SUM[204]), .DATA_B (INT_SUM[205]), .DATA_C (INT_CARRY[155]), .SAVE (INT_SUM[206]), .CARRY (INT_CARRY[169]) );
assign INT_SUM[207] = INT_CARRY[156];
smhalfadder dha24 (.DATA_A (INT_SUM[206]), .DATA_B (INT_SUM[207]), .SAVE (INT_SUM[208]), .CARRY (INT_CARRY[157]) );
smffb dla261 (.D(INT_SUM[208]), .clk(clk), .en_d2(en_d2), .Q(SUM[26]) );
smffb dla262 (.D(INT_CARRY[157]), .clk(clk), .en_d2(en_d2), .Q(CARRY[26]) );
smffa dla263 (.D(SUMMAND[210]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[210]) );
smffa dla264 (.D(SUMMAND[211]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[211]) );
smffa dla265 (.D(SUMMAND[212]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[212]) );
smfulladder dfa145 (.DATA_A (LATCHED_PP[210]), .DATA_B (LATCHED_PP[211]), .DATA_C (LATCHED_PP[212]), .SAVE (INT_SUM[209]), .CARRY (INT_CARRY[171]) );
smffa dla266 (.D(SUMMAND[213]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[213]) );
smffa dla267 (.D(SUMMAND[214]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[214]) );
smffa dla268 (.D(SUMMAND[215]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[215]) );
smfulladder dfa146 (.DATA_A (LATCHED_PP[213]), .DATA_B (LATCHED_PP[214]), .DATA_C (LATCHED_PP[215]), .SAVE (INT_SUM[210]), .CARRY (INT_CARRY[172]) );
smffa dla269 (.D(SUMMAND[216]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[216]) );
smffa dla270 (.D(SUMMAND[217]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[217]) );
smffa dla271 (.D(SUMMAND[218]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[218]) );
smfulladder dfa147 (.DATA_A (LATCHED_PP[216]), .DATA_B (LATCHED_PP[217]), .DATA_C (LATCHED_PP[218]), .SAVE (INT_SUM[211]), .CARRY (INT_CARRY[173]) );
smffa dla272 (.D(SUMMAND[219]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[219]) );
smffa dla273 (.D(SUMMAND[220]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[220]) );
smffa dla274 (.D(SUMMAND[221]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[221]) );
smfulladder dfa148 (.DATA_A (LATCHED_PP[219]), .DATA_B (LATCHED_PP[220]), .DATA_C (LATCHED_PP[221]), .SAVE (INT_SUM[212]), .CARRY (INT_CARRY[174]) );
smffa dla275 (.D(SUMMAND[222]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[222]) );
smffa dla276 (.D(SUMMAND[223]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[223]) );
smhalfadder dha25 (.DATA_A (LATCHED_PP[222]), .DATA_B (LATCHED_PP[223]), .SAVE (INT_SUM[213]), .CARRY (INT_CARRY[175]) );
smfulladder dfa149 (.DATA_A (INT_SUM[209]), .DATA_B (INT_SUM[210]), .DATA_C (INT_SUM[211]), .SAVE (INT_SUM[214]), .CARRY (INT_CARRY[176]) );
smfulladder dfa150 (.DATA_A (INT_SUM[212]), .DATA_B (INT_SUM[213]), .DATA_C (INT_CARRY[158]), .SAVE (INT_SUM[215]), .CARRY (INT_CARRY[177]) );
smfulladder dfa151 (.DATA_A (INT_CARRY[159]), .DATA_B (INT_CARRY[160]), .DATA_C (INT_CARRY[161]), .SAVE (INT_SUM[216]), .CARRY (INT_CARRY[178]) );
assign INT_SUM[217] = INT_CARRY[162];
smfulladder dfa152 (.DATA_A (INT_SUM[214]), .DATA_B (INT_SUM[215]), .DATA_C (INT_SUM[216]), .SAVE (INT_SUM[218]), .CARRY (INT_CARRY[179]) );
smfulladder dfa153 (.DATA_A (INT_SUM[217]), .DATA_B (INT_CARRY[163]), .DATA_C (INT_CARRY[164]), .SAVE (INT_SUM[219]), .CARRY (INT_CARRY[180]) );
assign INT_SUM[220] = INT_CARRY[165];
smfulladder dfa154 (.DATA_A (INT_SUM[218]), .DATA_B (INT_SUM[219]), .DATA_C (INT_SUM[220]), .SAVE (INT_SUM[221]), .CARRY (INT_CARRY[181]) );
assign INT_SUM[222] = INT_CARRY[166];
assign INT_SUM[223] = INT_CARRY[167];
smfulladder dfa155 (.DATA_A (INT_SUM[221]), .DATA_B (INT_SUM[222]), .DATA_C (INT_SUM[223]), .SAVE (INT_SUM[224]), .CARRY (INT_CARRY[182]) );
assign INT_SUM[225] = INT_CARRY[168];
smfulladder dfa156 (.DATA_A (INT_SUM[224]), .DATA_B (INT_SUM[225]), .DATA_C (INT_CARRY[169]), .SAVE (INT_SUM[226]), .CARRY (INT_CARRY[170]) );
smffb dla277 (.D(INT_SUM[226]), .clk(clk), .en_d2(en_d2), .Q(SUM[27]) );
smffb dla278 (.D(INT_CARRY[170]), .clk(clk), .en_d2(en_d2), .Q(CARRY[27]) );
smffa dla279 (.D(SUMMAND[224]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[224]) );
smffa dla280 (.D(SUMMAND[225]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[225]) );
smffa dla281 (.D(SUMMAND[226]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[226]) );
smfulladder dfa157 (.DATA_A (LATCHED_PP[224]), .DATA_B (LATCHED_PP[225]), .DATA_C (LATCHED_PP[226]), .SAVE (INT_SUM[227]), .CARRY (INT_CARRY[184]) );
smffa dla282 (.D(SUMMAND[227]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[227]) );
smffa dla283 (.D(SUMMAND[228]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[228]) );
smffa dla284 (.D(SUMMAND[229]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[229]) );
smfulladder dfa158 (.DATA_A (LATCHED_PP[227]), .DATA_B (LATCHED_PP[228]), .DATA_C (LATCHED_PP[229]), .SAVE (INT_SUM[228]), .CARRY (INT_CARRY[185]) );
smffa dla285 (.D(SUMMAND[230]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[230]) );
smffa dla286 (.D(SUMMAND[231]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[231]) );
smffa dla287 (.D(SUMMAND[232]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[232]) );
smfulladder dfa159 (.DATA_A (LATCHED_PP[230]), .DATA_B (LATCHED_PP[231]), .DATA_C (LATCHED_PP[232]), .SAVE (INT_SUM[229]), .CARRY (INT_CARRY[186]) );
smffa dla288 (.D(SUMMAND[233]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[233]) );
smffa dla289 (.D(SUMMAND[234]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[234]) );
smffa dla290 (.D(SUMMAND[235]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[235]) );
smfulladder dfa160 (.DATA_A (LATCHED_PP[233]), .DATA_B (LATCHED_PP[234]), .DATA_C (LATCHED_PP[235]), .SAVE (INT_SUM[230]), .CARRY (INT_CARRY[187]) );
smffa dla291 (.D(SUMMAND[236]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[236]) );
smffa dla292 (.D(SUMMAND[237]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[237]) );
smffa dla293 (.D(SUMMAND[238]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[238]) );
smfulladder dfa161 (.DATA_A (LATCHED_PP[236]), .DATA_B (LATCHED_PP[237]), .DATA_C (LATCHED_PP[238]), .SAVE (INT_SUM[231]), .CARRY (INT_CARRY[188]) );
smffa dla294 (.D(SUMMAND[239]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[239]) );
assign INT_SUM[232] = LATCHED_PP[239];
smfulladder dfa162 (.DATA_A (INT_SUM[227]), .DATA_B (INT_SUM[228]), .DATA_C (INT_SUM[229]), .SAVE (INT_SUM[233]), .CARRY (INT_CARRY[189]) );
smfulladder dfa163 (.DATA_A (INT_SUM[230]), .DATA_B (INT_SUM[231]), .DATA_C (INT_SUM[232]), .SAVE (INT_SUM[234]), .CARRY (INT_CARRY[190]) );
smfulladder dfa164 (.DATA_A (INT_CARRY[171]), .DATA_B (INT_CARRY[172]), .DATA_C (INT_CARRY[173]), .SAVE (INT_SUM[235]), .CARRY (INT_CARRY[191]) );
assign INT_SUM[236] = INT_CARRY[174];
assign INT_SUM[237] = INT_CARRY[175];
smfulladder dfa165 (.DATA_A (INT_SUM[233]), .DATA_B (INT_SUM[234]), .DATA_C (INT_SUM[235]), .SAVE (INT_SUM[238]), .CARRY (INT_CARRY[192]) );
smfulladder dfa166 (.DATA_A (INT_SUM[236]), .DATA_B (INT_SUM[237]), .DATA_C (INT_CARRY[176]), .SAVE (INT_SUM[239]), .CARRY (INT_CARRY[193]) );
assign INT_SUM[240] = INT_CARRY[177];
assign INT_SUM[241] = INT_CARRY[178];
smfulladder dfa167 (.DATA_A (INT_SUM[238]), .DATA_B (INT_SUM[239]), .DATA_C (INT_SUM[240]), .SAVE (INT_SUM[242]), .CARRY (INT_CARRY[194]) );
smfulladder dfa168 (.DATA_A (INT_SUM[241]), .DATA_B (INT_CARRY[179]), .DATA_C (INT_CARRY[180]), .SAVE (INT_SUM[243]), .CARRY (INT_CARRY[195]) );
smfulladder dfa169 (.DATA_A (INT_SUM[242]), .DATA_B (INT_SUM[243]), .DATA_C (INT_CARRY[181]), .SAVE (INT_SUM[244]), .CARRY (INT_CARRY[196]) );
smhalfadder dha26 (.DATA_A (INT_SUM[244]), .DATA_B (INT_CARRY[182]), .SAVE (INT_SUM[245]), .CARRY (INT_CARRY[183]) );
smffb dla295 (.D(INT_SUM[245]), .clk(clk), .en_d2(en_d2), .Q(SUM[28]) );
smffb dla296 (.D(INT_CARRY[183]), .clk(clk), .en_d2(en_d2), .Q(CARRY[28]) );
smffa dla297 (.D(SUMMAND[240]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[240]) );
smffa dla298 (.D(SUMMAND[241]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[241]) );
smffa dla299 (.D(SUMMAND[242]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[242]) );
smfulladder dfa170 (.DATA_A (LATCHED_PP[240]), .DATA_B (LATCHED_PP[241]), .DATA_C (LATCHED_PP[242]), .SAVE (INT_SUM[246]), .CARRY (INT_CARRY[198]) );
smffa dla300 (.D(SUMMAND[243]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[243]) );
smffa dla301 (.D(SUMMAND[244]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[244]) );
smffa dla302 (.D(SUMMAND[245]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[245]) );
smfulladder dfa171 (.DATA_A (LATCHED_PP[243]), .DATA_B (LATCHED_PP[244]), .DATA_C (LATCHED_PP[245]), .SAVE (INT_SUM[247]), .CARRY (INT_CARRY[199]) );
smffa dla303 (.D(SUMMAND[246]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[246]) );
smffa dla304 (.D(SUMMAND[247]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[247]) );
smffa dla305 (.D(SUMMAND[248]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[248]) );
smfulladder dfa172 (.DATA_A (LATCHED_PP[246]), .DATA_B (LATCHED_PP[247]), .DATA_C (LATCHED_PP[248]), .SAVE (INT_SUM[248]), .CARRY (INT_CARRY[200]) );
smffa dla306 (.D(SUMMAND[249]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[249]) );
smffa dla307 (.D(SUMMAND[250]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[250]) );
smffa dla308 (.D(SUMMAND[251]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[251]) );
smfulladder dfa173 (.DATA_A (LATCHED_PP[249]), .DATA_B (LATCHED_PP[250]), .DATA_C (LATCHED_PP[251]), .SAVE (INT_SUM[249]), .CARRY (INT_CARRY[201]) );
smffa dla309 (.D(SUMMAND[252]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[252]) );
smffa dla310 (.D(SUMMAND[253]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[253]) );
smffa dla311 (.D(SUMMAND[254]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[254]) );
smfulladder dfa174 (.DATA_A (LATCHED_PP[252]), .DATA_B (LATCHED_PP[253]), .DATA_C (LATCHED_PP[254]), .SAVE (INT_SUM[250]), .CARRY (INT_CARRY[202]) );
smfulladder dfa175 (.DATA_A (INT_SUM[246]), .DATA_B (INT_SUM[247]), .DATA_C (INT_SUM[248]), .SAVE (INT_SUM[251]), .CARRY (INT_CARRY[203]) );
smfulladder dfa176 (.DATA_A (INT_SUM[249]), .DATA_B (INT_SUM[250]), .DATA_C (INT_CARRY[184]), .SAVE (INT_SUM[252]), .CARRY (INT_CARRY[204]) );
smfulladder dfa177 (.DATA_A (INT_CARRY[185]), .DATA_B (INT_CARRY[186]), .DATA_C (INT_CARRY[187]), .SAVE (INT_SUM[253]), .CARRY (INT_CARRY[205]) );
assign INT_SUM[254] = INT_CARRY[188];
smfulladder dfa178 (.DATA_A (INT_SUM[251]), .DATA_B (INT_SUM[252]), .DATA_C (INT_SUM[253]), .SAVE (INT_SUM[255]), .CARRY (INT_CARRY[206]) );
smfulladder dfa179 (.DATA_A (INT_SUM[254]), .DATA_B (INT_CARRY[189]), .DATA_C (INT_CARRY[190]), .SAVE (INT_SUM[256]), .CARRY (INT_CARRY[207]) );
assign INT_SUM[257] = INT_CARRY[191];
smfulladder dfa180 (.DATA_A (INT_SUM[255]), .DATA_B (INT_SUM[256]), .DATA_C (INT_SUM[257]), .SAVE (INT_SUM[258]), .CARRY (INT_CARRY[208]) );
smhalfadder dha27 (.DATA_A (INT_CARRY[192]), .DATA_B (INT_CARRY[193]), .SAVE (INT_SUM[259]), .CARRY (INT_CARRY[209]) );
smfulladder dfa181 (.DATA_A (INT_SUM[258]), .DATA_B (INT_SUM[259]), .DATA_C (INT_CARRY[194]), .SAVE (INT_SUM[260]), .CARRY (INT_CARRY[210]) );
assign INT_SUM[261] = INT_CARRY[195];
smfulladder dfa182 (.DATA_A (INT_SUM[260]), .DATA_B (INT_SUM[261]), .DATA_C (INT_CARRY[196]), .SAVE (INT_SUM[262]), .CARRY (INT_CARRY[197]) );
smffb dla312 (.D(INT_SUM[262]), .clk(clk), .en_d2(en_d2), .Q(SUM[29]) );
smffb dla313 (.D(INT_CARRY[197]), .clk(clk), .en_d2(en_d2), .Q(CARRY[29]) );
smffa dla314 (.D(SUMMAND[255]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[255]) );
smffa dla315 (.D(SUMMAND[256]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[256]) );
smffa dla316 (.D(SUMMAND[257]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[257]) );
smfulladder dfa183 (.DATA_A (LATCHED_PP[255]), .DATA_B (LATCHED_PP[256]), .DATA_C (LATCHED_PP[257]), .SAVE (INT_SUM[263]), .CARRY (INT_CARRY[212]) );
smffa dla317 (.D(SUMMAND[258]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[258]) );
smffa dla318 (.D(SUMMAND[259]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[259]) );
smffa dla319 (.D(SUMMAND[260]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[260]) );
smfulladder dfa184 (.DATA_A (LATCHED_PP[258]), .DATA_B (LATCHED_PP[259]), .DATA_C (LATCHED_PP[260]), .SAVE (INT_SUM[264]), .CARRY (INT_CARRY[213]) );
smffa dla320 (.D(SUMMAND[261]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[261]) );
smffa dla321 (.D(SUMMAND[262]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[262]) );
smffa dla322 (.D(SUMMAND[263]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[263]) );
smfulladder dfa185 (.DATA_A (LATCHED_PP[261]), .DATA_B (LATCHED_PP[262]), .DATA_C (LATCHED_PP[263]), .SAVE (INT_SUM[265]), .CARRY (INT_CARRY[214]) );
smffa dla323 (.D(SUMMAND[264]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[264]) );
smffa dla324 (.D(SUMMAND[265]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[265]) );
smffa dla325 (.D(SUMMAND[266]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[266]) );
smfulladder dfa186 (.DATA_A (LATCHED_PP[264]), .DATA_B (LATCHED_PP[265]), .DATA_C (LATCHED_PP[266]), .SAVE (INT_SUM[266]), .CARRY (INT_CARRY[215]) );
smffa dla326 (.D(SUMMAND[267]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[267]) );
smffa dla327 (.D(SUMMAND[268]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[268]) );
smffa dla328 (.D(SUMMAND[269]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[269]) );
smfulladder dfa187 (.DATA_A (LATCHED_PP[267]), .DATA_B (LATCHED_PP[268]), .DATA_C (LATCHED_PP[269]), .SAVE (INT_SUM[267]), .CARRY (INT_CARRY[216]) );
smffa dla329 (.D(SUMMAND[270]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[270]) );
assign INT_SUM[268] = LATCHED_PP[270];
smffa dla330 (.D(SUMMAND[271]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[271]) );
assign INT_SUM[269] = LATCHED_PP[271];
smfulladder dfa188 (.DATA_A (INT_SUM[263]), .DATA_B (INT_SUM[264]), .DATA_C (INT_SUM[265]), .SAVE (INT_SUM[270]), .CARRY (INT_CARRY[217]) );
smfulladder dfa189 (.DATA_A (INT_SUM[266]), .DATA_B (INT_SUM[267]), .DATA_C (INT_SUM[268]), .SAVE (INT_SUM[271]), .CARRY (INT_CARRY[218]) );
smfulladder dfa190 (.DATA_A (INT_SUM[269]), .DATA_B (INT_CARRY[198]), .DATA_C (INT_CARRY[199]), .SAVE (INT_SUM[272]), .CARRY (INT_CARRY[219]) );
smfulladder dfa191 (.DATA_A (INT_CARRY[200]), .DATA_B (INT_CARRY[201]), .DATA_C (INT_CARRY[202]), .SAVE (INT_SUM[273]), .CARRY (INT_CARRY[220]) );
smfulladder dfa192 (.DATA_A (INT_SUM[270]), .DATA_B (INT_SUM[271]), .DATA_C (INT_SUM[272]), .SAVE (INT_SUM[274]), .CARRY (INT_CARRY[221]) );
smfulladder dfa193 (.DATA_A (INT_SUM[273]), .DATA_B (INT_CARRY[203]), .DATA_C (INT_CARRY[204]), .SAVE (INT_SUM[275]), .CARRY (INT_CARRY[222]) );
assign INT_SUM[276] = INT_CARRY[205];
smfulladder dfa194 (.DATA_A (INT_SUM[274]), .DATA_B (INT_SUM[275]), .DATA_C (INT_SUM[276]), .SAVE (INT_SUM[277]), .CARRY (INT_CARRY[223]) );
smhalfadder dha28 (.DATA_A (INT_CARRY[206]), .DATA_B (INT_CARRY[207]), .SAVE (INT_SUM[278]), .CARRY (INT_CARRY[224]) );
smfulladder dfa195 (.DATA_A (INT_SUM[277]), .DATA_B (INT_SUM[278]), .DATA_C (INT_CARRY[208]), .SAVE (INT_SUM[279]), .CARRY (INT_CARRY[225]) );
assign INT_SUM[280] = INT_CARRY[209];
smfulladder dfa196 (.DATA_A (INT_SUM[279]), .DATA_B (INT_SUM[280]), .DATA_C (INT_CARRY[210]), .SAVE (INT_SUM[281]), .CARRY (INT_CARRY[211]) );
smffb dla331 (.D(INT_SUM[281]), .clk(clk), .en_d2(en_d2), .Q(SUM[30]) );
smffb dla332 (.D(INT_CARRY[211]), .clk(clk), .en_d2(en_d2), .Q(CARRY[30]) );
smffa dla333 (.D(SUMMAND[272]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[272]) );
smffa dla334 (.D(SUMMAND[273]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[273]) );
smffa dla335 (.D(SUMMAND[274]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[274]) );
smfulladder dfa197 (.DATA_A (LATCHED_PP[272]), .DATA_B (LATCHED_PP[273]), .DATA_C (LATCHED_PP[274]), .SAVE (INT_SUM[282]), .CARRY (INT_CARRY[227]) );
smffa dla336 (.D(SUMMAND[275]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[275]) );
smffa dla337 (.D(SUMMAND[276]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[276]) );
smffa dla338 (.D(SUMMAND[277]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[277]) );
smfulladder dfa198 (.DATA_A (LATCHED_PP[275]), .DATA_B (LATCHED_PP[276]), .DATA_C (LATCHED_PP[277]), .SAVE (INT_SUM[283]), .CARRY (INT_CARRY[228]) );
smffa dla339 (.D(SUMMAND[278]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[278]) );
smffa dla340 (.D(SUMMAND[279]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[279]) );
smffa dla341 (.D(SUMMAND[280]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[280]) );
smfulladder dfa199 (.DATA_A (LATCHED_PP[278]), .DATA_B (LATCHED_PP[279]), .DATA_C (LATCHED_PP[280]), .SAVE (INT_SUM[284]), .CARRY (INT_CARRY[229]) );
smffa dla342 (.D(SUMMAND[281]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[281]) );
smffa dla343 (.D(SUMMAND[282]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[282]) );
smffa dla344 (.D(SUMMAND[283]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[283]) );
smfulladder dfa200 (.DATA_A (LATCHED_PP[281]), .DATA_B (LATCHED_PP[282]), .DATA_C (LATCHED_PP[283]), .SAVE (INT_SUM[285]), .CARRY (INT_CARRY[230]) );
smffa dla345 (.D(SUMMAND[284]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[284]) );
smffa dla346 (.D(SUMMAND[285]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[285]) );
smffa dla347 (.D(SUMMAND[286]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[286]) );
smfulladder dfa201 (.DATA_A (LATCHED_PP[284]), .DATA_B (LATCHED_PP[285]), .DATA_C (LATCHED_PP[286]), .SAVE (INT_SUM[286]), .CARRY (INT_CARRY[231]) );
smffa dla348 (.D(SUMMAND[287]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[287]) );
assign INT_SUM[287] = LATCHED_PP[287];
smfulladder dfa202 (.DATA_A (INT_SUM[282]), .DATA_B (INT_SUM[283]), .DATA_C (INT_SUM[284]), .SAVE (INT_SUM[288]), .CARRY (INT_CARRY[232]) );
smfulladder dfa203 (.DATA_A (INT_SUM[285]), .DATA_B (INT_SUM[286]), .DATA_C (INT_SUM[287]), .SAVE (INT_SUM[289]), .CARRY (INT_CARRY[233]) );
smfulladder dfa204 (.DATA_A (INT_CARRY[212]), .DATA_B (INT_CARRY[213]), .DATA_C (INT_CARRY[214]), .SAVE (INT_SUM[290]), .CARRY (INT_CARRY[234]) );
assign INT_SUM[291] = INT_CARRY[215];
assign INT_SUM[292] = INT_CARRY[216];
smfulladder dfa205 (.DATA_A (INT_SUM[288]), .DATA_B (INT_SUM[289]), .DATA_C (INT_SUM[290]), .SAVE (INT_SUM[293]), .CARRY (INT_CARRY[235]) );
smfulladder dfa206 (.DATA_A (INT_SUM[291]), .DATA_B (INT_SUM[292]), .DATA_C (INT_CARRY[217]), .SAVE (INT_SUM[294]), .CARRY (INT_CARRY[236]) );
smfulladder dfa207 (.DATA_A (INT_CARRY[218]), .DATA_B (INT_CARRY[219]), .DATA_C (INT_CARRY[220]), .SAVE (INT_SUM[295]), .CARRY (INT_CARRY[237]) );
smfulladder dfa208 (.DATA_A (INT_SUM[293]), .DATA_B (INT_SUM[294]), .DATA_C (INT_SUM[295]), .SAVE (INT_SUM[296]), .CARRY (INT_CARRY[238]) );
smhalfadder dha29 (.DATA_A (INT_CARRY[221]), .DATA_B (INT_CARRY[222]), .SAVE (INT_SUM[297]), .CARRY (INT_CARRY[239]) );
smfulladder dfa209 (.DATA_A (INT_SUM[296]), .DATA_B (INT_SUM[297]), .DATA_C (INT_CARRY[223]), .SAVE (INT_SUM[298]), .CARRY (INT_CARRY[240]) );
assign INT_SUM[299] = INT_CARRY[224];
smfulladder dfa210 (.DATA_A (INT_SUM[298]), .DATA_B (INT_SUM[299]), .DATA_C (INT_CARRY[225]), .SAVE (INT_SUM[300]), .CARRY (INT_CARRY[226]) );
smffb dla349 (.D(INT_SUM[300]), .clk(clk), .en_d2(en_d2), .Q(SUM[31]) );
smffb dla350 (.D(INT_CARRY[226]), .clk(clk), .en_d2(en_d2), .Q(CARRY[31]) );
smffa dla351 (.D(SUMMAND[288]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[288]) );
smffa dla352 (.D(SUMMAND[289]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[289]) );
smffa dla353 (.D(SUMMAND[290]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[290]) );
smfulladder dfa211 (.DATA_A (LATCHED_PP[288]), .DATA_B (LATCHED_PP[289]), .DATA_C (LATCHED_PP[290]), .SAVE (INT_SUM[301]), .CARRY (INT_CARRY[242]) );
smffa dla354 (.D(SUMMAND[291]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[291]) );
smffa dla355 (.D(SUMMAND[292]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[292]) );
smffa dla356 (.D(SUMMAND[293]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[293]) );
smfulladder dfa212 (.DATA_A (LATCHED_PP[291]), .DATA_B (LATCHED_PP[292]), .DATA_C (LATCHED_PP[293]), .SAVE (INT_SUM[302]), .CARRY (INT_CARRY[243]) );
smffa dla357 (.D(SUMMAND[294]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[294]) );
smffa dla358 (.D(SUMMAND[295]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[295]) );
smffa dla359 (.D(SUMMAND[296]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[296]) );
smfulladder dfa213 (.DATA_A (LATCHED_PP[294]), .DATA_B (LATCHED_PP[295]), .DATA_C (LATCHED_PP[296]), .SAVE (INT_SUM[303]), .CARRY (INT_CARRY[244]) );
smffa dla360 (.D(SUMMAND[297]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[297]) );
smffa dla361 (.D(SUMMAND[298]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[298]) );
smffa dla362 (.D(SUMMAND[299]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[299]) );
smfulladder dfa214 (.DATA_A (LATCHED_PP[297]), .DATA_B (LATCHED_PP[298]), .DATA_C (LATCHED_PP[299]), .SAVE (INT_SUM[304]), .CARRY (INT_CARRY[245]) );
smffa dla363 (.D(SUMMAND[300]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[300]) );
smffa dla364 (.D(SUMMAND[301]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[301]) );
smffa dla365 (.D(SUMMAND[302]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[302]) );
smfulladder dfa215 (.DATA_A (LATCHED_PP[300]), .DATA_B (LATCHED_PP[301]), .DATA_C (LATCHED_PP[302]), .SAVE (INT_SUM[305]), .CARRY (INT_CARRY[246]) );
smffa dla366 (.D(SUMMAND[303]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[303]) );
smffa dla367 (.D(SUMMAND[304]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[304]) );
smffa dla368 (.D(SUMMAND[305]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[305]) );
smfulladder dfa216 (.DATA_A (LATCHED_PP[303]), .DATA_B (LATCHED_PP[304]), .DATA_C (LATCHED_PP[305]), .SAVE (INT_SUM[306]), .CARRY (INT_CARRY[247]) );
smfulladder dfa217 (.DATA_A (INT_SUM[301]), .DATA_B (INT_SUM[302]), .DATA_C (INT_SUM[303]), .SAVE (INT_SUM[307]), .CARRY (INT_CARRY[248]) );
smfulladder dfa218 (.DATA_A (INT_SUM[304]), .DATA_B (INT_SUM[305]), .DATA_C (INT_SUM[306]), .SAVE (INT_SUM[308]), .CARRY (INT_CARRY[249]) );
smfulladder dfa219 (.DATA_A (INT_CARRY[227]), .DATA_B (INT_CARRY[228]), .DATA_C (INT_CARRY[229]), .SAVE (INT_SUM[309]), .CARRY (INT_CARRY[250]) );
smhalfadder dha30 (.DATA_A (INT_CARRY[230]), .DATA_B (INT_CARRY[231]), .SAVE (INT_SUM[310]), .CARRY (INT_CARRY[251]) );
smfulladder dfa220 (.DATA_A (INT_SUM[307]), .DATA_B (INT_SUM[308]), .DATA_C (INT_SUM[309]), .SAVE (INT_SUM[311]), .CARRY (INT_CARRY[252]) );
smfulladder dfa221 (.DATA_A (INT_SUM[310]), .DATA_B (INT_CARRY[232]), .DATA_C (INT_CARRY[233]), .SAVE (INT_SUM[312]), .CARRY (INT_CARRY[253]) );
assign INT_SUM[313] = INT_CARRY[234];
smfulladder dfa222 (.DATA_A (INT_SUM[311]), .DATA_B (INT_SUM[312]), .DATA_C (INT_SUM[313]), .SAVE (INT_SUM[314]), .CARRY (INT_CARRY[254]) );
smfulladder dfa223 (.DATA_A (INT_CARRY[235]), .DATA_B (INT_CARRY[236]), .DATA_C (INT_CARRY[237]), .SAVE (INT_SUM[315]), .CARRY (INT_CARRY[255]) );
smfulladder dfa224 (.DATA_A (INT_SUM[314]), .DATA_B (INT_SUM[315]), .DATA_C (INT_CARRY[238]), .SAVE (INT_SUM[316]), .CARRY (INT_CARRY[256]) );
assign INT_SUM[317] = INT_CARRY[239];
smfulladder dfa225 (.DATA_A (INT_SUM[316]), .DATA_B (INT_SUM[317]), .DATA_C (INT_CARRY[240]), .SAVE (INT_SUM[318]), .CARRY (INT_CARRY[241]) );
smffb dla369 (.D(INT_SUM[318]), .clk(clk), .en_d2(en_d2), .Q(SUM[32]) );
smffb dla370 (.D(INT_CARRY[241]), .clk(clk), .en_d2(en_d2), .Q(CARRY[32]) );
smffa dla371 (.D(SUMMAND[306]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[306]) );
smffa dla372 (.D(SUMMAND[307]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[307]) );
smffa dla373 (.D(SUMMAND[308]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[308]) );
smfulladder dfa226 (.DATA_A (LATCHED_PP[306]), .DATA_B (LATCHED_PP[307]), .DATA_C (LATCHED_PP[308]), .SAVE (INT_SUM[319]), .CARRY (INT_CARRY[258]) );
smffa dla374 (.D(SUMMAND[309]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[309]) );
smffa dla375 (.D(SUMMAND[310]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[310]) );
smffa dla376 (.D(SUMMAND[311]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[311]) );
smfulladder dfa227 (.DATA_A (LATCHED_PP[309]), .DATA_B (LATCHED_PP[310]), .DATA_C (LATCHED_PP[311]), .SAVE (INT_SUM[320]), .CARRY (INT_CARRY[259]) );
smffa dla377 (.D(SUMMAND[312]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[312]) );
smffa dla378 (.D(SUMMAND[313]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[313]) );
smffa dla379 (.D(SUMMAND[314]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[314]) );
smfulladder dfa228 (.DATA_A (LATCHED_PP[312]), .DATA_B (LATCHED_PP[313]), .DATA_C (LATCHED_PP[314]), .SAVE (INT_SUM[321]), .CARRY (INT_CARRY[260]) );
smffa dla380 (.D(SUMMAND[315]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[315]) );
smffa dla381 (.D(SUMMAND[316]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[316]) );
smffa dla382 (.D(SUMMAND[317]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[317]) );
smfulladder dfa229 (.DATA_A (LATCHED_PP[315]), .DATA_B (LATCHED_PP[316]), .DATA_C (LATCHED_PP[317]), .SAVE (INT_SUM[322]), .CARRY (INT_CARRY[261]) );
smffa dla383 (.D(SUMMAND[318]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[318]) );
smffa dla384 (.D(SUMMAND[319]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[319]) );
smffa dla385 (.D(SUMMAND[320]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[320]) );
smfulladder dfa230 (.DATA_A (LATCHED_PP[318]), .DATA_B (LATCHED_PP[319]), .DATA_C (LATCHED_PP[320]), .SAVE (INT_SUM[323]), .CARRY (INT_CARRY[262]) );
smffa dla386 (.D(SUMMAND[321]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[321]) );
assign INT_SUM[324] = LATCHED_PP[321];
smffa dla387 (.D(SUMMAND[322]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[322]) );
assign INT_SUM[325] = LATCHED_PP[322];
smfulladder dfa231 (.DATA_A (INT_SUM[319]), .DATA_B (INT_SUM[320]), .DATA_C (INT_SUM[321]), .SAVE (INT_SUM[326]), .CARRY (INT_CARRY[263]) );
smfulladder dfa232 (.DATA_A (INT_SUM[322]), .DATA_B (INT_SUM[323]), .DATA_C (INT_SUM[324]), .SAVE (INT_SUM[327]), .CARRY (INT_CARRY[264]) );
smfulladder dfa233 (.DATA_A (INT_SUM[325]), .DATA_B (INT_CARRY[242]), .DATA_C (INT_CARRY[243]), .SAVE (INT_SUM[328]), .CARRY (INT_CARRY[265]) );
smfulladder dfa234 (.DATA_A (INT_CARRY[244]), .DATA_B (INT_CARRY[245]), .DATA_C (INT_CARRY[246]), .SAVE (INT_SUM[329]), .CARRY (INT_CARRY[266]) );
assign INT_SUM[330] = INT_CARRY[247];
smfulladder dfa235 (.DATA_A (INT_SUM[326]), .DATA_B (INT_SUM[327]), .DATA_C (INT_SUM[328]), .SAVE (INT_SUM[331]), .CARRY (INT_CARRY[267]) );
smfulladder dfa236 (.DATA_A (INT_SUM[329]), .DATA_B (INT_SUM[330]), .DATA_C (INT_CARRY[248]), .SAVE (INT_SUM[332]), .CARRY (INT_CARRY[268]) );
smfulladder dfa237 (.DATA_A (INT_CARRY[249]), .DATA_B (INT_CARRY[250]), .DATA_C (INT_CARRY[251]), .SAVE (INT_SUM[333]), .CARRY (INT_CARRY[269]) );
smfulladder dfa238 (.DATA_A (INT_SUM[331]), .DATA_B (INT_SUM[332]), .DATA_C (INT_SUM[333]), .SAVE (INT_SUM[334]), .CARRY (INT_CARRY[270]) );
smhalfadder dha31 (.DATA_A (INT_CARRY[252]), .DATA_B (INT_CARRY[253]), .SAVE (INT_SUM[335]), .CARRY (INT_CARRY[271]) );
smfulladder dfa239 (.DATA_A (INT_SUM[334]), .DATA_B (INT_SUM[335]), .DATA_C (INT_CARRY[254]), .SAVE (INT_SUM[336]), .CARRY (INT_CARRY[272]) );
assign INT_SUM[337] = INT_CARRY[255];
smfulladder dfa240 (.DATA_A (INT_SUM[336]), .DATA_B (INT_SUM[337]), .DATA_C (INT_CARRY[256]), .SAVE (INT_SUM[338]), .CARRY (INT_CARRY[257]) );
smffb dla388 (.D(INT_SUM[338]), .clk(clk), .en_d2(en_d2), .Q(SUM[33]) );
smffb dla389 (.D(INT_CARRY[257]), .clk(clk), .en_d2(en_d2), .Q(CARRY[33]) );
smffa dla390 (.D(SUMMAND[323]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[323]) );
smffa dla391 (.D(SUMMAND[324]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[324]) );
smffa dla392 (.D(SUMMAND[325]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[325]) );
smfulladder dfa241 (.DATA_A (LATCHED_PP[323]), .DATA_B (LATCHED_PP[324]), .DATA_C (LATCHED_PP[325]), .SAVE (INT_SUM[339]), .CARRY (INT_CARRY[274]) );
smffa dla393 (.D(SUMMAND[326]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[326]) );
smffa dla394 (.D(SUMMAND[327]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[327]) );
smffa dla395 (.D(SUMMAND[328]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[328]) );
smfulladder dfa242 (.DATA_A (LATCHED_PP[326]), .DATA_B (LATCHED_PP[327]), .DATA_C (LATCHED_PP[328]), .SAVE (INT_SUM[340]), .CARRY (INT_CARRY[275]) );
smffa dla396 (.D(SUMMAND[329]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[329]) );
smffa dla397 (.D(SUMMAND[330]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[330]) );
smffa dla398 (.D(SUMMAND[331]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[331]) );
smfulladder dfa243 (.DATA_A (LATCHED_PP[329]), .DATA_B (LATCHED_PP[330]), .DATA_C (LATCHED_PP[331]), .SAVE (INT_SUM[341]), .CARRY (INT_CARRY[276]) );
smffa dla399 (.D(SUMMAND[332]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[332]) );
smffa dla400 (.D(SUMMAND[333]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[333]) );
smffa dla401 (.D(SUMMAND[334]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[334]) );
smfulladder dfa244 (.DATA_A (LATCHED_PP[332]), .DATA_B (LATCHED_PP[333]), .DATA_C (LATCHED_PP[334]), .SAVE (INT_SUM[342]), .CARRY (INT_CARRY[277]) );
smffa dla402 (.D(SUMMAND[335]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[335]) );
smffa dla403 (.D(SUMMAND[336]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[336]) );
smffa dla404 (.D(SUMMAND[337]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[337]) );
smfulladder dfa245 (.DATA_A (LATCHED_PP[335]), .DATA_B (LATCHED_PP[336]), .DATA_C (LATCHED_PP[337]), .SAVE (INT_SUM[343]), .CARRY (INT_CARRY[278]) );
smffa dla405 (.D(SUMMAND[338]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[338]) );
smffa dla406 (.D(SUMMAND[339]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[339]) );
smffa dla407 (.D(SUMMAND[340]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[340]) );
smfulladder dfa246 (.DATA_A (LATCHED_PP[338]), .DATA_B (LATCHED_PP[339]), .DATA_C (LATCHED_PP[340]), .SAVE (INT_SUM[344]), .CARRY (INT_CARRY[279]) );
smfulladder dfa247 (.DATA_A (INT_SUM[339]), .DATA_B (INT_SUM[340]), .DATA_C (INT_SUM[341]), .SAVE (INT_SUM[345]), .CARRY (INT_CARRY[280]) );
smfulladder dfa248 (.DATA_A (INT_SUM[342]), .DATA_B (INT_SUM[343]), .DATA_C (INT_SUM[344]), .SAVE (INT_SUM[346]), .CARRY (INT_CARRY[281]) );
smfulladder dfa249 (.DATA_A (INT_CARRY[258]), .DATA_B (INT_CARRY[259]), .DATA_C (INT_CARRY[260]), .SAVE (INT_SUM[347]), .CARRY (INT_CARRY[282]) );
assign INT_SUM[348] = INT_CARRY[261];
assign INT_SUM[349] = INT_CARRY[262];
smfulladder dfa250 (.DATA_A (INT_SUM[345]), .DATA_B (INT_SUM[346]), .DATA_C (INT_SUM[347]), .SAVE (INT_SUM[350]), .CARRY (INT_CARRY[283]) );
smfulladder dfa251 (.DATA_A (INT_SUM[348]), .DATA_B (INT_SUM[349]), .DATA_C (INT_CARRY[263]), .SAVE (INT_SUM[351]), .CARRY (INT_CARRY[284]) );
smfulladder dfa252 (.DATA_A (INT_CARRY[264]), .DATA_B (INT_CARRY[265]), .DATA_C (INT_CARRY[266]), .SAVE (INT_SUM[352]), .CARRY (INT_CARRY[285]) );
smfulladder dfa253 (.DATA_A (INT_SUM[350]), .DATA_B (INT_SUM[351]), .DATA_C (INT_SUM[352]), .SAVE (INT_SUM[353]), .CARRY (INT_CARRY[286]) );
smfulladder dfa254 (.DATA_A (INT_CARRY[267]), .DATA_B (INT_CARRY[268]), .DATA_C (INT_CARRY[269]), .SAVE (INT_SUM[354]), .CARRY (INT_CARRY[287]) );
smfulladder dfa255 (.DATA_A (INT_SUM[353]), .DATA_B (INT_SUM[354]), .DATA_C (INT_CARRY[270]), .SAVE (INT_SUM[355]), .CARRY (INT_CARRY[288]) );
assign INT_SUM[356] = INT_CARRY[271];
smfulladder dfa256 (.DATA_A (INT_SUM[355]), .DATA_B (INT_SUM[356]), .DATA_C (INT_CARRY[272]), .SAVE (INT_SUM[357]), .CARRY (INT_CARRY[273]) );
smffb dla408 (.D(INT_SUM[357]), .clk(clk), .en_d2(en_d2), .Q(SUM[34]) );
smffb dla409 (.D(INT_CARRY[273]), .clk(clk), .en_d2(en_d2), .Q(CARRY[34]) );
smffa dla410 (.D(SUMMAND[341]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[341]) );
smffa dla411 (.D(SUMMAND[342]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[342]) );
smffa dla412 (.D(SUMMAND[343]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[343]) );
smfulladder dfa257 (.DATA_A (LATCHED_PP[341]), .DATA_B (LATCHED_PP[342]), .DATA_C (LATCHED_PP[343]), .SAVE (INT_SUM[358]), .CARRY (INT_CARRY[290]) );
smffa dla413 (.D(SUMMAND[344]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[344]) );
smffa dla414 (.D(SUMMAND[345]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[345]) );
smffa dla415 (.D(SUMMAND[346]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[346]) );
smfulladder dfa258 (.DATA_A (LATCHED_PP[344]), .DATA_B (LATCHED_PP[345]), .DATA_C (LATCHED_PP[346]), .SAVE (INT_SUM[359]), .CARRY (INT_CARRY[291]) );
smffa dla416 (.D(SUMMAND[347]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[347]) );
smffa dla417 (.D(SUMMAND[348]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[348]) );
smffa dla418 (.D(SUMMAND[349]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[349]) );
smfulladder dfa259 (.DATA_A (LATCHED_PP[347]), .DATA_B (LATCHED_PP[348]), .DATA_C (LATCHED_PP[349]), .SAVE (INT_SUM[360]), .CARRY (INT_CARRY[292]) );
smffa dla419 (.D(SUMMAND[350]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[350]) );
smffa dla420 (.D(SUMMAND[351]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[351]) );
smffa dla421 (.D(SUMMAND[352]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[352]) );
smfulladder dfa260 (.DATA_A (LATCHED_PP[350]), .DATA_B (LATCHED_PP[351]), .DATA_C (LATCHED_PP[352]), .SAVE (INT_SUM[361]), .CARRY (INT_CARRY[293]) );
smffa dla422 (.D(SUMMAND[353]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[353]) );
smffa dla423 (.D(SUMMAND[354]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[354]) );
smffa dla424 (.D(SUMMAND[355]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[355]) );
smfulladder dfa261 (.DATA_A (LATCHED_PP[353]), .DATA_B (LATCHED_PP[354]), .DATA_C (LATCHED_PP[355]), .SAVE (INT_SUM[362]), .CARRY (INT_CARRY[294]) );
smffa dla425 (.D(SUMMAND[356]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[356]) );
smffa dla426 (.D(SUMMAND[357]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[357]) );
smhalfadder dha32 (.DATA_A (LATCHED_PP[356]), .DATA_B (LATCHED_PP[357]), .SAVE (INT_SUM[363]), .CARRY (INT_CARRY[295]) );
smfulladder dfa262 (.DATA_A (INT_SUM[358]), .DATA_B (INT_SUM[359]), .DATA_C (INT_SUM[360]), .SAVE (INT_SUM[364]), .CARRY (INT_CARRY[296]) );
smfulladder dfa263 (.DATA_A (INT_SUM[361]), .DATA_B (INT_SUM[362]), .DATA_C (INT_SUM[363]), .SAVE (INT_SUM[365]), .CARRY (INT_CARRY[297]) );
smfulladder dfa264 (.DATA_A (INT_CARRY[274]), .DATA_B (INT_CARRY[275]), .DATA_C (INT_CARRY[276]), .SAVE (INT_SUM[366]), .CARRY (INT_CARRY[298]) );
smfulladder dfa265 (.DATA_A (INT_CARRY[277]), .DATA_B (INT_CARRY[278]), .DATA_C (INT_CARRY[279]), .SAVE (INT_SUM[367]), .CARRY (INT_CARRY[299]) );
smfulladder dfa266 (.DATA_A (INT_SUM[364]), .DATA_B (INT_SUM[365]), .DATA_C (INT_SUM[366]), .SAVE (INT_SUM[368]), .CARRY (INT_CARRY[300]) );
smfulladder dfa267 (.DATA_A (INT_SUM[367]), .DATA_B (INT_CARRY[280]), .DATA_C (INT_CARRY[281]), .SAVE (INT_SUM[369]), .CARRY (INT_CARRY[301]) );
assign INT_SUM[370] = INT_CARRY[282];
smfulladder dfa268 (.DATA_A (INT_SUM[368]), .DATA_B (INT_SUM[369]), .DATA_C (INT_SUM[370]), .SAVE (INT_SUM[371]), .CARRY (INT_CARRY[302]) );
smfulladder dfa269 (.DATA_A (INT_CARRY[283]), .DATA_B (INT_CARRY[284]), .DATA_C (INT_CARRY[285]), .SAVE (INT_SUM[372]), .CARRY (INT_CARRY[303]) );
smfulladder dfa270 (.DATA_A (INT_SUM[371]), .DATA_B (INT_SUM[372]), .DATA_C (INT_CARRY[286]), .SAVE (INT_SUM[373]), .CARRY (INT_CARRY[304]) );
assign INT_SUM[374] = INT_CARRY[287];
smfulladder dfa271 (.DATA_A (INT_SUM[373]), .DATA_B (INT_SUM[374]), .DATA_C (INT_CARRY[288]), .SAVE (INT_SUM[375]), .CARRY (INT_CARRY[289]) );
smffb dla427 (.D(INT_SUM[375]), .clk(clk), .en_d2(en_d2), .Q(SUM[35]) );
smffb dla428 (.D(INT_CARRY[289]), .clk(clk), .en_d2(en_d2), .Q(CARRY[35]) );
smffa dla429 (.D(SUMMAND[358]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[358]) );
smffa dla430 (.D(SUMMAND[359]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[359]) );
smffa dla431 (.D(SUMMAND[360]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[360]) );
smfulladder dfa272 (.DATA_A (LATCHED_PP[358]), .DATA_B (LATCHED_PP[359]), .DATA_C (LATCHED_PP[360]), .SAVE (INT_SUM[376]), .CARRY (INT_CARRY[306]) );
smffa dla432 (.D(SUMMAND[361]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[361]) );
smffa dla433 (.D(SUMMAND[362]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[362]) );
smffa dla434 (.D(SUMMAND[363]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[363]) );
smfulladder dfa273 (.DATA_A (LATCHED_PP[361]), .DATA_B (LATCHED_PP[362]), .DATA_C (LATCHED_PP[363]), .SAVE (INT_SUM[377]), .CARRY (INT_CARRY[307]) );
smffa dla435 (.D(SUMMAND[364]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[364]) );
smffa dla436 (.D(SUMMAND[365]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[365]) );
smffa dla437 (.D(SUMMAND[366]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[366]) );
smfulladder dfa274 (.DATA_A (LATCHED_PP[364]), .DATA_B (LATCHED_PP[365]), .DATA_C (LATCHED_PP[366]), .SAVE (INT_SUM[378]), .CARRY (INT_CARRY[308]) );
smffa dla438 (.D(SUMMAND[367]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[367]) );
smffa dla439 (.D(SUMMAND[368]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[368]) );
smffa dla440 (.D(SUMMAND[369]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[369]) );
smfulladder dfa275 (.DATA_A (LATCHED_PP[367]), .DATA_B (LATCHED_PP[368]), .DATA_C (LATCHED_PP[369]), .SAVE (INT_SUM[379]), .CARRY (INT_CARRY[309]) );
smffa dla441 (.D(SUMMAND[370]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[370]) );
smffa dla442 (.D(SUMMAND[371]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[371]) );
smffa dla443 (.D(SUMMAND[372]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[372]) );
smfulladder dfa276 (.DATA_A (LATCHED_PP[370]), .DATA_B (LATCHED_PP[371]), .DATA_C (LATCHED_PP[372]), .SAVE (INT_SUM[380]), .CARRY (INT_CARRY[310]) );
smffa dla444 (.D(SUMMAND[373]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[373]) );
assign INT_SUM[381] = LATCHED_PP[373];
smfulladder dfa277 (.DATA_A (INT_SUM[376]), .DATA_B (INT_SUM[377]), .DATA_C (INT_SUM[378]), .SAVE (INT_SUM[382]), .CARRY (INT_CARRY[311]) );
smfulladder dfa278 (.DATA_A (INT_SUM[379]), .DATA_B (INT_SUM[380]), .DATA_C (INT_SUM[381]), .SAVE (INT_SUM[383]), .CARRY (INT_CARRY[312]) );
smfulladder dfa279 (.DATA_A (INT_CARRY[290]), .DATA_B (INT_CARRY[291]), .DATA_C (INT_CARRY[292]), .SAVE (INT_SUM[384]), .CARRY (INT_CARRY[313]) );
smfulladder dfa280 (.DATA_A (INT_CARRY[293]), .DATA_B (INT_CARRY[294]), .DATA_C (INT_CARRY[295]), .SAVE (INT_SUM[385]), .CARRY (INT_CARRY[314]) );
smfulladder dfa281 (.DATA_A (INT_SUM[382]), .DATA_B (INT_SUM[383]), .DATA_C (INT_SUM[384]), .SAVE (INT_SUM[386]), .CARRY (INT_CARRY[315]) );
smfulladder dfa282 (.DATA_A (INT_SUM[385]), .DATA_B (INT_CARRY[296]), .DATA_C (INT_CARRY[297]), .SAVE (INT_SUM[387]), .CARRY (INT_CARRY[316]) );
assign INT_SUM[388] = INT_CARRY[298];
assign INT_SUM[389] = INT_CARRY[299];
smfulladder dfa283 (.DATA_A (INT_SUM[386]), .DATA_B (INT_SUM[387]), .DATA_C (INT_SUM[388]), .SAVE (INT_SUM[390]), .CARRY (INT_CARRY[317]) );
smfulladder dfa284 (.DATA_A (INT_SUM[389]), .DATA_B (INT_CARRY[300]), .DATA_C (INT_CARRY[301]), .SAVE (INT_SUM[391]), .CARRY (INT_CARRY[318]) );
smfulladder dfa285 (.DATA_A (INT_SUM[390]), .DATA_B (INT_SUM[391]), .DATA_C (INT_CARRY[302]), .SAVE (INT_SUM[392]), .CARRY (INT_CARRY[319]) );
assign INT_SUM[393] = INT_CARRY[303];
smfulladder dfa286 (.DATA_A (INT_SUM[392]), .DATA_B (INT_SUM[393]), .DATA_C (INT_CARRY[304]), .SAVE (INT_SUM[394]), .CARRY (INT_CARRY[305]) );
smffb dla445 (.D(INT_SUM[394]), .clk(clk), .en_d2(en_d2), .Q(SUM[36]) );
smffb dla446 (.D(INT_CARRY[305]), .clk(clk), .en_d2(en_d2), .Q(CARRY[36]) );
smffa dla447 (.D(SUMMAND[374]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[374]) );
smffa dla448 (.D(SUMMAND[375]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[375]) );
smffa dla449 (.D(SUMMAND[376]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[376]) );
smfulladder dfa287 (.DATA_A (LATCHED_PP[374]), .DATA_B (LATCHED_PP[375]), .DATA_C (LATCHED_PP[376]), .SAVE (INT_SUM[395]), .CARRY (INT_CARRY[321]) );
smffa dla450 (.D(SUMMAND[377]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[377]) );
smffa dla451 (.D(SUMMAND[378]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[378]) );
smffa dla452 (.D(SUMMAND[379]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[379]) );
smfulladder dfa288 (.DATA_A (LATCHED_PP[377]), .DATA_B (LATCHED_PP[378]), .DATA_C (LATCHED_PP[379]), .SAVE (INT_SUM[396]), .CARRY (INT_CARRY[322]) );
smffa dla453 (.D(SUMMAND[380]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[380]) );
smffa dla454 (.D(SUMMAND[381]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[381]) );
smffa dla455 (.D(SUMMAND[382]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[382]) );
smfulladder dfa289 (.DATA_A (LATCHED_PP[380]), .DATA_B (LATCHED_PP[381]), .DATA_C (LATCHED_PP[382]), .SAVE (INT_SUM[397]), .CARRY (INT_CARRY[323]) );
smffa dla456 (.D(SUMMAND[383]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[383]) );
smffa dla457 (.D(SUMMAND[384]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[384]) );
smffa dla458 (.D(SUMMAND[385]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[385]) );
smfulladder dfa290 (.DATA_A (LATCHED_PP[383]), .DATA_B (LATCHED_PP[384]), .DATA_C (LATCHED_PP[385]), .SAVE (INT_SUM[398]), .CARRY (INT_CARRY[324]) );
smffa dla459 (.D(SUMMAND[386]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[386]) );
smffa dla460 (.D(SUMMAND[387]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[387]) );
smffa dla461 (.D(SUMMAND[388]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[388]) );
smfulladder dfa291 (.DATA_A (LATCHED_PP[386]), .DATA_B (LATCHED_PP[387]), .DATA_C (LATCHED_PP[388]), .SAVE (INT_SUM[399]), .CARRY (INT_CARRY[325]) );
smffa dla462 (.D(SUMMAND[389]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[389]) );
assign INT_SUM[400] = LATCHED_PP[389];
smfulladder dfa292 (.DATA_A (INT_SUM[395]), .DATA_B (INT_SUM[396]), .DATA_C (INT_SUM[397]), .SAVE (INT_SUM[401]), .CARRY (INT_CARRY[326]) );
smfulladder dfa293 (.DATA_A (INT_SUM[398]), .DATA_B (INT_SUM[399]), .DATA_C (INT_SUM[400]), .SAVE (INT_SUM[402]), .CARRY (INT_CARRY[327]) );
smfulladder dfa294 (.DATA_A (INT_CARRY[306]), .DATA_B (INT_CARRY[307]), .DATA_C (INT_CARRY[308]), .SAVE (INT_SUM[403]), .CARRY (INT_CARRY[328]) );
assign INT_SUM[404] = INT_CARRY[309];
assign INT_SUM[405] = INT_CARRY[310];
smfulladder dfa295 (.DATA_A (INT_SUM[401]), .DATA_B (INT_SUM[402]), .DATA_C (INT_SUM[403]), .SAVE (INT_SUM[406]), .CARRY (INT_CARRY[329]) );
smfulladder dfa296 (.DATA_A (INT_SUM[404]), .DATA_B (INT_SUM[405]), .DATA_C (INT_CARRY[311]), .SAVE (INT_SUM[407]), .CARRY (INT_CARRY[330]) );
smfulladder dfa297 (.DATA_A (INT_CARRY[312]), .DATA_B (INT_CARRY[313]), .DATA_C (INT_CARRY[314]), .SAVE (INT_SUM[408]), .CARRY (INT_CARRY[331]) );
smfulladder dfa298 (.DATA_A (INT_SUM[406]), .DATA_B (INT_SUM[407]), .DATA_C (INT_SUM[408]), .SAVE (INT_SUM[409]), .CARRY (INT_CARRY[332]) );
smhalfadder dha33 (.DATA_A (INT_CARRY[315]), .DATA_B (INT_CARRY[316]), .SAVE (INT_SUM[410]), .CARRY (INT_CARRY[333]) );
smfulladder dfa299 (.DATA_A (INT_SUM[409]), .DATA_B (INT_SUM[410]), .DATA_C (INT_CARRY[317]), .SAVE (INT_SUM[411]), .CARRY (INT_CARRY[334]) );
assign INT_SUM[412] = INT_CARRY[318];
smfulladder dfa300 (.DATA_A (INT_SUM[411]), .DATA_B (INT_SUM[412]), .DATA_C (INT_CARRY[319]), .SAVE (INT_SUM[413]), .CARRY (INT_CARRY[320]) );
smffb dla463 (.D(INT_SUM[413]), .clk(clk), .en_d2(en_d2), .Q(SUM[37]) );
smffb dla464 (.D(INT_CARRY[320]), .clk(clk), .en_d2(en_d2), .Q(CARRY[37]) );
smffa dla465 (.D(SUMMAND[390]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[390]) );
smffa dla466 (.D(SUMMAND[391]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[391]) );
smffa dla467 (.D(SUMMAND[392]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[392]) );
smfulladder dfa301 (.DATA_A (LATCHED_PP[390]), .DATA_B (LATCHED_PP[391]), .DATA_C (LATCHED_PP[392]), .SAVE (INT_SUM[414]), .CARRY (INT_CARRY[336]) );
smffa dla468 (.D(SUMMAND[393]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[393]) );
smffa dla469 (.D(SUMMAND[394]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[394]) );
smffa dla470 (.D(SUMMAND[395]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[395]) );
smfulladder dfa302 (.DATA_A (LATCHED_PP[393]), .DATA_B (LATCHED_PP[394]), .DATA_C (LATCHED_PP[395]), .SAVE (INT_SUM[415]), .CARRY (INT_CARRY[337]) );
smffa dla471 (.D(SUMMAND[396]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[396]) );
smffa dla472 (.D(SUMMAND[397]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[397]) );
smffa dla473 (.D(SUMMAND[398]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[398]) );
smfulladder dfa303 (.DATA_A (LATCHED_PP[396]), .DATA_B (LATCHED_PP[397]), .DATA_C (LATCHED_PP[398]), .SAVE (INT_SUM[416]), .CARRY (INT_CARRY[338]) );
smffa dla474 (.D(SUMMAND[399]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[399]) );
smffa dla475 (.D(SUMMAND[400]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[400]) );
smffa dla476 (.D(SUMMAND[401]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[401]) );
smfulladder dfa304 (.DATA_A (LATCHED_PP[399]), .DATA_B (LATCHED_PP[400]), .DATA_C (LATCHED_PP[401]), .SAVE (INT_SUM[417]), .CARRY (INT_CARRY[339]) );
smffa dla477 (.D(SUMMAND[402]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[402]) );
smffa dla478 (.D(SUMMAND[403]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[403]) );
smffa dla479 (.D(SUMMAND[404]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[404]) );
smfulladder dfa305 (.DATA_A (LATCHED_PP[402]), .DATA_B (LATCHED_PP[403]), .DATA_C (LATCHED_PP[404]), .SAVE (INT_SUM[418]), .CARRY (INT_CARRY[340]) );
smfulladder dfa306 (.DATA_A (INT_SUM[414]), .DATA_B (INT_SUM[415]), .DATA_C (INT_SUM[416]), .SAVE (INT_SUM[419]), .CARRY (INT_CARRY[341]) );
smfulladder dfa307 (.DATA_A (INT_SUM[417]), .DATA_B (INT_SUM[418]), .DATA_C (INT_CARRY[321]), .SAVE (INT_SUM[420]), .CARRY (INT_CARRY[342]) );
smfulladder dfa308 (.DATA_A (INT_CARRY[322]), .DATA_B (INT_CARRY[323]), .DATA_C (INT_CARRY[324]), .SAVE (INT_SUM[421]), .CARRY (INT_CARRY[343]) );
assign INT_SUM[422] = INT_CARRY[325];
smfulladder dfa309 (.DATA_A (INT_SUM[419]), .DATA_B (INT_SUM[420]), .DATA_C (INT_SUM[421]), .SAVE (INT_SUM[423]), .CARRY (INT_CARRY[344]) );
smfulladder dfa310 (.DATA_A (INT_SUM[422]), .DATA_B (INT_CARRY[326]), .DATA_C (INT_CARRY[327]), .SAVE (INT_SUM[424]), .CARRY (INT_CARRY[345]) );
assign INT_SUM[425] = INT_CARRY[328];
smfulladder dfa311 (.DATA_A (INT_SUM[423]), .DATA_B (INT_SUM[424]), .DATA_C (INT_SUM[425]), .SAVE (INT_SUM[426]), .CARRY (INT_CARRY[346]) );
smfulladder dfa312 (.DATA_A (INT_CARRY[329]), .DATA_B (INT_CARRY[330]), .DATA_C (INT_CARRY[331]), .SAVE (INT_SUM[427]), .CARRY (INT_CARRY[347]) );
smfulladder dfa313 (.DATA_A (INT_SUM[426]), .DATA_B (INT_SUM[427]), .DATA_C (INT_CARRY[332]), .SAVE (INT_SUM[428]), .CARRY (INT_CARRY[348]) );
assign INT_SUM[429] = INT_CARRY[333];
smfulladder dfa314 (.DATA_A (INT_SUM[428]), .DATA_B (INT_SUM[429]), .DATA_C (INT_CARRY[334]), .SAVE (INT_SUM[430]), .CARRY (INT_CARRY[335]) );
smffb dla480 (.D(INT_SUM[430]), .clk(clk), .en_d2(en_d2), .Q(SUM[38]) );
smffb dla481 (.D(INT_CARRY[335]), .clk(clk), .en_d2(en_d2), .Q(CARRY[38]) );
smffa dla482 (.D(SUMMAND[405]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[405]) );
smffa dla483 (.D(SUMMAND[406]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[406]) );
smffa dla484 (.D(SUMMAND[407]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[407]) );
smfulladder dfa315 (.DATA_A (LATCHED_PP[405]), .DATA_B (LATCHED_PP[406]), .DATA_C (LATCHED_PP[407]), .SAVE (INT_SUM[431]), .CARRY (INT_CARRY[350]) );
smffa dla485 (.D(SUMMAND[408]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[408]) );
smffa dla486 (.D(SUMMAND[409]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[409]) );
smffa dla487 (.D(SUMMAND[410]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[410]) );
smfulladder dfa316 (.DATA_A (LATCHED_PP[408]), .DATA_B (LATCHED_PP[409]), .DATA_C (LATCHED_PP[410]), .SAVE (INT_SUM[432]), .CARRY (INT_CARRY[351]) );
smffa dla488 (.D(SUMMAND[411]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[411]) );
smffa dla489 (.D(SUMMAND[412]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[412]) );
smffa dla490 (.D(SUMMAND[413]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[413]) );
smfulladder dfa317 (.DATA_A (LATCHED_PP[411]), .DATA_B (LATCHED_PP[412]), .DATA_C (LATCHED_PP[413]), .SAVE (INT_SUM[433]), .CARRY (INT_CARRY[352]) );
smffa dla491 (.D(SUMMAND[414]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[414]) );
smffa dla492 (.D(SUMMAND[415]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[415]) );
smffa dla493 (.D(SUMMAND[416]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[416]) );
smfulladder dfa318 (.DATA_A (LATCHED_PP[414]), .DATA_B (LATCHED_PP[415]), .DATA_C (LATCHED_PP[416]), .SAVE (INT_SUM[434]), .CARRY (INT_CARRY[353]) );
smffa dla494 (.D(SUMMAND[417]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[417]) );
smffa dla495 (.D(SUMMAND[418]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[418]) );
smffa dla496 (.D(SUMMAND[419]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[419]) );
smfulladder dfa319 (.DATA_A (LATCHED_PP[417]), .DATA_B (LATCHED_PP[418]), .DATA_C (LATCHED_PP[419]), .SAVE (INT_SUM[435]), .CARRY (INT_CARRY[354]) );
smfulladder dfa320 (.DATA_A (INT_SUM[431]), .DATA_B (INT_SUM[432]), .DATA_C (INT_SUM[433]), .SAVE (INT_SUM[436]), .CARRY (INT_CARRY[355]) );
smfulladder dfa321 (.DATA_A (INT_SUM[434]), .DATA_B (INT_SUM[435]), .DATA_C (INT_CARRY[336]), .SAVE (INT_SUM[437]), .CARRY (INT_CARRY[356]) );
smfulladder dfa322 (.DATA_A (INT_CARRY[337]), .DATA_B (INT_CARRY[338]), .DATA_C (INT_CARRY[339]), .SAVE (INT_SUM[438]), .CARRY (INT_CARRY[357]) );
assign INT_SUM[439] = INT_CARRY[340];
smfulladder dfa323 (.DATA_A (INT_SUM[436]), .DATA_B (INT_SUM[437]), .DATA_C (INT_SUM[438]), .SAVE (INT_SUM[440]), .CARRY (INT_CARRY[358]) );
smfulladder dfa324 (.DATA_A (INT_SUM[439]), .DATA_B (INT_CARRY[341]), .DATA_C (INT_CARRY[342]), .SAVE (INT_SUM[441]), .CARRY (INT_CARRY[359]) );
assign INT_SUM[442] = INT_CARRY[343];
smfulladder dfa325 (.DATA_A (INT_SUM[440]), .DATA_B (INT_SUM[441]), .DATA_C (INT_SUM[442]), .SAVE (INT_SUM[443]), .CARRY (INT_CARRY[360]) );
smhalfadder dha34 (.DATA_A (INT_CARRY[344]), .DATA_B (INT_CARRY[345]), .SAVE (INT_SUM[444]), .CARRY (INT_CARRY[361]) );
smfulladder dfa326 (.DATA_A (INT_SUM[443]), .DATA_B (INT_SUM[444]), .DATA_C (INT_CARRY[346]), .SAVE (INT_SUM[445]), .CARRY (INT_CARRY[362]) );
assign INT_SUM[446] = INT_CARRY[347];
smfulladder dfa327 (.DATA_A (INT_SUM[445]), .DATA_B (INT_SUM[446]), .DATA_C (INT_CARRY[348]), .SAVE (INT_SUM[447]), .CARRY (INT_CARRY[349]) );
smffb dla497 (.D(INT_SUM[447]), .clk(clk), .en_d2(en_d2), .Q(SUM[39]) );
smffb dla498 (.D(INT_CARRY[349]), .clk(clk), .en_d2(en_d2), .Q(CARRY[39]) );
smffa dla499 (.D(SUMMAND[420]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[420]) );
smffa dla500 (.D(SUMMAND[421]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[421]) );
smffa dla501 (.D(SUMMAND[422]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[422]) );
smfulladder dfa328 (.DATA_A (LATCHED_PP[420]), .DATA_B (LATCHED_PP[421]), .DATA_C (LATCHED_PP[422]), .SAVE (INT_SUM[448]), .CARRY (INT_CARRY[364]) );
smffa dla502 (.D(SUMMAND[423]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[423]) );
smffa dla503 (.D(SUMMAND[424]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[424]) );
smffa dla504 (.D(SUMMAND[425]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[425]) );
smfulladder dfa329 (.DATA_A (LATCHED_PP[423]), .DATA_B (LATCHED_PP[424]), .DATA_C (LATCHED_PP[425]), .SAVE (INT_SUM[449]), .CARRY (INT_CARRY[365]) );
smffa dla505 (.D(SUMMAND[426]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[426]) );
smffa dla506 (.D(SUMMAND[427]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[427]) );
smffa dla507 (.D(SUMMAND[428]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[428]) );
smfulladder dfa330 (.DATA_A (LATCHED_PP[426]), .DATA_B (LATCHED_PP[427]), .DATA_C (LATCHED_PP[428]), .SAVE (INT_SUM[450]), .CARRY (INT_CARRY[366]) );
smffa dla508 (.D(SUMMAND[429]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[429]) );
smffa dla509 (.D(SUMMAND[430]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[430]) );
smffa dla510 (.D(SUMMAND[431]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[431]) );
smfulladder dfa331 (.DATA_A (LATCHED_PP[429]), .DATA_B (LATCHED_PP[430]), .DATA_C (LATCHED_PP[431]), .SAVE (INT_SUM[451]), .CARRY (INT_CARRY[367]) );
smffa dla511 (.D(SUMMAND[432]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[432]) );
smffa dla512 (.D(SUMMAND[433]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[433]) );
smhalfadder dha35 (.DATA_A (LATCHED_PP[432]), .DATA_B (LATCHED_PP[433]), .SAVE (INT_SUM[452]), .CARRY (INT_CARRY[368]) );
smfulladder dfa332 (.DATA_A (INT_SUM[448]), .DATA_B (INT_SUM[449]), .DATA_C (INT_SUM[450]), .SAVE (INT_SUM[453]), .CARRY (INT_CARRY[369]) );
smfulladder dfa333 (.DATA_A (INT_SUM[451]), .DATA_B (INT_SUM[452]), .DATA_C (INT_CARRY[350]), .SAVE (INT_SUM[454]), .CARRY (INT_CARRY[370]) );
smfulladder dfa334 (.DATA_A (INT_CARRY[351]), .DATA_B (INT_CARRY[352]), .DATA_C (INT_CARRY[353]), .SAVE (INT_SUM[455]), .CARRY (INT_CARRY[371]) );
assign INT_SUM[456] = INT_CARRY[354];
smfulladder dfa335 (.DATA_A (INT_SUM[453]), .DATA_B (INT_SUM[454]), .DATA_C (INT_SUM[455]), .SAVE (INT_SUM[457]), .CARRY (INT_CARRY[372]) );
smfulladder dfa336 (.DATA_A (INT_SUM[456]), .DATA_B (INT_CARRY[355]), .DATA_C (INT_CARRY[356]), .SAVE (INT_SUM[458]), .CARRY (INT_CARRY[373]) );
assign INT_SUM[459] = INT_CARRY[357];
smfulladder dfa337 (.DATA_A (INT_SUM[457]), .DATA_B (INT_SUM[458]), .DATA_C (INT_SUM[459]), .SAVE (INT_SUM[460]), .CARRY (INT_CARRY[374]) );
smhalfadder dha36 (.DATA_A (INT_CARRY[358]), .DATA_B (INT_CARRY[359]), .SAVE (INT_SUM[461]), .CARRY (INT_CARRY[375]) );
smfulladder dfa338 (.DATA_A (INT_SUM[460]), .DATA_B (INT_SUM[461]), .DATA_C (INT_CARRY[360]), .SAVE (INT_SUM[462]), .CARRY (INT_CARRY[376]) );
assign INT_SUM[463] = INT_CARRY[361];
smfulladder dfa339 (.DATA_A (INT_SUM[462]), .DATA_B (INT_SUM[463]), .DATA_C (INT_CARRY[362]), .SAVE (INT_SUM[464]), .CARRY (INT_CARRY[363]) );
smffb dla513 (.D(INT_SUM[464]), .clk(clk), .en_d2(en_d2), .Q(SUM[40]) );
smffb dla514 (.D(INT_CARRY[363]), .clk(clk), .en_d2(en_d2), .Q(CARRY[40]) );
smffa dla515 (.D(SUMMAND[434]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[434]) );
smffa dla516 (.D(SUMMAND[435]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[435]) );
smffa dla517 (.D(SUMMAND[436]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[436]) );
smfulladder dfa340 (.DATA_A (LATCHED_PP[434]), .DATA_B (LATCHED_PP[435]), .DATA_C (LATCHED_PP[436]), .SAVE (INT_SUM[465]), .CARRY (INT_CARRY[378]) );
smffa dla518 (.D(SUMMAND[437]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[437]) );
smffa dla519 (.D(SUMMAND[438]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[438]) );
smffa dla520 (.D(SUMMAND[439]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[439]) );
smfulladder dfa341 (.DATA_A (LATCHED_PP[437]), .DATA_B (LATCHED_PP[438]), .DATA_C (LATCHED_PP[439]), .SAVE (INT_SUM[466]), .CARRY (INT_CARRY[379]) );
smffa dla521 (.D(SUMMAND[440]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[440]) );
smffa dla522 (.D(SUMMAND[441]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[441]) );
smffa dla523 (.D(SUMMAND[442]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[442]) );
smfulladder dfa342 (.DATA_A (LATCHED_PP[440]), .DATA_B (LATCHED_PP[441]), .DATA_C (LATCHED_PP[442]), .SAVE (INT_SUM[467]), .CARRY (INT_CARRY[380]) );
smffa dla524 (.D(SUMMAND[443]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[443]) );
smffa dla525 (.D(SUMMAND[444]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[444]) );
smffa dla526 (.D(SUMMAND[445]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[445]) );
smfulladder dfa343 (.DATA_A (LATCHED_PP[443]), .DATA_B (LATCHED_PP[444]), .DATA_C (LATCHED_PP[445]), .SAVE (INT_SUM[468]), .CARRY (INT_CARRY[381]) );
smffa dla527 (.D(SUMMAND[446]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[446]) );
smffa dla528 (.D(SUMMAND[447]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[447]) );
smhalfadder dha37 (.DATA_A (LATCHED_PP[446]), .DATA_B (LATCHED_PP[447]), .SAVE (INT_SUM[469]), .CARRY (INT_CARRY[382]) );
smfulladder dfa344 (.DATA_A (INT_SUM[465]), .DATA_B (INT_SUM[466]), .DATA_C (INT_SUM[467]), .SAVE (INT_SUM[470]), .CARRY (INT_CARRY[383]) );
smfulladder dfa345 (.DATA_A (INT_SUM[468]), .DATA_B (INT_SUM[469]), .DATA_C (INT_CARRY[364]), .SAVE (INT_SUM[471]), .CARRY (INT_CARRY[384]) );
smfulladder dfa346 (.DATA_A (INT_CARRY[365]), .DATA_B (INT_CARRY[366]), .DATA_C (INT_CARRY[367]), .SAVE (INT_SUM[472]), .CARRY (INT_CARRY[385]) );
assign INT_SUM[473] = INT_CARRY[368];
smfulladder dfa347 (.DATA_A (INT_SUM[470]), .DATA_B (INT_SUM[471]), .DATA_C (INT_SUM[472]), .SAVE (INT_SUM[474]), .CARRY (INT_CARRY[386]) );
smfulladder dfa348 (.DATA_A (INT_SUM[473]), .DATA_B (INT_CARRY[369]), .DATA_C (INT_CARRY[370]), .SAVE (INT_SUM[475]), .CARRY (INT_CARRY[387]) );
assign INT_SUM[476] = INT_CARRY[371];
smfulladder dfa349 (.DATA_A (INT_SUM[474]), .DATA_B (INT_SUM[475]), .DATA_C (INT_SUM[476]), .SAVE (INT_SUM[477]), .CARRY (INT_CARRY[388]) );
smhalfadder dha38 (.DATA_A (INT_CARRY[372]), .DATA_B (INT_CARRY[373]), .SAVE (INT_SUM[478]), .CARRY (INT_CARRY[389]) );
smfulladder dfa350 (.DATA_A (INT_SUM[477]), .DATA_B (INT_SUM[478]), .DATA_C (INT_CARRY[374]), .SAVE (INT_SUM[479]), .CARRY (INT_CARRY[390]) );
assign INT_SUM[480] = INT_CARRY[375];
smfulladder dfa351 (.DATA_A (INT_SUM[479]), .DATA_B (INT_SUM[480]), .DATA_C (INT_CARRY[376]), .SAVE (INT_SUM[481]), .CARRY (INT_CARRY[377]) );
smffb dla529 (.D(INT_SUM[481]), .clk(clk), .en_d2(en_d2), .Q(SUM[41]) );
smffb dla530 (.D(INT_CARRY[377]), .clk(clk), .en_d2(en_d2), .Q(CARRY[41]) );
smffa dla531 (.D(SUMMAND[448]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[448]) );
smffa dla532 (.D(SUMMAND[449]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[449]) );
smffa dla533 (.D(SUMMAND[450]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[450]) );
smfulladder dfa352 (.DATA_A (LATCHED_PP[448]), .DATA_B (LATCHED_PP[449]), .DATA_C (LATCHED_PP[450]), .SAVE (INT_SUM[482]), .CARRY (INT_CARRY[392]) );
smffa dla534 (.D(SUMMAND[451]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[451]) );
smffa dla535 (.D(SUMMAND[452]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[452]) );
smffa dla536 (.D(SUMMAND[453]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[453]) );
smfulladder dfa353 (.DATA_A (LATCHED_PP[451]), .DATA_B (LATCHED_PP[452]), .DATA_C (LATCHED_PP[453]), .SAVE (INT_SUM[483]), .CARRY (INT_CARRY[393]) );
smffa dla537 (.D(SUMMAND[454]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[454]) );
smffa dla538 (.D(SUMMAND[455]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[455]) );
smffa dla539 (.D(SUMMAND[456]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[456]) );
smfulladder dfa354 (.DATA_A (LATCHED_PP[454]), .DATA_B (LATCHED_PP[455]), .DATA_C (LATCHED_PP[456]), .SAVE (INT_SUM[484]), .CARRY (INT_CARRY[394]) );
smffa dla540 (.D(SUMMAND[457]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[457]) );
smffa dla541 (.D(SUMMAND[458]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[458]) );
smffa dla542 (.D(SUMMAND[459]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[459]) );
smfulladder dfa355 (.DATA_A (LATCHED_PP[457]), .DATA_B (LATCHED_PP[458]), .DATA_C (LATCHED_PP[459]), .SAVE (INT_SUM[485]), .CARRY (INT_CARRY[395]) );
smffa dla543 (.D(SUMMAND[460]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[460]) );
assign INT_SUM[486] = LATCHED_PP[460];
smfulladder dfa356 (.DATA_A (INT_SUM[482]), .DATA_B (INT_SUM[483]), .DATA_C (INT_SUM[484]), .SAVE (INT_SUM[487]), .CARRY (INT_CARRY[396]) );
smfulladder dfa357 (.DATA_A (INT_SUM[485]), .DATA_B (INT_SUM[486]), .DATA_C (INT_CARRY[378]), .SAVE (INT_SUM[488]), .CARRY (INT_CARRY[397]) );
smfulladder dfa358 (.DATA_A (INT_CARRY[379]), .DATA_B (INT_CARRY[380]), .DATA_C (INT_CARRY[381]), .SAVE (INT_SUM[489]), .CARRY (INT_CARRY[398]) );
assign INT_SUM[490] = INT_CARRY[382];
smfulladder dfa359 (.DATA_A (INT_SUM[487]), .DATA_B (INT_SUM[488]), .DATA_C (INT_SUM[489]), .SAVE (INT_SUM[491]), .CARRY (INT_CARRY[399]) );
smfulladder dfa360 (.DATA_A (INT_SUM[490]), .DATA_B (INT_CARRY[383]), .DATA_C (INT_CARRY[384]), .SAVE (INT_SUM[492]), .CARRY (INT_CARRY[400]) );
assign INT_SUM[493] = INT_CARRY[385];
smfulladder dfa361 (.DATA_A (INT_SUM[491]), .DATA_B (INT_SUM[492]), .DATA_C (INT_SUM[493]), .SAVE (INT_SUM[494]), .CARRY (INT_CARRY[401]) );
smhalfadder dha39 (.DATA_A (INT_CARRY[386]), .DATA_B (INT_CARRY[387]), .SAVE (INT_SUM[495]), .CARRY (INT_CARRY[402]) );
smfulladder dfa362 (.DATA_A (INT_SUM[494]), .DATA_B (INT_SUM[495]), .DATA_C (INT_CARRY[388]), .SAVE (INT_SUM[496]), .CARRY (INT_CARRY[403]) );
assign INT_SUM[497] = INT_CARRY[389];
smfulladder dfa363 (.DATA_A (INT_SUM[496]), .DATA_B (INT_SUM[497]), .DATA_C (INT_CARRY[390]), .SAVE (INT_SUM[498]), .CARRY (INT_CARRY[391]) );
smffb dla544 (.D(INT_SUM[498]), .clk(clk), .en_d2(en_d2), .Q(SUM[42]) );
smffb dla545 (.D(INT_CARRY[391]), .clk(clk), .en_d2(en_d2), .Q(CARRY[42]) );
smffa dla546 (.D(SUMMAND[461]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[461]) );
smffa dla547 (.D(SUMMAND[462]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[462]) );
smffa dla548 (.D(SUMMAND[463]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[463]) );
smfulladder dfa364 (.DATA_A (LATCHED_PP[461]), .DATA_B (LATCHED_PP[462]), .DATA_C (LATCHED_PP[463]), .SAVE (INT_SUM[499]), .CARRY (INT_CARRY[405]) );
smffa dla549 (.D(SUMMAND[464]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[464]) );
smffa dla550 (.D(SUMMAND[465]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[465]) );
smffa dla551 (.D(SUMMAND[466]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[466]) );
smfulladder dfa365 (.DATA_A (LATCHED_PP[464]), .DATA_B (LATCHED_PP[465]), .DATA_C (LATCHED_PP[466]), .SAVE (INT_SUM[500]), .CARRY (INT_CARRY[406]) );
smffa dla552 (.D(SUMMAND[467]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[467]) );
smffa dla553 (.D(SUMMAND[468]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[468]) );
smffa dla554 (.D(SUMMAND[469]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[469]) );
smfulladder dfa366 (.DATA_A (LATCHED_PP[467]), .DATA_B (LATCHED_PP[468]), .DATA_C (LATCHED_PP[469]), .SAVE (INT_SUM[501]), .CARRY (INT_CARRY[407]) );
smffa dla555 (.D(SUMMAND[470]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[470]) );
smffa dla556 (.D(SUMMAND[471]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[471]) );
smffa dla557 (.D(SUMMAND[472]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[472]) );
smfulladder dfa367 (.DATA_A (LATCHED_PP[470]), .DATA_B (LATCHED_PP[471]), .DATA_C (LATCHED_PP[472]), .SAVE (INT_SUM[502]), .CARRY (INT_CARRY[408]) );
smffa dla558 (.D(SUMMAND[473]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[473]) );
smfulladder dfa368 (.DATA_A (LATCHED_PP[473]), .DATA_B (INT_CARRY[392]), .DATA_C (INT_CARRY[393]), .SAVE (INT_SUM[503]), .CARRY (INT_CARRY[409]) );
assign INT_SUM[504] = INT_CARRY[394];
assign INT_SUM[505] = INT_CARRY[395];
smfulladder dfa369 (.DATA_A (INT_SUM[499]), .DATA_B (INT_SUM[500]), .DATA_C (INT_SUM[501]), .SAVE (INT_SUM[506]), .CARRY (INT_CARRY[410]) );
smfulladder dfa370 (.DATA_A (INT_SUM[502]), .DATA_B (INT_SUM[503]), .DATA_C (INT_SUM[504]), .SAVE (INT_SUM[507]), .CARRY (INT_CARRY[411]) );
smfulladder dfa371 (.DATA_A (INT_SUM[505]), .DATA_B (INT_CARRY[396]), .DATA_C (INT_CARRY[397]), .SAVE (INT_SUM[508]), .CARRY (INT_CARRY[412]) );
assign INT_SUM[509] = INT_CARRY[398];
smfulladder dfa372 (.DATA_A (INT_SUM[506]), .DATA_B (INT_SUM[507]), .DATA_C (INT_SUM[508]), .SAVE (INT_SUM[510]), .CARRY (INT_CARRY[413]) );
smfulladder dfa373 (.DATA_A (INT_SUM[509]), .DATA_B (INT_CARRY[399]), .DATA_C (INT_CARRY[400]), .SAVE (INT_SUM[511]), .CARRY (INT_CARRY[414]) );
smfulladder dfa374 (.DATA_A (INT_SUM[510]), .DATA_B (INT_SUM[511]), .DATA_C (INT_CARRY[401]), .SAVE (INT_SUM[512]), .CARRY (INT_CARRY[415]) );
assign INT_SUM[513] = INT_CARRY[402];
smfulladder dfa375 (.DATA_A (INT_SUM[512]), .DATA_B (INT_SUM[513]), .DATA_C (INT_CARRY[403]), .SAVE (INT_SUM[514]), .CARRY (INT_CARRY[404]) );
smffb dla559 (.D(INT_SUM[514]), .clk(clk), .en_d2(en_d2), .Q(SUM[43]) );
smffb dla560 (.D(INT_CARRY[404]), .clk(clk), .en_d2(en_d2), .Q(CARRY[43]) );
smffa dla561 (.D(SUMMAND[474]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[474]) );
smffa dla562 (.D(SUMMAND[475]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[475]) );
smffa dla563 (.D(SUMMAND[476]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[476]) );
smfulladder dfa376 (.DATA_A (LATCHED_PP[474]), .DATA_B (LATCHED_PP[475]), .DATA_C (LATCHED_PP[476]), .SAVE (INT_SUM[515]), .CARRY (INT_CARRY[417]) );
smffa dla564 (.D(SUMMAND[477]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[477]) );
smffa dla565 (.D(SUMMAND[478]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[478]) );
smffa dla566 (.D(SUMMAND[479]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[479]) );
smfulladder dfa377 (.DATA_A (LATCHED_PP[477]), .DATA_B (LATCHED_PP[478]), .DATA_C (LATCHED_PP[479]), .SAVE (INT_SUM[516]), .CARRY (INT_CARRY[418]) );
smffa dla567 (.D(SUMMAND[480]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[480]) );
smffa dla568 (.D(SUMMAND[481]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[481]) );
smffa dla569 (.D(SUMMAND[482]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[482]) );
smfulladder dfa378 (.DATA_A (LATCHED_PP[480]), .DATA_B (LATCHED_PP[481]), .DATA_C (LATCHED_PP[482]), .SAVE (INT_SUM[517]), .CARRY (INT_CARRY[419]) );
smffa dla570 (.D(SUMMAND[483]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[483]) );
smffa dla571 (.D(SUMMAND[484]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[484]) );
smffa dla572 (.D(SUMMAND[485]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[485]) );
smfulladder dfa379 (.DATA_A (LATCHED_PP[483]), .DATA_B (LATCHED_PP[484]), .DATA_C (LATCHED_PP[485]), .SAVE (INT_SUM[518]), .CARRY (INT_CARRY[420]) );
smfulladder dfa380 (.DATA_A (INT_SUM[515]), .DATA_B (INT_SUM[516]), .DATA_C (INT_SUM[517]), .SAVE (INT_SUM[519]), .CARRY (INT_CARRY[421]) );
smfulladder dfa381 (.DATA_A (INT_SUM[518]), .DATA_B (INT_CARRY[405]), .DATA_C (INT_CARRY[406]), .SAVE (INT_SUM[520]), .CARRY (INT_CARRY[422]) );
smfulladder dfa382 (.DATA_A (INT_CARRY[407]), .DATA_B (INT_CARRY[408]), .DATA_C (INT_CARRY[409]), .SAVE (INT_SUM[521]), .CARRY (INT_CARRY[423]) );
smfulladder dfa383 (.DATA_A (INT_SUM[519]), .DATA_B (INT_SUM[520]), .DATA_C (INT_SUM[521]), .SAVE (INT_SUM[522]), .CARRY (INT_CARRY[424]) );
smfulladder dfa384 (.DATA_A (INT_CARRY[410]), .DATA_B (INT_CARRY[411]), .DATA_C (INT_CARRY[412]), .SAVE (INT_SUM[523]), .CARRY (INT_CARRY[425]) );
smfulladder dfa385 (.DATA_A (INT_SUM[522]), .DATA_B (INT_SUM[523]), .DATA_C (INT_CARRY[413]), .SAVE (INT_SUM[524]), .CARRY (INT_CARRY[426]) );
assign INT_SUM[525] = INT_CARRY[414];
smfulladder dfa386 (.DATA_A (INT_SUM[524]), .DATA_B (INT_SUM[525]), .DATA_C (INT_CARRY[415]), .SAVE (INT_SUM[526]), .CARRY (INT_CARRY[416]) );
smffb dla573 (.D(INT_SUM[526]), .clk(clk), .en_d2(en_d2), .Q(SUM[44]) );
smffb dla574 (.D(INT_CARRY[416]), .clk(clk), .en_d2(en_d2), .Q(CARRY[44]) );
smffa dla575 (.D(SUMMAND[486]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[486]) );
smffa dla576 (.D(SUMMAND[487]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[487]) );
smffa dla577 (.D(SUMMAND[488]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[488]) );
smfulladder dfa387 (.DATA_A (LATCHED_PP[486]), .DATA_B (LATCHED_PP[487]), .DATA_C (LATCHED_PP[488]), .SAVE (INT_SUM[527]), .CARRY (INT_CARRY[428]) );
smffa dla578 (.D(SUMMAND[489]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[489]) );
smffa dla579 (.D(SUMMAND[490]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[490]) );
smffa dla580 (.D(SUMMAND[491]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[491]) );
smfulladder dfa388 (.DATA_A (LATCHED_PP[489]), .DATA_B (LATCHED_PP[490]), .DATA_C (LATCHED_PP[491]), .SAVE (INT_SUM[528]), .CARRY (INT_CARRY[429]) );
smffa dla581 (.D(SUMMAND[492]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[492]) );
smffa dla582 (.D(SUMMAND[493]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[493]) );
smffa dla583 (.D(SUMMAND[494]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[494]) );
smfulladder dfa389 (.DATA_A (LATCHED_PP[492]), .DATA_B (LATCHED_PP[493]), .DATA_C (LATCHED_PP[494]), .SAVE (INT_SUM[529]), .CARRY (INT_CARRY[430]) );
smffa dla584 (.D(SUMMAND[495]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[495]) );
smffa dla585 (.D(SUMMAND[496]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[496]) );
smffa dla586 (.D(SUMMAND[497]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[497]) );
smfulladder dfa390 (.DATA_A (LATCHED_PP[495]), .DATA_B (LATCHED_PP[496]), .DATA_C (LATCHED_PP[497]), .SAVE (INT_SUM[530]), .CARRY (INT_CARRY[431]) );
smfulladder dfa391 (.DATA_A (INT_SUM[527]), .DATA_B (INT_SUM[528]), .DATA_C (INT_SUM[529]), .SAVE (INT_SUM[531]), .CARRY (INT_CARRY[432]) );
smfulladder dfa392 (.DATA_A (INT_SUM[530]), .DATA_B (INT_CARRY[417]), .DATA_C (INT_CARRY[418]), .SAVE (INT_SUM[532]), .CARRY (INT_CARRY[433]) );
smhalfadder dha40 (.DATA_A (INT_CARRY[419]), .DATA_B (INT_CARRY[420]), .SAVE (INT_SUM[533]), .CARRY (INT_CARRY[434]) );
smfulladder dfa393 (.DATA_A (INT_SUM[531]), .DATA_B (INT_SUM[532]), .DATA_C (INT_SUM[533]), .SAVE (INT_SUM[534]), .CARRY (INT_CARRY[435]) );
smfulladder dfa394 (.DATA_A (INT_CARRY[421]), .DATA_B (INT_CARRY[422]), .DATA_C (INT_CARRY[423]), .SAVE (INT_SUM[535]), .CARRY (INT_CARRY[436]) );
smfulladder dfa395 (.DATA_A (INT_SUM[534]), .DATA_B (INT_SUM[535]), .DATA_C (INT_CARRY[424]), .SAVE (INT_SUM[536]), .CARRY (INT_CARRY[437]) );
assign INT_SUM[537] = INT_CARRY[425];
smfulladder dfa396 (.DATA_A (INT_SUM[536]), .DATA_B (INT_SUM[537]), .DATA_C (INT_CARRY[426]), .SAVE (INT_SUM[538]), .CARRY (INT_CARRY[427]) );
smffb dla587 (.D(INT_SUM[538]), .clk(clk), .en_d2(en_d2), .Q(SUM[45]) );
smffb dla588 (.D(INT_CARRY[427]), .clk(clk), .en_d2(en_d2), .Q(CARRY[45]) );
smffa dla589 (.D(SUMMAND[498]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[498]) );
smffa dla590 (.D(SUMMAND[499]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[499]) );
smffa dla591 (.D(SUMMAND[500]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[500]) );
smfulladder dfa397 (.DATA_A (LATCHED_PP[498]), .DATA_B (LATCHED_PP[499]), .DATA_C (LATCHED_PP[500]), .SAVE (INT_SUM[539]), .CARRY (INT_CARRY[439]) );
smffa dla592 (.D(SUMMAND[501]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[501]) );
smffa dla593 (.D(SUMMAND[502]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[502]) );
smffa dla594 (.D(SUMMAND[503]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[503]) );
smfulladder dfa398 (.DATA_A (LATCHED_PP[501]), .DATA_B (LATCHED_PP[502]), .DATA_C (LATCHED_PP[503]), .SAVE (INT_SUM[540]), .CARRY (INT_CARRY[440]) );
smffa dla595 (.D(SUMMAND[504]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[504]) );
smffa dla596 (.D(SUMMAND[505]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[505]) );
smffa dla597 (.D(SUMMAND[506]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[506]) );
smfulladder dfa399 (.DATA_A (LATCHED_PP[504]), .DATA_B (LATCHED_PP[505]), .DATA_C (LATCHED_PP[506]), .SAVE (INT_SUM[541]), .CARRY (INT_CARRY[441]) );
smffa dla598 (.D(SUMMAND[507]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[507]) );
assign INT_SUM[542] = LATCHED_PP[507];
smffa dla599 (.D(SUMMAND[508]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[508]) );
assign INT_SUM[543] = LATCHED_PP[508];
smfulladder dfa400 (.DATA_A (INT_SUM[539]), .DATA_B (INT_SUM[540]), .DATA_C (INT_SUM[541]), .SAVE (INT_SUM[544]), .CARRY (INT_CARRY[442]) );
smfulladder dfa401 (.DATA_A (INT_SUM[542]), .DATA_B (INT_SUM[543]), .DATA_C (INT_CARRY[428]), .SAVE (INT_SUM[545]), .CARRY (INT_CARRY[443]) );
smfulladder dfa402 (.DATA_A (INT_CARRY[429]), .DATA_B (INT_CARRY[430]), .DATA_C (INT_CARRY[431]), .SAVE (INT_SUM[546]), .CARRY (INT_CARRY[444]) );
smfulladder dfa403 (.DATA_A (INT_SUM[544]), .DATA_B (INT_SUM[545]), .DATA_C (INT_SUM[546]), .SAVE (INT_SUM[547]), .CARRY (INT_CARRY[445]) );
smfulladder dfa404 (.DATA_A (INT_CARRY[432]), .DATA_B (INT_CARRY[433]), .DATA_C (INT_CARRY[434]), .SAVE (INT_SUM[548]), .CARRY (INT_CARRY[446]) );
smfulladder dfa405 (.DATA_A (INT_SUM[547]), .DATA_B (INT_SUM[548]), .DATA_C (INT_CARRY[435]), .SAVE (INT_SUM[549]), .CARRY (INT_CARRY[447]) );
assign INT_SUM[550] = INT_CARRY[436];
smfulladder dfa406 (.DATA_A (INT_SUM[549]), .DATA_B (INT_SUM[550]), .DATA_C (INT_CARRY[437]), .SAVE (INT_SUM[551]), .CARRY (INT_CARRY[438]) );
smffb dla600 (.D(INT_SUM[551]), .clk(clk), .en_d2(en_d2), .Q(SUM[46]) );
smffb dla601 (.D(INT_CARRY[438]), .clk(clk), .en_d2(en_d2), .Q(CARRY[46]) );
smffa dla602 (.D(SUMMAND[509]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[509]) );
smffa dla603 (.D(SUMMAND[510]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[510]) );
smffa dla604 (.D(SUMMAND[511]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[511]) );
smfulladder dfa407 (.DATA_A (LATCHED_PP[509]), .DATA_B (LATCHED_PP[510]), .DATA_C (LATCHED_PP[511]), .SAVE (INT_SUM[552]), .CARRY (INT_CARRY[449]) );
smffa dla605 (.D(SUMMAND[512]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[512]) );
smffa dla606 (.D(SUMMAND[513]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[513]) );
smffa dla607 (.D(SUMMAND[514]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[514]) );
smfulladder dfa408 (.DATA_A (LATCHED_PP[512]), .DATA_B (LATCHED_PP[513]), .DATA_C (LATCHED_PP[514]), .SAVE (INT_SUM[553]), .CARRY (INT_CARRY[450]) );
smffa dla608 (.D(SUMMAND[515]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[515]) );
smffa dla609 (.D(SUMMAND[516]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[516]) );
smffa dla610 (.D(SUMMAND[517]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[517]) );
smfulladder dfa409 (.DATA_A (LATCHED_PP[515]), .DATA_B (LATCHED_PP[516]), .DATA_C (LATCHED_PP[517]), .SAVE (INT_SUM[554]), .CARRY (INT_CARRY[451]) );
smffa dla611 (.D(SUMMAND[518]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[518]) );
smffa dla612 (.D(SUMMAND[519]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[519]) );
smhalfadder dha41 (.DATA_A (LATCHED_PP[518]), .DATA_B (LATCHED_PP[519]), .SAVE (INT_SUM[555]), .CARRY (INT_CARRY[452]) );
smfulladder dfa410 (.DATA_A (INT_SUM[552]), .DATA_B (INT_SUM[553]), .DATA_C (INT_SUM[554]), .SAVE (INT_SUM[556]), .CARRY (INT_CARRY[453]) );
smfulladder dfa411 (.DATA_A (INT_SUM[555]), .DATA_B (INT_CARRY[439]), .DATA_C (INT_CARRY[440]), .SAVE (INT_SUM[557]), .CARRY (INT_CARRY[454]) );
assign INT_SUM[558] = INT_CARRY[441];
smfulladder dfa412 (.DATA_A (INT_SUM[556]), .DATA_B (INT_SUM[557]), .DATA_C (INT_SUM[558]), .SAVE (INT_SUM[559]), .CARRY (INT_CARRY[455]) );
smfulladder dfa413 (.DATA_A (INT_CARRY[442]), .DATA_B (INT_CARRY[443]), .DATA_C (INT_CARRY[444]), .SAVE (INT_SUM[560]), .CARRY (INT_CARRY[456]) );
smfulladder dfa414 (.DATA_A (INT_SUM[559]), .DATA_B (INT_SUM[560]), .DATA_C (INT_CARRY[445]), .SAVE (INT_SUM[561]), .CARRY (INT_CARRY[457]) );
assign INT_SUM[562] = INT_CARRY[446];
smfulladder dfa415 (.DATA_A (INT_SUM[561]), .DATA_B (INT_SUM[562]), .DATA_C (INT_CARRY[447]), .SAVE (INT_SUM[563]), .CARRY (INT_CARRY[448]) );
smffb dla613 (.D(INT_SUM[563]), .clk(clk), .en_d2(en_d2), .Q(SUM[47]) );
smffb dla614 (.D(INT_CARRY[448]), .clk(clk), .en_d2(en_d2), .Q(CARRY[47]) );
smffa dla615 (.D(SUMMAND[520]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[520]) );
smffa dla616 (.D(SUMMAND[521]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[521]) );
smffa dla617 (.D(SUMMAND[522]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[522]) );
smfulladder dfa416 (.DATA_A (LATCHED_PP[520]), .DATA_B (LATCHED_PP[521]), .DATA_C (LATCHED_PP[522]), .SAVE (INT_SUM[564]), .CARRY (INT_CARRY[459]) );
smffa dla618 (.D(SUMMAND[523]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[523]) );
smffa dla619 (.D(SUMMAND[524]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[524]) );
smffa dla620 (.D(SUMMAND[525]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[525]) );
smfulladder dfa417 (.DATA_A (LATCHED_PP[523]), .DATA_B (LATCHED_PP[524]), .DATA_C (LATCHED_PP[525]), .SAVE (INT_SUM[565]), .CARRY (INT_CARRY[460]) );
smffa dla621 (.D(SUMMAND[526]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[526]) );
smffa dla622 (.D(SUMMAND[527]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[527]) );
smffa dla623 (.D(SUMMAND[528]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[528]) );
smfulladder dfa418 (.DATA_A (LATCHED_PP[526]), .DATA_B (LATCHED_PP[527]), .DATA_C (LATCHED_PP[528]), .SAVE (INT_SUM[566]), .CARRY (INT_CARRY[461]) );
smffa dla624 (.D(SUMMAND[529]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[529]) );
assign INT_SUM[567] = LATCHED_PP[529];
smfulladder dfa419 (.DATA_A (INT_SUM[564]), .DATA_B (INT_SUM[565]), .DATA_C (INT_SUM[566]), .SAVE (INT_SUM[568]), .CARRY (INT_CARRY[462]) );
smfulladder dfa420 (.DATA_A (INT_SUM[567]), .DATA_B (INT_CARRY[449]), .DATA_C (INT_CARRY[450]), .SAVE (INT_SUM[569]), .CARRY (INT_CARRY[463]) );
assign INT_SUM[570] = INT_CARRY[451];
assign INT_SUM[571] = INT_CARRY[452];
smfulladder dfa421 (.DATA_A (INT_SUM[568]), .DATA_B (INT_SUM[569]), .DATA_C (INT_SUM[570]), .SAVE (INT_SUM[572]), .CARRY (INT_CARRY[464]) );
smfulladder dfa422 (.DATA_A (INT_SUM[571]), .DATA_B (INT_CARRY[453]), .DATA_C (INT_CARRY[454]), .SAVE (INT_SUM[573]), .CARRY (INT_CARRY[465]) );
smfulladder dfa423 (.DATA_A (INT_SUM[572]), .DATA_B (INT_SUM[573]), .DATA_C (INT_CARRY[455]), .SAVE (INT_SUM[574]), .CARRY (INT_CARRY[466]) );
assign INT_SUM[575] = INT_CARRY[456];
smfulladder dfa424 (.DATA_A (INT_SUM[574]), .DATA_B (INT_SUM[575]), .DATA_C (INT_CARRY[457]), .SAVE (INT_SUM[576]), .CARRY (INT_CARRY[458]) );
smffb dla625 (.D(INT_SUM[576]), .clk(clk), .en_d2(en_d2), .Q(SUM[48]) );
smffb dla626 (.D(INT_CARRY[458]), .clk(clk), .en_d2(en_d2), .Q(CARRY[48]) );
smffa dla627 (.D(SUMMAND[530]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[530]) );
smffa dla628 (.D(SUMMAND[531]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[531]) );
smffa dla629 (.D(SUMMAND[532]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[532]) );
smfulladder dfa425 (.DATA_A (LATCHED_PP[530]), .DATA_B (LATCHED_PP[531]), .DATA_C (LATCHED_PP[532]), .SAVE (INT_SUM[577]), .CARRY (INT_CARRY[468]) );
smffa dla630 (.D(SUMMAND[533]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[533]) );
smffa dla631 (.D(SUMMAND[534]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[534]) );
smffa dla632 (.D(SUMMAND[535]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[535]) );
smfulladder dfa426 (.DATA_A (LATCHED_PP[533]), .DATA_B (LATCHED_PP[534]), .DATA_C (LATCHED_PP[535]), .SAVE (INT_SUM[578]), .CARRY (INT_CARRY[469]) );
smffa dla633 (.D(SUMMAND[536]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[536]) );
smffa dla634 (.D(SUMMAND[537]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[537]) );
smffa dla635 (.D(SUMMAND[538]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[538]) );
smfulladder dfa427 (.DATA_A (LATCHED_PP[536]), .DATA_B (LATCHED_PP[537]), .DATA_C (LATCHED_PP[538]), .SAVE (INT_SUM[579]), .CARRY (INT_CARRY[470]) );
smffa dla636 (.D(SUMMAND[539]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[539]) );
assign INT_SUM[580] = LATCHED_PP[539];
smfulladder dfa428 (.DATA_A (INT_SUM[577]), .DATA_B (INT_SUM[578]), .DATA_C (INT_SUM[579]), .SAVE (INT_SUM[581]), .CARRY (INT_CARRY[471]) );
smfulladder dfa429 (.DATA_A (INT_SUM[580]), .DATA_B (INT_CARRY[459]), .DATA_C (INT_CARRY[460]), .SAVE (INT_SUM[582]), .CARRY (INT_CARRY[472]) );
assign INT_SUM[583] = INT_CARRY[461];
smfulladder dfa430 (.DATA_A (INT_SUM[581]), .DATA_B (INT_SUM[582]), .DATA_C (INT_SUM[583]), .SAVE (INT_SUM[584]), .CARRY (INT_CARRY[473]) );
smhalfadder dha42 (.DATA_A (INT_CARRY[462]), .DATA_B (INT_CARRY[463]), .SAVE (INT_SUM[585]), .CARRY (INT_CARRY[474]) );
smfulladder dfa431 (.DATA_A (INT_SUM[584]), .DATA_B (INT_SUM[585]), .DATA_C (INT_CARRY[464]), .SAVE (INT_SUM[586]), .CARRY (INT_CARRY[475]) );
assign INT_SUM[587] = INT_CARRY[465];
smfulladder dfa432 (.DATA_A (INT_SUM[586]), .DATA_B (INT_SUM[587]), .DATA_C (INT_CARRY[466]), .SAVE (INT_SUM[588]), .CARRY (INT_CARRY[467]) );
smffb dla637 (.D(INT_SUM[588]), .clk(clk), .en_d2(en_d2), .Q(SUM[49]) );
smffb dla638 (.D(INT_CARRY[467]), .clk(clk), .en_d2(en_d2), .Q(CARRY[49]) );
smffa dla639 (.D(SUMMAND[540]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[540]) );
smffa dla640 (.D(SUMMAND[541]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[541]) );
smffa dla641 (.D(SUMMAND[542]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[542]) );
smfulladder dfa433 (.DATA_A (LATCHED_PP[540]), .DATA_B (LATCHED_PP[541]), .DATA_C (LATCHED_PP[542]), .SAVE (INT_SUM[589]), .CARRY (INT_CARRY[477]) );
smffa dla642 (.D(SUMMAND[543]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[543]) );
smffa dla643 (.D(SUMMAND[544]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[544]) );
smffa dla644 (.D(SUMMAND[545]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[545]) );
smfulladder dfa434 (.DATA_A (LATCHED_PP[543]), .DATA_B (LATCHED_PP[544]), .DATA_C (LATCHED_PP[545]), .SAVE (INT_SUM[590]), .CARRY (INT_CARRY[478]) );
smffa dla645 (.D(SUMMAND[546]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[546]) );
smffa dla646 (.D(SUMMAND[547]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[547]) );
smffa dla647 (.D(SUMMAND[548]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[548]) );
smfulladder dfa435 (.DATA_A (LATCHED_PP[546]), .DATA_B (LATCHED_PP[547]), .DATA_C (LATCHED_PP[548]), .SAVE (INT_SUM[591]), .CARRY (INT_CARRY[479]) );
smfulladder dfa436 (.DATA_A (INT_SUM[589]), .DATA_B (INT_SUM[590]), .DATA_C (INT_SUM[591]), .SAVE (INT_SUM[592]), .CARRY (INT_CARRY[480]) );
smfulladder dfa437 (.DATA_A (INT_CARRY[468]), .DATA_B (INT_CARRY[469]), .DATA_C (INT_CARRY[470]), .SAVE (INT_SUM[593]), .CARRY (INT_CARRY[481]) );
smfulladder dfa438 (.DATA_A (INT_SUM[592]), .DATA_B (INT_SUM[593]), .DATA_C (INT_CARRY[471]), .SAVE (INT_SUM[594]), .CARRY (INT_CARRY[482]) );
assign INT_SUM[595] = INT_CARRY[472];
smfulladder dfa439 (.DATA_A (INT_SUM[594]), .DATA_B (INT_SUM[595]), .DATA_C (INT_CARRY[473]), .SAVE (INT_SUM[596]), .CARRY (INT_CARRY[483]) );
assign INT_SUM[597] = INT_CARRY[474];
smfulladder dfa440 (.DATA_A (INT_SUM[596]), .DATA_B (INT_SUM[597]), .DATA_C (INT_CARRY[475]), .SAVE (INT_SUM[598]), .CARRY (INT_CARRY[476]) );
smffb dla648 (.D(INT_SUM[598]), .clk(clk), .en_d2(en_d2), .Q(SUM[50]) );
smffb dla649 (.D(INT_CARRY[476]), .clk(clk), .en_d2(en_d2), .Q(CARRY[50]) );
smffa dla650 (.D(SUMMAND[549]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[549]) );
smffa dla651 (.D(SUMMAND[550]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[550]) );
smffa dla652 (.D(SUMMAND[551]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[551]) );
smfulladder dfa441 (.DATA_A (LATCHED_PP[549]), .DATA_B (LATCHED_PP[550]), .DATA_C (LATCHED_PP[551]), .SAVE (INT_SUM[599]), .CARRY (INT_CARRY[485]) );
smffa dla653 (.D(SUMMAND[552]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[552]) );
smffa dla654 (.D(SUMMAND[553]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[553]) );
smffa dla655 (.D(SUMMAND[554]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[554]) );
smfulladder dfa442 (.DATA_A (LATCHED_PP[552]), .DATA_B (LATCHED_PP[553]), .DATA_C (LATCHED_PP[554]), .SAVE (INT_SUM[600]), .CARRY (INT_CARRY[486]) );
smffa dla656 (.D(SUMMAND[555]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[555]) );
smffa dla657 (.D(SUMMAND[556]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[556]) );
smffa dla658 (.D(SUMMAND[557]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[557]) );
smfulladder dfa443 (.DATA_A (LATCHED_PP[555]), .DATA_B (LATCHED_PP[556]), .DATA_C (LATCHED_PP[557]), .SAVE (INT_SUM[601]), .CARRY (INT_CARRY[487]) );
smfulladder dfa444 (.DATA_A (INT_SUM[599]), .DATA_B (INT_SUM[600]), .DATA_C (INT_SUM[601]), .SAVE (INT_SUM[602]), .CARRY (INT_CARRY[488]) );
smfulladder dfa445 (.DATA_A (INT_CARRY[477]), .DATA_B (INT_CARRY[478]), .DATA_C (INT_CARRY[479]), .SAVE (INT_SUM[603]), .CARRY (INT_CARRY[489]) );
smfulladder dfa446 (.DATA_A (INT_SUM[602]), .DATA_B (INT_SUM[603]), .DATA_C (INT_CARRY[480]), .SAVE (INT_SUM[604]), .CARRY (INT_CARRY[490]) );
assign INT_SUM[605] = INT_CARRY[481];
smfulladder dfa447 (.DATA_A (INT_SUM[604]), .DATA_B (INT_SUM[605]), .DATA_C (INT_CARRY[482]), .SAVE (INT_SUM[606]), .CARRY (INT_CARRY[491]) );
smhalfadder dha43 (.DATA_A (INT_SUM[606]), .DATA_B (INT_CARRY[483]), .SAVE (INT_SUM[607]), .CARRY (INT_CARRY[484]) );
smffb dla659 (.D(INT_SUM[607]), .clk(clk), .en_d2(en_d2), .Q(SUM[51]) );
smffb dla660 (.D(INT_CARRY[484]), .clk(clk), .en_d2(en_d2), .Q(CARRY[51]) );
smffa dla661 (.D(SUMMAND[558]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[558]) );
smffa dla662 (.D(SUMMAND[559]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[559]) );
smffa dla663 (.D(SUMMAND[560]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[560]) );
smfulladder dfa448 (.DATA_A (LATCHED_PP[558]), .DATA_B (LATCHED_PP[559]), .DATA_C (LATCHED_PP[560]), .SAVE (INT_SUM[608]), .CARRY (INT_CARRY[493]) );
smffa dla664 (.D(SUMMAND[561]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[561]) );
smffa dla665 (.D(SUMMAND[562]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[562]) );
smffa dla666 (.D(SUMMAND[563]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[563]) );
smfulladder dfa449 (.DATA_A (LATCHED_PP[561]), .DATA_B (LATCHED_PP[562]), .DATA_C (LATCHED_PP[563]), .SAVE (INT_SUM[609]), .CARRY (INT_CARRY[494]) );
smffa dla667 (.D(SUMMAND[564]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[564]) );
smffa dla668 (.D(SUMMAND[565]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[565]) );
smfulladder dfa450 (.DATA_A (LATCHED_PP[564]), .DATA_B (LATCHED_PP[565]), .DATA_C (INT_CARRY[485]), .SAVE (INT_SUM[610]), .CARRY (INT_CARRY[495]) );
smhalfadder dha44 (.DATA_A (INT_CARRY[486]), .DATA_B (INT_CARRY[487]), .SAVE (INT_SUM[611]), .CARRY (INT_CARRY[496]) );
smfulladder dfa451 (.DATA_A (INT_SUM[608]), .DATA_B (INT_SUM[609]), .DATA_C (INT_SUM[610]), .SAVE (INT_SUM[612]), .CARRY (INT_CARRY[497]) );
smfulladder dfa452 (.DATA_A (INT_SUM[611]), .DATA_B (INT_CARRY[488]), .DATA_C (INT_CARRY[489]), .SAVE (INT_SUM[613]), .CARRY (INT_CARRY[498]) );
smfulladder dfa453 (.DATA_A (INT_SUM[612]), .DATA_B (INT_SUM[613]), .DATA_C (INT_CARRY[490]), .SAVE (INT_SUM[614]), .CARRY (INT_CARRY[499]) );
smhalfadder dha45 (.DATA_A (INT_SUM[614]), .DATA_B (INT_CARRY[491]), .SAVE (INT_SUM[615]), .CARRY (INT_CARRY[492]) );
smffb dla669 (.D(INT_SUM[615]), .clk(clk), .en_d2(en_d2), .Q(SUM[52]) );
smffb dla670 (.D(INT_CARRY[492]), .clk(clk), .en_d2(en_d2), .Q(CARRY[52]) );
smffa dla671 (.D(SUMMAND[566]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[566]) );
smffa dla672 (.D(SUMMAND[567]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[567]) );
smffa dla673 (.D(SUMMAND[568]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[568]) );
smfulladder dfa454 (.DATA_A (LATCHED_PP[566]), .DATA_B (LATCHED_PP[567]), .DATA_C (LATCHED_PP[568]), .SAVE (INT_SUM[616]), .CARRY (INT_CARRY[501]) );
smffa dla674 (.D(SUMMAND[569]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[569]) );
smffa dla675 (.D(SUMMAND[570]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[570]) );
smffa dla676 (.D(SUMMAND[571]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[571]) );
smfulladder dfa455 (.DATA_A (LATCHED_PP[569]), .DATA_B (LATCHED_PP[570]), .DATA_C (LATCHED_PP[571]), .SAVE (INT_SUM[617]), .CARRY (INT_CARRY[502]) );
smffa dla677 (.D(SUMMAND[572]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[572]) );
assign INT_SUM[618] = LATCHED_PP[572];
smffa dla678 (.D(SUMMAND[573]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[573]) );
assign INT_SUM[619] = LATCHED_PP[573];
smfulladder dfa456 (.DATA_A (INT_SUM[616]), .DATA_B (INT_SUM[617]), .DATA_C (INT_SUM[618]), .SAVE (INT_SUM[620]), .CARRY (INT_CARRY[503]) );
assign INT_SUM[621] = INT_SUM[619];
smfulladder dfa457 (.DATA_A (INT_SUM[620]), .DATA_B (INT_SUM[621]), .DATA_C (INT_CARRY[493]), .SAVE (INT_SUM[622]), .CARRY (INT_CARRY[504]) );
smfulladder dfa458 (.DATA_A (INT_CARRY[494]), .DATA_B (INT_CARRY[495]), .DATA_C (INT_CARRY[496]), .SAVE (INT_SUM[623]), .CARRY (INT_CARRY[505]) );
smfulladder dfa459 (.DATA_A (INT_SUM[622]), .DATA_B (INT_SUM[623]), .DATA_C (INT_CARRY[497]), .SAVE (INT_SUM[624]), .CARRY (INT_CARRY[506]) );
assign INT_SUM[625] = INT_CARRY[498];
smfulladder dfa460 (.DATA_A (INT_SUM[624]), .DATA_B (INT_SUM[625]), .DATA_C (INT_CARRY[499]), .SAVE (INT_SUM[626]), .CARRY (INT_CARRY[500]) );
smffb dla679 (.D(INT_SUM[626]), .clk(clk), .en_d2(en_d2), .Q(SUM[53]) );
smffb dla680 (.D(INT_CARRY[500]), .clk(clk), .en_d2(en_d2), .Q(CARRY[53]) );
smffa dla681 (.D(SUMMAND[574]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[574]) );
smffa dla682 (.D(SUMMAND[575]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[575]) );
smffa dla683 (.D(SUMMAND[576]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[576]) );
smfulladder dfa461 (.DATA_A (LATCHED_PP[574]), .DATA_B (LATCHED_PP[575]), .DATA_C (LATCHED_PP[576]), .SAVE (INT_SUM[627]), .CARRY (INT_CARRY[508]) );
smffa dla684 (.D(SUMMAND[577]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[577]) );
smffa dla685 (.D(SUMMAND[578]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[578]) );
smffa dla686 (.D(SUMMAND[579]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[579]) );
smfulladder dfa462 (.DATA_A (LATCHED_PP[577]), .DATA_B (LATCHED_PP[578]), .DATA_C (LATCHED_PP[579]), .SAVE (INT_SUM[628]), .CARRY (INT_CARRY[509]) );
smffa dla687 (.D(SUMMAND[580]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[580]) );
smfulladder dfa463 (.DATA_A (LATCHED_PP[580]), .DATA_B (INT_CARRY[501]), .DATA_C (INT_CARRY[502]), .SAVE (INT_SUM[629]), .CARRY (INT_CARRY[510]) );
smfulladder dfa464 (.DATA_A (INT_SUM[627]), .DATA_B (INT_SUM[628]), .DATA_C (INT_SUM[629]), .SAVE (INT_SUM[630]), .CARRY (INT_CARRY[511]) );
assign INT_SUM[631] = INT_CARRY[503];
smfulladder dfa465 (.DATA_A (INT_SUM[630]), .DATA_B (INT_SUM[631]), .DATA_C (INT_CARRY[504]), .SAVE (INT_SUM[632]), .CARRY (INT_CARRY[512]) );
assign INT_SUM[633] = INT_CARRY[505];
smfulladder dfa466 (.DATA_A (INT_SUM[632]), .DATA_B (INT_SUM[633]), .DATA_C (INT_CARRY[506]), .SAVE (INT_SUM[634]), .CARRY (INT_CARRY[507]) );
smffb dla688 (.D(INT_SUM[634]), .clk(clk), .en_d2(en_d2), .Q(SUM[54]) );
smffb dla689 (.D(INT_CARRY[507]), .clk(clk), .en_d2(en_d2), .Q(CARRY[54]) );
smffa dla690 (.D(SUMMAND[581]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[581]) );
smffa dla691 (.D(SUMMAND[582]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[582]) );
smffa dla692 (.D(SUMMAND[583]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[583]) );
smfulladder dfa467 (.DATA_A (LATCHED_PP[581]), .DATA_B (LATCHED_PP[582]), .DATA_C (LATCHED_PP[583]), .SAVE (INT_SUM[635]), .CARRY (INT_CARRY[514]) );
smffa dla693 (.D(SUMMAND[584]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[584]) );
smffa dla694 (.D(SUMMAND[585]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[585]) );
smffa dla695 (.D(SUMMAND[586]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[586]) );
smfulladder dfa468 (.DATA_A (LATCHED_PP[584]), .DATA_B (LATCHED_PP[585]), .DATA_C (LATCHED_PP[586]), .SAVE (INT_SUM[636]), .CARRY (INT_CARRY[515]) );
smffa dla696 (.D(SUMMAND[587]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[587]) );
assign INT_SUM[637] = LATCHED_PP[587];
smfulladder dfa469 (.DATA_A (INT_SUM[635]), .DATA_B (INT_SUM[636]), .DATA_C (INT_SUM[637]), .SAVE (INT_SUM[638]), .CARRY (INT_CARRY[516]) );
smfulladder dfa470 (.DATA_A (INT_CARRY[508]), .DATA_B (INT_CARRY[509]), .DATA_C (INT_CARRY[510]), .SAVE (INT_SUM[639]), .CARRY (INT_CARRY[517]) );
smfulladder dfa471 (.DATA_A (INT_SUM[638]), .DATA_B (INT_SUM[639]), .DATA_C (INT_CARRY[511]), .SAVE (INT_SUM[640]), .CARRY (INT_CARRY[518]) );
smhalfadder dha46 (.DATA_A (INT_SUM[640]), .DATA_B (INT_CARRY[512]), .SAVE (INT_SUM[641]), .CARRY (INT_CARRY[513]) );
smffb dla697 (.D(INT_SUM[641]), .clk(clk), .en_d2(en_d2), .Q(SUM[55]) );
smffb dla698 (.D(INT_CARRY[513]), .clk(clk), .en_d2(en_d2), .Q(CARRY[55]) );
smffa dla699 (.D(SUMMAND[588]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[588]) );
smffa dla700 (.D(SUMMAND[589]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[589]) );
smffa dla701 (.D(SUMMAND[590]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[590]) );
smfulladder dfa472 (.DATA_A (LATCHED_PP[588]), .DATA_B (LATCHED_PP[589]), .DATA_C (LATCHED_PP[590]), .SAVE (INT_SUM[642]), .CARRY (INT_CARRY[520]) );
smffa dla702 (.D(SUMMAND[591]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[591]) );
smffa dla703 (.D(SUMMAND[592]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[592]) );
smffa dla704 (.D(SUMMAND[593]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[593]) );
smfulladder dfa473 (.DATA_A (LATCHED_PP[591]), .DATA_B (LATCHED_PP[592]), .DATA_C (LATCHED_PP[593]), .SAVE (INT_SUM[643]), .CARRY (INT_CARRY[521]) );
smfulladder dfa474 (.DATA_A (INT_SUM[642]), .DATA_B (INT_SUM[643]), .DATA_C (INT_CARRY[514]), .SAVE (INT_SUM[644]), .CARRY (INT_CARRY[522]) );
assign INT_SUM[645] = INT_CARRY[515];
smfulladder dfa475 (.DATA_A (INT_SUM[644]), .DATA_B (INT_SUM[645]), .DATA_C (INT_CARRY[516]), .SAVE (INT_SUM[646]), .CARRY (INT_CARRY[523]) );
assign INT_SUM[647] = INT_CARRY[517];
smfulladder dfa476 (.DATA_A (INT_SUM[646]), .DATA_B (INT_SUM[647]), .DATA_C (INT_CARRY[518]), .SAVE (INT_SUM[648]), .CARRY (INT_CARRY[519]) );
smffb dla705 (.D(INT_SUM[648]), .clk(clk), .en_d2(en_d2), .Q(SUM[56]) );
smffb dla706 (.D(INT_CARRY[519]), .clk(clk), .en_d2(en_d2), .Q(CARRY[56]) );
smffa dla707 (.D(SUMMAND[594]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[594]) );
smffa dla708 (.D(SUMMAND[595]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[595]) );
smffa dla709 (.D(SUMMAND[596]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[596]) );
smfulladder dfa477 (.DATA_A (LATCHED_PP[594]), .DATA_B (LATCHED_PP[595]), .DATA_C (LATCHED_PP[596]), .SAVE (INT_SUM[649]), .CARRY (INT_CARRY[525]) );
smffa dla710 (.D(SUMMAND[597]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[597]) );
smffa dla711 (.D(SUMMAND[598]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[598]) );
smffa dla712 (.D(SUMMAND[599]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[599]) );
smfulladder dfa478 (.DATA_A (LATCHED_PP[597]), .DATA_B (LATCHED_PP[598]), .DATA_C (LATCHED_PP[599]), .SAVE (INT_SUM[650]), .CARRY (INT_CARRY[526]) );
smfulladder dfa479 (.DATA_A (INT_SUM[649]), .DATA_B (INT_SUM[650]), .DATA_C (INT_CARRY[520]), .SAVE (INT_SUM[651]), .CARRY (INT_CARRY[527]) );
assign INT_SUM[652] = INT_CARRY[521];
smfulladder dfa480 (.DATA_A (INT_SUM[651]), .DATA_B (INT_SUM[652]), .DATA_C (INT_CARRY[522]), .SAVE (INT_SUM[653]), .CARRY (INT_CARRY[528]) );
smhalfadder dha47 (.DATA_A (INT_SUM[653]), .DATA_B (INT_CARRY[523]), .SAVE (INT_SUM[654]), .CARRY (INT_CARRY[524]) );
smffb dla713 (.D(INT_SUM[654]), .clk(clk), .en_d2(en_d2), .Q(SUM[57]) );
smffb dla714 (.D(INT_CARRY[524]), .clk(clk), .en_d2(en_d2), .Q(CARRY[57]) );
smffa dla715 (.D(SUMMAND[600]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[600]) );
smffa dla716 (.D(SUMMAND[601]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[601]) );
smffa dla717 (.D(SUMMAND[602]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[602]) );
smfulladder dfa481 (.DATA_A (LATCHED_PP[600]), .DATA_B (LATCHED_PP[601]), .DATA_C (LATCHED_PP[602]), .SAVE (INT_SUM[655]), .CARRY (INT_CARRY[530]) );
smffa dla718 (.D(SUMMAND[603]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[603]) );
smffa dla719 (.D(SUMMAND[604]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[604]) );
smhalfadder dha48 (.DATA_A (LATCHED_PP[603]), .DATA_B (LATCHED_PP[604]), .SAVE (INT_SUM[656]), .CARRY (INT_CARRY[531]) );
smfulladder dfa482 (.DATA_A (INT_SUM[655]), .DATA_B (INT_SUM[656]), .DATA_C (INT_CARRY[525]), .SAVE (INT_SUM[657]), .CARRY (INT_CARRY[532]) );
assign INT_SUM[658] = INT_CARRY[526];
smfulladder dfa483 (.DATA_A (INT_SUM[657]), .DATA_B (INT_SUM[658]), .DATA_C (INT_CARRY[527]), .SAVE (INT_SUM[659]), .CARRY (INT_CARRY[533]) );
smhalfadder dha49 (.DATA_A (INT_SUM[659]), .DATA_B (INT_CARRY[528]), .SAVE (INT_SUM[660]), .CARRY (INT_CARRY[529]) );
smffb dla720 (.D(INT_SUM[660]), .clk(clk), .en_d2(en_d2), .Q(SUM[58]) );
smffb dla721 (.D(INT_CARRY[529]), .clk(clk), .en_d2(en_d2), .Q(CARRY[58]) );
smffa dla722 (.D(SUMMAND[605]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[605]) );
smffa dla723 (.D(SUMMAND[606]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[606]) );
smffa dla724 (.D(SUMMAND[607]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[607]) );
smfulladder dfa484 (.DATA_A (LATCHED_PP[605]), .DATA_B (LATCHED_PP[606]), .DATA_C (LATCHED_PP[607]), .SAVE (INT_SUM[661]), .CARRY (INT_CARRY[535]) );
smffa dla725 (.D(SUMMAND[608]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[608]) );
smffa dla726 (.D(SUMMAND[609]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[609]) );
smhalfadder dha50 (.DATA_A (LATCHED_PP[608]), .DATA_B (LATCHED_PP[609]), .SAVE (INT_SUM[662]), .CARRY (INT_CARRY[536]) );
smfulladder dfa485 (.DATA_A (INT_SUM[661]), .DATA_B (INT_SUM[662]), .DATA_C (INT_CARRY[530]), .SAVE (INT_SUM[663]), .CARRY (INT_CARRY[537]) );
assign INT_SUM[664] = INT_CARRY[531];
smfulladder dfa486 (.DATA_A (INT_SUM[663]), .DATA_B (INT_SUM[664]), .DATA_C (INT_CARRY[532]), .SAVE (INT_SUM[665]), .CARRY (INT_CARRY[538]) );
smhalfadder dha51 (.DATA_A (INT_SUM[665]), .DATA_B (INT_CARRY[533]), .SAVE (INT_SUM[666]), .CARRY (INT_CARRY[534]) );
smffb dla727 (.D(INT_SUM[666]), .clk(clk), .en_d2(en_d2), .Q(SUM[59]) );
smffb dla728 (.D(INT_CARRY[534]), .clk(clk), .en_d2(en_d2), .Q(CARRY[59]) );
smffa dla729 (.D(SUMMAND[610]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[610]) );
smffa dla730 (.D(SUMMAND[611]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[611]) );
smffa dla731 (.D(SUMMAND[612]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[612]) );
smfulladder dfa487 (.DATA_A (LATCHED_PP[610]), .DATA_B (LATCHED_PP[611]), .DATA_C (LATCHED_PP[612]), .SAVE (INT_SUM[667]), .CARRY (INT_CARRY[540]) );
smffa dla732 (.D(SUMMAND[613]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[613]) );
smfulladder dfa488 (.DATA_A (LATCHED_PP[613]), .DATA_B (INT_CARRY[535]), .DATA_C (INT_CARRY[536]), .SAVE (INT_SUM[668]), .CARRY (INT_CARRY[541]) );
smfulladder dfa489 (.DATA_A (INT_SUM[667]), .DATA_B (INT_SUM[668]), .DATA_C (INT_CARRY[537]), .SAVE (INT_SUM[669]), .CARRY (INT_CARRY[542]) );
smhalfadder dha52 (.DATA_A (INT_SUM[669]), .DATA_B (INT_CARRY[538]), .SAVE (INT_SUM[670]), .CARRY (INT_CARRY[539]) );
smffb dla733 (.D(INT_SUM[670]), .clk(clk), .en_d2(en_d2), .Q(SUM[60]) );
smffb dla734 (.D(INT_CARRY[539]), .clk(clk), .en_d2(en_d2), .Q(CARRY[60]) );
smffa dla735 (.D(SUMMAND[614]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[614]) );
smffa dla736 (.D(SUMMAND[615]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[615]) );
smffa dla737 (.D(SUMMAND[616]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[616]) );
smfulladder dfa490 (.DATA_A (LATCHED_PP[614]), .DATA_B (LATCHED_PP[615]), .DATA_C (LATCHED_PP[616]), .SAVE (INT_SUM[671]), .CARRY (INT_CARRY[544]) );
smffa dla738 (.D(SUMMAND[617]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[617]) );
assign INT_SUM[672] = LATCHED_PP[617];
smfulladder dfa491 (.DATA_A (INT_SUM[671]), .DATA_B (INT_SUM[672]), .DATA_C (INT_CARRY[540]), .SAVE (INT_SUM[673]), .CARRY (INT_CARRY[545]) );
assign INT_SUM[674] = INT_CARRY[541];
smfulladder dfa492 (.DATA_A (INT_SUM[673]), .DATA_B (INT_SUM[674]), .DATA_C (INT_CARRY[542]), .SAVE (INT_SUM[675]), .CARRY (INT_CARRY[543]) );
smffb dla739 (.D(INT_SUM[675]), .clk(clk), .en_d2(en_d2), .Q(SUM[61]) );
smffb dla740 (.D(INT_CARRY[543]), .clk(clk), .en_d2(en_d2), .Q(CARRY[61]) );
smffa dla741 (.D(SUMMAND[618]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[618]) );
smffa dla742 (.D(SUMMAND[619]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[619]) );
smffa dla743 (.D(SUMMAND[620]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[620]) );
smfulladder dfa493 (.DATA_A (LATCHED_PP[618]), .DATA_B (LATCHED_PP[619]), .DATA_C (LATCHED_PP[620]), .SAVE (INT_SUM[676]), .CARRY (INT_CARRY[547]) );
assign INT_SUM[677] = INT_SUM[676];
assign INT_SUM[678] = INT_CARRY[544];
smfulladder dfa494 (.DATA_A (INT_SUM[677]), .DATA_B (INT_SUM[678]), .DATA_C (INT_CARRY[545]), .SAVE (INT_SUM[679]), .CARRY (INT_CARRY[546]) );
smffb dla744 (.D(INT_SUM[679]), .clk(clk), .en_d2(en_d2), .Q(SUM[62]) );
smffb dla745 (.D(INT_CARRY[546]), .clk(clk), .en_d2(en_d2), .Q(CARRY[62]) );
smffa dla746 (.D(SUMMAND[621]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[621]) );
smffa dla747 (.D(SUMMAND[622]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[622]) );
smffa dla748 (.D(SUMMAND[623]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[623]) );
smfulladder dfa495 (.DATA_A (LATCHED_PP[621]), .DATA_B (LATCHED_PP[622]), .DATA_C (LATCHED_PP[623]), .SAVE (INT_SUM[680]), .CARRY (INT_CARRY[549]) );
assign INT_SUM[681] = INT_CARRY[547];
smhalfadder dha53 (.DATA_A (INT_SUM[680]), .DATA_B (INT_SUM[681]), .SAVE (INT_SUM[682]), .CARRY (INT_CARRY[548]) );
smffb dla749 (.D(INT_SUM[682]), .clk(clk), .en_d2(en_d2), .Q(SUM[63]) );
smffb dla750 (.D(INT_CARRY[548]), .clk(clk), .en_d2(en_d2), .Q(CARRY[63]) );
smffa dla751 (.D(SUMMAND[624]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[624]) );
assign INT_SUM[683] = LATCHED_PP[624];
smffa dla752 (.D(SUMMAND[625]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[625]) );
assign INT_SUM[684] = LATCHED_PP[625];
smfulladder dfa496 (.DATA_A (INT_SUM[683]), .DATA_B (INT_SUM[684]), .DATA_C (INT_CARRY[549]), .SAVE (INT_SUM[685]), .CARRY (INT_CARRY[550]) );
smffb dla753 (.D(INT_SUM[685]), .clk(clk), .en_d2(en_d2), .Q(SUM[64]) );
smffb dla754 (.D(INT_CARRY[550]), .clk(clk), .en_d2(en_d2), .Q(CARRY[64]) );
smffa dla755 (.D(SUMMAND[626]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[626]) );
smffa dla756 (.D(SUMMAND[627]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[627]) );
smhalfadder dha54 (.DATA_A (LATCHED_PP[626]), .DATA_B (LATCHED_PP[627]), .SAVE (INT_SUM[686]), .CARRY (INT_CARRY[551]) );
smffb dla757 (.D(INT_SUM[686]), .clk(clk), .en_d2(en_d2), .Q(SUM[65]) );
smffb dla758 (.D(INT_CARRY[551]), .clk(clk), .en_d2(en_d2), .Q(CARRY[65]) );
smffa dla759 (.D(SUMMAND[628]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[628]) );
assign INT_SUM[687] = LATCHED_PP[628];
smffb dla760 (.D(INT_SUM[687]), .clk(clk), .en_d2(en_d2), .Q(SUM[66]) );
endmodule
module smprestage_128 ( A, B, CIN, POUT, GOUT );
input [63:0] A;
input [63:0] B;
input CIN;
output [63:0] POUT;
output [63:0] GOUT;
smblock0 d10 (A[0], B[0], POUT[0], GOUT[1] );
smblock0 d11 (A[1], B[1], POUT[1], GOUT[2] );
smblock0 d12 (A[2], B[2], POUT[2], GOUT[3] );
smblock0 d13 (A[3], B[3], POUT[3], GOUT[4] );
smblock0 d14 (A[4], B[4], POUT[4], GOUT[5] );
smblock0 d15 (A[5], B[5], POUT[5], GOUT[6] );
smblock0 d16 (A[6], B[6], POUT[6], GOUT[7] );
smblock0 d17 (A[7], B[7], POUT[7], GOUT[8] );
smblock0 d18 (A[8], B[8], POUT[8], GOUT[9] );
smblock0 d19 (A[9], B[9], POUT[9], GOUT[10] );
smblock0 d110 (A[10], B[10], POUT[10], GOUT[11] );
smblock0 d111 (A[11], B[11], POUT[11], GOUT[12] );
smblock0 d112 (A[12], B[12], POUT[12], GOUT[13] );
smblock0 d113 (A[13], B[13], POUT[13], GOUT[14] );
smblock0 d114 (A[14], B[14], POUT[14], GOUT[15] );
smblock0 d115 (A[15], B[15], POUT[15], GOUT[16] );
smblock0 d116 (A[16], B[16], POUT[16], GOUT[17] );
smblock0 d117 (A[17], B[17], POUT[17], GOUT[18] );
smblock0 d118 (A[18], B[18], POUT[18], GOUT[19] );
smblock0 d119 (A[19], B[19], POUT[19], GOUT[20] );
smblock0 d120 (A[20], B[20], POUT[20], GOUT[21] );
smblock0 d121 (A[21], B[21], POUT[21], GOUT[22] );
smblock0 d122 (A[22], B[22], POUT[22], GOUT[23] );
smblock0 d123 (A[23], B[23], POUT[23], GOUT[24] );
smblock0 d124 (A[24], B[24], POUT[24], GOUT[25] );
smblock0 d125 (A[25], B[25], POUT[25], GOUT[26] );
smblock0 d126 (A[26], B[26], POUT[26], GOUT[27] );
smblock0 d127 (A[27], B[27], POUT[27], GOUT[28] );
smblock0 d128 (A[28], B[28], POUT[28], GOUT[29] );
smblock0 d129 (A[29], B[29], POUT[29], GOUT[30] );
smblock0 d130 (A[30], B[30], POUT[30], GOUT[31] );
smblock0 d131 (A[31], B[31], POUT[31], GOUT[32] );
smblock0 d132 (A[32], B[32], POUT[32], GOUT[33] );
smblock0 d133 (A[33], B[33], POUT[33], GOUT[34] );
smblock0 d134 (A[34], B[34], POUT[34], GOUT[35] );
smblock0 d135 (A[35], B[35], POUT[35], GOUT[36] );
smblock0 d136 (A[36], B[36], POUT[36], GOUT[37] );
smblock0 d137 (A[37], B[37], POUT[37], GOUT[38] );
smblock0 d138 (A[38], B[38], POUT[38], GOUT[39] );
smblock0 d139 (A[39], B[39], POUT[39], GOUT[40] );
smblock0 d140 (A[40], B[40], POUT[40], GOUT[41] );
smblock0 d141 (A[41], B[41], POUT[41], GOUT[42] );
smblock0 d142 (A[42], B[42], POUT[42], GOUT[43] );
smblock0 d143 (A[43], B[43], POUT[43], GOUT[44] );
smblock0 d144 (A[44], B[44], POUT[44], GOUT[45] );
smblock0 d145 (A[45], B[45], POUT[45], GOUT[46] );
smblock0 d146 (A[46], B[46], POUT[46], GOUT[47] );
smblock0 d147 (A[47], B[47], POUT[47], GOUT[48] );
smblock0 d148 (A[48], B[48], POUT[48], GOUT[49] );
smblock0 d149 (A[49], B[49], POUT[49], GOUT[50] );
smblock0 d150 (A[50], B[50], POUT[50], GOUT[51] );
smblock0 d151 (A[51], B[51], POUT[51], GOUT[52] );
smblock0 d152 (A[52], B[52], POUT[52], GOUT[53] );
smblock0 d153 (A[53], B[53], POUT[53], GOUT[54] );
smblock0 d154 (A[54], B[54], POUT[54], GOUT[55] );
smblock0 d155 (A[55], B[55], POUT[55], GOUT[56] );
smblock0 d156 (A[56], B[56], POUT[56], GOUT[57] );
smblock0 d157 (A[57], B[57], POUT[57], GOUT[58] );
smblock0 d158 (A[58], B[58], POUT[58], GOUT[59] );
smblock0 d159 (A[59], B[59], POUT[59], GOUT[60] );
smblock0 d160 (A[60], B[60], POUT[60], GOUT[61] );
smblock0 d161 (A[61], B[61], POUT[61], GOUT[62] );
smblock0 d162 (A[62], B[62], POUT[62], GOUT[63] );
sminvblock d2 (CIN, GOUT[0] );
endmodule
module smdblc_0_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
smblock1a d21 (PIN[0], GIN[0], GIN[1], GOUT[1] );
smblock1 d32 (PIN[0], PIN[1], GIN[1], GIN[2], POUT[0], GOUT[2] );
smblock1 d33 (PIN[1], PIN[2], GIN[2], GIN[3], POUT[1], GOUT[3] );
smblock1 d34 (PIN[2], PIN[3], GIN[3], GIN[4], POUT[2], GOUT[4] );
smblock1 d35 (PIN[3], PIN[4], GIN[4], GIN[5], POUT[3], GOUT[5] );
smblock1 d36 (PIN[4], PIN[5], GIN[5], GIN[6], POUT[4], GOUT[6] );
smblock1 d37 (PIN[5], PIN[6], GIN[6], GIN[7], POUT[5], GOUT[7] );
smblock1 d38 (PIN[6], PIN[7], GIN[7], GIN[8], POUT[6], GOUT[8] );
smblock1 d39 (PIN[7], PIN[8], GIN[8], GIN[9], POUT[7], GOUT[9] );
smblock1 d310 (PIN[8], PIN[9], GIN[9], GIN[10], POUT[8], GOUT[10] );
smblock1 d311 (PIN[9], PIN[10], GIN[10], GIN[11], POUT[9], GOUT[11] );
smblock1 d312 (PIN[10], PIN[11], GIN[11], GIN[12], POUT[10], GOUT[12] );
smblock1 d313 (PIN[11], PIN[12], GIN[12], GIN[13], POUT[11], GOUT[13] );
smblock1 d314 (PIN[12], PIN[13], GIN[13], GIN[14], POUT[12], GOUT[14] );
smblock1 d315 (PIN[13], PIN[14], GIN[14], GIN[15], POUT[13], GOUT[15] );
smblock1 d316 (PIN[14], PIN[15], GIN[15], GIN[16], POUT[14], GOUT[16] );
smblock1 d317 (PIN[15], PIN[16], GIN[16], GIN[17], POUT[15], GOUT[17] );
smblock1 d318 (PIN[16], PIN[17], GIN[17], GIN[18], POUT[16], GOUT[18] );
smblock1 d319 (PIN[17], PIN[18], GIN[18], GIN[19], POUT[17], GOUT[19] );
smblock1 d320 (PIN[18], PIN[19], GIN[19], GIN[20], POUT[18], GOUT[20] );
smblock1 d321 (PIN[19], PIN[20], GIN[20], GIN[21], POUT[19], GOUT[21] );
smblock1 d322 (PIN[20], PIN[21], GIN[21], GIN[22], POUT[20], GOUT[22] );
smblock1 d323 (PIN[21], PIN[22], GIN[22], GIN[23], POUT[21], GOUT[23] );
smblock1 d324 (PIN[22], PIN[23], GIN[23], GIN[24], POUT[22], GOUT[24] );
smblock1 d325 (PIN[23], PIN[24], GIN[24], GIN[25], POUT[23], GOUT[25] );
smblock1 d326 (PIN[24], PIN[25], GIN[25], GIN[26], POUT[24], GOUT[26] );
smblock1 d327 (PIN[25], PIN[26], GIN[26], GIN[27], POUT[25], GOUT[27] );
smblock1 d328 (PIN[26], PIN[27], GIN[27], GIN[28], POUT[26], GOUT[28] );
smblock1 d329 (PIN[27], PIN[28], GIN[28], GIN[29], POUT[27], GOUT[29] );
smblock1 d330 (PIN[28], PIN[29], GIN[29], GIN[30], POUT[28], GOUT[30] );
smblock1 d331 (PIN[29], PIN[30], GIN[30], GIN[31], POUT[29], GOUT[31] );
smblock1 d332 (PIN[30], PIN[31], GIN[31], GIN[32], POUT[30], GOUT[32] );
smblock1 d333 (PIN[31], PIN[32], GIN[32], GIN[33], POUT[31], GOUT[33] );
smblock1 d334 (PIN[32], PIN[33], GIN[33], GIN[34], POUT[32], GOUT[34] );
smblock1 d335 (PIN[33], PIN[34], GIN[34], GIN[35], POUT[33], GOUT[35] );
smblock1 d336 (PIN[34], PIN[35], GIN[35], GIN[36], POUT[34], GOUT[36] );
smblock1 d337 (PIN[35], PIN[36], GIN[36], GIN[37], POUT[35], GOUT[37] );
smblock1 d338 (PIN[36], PIN[37], GIN[37], GIN[38], POUT[36], GOUT[38] );
smblock1 d339 (PIN[37], PIN[38], GIN[38], GIN[39], POUT[37], GOUT[39] );
smblock1 d340 (PIN[38], PIN[39], GIN[39], GIN[40], POUT[38], GOUT[40] );
smblock1 d341 (PIN[39], PIN[40], GIN[40], GIN[41], POUT[39], GOUT[41] );
smblock1 d342 (PIN[40], PIN[41], GIN[41], GIN[42], POUT[40], GOUT[42] );
smblock1 d343 (PIN[41], PIN[42], GIN[42], GIN[43], POUT[41], GOUT[43] );
smblock1 d344 (PIN[42], PIN[43], GIN[43], GIN[44], POUT[42], GOUT[44] );
smblock1 d345 (PIN[43], PIN[44], GIN[44], GIN[45], POUT[43], GOUT[45] );
smblock1 d346 (PIN[44], PIN[45], GIN[45], GIN[46], POUT[44], GOUT[46] );
smblock1 d347 (PIN[45], PIN[46], GIN[46], GIN[47], POUT[45], GOUT[47] );
smblock1 d348 (PIN[46], PIN[47], GIN[47], GIN[48], POUT[46], GOUT[48] );
smblock1 d349 (PIN[47], PIN[48], GIN[48], GIN[49], POUT[47], GOUT[49] );
smblock1 d350 (PIN[48], PIN[49], GIN[49], GIN[50], POUT[48], GOUT[50] );
smblock1 d351 (PIN[49], PIN[50], GIN[50], GIN[51], POUT[49], GOUT[51] );
smblock1 d352 (PIN[50], PIN[51], GIN[51], GIN[52], POUT[50], GOUT[52] );
smblock1 d353 (PIN[51], PIN[52], GIN[52], GIN[53], POUT[51], GOUT[53] );
smblock1 d354 (PIN[52], PIN[53], GIN[53], GIN[54], POUT[52], GOUT[54] );
smblock1 d355 (PIN[53], PIN[54], GIN[54], GIN[55], POUT[53], GOUT[55] );
smblock1 d356 (PIN[54], PIN[55], GIN[55], GIN[56], POUT[54], GOUT[56] );
smblock1 d357 (PIN[55], PIN[56], GIN[56], GIN[57], POUT[55], GOUT[57] );
smblock1 d358 (PIN[56], PIN[57], GIN[57], GIN[58], POUT[56], GOUT[58] );
smblock1 d359 (PIN[57], PIN[58], GIN[58], GIN[59], POUT[57], GOUT[59] );
smblock1 d360 (PIN[58], PIN[59], GIN[59], GIN[60], POUT[58], GOUT[60] );
smblock1 d361 (PIN[59], PIN[60], GIN[60], GIN[61], POUT[59], GOUT[61] );
smblock1 d362 (PIN[60], PIN[61], GIN[61], GIN[62], POUT[60], GOUT[62] );
smblock1 d363 (PIN[61], PIN[62], GIN[62], GIN[63], POUT[61], GOUT[63] );
endmodule
module smdblc_1_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
smblock2a d22 (PIN[0], GIN[0], GIN[2], GOUT[2] );
smblock2a d23 (PIN[1], GIN[1], GIN[3], GOUT[3] );
smblock2 d34 (PIN[0], PIN[2], GIN[2], GIN[4], POUT[0], GOUT[4] );
smblock2 d35 (PIN[1], PIN[3], GIN[3], GIN[5], POUT[1], GOUT[5] );
smblock2 d36 (PIN[2], PIN[4], GIN[4], GIN[6], POUT[2], GOUT[6] );
smblock2 d37 (PIN[3], PIN[5], GIN[5], GIN[7], POUT[3], GOUT[7] );
smblock2 d38 (PIN[4], PIN[6], GIN[6], GIN[8], POUT[4], GOUT[8] );
smblock2 d39 (PIN[5], PIN[7], GIN[7], GIN[9], POUT[5], GOUT[9] );
smblock2 d310 (PIN[6], PIN[8], GIN[8], GIN[10], POUT[6], GOUT[10] );
smblock2 d311 (PIN[7], PIN[9], GIN[9], GIN[11], POUT[7], GOUT[11] );
smblock2 d312 (PIN[8], PIN[10], GIN[10], GIN[12], POUT[8], GOUT[12] );
smblock2 d313 (PIN[9], PIN[11], GIN[11], GIN[13], POUT[9], GOUT[13] );
smblock2 d314 (PIN[10], PIN[12], GIN[12], GIN[14], POUT[10], GOUT[14] );
smblock2 d315 (PIN[11], PIN[13], GIN[13], GIN[15], POUT[11], GOUT[15] );
smblock2 d316 (PIN[12], PIN[14], GIN[14], GIN[16], POUT[12], GOUT[16] );
smblock2 d317 (PIN[13], PIN[15], GIN[15], GIN[17], POUT[13], GOUT[17] );
smblock2 d318 (PIN[14], PIN[16], GIN[16], GIN[18], POUT[14], GOUT[18] );
smblock2 d319 (PIN[15], PIN[17], GIN[17], GIN[19], POUT[15], GOUT[19] );
smblock2 d320 (PIN[16], PIN[18], GIN[18], GIN[20], POUT[16], GOUT[20] );
smblock2 d321 (PIN[17], PIN[19], GIN[19], GIN[21], POUT[17], GOUT[21] );
smblock2 d322 (PIN[18], PIN[20], GIN[20], GIN[22], POUT[18], GOUT[22] );
smblock2 d323 (PIN[19], PIN[21], GIN[21], GIN[23], POUT[19], GOUT[23] );
smblock2 d324 (PIN[20], PIN[22], GIN[22], GIN[24], POUT[20], GOUT[24] );
smblock2 d325 (PIN[21], PIN[23], GIN[23], GIN[25], POUT[21], GOUT[25] );
smblock2 d326 (PIN[22], PIN[24], GIN[24], GIN[26], POUT[22], GOUT[26] );
smblock2 d327 (PIN[23], PIN[25], GIN[25], GIN[27], POUT[23], GOUT[27] );
smblock2 d328 (PIN[24], PIN[26], GIN[26], GIN[28], POUT[24], GOUT[28] );
smblock2 d329 (PIN[25], PIN[27], GIN[27], GIN[29], POUT[25], GOUT[29] );
smblock2 d330 (PIN[26], PIN[28], GIN[28], GIN[30], POUT[26], GOUT[30] );
smblock2 d331 (PIN[27], PIN[29], GIN[29], GIN[31], POUT[27], GOUT[31] );
smblock2 d332 (PIN[28], PIN[30], GIN[30], GIN[32], POUT[28], GOUT[32] );
smblock2 d333 (PIN[29], PIN[31], GIN[31], GIN[33], POUT[29], GOUT[33] );
smblock2 d334 (PIN[30], PIN[32], GIN[32], GIN[34], POUT[30], GOUT[34] );
smblock2 d335 (PIN[31], PIN[33], GIN[33], GIN[35], POUT[31], GOUT[35] );
smblock2 d336 (PIN[32], PIN[34], GIN[34], GIN[36], POUT[32], GOUT[36] );
smblock2 d337 (PIN[33], PIN[35], GIN[35], GIN[37], POUT[33], GOUT[37] );
smblock2 d338 (PIN[34], PIN[36], GIN[36], GIN[38], POUT[34], GOUT[38] );
smblock2 d339 (PIN[35], PIN[37], GIN[37], GIN[39], POUT[35], GOUT[39] );
smblock2 d340 (PIN[36], PIN[38], GIN[38], GIN[40], POUT[36], GOUT[40] );
smblock2 d341 (PIN[37], PIN[39], GIN[39], GIN[41], POUT[37], GOUT[41] );
smblock2 d342 (PIN[38], PIN[40], GIN[40], GIN[42], POUT[38], GOUT[42] );
smblock2 d343 (PIN[39], PIN[41], GIN[41], GIN[43], POUT[39], GOUT[43] );
smblock2 d344 (PIN[40], PIN[42], GIN[42], GIN[44], POUT[40], GOUT[44] );
smblock2 d345 (PIN[41], PIN[43], GIN[43], GIN[45], POUT[41], GOUT[45] );
smblock2 d346 (PIN[42], PIN[44], GIN[44], GIN[46], POUT[42], GOUT[46] );
smblock2 d347 (PIN[43], PIN[45], GIN[45], GIN[47], POUT[43], GOUT[47] );
smblock2 d348 (PIN[44], PIN[46], GIN[46], GIN[48], POUT[44], GOUT[48] );
smblock2 d349 (PIN[45], PIN[47], GIN[47], GIN[49], POUT[45], GOUT[49] );
smblock2 d350 (PIN[46], PIN[48], GIN[48], GIN[50], POUT[46], GOUT[50] );
smblock2 d351 (PIN[47], PIN[49], GIN[49], GIN[51], POUT[47], GOUT[51] );
smblock2 d352 (PIN[48], PIN[50], GIN[50], GIN[52], POUT[48], GOUT[52] );
smblock2 d353 (PIN[49], PIN[51], GIN[51], GIN[53], POUT[49], GOUT[53] );
smblock2 d354 (PIN[50], PIN[52], GIN[52], GIN[54], POUT[50], GOUT[54] );
smblock2 d355 (PIN[51], PIN[53], GIN[53], GIN[55], POUT[51], GOUT[55] );
smblock2 d356 (PIN[52], PIN[54], GIN[54], GIN[56], POUT[52], GOUT[56] );
smblock2 d357 (PIN[53], PIN[55], GIN[55], GIN[57], POUT[53], GOUT[57] );
smblock2 d358 (PIN[54], PIN[56], GIN[56], GIN[58], POUT[54], GOUT[58] );
smblock2 d359 (PIN[55], PIN[57], GIN[57], GIN[59], POUT[55], GOUT[59] );
smblock2 d360 (PIN[56], PIN[58], GIN[58], GIN[60], POUT[56], GOUT[60] );
smblock2 d361 (PIN[57], PIN[59], GIN[59], GIN[61], POUT[57], GOUT[61] );
smblock2 d362 (PIN[58], PIN[60], GIN[60], GIN[62], POUT[58], GOUT[62] );
smblock2 d363 (PIN[59], PIN[61], GIN[61], GIN[63], POUT[59], GOUT[63] );
endmodule
module smdblc_2_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
sminvblock d12 (GIN[2], GOUT[2] );
sminvblock d13 (GIN[3], GOUT[3] );
smblock1a d24 (PIN[0], GIN[0], GIN[4], GOUT[4] );
smblock1a d25 (PIN[1], GIN[1], GIN[5], GOUT[5] );
smblock1a d26 (PIN[2], GIN[2], GIN[6], GOUT[6] );
smblock1a d27 (PIN[3], GIN[3], GIN[7], GOUT[7] );
smblock1 d38 (PIN[0], PIN[4], GIN[4], GIN[8], POUT[0], GOUT[8] );
smblock1 d39 (PIN[1], PIN[5], GIN[5], GIN[9], POUT[1], GOUT[9] );
smblock1 d310 (PIN[2], PIN[6], GIN[6], GIN[10], POUT[2], GOUT[10] );
smblock1 d311 (PIN[3], PIN[7], GIN[7], GIN[11], POUT[3], GOUT[11] );
smblock1 d312 (PIN[4], PIN[8], GIN[8], GIN[12], POUT[4], GOUT[12] );
smblock1 d313 (PIN[5], PIN[9], GIN[9], GIN[13], POUT[5], GOUT[13] );
smblock1 d314 (PIN[6], PIN[10], GIN[10], GIN[14], POUT[6], GOUT[14] );
smblock1 d315 (PIN[7], PIN[11], GIN[11], GIN[15], POUT[7], GOUT[15] );
smblock1 d316 (PIN[8], PIN[12], GIN[12], GIN[16], POUT[8], GOUT[16] );
smblock1 d317 (PIN[9], PIN[13], GIN[13], GIN[17], POUT[9], GOUT[17] );
smblock1 d318 (PIN[10], PIN[14], GIN[14], GIN[18], POUT[10], GOUT[18] );
smblock1 d319 (PIN[11], PIN[15], GIN[15], GIN[19], POUT[11], GOUT[19] );
smblock1 d320 (PIN[12], PIN[16], GIN[16], GIN[20], POUT[12], GOUT[20] );
smblock1 d321 (PIN[13], PIN[17], GIN[17], GIN[21], POUT[13], GOUT[21] );
smblock1 d322 (PIN[14], PIN[18], GIN[18], GIN[22], POUT[14], GOUT[22] );
smblock1 d323 (PIN[15], PIN[19], GIN[19], GIN[23], POUT[15], GOUT[23] );
smblock1 d324 (PIN[16], PIN[20], GIN[20], GIN[24], POUT[16], GOUT[24] );
smblock1 d325 (PIN[17], PIN[21], GIN[21], GIN[25], POUT[17], GOUT[25] );
smblock1 d326 (PIN[18], PIN[22], GIN[22], GIN[26], POUT[18], GOUT[26] );
smblock1 d327 (PIN[19], PIN[23], GIN[23], GIN[27], POUT[19], GOUT[27] );
smblock1 d328 (PIN[20], PIN[24], GIN[24], GIN[28], POUT[20], GOUT[28] );
smblock1 d329 (PIN[21], PIN[25], GIN[25], GIN[29], POUT[21], GOUT[29] );
smblock1 d330 (PIN[22], PIN[26], GIN[26], GIN[30], POUT[22], GOUT[30] );
smblock1 d331 (PIN[23], PIN[27], GIN[27], GIN[31], POUT[23], GOUT[31] );
smblock1 d332 (PIN[24], PIN[28], GIN[28], GIN[32], POUT[24], GOUT[32] );
smblock1 d333 (PIN[25], PIN[29], GIN[29], GIN[33], POUT[25], GOUT[33] );
smblock1 d334 (PIN[26], PIN[30], GIN[30], GIN[34], POUT[26], GOUT[34] );
smblock1 d335 (PIN[27], PIN[31], GIN[31], GIN[35], POUT[27], GOUT[35] );
smblock1 d336 (PIN[28], PIN[32], GIN[32], GIN[36], POUT[28], GOUT[36] );
smblock1 d337 (PIN[29], PIN[33], GIN[33], GIN[37], POUT[29], GOUT[37] );
smblock1 d338 (PIN[30], PIN[34], GIN[34], GIN[38], POUT[30], GOUT[38] );
smblock1 d339 (PIN[31], PIN[35], GIN[35], GIN[39], POUT[31], GOUT[39] );
smblock1 d340 (PIN[32], PIN[36], GIN[36], GIN[40], POUT[32], GOUT[40] );
smblock1 d341 (PIN[33], PIN[37], GIN[37], GIN[41], POUT[33], GOUT[41] );
smblock1 d342 (PIN[34], PIN[38], GIN[38], GIN[42], POUT[34], GOUT[42] );
smblock1 d343 (PIN[35], PIN[39], GIN[39], GIN[43], POUT[35], GOUT[43] );
smblock1 d344 (PIN[36], PIN[40], GIN[40], GIN[44], POUT[36], GOUT[44] );
smblock1 d345 (PIN[37], PIN[41], GIN[41], GIN[45], POUT[37], GOUT[45] );
smblock1 d346 (PIN[38], PIN[42], GIN[42], GIN[46], POUT[38], GOUT[46] );
smblock1 d347 (PIN[39], PIN[43], GIN[43], GIN[47], POUT[39], GOUT[47] );
smblock1 d348 (PIN[40], PIN[44], GIN[44], GIN[48], POUT[40], GOUT[48] );
smblock1 d349 (PIN[41], PIN[45], GIN[45], GIN[49], POUT[41], GOUT[49] );
smblock1 d350 (PIN[42], PIN[46], GIN[46], GIN[50], POUT[42], GOUT[50] );
smblock1 d351 (PIN[43], PIN[47], GIN[47], GIN[51], POUT[43], GOUT[51] );
smblock1 d352 (PIN[44], PIN[48], GIN[48], GIN[52], POUT[44], GOUT[52] );
smblock1 d353 (PIN[45], PIN[49], GIN[49], GIN[53], POUT[45], GOUT[53] );
smblock1 d354 (PIN[46], PIN[50], GIN[50], GIN[54], POUT[46], GOUT[54] );
smblock1 d355 (PIN[47], PIN[51], GIN[51], GIN[55], POUT[47], GOUT[55] );
smblock1 d356 (PIN[48], PIN[52], GIN[52], GIN[56], POUT[48], GOUT[56] );
smblock1 d357 (PIN[49], PIN[53], GIN[53], GIN[57], POUT[49], GOUT[57] );
smblock1 d358 (PIN[50], PIN[54], GIN[54], GIN[58], POUT[50], GOUT[58] );
smblock1 d359 (PIN[51], PIN[55], GIN[55], GIN[59], POUT[51], GOUT[59] );
smblock1 d360 (PIN[52], PIN[56], GIN[56], GIN[60], POUT[52], GOUT[60] );
smblock1 d361 (PIN[53], PIN[57], GIN[57], GIN[61], POUT[53], GOUT[61] );
smblock1 d362 (PIN[54], PIN[58], GIN[58], GIN[62], POUT[54], GOUT[62] );
smblock1 d363 (PIN[55], PIN[59], GIN[59], GIN[63], POUT[55], GOUT[63] );
endmodule
module smdblc_3_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
sminvblock d12 (GIN[2], GOUT[2] );
sminvblock d13 (GIN[3], GOUT[3] );
sminvblock d14 (GIN[4], GOUT[4] );
sminvblock d15 (GIN[5], GOUT[5] );
sminvblock d16 (GIN[6], GOUT[6] );
sminvblock d17 (GIN[7], GOUT[7] );
smblock2a d28 (PIN[0], GIN[0], GIN[8], GOUT[8] );
smblock2a d29 (PIN[1], GIN[1], GIN[9], GOUT[9] );
smblock2a d210 (PIN[2], GIN[2], GIN[10], GOUT[10] );
smblock2a d211 (PIN[3], GIN[3], GIN[11], GOUT[11] );
smblock2a d212 (PIN[4], GIN[4], GIN[12], GOUT[12] );
smblock2a d213 (PIN[5], GIN[5], GIN[13], GOUT[13] );
smblock2a d214 (PIN[6], GIN[6], GIN[14], GOUT[14] );
smblock2a d215 (PIN[7], GIN[7], GIN[15], GOUT[15] );
smblock2 d316 (PIN[0], PIN[8], GIN[8], GIN[16], POUT[0], GOUT[16] );
smblock2 d317 (PIN[1], PIN[9], GIN[9], GIN[17], POUT[1], GOUT[17] );
smblock2 d318 (PIN[2], PIN[10], GIN[10], GIN[18], POUT[2], GOUT[18] );
smblock2 d319 (PIN[3], PIN[11], GIN[11], GIN[19], POUT[3], GOUT[19] );
smblock2 d320 (PIN[4], PIN[12], GIN[12], GIN[20], POUT[4], GOUT[20] );
smblock2 d321 (PIN[5], PIN[13], GIN[13], GIN[21], POUT[5], GOUT[21] );
smblock2 d322 (PIN[6], PIN[14], GIN[14], GIN[22], POUT[6], GOUT[22] );
smblock2 d323 (PIN[7], PIN[15], GIN[15], GIN[23], POUT[7], GOUT[23] );
smblock2 d324 (PIN[8], PIN[16], GIN[16], GIN[24], POUT[8], GOUT[24] );
smblock2 d325 (PIN[9], PIN[17], GIN[17], GIN[25], POUT[9], GOUT[25] );
smblock2 d326 (PIN[10], PIN[18], GIN[18], GIN[26], POUT[10], GOUT[26] );
smblock2 d327 (PIN[11], PIN[19], GIN[19], GIN[27], POUT[11], GOUT[27] );
smblock2 d328 (PIN[12], PIN[20], GIN[20], GIN[28], POUT[12], GOUT[28] );
smblock2 d329 (PIN[13], PIN[21], GIN[21], GIN[29], POUT[13], GOUT[29] );
smblock2 d330 (PIN[14], PIN[22], GIN[22], GIN[30], POUT[14], GOUT[30] );
smblock2 d331 (PIN[15], PIN[23], GIN[23], GIN[31], POUT[15], GOUT[31] );
smblock2 d332 (PIN[16], PIN[24], GIN[24], GIN[32], POUT[16], GOUT[32] );
smblock2 d333 (PIN[17], PIN[25], GIN[25], GIN[33], POUT[17], GOUT[33] );
smblock2 d334 (PIN[18], PIN[26], GIN[26], GIN[34], POUT[18], GOUT[34] );
smblock2 d335 (PIN[19], PIN[27], GIN[27], GIN[35], POUT[19], GOUT[35] );
smblock2 d336 (PIN[20], PIN[28], GIN[28], GIN[36], POUT[20], GOUT[36] );
smblock2 d337 (PIN[21], PIN[29], GIN[29], GIN[37], POUT[21], GOUT[37] );
smblock2 d338 (PIN[22], PIN[30], GIN[30], GIN[38], POUT[22], GOUT[38] );
smblock2 d339 (PIN[23], PIN[31], GIN[31], GIN[39], POUT[23], GOUT[39] );
smblock2 d340 (PIN[24], PIN[32], GIN[32], GIN[40], POUT[24], GOUT[40] );
smblock2 d341 (PIN[25], PIN[33], GIN[33], GIN[41], POUT[25], GOUT[41] );
smblock2 d342 (PIN[26], PIN[34], GIN[34], GIN[42], POUT[26], GOUT[42] );
smblock2 d343 (PIN[27], PIN[35], GIN[35], GIN[43], POUT[27], GOUT[43] );
smblock2 d344 (PIN[28], PIN[36], GIN[36], GIN[44], POUT[28], GOUT[44] );
smblock2 d345 (PIN[29], PIN[37], GIN[37], GIN[45], POUT[29], GOUT[45] );
smblock2 d346 (PIN[30], PIN[38], GIN[38], GIN[46], POUT[30], GOUT[46] );
smblock2 d347 (PIN[31], PIN[39], GIN[39], GIN[47], POUT[31], GOUT[47] );
smblock2 d348 (PIN[32], PIN[40], GIN[40], GIN[48], POUT[32], GOUT[48] );
smblock2 d349 (PIN[33], PIN[41], GIN[41], GIN[49], POUT[33], GOUT[49] );
smblock2 d350 (PIN[34], PIN[42], GIN[42], GIN[50], POUT[34], GOUT[50] );
smblock2 d351 (PIN[35], PIN[43], GIN[43], GIN[51], POUT[35], GOUT[51] );
smblock2 d352 (PIN[36], PIN[44], GIN[44], GIN[52], POUT[36], GOUT[52] );
smblock2 d353 (PIN[37], PIN[45], GIN[45], GIN[53], POUT[37], GOUT[53] );
smblock2 d354 (PIN[38], PIN[46], GIN[46], GIN[54], POUT[38], GOUT[54] );
smblock2 d355 (PIN[39], PIN[47], GIN[47], GIN[55], POUT[39], GOUT[55] );
smblock2 d356 (PIN[40], PIN[48], GIN[48], GIN[56], POUT[40], GOUT[56] );
smblock2 d357 (PIN[41], PIN[49], GIN[49], GIN[57], POUT[41], GOUT[57] );
smblock2 d358 (PIN[42], PIN[50], GIN[50], GIN[58], POUT[42], GOUT[58] );
smblock2 d359 (PIN[43], PIN[51], GIN[51], GIN[59], POUT[43], GOUT[59] );
smblock2 d360 (PIN[44], PIN[52], GIN[52], GIN[60], POUT[44], GOUT[60] );
smblock2 d361 (PIN[45], PIN[53], GIN[53], GIN[61], POUT[45], GOUT[61] );
smblock2 d362 (PIN[46], PIN[54], GIN[54], GIN[62], POUT[46], GOUT[62] );
smblock2 d363 (PIN[47], PIN[55], GIN[55], GIN[63], POUT[47], GOUT[63] );
endmodule
module smdblc_4_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
sminvblock d12 (GIN[2], GOUT[2] );
sminvblock d13 (GIN[3], GOUT[3] );
sminvblock d14 (GIN[4], GOUT[4] );
sminvblock d15 (GIN[5], GOUT[5] );
sminvblock d16 (GIN[6], GOUT[6] );
sminvblock d17 (GIN[7], GOUT[7] );
sminvblock d18 (GIN[8], GOUT[8] );
sminvblock d19 (GIN[9], GOUT[9] );
sminvblock d110 (GIN[10], GOUT[10] );
sminvblock d111 (GIN[11], GOUT[11] );
sminvblock d112 (GIN[12], GOUT[12] );
sminvblock d113 (GIN[13], GOUT[13] );
sminvblock d114 (GIN[14], GOUT[14] );
sminvblock d115 (GIN[15], GOUT[15] );
smblock1a d216 (PIN[0], GIN[0], GIN[16], GOUT[16] );
smblock1a d217 (PIN[1], GIN[1], GIN[17], GOUT[17] );
smblock1a d218 (PIN[2], GIN[2], GIN[18], GOUT[18] );
smblock1a d219 (PIN[3], GIN[3], GIN[19], GOUT[19] );
smblock1a d220 (PIN[4], GIN[4], GIN[20], GOUT[20] );
smblock1a d221 (PIN[5], GIN[5], GIN[21], GOUT[21] );
smblock1a d222 (PIN[6], GIN[6], GIN[22], GOUT[22] );
smblock1a d223 (PIN[7], GIN[7], GIN[23], GOUT[23] );
smblock1a d224 (PIN[8], GIN[8], GIN[24], GOUT[24] );
smblock1a d225 (PIN[9], GIN[9], GIN[25], GOUT[25] );
smblock1a d226 (PIN[10], GIN[10], GIN[26], GOUT[26] );
smblock1a d227 (PIN[11], GIN[11], GIN[27], GOUT[27] );
smblock1a d228 (PIN[12], GIN[12], GIN[28], GOUT[28] );
smblock1a d229 (PIN[13], GIN[13], GIN[29], GOUT[29] );
smblock1a d230 (PIN[14], GIN[14], GIN[30], GOUT[30] );
smblock1a d231 (PIN[15], GIN[15], GIN[31], GOUT[31] );
smblock1 d332 (PIN[0], PIN[16], GIN[16], GIN[32], POUT[0], GOUT[32] );
smblock1 d333 (PIN[1], PIN[17], GIN[17], GIN[33], POUT[1], GOUT[33] );
smblock1 d334 (PIN[2], PIN[18], GIN[18], GIN[34], POUT[2], GOUT[34] );
smblock1 d335 (PIN[3], PIN[19], GIN[19], GIN[35], POUT[3], GOUT[35] );
smblock1 d336 (PIN[4], PIN[20], GIN[20], GIN[36], POUT[4], GOUT[36] );
smblock1 d337 (PIN[5], PIN[21], GIN[21], GIN[37], POUT[5], GOUT[37] );
smblock1 d338 (PIN[6], PIN[22], GIN[22], GIN[38], POUT[6], GOUT[38] );
smblock1 d339 (PIN[7], PIN[23], GIN[23], GIN[39], POUT[7], GOUT[39] );
smblock1 d340 (PIN[8], PIN[24], GIN[24], GIN[40], POUT[8], GOUT[40] );
smblock1 d341 (PIN[9], PIN[25], GIN[25], GIN[41], POUT[9], GOUT[41] );
smblock1 d342 (PIN[10], PIN[26], GIN[26], GIN[42], POUT[10], GOUT[42] );
smblock1 d343 (PIN[11], PIN[27], GIN[27], GIN[43], POUT[11], GOUT[43] );
smblock1 d344 (PIN[12], PIN[28], GIN[28], GIN[44], POUT[12], GOUT[44] );
smblock1 d345 (PIN[13], PIN[29], GIN[29], GIN[45], POUT[13], GOUT[45] );
smblock1 d346 (PIN[14], PIN[30], GIN[30], GIN[46], POUT[14], GOUT[46] );
smblock1 d347 (PIN[15], PIN[31], GIN[31], GIN[47], POUT[15], GOUT[47] );
smblock1 d348 (PIN[16], PIN[32], GIN[32], GIN[48], POUT[16], GOUT[48] );
smblock1 d349 (PIN[17], PIN[33], GIN[33], GIN[49], POUT[17], GOUT[49] );
smblock1 d350 (PIN[18], PIN[34], GIN[34], GIN[50], POUT[18], GOUT[50] );
smblock1 d351 (PIN[19], PIN[35], GIN[35], GIN[51], POUT[19], GOUT[51] );
smblock1 d352 (PIN[20], PIN[36], GIN[36], GIN[52], POUT[20], GOUT[52] );
smblock1 d353 (PIN[21], PIN[37], GIN[37], GIN[53], POUT[21], GOUT[53] );
smblock1 d354 (PIN[22], PIN[38], GIN[38], GIN[54], POUT[22], GOUT[54] );
smblock1 d355 (PIN[23], PIN[39], GIN[39], GIN[55], POUT[23], GOUT[55] );
smblock1 d356 (PIN[24], PIN[40], GIN[40], GIN[56], POUT[24], GOUT[56] );
smblock1 d357 (PIN[25], PIN[41], GIN[41], GIN[57], POUT[25], GOUT[57] );
smblock1 d358 (PIN[26], PIN[42], GIN[42], GIN[58], POUT[26], GOUT[58] );
smblock1 d359 (PIN[27], PIN[43], GIN[43], GIN[59], POUT[27], GOUT[59] );
smblock1 d360 (PIN[28], PIN[44], GIN[44], GIN[60], POUT[28], GOUT[60] );
smblock1 d361 (PIN[29], PIN[45], GIN[45], GIN[61], POUT[29], GOUT[61] );
smblock1 d362 (PIN[30], PIN[46], GIN[46], GIN[62], POUT[30], GOUT[62] );
smblock1 d363 (PIN[31], PIN[47], GIN[47], GIN[63], POUT[31], GOUT[63] );
endmodule
module smxorstage_128 ( A, B, PBIT, CARRY, SUM );
input [63:0] A;
input [63:0] B;
input PBIT;
input [63:0] CARRY;
output [63:0] SUM;
smxxor1 d20 (A[0], B[0], CARRY[0], SUM[0] );
smxxor1 d21 (A[1], B[1], CARRY[1], SUM[1] );
smxxor1 d22 (A[2], B[2], CARRY[2], SUM[2] );
smxxor1 d23 (A[3], B[3], CARRY[3], SUM[3] );
smxxor1 d24 (A[4], B[4], CARRY[4], SUM[4] );
smxxor1 d25 (A[5], B[5], CARRY[5], SUM[5] );
smxxor1 d26 (A[6], B[6], CARRY[6], SUM[6] );
smxxor1 d27 (A[7], B[7], CARRY[7], SUM[7] );
smxxor1 d28 (A[8], B[8], CARRY[8], SUM[8] );
smxxor1 d29 (A[9], B[9], CARRY[9], SUM[9] );
smxxor1 d210 (A[10], B[10], CARRY[10], SUM[10] );
smxxor1 d211 (A[11], B[11], CARRY[11], SUM[11] );
smxxor1 d212 (A[12], B[12], CARRY[12], SUM[12] );
smxxor1 d213 (A[13], B[13], CARRY[13], SUM[13] );
smxxor1 d214 (A[14], B[14], CARRY[14], SUM[14] );
smxxor1 d215 (A[15], B[15], CARRY[15], SUM[15] );
smxxor1 d216 (A[16], B[16], CARRY[16], SUM[16] );
smxxor1 d217 (A[17], B[17], CARRY[17], SUM[17] );
smxxor1 d218 (A[18], B[18], CARRY[18], SUM[18] );
smxxor1 d219 (A[19], B[19], CARRY[19], SUM[19] );
smxxor1 d220 (A[20], B[20], CARRY[20], SUM[20] );
smxxor1 d221 (A[21], B[21], CARRY[21], SUM[21] );
smxxor1 d222 (A[22], B[22], CARRY[22], SUM[22] );
smxxor1 d223 (A[23], B[23], CARRY[23], SUM[23] );
smxxor1 d224 (A[24], B[24], CARRY[24], SUM[24] );
smxxor1 d225 (A[25], B[25], CARRY[25], SUM[25] );
smxxor1 d226 (A[26], B[26], CARRY[26], SUM[26] );
smxxor1 d227 (A[27], B[27], CARRY[27], SUM[27] );
smxxor1 d228 (A[28], B[28], CARRY[28], SUM[28] );
smxxor1 d229 (A[29], B[29], CARRY[29], SUM[29] );
smxxor1 d230 (A[30], B[30], CARRY[30], SUM[30] );
smxxor1 d231 (A[31], B[31], CARRY[31], SUM[31] );
smxxor1 d232 (A[32], B[32], CARRY[32], SUM[32] );
smxxor1 d233 (A[33], B[33], CARRY[33], SUM[33] );
smxxor1 d234 (A[34], B[34], CARRY[34], SUM[34] );
smxxor1 d235 (A[35], B[35], CARRY[35], SUM[35] );
smxxor1 d236 (A[36], B[36], CARRY[36], SUM[36] );
smxxor1 d237 (A[37], B[37], CARRY[37], SUM[37] );
smxxor1 d238 (A[38], B[38], CARRY[38], SUM[38] );
smxxor1 d239 (A[39], B[39], CARRY[39], SUM[39] );
smxxor1 d240 (A[40], B[40], CARRY[40], SUM[40] );
smxxor1 d241 (A[41], B[41], CARRY[41], SUM[41] );
smxxor1 d242 (A[42], B[42], CARRY[42], SUM[42] );
smxxor1 d243 (A[43], B[43], CARRY[43], SUM[43] );
smxxor1 d244 (A[44], B[44], CARRY[44], SUM[44] );
smxxor1 d245 (A[45], B[45], CARRY[45], SUM[45] );
smxxor1 d246 (A[46], B[46], CARRY[46], SUM[46] );
smxxor1 d247 (A[47], B[47], CARRY[47], SUM[47] );
smxxor1 d248 (A[48], B[48], CARRY[48], SUM[48] );
smxxor1 d249 (A[49], B[49], CARRY[49], SUM[49] );
smxxor1 d250 (A[50], B[50], CARRY[50], SUM[50] );
smxxor1 d251 (A[51], B[51], CARRY[51], SUM[51] );
smxxor1 d252 (A[52], B[52], CARRY[52], SUM[52] );
smxxor1 d253 (A[53], B[53], CARRY[53], SUM[53] );
smxxor1 d254 (A[54], B[54], CARRY[54], SUM[54] );
smxxor1 d255 (A[55], B[55], CARRY[55], SUM[55] );
smxxor1 d256 (A[56], B[56], CARRY[56], SUM[56] );
smxxor1 d257 (A[57], B[57], CARRY[57], SUM[57] );
smxxor1 d258 (A[58], B[58], CARRY[58], SUM[58] );
smxxor1 d259 (A[59], B[59], CARRY[59], SUM[59] );
smxxor1 d260 (A[60], B[60], CARRY[60], SUM[60] );
smxxor1 d261 (A[61], B[61], CARRY[61], SUM[61] );
smxxor1 d262 (A[62], B[62], CARRY[62], SUM[62] );
smxxor1 d263 (A[63], B[63], CARRY[63], SUM[63] );
endmodule
module smdblc_5_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
sminvblock d12 (GIN[2], GOUT[2] );
sminvblock d13 (GIN[3], GOUT[3] );
sminvblock d14 (GIN[4], GOUT[4] );
sminvblock d15 (GIN[5], GOUT[5] );
sminvblock d16 (GIN[6], GOUT[6] );
sminvblock d17 (GIN[7], GOUT[7] );
sminvblock d18 (GIN[8], GOUT[8] );
sminvblock d19 (GIN[9], GOUT[9] );
sminvblock d110 (GIN[10], GOUT[10] );
sminvblock d111 (GIN[11], GOUT[11] );
sminvblock d112 (GIN[12], GOUT[12] );
sminvblock d113 (GIN[13], GOUT[13] );
sminvblock d114 (GIN[14], GOUT[14] );
sminvblock d115 (GIN[15], GOUT[15] );
sminvblock d116 (GIN[16], GOUT[16] );
sminvblock d117 (GIN[17], GOUT[17] );
sminvblock d118 (GIN[18], GOUT[18] );
sminvblock d119 (GIN[19], GOUT[19] );
sminvblock d120 (GIN[20], GOUT[20] );
sminvblock d121 (GIN[21], GOUT[21] );
sminvblock d122 (GIN[22], GOUT[22] );
sminvblock d123 (GIN[23], GOUT[23] );
sminvblock d124 (GIN[24], GOUT[24] );
sminvblock d125 (GIN[25], GOUT[25] );
sminvblock d126 (GIN[26], GOUT[26] );
sminvblock d127 (GIN[27], GOUT[27] );
sminvblock d128 (GIN[28], GOUT[28] );
sminvblock d129 (GIN[29], GOUT[29] );
sminvblock d130 (GIN[30], GOUT[30] );
sminvblock d131 (GIN[31], GOUT[31] );
smblock2a d232 (PIN[0], GIN[0], GIN[32], GOUT[32] );
smblock2a d233 (PIN[1], GIN[1], GIN[33], GOUT[33] );
smblock2a d234 (PIN[2], GIN[2], GIN[34], GOUT[34] );
smblock2a d235 (PIN[3], GIN[3], GIN[35], GOUT[35] );
smblock2a d236 (PIN[4], GIN[4], GIN[36], GOUT[36] );
smblock2a d237 (PIN[5], GIN[5], GIN[37], GOUT[37] );
smblock2a d238 (PIN[6], GIN[6], GIN[38], GOUT[38] );
smblock2a d239 (PIN[7], GIN[7], GIN[39], GOUT[39] );
smblock2a d240 (PIN[8], GIN[8], GIN[40], GOUT[40] );
smblock2a d241 (PIN[9], GIN[9], GIN[41], GOUT[41] );
smblock2a d242 (PIN[10], GIN[10], GIN[42], GOUT[42] );
smblock2a d243 (PIN[11], GIN[11], GIN[43], GOUT[43] );
smblock2a d244 (PIN[12], GIN[12], GIN[44], GOUT[44] );
smblock2a d245 (PIN[13], GIN[13], GIN[45], GOUT[45] );
smblock2a d246 (PIN[14], GIN[14], GIN[46], GOUT[46] );
smblock2a d247 (PIN[15], GIN[15], GIN[47], GOUT[47] );
smblock2a d248 (PIN[16], GIN[16], GIN[48], GOUT[48] );
smblock2a d249 (PIN[17], GIN[17], GIN[49], GOUT[49] );
smblock2a d250 (PIN[18], GIN[18], GIN[50], GOUT[50] );
smblock2a d251 (PIN[19], GIN[19], GIN[51], GOUT[51] );
smblock2a d252 (PIN[20], GIN[20], GIN[52], GOUT[52] );
smblock2a d253 (PIN[21], GIN[21], GIN[53], GOUT[53] );
smblock2a d254 (PIN[22], GIN[22], GIN[54], GOUT[54] );
smblock2a d255 (PIN[23], GIN[23], GIN[55], GOUT[55] );
smblock2a d256 (PIN[24], GIN[24], GIN[56], GOUT[56] );
smblock2a d257 (PIN[25], GIN[25], GIN[57], GOUT[57] );
smblock2a d258 (PIN[26], GIN[26], GIN[58], GOUT[58] );
smblock2a d259 (PIN[27], GIN[27], GIN[59], GOUT[59] );
smblock2a d260 (PIN[28], GIN[28], GIN[60], GOUT[60] );
smblock2a d261 (PIN[29], GIN[29], GIN[61], GOUT[61] );
smblock2a d262 (PIN[30], GIN[30], GIN[62], GOUT[62] );
smblock2a d263 (PIN[31], GIN[31], GIN[63], GOUT[63] );
endmodule
module smdblc_6_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [0:0] POUT;
output [63:0] GOUT;
assign GOUT[63:0] = GIN[63:0];
endmodule
module smboothcoder_34_34 ( OPA, OPB, SUMMAND );
input [33:0] OPA;
input [33:0] OPB;
output [628:0] SUMMAND;
wire [33:0] OPA_;
wire [67:0] INT_MULTIPLIER;
wire LOGIC_ONE, LOGIC_ZERO;
assign LOGIC_ONE = 1'b1;
assign LOGIC_ZERO = 1'b0;
smdecoder dDEC0 (.INA (LOGIC_ZERO), .INB (OPB[0]), .INC (OPB[1]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]) );
assign OPA_ = ~ OPA;
smpp_low dPPL0 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[0]) );
smr_gate dRGATE0 (.INA (LOGIC_ZERO), .INB (OPB[0]), .INC (OPB[1]), .PPBIT (SUMMAND[1]) );
smpp_middle dPPM0 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[2]) );
smpp_middle dPPM1 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[3]) );
smpp_middle dPPM2 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[6]) );
smpp_middle dPPM3 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[8]) );
smpp_middle dPPM4 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[12]) );
smpp_middle dPPM5 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[15]) );
smpp_middle dPPM6 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[20]) );
smpp_middle dPPM7 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[24]) );
smpp_middle dPPM8 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[30]) );
smpp_middle dPPM9 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[35]) );
smpp_middle dPPM10 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[42]) );
smpp_middle dPPM11 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[48]) );
smpp_middle dPPM12 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[56]) );
smpp_middle dPPM13 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[63]) );
smpp_middle dPPM14 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[72]) );
smpp_middle dPPM15 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[80]) );
smpp_middle dPPM16 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[90]) );
smpp_middle dPPM17 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[99]) );
smpp_middle dPPM18 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[110]) );
smpp_middle dPPM19 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[120]) );
smpp_middle dPPM20 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[132]) );
smpp_middle dPPM21 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[143]) );
smpp_middle dPPM22 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[156]) );
smpp_middle dPPM23 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[168]) );
smpp_middle dPPM24 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[182]) );
smpp_middle dPPM25 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[195]) );
smpp_middle dPPM26 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[210]) );
smpp_middle dPPM27 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[224]) );
smpp_middle dPPM28 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[240]) );
smpp_middle dPPM29 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[255]) );
smpp_middle dPPM30 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[272]) );
smpp_middle dPPM31 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[288]) );
smpp_middle dPPM32 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[306]) );
smpp_high dPPH0 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[323]) );
assign SUMMAND[324] = 1'b1;
smdecoder dDEC1 (.INA (OPB[1]), .INB (OPB[2]), .INC (OPB[3]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]) );
smpp_low dPPL1 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[4]) );
smr_gate dRGATE1 (.INA (OPB[1]), .INB (OPB[2]), .INC (OPB[3]), .PPBIT (SUMMAND[5]) );
smpp_middle dPPM33 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[7]) );
smpp_middle dPPM34 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[9]) );
smpp_middle dPPM35 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[13]) );
smpp_middle dPPM36 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[16]) );
smpp_middle dPPM37 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[21]) );
smpp_middle dPPM38 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[25]) );
smpp_middle dPPM39 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[31]) );
smpp_middle dPPM40 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[36]) );
smpp_middle dPPM41 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[43]) );
smpp_middle dPPM42 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[49]) );
smpp_middle dPPM43 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[57]) );
smpp_middle dPPM44 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[64]) );
smpp_middle dPPM45 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[73]) );
smpp_middle dPPM46 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[81]) );
smpp_middle dPPM47 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[91]) );
smpp_middle dPPM48 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[100]) );
smpp_middle dPPM49 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[111]) );
smpp_middle dPPM50 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[121]) );
smpp_middle dPPM51 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[133]) );
smpp_middle dPPM52 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[144]) );
smpp_middle dPPM53 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[157]) );
smpp_middle dPPM54 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[169]) );
smpp_middle dPPM55 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[183]) );
smpp_middle dPPM56 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[196]) );
smpp_middle dPPM57 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[211]) );
smpp_middle dPPM58 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[225]) );
smpp_middle dPPM59 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[241]) );
smpp_middle dPPM60 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[256]) );
smpp_middle dPPM61 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[273]) );
smpp_middle dPPM62 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[289]) );
smpp_middle dPPM63 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[307]) );
smpp_middle dPPM64 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[325]) );
smpp_middle dPPM65 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[341]) );
assign SUMMAND[342] = LOGIC_ONE;
smpp_high dPPH1 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[358]) );
smdecoder dDEC2 (.INA (OPB[3]), .INB (OPB[4]), .INC (OPB[5]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]) );
smpp_low dPPL2 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[10]) );
smr_gate dRGATE2 (.INA (OPB[3]), .INB (OPB[4]), .INC (OPB[5]), .PPBIT (SUMMAND[11]) );
smpp_middle dPPM66 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[14]) );
smpp_middle dPPM67 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[17]) );
smpp_middle dPPM68 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[22]) );
smpp_middle dPPM69 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[26]) );
smpp_middle dPPM70 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[32]) );
smpp_middle dPPM71 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[37]) );
smpp_middle dPPM72 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[44]) );
smpp_middle dPPM73 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[50]) );
smpp_middle dPPM74 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[58]) );
smpp_middle dPPM75 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[65]) );
smpp_middle dPPM76 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[74]) );
smpp_middle dPPM77 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[82]) );
smpp_middle dPPM78 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[92]) );
smpp_middle dPPM79 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[101]) );
smpp_middle dPPM80 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[112]) );
smpp_middle dPPM81 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[122]) );
smpp_middle dPPM82 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[134]) );
smpp_middle dPPM83 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[145]) );
smpp_middle dPPM84 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[158]) );
smpp_middle dPPM85 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[170]) );
smpp_middle dPPM86 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[184]) );
smpp_middle dPPM87 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[197]) );
smpp_middle dPPM88 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[212]) );
smpp_middle dPPM89 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[226]) );
smpp_middle dPPM90 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[242]) );
smpp_middle dPPM91 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[257]) );
smpp_middle dPPM92 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[274]) );
smpp_middle dPPM93 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[290]) );
smpp_middle dPPM94 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[308]) );
smpp_middle dPPM95 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[326]) );
smpp_middle dPPM96 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[343]) );
smpp_middle dPPM97 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[359]) );
smpp_middle dPPM98 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[374]) );
assign SUMMAND[375] = LOGIC_ONE;
smpp_high dPPH2 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[390]) );
smdecoder dDEC3 (.INA (OPB[5]), .INB (OPB[6]), .INC (OPB[7]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]) );
smpp_low dPPL3 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[18]) );
smr_gate dRGATE3 (.INA (OPB[5]), .INB (OPB[6]), .INC (OPB[7]), .PPBIT (SUMMAND[19]) );
smpp_middle dPPM99 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[23]) );
smpp_middle dPPM100 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[27]) );
smpp_middle dPPM101 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[33]) );
smpp_middle dPPM102 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[38]) );
smpp_middle dPPM103 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[45]) );
smpp_middle dPPM104 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[51]) );
smpp_middle dPPM105 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[59]) );
smpp_middle dPPM106 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[66]) );
smpp_middle dPPM107 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[75]) );
smpp_middle dPPM108 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[83]) );
smpp_middle dPPM109 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[93]) );
smpp_middle dPPM110 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[102]) );
smpp_middle dPPM111 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[113]) );
smpp_middle dPPM112 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[123]) );
smpp_middle dPPM113 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[135]) );
smpp_middle dPPM114 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[146]) );
smpp_middle dPPM115 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[159]) );
smpp_middle dPPM116 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[171]) );
smpp_middle dPPM117 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[185]) );
smpp_middle dPPM118 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[198]) );
smpp_middle dPPM119 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[213]) );
smpp_middle dPPM120 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[227]) );
smpp_middle dPPM121 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[243]) );
smpp_middle dPPM122 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[258]) );
smpp_middle dPPM123 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[275]) );
smpp_middle dPPM124 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[291]) );
smpp_middle dPPM125 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[309]) );
smpp_middle dPPM126 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[327]) );
smpp_middle dPPM127 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[344]) );
smpp_middle dPPM128 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[360]) );
smpp_middle dPPM129 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[376]) );
smpp_middle dPPM130 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[391]) );
smpp_middle dPPM131 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[405]) );
assign SUMMAND[406] = LOGIC_ONE;
smpp_high dPPH3 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[420]) );
smdecoder dDEC4 (.INA (OPB[7]), .INB (OPB[8]), .INC (OPB[9]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]) );
smpp_low dPPL4 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[28]) );
smr_gate dRGATE4 (.INA (OPB[7]), .INB (OPB[8]), .INC (OPB[9]), .PPBIT (SUMMAND[29]) );
smpp_middle dPPM132 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[34]) );
smpp_middle dPPM133 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[39]) );
smpp_middle dPPM134 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[46]) );
smpp_middle dPPM135 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[52]) );
smpp_middle dPPM136 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[60]) );
smpp_middle dPPM137 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[67]) );
smpp_middle dPPM138 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[76]) );
smpp_middle dPPM139 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[84]) );
smpp_middle dPPM140 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[94]) );
smpp_middle dPPM141 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[103]) );
smpp_middle dPPM142 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[114]) );
smpp_middle dPPM143 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[124]) );
smpp_middle dPPM144 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[136]) );
smpp_middle dPPM145 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[147]) );
smpp_middle dPPM146 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[160]) );
smpp_middle dPPM147 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[172]) );
smpp_middle dPPM148 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[186]) );
smpp_middle dPPM149 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[199]) );
smpp_middle dPPM150 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[214]) );
smpp_middle dPPM151 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[228]) );
smpp_middle dPPM152 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[244]) );
smpp_middle dPPM153 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[259]) );
smpp_middle dPPM154 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[276]) );
smpp_middle dPPM155 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[292]) );
smpp_middle dPPM156 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[310]) );
smpp_middle dPPM157 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[328]) );
smpp_middle dPPM158 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[345]) );
smpp_middle dPPM159 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[361]) );
smpp_middle dPPM160 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[377]) );
smpp_middle dPPM161 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[392]) );
smpp_middle dPPM162 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[407]) );
smpp_middle dPPM163 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[421]) );
smpp_middle dPPM164 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[434]) );
assign SUMMAND[435] = LOGIC_ONE;
smpp_high dPPH4 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[448]) );
smdecoder dDEC5 (.INA (OPB[9]), .INB (OPB[10]), .INC (OPB[11]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]) );
smpp_low dPPL5 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[40]) );
smr_gate dRGATE5 (.INA (OPB[9]), .INB (OPB[10]), .INC (OPB[11]), .PPBIT (SUMMAND[41]) );
smpp_middle dPPM165 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[47]) );
smpp_middle dPPM166 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[53]) );
smpp_middle dPPM167 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[61]) );
smpp_middle dPPM168 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[68]) );
smpp_middle dPPM169 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[77]) );
smpp_middle dPPM170 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[85]) );
smpp_middle dPPM171 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[95]) );
smpp_middle dPPM172 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[104]) );
smpp_middle dPPM173 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[115]) );
smpp_middle dPPM174 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[125]) );
smpp_middle dPPM175 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[137]) );
smpp_middle dPPM176 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[148]) );
smpp_middle dPPM177 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[161]) );
smpp_middle dPPM178 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[173]) );
smpp_middle dPPM179 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[187]) );
smpp_middle dPPM180 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[200]) );
smpp_middle dPPM181 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[215]) );
smpp_middle dPPM182 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[229]) );
smpp_middle dPPM183 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[245]) );
smpp_middle dPPM184 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[260]) );
smpp_middle dPPM185 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[277]) );
smpp_middle dPPM186 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[293]) );
smpp_middle dPPM187 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[311]) );
smpp_middle dPPM188 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[329]) );
smpp_middle dPPM189 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[346]) );
smpp_middle dPPM190 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[362]) );
smpp_middle dPPM191 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[378]) );
smpp_middle dPPM192 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[393]) );
smpp_middle dPPM193 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[408]) );
smpp_middle dPPM194 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[422]) );
smpp_middle dPPM195 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[436]) );
smpp_middle dPPM196 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[449]) );
smpp_middle dPPM197 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[461]) );
assign SUMMAND[462] = LOGIC_ONE;
smpp_high dPPH5 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[474]) );
smdecoder dDEC6 (.INA (OPB[11]), .INB (OPB[12]), .INC (OPB[13]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]) );
smpp_low dPPL6 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[54]) );
smr_gate dRGATE6 (.INA (OPB[11]), .INB (OPB[12]), .INC (OPB[13]), .PPBIT (SUMMAND[55]) );
smpp_middle dPPM198 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[62]) );
smpp_middle dPPM199 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[69]) );
smpp_middle dPPM200 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[78]) );
smpp_middle dPPM201 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[86]) );
smpp_middle dPPM202 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[96]) );
smpp_middle dPPM203 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[105]) );
smpp_middle dPPM204 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[116]) );
smpp_middle dPPM205 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[126]) );
smpp_middle dPPM206 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[138]) );
smpp_middle dPPM207 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[149]) );
smpp_middle dPPM208 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[162]) );
smpp_middle dPPM209 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[174]) );
smpp_middle dPPM210 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[188]) );
smpp_middle dPPM211 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[201]) );
smpp_middle dPPM212 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[216]) );
smpp_middle dPPM213 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[230]) );
smpp_middle dPPM214 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[246]) );
smpp_middle dPPM215 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[261]) );
smpp_middle dPPM216 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[278]) );
smpp_middle dPPM217 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[294]) );
smpp_middle dPPM218 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[312]) );
smpp_middle dPPM219 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[330]) );
smpp_middle dPPM220 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[347]) );
smpp_middle dPPM221 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[363]) );
smpp_middle dPPM222 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[379]) );
smpp_middle dPPM223 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[394]) );
smpp_middle dPPM224 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[409]) );
smpp_middle dPPM225 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[423]) );
smpp_middle dPPM226 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[437]) );
smpp_middle dPPM227 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[450]) );
smpp_middle dPPM228 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[463]) );
smpp_middle dPPM229 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[475]) );
smpp_middle dPPM230 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[486]) );
assign SUMMAND[487] = LOGIC_ONE;
smpp_high dPPH6 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[498]) );
smdecoder dDEC7 (.INA (OPB[13]), .INB (OPB[14]), .INC (OPB[15]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]) );
smpp_low dPPL7 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[70]) );
smr_gate dRGATE7 (.INA (OPB[13]), .INB (OPB[14]), .INC (OPB[15]), .PPBIT (SUMMAND[71]) );
smpp_middle dPPM231 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[79]) );
smpp_middle dPPM232 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[87]) );
smpp_middle dPPM233 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[97]) );
smpp_middle dPPM234 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[106]) );
smpp_middle dPPM235 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[117]) );
smpp_middle dPPM236 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[127]) );
smpp_middle dPPM237 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[139]) );
smpp_middle dPPM238 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[150]) );
smpp_middle dPPM239 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[163]) );
smpp_middle dPPM240 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[175]) );
smpp_middle dPPM241 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[189]) );
smpp_middle dPPM242 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[202]) );
smpp_middle dPPM243 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[217]) );
smpp_middle dPPM244 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[231]) );
smpp_middle dPPM245 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[247]) );
smpp_middle dPPM246 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[262]) );
smpp_middle dPPM247 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[279]) );
smpp_middle dPPM248 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[295]) );
smpp_middle dPPM249 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[313]) );
smpp_middle dPPM250 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[331]) );
smpp_middle dPPM251 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[348]) );
smpp_middle dPPM252 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[364]) );
smpp_middle dPPM253 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[380]) );
smpp_middle dPPM254 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[395]) );
smpp_middle dPPM255 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[410]) );
smpp_middle dPPM256 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[424]) );
smpp_middle dPPM257 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[438]) );
smpp_middle dPPM258 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[451]) );
smpp_middle dPPM259 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[464]) );
smpp_middle dPPM260 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[476]) );
smpp_middle dPPM261 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[488]) );
smpp_middle dPPM262 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[499]) );
smpp_middle dPPM263 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[509]) );
assign SUMMAND[510] = LOGIC_ONE;
smpp_high dPPH7 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[520]) );
smdecoder dDEC8 (.INA (OPB[15]), .INB (OPB[16]), .INC (OPB[17]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]) );
smpp_low dPPL8 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[88]) );
smr_gate dRGATE8 (.INA (OPB[15]), .INB (OPB[16]), .INC (OPB[17]), .PPBIT (SUMMAND[89]) );
smpp_middle dPPM264 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[98]) );
smpp_middle dPPM265 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[107]) );
smpp_middle dPPM266 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[118]) );
smpp_middle dPPM267 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[128]) );
smpp_middle dPPM268 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[140]) );
smpp_middle dPPM269 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[151]) );
smpp_middle dPPM270 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[164]) );
smpp_middle dPPM271 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[176]) );
smpp_middle dPPM272 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[190]) );
smpp_middle dPPM273 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[203]) );
smpp_middle dPPM274 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[218]) );
smpp_middle dPPM275 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[232]) );
smpp_middle dPPM276 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[248]) );
smpp_middle dPPM277 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[263]) );
smpp_middle dPPM278 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[280]) );
smpp_middle dPPM279 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[296]) );
smpp_middle dPPM280 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[314]) );
smpp_middle dPPM281 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[332]) );
smpp_middle dPPM282 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[349]) );
smpp_middle dPPM283 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[365]) );
smpp_middle dPPM284 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[381]) );
smpp_middle dPPM285 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[396]) );
smpp_middle dPPM286 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[411]) );
smpp_middle dPPM287 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[425]) );
smpp_middle dPPM288 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[439]) );
smpp_middle dPPM289 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[452]) );
smpp_middle dPPM290 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[465]) );
smpp_middle dPPM291 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[477]) );
smpp_middle dPPM292 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[489]) );
smpp_middle dPPM293 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[500]) );
smpp_middle dPPM294 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[511]) );
smpp_middle dPPM295 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[521]) );
smpp_middle dPPM296 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[530]) );
assign SUMMAND[531] = LOGIC_ONE;
smpp_high dPPH8 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[540]) );
smdecoder dDEC9 (.INA (OPB[17]), .INB (OPB[18]), .INC (OPB[19]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]) );
smpp_low dPPL9 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[108]) );
smr_gate dRGATE9 (.INA (OPB[17]), .INB (OPB[18]), .INC (OPB[19]), .PPBIT (SUMMAND[109]) );
smpp_middle dPPM297 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[119]) );
smpp_middle dPPM298 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[129]) );
smpp_middle dPPM299 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[141]) );
smpp_middle dPPM300 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[152]) );
smpp_middle dPPM301 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[165]) );
smpp_middle dPPM302 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[177]) );
smpp_middle dPPM303 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[191]) );
smpp_middle dPPM304 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[204]) );
smpp_middle dPPM305 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[219]) );
smpp_middle dPPM306 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[233]) );
smpp_middle dPPM307 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[249]) );
smpp_middle dPPM308 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[264]) );
smpp_middle dPPM309 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[281]) );
smpp_middle dPPM310 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[297]) );
smpp_middle dPPM311 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[315]) );
smpp_middle dPPM312 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[333]) );
smpp_middle dPPM313 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[350]) );
smpp_middle dPPM314 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[366]) );
smpp_middle dPPM315 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[382]) );
smpp_middle dPPM316 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[397]) );
smpp_middle dPPM317 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[412]) );
smpp_middle dPPM318 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[426]) );
smpp_middle dPPM319 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[440]) );
smpp_middle dPPM320 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[453]) );
smpp_middle dPPM321 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[466]) );
smpp_middle dPPM322 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[478]) );
smpp_middle dPPM323 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[490]) );
smpp_middle dPPM324 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[501]) );
smpp_middle dPPM325 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[512]) );
smpp_middle dPPM326 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[522]) );
smpp_middle dPPM327 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[532]) );
smpp_middle dPPM328 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[541]) );
smpp_middle dPPM329 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[549]) );
assign SUMMAND[550] = LOGIC_ONE;
smpp_high dPPH9 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[558]) );
smdecoder dDEC10 (.INA (OPB[19]), .INB (OPB[20]), .INC (OPB[21]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]) );
smpp_low dPPL10 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[130]) );
smr_gate dRGATE10 (.INA (OPB[19]), .INB (OPB[20]), .INC (OPB[21]), .PPBIT (SUMMAND[131]) );
smpp_middle dPPM330 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[142]) );
smpp_middle dPPM331 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[153]) );
smpp_middle dPPM332 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[166]) );
smpp_middle dPPM333 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[178]) );
smpp_middle dPPM334 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[192]) );
smpp_middle dPPM335 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[205]) );
smpp_middle dPPM336 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[220]) );
smpp_middle dPPM337 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[234]) );
smpp_middle dPPM338 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[250]) );
smpp_middle dPPM339 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[265]) );
smpp_middle dPPM340 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[282]) );
smpp_middle dPPM341 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[298]) );
smpp_middle dPPM342 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[316]) );
smpp_middle dPPM343 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[334]) );
smpp_middle dPPM344 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[351]) );
smpp_middle dPPM345 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[367]) );
smpp_middle dPPM346 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[383]) );
smpp_middle dPPM347 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[398]) );
smpp_middle dPPM348 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[413]) );
smpp_middle dPPM349 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[427]) );
smpp_middle dPPM350 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[441]) );
smpp_middle dPPM351 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[454]) );
smpp_middle dPPM352 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[467]) );
smpp_middle dPPM353 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[479]) );
smpp_middle dPPM354 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[491]) );
smpp_middle dPPM355 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[502]) );
smpp_middle dPPM356 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[513]) );
smpp_middle dPPM357 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[523]) );
smpp_middle dPPM358 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[533]) );
smpp_middle dPPM359 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[542]) );
smpp_middle dPPM360 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[551]) );
smpp_middle dPPM361 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[559]) );
smpp_middle dPPM362 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[566]) );
assign SUMMAND[567] = LOGIC_ONE;
smpp_high dPPH10 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[574]) );
smdecoder dDEC11 (.INA (OPB[21]), .INB (OPB[22]), .INC (OPB[23]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]) );
smpp_low dPPL11 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[154]) );
smr_gate dRGATE11 (.INA (OPB[21]), .INB (OPB[22]), .INC (OPB[23]), .PPBIT (SUMMAND[155]) );
smpp_middle dPPM363 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[167]) );
smpp_middle dPPM364 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[179]) );
smpp_middle dPPM365 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[193]) );
smpp_middle dPPM366 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[206]) );
smpp_middle dPPM367 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[221]) );
smpp_middle dPPM368 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[235]) );
smpp_middle dPPM369 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[251]) );
smpp_middle dPPM370 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[266]) );
smpp_middle dPPM371 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[283]) );
smpp_middle dPPM372 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[299]) );
smpp_middle dPPM373 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[317]) );
smpp_middle dPPM374 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[335]) );
smpp_middle dPPM375 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[352]) );
smpp_middle dPPM376 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[368]) );
smpp_middle dPPM377 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[384]) );
smpp_middle dPPM378 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[399]) );
smpp_middle dPPM379 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[414]) );
smpp_middle dPPM380 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[428]) );
smpp_middle dPPM381 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[442]) );
smpp_middle dPPM382 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[455]) );
smpp_middle dPPM383 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[468]) );
smpp_middle dPPM384 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[480]) );
smpp_middle dPPM385 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[492]) );
smpp_middle dPPM386 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[503]) );
smpp_middle dPPM387 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[514]) );
smpp_middle dPPM388 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[524]) );
smpp_middle dPPM389 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[534]) );
smpp_middle dPPM390 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[543]) );
smpp_middle dPPM391 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[552]) );
smpp_middle dPPM392 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[560]) );
smpp_middle dPPM393 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[568]) );
smpp_middle dPPM394 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[575]) );
smpp_middle dPPM395 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[581]) );
assign SUMMAND[582] = LOGIC_ONE;
smpp_high dPPH11 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[588]) );
smdecoder dDEC12 (.INA (OPB[23]), .INB (OPB[24]), .INC (OPB[25]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]) );
smpp_low dPPL12 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[180]) );
smr_gate dRGATE12 (.INA (OPB[23]), .INB (OPB[24]), .INC (OPB[25]), .PPBIT (SUMMAND[181]) );
smpp_middle dPPM396 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[194]) );
smpp_middle dPPM397 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[207]) );
smpp_middle dPPM398 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[222]) );
smpp_middle dPPM399 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[236]) );
smpp_middle dPPM400 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[252]) );
smpp_middle dPPM401 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[267]) );
smpp_middle dPPM402 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[284]) );
smpp_middle dPPM403 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[300]) );
smpp_middle dPPM404 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[318]) );
smpp_middle dPPM405 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[336]) );
smpp_middle dPPM406 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[353]) );
smpp_middle dPPM407 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[369]) );
smpp_middle dPPM408 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[385]) );
smpp_middle dPPM409 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[400]) );
smpp_middle dPPM410 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[415]) );
smpp_middle dPPM411 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[429]) );
smpp_middle dPPM412 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[443]) );
smpp_middle dPPM413 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[456]) );
smpp_middle dPPM414 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[469]) );
smpp_middle dPPM415 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[481]) );
smpp_middle dPPM416 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[493]) );
smpp_middle dPPM417 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[504]) );
smpp_middle dPPM418 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[515]) );
smpp_middle dPPM419 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[525]) );
smpp_middle dPPM420 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[535]) );
smpp_middle dPPM421 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[544]) );
smpp_middle dPPM422 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[553]) );
smpp_middle dPPM423 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[561]) );
smpp_middle dPPM424 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[569]) );
smpp_middle dPPM425 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[576]) );
smpp_middle dPPM426 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[583]) );
smpp_middle dPPM427 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[589]) );
smpp_middle dPPM428 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[594]) );
assign SUMMAND[595] = LOGIC_ONE;
smpp_high dPPH12 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[600]) );
smdecoder dDEC13 (.INA (OPB[25]), .INB (OPB[26]), .INC (OPB[27]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]) );
smpp_low dPPL13 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[208]) );
smr_gate dRGATE13 (.INA (OPB[25]), .INB (OPB[26]), .INC (OPB[27]), .PPBIT (SUMMAND[209]) );
smpp_middle dPPM429 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[223]) );
smpp_middle dPPM430 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[237]) );
smpp_middle dPPM431 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[253]) );
smpp_middle dPPM432 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[268]) );
smpp_middle dPPM433 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[285]) );
smpp_middle dPPM434 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[301]) );
smpp_middle dPPM435 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[319]) );
smpp_middle dPPM436 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[337]) );
smpp_middle dPPM437 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[354]) );
smpp_middle dPPM438 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[370]) );
smpp_middle dPPM439 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[386]) );
smpp_middle dPPM440 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[401]) );
smpp_middle dPPM441 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[416]) );
smpp_middle dPPM442 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[430]) );
smpp_middle dPPM443 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[444]) );
smpp_middle dPPM444 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[457]) );
smpp_middle dPPM445 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[470]) );
smpp_middle dPPM446 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[482]) );
smpp_middle dPPM447 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[494]) );
smpp_middle dPPM448 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[505]) );
smpp_middle dPPM449 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[516]) );
smpp_middle dPPM450 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[526]) );
smpp_middle dPPM451 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[536]) );
smpp_middle dPPM452 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[545]) );
smpp_middle dPPM453 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[554]) );
smpp_middle dPPM454 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[562]) );
smpp_middle dPPM455 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[570]) );
smpp_middle dPPM456 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[577]) );
smpp_middle dPPM457 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[584]) );
smpp_middle dPPM458 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[590]) );
smpp_middle dPPM459 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[596]) );
smpp_middle dPPM460 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[601]) );
smpp_middle dPPM461 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[605]) );
assign SUMMAND[606] = LOGIC_ONE;
smpp_high dPPH13 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[610]) );
smdecoder dDEC14 (.INA (OPB[27]), .INB (OPB[28]), .INC (OPB[29]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]) );
smpp_low dPPL14 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[238]) );
smr_gate dRGATE14 (.INA (OPB[27]), .INB (OPB[28]), .INC (OPB[29]), .PPBIT (SUMMAND[239]) );
smpp_middle dPPM462 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[254]) );
smpp_middle dPPM463 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[269]) );
smpp_middle dPPM464 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[286]) );
smpp_middle dPPM465 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[302]) );
smpp_middle dPPM466 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[320]) );
smpp_middle dPPM467 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[338]) );
smpp_middle dPPM468 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[355]) );
smpp_middle dPPM469 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[371]) );
smpp_middle dPPM470 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[387]) );
smpp_middle dPPM471 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[402]) );
smpp_middle dPPM472 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[417]) );
smpp_middle dPPM473 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[431]) );
smpp_middle dPPM474 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[445]) );
smpp_middle dPPM475 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[458]) );
smpp_middle dPPM476 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[471]) );
smpp_middle dPPM477 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[483]) );
smpp_middle dPPM478 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[495]) );
smpp_middle dPPM479 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[506]) );
smpp_middle dPPM480 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[517]) );
smpp_middle dPPM481 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[527]) );
smpp_middle dPPM482 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[537]) );
smpp_middle dPPM483 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[546]) );
smpp_middle dPPM484 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[555]) );
smpp_middle dPPM485 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[563]) );
smpp_middle dPPM486 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[571]) );
smpp_middle dPPM487 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[578]) );
smpp_middle dPPM488 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[585]) );
smpp_middle dPPM489 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[591]) );
smpp_middle dPPM490 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[597]) );
smpp_middle dPPM491 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[602]) );
smpp_middle dPPM492 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[607]) );
smpp_middle dPPM493 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[611]) );
smpp_middle dPPM494 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[614]) );
assign SUMMAND[615] = LOGIC_ONE;
smpp_high dPPH14 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[618]) );
smdecoder dDEC15 (.INA (OPB[29]), .INB (OPB[30]), .INC (OPB[31]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]) );
smpp_low dPPL15 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[270]) );
smr_gate dRGATE15 (.INA (OPB[29]), .INB (OPB[30]), .INC (OPB[31]), .PPBIT (SUMMAND[271]) );
smpp_middle dPPM495 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[287]) );
smpp_middle dPPM496 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[303]) );
smpp_middle dPPM497 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[321]) );
smpp_middle dPPM498 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[339]) );
smpp_middle dPPM499 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[356]) );
smpp_middle dPPM500 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[372]) );
smpp_middle dPPM501 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[388]) );
smpp_middle dPPM502 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[403]) );
smpp_middle dPPM503 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[418]) );
smpp_middle dPPM504 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[432]) );
smpp_middle dPPM505 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[446]) );
smpp_middle dPPM506 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[459]) );
smpp_middle dPPM507 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[472]) );
smpp_middle dPPM508 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[484]) );
smpp_middle dPPM509 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[496]) );
smpp_middle dPPM510 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[507]) );
smpp_middle dPPM511 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[518]) );
smpp_middle dPPM512 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[528]) );
smpp_middle dPPM513 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[538]) );
smpp_middle dPPM514 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[547]) );
smpp_middle dPPM515 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[556]) );
smpp_middle dPPM516 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[564]) );
smpp_middle dPPM517 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[572]) );
smpp_middle dPPM518 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[579]) );
smpp_middle dPPM519 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[586]) );
smpp_middle dPPM520 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[592]) );
smpp_middle dPPM521 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[598]) );
smpp_middle dPPM522 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[603]) );
smpp_middle dPPM523 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[608]) );
smpp_middle dPPM524 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[612]) );
smpp_middle dPPM525 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[616]) );
smpp_middle dPPM526 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[619]) );
smpp_middle dPPM527 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[621]) );
assign SUMMAND[622] = LOGIC_ONE;
smpp_high dPPH15 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[624]) );
smdecoder dDEC16 (.INA (OPB[31]), .INB (OPB[32]), .INC (OPB[33]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]) );
smpp_low dPPL16 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[304]) );
smr_gate dRGATE16 (.INA (OPB[31]), .INB (OPB[32]), .INC (OPB[33]), .PPBIT (SUMMAND[305]) );
smpp_middle dPPM528 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[322]) );
smpp_middle dPPM529 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[340]) );
smpp_middle dPPM530 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[357]) );
smpp_middle dPPM531 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[373]) );
smpp_middle dPPM532 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[389]) );
smpp_middle dPPM533 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[404]) );
smpp_middle dPPM534 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[419]) );
smpp_middle dPPM535 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[433]) );
smpp_middle dPPM536 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[447]) );
smpp_middle dPPM537 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[460]) );
smpp_middle dPPM538 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[473]) );
smpp_middle dPPM539 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[485]) );
smpp_middle dPPM540 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[497]) );
smpp_middle dPPM541 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[508]) );
smpp_middle dPPM542 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[519]) );
smpp_middle dPPM543 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[529]) );
smpp_middle dPPM544 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[539]) );
smpp_middle dPPM545 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[548]) );
smpp_middle dPPM546 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[557]) );
smpp_middle dPPM547 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[565]) );
smpp_middle dPPM548 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[573]) );
smpp_middle dPPM549 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[580]) );
smpp_middle dPPM550 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[587]) );
smpp_middle dPPM551 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[593]) );
smpp_middle dPPM552 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[599]) );
smpp_middle dPPM553 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[604]) );
smpp_middle dPPM554 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[609]) );
smpp_middle dPPM555 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[613]) );
smpp_middle dPPM556 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[617]) );
smpp_middle dPPM557 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[620]) );
smpp_middle dPPM558 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[623]) );
smpp_middle dPPM559 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[625]) );
smpp_middle dPPM560 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[626]) );
assign SUMMAND[627] = LOGIC_ONE;
smpp_high dPPH16 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[628]) );
endmodule
// Simple cells
module smpp_low ( ONEPOS, ONENEG, TWONEG, INA, INB, PPBIT );
input ONEPOS;
input ONENEG;
input TWONEG;
input INA;
input INB;
output PPBIT;
assign PPBIT = (ONEPOS & INA) | (ONENEG & INB) | TWONEG;
endmodule
module smpp_middle ( ONEPOS, ONENEG, TWOPOS, TWONEG, INA, INB, INC, IND, PPBIT );
input ONEPOS;
input ONENEG;
input TWOPOS;
input TWONEG;
input INA;
input INB;
input INC;
input IND;
output PPBIT;
assign PPBIT = ~ (( ~ (INA & TWOPOS)) & ( ~ (INB & TWONEG)) & ( ~ (INC & ONEPOS)) & ( ~ (IND & ONENEG)));
endmodule
module smpp_high ( ONEPOS, ONENEG, TWOPOS, TWONEG, INA, INB, PPBIT );
input ONEPOS;
input ONENEG;
input TWOPOS;
input TWONEG;
input INA;
input INB;
output PPBIT;
assign PPBIT = ~ ((INA & ONEPOS) | (INB & ONENEG) | (INA & TWOPOS) | (INB & TWONEG));
endmodule
module smr_gate ( INA, INB, INC, PPBIT );
input INA;
input INB;
input INC;
output PPBIT;
assign PPBIT = ( ~ (INA & INB)) & INC;
endmodule
module smdecoder ( INA, INB, INC, TWOPOS, TWONEG, ONEPOS, ONENEG );
input INA;
input INB;
input INC;
output TWOPOS;
output TWONEG;
output ONEPOS;
output ONENEG;
assign TWOPOS = ~ ( ~ (INA & INB & ( ~ INC)));
assign TWONEG = ~ ( ~ (( ~ INA) & ( ~ INB) & INC));
assign ONEPOS = (( ~ INA) & INB & ( ~ INC)) | (( ~ INC) & ( ~ INB) & INA);
assign ONENEG = (INA & ( ~ INB) & INC) | (INC & INB & ( ~ INA));
endmodule
module smfulladder ( DATA_A, DATA_B, DATA_C, SAVE, CARRY );
input DATA_A;
input DATA_B;
input DATA_C;
output SAVE;
output CARRY;
wire TMP;
assign TMP = DATA_A ^ DATA_B;
assign SAVE = TMP ^ DATA_C;
assign CARRY = ~ (( ~ (TMP & DATA_C)) & ( ~ (DATA_A & DATA_B)));
endmodule
module smhalfadder ( DATA_A, DATA_B, SAVE, CARRY );
input DATA_A;
input DATA_B;
output SAVE;
output CARRY;
assign SAVE = DATA_A ^ DATA_B;
assign CARRY = DATA_A & DATA_B;
endmodule
module smffa
(
input clk,
input en_d1,
input D,
output reg Q
);
always @ (posedge clk) begin
Q <= D;
end
endmodule
module smffb
(
input clk,
input en_d2,
input D,
output reg Q
);
always @ (posedge clk) begin
Q <= D;
end
endmodule
module sminvblock ( GIN, GOUT );
input GIN;
output GOUT;
assign GOUT = ~ GIN;
endmodule
module smxxor1 ( A, B, GIN, SUM );
input A;
input B;
input GIN;
output SUM;
assign SUM = ( ~ (A ^ B)) ^ GIN;
endmodule
module smblock0 ( A, B, POUT, GOUT );
input A;
input B;
output POUT;
output GOUT;
assign POUT = ~ (A | B);
assign GOUT = ~ (A & B);
endmodule
module smblock1 ( PIN1, PIN2, GIN1, GIN2, POUT, GOUT );
input PIN1;
input PIN2;
input GIN1;
input GIN2;
output POUT;
output GOUT;
assign POUT = ~ (PIN1 | PIN2);
assign GOUT = ~ (GIN2 & (PIN2 | GIN1));
endmodule
module smblock2 ( PIN1, PIN2, GIN1, GIN2, POUT, GOUT );
input PIN1;
input PIN2;
input GIN1;
input GIN2;
output POUT;
output GOUT;
assign POUT = ~ (PIN1 & PIN2);
assign GOUT = ~ (GIN2 | (PIN2 & GIN1));
endmodule
module smblock1a ( PIN2, GIN1, GIN2, GOUT );
input PIN2;
input GIN1;
input GIN2;
output GOUT;
assign GOUT = ~ (GIN2 & (PIN2 | GIN1));
endmodule
module smblock2a ( PIN2, GIN1, GIN2, GOUT );
input PIN2;
input GIN1;
input GIN2;
output GOUT;
assign GOUT = ~ (GIN2 | (PIN2 & GIN1));
endmodule
// Local Variables:
// compile-command: "vlint --brief --nowarn=MULTMF,MODLNM t_math_wallace_mul.v"
// End:
|
module data_packet_fifo
( input reset,
input clock,
input [31:0]ram_data_in,
input write_enable,
output reg have_space,
output reg [31:0]ram_data_out,
output reg pkt_waiting,
output reg isfull,
output reg [1:0]usb_ram_packet_out,
output reg [1:0]usb_ram_packet_in,
input read_enable,
input pkt_complete,
input skip_packet) ;
/* Some parameters for usage later on */
parameter DATA_WIDTH = 32 ;
parameter PKT_DEPTH = 128 ;
parameter NUM_PACKETS = 4 ;
/* Create the RAM here */
reg [DATA_WIDTH-1:0] usb_ram [PKT_DEPTH*NUM_PACKETS-1:0] ;
/* Create the address signals */
reg [6:0] usb_ram_offset_out ;
//reg [1:0] usb_ram_packet_out ;
reg [6:0] usb_ram_offset_in ;
//reg [1:0] usb_ram_packet_in ;
wire [6-2+NUM_PACKETS:0] usb_ram_aout ;
wire [6-2+NUM_PACKETS:0] usb_ram_ain ;
//reg isfull;
assign usb_ram_aout = {usb_ram_packet_out, usb_ram_offset_out} ;
assign usb_ram_ain = {usb_ram_packet_in, usb_ram_offset_in} ;
// Check if there is one full packet to process
always @(usb_ram_ain, usb_ram_aout, isfull)
begin
if (usb_ram_ain == usb_ram_aout)
pkt_waiting <= isfull ;
else if (usb_ram_ain > usb_ram_aout)
pkt_waiting <= (usb_ram_ain - usb_ram_aout) >= PKT_DEPTH;
else
pkt_waiting <= (usb_ram_ain + 10'b1000000000 - usb_ram_aout) >= PKT_DEPTH;
end
// Check if there is room
always @(usb_ram_ain, usb_ram_aout, isfull)
begin
if (usb_ram_ain == usb_ram_aout)
have_space <= ~isfull;
else if (usb_ram_ain > usb_ram_aout)
have_space <= ((usb_ram_ain - usb_ram_aout) <= PKT_DEPTH * (NUM_PACKETS - 1))? 1'b1 : 1'b0;
else
have_space <= (usb_ram_aout - usb_ram_ain) >= PKT_DEPTH;
end
/* RAM Writing/Reading process */
always @(posedge clock)
begin
if( write_enable )
begin
usb_ram[usb_ram_ain] <= ram_data_in ;
end
ram_data_out <= usb_ram[usb_ram_aout] ;
end
/* RAM Write/Read Address process */
always @(posedge clock)
begin
if( reset )
begin
usb_ram_packet_out <= 0 ;
usb_ram_offset_out <= 0 ;
usb_ram_offset_in <= 0 ;
usb_ram_packet_in <= 0 ;
isfull <= 0;
end
else
begin
if( skip_packet )
begin
usb_ram_packet_out <= usb_ram_packet_out + 1 ;
usb_ram_offset_out <= 0 ;
isfull <= 0;
end
else if(read_enable)
begin
if( usb_ram_offset_out == 7'b1111111 )
begin
isfull <= 0 ;
usb_ram_offset_out <= 0 ;
usb_ram_packet_out <= usb_ram_packet_out + 1 ;
end
else
usb_ram_offset_out <= usb_ram_offset_out + 1 ;
end
if( pkt_complete )
begin
usb_ram_packet_in <= usb_ram_packet_in + 1 ;
usb_ram_offset_in <= 0 ;
if ((usb_ram_packet_in + 2'b1) == usb_ram_packet_out)
isfull <= 1 ;
end
else if( write_enable )
begin
if (usb_ram_offset_in == 7'b1111111)
usb_ram_offset_in <= 7'b1111111 ;
else
usb_ram_offset_in <= usb_ram_offset_in + 1 ;
end
end
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2008 by Mahesh Kumashikar
module t_math_synmul_mul ( /*AUTOARG*/
// Outputs
product_d4,
// Inputs
clk, enable, negate, datA, datB
);
input clk;
input enable;
input negate;
input [31:0] datA;
input [31:0] datB;
// verilator lint_off UNOPTFLAT
output reg [64:0] product_d4;
reg [33:0] datA_d1r;
reg [33:0] datB_d1r;
always @ (posedge clk) begin
if (enable) begin
datA_d1r <= {2'b0,datA};
datB_d1r <= {2'b0,datB};
// The extra multiplier bits were for signed, for this
// test we've ripped that out
if (negate) $stop;
end
end
reg en_d1;
reg en_d2;
reg en_d3;
always @ (posedge clk) begin
en_d1 <= enable;
en_d2 <= en_d1;
en_d3 <= en_d2;
end
wire [63:0] prod_d3;
smmultiplier_34_34 mul (.OPA(datA_d1r),
.OPB(datB_d1r),
.RESULT(prod_d3),
/*AUTOINST*/
// Inputs
.clk (clk),
.en_d1 (en_d1),
.en_d2 (en_d2));
always @ (posedge clk) begin
if (en_d3) begin
product_d4 <= {1'b0,prod_d3};
end
end
endmodule
// The below was originally generated by the "Synthesizable Arithmetic Module Generator"
// at http://modgen.fysel.ntnu.no/~pihl/iwlas98/ then cleaned up by hand.
// Unfortunately the generator no longer appears available. Please contact
// us if you know otherwise.
module smmultiplier_34_34
(
input clk,
input en_d1,
input en_d2,
input [33:0] OPA,
input [33:0] OPB,
output [63:0] RESULT
);
wire [628:0] PPBIT;
wire [66:0] INT_CARRY;
wire [66:0] INT_SUM;
smboothcoder_34_34 db (.OPA(OPA[33:0]), .OPB(OPB[33:0]), .SUMMAND(PPBIT[628:0]) );
smwallace_34_34 dw (.SUMMAND(PPBIT[628:0]), .CARRY(INT_CARRY[66:1]), .SUM(INT_SUM[66:0]),
/*AUTOINST*/
// Inputs
.clk (clk),
.en_d1 (en_d1),
.en_d2 (en_d2));
assign INT_CARRY[0] = 1'b0;
smdblcadder_128_128 dd (.OPA(INT_SUM[63:0]), .OPB(INT_CARRY[63:0]), .CIN (1'b0), .SUM(RESULT));
endmodule
module smdblcadder_128_128 ( OPA, OPB, CIN, SUM );
input [63:0] OPA;
input [63:0] OPB;
input CIN;
output [63:0] SUM;
wire [63:0] INTPROP;
wire [63:0] INTGEN;
wire [0:0] PBIT;
wire [63:0] CARRY;
smprestage_128 dp (OPA[63:0], OPB[63:0], CIN, INTPROP, INTGEN );
smdblctree_128 dd (INTPROP[63:0], INTGEN[63:0], CARRY[63:0], PBIT );
smxorstage_128 dx (OPA[63:0], OPB[63:0], PBIT[0], CARRY[63:0], SUM );
endmodule
module smdblctree_128 ( PIN, GIN, GOUT, POUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] GOUT;
output [0:0] POUT;
wire [63:0] INTPROP_0;
wire [63:0] INTGEN_0;
wire [63:0] INTPROP_1;
wire [63:0] INTGEN_1;
wire [63:0] INTPROP_2;
wire [63:0] INTGEN_2;
wire [63:0] INTPROP_3;
wire [63:0] INTGEN_3;
wire [63:0] INTPROP_4;
wire [63:0] INTGEN_4;
wire [63:0] INTPROP_5;
wire [63:0] INTGEN_5;
smdblc_0_128 ddb0 (.PIN(PIN), .GIN(GIN), .POUT(INTPROP_0), .GOUT(INTGEN_0) );
smdblc_1_128 ddb1 (.PIN(INTPROP_0), .GIN(INTGEN_0), .POUT(INTPROP_1), .GOUT(INTGEN_1) );
smdblc_2_128 ddb2 (.PIN(INTPROP_1), .GIN(INTGEN_1), .POUT(INTPROP_2), .GOUT(INTGEN_2) );
smdblc_3_128 ddb3 (.PIN(INTPROP_2), .GIN(INTGEN_2), .POUT(INTPROP_3), .GOUT(INTGEN_3) );
smdblc_4_128 ddb4 (.PIN(INTPROP_3), .GIN(INTGEN_3), .POUT(INTPROP_4), .GOUT(INTGEN_4) );
smdblc_5_128 ddb5 (.PIN(INTPROP_4), .GIN(INTGEN_4), .POUT(INTPROP_5), .GOUT(INTGEN_5) );
smdblc_6_128 ddb6 (.PIN(INTPROP_5), .GIN(INTGEN_5), .POUT(POUT), .GOUT(GOUT) );
endmodule
module smwallace_34_34
(
input clk,
input en_d1,
input en_d2,
input [628:0] SUMMAND,
output [65:0] CARRY,
output [66:0] SUM
);
wire [628:0] LATCHED_PP;
wire [551:0] INT_CARRY;
wire [687:0] INT_SUM;
smffa dla0 (.D(SUMMAND[0]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[0]) );
smffa dla1 (.D(SUMMAND[1]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[1]) );
smhalfadder dha0 (.DATA_A (LATCHED_PP[0]), .DATA_B (LATCHED_PP[1]), .SAVE (INT_SUM[0]), .CARRY (INT_CARRY[0]) );
smffb dla2 (.D(INT_SUM[0]), .clk(clk), .en_d2(en_d2), .Q(SUM[0]) );
smffb dla3 (.D(INT_CARRY[0]), .clk(clk), .en_d2(en_d2), .Q(CARRY[0]) );
smffa dla4 (.D(SUMMAND[2]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[2]) );
assign INT_SUM[1] = LATCHED_PP[2];
assign CARRY[1] = 1'b0;
smffb dla5 (.D(INT_SUM[1]), .clk(clk), .en_d2(en_d2), .Q(SUM[1]) );
smffa dla6 (.D(SUMMAND[3]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[3]) );
smffa dla7 (.D(SUMMAND[4]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[4]) );
smffa dla8 (.D(SUMMAND[5]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[5]) );
smfulladder dfa0 (.DATA_A (LATCHED_PP[3]), .DATA_B (LATCHED_PP[4]), .DATA_C (LATCHED_PP[5]), .SAVE (INT_SUM[2]), .CARRY (INT_CARRY[1]) );
smffb dla9 (.D(INT_SUM[2]), .clk(clk), .en_d2(en_d2), .Q(SUM[2]) );
smffb dla10 (.D(INT_CARRY[1]), .clk(clk), .en_d2(en_d2), .Q(CARRY[2]) );
smffa dla11 (.D(SUMMAND[6]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[6]) );
smffa dla12 (.D(SUMMAND[7]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[7]) );
smhalfadder dha1 (.DATA_A (LATCHED_PP[6]), .DATA_B (LATCHED_PP[7]), .SAVE (INT_SUM[3]), .CARRY (INT_CARRY[2]) );
smffb dla13 (.D(INT_SUM[3]), .clk(clk), .en_d2(en_d2), .Q(SUM[3]) );
smffb dla14 (.D(INT_CARRY[2]), .clk(clk), .en_d2(en_d2), .Q(CARRY[3]) );
smffa dla15 (.D(SUMMAND[8]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[8]) );
smffa dla16 (.D(SUMMAND[9]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[9]) );
smffa dla17 (.D(SUMMAND[10]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[10]) );
smfulladder dfa1 (.DATA_A (LATCHED_PP[8]), .DATA_B (LATCHED_PP[9]), .DATA_C (LATCHED_PP[10]), .SAVE (INT_SUM[4]), .CARRY (INT_CARRY[4]) );
smffa dla18 (.D(SUMMAND[11]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[11]) );
assign INT_SUM[5] = LATCHED_PP[11];
smhalfadder dha2 (.DATA_A (INT_SUM[4]), .DATA_B (INT_SUM[5]), .SAVE (INT_SUM[6]), .CARRY (INT_CARRY[3]) );
smffb dla19 (.D(INT_SUM[6]), .clk(clk), .en_d2(en_d2), .Q(SUM[4]) );
smffb dla20 (.D(INT_CARRY[3]), .clk(clk), .en_d2(en_d2), .Q(CARRY[4]) );
smffa dla21 (.D(SUMMAND[12]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[12]) );
smffa dla22 (.D(SUMMAND[13]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[13]) );
smffa dla23 (.D(SUMMAND[14]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[14]) );
smfulladder dfa2 (.DATA_A (LATCHED_PP[12]), .DATA_B (LATCHED_PP[13]), .DATA_C (LATCHED_PP[14]), .SAVE (INT_SUM[7]), .CARRY (INT_CARRY[6]) );
smhalfadder dha3 (.DATA_A (INT_SUM[7]), .DATA_B (INT_CARRY[4]), .SAVE (INT_SUM[8]), .CARRY (INT_CARRY[5]) );
smffb dla24 (.D(INT_SUM[8]), .clk(clk), .en_d2(en_d2), .Q(SUM[5]) );
smffb dla25 (.D(INT_CARRY[5]), .clk(clk), .en_d2(en_d2), .Q(CARRY[5]) );
smffa dla26 (.D(SUMMAND[15]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[15]) );
smffa dla27 (.D(SUMMAND[16]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[16]) );
smffa dla28 (.D(SUMMAND[17]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[17]) );
smfulladder dfa3 (.DATA_A (LATCHED_PP[15]), .DATA_B (LATCHED_PP[16]), .DATA_C (LATCHED_PP[17]), .SAVE (INT_SUM[9]), .CARRY (INT_CARRY[8]) );
smffa dla29 (.D(SUMMAND[18]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[18]) );
smffa dla30 (.D(SUMMAND[19]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[19]) );
smhalfadder dha4 (.DATA_A (LATCHED_PP[18]), .DATA_B (LATCHED_PP[19]), .SAVE (INT_SUM[10]), .CARRY (INT_CARRY[9]) );
smfulladder dfa4 (.DATA_A (INT_SUM[9]), .DATA_B (INT_SUM[10]), .DATA_C (INT_CARRY[6]), .SAVE (INT_SUM[11]), .CARRY (INT_CARRY[7]) );
smffb dla31 (.D(INT_SUM[11]), .clk(clk), .en_d2(en_d2), .Q(SUM[6]) );
smffb dla32 (.D(INT_CARRY[7]), .clk(clk), .en_d2(en_d2), .Q(CARRY[6]) );
smffa dla33 (.D(SUMMAND[20]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[20]) );
smffa dla34 (.D(SUMMAND[21]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[21]) );
smffa dla35 (.D(SUMMAND[22]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[22]) );
smfulladder dfa5 (.DATA_A (LATCHED_PP[20]), .DATA_B (LATCHED_PP[21]), .DATA_C (LATCHED_PP[22]), .SAVE (INT_SUM[12]), .CARRY (INT_CARRY[11]) );
smffa dla36 (.D(SUMMAND[23]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[23]) );
assign INT_SUM[13] = LATCHED_PP[23];
smfulladder dfa6 (.DATA_A (INT_SUM[12]), .DATA_B (INT_SUM[13]), .DATA_C (INT_CARRY[8]), .SAVE (INT_SUM[14]), .CARRY (INT_CARRY[12]) );
assign INT_SUM[15] = INT_CARRY[9];
smhalfadder dha5 (.DATA_A (INT_SUM[14]), .DATA_B (INT_SUM[15]), .SAVE (INT_SUM[16]), .CARRY (INT_CARRY[10]) );
smffb dla37 (.D(INT_SUM[16]), .clk(clk), .en_d2(en_d2), .Q(SUM[7]) );
smffb dla38 (.D(INT_CARRY[10]), .clk(clk), .en_d2(en_d2), .Q(CARRY[7]) );
smffa dla39 (.D(SUMMAND[24]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[24]) );
smffa dla40 (.D(SUMMAND[25]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[25]) );
smffa dla41 (.D(SUMMAND[26]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[26]) );
smfulladder dfa7 (.DATA_A (LATCHED_PP[24]), .DATA_B (LATCHED_PP[25]), .DATA_C (LATCHED_PP[26]), .SAVE (INT_SUM[17]), .CARRY (INT_CARRY[14]) );
smffa dla42 (.D(SUMMAND[27]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[27]) );
smffa dla43 (.D(SUMMAND[28]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[28]) );
smffa dla44 (.D(SUMMAND[29]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[29]) );
smfulladder dfa8 (.DATA_A (LATCHED_PP[27]), .DATA_B (LATCHED_PP[28]), .DATA_C (LATCHED_PP[29]), .SAVE (INT_SUM[18]), .CARRY (INT_CARRY[15]) );
smfulladder dfa9 (.DATA_A (INT_SUM[17]), .DATA_B (INT_SUM[18]), .DATA_C (INT_CARRY[11]), .SAVE (INT_SUM[19]), .CARRY (INT_CARRY[16]) );
smhalfadder dha6 (.DATA_A (INT_SUM[19]), .DATA_B (INT_CARRY[12]), .SAVE (INT_SUM[20]), .CARRY (INT_CARRY[13]) );
smffb dla45 (.D(INT_SUM[20]), .clk(clk), .en_d2(en_d2), .Q(SUM[8]) );
smffb dla46 (.D(INT_CARRY[13]), .clk(clk), .en_d2(en_d2), .Q(CARRY[8]) );
smffa dla47 (.D(SUMMAND[30]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[30]) );
smffa dla48 (.D(SUMMAND[31]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[31]) );
smffa dla49 (.D(SUMMAND[32]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[32]) );
smfulladder dfa10 (.DATA_A (LATCHED_PP[30]), .DATA_B (LATCHED_PP[31]), .DATA_C (LATCHED_PP[32]), .SAVE (INT_SUM[21]), .CARRY (INT_CARRY[18]) );
smffa dla50 (.D(SUMMAND[33]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[33]) );
smffa dla51 (.D(SUMMAND[34]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[34]) );
smhalfadder dha7 (.DATA_A (LATCHED_PP[33]), .DATA_B (LATCHED_PP[34]), .SAVE (INT_SUM[22]), .CARRY (INT_CARRY[19]) );
smfulladder dfa11 (.DATA_A (INT_SUM[21]), .DATA_B (INT_SUM[22]), .DATA_C (INT_CARRY[14]), .SAVE (INT_SUM[23]), .CARRY (INT_CARRY[20]) );
assign INT_SUM[24] = INT_CARRY[15];
smfulladder dfa12 (.DATA_A (INT_SUM[23]), .DATA_B (INT_SUM[24]), .DATA_C (INT_CARRY[16]), .SAVE (INT_SUM[25]), .CARRY (INT_CARRY[17]) );
smffb dla52 (.D(INT_SUM[25]), .clk(clk), .en_d2(en_d2), .Q(SUM[9]) );
smffb dla53 (.D(INT_CARRY[17]), .clk(clk), .en_d2(en_d2), .Q(CARRY[9]) );
smffa dla54 (.D(SUMMAND[35]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[35]) );
smffa dla55 (.D(SUMMAND[36]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[36]) );
smffa dla56 (.D(SUMMAND[37]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[37]) );
smfulladder dfa13 (.DATA_A (LATCHED_PP[35]), .DATA_B (LATCHED_PP[36]), .DATA_C (LATCHED_PP[37]), .SAVE (INT_SUM[26]), .CARRY (INT_CARRY[22]) );
smffa dla57 (.D(SUMMAND[38]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[38]) );
smffa dla58 (.D(SUMMAND[39]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[39]) );
smffa dla59 (.D(SUMMAND[40]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[40]) );
smfulladder dfa14 (.DATA_A (LATCHED_PP[38]), .DATA_B (LATCHED_PP[39]), .DATA_C (LATCHED_PP[40]), .SAVE (INT_SUM[27]), .CARRY (INT_CARRY[23]) );
smffa dla60 (.D(SUMMAND[41]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[41]) );
assign INT_SUM[28] = LATCHED_PP[41];
smfulladder dfa15 (.DATA_A (INT_SUM[26]), .DATA_B (INT_SUM[27]), .DATA_C (INT_SUM[28]), .SAVE (INT_SUM[29]), .CARRY (INT_CARRY[24]) );
smhalfadder dha8 (.DATA_A (INT_CARRY[18]), .DATA_B (INT_CARRY[19]), .SAVE (INT_SUM[30]), .CARRY (INT_CARRY[25]) );
smfulladder dfa16 (.DATA_A (INT_SUM[29]), .DATA_B (INT_SUM[30]), .DATA_C (INT_CARRY[20]), .SAVE (INT_SUM[31]), .CARRY (INT_CARRY[21]) );
smffb dla61 (.D(INT_SUM[31]), .clk(clk), .en_d2(en_d2), .Q(SUM[10]) );
smffb dla62 (.D(INT_CARRY[21]), .clk(clk), .en_d2(en_d2), .Q(CARRY[10]) );
smffa dla63 (.D(SUMMAND[42]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[42]) );
smffa dla64 (.D(SUMMAND[43]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[43]) );
smffa dla65 (.D(SUMMAND[44]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[44]) );
smfulladder dfa17 (.DATA_A (LATCHED_PP[42]), .DATA_B (LATCHED_PP[43]), .DATA_C (LATCHED_PP[44]), .SAVE (INT_SUM[32]), .CARRY (INT_CARRY[27]) );
smffa dla66 (.D(SUMMAND[45]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[45]) );
smffa dla67 (.D(SUMMAND[46]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[46]) );
smffa dla68 (.D(SUMMAND[47]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[47]) );
smfulladder dfa18 (.DATA_A (LATCHED_PP[45]), .DATA_B (LATCHED_PP[46]), .DATA_C (LATCHED_PP[47]), .SAVE (INT_SUM[33]), .CARRY (INT_CARRY[28]) );
smfulladder dfa19 (.DATA_A (INT_SUM[32]), .DATA_B (INT_SUM[33]), .DATA_C (INT_CARRY[22]), .SAVE (INT_SUM[34]), .CARRY (INT_CARRY[29]) );
assign INT_SUM[35] = INT_CARRY[23];
smfulladder dfa20 (.DATA_A (INT_SUM[34]), .DATA_B (INT_SUM[35]), .DATA_C (INT_CARRY[24]), .SAVE (INT_SUM[36]), .CARRY (INT_CARRY[30]) );
assign INT_SUM[37] = INT_CARRY[25];
smhalfadder dha9 (.DATA_A (INT_SUM[36]), .DATA_B (INT_SUM[37]), .SAVE (INT_SUM[38]), .CARRY (INT_CARRY[26]) );
smffb dla69 (.D(INT_SUM[38]), .clk(clk), .en_d2(en_d2), .Q(SUM[11]) );
smffb dla70 (.D(INT_CARRY[26]), .clk(clk), .en_d2(en_d2), .Q(CARRY[11]) );
smffa dla71 (.D(SUMMAND[48]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[48]) );
smffa dla72 (.D(SUMMAND[49]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[49]) );
smffa dla73 (.D(SUMMAND[50]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[50]) );
smfulladder dfa21 (.DATA_A (LATCHED_PP[48]), .DATA_B (LATCHED_PP[49]), .DATA_C (LATCHED_PP[50]), .SAVE (INT_SUM[39]), .CARRY (INT_CARRY[32]) );
smffa dla74 (.D(SUMMAND[51]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[51]) );
smffa dla75 (.D(SUMMAND[52]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[52]) );
smffa dla76 (.D(SUMMAND[53]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[53]) );
smfulladder dfa22 (.DATA_A (LATCHED_PP[51]), .DATA_B (LATCHED_PP[52]), .DATA_C (LATCHED_PP[53]), .SAVE (INT_SUM[40]), .CARRY (INT_CARRY[33]) );
smffa dla77 (.D(SUMMAND[54]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[54]) );
assign INT_SUM[41] = LATCHED_PP[54];
smffa dla78 (.D(SUMMAND[55]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[55]) );
assign INT_SUM[42] = LATCHED_PP[55];
smfulladder dfa23 (.DATA_A (INT_SUM[39]), .DATA_B (INT_SUM[40]), .DATA_C (INT_SUM[41]), .SAVE (INT_SUM[43]), .CARRY (INT_CARRY[34]) );
smfulladder dfa24 (.DATA_A (INT_SUM[42]), .DATA_B (INT_CARRY[27]), .DATA_C (INT_CARRY[28]), .SAVE (INT_SUM[44]), .CARRY (INT_CARRY[35]) );
smfulladder dfa25 (.DATA_A (INT_SUM[43]), .DATA_B (INT_SUM[44]), .DATA_C (INT_CARRY[29]), .SAVE (INT_SUM[45]), .CARRY (INT_CARRY[36]) );
smhalfadder dha10 (.DATA_A (INT_SUM[45]), .DATA_B (INT_CARRY[30]), .SAVE (INT_SUM[46]), .CARRY (INT_CARRY[31]) );
smffb dla79 (.D(INT_SUM[46]), .clk(clk), .en_d2(en_d2), .Q(SUM[12]) );
smffb dla80 (.D(INT_CARRY[31]), .clk(clk), .en_d2(en_d2), .Q(CARRY[12]) );
smffa dla81 (.D(SUMMAND[56]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[56]) );
smffa dla82 (.D(SUMMAND[57]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[57]) );
smffa dla83 (.D(SUMMAND[58]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[58]) );
smfulladder dfa26 (.DATA_A (LATCHED_PP[56]), .DATA_B (LATCHED_PP[57]), .DATA_C (LATCHED_PP[58]), .SAVE (INT_SUM[47]), .CARRY (INT_CARRY[38]) );
smffa dla84 (.D(SUMMAND[59]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[59]) );
smffa dla85 (.D(SUMMAND[60]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[60]) );
smffa dla86 (.D(SUMMAND[61]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[61]) );
smfulladder dfa27 (.DATA_A (LATCHED_PP[59]), .DATA_B (LATCHED_PP[60]), .DATA_C (LATCHED_PP[61]), .SAVE (INT_SUM[48]), .CARRY (INT_CARRY[39]) );
smffa dla87 (.D(SUMMAND[62]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[62]) );
assign INT_SUM[49] = LATCHED_PP[62];
smfulladder dfa28 (.DATA_A (INT_SUM[47]), .DATA_B (INT_SUM[48]), .DATA_C (INT_SUM[49]), .SAVE (INT_SUM[50]), .CARRY (INT_CARRY[40]) );
smhalfadder dha11 (.DATA_A (INT_CARRY[32]), .DATA_B (INT_CARRY[33]), .SAVE (INT_SUM[51]), .CARRY (INT_CARRY[41]) );
smfulladder dfa29 (.DATA_A (INT_SUM[50]), .DATA_B (INT_SUM[51]), .DATA_C (INT_CARRY[34]), .SAVE (INT_SUM[52]), .CARRY (INT_CARRY[42]) );
assign INT_SUM[53] = INT_CARRY[35];
smfulladder dfa30 (.DATA_A (INT_SUM[52]), .DATA_B (INT_SUM[53]), .DATA_C (INT_CARRY[36]), .SAVE (INT_SUM[54]), .CARRY (INT_CARRY[37]) );
smffb dla88 (.D(INT_SUM[54]), .clk(clk), .en_d2(en_d2), .Q(SUM[13]) );
smffb dla89 (.D(INT_CARRY[37]), .clk(clk), .en_d2(en_d2), .Q(CARRY[13]) );
smffa dla90 (.D(SUMMAND[63]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[63]) );
smffa dla91 (.D(SUMMAND[64]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[64]) );
smffa dla92 (.D(SUMMAND[65]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[65]) );
smfulladder dfa31 (.DATA_A (LATCHED_PP[63]), .DATA_B (LATCHED_PP[64]), .DATA_C (LATCHED_PP[65]), .SAVE (INT_SUM[55]), .CARRY (INT_CARRY[44]) );
smffa dla93 (.D(SUMMAND[66]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[66]) );
smffa dla94 (.D(SUMMAND[67]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[67]) );
smffa dla95 (.D(SUMMAND[68]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[68]) );
smfulladder dfa32 (.DATA_A (LATCHED_PP[66]), .DATA_B (LATCHED_PP[67]), .DATA_C (LATCHED_PP[68]), .SAVE (INT_SUM[56]), .CARRY (INT_CARRY[45]) );
smffa dla96 (.D(SUMMAND[69]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[69]) );
smffa dla97 (.D(SUMMAND[70]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[70]) );
smffa dla98 (.D(SUMMAND[71]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[71]) );
smfulladder dfa33 (.DATA_A (LATCHED_PP[69]), .DATA_B (LATCHED_PP[70]), .DATA_C (LATCHED_PP[71]), .SAVE (INT_SUM[57]), .CARRY (INT_CARRY[46]) );
smfulladder dfa34 (.DATA_A (INT_SUM[55]), .DATA_B (INT_SUM[56]), .DATA_C (INT_SUM[57]), .SAVE (INT_SUM[58]), .CARRY (INT_CARRY[47]) );
smhalfadder dha12 (.DATA_A (INT_CARRY[38]), .DATA_B (INT_CARRY[39]), .SAVE (INT_SUM[59]), .CARRY (INT_CARRY[48]) );
smfulladder dfa35 (.DATA_A (INT_SUM[58]), .DATA_B (INT_SUM[59]), .DATA_C (INT_CARRY[40]), .SAVE (INT_SUM[60]), .CARRY (INT_CARRY[49]) );
assign INT_SUM[61] = INT_CARRY[41];
smfulladder dfa36 (.DATA_A (INT_SUM[60]), .DATA_B (INT_SUM[61]), .DATA_C (INT_CARRY[42]), .SAVE (INT_SUM[62]), .CARRY (INT_CARRY[43]) );
smffb dla99 (.D(INT_SUM[62]), .clk(clk), .en_d2(en_d2), .Q(SUM[14]) );
smffb dla100 (.D(INT_CARRY[43]), .clk(clk), .en_d2(en_d2), .Q(CARRY[14]) );
smffa dla101 (.D(SUMMAND[72]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[72]) );
smffa dla102 (.D(SUMMAND[73]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[73]) );
smffa dla103 (.D(SUMMAND[74]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[74]) );
smfulladder dfa37 (.DATA_A (LATCHED_PP[72]), .DATA_B (LATCHED_PP[73]), .DATA_C (LATCHED_PP[74]), .SAVE (INT_SUM[63]), .CARRY (INT_CARRY[51]) );
smffa dla104 (.D(SUMMAND[75]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[75]) );
smffa dla105 (.D(SUMMAND[76]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[76]) );
smffa dla106 (.D(SUMMAND[77]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[77]) );
smfulladder dfa38 (.DATA_A (LATCHED_PP[75]), .DATA_B (LATCHED_PP[76]), .DATA_C (LATCHED_PP[77]), .SAVE (INT_SUM[64]), .CARRY (INT_CARRY[52]) );
smffa dla107 (.D(SUMMAND[78]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[78]) );
smffa dla108 (.D(SUMMAND[79]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[79]) );
smhalfadder dha13 (.DATA_A (LATCHED_PP[78]), .DATA_B (LATCHED_PP[79]), .SAVE (INT_SUM[65]), .CARRY (INT_CARRY[53]) );
smfulladder dfa39 (.DATA_A (INT_SUM[63]), .DATA_B (INT_SUM[64]), .DATA_C (INT_SUM[65]), .SAVE (INT_SUM[66]), .CARRY (INT_CARRY[54]) );
smfulladder dfa40 (.DATA_A (INT_CARRY[44]), .DATA_B (INT_CARRY[45]), .DATA_C (INT_CARRY[46]), .SAVE (INT_SUM[67]), .CARRY (INT_CARRY[55]) );
smfulladder dfa41 (.DATA_A (INT_SUM[66]), .DATA_B (INT_SUM[67]), .DATA_C (INT_CARRY[47]), .SAVE (INT_SUM[68]), .CARRY (INT_CARRY[56]) );
assign INT_SUM[69] = INT_CARRY[48];
smfulladder dfa42 (.DATA_A (INT_SUM[68]), .DATA_B (INT_SUM[69]), .DATA_C (INT_CARRY[49]), .SAVE (INT_SUM[70]), .CARRY (INT_CARRY[50]) );
smffb dla109 (.D(INT_SUM[70]), .clk(clk), .en_d2(en_d2), .Q(SUM[15]) );
smffb dla110 (.D(INT_CARRY[50]), .clk(clk), .en_d2(en_d2), .Q(CARRY[15]) );
smffa dla111 (.D(SUMMAND[80]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[80]) );
smffa dla112 (.D(SUMMAND[81]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[81]) );
smffa dla113 (.D(SUMMAND[82]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[82]) );
smfulladder dfa43 (.DATA_A (LATCHED_PP[80]), .DATA_B (LATCHED_PP[81]), .DATA_C (LATCHED_PP[82]), .SAVE (INT_SUM[71]), .CARRY (INT_CARRY[58]) );
smffa dla114 (.D(SUMMAND[83]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[83]) );
smffa dla115 (.D(SUMMAND[84]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[84]) );
smffa dla116 (.D(SUMMAND[85]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[85]) );
smfulladder dfa44 (.DATA_A (LATCHED_PP[83]), .DATA_B (LATCHED_PP[84]), .DATA_C (LATCHED_PP[85]), .SAVE (INT_SUM[72]), .CARRY (INT_CARRY[59]) );
smffa dla117 (.D(SUMMAND[86]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[86]) );
smffa dla118 (.D(SUMMAND[87]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[87]) );
smffa dla119 (.D(SUMMAND[88]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[88]) );
smfulladder dfa45 (.DATA_A (LATCHED_PP[86]), .DATA_B (LATCHED_PP[87]), .DATA_C (LATCHED_PP[88]), .SAVE (INT_SUM[73]), .CARRY (INT_CARRY[60]) );
smffa dla120 (.D(SUMMAND[89]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[89]) );
assign INT_SUM[74] = LATCHED_PP[89];
smfulladder dfa46 (.DATA_A (INT_SUM[71]), .DATA_B (INT_SUM[72]), .DATA_C (INT_SUM[73]), .SAVE (INT_SUM[75]), .CARRY (INT_CARRY[61]) );
smfulladder dfa47 (.DATA_A (INT_SUM[74]), .DATA_B (INT_CARRY[51]), .DATA_C (INT_CARRY[52]), .SAVE (INT_SUM[76]), .CARRY (INT_CARRY[62]) );
assign INT_SUM[77] = INT_CARRY[53];
smfulladder dfa48 (.DATA_A (INT_SUM[75]), .DATA_B (INT_SUM[76]), .DATA_C (INT_SUM[77]), .SAVE (INT_SUM[78]), .CARRY (INT_CARRY[63]) );
smhalfadder dha14 (.DATA_A (INT_CARRY[54]), .DATA_B (INT_CARRY[55]), .SAVE (INT_SUM[79]), .CARRY (INT_CARRY[64]) );
smfulladder dfa49 (.DATA_A (INT_SUM[78]), .DATA_B (INT_SUM[79]), .DATA_C (INT_CARRY[56]), .SAVE (INT_SUM[80]), .CARRY (INT_CARRY[57]) );
smffb dla121 (.D(INT_SUM[80]), .clk(clk), .en_d2(en_d2), .Q(SUM[16]) );
smffb dla122 (.D(INT_CARRY[57]), .clk(clk), .en_d2(en_d2), .Q(CARRY[16]) );
smffa dla123 (.D(SUMMAND[90]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[90]) );
smffa dla124 (.D(SUMMAND[91]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[91]) );
smffa dla125 (.D(SUMMAND[92]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[92]) );
smfulladder dfa50 (.DATA_A (LATCHED_PP[90]), .DATA_B (LATCHED_PP[91]), .DATA_C (LATCHED_PP[92]), .SAVE (INT_SUM[81]), .CARRY (INT_CARRY[66]) );
smffa dla126 (.D(SUMMAND[93]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[93]) );
smffa dla127 (.D(SUMMAND[94]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[94]) );
smffa dla128 (.D(SUMMAND[95]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[95]) );
smfulladder dfa51 (.DATA_A (LATCHED_PP[93]), .DATA_B (LATCHED_PP[94]), .DATA_C (LATCHED_PP[95]), .SAVE (INT_SUM[82]), .CARRY (INT_CARRY[67]) );
smffa dla129 (.D(SUMMAND[96]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[96]) );
smffa dla130 (.D(SUMMAND[97]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[97]) );
smffa dla131 (.D(SUMMAND[98]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[98]) );
smfulladder dfa52 (.DATA_A (LATCHED_PP[96]), .DATA_B (LATCHED_PP[97]), .DATA_C (LATCHED_PP[98]), .SAVE (INT_SUM[83]), .CARRY (INT_CARRY[68]) );
smfulladder dfa53 (.DATA_A (INT_SUM[81]), .DATA_B (INT_SUM[82]), .DATA_C (INT_SUM[83]), .SAVE (INT_SUM[84]), .CARRY (INT_CARRY[69]) );
smfulladder dfa54 (.DATA_A (INT_CARRY[58]), .DATA_B (INT_CARRY[59]), .DATA_C (INT_CARRY[60]), .SAVE (INT_SUM[85]), .CARRY (INT_CARRY[70]) );
smfulladder dfa55 (.DATA_A (INT_SUM[84]), .DATA_B (INT_SUM[85]), .DATA_C (INT_CARRY[61]), .SAVE (INT_SUM[86]), .CARRY (INT_CARRY[71]) );
assign INT_SUM[87] = INT_CARRY[62];
smfulladder dfa56 (.DATA_A (INT_SUM[86]), .DATA_B (INT_SUM[87]), .DATA_C (INT_CARRY[63]), .SAVE (INT_SUM[88]), .CARRY (INT_CARRY[72]) );
assign INT_SUM[89] = INT_CARRY[64];
smhalfadder dha15 (.DATA_A (INT_SUM[88]), .DATA_B (INT_SUM[89]), .SAVE (INT_SUM[90]), .CARRY (INT_CARRY[65]) );
smffb dla132 (.D(INT_SUM[90]), .clk(clk), .en_d2(en_d2), .Q(SUM[17]) );
smffb dla133 (.D(INT_CARRY[65]), .clk(clk), .en_d2(en_d2), .Q(CARRY[17]) );
smffa dla134 (.D(SUMMAND[99]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[99]) );
smffa dla135 (.D(SUMMAND[100]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[100]) );
smffa dla136 (.D(SUMMAND[101]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[101]) );
smfulladder dfa57 (.DATA_A (LATCHED_PP[99]), .DATA_B (LATCHED_PP[100]), .DATA_C (LATCHED_PP[101]), .SAVE (INT_SUM[91]), .CARRY (INT_CARRY[74]) );
smffa dla137 (.D(SUMMAND[102]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[102]) );
smffa dla138 (.D(SUMMAND[103]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[103]) );
smffa dla139 (.D(SUMMAND[104]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[104]) );
smfulladder dfa58 (.DATA_A (LATCHED_PP[102]), .DATA_B (LATCHED_PP[103]), .DATA_C (LATCHED_PP[104]), .SAVE (INT_SUM[92]), .CARRY (INT_CARRY[75]) );
smffa dla140 (.D(SUMMAND[105]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[105]) );
smffa dla141 (.D(SUMMAND[106]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[106]) );
smffa dla142 (.D(SUMMAND[107]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[107]) );
smfulladder dfa59 (.DATA_A (LATCHED_PP[105]), .DATA_B (LATCHED_PP[106]), .DATA_C (LATCHED_PP[107]), .SAVE (INT_SUM[93]), .CARRY (INT_CARRY[76]) );
smffa dla143 (.D(SUMMAND[108]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[108]) );
assign INT_SUM[94] = LATCHED_PP[108];
smffa dla144 (.D(SUMMAND[109]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[109]) );
assign INT_SUM[95] = LATCHED_PP[109];
smfulladder dfa60 (.DATA_A (INT_SUM[91]), .DATA_B (INT_SUM[92]), .DATA_C (INT_SUM[93]), .SAVE (INT_SUM[96]), .CARRY (INT_CARRY[77]) );
smfulladder dfa61 (.DATA_A (INT_SUM[94]), .DATA_B (INT_SUM[95]), .DATA_C (INT_CARRY[66]), .SAVE (INT_SUM[97]), .CARRY (INT_CARRY[78]) );
assign INT_SUM[98] = INT_CARRY[67];
assign INT_SUM[99] = INT_CARRY[68];
smfulladder dfa62 (.DATA_A (INT_SUM[96]), .DATA_B (INT_SUM[97]), .DATA_C (INT_SUM[98]), .SAVE (INT_SUM[100]), .CARRY (INT_CARRY[79]) );
smfulladder dfa63 (.DATA_A (INT_SUM[99]), .DATA_B (INT_CARRY[69]), .DATA_C (INT_CARRY[70]), .SAVE (INT_SUM[101]), .CARRY (INT_CARRY[80]) );
smfulladder dfa64 (.DATA_A (INT_SUM[100]), .DATA_B (INT_SUM[101]), .DATA_C (INT_CARRY[71]), .SAVE (INT_SUM[102]), .CARRY (INT_CARRY[81]) );
smhalfadder dha16 (.DATA_A (INT_SUM[102]), .DATA_B (INT_CARRY[72]), .SAVE (INT_SUM[103]), .CARRY (INT_CARRY[73]) );
smffb dla145 (.D(INT_SUM[103]), .clk(clk), .en_d2(en_d2), .Q(SUM[18]) );
smffb dla146 (.D(INT_CARRY[73]), .clk(clk), .en_d2(en_d2), .Q(CARRY[18]) );
smffa dla147 (.D(SUMMAND[110]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[110]) );
smffa dla148 (.D(SUMMAND[111]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[111]) );
smffa dla149 (.D(SUMMAND[112]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[112]) );
smfulladder dfa65 (.DATA_A (LATCHED_PP[110]), .DATA_B (LATCHED_PP[111]), .DATA_C (LATCHED_PP[112]), .SAVE (INT_SUM[104]), .CARRY (INT_CARRY[83]) );
smffa dla150 (.D(SUMMAND[113]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[113]) );
smffa dla151 (.D(SUMMAND[114]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[114]) );
smffa dla152 (.D(SUMMAND[115]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[115]) );
smfulladder dfa66 (.DATA_A (LATCHED_PP[113]), .DATA_B (LATCHED_PP[114]), .DATA_C (LATCHED_PP[115]), .SAVE (INT_SUM[105]), .CARRY (INT_CARRY[84]) );
smffa dla153 (.D(SUMMAND[116]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[116]) );
smffa dla154 (.D(SUMMAND[117]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[117]) );
smffa dla155 (.D(SUMMAND[118]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[118]) );
smfulladder dfa67 (.DATA_A (LATCHED_PP[116]), .DATA_B (LATCHED_PP[117]), .DATA_C (LATCHED_PP[118]), .SAVE (INT_SUM[106]), .CARRY (INT_CARRY[85]) );
smffa dla156 (.D(SUMMAND[119]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[119]) );
assign INT_SUM[107] = LATCHED_PP[119];
smfulladder dfa68 (.DATA_A (INT_SUM[104]), .DATA_B (INT_SUM[105]), .DATA_C (INT_SUM[106]), .SAVE (INT_SUM[108]), .CARRY (INT_CARRY[86]) );
smfulladder dfa69 (.DATA_A (INT_SUM[107]), .DATA_B (INT_CARRY[74]), .DATA_C (INT_CARRY[75]), .SAVE (INT_SUM[109]), .CARRY (INT_CARRY[87]) );
assign INT_SUM[110] = INT_CARRY[76];
smfulladder dfa70 (.DATA_A (INT_SUM[108]), .DATA_B (INT_SUM[109]), .DATA_C (INT_SUM[110]), .SAVE (INT_SUM[111]), .CARRY (INT_CARRY[88]) );
smhalfadder dha17 (.DATA_A (INT_CARRY[77]), .DATA_B (INT_CARRY[78]), .SAVE (INT_SUM[112]), .CARRY (INT_CARRY[89]) );
smfulladder dfa71 (.DATA_A (INT_SUM[111]), .DATA_B (INT_SUM[112]), .DATA_C (INT_CARRY[79]), .SAVE (INT_SUM[113]), .CARRY (INT_CARRY[90]) );
assign INT_SUM[114] = INT_CARRY[80];
smfulladder dfa72 (.DATA_A (INT_SUM[113]), .DATA_B (INT_SUM[114]), .DATA_C (INT_CARRY[81]), .SAVE (INT_SUM[115]), .CARRY (INT_CARRY[82]) );
smffb dla157 (.D(INT_SUM[115]), .clk(clk), .en_d2(en_d2), .Q(SUM[19]) );
smffb dla158 (.D(INT_CARRY[82]), .clk(clk), .en_d2(en_d2), .Q(CARRY[19]) );
smffa dla159 (.D(SUMMAND[120]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[120]) );
smffa dla160 (.D(SUMMAND[121]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[121]) );
smffa dla161 (.D(SUMMAND[122]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[122]) );
smfulladder dfa73 (.DATA_A (LATCHED_PP[120]), .DATA_B (LATCHED_PP[121]), .DATA_C (LATCHED_PP[122]), .SAVE (INT_SUM[116]), .CARRY (INT_CARRY[92]) );
smffa dla162 (.D(SUMMAND[123]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[123]) );
smffa dla163 (.D(SUMMAND[124]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[124]) );
smffa dla164 (.D(SUMMAND[125]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[125]) );
smfulladder dfa74 (.DATA_A (LATCHED_PP[123]), .DATA_B (LATCHED_PP[124]), .DATA_C (LATCHED_PP[125]), .SAVE (INT_SUM[117]), .CARRY (INT_CARRY[93]) );
smffa dla165 (.D(SUMMAND[126]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[126]) );
smffa dla166 (.D(SUMMAND[127]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[127]) );
smffa dla167 (.D(SUMMAND[128]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[128]) );
smfulladder dfa75 (.DATA_A (LATCHED_PP[126]), .DATA_B (LATCHED_PP[127]), .DATA_C (LATCHED_PP[128]), .SAVE (INT_SUM[118]), .CARRY (INT_CARRY[94]) );
smffa dla168 (.D(SUMMAND[129]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[129]) );
smffa dla169 (.D(SUMMAND[130]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[130]) );
smffa dla170 (.D(SUMMAND[131]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[131]) );
smfulladder dfa76 (.DATA_A (LATCHED_PP[129]), .DATA_B (LATCHED_PP[130]), .DATA_C (LATCHED_PP[131]), .SAVE (INT_SUM[119]), .CARRY (INT_CARRY[95]) );
smfulladder dfa77 (.DATA_A (INT_SUM[116]), .DATA_B (INT_SUM[117]), .DATA_C (INT_SUM[118]), .SAVE (INT_SUM[120]), .CARRY (INT_CARRY[96]) );
smfulladder dfa78 (.DATA_A (INT_SUM[119]), .DATA_B (INT_CARRY[83]), .DATA_C (INT_CARRY[84]), .SAVE (INT_SUM[121]), .CARRY (INT_CARRY[97]) );
assign INT_SUM[122] = INT_CARRY[85];
smfulladder dfa79 (.DATA_A (INT_SUM[120]), .DATA_B (INT_SUM[121]), .DATA_C (INT_SUM[122]), .SAVE (INT_SUM[123]), .CARRY (INT_CARRY[98]) );
smhalfadder dha18 (.DATA_A (INT_CARRY[86]), .DATA_B (INT_CARRY[87]), .SAVE (INT_SUM[124]), .CARRY (INT_CARRY[99]) );
smfulladder dfa80 (.DATA_A (INT_SUM[123]), .DATA_B (INT_SUM[124]), .DATA_C (INT_CARRY[88]), .SAVE (INT_SUM[125]), .CARRY (INT_CARRY[100]) );
assign INT_SUM[126] = INT_CARRY[89];
smfulladder dfa81 (.DATA_A (INT_SUM[125]), .DATA_B (INT_SUM[126]), .DATA_C (INT_CARRY[90]), .SAVE (INT_SUM[127]), .CARRY (INT_CARRY[91]) );
smffb dla171 (.D(INT_SUM[127]), .clk(clk), .en_d2(en_d2), .Q(SUM[20]) );
smffb dla172 (.D(INT_CARRY[91]), .clk(clk), .en_d2(en_d2), .Q(CARRY[20]) );
smffa dla173 (.D(SUMMAND[132]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[132]) );
smffa dla174 (.D(SUMMAND[133]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[133]) );
smffa dla175 (.D(SUMMAND[134]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[134]) );
smfulladder dfa82 (.DATA_A (LATCHED_PP[132]), .DATA_B (LATCHED_PP[133]), .DATA_C (LATCHED_PP[134]), .SAVE (INT_SUM[128]), .CARRY (INT_CARRY[102]) );
smffa dla176 (.D(SUMMAND[135]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[135]) );
smffa dla177 (.D(SUMMAND[136]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[136]) );
smffa dla178 (.D(SUMMAND[137]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[137]) );
smfulladder dfa83 (.DATA_A (LATCHED_PP[135]), .DATA_B (LATCHED_PP[136]), .DATA_C (LATCHED_PP[137]), .SAVE (INT_SUM[129]), .CARRY (INT_CARRY[103]) );
smffa dla179 (.D(SUMMAND[138]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[138]) );
smffa dla180 (.D(SUMMAND[139]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[139]) );
smffa dla181 (.D(SUMMAND[140]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[140]) );
smfulladder dfa84 (.DATA_A (LATCHED_PP[138]), .DATA_B (LATCHED_PP[139]), .DATA_C (LATCHED_PP[140]), .SAVE (INT_SUM[130]), .CARRY (INT_CARRY[104]) );
smffa dla182 (.D(SUMMAND[141]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[141]) );
assign INT_SUM[131] = LATCHED_PP[141];
smffa dla183 (.D(SUMMAND[142]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[142]) );
assign INT_SUM[132] = LATCHED_PP[142];
smfulladder dfa85 (.DATA_A (INT_SUM[128]), .DATA_B (INT_SUM[129]), .DATA_C (INT_SUM[130]), .SAVE (INT_SUM[133]), .CARRY (INT_CARRY[105]) );
smfulladder dfa86 (.DATA_A (INT_SUM[131]), .DATA_B (INT_SUM[132]), .DATA_C (INT_CARRY[92]), .SAVE (INT_SUM[134]), .CARRY (INT_CARRY[106]) );
smfulladder dfa87 (.DATA_A (INT_CARRY[93]), .DATA_B (INT_CARRY[94]), .DATA_C (INT_CARRY[95]), .SAVE (INT_SUM[135]), .CARRY (INT_CARRY[107]) );
smfulladder dfa88 (.DATA_A (INT_SUM[133]), .DATA_B (INT_SUM[134]), .DATA_C (INT_SUM[135]), .SAVE (INT_SUM[136]), .CARRY (INT_CARRY[108]) );
smhalfadder dha19 (.DATA_A (INT_CARRY[96]), .DATA_B (INT_CARRY[97]), .SAVE (INT_SUM[137]), .CARRY (INT_CARRY[109]) );
smfulladder dfa89 (.DATA_A (INT_SUM[136]), .DATA_B (INT_SUM[137]), .DATA_C (INT_CARRY[98]), .SAVE (INT_SUM[138]), .CARRY (INT_CARRY[110]) );
assign INT_SUM[139] = INT_CARRY[99];
smfulladder dfa90 (.DATA_A (INT_SUM[138]), .DATA_B (INT_SUM[139]), .DATA_C (INT_CARRY[100]), .SAVE (INT_SUM[140]), .CARRY (INT_CARRY[101]) );
smffb dla184 (.D(INT_SUM[140]), .clk(clk), .en_d2(en_d2), .Q(SUM[21]) );
smffb dla185 (.D(INT_CARRY[101]), .clk(clk), .en_d2(en_d2), .Q(CARRY[21]) );
smffa dla186 (.D(SUMMAND[143]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[143]) );
smffa dla187 (.D(SUMMAND[144]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[144]) );
smffa dla188 (.D(SUMMAND[145]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[145]) );
smfulladder dfa91 (.DATA_A (LATCHED_PP[143]), .DATA_B (LATCHED_PP[144]), .DATA_C (LATCHED_PP[145]), .SAVE (INT_SUM[141]), .CARRY (INT_CARRY[112]) );
smffa dla189 (.D(SUMMAND[146]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[146]) );
smffa dla190 (.D(SUMMAND[147]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[147]) );
smffa dla191 (.D(SUMMAND[148]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[148]) );
smfulladder dfa92 (.DATA_A (LATCHED_PP[146]), .DATA_B (LATCHED_PP[147]), .DATA_C (LATCHED_PP[148]), .SAVE (INT_SUM[142]), .CARRY (INT_CARRY[113]) );
smffa dla192 (.D(SUMMAND[149]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[149]) );
smffa dla193 (.D(SUMMAND[150]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[150]) );
smffa dla194 (.D(SUMMAND[151]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[151]) );
smfulladder dfa93 (.DATA_A (LATCHED_PP[149]), .DATA_B (LATCHED_PP[150]), .DATA_C (LATCHED_PP[151]), .SAVE (INT_SUM[143]), .CARRY (INT_CARRY[114]) );
smffa dla195 (.D(SUMMAND[152]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[152]) );
smffa dla196 (.D(SUMMAND[153]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[153]) );
smffa dla197 (.D(SUMMAND[154]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[154]) );
smfulladder dfa94 (.DATA_A (LATCHED_PP[152]), .DATA_B (LATCHED_PP[153]), .DATA_C (LATCHED_PP[154]), .SAVE (INT_SUM[144]), .CARRY (INT_CARRY[115]) );
smffa dla198 (.D(SUMMAND[155]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[155]) );
assign INT_SUM[145] = LATCHED_PP[155];
smfulladder dfa95 (.DATA_A (INT_SUM[141]), .DATA_B (INT_SUM[142]), .DATA_C (INT_SUM[143]), .SAVE (INT_SUM[146]), .CARRY (INT_CARRY[116]) );
smfulladder dfa96 (.DATA_A (INT_SUM[144]), .DATA_B (INT_SUM[145]), .DATA_C (INT_CARRY[102]), .SAVE (INT_SUM[147]), .CARRY (INT_CARRY[117]) );
smhalfadder dha20 (.DATA_A (INT_CARRY[103]), .DATA_B (INT_CARRY[104]), .SAVE (INT_SUM[148]), .CARRY (INT_CARRY[118]) );
smfulladder dfa97 (.DATA_A (INT_SUM[146]), .DATA_B (INT_SUM[147]), .DATA_C (INT_SUM[148]), .SAVE (INT_SUM[149]), .CARRY (INT_CARRY[119]) );
smfulladder dfa98 (.DATA_A (INT_CARRY[105]), .DATA_B (INT_CARRY[106]), .DATA_C (INT_CARRY[107]), .SAVE (INT_SUM[150]), .CARRY (INT_CARRY[120]) );
smfulladder dfa99 (.DATA_A (INT_SUM[149]), .DATA_B (INT_SUM[150]), .DATA_C (INT_CARRY[108]), .SAVE (INT_SUM[151]), .CARRY (INT_CARRY[121]) );
assign INT_SUM[152] = INT_CARRY[109];
smfulladder dfa100 (.DATA_A (INT_SUM[151]), .DATA_B (INT_SUM[152]), .DATA_C (INT_CARRY[110]), .SAVE (INT_SUM[153]), .CARRY (INT_CARRY[111]) );
smffb dla199 (.D(INT_SUM[153]), .clk(clk), .en_d2(en_d2), .Q(SUM[22]) );
smffb dla200 (.D(INT_CARRY[111]), .clk(clk), .en_d2(en_d2), .Q(CARRY[22]) );
smffa dla201 (.D(SUMMAND[156]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[156]) );
smffa dla202 (.D(SUMMAND[157]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[157]) );
smffa dla203 (.D(SUMMAND[158]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[158]) );
smfulladder dfa101 (.DATA_A (LATCHED_PP[156]), .DATA_B (LATCHED_PP[157]), .DATA_C (LATCHED_PP[158]), .SAVE (INT_SUM[154]), .CARRY (INT_CARRY[123]) );
smffa dla204 (.D(SUMMAND[159]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[159]) );
smffa dla205 (.D(SUMMAND[160]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[160]) );
smffa dla206 (.D(SUMMAND[161]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[161]) );
smfulladder dfa102 (.DATA_A (LATCHED_PP[159]), .DATA_B (LATCHED_PP[160]), .DATA_C (LATCHED_PP[161]), .SAVE (INT_SUM[155]), .CARRY (INT_CARRY[124]) );
smffa dla207 (.D(SUMMAND[162]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[162]) );
smffa dla208 (.D(SUMMAND[163]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[163]) );
smffa dla209 (.D(SUMMAND[164]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[164]) );
smfulladder dfa103 (.DATA_A (LATCHED_PP[162]), .DATA_B (LATCHED_PP[163]), .DATA_C (LATCHED_PP[164]), .SAVE (INT_SUM[156]), .CARRY (INT_CARRY[125]) );
smffa dla210 (.D(SUMMAND[165]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[165]) );
smffa dla211 (.D(SUMMAND[166]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[166]) );
smffa dla212 (.D(SUMMAND[167]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[167]) );
smfulladder dfa104 (.DATA_A (LATCHED_PP[165]), .DATA_B (LATCHED_PP[166]), .DATA_C (LATCHED_PP[167]), .SAVE (INT_SUM[157]), .CARRY (INT_CARRY[126]) );
smfulladder dfa105 (.DATA_A (INT_SUM[154]), .DATA_B (INT_SUM[155]), .DATA_C (INT_SUM[156]), .SAVE (INT_SUM[158]), .CARRY (INT_CARRY[127]) );
smfulladder dfa106 (.DATA_A (INT_SUM[157]), .DATA_B (INT_CARRY[112]), .DATA_C (INT_CARRY[113]), .SAVE (INT_SUM[159]), .CARRY (INT_CARRY[128]) );
smhalfadder dha21 (.DATA_A (INT_CARRY[114]), .DATA_B (INT_CARRY[115]), .SAVE (INT_SUM[160]), .CARRY (INT_CARRY[129]) );
smfulladder dfa107 (.DATA_A (INT_SUM[158]), .DATA_B (INT_SUM[159]), .DATA_C (INT_SUM[160]), .SAVE (INT_SUM[161]), .CARRY (INT_CARRY[130]) );
smfulladder dfa108 (.DATA_A (INT_CARRY[116]), .DATA_B (INT_CARRY[117]), .DATA_C (INT_CARRY[118]), .SAVE (INT_SUM[162]), .CARRY (INT_CARRY[131]) );
smfulladder dfa109 (.DATA_A (INT_SUM[161]), .DATA_B (INT_SUM[162]), .DATA_C (INT_CARRY[119]), .SAVE (INT_SUM[163]), .CARRY (INT_CARRY[132]) );
assign INT_SUM[164] = INT_CARRY[120];
smfulladder dfa110 (.DATA_A (INT_SUM[163]), .DATA_B (INT_SUM[164]), .DATA_C (INT_CARRY[121]), .SAVE (INT_SUM[165]), .CARRY (INT_CARRY[122]) );
smffb dla213 (.D(INT_SUM[165]), .clk(clk), .en_d2(en_d2), .Q(SUM[23]) );
smffb dla214 (.D(INT_CARRY[122]), .clk(clk), .en_d2(en_d2), .Q(CARRY[23]) );
smffa dla215 (.D(SUMMAND[168]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[168]) );
smffa dla216 (.D(SUMMAND[169]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[169]) );
smffa dla217 (.D(SUMMAND[170]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[170]) );
smfulladder dfa111 (.DATA_A (LATCHED_PP[168]), .DATA_B (LATCHED_PP[169]), .DATA_C (LATCHED_PP[170]), .SAVE (INT_SUM[166]), .CARRY (INT_CARRY[134]) );
smffa dla218 (.D(SUMMAND[171]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[171]) );
smffa dla219 (.D(SUMMAND[172]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[172]) );
smffa dla220 (.D(SUMMAND[173]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[173]) );
smfulladder dfa112 (.DATA_A (LATCHED_PP[171]), .DATA_B (LATCHED_PP[172]), .DATA_C (LATCHED_PP[173]), .SAVE (INT_SUM[167]), .CARRY (INT_CARRY[135]) );
smffa dla221 (.D(SUMMAND[174]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[174]) );
smffa dla222 (.D(SUMMAND[175]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[175]) );
smffa dla223 (.D(SUMMAND[176]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[176]) );
smfulladder dfa113 (.DATA_A (LATCHED_PP[174]), .DATA_B (LATCHED_PP[175]), .DATA_C (LATCHED_PP[176]), .SAVE (INT_SUM[168]), .CARRY (INT_CARRY[136]) );
smffa dla224 (.D(SUMMAND[177]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[177]) );
smffa dla225 (.D(SUMMAND[178]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[178]) );
smffa dla226 (.D(SUMMAND[179]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[179]) );
smfulladder dfa114 (.DATA_A (LATCHED_PP[177]), .DATA_B (LATCHED_PP[178]), .DATA_C (LATCHED_PP[179]), .SAVE (INT_SUM[169]), .CARRY (INT_CARRY[137]) );
smffa dla227 (.D(SUMMAND[180]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[180]) );
smffa dla228 (.D(SUMMAND[181]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[181]) );
smhalfadder dha22 (.DATA_A (LATCHED_PP[180]), .DATA_B (LATCHED_PP[181]), .SAVE (INT_SUM[170]), .CARRY (INT_CARRY[138]) );
smfulladder dfa115 (.DATA_A (INT_SUM[166]), .DATA_B (INT_SUM[167]), .DATA_C (INT_SUM[168]), .SAVE (INT_SUM[171]), .CARRY (INT_CARRY[139]) );
smfulladder dfa116 (.DATA_A (INT_SUM[169]), .DATA_B (INT_SUM[170]), .DATA_C (INT_CARRY[123]), .SAVE (INT_SUM[172]), .CARRY (INT_CARRY[140]) );
smfulladder dfa117 (.DATA_A (INT_CARRY[124]), .DATA_B (INT_CARRY[125]), .DATA_C (INT_CARRY[126]), .SAVE (INT_SUM[173]), .CARRY (INT_CARRY[141]) );
smfulladder dfa118 (.DATA_A (INT_SUM[171]), .DATA_B (INT_SUM[172]), .DATA_C (INT_SUM[173]), .SAVE (INT_SUM[174]), .CARRY (INT_CARRY[142]) );
smfulladder dfa119 (.DATA_A (INT_CARRY[127]), .DATA_B (INT_CARRY[128]), .DATA_C (INT_CARRY[129]), .SAVE (INT_SUM[175]), .CARRY (INT_CARRY[143]) );
smfulladder dfa120 (.DATA_A (INT_SUM[174]), .DATA_B (INT_SUM[175]), .DATA_C (INT_CARRY[130]), .SAVE (INT_SUM[176]), .CARRY (INT_CARRY[144]) );
assign INT_SUM[177] = INT_CARRY[131];
smfulladder dfa121 (.DATA_A (INT_SUM[176]), .DATA_B (INT_SUM[177]), .DATA_C (INT_CARRY[132]), .SAVE (INT_SUM[178]), .CARRY (INT_CARRY[133]) );
smffb dla229 (.D(INT_SUM[178]), .clk(clk), .en_d2(en_d2), .Q(SUM[24]) );
smffb dla230 (.D(INT_CARRY[133]), .clk(clk), .en_d2(en_d2), .Q(CARRY[24]) );
smffa dla231 (.D(SUMMAND[182]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[182]) );
smffa dla232 (.D(SUMMAND[183]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[183]) );
smffa dla233 (.D(SUMMAND[184]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[184]) );
smfulladder dfa122 (.DATA_A (LATCHED_PP[182]), .DATA_B (LATCHED_PP[183]), .DATA_C (LATCHED_PP[184]), .SAVE (INT_SUM[179]), .CARRY (INT_CARRY[146]) );
smffa dla234 (.D(SUMMAND[185]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[185]) );
smffa dla235 (.D(SUMMAND[186]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[186]) );
smffa dla236 (.D(SUMMAND[187]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[187]) );
smfulladder dfa123 (.DATA_A (LATCHED_PP[185]), .DATA_B (LATCHED_PP[186]), .DATA_C (LATCHED_PP[187]), .SAVE (INT_SUM[180]), .CARRY (INT_CARRY[147]) );
smffa dla237 (.D(SUMMAND[188]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[188]) );
smffa dla238 (.D(SUMMAND[189]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[189]) );
smffa dla239 (.D(SUMMAND[190]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[190]) );
smfulladder dfa124 (.DATA_A (LATCHED_PP[188]), .DATA_B (LATCHED_PP[189]), .DATA_C (LATCHED_PP[190]), .SAVE (INT_SUM[181]), .CARRY (INT_CARRY[148]) );
smffa dla240 (.D(SUMMAND[191]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[191]) );
smffa dla241 (.D(SUMMAND[192]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[192]) );
smffa dla242 (.D(SUMMAND[193]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[193]) );
smfulladder dfa125 (.DATA_A (LATCHED_PP[191]), .DATA_B (LATCHED_PP[192]), .DATA_C (LATCHED_PP[193]), .SAVE (INT_SUM[182]), .CARRY (INT_CARRY[149]) );
smffa dla243 (.D(SUMMAND[194]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[194]) );
assign INT_SUM[183] = LATCHED_PP[194];
smfulladder dfa126 (.DATA_A (INT_SUM[179]), .DATA_B (INT_SUM[180]), .DATA_C (INT_SUM[181]), .SAVE (INT_SUM[184]), .CARRY (INT_CARRY[150]) );
smfulladder dfa127 (.DATA_A (INT_SUM[182]), .DATA_B (INT_SUM[183]), .DATA_C (INT_CARRY[134]), .SAVE (INT_SUM[185]), .CARRY (INT_CARRY[151]) );
smfulladder dfa128 (.DATA_A (INT_CARRY[135]), .DATA_B (INT_CARRY[136]), .DATA_C (INT_CARRY[137]), .SAVE (INT_SUM[186]), .CARRY (INT_CARRY[152]) );
assign INT_SUM[187] = INT_CARRY[138];
smfulladder dfa129 (.DATA_A (INT_SUM[184]), .DATA_B (INT_SUM[185]), .DATA_C (INT_SUM[186]), .SAVE (INT_SUM[188]), .CARRY (INT_CARRY[153]) );
smfulladder dfa130 (.DATA_A (INT_SUM[187]), .DATA_B (INT_CARRY[139]), .DATA_C (INT_CARRY[140]), .SAVE (INT_SUM[189]), .CARRY (INT_CARRY[154]) );
assign INT_SUM[190] = INT_CARRY[141];
smfulladder dfa131 (.DATA_A (INT_SUM[188]), .DATA_B (INT_SUM[189]), .DATA_C (INT_SUM[190]), .SAVE (INT_SUM[191]), .CARRY (INT_CARRY[155]) );
smhalfadder dha23 (.DATA_A (INT_CARRY[142]), .DATA_B (INT_CARRY[143]), .SAVE (INT_SUM[192]), .CARRY (INT_CARRY[156]) );
smfulladder dfa132 (.DATA_A (INT_SUM[191]), .DATA_B (INT_SUM[192]), .DATA_C (INT_CARRY[144]), .SAVE (INT_SUM[193]), .CARRY (INT_CARRY[145]) );
smffb dla244 (.D(INT_SUM[193]), .clk(clk), .en_d2(en_d2), .Q(SUM[25]) );
smffb dla245 (.D(INT_CARRY[145]), .clk(clk), .en_d2(en_d2), .Q(CARRY[25]) );
smffa dla246 (.D(SUMMAND[195]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[195]) );
smffa dla247 (.D(SUMMAND[196]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[196]) );
smffa dla248 (.D(SUMMAND[197]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[197]) );
smfulladder dfa133 (.DATA_A (LATCHED_PP[195]), .DATA_B (LATCHED_PP[196]), .DATA_C (LATCHED_PP[197]), .SAVE (INT_SUM[194]), .CARRY (INT_CARRY[158]) );
smffa dla249 (.D(SUMMAND[198]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[198]) );
smffa dla250 (.D(SUMMAND[199]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[199]) );
smffa dla251 (.D(SUMMAND[200]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[200]) );
smfulladder dfa134 (.DATA_A (LATCHED_PP[198]), .DATA_B (LATCHED_PP[199]), .DATA_C (LATCHED_PP[200]), .SAVE (INT_SUM[195]), .CARRY (INT_CARRY[159]) );
smffa dla252 (.D(SUMMAND[201]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[201]) );
smffa dla253 (.D(SUMMAND[202]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[202]) );
smffa dla254 (.D(SUMMAND[203]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[203]) );
smfulladder dfa135 (.DATA_A (LATCHED_PP[201]), .DATA_B (LATCHED_PP[202]), .DATA_C (LATCHED_PP[203]), .SAVE (INT_SUM[196]), .CARRY (INT_CARRY[160]) );
smffa dla255 (.D(SUMMAND[204]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[204]) );
smffa dla256 (.D(SUMMAND[205]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[205]) );
smffa dla257 (.D(SUMMAND[206]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[206]) );
smfulladder dfa136 (.DATA_A (LATCHED_PP[204]), .DATA_B (LATCHED_PP[205]), .DATA_C (LATCHED_PP[206]), .SAVE (INT_SUM[197]), .CARRY (INT_CARRY[161]) );
smffa dla258 (.D(SUMMAND[207]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[207]) );
smffa dla259 (.D(SUMMAND[208]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[208]) );
smffa dla260 (.D(SUMMAND[209]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[209]) );
smfulladder dfa137 (.DATA_A (LATCHED_PP[207]), .DATA_B (LATCHED_PP[208]), .DATA_C (LATCHED_PP[209]), .SAVE (INT_SUM[198]), .CARRY (INT_CARRY[162]) );
smfulladder dfa138 (.DATA_A (INT_SUM[194]), .DATA_B (INT_SUM[195]), .DATA_C (INT_SUM[196]), .SAVE (INT_SUM[199]), .CARRY (INT_CARRY[163]) );
smfulladder dfa139 (.DATA_A (INT_SUM[197]), .DATA_B (INT_SUM[198]), .DATA_C (INT_CARRY[146]), .SAVE (INT_SUM[200]), .CARRY (INT_CARRY[164]) );
smfulladder dfa140 (.DATA_A (INT_CARRY[147]), .DATA_B (INT_CARRY[148]), .DATA_C (INT_CARRY[149]), .SAVE (INT_SUM[201]), .CARRY (INT_CARRY[165]) );
smfulladder dfa141 (.DATA_A (INT_SUM[199]), .DATA_B (INT_SUM[200]), .DATA_C (INT_SUM[201]), .SAVE (INT_SUM[202]), .CARRY (INT_CARRY[166]) );
smfulladder dfa142 (.DATA_A (INT_CARRY[150]), .DATA_B (INT_CARRY[151]), .DATA_C (INT_CARRY[152]), .SAVE (INT_SUM[203]), .CARRY (INT_CARRY[167]) );
smfulladder dfa143 (.DATA_A (INT_SUM[202]), .DATA_B (INT_SUM[203]), .DATA_C (INT_CARRY[153]), .SAVE (INT_SUM[204]), .CARRY (INT_CARRY[168]) );
assign INT_SUM[205] = INT_CARRY[154];
smfulladder dfa144 (.DATA_A (INT_SUM[204]), .DATA_B (INT_SUM[205]), .DATA_C (INT_CARRY[155]), .SAVE (INT_SUM[206]), .CARRY (INT_CARRY[169]) );
assign INT_SUM[207] = INT_CARRY[156];
smhalfadder dha24 (.DATA_A (INT_SUM[206]), .DATA_B (INT_SUM[207]), .SAVE (INT_SUM[208]), .CARRY (INT_CARRY[157]) );
smffb dla261 (.D(INT_SUM[208]), .clk(clk), .en_d2(en_d2), .Q(SUM[26]) );
smffb dla262 (.D(INT_CARRY[157]), .clk(clk), .en_d2(en_d2), .Q(CARRY[26]) );
smffa dla263 (.D(SUMMAND[210]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[210]) );
smffa dla264 (.D(SUMMAND[211]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[211]) );
smffa dla265 (.D(SUMMAND[212]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[212]) );
smfulladder dfa145 (.DATA_A (LATCHED_PP[210]), .DATA_B (LATCHED_PP[211]), .DATA_C (LATCHED_PP[212]), .SAVE (INT_SUM[209]), .CARRY (INT_CARRY[171]) );
smffa dla266 (.D(SUMMAND[213]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[213]) );
smffa dla267 (.D(SUMMAND[214]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[214]) );
smffa dla268 (.D(SUMMAND[215]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[215]) );
smfulladder dfa146 (.DATA_A (LATCHED_PP[213]), .DATA_B (LATCHED_PP[214]), .DATA_C (LATCHED_PP[215]), .SAVE (INT_SUM[210]), .CARRY (INT_CARRY[172]) );
smffa dla269 (.D(SUMMAND[216]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[216]) );
smffa dla270 (.D(SUMMAND[217]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[217]) );
smffa dla271 (.D(SUMMAND[218]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[218]) );
smfulladder dfa147 (.DATA_A (LATCHED_PP[216]), .DATA_B (LATCHED_PP[217]), .DATA_C (LATCHED_PP[218]), .SAVE (INT_SUM[211]), .CARRY (INT_CARRY[173]) );
smffa dla272 (.D(SUMMAND[219]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[219]) );
smffa dla273 (.D(SUMMAND[220]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[220]) );
smffa dla274 (.D(SUMMAND[221]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[221]) );
smfulladder dfa148 (.DATA_A (LATCHED_PP[219]), .DATA_B (LATCHED_PP[220]), .DATA_C (LATCHED_PP[221]), .SAVE (INT_SUM[212]), .CARRY (INT_CARRY[174]) );
smffa dla275 (.D(SUMMAND[222]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[222]) );
smffa dla276 (.D(SUMMAND[223]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[223]) );
smhalfadder dha25 (.DATA_A (LATCHED_PP[222]), .DATA_B (LATCHED_PP[223]), .SAVE (INT_SUM[213]), .CARRY (INT_CARRY[175]) );
smfulladder dfa149 (.DATA_A (INT_SUM[209]), .DATA_B (INT_SUM[210]), .DATA_C (INT_SUM[211]), .SAVE (INT_SUM[214]), .CARRY (INT_CARRY[176]) );
smfulladder dfa150 (.DATA_A (INT_SUM[212]), .DATA_B (INT_SUM[213]), .DATA_C (INT_CARRY[158]), .SAVE (INT_SUM[215]), .CARRY (INT_CARRY[177]) );
smfulladder dfa151 (.DATA_A (INT_CARRY[159]), .DATA_B (INT_CARRY[160]), .DATA_C (INT_CARRY[161]), .SAVE (INT_SUM[216]), .CARRY (INT_CARRY[178]) );
assign INT_SUM[217] = INT_CARRY[162];
smfulladder dfa152 (.DATA_A (INT_SUM[214]), .DATA_B (INT_SUM[215]), .DATA_C (INT_SUM[216]), .SAVE (INT_SUM[218]), .CARRY (INT_CARRY[179]) );
smfulladder dfa153 (.DATA_A (INT_SUM[217]), .DATA_B (INT_CARRY[163]), .DATA_C (INT_CARRY[164]), .SAVE (INT_SUM[219]), .CARRY (INT_CARRY[180]) );
assign INT_SUM[220] = INT_CARRY[165];
smfulladder dfa154 (.DATA_A (INT_SUM[218]), .DATA_B (INT_SUM[219]), .DATA_C (INT_SUM[220]), .SAVE (INT_SUM[221]), .CARRY (INT_CARRY[181]) );
assign INT_SUM[222] = INT_CARRY[166];
assign INT_SUM[223] = INT_CARRY[167];
smfulladder dfa155 (.DATA_A (INT_SUM[221]), .DATA_B (INT_SUM[222]), .DATA_C (INT_SUM[223]), .SAVE (INT_SUM[224]), .CARRY (INT_CARRY[182]) );
assign INT_SUM[225] = INT_CARRY[168];
smfulladder dfa156 (.DATA_A (INT_SUM[224]), .DATA_B (INT_SUM[225]), .DATA_C (INT_CARRY[169]), .SAVE (INT_SUM[226]), .CARRY (INT_CARRY[170]) );
smffb dla277 (.D(INT_SUM[226]), .clk(clk), .en_d2(en_d2), .Q(SUM[27]) );
smffb dla278 (.D(INT_CARRY[170]), .clk(clk), .en_d2(en_d2), .Q(CARRY[27]) );
smffa dla279 (.D(SUMMAND[224]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[224]) );
smffa dla280 (.D(SUMMAND[225]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[225]) );
smffa dla281 (.D(SUMMAND[226]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[226]) );
smfulladder dfa157 (.DATA_A (LATCHED_PP[224]), .DATA_B (LATCHED_PP[225]), .DATA_C (LATCHED_PP[226]), .SAVE (INT_SUM[227]), .CARRY (INT_CARRY[184]) );
smffa dla282 (.D(SUMMAND[227]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[227]) );
smffa dla283 (.D(SUMMAND[228]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[228]) );
smffa dla284 (.D(SUMMAND[229]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[229]) );
smfulladder dfa158 (.DATA_A (LATCHED_PP[227]), .DATA_B (LATCHED_PP[228]), .DATA_C (LATCHED_PP[229]), .SAVE (INT_SUM[228]), .CARRY (INT_CARRY[185]) );
smffa dla285 (.D(SUMMAND[230]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[230]) );
smffa dla286 (.D(SUMMAND[231]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[231]) );
smffa dla287 (.D(SUMMAND[232]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[232]) );
smfulladder dfa159 (.DATA_A (LATCHED_PP[230]), .DATA_B (LATCHED_PP[231]), .DATA_C (LATCHED_PP[232]), .SAVE (INT_SUM[229]), .CARRY (INT_CARRY[186]) );
smffa dla288 (.D(SUMMAND[233]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[233]) );
smffa dla289 (.D(SUMMAND[234]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[234]) );
smffa dla290 (.D(SUMMAND[235]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[235]) );
smfulladder dfa160 (.DATA_A (LATCHED_PP[233]), .DATA_B (LATCHED_PP[234]), .DATA_C (LATCHED_PP[235]), .SAVE (INT_SUM[230]), .CARRY (INT_CARRY[187]) );
smffa dla291 (.D(SUMMAND[236]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[236]) );
smffa dla292 (.D(SUMMAND[237]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[237]) );
smffa dla293 (.D(SUMMAND[238]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[238]) );
smfulladder dfa161 (.DATA_A (LATCHED_PP[236]), .DATA_B (LATCHED_PP[237]), .DATA_C (LATCHED_PP[238]), .SAVE (INT_SUM[231]), .CARRY (INT_CARRY[188]) );
smffa dla294 (.D(SUMMAND[239]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[239]) );
assign INT_SUM[232] = LATCHED_PP[239];
smfulladder dfa162 (.DATA_A (INT_SUM[227]), .DATA_B (INT_SUM[228]), .DATA_C (INT_SUM[229]), .SAVE (INT_SUM[233]), .CARRY (INT_CARRY[189]) );
smfulladder dfa163 (.DATA_A (INT_SUM[230]), .DATA_B (INT_SUM[231]), .DATA_C (INT_SUM[232]), .SAVE (INT_SUM[234]), .CARRY (INT_CARRY[190]) );
smfulladder dfa164 (.DATA_A (INT_CARRY[171]), .DATA_B (INT_CARRY[172]), .DATA_C (INT_CARRY[173]), .SAVE (INT_SUM[235]), .CARRY (INT_CARRY[191]) );
assign INT_SUM[236] = INT_CARRY[174];
assign INT_SUM[237] = INT_CARRY[175];
smfulladder dfa165 (.DATA_A (INT_SUM[233]), .DATA_B (INT_SUM[234]), .DATA_C (INT_SUM[235]), .SAVE (INT_SUM[238]), .CARRY (INT_CARRY[192]) );
smfulladder dfa166 (.DATA_A (INT_SUM[236]), .DATA_B (INT_SUM[237]), .DATA_C (INT_CARRY[176]), .SAVE (INT_SUM[239]), .CARRY (INT_CARRY[193]) );
assign INT_SUM[240] = INT_CARRY[177];
assign INT_SUM[241] = INT_CARRY[178];
smfulladder dfa167 (.DATA_A (INT_SUM[238]), .DATA_B (INT_SUM[239]), .DATA_C (INT_SUM[240]), .SAVE (INT_SUM[242]), .CARRY (INT_CARRY[194]) );
smfulladder dfa168 (.DATA_A (INT_SUM[241]), .DATA_B (INT_CARRY[179]), .DATA_C (INT_CARRY[180]), .SAVE (INT_SUM[243]), .CARRY (INT_CARRY[195]) );
smfulladder dfa169 (.DATA_A (INT_SUM[242]), .DATA_B (INT_SUM[243]), .DATA_C (INT_CARRY[181]), .SAVE (INT_SUM[244]), .CARRY (INT_CARRY[196]) );
smhalfadder dha26 (.DATA_A (INT_SUM[244]), .DATA_B (INT_CARRY[182]), .SAVE (INT_SUM[245]), .CARRY (INT_CARRY[183]) );
smffb dla295 (.D(INT_SUM[245]), .clk(clk), .en_d2(en_d2), .Q(SUM[28]) );
smffb dla296 (.D(INT_CARRY[183]), .clk(clk), .en_d2(en_d2), .Q(CARRY[28]) );
smffa dla297 (.D(SUMMAND[240]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[240]) );
smffa dla298 (.D(SUMMAND[241]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[241]) );
smffa dla299 (.D(SUMMAND[242]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[242]) );
smfulladder dfa170 (.DATA_A (LATCHED_PP[240]), .DATA_B (LATCHED_PP[241]), .DATA_C (LATCHED_PP[242]), .SAVE (INT_SUM[246]), .CARRY (INT_CARRY[198]) );
smffa dla300 (.D(SUMMAND[243]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[243]) );
smffa dla301 (.D(SUMMAND[244]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[244]) );
smffa dla302 (.D(SUMMAND[245]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[245]) );
smfulladder dfa171 (.DATA_A (LATCHED_PP[243]), .DATA_B (LATCHED_PP[244]), .DATA_C (LATCHED_PP[245]), .SAVE (INT_SUM[247]), .CARRY (INT_CARRY[199]) );
smffa dla303 (.D(SUMMAND[246]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[246]) );
smffa dla304 (.D(SUMMAND[247]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[247]) );
smffa dla305 (.D(SUMMAND[248]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[248]) );
smfulladder dfa172 (.DATA_A (LATCHED_PP[246]), .DATA_B (LATCHED_PP[247]), .DATA_C (LATCHED_PP[248]), .SAVE (INT_SUM[248]), .CARRY (INT_CARRY[200]) );
smffa dla306 (.D(SUMMAND[249]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[249]) );
smffa dla307 (.D(SUMMAND[250]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[250]) );
smffa dla308 (.D(SUMMAND[251]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[251]) );
smfulladder dfa173 (.DATA_A (LATCHED_PP[249]), .DATA_B (LATCHED_PP[250]), .DATA_C (LATCHED_PP[251]), .SAVE (INT_SUM[249]), .CARRY (INT_CARRY[201]) );
smffa dla309 (.D(SUMMAND[252]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[252]) );
smffa dla310 (.D(SUMMAND[253]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[253]) );
smffa dla311 (.D(SUMMAND[254]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[254]) );
smfulladder dfa174 (.DATA_A (LATCHED_PP[252]), .DATA_B (LATCHED_PP[253]), .DATA_C (LATCHED_PP[254]), .SAVE (INT_SUM[250]), .CARRY (INT_CARRY[202]) );
smfulladder dfa175 (.DATA_A (INT_SUM[246]), .DATA_B (INT_SUM[247]), .DATA_C (INT_SUM[248]), .SAVE (INT_SUM[251]), .CARRY (INT_CARRY[203]) );
smfulladder dfa176 (.DATA_A (INT_SUM[249]), .DATA_B (INT_SUM[250]), .DATA_C (INT_CARRY[184]), .SAVE (INT_SUM[252]), .CARRY (INT_CARRY[204]) );
smfulladder dfa177 (.DATA_A (INT_CARRY[185]), .DATA_B (INT_CARRY[186]), .DATA_C (INT_CARRY[187]), .SAVE (INT_SUM[253]), .CARRY (INT_CARRY[205]) );
assign INT_SUM[254] = INT_CARRY[188];
smfulladder dfa178 (.DATA_A (INT_SUM[251]), .DATA_B (INT_SUM[252]), .DATA_C (INT_SUM[253]), .SAVE (INT_SUM[255]), .CARRY (INT_CARRY[206]) );
smfulladder dfa179 (.DATA_A (INT_SUM[254]), .DATA_B (INT_CARRY[189]), .DATA_C (INT_CARRY[190]), .SAVE (INT_SUM[256]), .CARRY (INT_CARRY[207]) );
assign INT_SUM[257] = INT_CARRY[191];
smfulladder dfa180 (.DATA_A (INT_SUM[255]), .DATA_B (INT_SUM[256]), .DATA_C (INT_SUM[257]), .SAVE (INT_SUM[258]), .CARRY (INT_CARRY[208]) );
smhalfadder dha27 (.DATA_A (INT_CARRY[192]), .DATA_B (INT_CARRY[193]), .SAVE (INT_SUM[259]), .CARRY (INT_CARRY[209]) );
smfulladder dfa181 (.DATA_A (INT_SUM[258]), .DATA_B (INT_SUM[259]), .DATA_C (INT_CARRY[194]), .SAVE (INT_SUM[260]), .CARRY (INT_CARRY[210]) );
assign INT_SUM[261] = INT_CARRY[195];
smfulladder dfa182 (.DATA_A (INT_SUM[260]), .DATA_B (INT_SUM[261]), .DATA_C (INT_CARRY[196]), .SAVE (INT_SUM[262]), .CARRY (INT_CARRY[197]) );
smffb dla312 (.D(INT_SUM[262]), .clk(clk), .en_d2(en_d2), .Q(SUM[29]) );
smffb dla313 (.D(INT_CARRY[197]), .clk(clk), .en_d2(en_d2), .Q(CARRY[29]) );
smffa dla314 (.D(SUMMAND[255]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[255]) );
smffa dla315 (.D(SUMMAND[256]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[256]) );
smffa dla316 (.D(SUMMAND[257]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[257]) );
smfulladder dfa183 (.DATA_A (LATCHED_PP[255]), .DATA_B (LATCHED_PP[256]), .DATA_C (LATCHED_PP[257]), .SAVE (INT_SUM[263]), .CARRY (INT_CARRY[212]) );
smffa dla317 (.D(SUMMAND[258]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[258]) );
smffa dla318 (.D(SUMMAND[259]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[259]) );
smffa dla319 (.D(SUMMAND[260]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[260]) );
smfulladder dfa184 (.DATA_A (LATCHED_PP[258]), .DATA_B (LATCHED_PP[259]), .DATA_C (LATCHED_PP[260]), .SAVE (INT_SUM[264]), .CARRY (INT_CARRY[213]) );
smffa dla320 (.D(SUMMAND[261]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[261]) );
smffa dla321 (.D(SUMMAND[262]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[262]) );
smffa dla322 (.D(SUMMAND[263]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[263]) );
smfulladder dfa185 (.DATA_A (LATCHED_PP[261]), .DATA_B (LATCHED_PP[262]), .DATA_C (LATCHED_PP[263]), .SAVE (INT_SUM[265]), .CARRY (INT_CARRY[214]) );
smffa dla323 (.D(SUMMAND[264]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[264]) );
smffa dla324 (.D(SUMMAND[265]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[265]) );
smffa dla325 (.D(SUMMAND[266]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[266]) );
smfulladder dfa186 (.DATA_A (LATCHED_PP[264]), .DATA_B (LATCHED_PP[265]), .DATA_C (LATCHED_PP[266]), .SAVE (INT_SUM[266]), .CARRY (INT_CARRY[215]) );
smffa dla326 (.D(SUMMAND[267]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[267]) );
smffa dla327 (.D(SUMMAND[268]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[268]) );
smffa dla328 (.D(SUMMAND[269]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[269]) );
smfulladder dfa187 (.DATA_A (LATCHED_PP[267]), .DATA_B (LATCHED_PP[268]), .DATA_C (LATCHED_PP[269]), .SAVE (INT_SUM[267]), .CARRY (INT_CARRY[216]) );
smffa dla329 (.D(SUMMAND[270]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[270]) );
assign INT_SUM[268] = LATCHED_PP[270];
smffa dla330 (.D(SUMMAND[271]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[271]) );
assign INT_SUM[269] = LATCHED_PP[271];
smfulladder dfa188 (.DATA_A (INT_SUM[263]), .DATA_B (INT_SUM[264]), .DATA_C (INT_SUM[265]), .SAVE (INT_SUM[270]), .CARRY (INT_CARRY[217]) );
smfulladder dfa189 (.DATA_A (INT_SUM[266]), .DATA_B (INT_SUM[267]), .DATA_C (INT_SUM[268]), .SAVE (INT_SUM[271]), .CARRY (INT_CARRY[218]) );
smfulladder dfa190 (.DATA_A (INT_SUM[269]), .DATA_B (INT_CARRY[198]), .DATA_C (INT_CARRY[199]), .SAVE (INT_SUM[272]), .CARRY (INT_CARRY[219]) );
smfulladder dfa191 (.DATA_A (INT_CARRY[200]), .DATA_B (INT_CARRY[201]), .DATA_C (INT_CARRY[202]), .SAVE (INT_SUM[273]), .CARRY (INT_CARRY[220]) );
smfulladder dfa192 (.DATA_A (INT_SUM[270]), .DATA_B (INT_SUM[271]), .DATA_C (INT_SUM[272]), .SAVE (INT_SUM[274]), .CARRY (INT_CARRY[221]) );
smfulladder dfa193 (.DATA_A (INT_SUM[273]), .DATA_B (INT_CARRY[203]), .DATA_C (INT_CARRY[204]), .SAVE (INT_SUM[275]), .CARRY (INT_CARRY[222]) );
assign INT_SUM[276] = INT_CARRY[205];
smfulladder dfa194 (.DATA_A (INT_SUM[274]), .DATA_B (INT_SUM[275]), .DATA_C (INT_SUM[276]), .SAVE (INT_SUM[277]), .CARRY (INT_CARRY[223]) );
smhalfadder dha28 (.DATA_A (INT_CARRY[206]), .DATA_B (INT_CARRY[207]), .SAVE (INT_SUM[278]), .CARRY (INT_CARRY[224]) );
smfulladder dfa195 (.DATA_A (INT_SUM[277]), .DATA_B (INT_SUM[278]), .DATA_C (INT_CARRY[208]), .SAVE (INT_SUM[279]), .CARRY (INT_CARRY[225]) );
assign INT_SUM[280] = INT_CARRY[209];
smfulladder dfa196 (.DATA_A (INT_SUM[279]), .DATA_B (INT_SUM[280]), .DATA_C (INT_CARRY[210]), .SAVE (INT_SUM[281]), .CARRY (INT_CARRY[211]) );
smffb dla331 (.D(INT_SUM[281]), .clk(clk), .en_d2(en_d2), .Q(SUM[30]) );
smffb dla332 (.D(INT_CARRY[211]), .clk(clk), .en_d2(en_d2), .Q(CARRY[30]) );
smffa dla333 (.D(SUMMAND[272]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[272]) );
smffa dla334 (.D(SUMMAND[273]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[273]) );
smffa dla335 (.D(SUMMAND[274]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[274]) );
smfulladder dfa197 (.DATA_A (LATCHED_PP[272]), .DATA_B (LATCHED_PP[273]), .DATA_C (LATCHED_PP[274]), .SAVE (INT_SUM[282]), .CARRY (INT_CARRY[227]) );
smffa dla336 (.D(SUMMAND[275]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[275]) );
smffa dla337 (.D(SUMMAND[276]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[276]) );
smffa dla338 (.D(SUMMAND[277]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[277]) );
smfulladder dfa198 (.DATA_A (LATCHED_PP[275]), .DATA_B (LATCHED_PP[276]), .DATA_C (LATCHED_PP[277]), .SAVE (INT_SUM[283]), .CARRY (INT_CARRY[228]) );
smffa dla339 (.D(SUMMAND[278]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[278]) );
smffa dla340 (.D(SUMMAND[279]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[279]) );
smffa dla341 (.D(SUMMAND[280]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[280]) );
smfulladder dfa199 (.DATA_A (LATCHED_PP[278]), .DATA_B (LATCHED_PP[279]), .DATA_C (LATCHED_PP[280]), .SAVE (INT_SUM[284]), .CARRY (INT_CARRY[229]) );
smffa dla342 (.D(SUMMAND[281]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[281]) );
smffa dla343 (.D(SUMMAND[282]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[282]) );
smffa dla344 (.D(SUMMAND[283]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[283]) );
smfulladder dfa200 (.DATA_A (LATCHED_PP[281]), .DATA_B (LATCHED_PP[282]), .DATA_C (LATCHED_PP[283]), .SAVE (INT_SUM[285]), .CARRY (INT_CARRY[230]) );
smffa dla345 (.D(SUMMAND[284]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[284]) );
smffa dla346 (.D(SUMMAND[285]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[285]) );
smffa dla347 (.D(SUMMAND[286]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[286]) );
smfulladder dfa201 (.DATA_A (LATCHED_PP[284]), .DATA_B (LATCHED_PP[285]), .DATA_C (LATCHED_PP[286]), .SAVE (INT_SUM[286]), .CARRY (INT_CARRY[231]) );
smffa dla348 (.D(SUMMAND[287]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[287]) );
assign INT_SUM[287] = LATCHED_PP[287];
smfulladder dfa202 (.DATA_A (INT_SUM[282]), .DATA_B (INT_SUM[283]), .DATA_C (INT_SUM[284]), .SAVE (INT_SUM[288]), .CARRY (INT_CARRY[232]) );
smfulladder dfa203 (.DATA_A (INT_SUM[285]), .DATA_B (INT_SUM[286]), .DATA_C (INT_SUM[287]), .SAVE (INT_SUM[289]), .CARRY (INT_CARRY[233]) );
smfulladder dfa204 (.DATA_A (INT_CARRY[212]), .DATA_B (INT_CARRY[213]), .DATA_C (INT_CARRY[214]), .SAVE (INT_SUM[290]), .CARRY (INT_CARRY[234]) );
assign INT_SUM[291] = INT_CARRY[215];
assign INT_SUM[292] = INT_CARRY[216];
smfulladder dfa205 (.DATA_A (INT_SUM[288]), .DATA_B (INT_SUM[289]), .DATA_C (INT_SUM[290]), .SAVE (INT_SUM[293]), .CARRY (INT_CARRY[235]) );
smfulladder dfa206 (.DATA_A (INT_SUM[291]), .DATA_B (INT_SUM[292]), .DATA_C (INT_CARRY[217]), .SAVE (INT_SUM[294]), .CARRY (INT_CARRY[236]) );
smfulladder dfa207 (.DATA_A (INT_CARRY[218]), .DATA_B (INT_CARRY[219]), .DATA_C (INT_CARRY[220]), .SAVE (INT_SUM[295]), .CARRY (INT_CARRY[237]) );
smfulladder dfa208 (.DATA_A (INT_SUM[293]), .DATA_B (INT_SUM[294]), .DATA_C (INT_SUM[295]), .SAVE (INT_SUM[296]), .CARRY (INT_CARRY[238]) );
smhalfadder dha29 (.DATA_A (INT_CARRY[221]), .DATA_B (INT_CARRY[222]), .SAVE (INT_SUM[297]), .CARRY (INT_CARRY[239]) );
smfulladder dfa209 (.DATA_A (INT_SUM[296]), .DATA_B (INT_SUM[297]), .DATA_C (INT_CARRY[223]), .SAVE (INT_SUM[298]), .CARRY (INT_CARRY[240]) );
assign INT_SUM[299] = INT_CARRY[224];
smfulladder dfa210 (.DATA_A (INT_SUM[298]), .DATA_B (INT_SUM[299]), .DATA_C (INT_CARRY[225]), .SAVE (INT_SUM[300]), .CARRY (INT_CARRY[226]) );
smffb dla349 (.D(INT_SUM[300]), .clk(clk), .en_d2(en_d2), .Q(SUM[31]) );
smffb dla350 (.D(INT_CARRY[226]), .clk(clk), .en_d2(en_d2), .Q(CARRY[31]) );
smffa dla351 (.D(SUMMAND[288]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[288]) );
smffa dla352 (.D(SUMMAND[289]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[289]) );
smffa dla353 (.D(SUMMAND[290]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[290]) );
smfulladder dfa211 (.DATA_A (LATCHED_PP[288]), .DATA_B (LATCHED_PP[289]), .DATA_C (LATCHED_PP[290]), .SAVE (INT_SUM[301]), .CARRY (INT_CARRY[242]) );
smffa dla354 (.D(SUMMAND[291]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[291]) );
smffa dla355 (.D(SUMMAND[292]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[292]) );
smffa dla356 (.D(SUMMAND[293]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[293]) );
smfulladder dfa212 (.DATA_A (LATCHED_PP[291]), .DATA_B (LATCHED_PP[292]), .DATA_C (LATCHED_PP[293]), .SAVE (INT_SUM[302]), .CARRY (INT_CARRY[243]) );
smffa dla357 (.D(SUMMAND[294]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[294]) );
smffa dla358 (.D(SUMMAND[295]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[295]) );
smffa dla359 (.D(SUMMAND[296]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[296]) );
smfulladder dfa213 (.DATA_A (LATCHED_PP[294]), .DATA_B (LATCHED_PP[295]), .DATA_C (LATCHED_PP[296]), .SAVE (INT_SUM[303]), .CARRY (INT_CARRY[244]) );
smffa dla360 (.D(SUMMAND[297]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[297]) );
smffa dla361 (.D(SUMMAND[298]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[298]) );
smffa dla362 (.D(SUMMAND[299]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[299]) );
smfulladder dfa214 (.DATA_A (LATCHED_PP[297]), .DATA_B (LATCHED_PP[298]), .DATA_C (LATCHED_PP[299]), .SAVE (INT_SUM[304]), .CARRY (INT_CARRY[245]) );
smffa dla363 (.D(SUMMAND[300]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[300]) );
smffa dla364 (.D(SUMMAND[301]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[301]) );
smffa dla365 (.D(SUMMAND[302]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[302]) );
smfulladder dfa215 (.DATA_A (LATCHED_PP[300]), .DATA_B (LATCHED_PP[301]), .DATA_C (LATCHED_PP[302]), .SAVE (INT_SUM[305]), .CARRY (INT_CARRY[246]) );
smffa dla366 (.D(SUMMAND[303]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[303]) );
smffa dla367 (.D(SUMMAND[304]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[304]) );
smffa dla368 (.D(SUMMAND[305]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[305]) );
smfulladder dfa216 (.DATA_A (LATCHED_PP[303]), .DATA_B (LATCHED_PP[304]), .DATA_C (LATCHED_PP[305]), .SAVE (INT_SUM[306]), .CARRY (INT_CARRY[247]) );
smfulladder dfa217 (.DATA_A (INT_SUM[301]), .DATA_B (INT_SUM[302]), .DATA_C (INT_SUM[303]), .SAVE (INT_SUM[307]), .CARRY (INT_CARRY[248]) );
smfulladder dfa218 (.DATA_A (INT_SUM[304]), .DATA_B (INT_SUM[305]), .DATA_C (INT_SUM[306]), .SAVE (INT_SUM[308]), .CARRY (INT_CARRY[249]) );
smfulladder dfa219 (.DATA_A (INT_CARRY[227]), .DATA_B (INT_CARRY[228]), .DATA_C (INT_CARRY[229]), .SAVE (INT_SUM[309]), .CARRY (INT_CARRY[250]) );
smhalfadder dha30 (.DATA_A (INT_CARRY[230]), .DATA_B (INT_CARRY[231]), .SAVE (INT_SUM[310]), .CARRY (INT_CARRY[251]) );
smfulladder dfa220 (.DATA_A (INT_SUM[307]), .DATA_B (INT_SUM[308]), .DATA_C (INT_SUM[309]), .SAVE (INT_SUM[311]), .CARRY (INT_CARRY[252]) );
smfulladder dfa221 (.DATA_A (INT_SUM[310]), .DATA_B (INT_CARRY[232]), .DATA_C (INT_CARRY[233]), .SAVE (INT_SUM[312]), .CARRY (INT_CARRY[253]) );
assign INT_SUM[313] = INT_CARRY[234];
smfulladder dfa222 (.DATA_A (INT_SUM[311]), .DATA_B (INT_SUM[312]), .DATA_C (INT_SUM[313]), .SAVE (INT_SUM[314]), .CARRY (INT_CARRY[254]) );
smfulladder dfa223 (.DATA_A (INT_CARRY[235]), .DATA_B (INT_CARRY[236]), .DATA_C (INT_CARRY[237]), .SAVE (INT_SUM[315]), .CARRY (INT_CARRY[255]) );
smfulladder dfa224 (.DATA_A (INT_SUM[314]), .DATA_B (INT_SUM[315]), .DATA_C (INT_CARRY[238]), .SAVE (INT_SUM[316]), .CARRY (INT_CARRY[256]) );
assign INT_SUM[317] = INT_CARRY[239];
smfulladder dfa225 (.DATA_A (INT_SUM[316]), .DATA_B (INT_SUM[317]), .DATA_C (INT_CARRY[240]), .SAVE (INT_SUM[318]), .CARRY (INT_CARRY[241]) );
smffb dla369 (.D(INT_SUM[318]), .clk(clk), .en_d2(en_d2), .Q(SUM[32]) );
smffb dla370 (.D(INT_CARRY[241]), .clk(clk), .en_d2(en_d2), .Q(CARRY[32]) );
smffa dla371 (.D(SUMMAND[306]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[306]) );
smffa dla372 (.D(SUMMAND[307]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[307]) );
smffa dla373 (.D(SUMMAND[308]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[308]) );
smfulladder dfa226 (.DATA_A (LATCHED_PP[306]), .DATA_B (LATCHED_PP[307]), .DATA_C (LATCHED_PP[308]), .SAVE (INT_SUM[319]), .CARRY (INT_CARRY[258]) );
smffa dla374 (.D(SUMMAND[309]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[309]) );
smffa dla375 (.D(SUMMAND[310]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[310]) );
smffa dla376 (.D(SUMMAND[311]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[311]) );
smfulladder dfa227 (.DATA_A (LATCHED_PP[309]), .DATA_B (LATCHED_PP[310]), .DATA_C (LATCHED_PP[311]), .SAVE (INT_SUM[320]), .CARRY (INT_CARRY[259]) );
smffa dla377 (.D(SUMMAND[312]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[312]) );
smffa dla378 (.D(SUMMAND[313]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[313]) );
smffa dla379 (.D(SUMMAND[314]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[314]) );
smfulladder dfa228 (.DATA_A (LATCHED_PP[312]), .DATA_B (LATCHED_PP[313]), .DATA_C (LATCHED_PP[314]), .SAVE (INT_SUM[321]), .CARRY (INT_CARRY[260]) );
smffa dla380 (.D(SUMMAND[315]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[315]) );
smffa dla381 (.D(SUMMAND[316]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[316]) );
smffa dla382 (.D(SUMMAND[317]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[317]) );
smfulladder dfa229 (.DATA_A (LATCHED_PP[315]), .DATA_B (LATCHED_PP[316]), .DATA_C (LATCHED_PP[317]), .SAVE (INT_SUM[322]), .CARRY (INT_CARRY[261]) );
smffa dla383 (.D(SUMMAND[318]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[318]) );
smffa dla384 (.D(SUMMAND[319]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[319]) );
smffa dla385 (.D(SUMMAND[320]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[320]) );
smfulladder dfa230 (.DATA_A (LATCHED_PP[318]), .DATA_B (LATCHED_PP[319]), .DATA_C (LATCHED_PP[320]), .SAVE (INT_SUM[323]), .CARRY (INT_CARRY[262]) );
smffa dla386 (.D(SUMMAND[321]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[321]) );
assign INT_SUM[324] = LATCHED_PP[321];
smffa dla387 (.D(SUMMAND[322]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[322]) );
assign INT_SUM[325] = LATCHED_PP[322];
smfulladder dfa231 (.DATA_A (INT_SUM[319]), .DATA_B (INT_SUM[320]), .DATA_C (INT_SUM[321]), .SAVE (INT_SUM[326]), .CARRY (INT_CARRY[263]) );
smfulladder dfa232 (.DATA_A (INT_SUM[322]), .DATA_B (INT_SUM[323]), .DATA_C (INT_SUM[324]), .SAVE (INT_SUM[327]), .CARRY (INT_CARRY[264]) );
smfulladder dfa233 (.DATA_A (INT_SUM[325]), .DATA_B (INT_CARRY[242]), .DATA_C (INT_CARRY[243]), .SAVE (INT_SUM[328]), .CARRY (INT_CARRY[265]) );
smfulladder dfa234 (.DATA_A (INT_CARRY[244]), .DATA_B (INT_CARRY[245]), .DATA_C (INT_CARRY[246]), .SAVE (INT_SUM[329]), .CARRY (INT_CARRY[266]) );
assign INT_SUM[330] = INT_CARRY[247];
smfulladder dfa235 (.DATA_A (INT_SUM[326]), .DATA_B (INT_SUM[327]), .DATA_C (INT_SUM[328]), .SAVE (INT_SUM[331]), .CARRY (INT_CARRY[267]) );
smfulladder dfa236 (.DATA_A (INT_SUM[329]), .DATA_B (INT_SUM[330]), .DATA_C (INT_CARRY[248]), .SAVE (INT_SUM[332]), .CARRY (INT_CARRY[268]) );
smfulladder dfa237 (.DATA_A (INT_CARRY[249]), .DATA_B (INT_CARRY[250]), .DATA_C (INT_CARRY[251]), .SAVE (INT_SUM[333]), .CARRY (INT_CARRY[269]) );
smfulladder dfa238 (.DATA_A (INT_SUM[331]), .DATA_B (INT_SUM[332]), .DATA_C (INT_SUM[333]), .SAVE (INT_SUM[334]), .CARRY (INT_CARRY[270]) );
smhalfadder dha31 (.DATA_A (INT_CARRY[252]), .DATA_B (INT_CARRY[253]), .SAVE (INT_SUM[335]), .CARRY (INT_CARRY[271]) );
smfulladder dfa239 (.DATA_A (INT_SUM[334]), .DATA_B (INT_SUM[335]), .DATA_C (INT_CARRY[254]), .SAVE (INT_SUM[336]), .CARRY (INT_CARRY[272]) );
assign INT_SUM[337] = INT_CARRY[255];
smfulladder dfa240 (.DATA_A (INT_SUM[336]), .DATA_B (INT_SUM[337]), .DATA_C (INT_CARRY[256]), .SAVE (INT_SUM[338]), .CARRY (INT_CARRY[257]) );
smffb dla388 (.D(INT_SUM[338]), .clk(clk), .en_d2(en_d2), .Q(SUM[33]) );
smffb dla389 (.D(INT_CARRY[257]), .clk(clk), .en_d2(en_d2), .Q(CARRY[33]) );
smffa dla390 (.D(SUMMAND[323]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[323]) );
smffa dla391 (.D(SUMMAND[324]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[324]) );
smffa dla392 (.D(SUMMAND[325]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[325]) );
smfulladder dfa241 (.DATA_A (LATCHED_PP[323]), .DATA_B (LATCHED_PP[324]), .DATA_C (LATCHED_PP[325]), .SAVE (INT_SUM[339]), .CARRY (INT_CARRY[274]) );
smffa dla393 (.D(SUMMAND[326]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[326]) );
smffa dla394 (.D(SUMMAND[327]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[327]) );
smffa dla395 (.D(SUMMAND[328]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[328]) );
smfulladder dfa242 (.DATA_A (LATCHED_PP[326]), .DATA_B (LATCHED_PP[327]), .DATA_C (LATCHED_PP[328]), .SAVE (INT_SUM[340]), .CARRY (INT_CARRY[275]) );
smffa dla396 (.D(SUMMAND[329]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[329]) );
smffa dla397 (.D(SUMMAND[330]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[330]) );
smffa dla398 (.D(SUMMAND[331]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[331]) );
smfulladder dfa243 (.DATA_A (LATCHED_PP[329]), .DATA_B (LATCHED_PP[330]), .DATA_C (LATCHED_PP[331]), .SAVE (INT_SUM[341]), .CARRY (INT_CARRY[276]) );
smffa dla399 (.D(SUMMAND[332]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[332]) );
smffa dla400 (.D(SUMMAND[333]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[333]) );
smffa dla401 (.D(SUMMAND[334]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[334]) );
smfulladder dfa244 (.DATA_A (LATCHED_PP[332]), .DATA_B (LATCHED_PP[333]), .DATA_C (LATCHED_PP[334]), .SAVE (INT_SUM[342]), .CARRY (INT_CARRY[277]) );
smffa dla402 (.D(SUMMAND[335]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[335]) );
smffa dla403 (.D(SUMMAND[336]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[336]) );
smffa dla404 (.D(SUMMAND[337]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[337]) );
smfulladder dfa245 (.DATA_A (LATCHED_PP[335]), .DATA_B (LATCHED_PP[336]), .DATA_C (LATCHED_PP[337]), .SAVE (INT_SUM[343]), .CARRY (INT_CARRY[278]) );
smffa dla405 (.D(SUMMAND[338]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[338]) );
smffa dla406 (.D(SUMMAND[339]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[339]) );
smffa dla407 (.D(SUMMAND[340]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[340]) );
smfulladder dfa246 (.DATA_A (LATCHED_PP[338]), .DATA_B (LATCHED_PP[339]), .DATA_C (LATCHED_PP[340]), .SAVE (INT_SUM[344]), .CARRY (INT_CARRY[279]) );
smfulladder dfa247 (.DATA_A (INT_SUM[339]), .DATA_B (INT_SUM[340]), .DATA_C (INT_SUM[341]), .SAVE (INT_SUM[345]), .CARRY (INT_CARRY[280]) );
smfulladder dfa248 (.DATA_A (INT_SUM[342]), .DATA_B (INT_SUM[343]), .DATA_C (INT_SUM[344]), .SAVE (INT_SUM[346]), .CARRY (INT_CARRY[281]) );
smfulladder dfa249 (.DATA_A (INT_CARRY[258]), .DATA_B (INT_CARRY[259]), .DATA_C (INT_CARRY[260]), .SAVE (INT_SUM[347]), .CARRY (INT_CARRY[282]) );
assign INT_SUM[348] = INT_CARRY[261];
assign INT_SUM[349] = INT_CARRY[262];
smfulladder dfa250 (.DATA_A (INT_SUM[345]), .DATA_B (INT_SUM[346]), .DATA_C (INT_SUM[347]), .SAVE (INT_SUM[350]), .CARRY (INT_CARRY[283]) );
smfulladder dfa251 (.DATA_A (INT_SUM[348]), .DATA_B (INT_SUM[349]), .DATA_C (INT_CARRY[263]), .SAVE (INT_SUM[351]), .CARRY (INT_CARRY[284]) );
smfulladder dfa252 (.DATA_A (INT_CARRY[264]), .DATA_B (INT_CARRY[265]), .DATA_C (INT_CARRY[266]), .SAVE (INT_SUM[352]), .CARRY (INT_CARRY[285]) );
smfulladder dfa253 (.DATA_A (INT_SUM[350]), .DATA_B (INT_SUM[351]), .DATA_C (INT_SUM[352]), .SAVE (INT_SUM[353]), .CARRY (INT_CARRY[286]) );
smfulladder dfa254 (.DATA_A (INT_CARRY[267]), .DATA_B (INT_CARRY[268]), .DATA_C (INT_CARRY[269]), .SAVE (INT_SUM[354]), .CARRY (INT_CARRY[287]) );
smfulladder dfa255 (.DATA_A (INT_SUM[353]), .DATA_B (INT_SUM[354]), .DATA_C (INT_CARRY[270]), .SAVE (INT_SUM[355]), .CARRY (INT_CARRY[288]) );
assign INT_SUM[356] = INT_CARRY[271];
smfulladder dfa256 (.DATA_A (INT_SUM[355]), .DATA_B (INT_SUM[356]), .DATA_C (INT_CARRY[272]), .SAVE (INT_SUM[357]), .CARRY (INT_CARRY[273]) );
smffb dla408 (.D(INT_SUM[357]), .clk(clk), .en_d2(en_d2), .Q(SUM[34]) );
smffb dla409 (.D(INT_CARRY[273]), .clk(clk), .en_d2(en_d2), .Q(CARRY[34]) );
smffa dla410 (.D(SUMMAND[341]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[341]) );
smffa dla411 (.D(SUMMAND[342]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[342]) );
smffa dla412 (.D(SUMMAND[343]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[343]) );
smfulladder dfa257 (.DATA_A (LATCHED_PP[341]), .DATA_B (LATCHED_PP[342]), .DATA_C (LATCHED_PP[343]), .SAVE (INT_SUM[358]), .CARRY (INT_CARRY[290]) );
smffa dla413 (.D(SUMMAND[344]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[344]) );
smffa dla414 (.D(SUMMAND[345]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[345]) );
smffa dla415 (.D(SUMMAND[346]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[346]) );
smfulladder dfa258 (.DATA_A (LATCHED_PP[344]), .DATA_B (LATCHED_PP[345]), .DATA_C (LATCHED_PP[346]), .SAVE (INT_SUM[359]), .CARRY (INT_CARRY[291]) );
smffa dla416 (.D(SUMMAND[347]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[347]) );
smffa dla417 (.D(SUMMAND[348]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[348]) );
smffa dla418 (.D(SUMMAND[349]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[349]) );
smfulladder dfa259 (.DATA_A (LATCHED_PP[347]), .DATA_B (LATCHED_PP[348]), .DATA_C (LATCHED_PP[349]), .SAVE (INT_SUM[360]), .CARRY (INT_CARRY[292]) );
smffa dla419 (.D(SUMMAND[350]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[350]) );
smffa dla420 (.D(SUMMAND[351]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[351]) );
smffa dla421 (.D(SUMMAND[352]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[352]) );
smfulladder dfa260 (.DATA_A (LATCHED_PP[350]), .DATA_B (LATCHED_PP[351]), .DATA_C (LATCHED_PP[352]), .SAVE (INT_SUM[361]), .CARRY (INT_CARRY[293]) );
smffa dla422 (.D(SUMMAND[353]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[353]) );
smffa dla423 (.D(SUMMAND[354]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[354]) );
smffa dla424 (.D(SUMMAND[355]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[355]) );
smfulladder dfa261 (.DATA_A (LATCHED_PP[353]), .DATA_B (LATCHED_PP[354]), .DATA_C (LATCHED_PP[355]), .SAVE (INT_SUM[362]), .CARRY (INT_CARRY[294]) );
smffa dla425 (.D(SUMMAND[356]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[356]) );
smffa dla426 (.D(SUMMAND[357]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[357]) );
smhalfadder dha32 (.DATA_A (LATCHED_PP[356]), .DATA_B (LATCHED_PP[357]), .SAVE (INT_SUM[363]), .CARRY (INT_CARRY[295]) );
smfulladder dfa262 (.DATA_A (INT_SUM[358]), .DATA_B (INT_SUM[359]), .DATA_C (INT_SUM[360]), .SAVE (INT_SUM[364]), .CARRY (INT_CARRY[296]) );
smfulladder dfa263 (.DATA_A (INT_SUM[361]), .DATA_B (INT_SUM[362]), .DATA_C (INT_SUM[363]), .SAVE (INT_SUM[365]), .CARRY (INT_CARRY[297]) );
smfulladder dfa264 (.DATA_A (INT_CARRY[274]), .DATA_B (INT_CARRY[275]), .DATA_C (INT_CARRY[276]), .SAVE (INT_SUM[366]), .CARRY (INT_CARRY[298]) );
smfulladder dfa265 (.DATA_A (INT_CARRY[277]), .DATA_B (INT_CARRY[278]), .DATA_C (INT_CARRY[279]), .SAVE (INT_SUM[367]), .CARRY (INT_CARRY[299]) );
smfulladder dfa266 (.DATA_A (INT_SUM[364]), .DATA_B (INT_SUM[365]), .DATA_C (INT_SUM[366]), .SAVE (INT_SUM[368]), .CARRY (INT_CARRY[300]) );
smfulladder dfa267 (.DATA_A (INT_SUM[367]), .DATA_B (INT_CARRY[280]), .DATA_C (INT_CARRY[281]), .SAVE (INT_SUM[369]), .CARRY (INT_CARRY[301]) );
assign INT_SUM[370] = INT_CARRY[282];
smfulladder dfa268 (.DATA_A (INT_SUM[368]), .DATA_B (INT_SUM[369]), .DATA_C (INT_SUM[370]), .SAVE (INT_SUM[371]), .CARRY (INT_CARRY[302]) );
smfulladder dfa269 (.DATA_A (INT_CARRY[283]), .DATA_B (INT_CARRY[284]), .DATA_C (INT_CARRY[285]), .SAVE (INT_SUM[372]), .CARRY (INT_CARRY[303]) );
smfulladder dfa270 (.DATA_A (INT_SUM[371]), .DATA_B (INT_SUM[372]), .DATA_C (INT_CARRY[286]), .SAVE (INT_SUM[373]), .CARRY (INT_CARRY[304]) );
assign INT_SUM[374] = INT_CARRY[287];
smfulladder dfa271 (.DATA_A (INT_SUM[373]), .DATA_B (INT_SUM[374]), .DATA_C (INT_CARRY[288]), .SAVE (INT_SUM[375]), .CARRY (INT_CARRY[289]) );
smffb dla427 (.D(INT_SUM[375]), .clk(clk), .en_d2(en_d2), .Q(SUM[35]) );
smffb dla428 (.D(INT_CARRY[289]), .clk(clk), .en_d2(en_d2), .Q(CARRY[35]) );
smffa dla429 (.D(SUMMAND[358]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[358]) );
smffa dla430 (.D(SUMMAND[359]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[359]) );
smffa dla431 (.D(SUMMAND[360]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[360]) );
smfulladder dfa272 (.DATA_A (LATCHED_PP[358]), .DATA_B (LATCHED_PP[359]), .DATA_C (LATCHED_PP[360]), .SAVE (INT_SUM[376]), .CARRY (INT_CARRY[306]) );
smffa dla432 (.D(SUMMAND[361]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[361]) );
smffa dla433 (.D(SUMMAND[362]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[362]) );
smffa dla434 (.D(SUMMAND[363]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[363]) );
smfulladder dfa273 (.DATA_A (LATCHED_PP[361]), .DATA_B (LATCHED_PP[362]), .DATA_C (LATCHED_PP[363]), .SAVE (INT_SUM[377]), .CARRY (INT_CARRY[307]) );
smffa dla435 (.D(SUMMAND[364]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[364]) );
smffa dla436 (.D(SUMMAND[365]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[365]) );
smffa dla437 (.D(SUMMAND[366]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[366]) );
smfulladder dfa274 (.DATA_A (LATCHED_PP[364]), .DATA_B (LATCHED_PP[365]), .DATA_C (LATCHED_PP[366]), .SAVE (INT_SUM[378]), .CARRY (INT_CARRY[308]) );
smffa dla438 (.D(SUMMAND[367]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[367]) );
smffa dla439 (.D(SUMMAND[368]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[368]) );
smffa dla440 (.D(SUMMAND[369]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[369]) );
smfulladder dfa275 (.DATA_A (LATCHED_PP[367]), .DATA_B (LATCHED_PP[368]), .DATA_C (LATCHED_PP[369]), .SAVE (INT_SUM[379]), .CARRY (INT_CARRY[309]) );
smffa dla441 (.D(SUMMAND[370]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[370]) );
smffa dla442 (.D(SUMMAND[371]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[371]) );
smffa dla443 (.D(SUMMAND[372]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[372]) );
smfulladder dfa276 (.DATA_A (LATCHED_PP[370]), .DATA_B (LATCHED_PP[371]), .DATA_C (LATCHED_PP[372]), .SAVE (INT_SUM[380]), .CARRY (INT_CARRY[310]) );
smffa dla444 (.D(SUMMAND[373]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[373]) );
assign INT_SUM[381] = LATCHED_PP[373];
smfulladder dfa277 (.DATA_A (INT_SUM[376]), .DATA_B (INT_SUM[377]), .DATA_C (INT_SUM[378]), .SAVE (INT_SUM[382]), .CARRY (INT_CARRY[311]) );
smfulladder dfa278 (.DATA_A (INT_SUM[379]), .DATA_B (INT_SUM[380]), .DATA_C (INT_SUM[381]), .SAVE (INT_SUM[383]), .CARRY (INT_CARRY[312]) );
smfulladder dfa279 (.DATA_A (INT_CARRY[290]), .DATA_B (INT_CARRY[291]), .DATA_C (INT_CARRY[292]), .SAVE (INT_SUM[384]), .CARRY (INT_CARRY[313]) );
smfulladder dfa280 (.DATA_A (INT_CARRY[293]), .DATA_B (INT_CARRY[294]), .DATA_C (INT_CARRY[295]), .SAVE (INT_SUM[385]), .CARRY (INT_CARRY[314]) );
smfulladder dfa281 (.DATA_A (INT_SUM[382]), .DATA_B (INT_SUM[383]), .DATA_C (INT_SUM[384]), .SAVE (INT_SUM[386]), .CARRY (INT_CARRY[315]) );
smfulladder dfa282 (.DATA_A (INT_SUM[385]), .DATA_B (INT_CARRY[296]), .DATA_C (INT_CARRY[297]), .SAVE (INT_SUM[387]), .CARRY (INT_CARRY[316]) );
assign INT_SUM[388] = INT_CARRY[298];
assign INT_SUM[389] = INT_CARRY[299];
smfulladder dfa283 (.DATA_A (INT_SUM[386]), .DATA_B (INT_SUM[387]), .DATA_C (INT_SUM[388]), .SAVE (INT_SUM[390]), .CARRY (INT_CARRY[317]) );
smfulladder dfa284 (.DATA_A (INT_SUM[389]), .DATA_B (INT_CARRY[300]), .DATA_C (INT_CARRY[301]), .SAVE (INT_SUM[391]), .CARRY (INT_CARRY[318]) );
smfulladder dfa285 (.DATA_A (INT_SUM[390]), .DATA_B (INT_SUM[391]), .DATA_C (INT_CARRY[302]), .SAVE (INT_SUM[392]), .CARRY (INT_CARRY[319]) );
assign INT_SUM[393] = INT_CARRY[303];
smfulladder dfa286 (.DATA_A (INT_SUM[392]), .DATA_B (INT_SUM[393]), .DATA_C (INT_CARRY[304]), .SAVE (INT_SUM[394]), .CARRY (INT_CARRY[305]) );
smffb dla445 (.D(INT_SUM[394]), .clk(clk), .en_d2(en_d2), .Q(SUM[36]) );
smffb dla446 (.D(INT_CARRY[305]), .clk(clk), .en_d2(en_d2), .Q(CARRY[36]) );
smffa dla447 (.D(SUMMAND[374]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[374]) );
smffa dla448 (.D(SUMMAND[375]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[375]) );
smffa dla449 (.D(SUMMAND[376]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[376]) );
smfulladder dfa287 (.DATA_A (LATCHED_PP[374]), .DATA_B (LATCHED_PP[375]), .DATA_C (LATCHED_PP[376]), .SAVE (INT_SUM[395]), .CARRY (INT_CARRY[321]) );
smffa dla450 (.D(SUMMAND[377]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[377]) );
smffa dla451 (.D(SUMMAND[378]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[378]) );
smffa dla452 (.D(SUMMAND[379]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[379]) );
smfulladder dfa288 (.DATA_A (LATCHED_PP[377]), .DATA_B (LATCHED_PP[378]), .DATA_C (LATCHED_PP[379]), .SAVE (INT_SUM[396]), .CARRY (INT_CARRY[322]) );
smffa dla453 (.D(SUMMAND[380]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[380]) );
smffa dla454 (.D(SUMMAND[381]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[381]) );
smffa dla455 (.D(SUMMAND[382]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[382]) );
smfulladder dfa289 (.DATA_A (LATCHED_PP[380]), .DATA_B (LATCHED_PP[381]), .DATA_C (LATCHED_PP[382]), .SAVE (INT_SUM[397]), .CARRY (INT_CARRY[323]) );
smffa dla456 (.D(SUMMAND[383]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[383]) );
smffa dla457 (.D(SUMMAND[384]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[384]) );
smffa dla458 (.D(SUMMAND[385]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[385]) );
smfulladder dfa290 (.DATA_A (LATCHED_PP[383]), .DATA_B (LATCHED_PP[384]), .DATA_C (LATCHED_PP[385]), .SAVE (INT_SUM[398]), .CARRY (INT_CARRY[324]) );
smffa dla459 (.D(SUMMAND[386]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[386]) );
smffa dla460 (.D(SUMMAND[387]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[387]) );
smffa dla461 (.D(SUMMAND[388]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[388]) );
smfulladder dfa291 (.DATA_A (LATCHED_PP[386]), .DATA_B (LATCHED_PP[387]), .DATA_C (LATCHED_PP[388]), .SAVE (INT_SUM[399]), .CARRY (INT_CARRY[325]) );
smffa dla462 (.D(SUMMAND[389]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[389]) );
assign INT_SUM[400] = LATCHED_PP[389];
smfulladder dfa292 (.DATA_A (INT_SUM[395]), .DATA_B (INT_SUM[396]), .DATA_C (INT_SUM[397]), .SAVE (INT_SUM[401]), .CARRY (INT_CARRY[326]) );
smfulladder dfa293 (.DATA_A (INT_SUM[398]), .DATA_B (INT_SUM[399]), .DATA_C (INT_SUM[400]), .SAVE (INT_SUM[402]), .CARRY (INT_CARRY[327]) );
smfulladder dfa294 (.DATA_A (INT_CARRY[306]), .DATA_B (INT_CARRY[307]), .DATA_C (INT_CARRY[308]), .SAVE (INT_SUM[403]), .CARRY (INT_CARRY[328]) );
assign INT_SUM[404] = INT_CARRY[309];
assign INT_SUM[405] = INT_CARRY[310];
smfulladder dfa295 (.DATA_A (INT_SUM[401]), .DATA_B (INT_SUM[402]), .DATA_C (INT_SUM[403]), .SAVE (INT_SUM[406]), .CARRY (INT_CARRY[329]) );
smfulladder dfa296 (.DATA_A (INT_SUM[404]), .DATA_B (INT_SUM[405]), .DATA_C (INT_CARRY[311]), .SAVE (INT_SUM[407]), .CARRY (INT_CARRY[330]) );
smfulladder dfa297 (.DATA_A (INT_CARRY[312]), .DATA_B (INT_CARRY[313]), .DATA_C (INT_CARRY[314]), .SAVE (INT_SUM[408]), .CARRY (INT_CARRY[331]) );
smfulladder dfa298 (.DATA_A (INT_SUM[406]), .DATA_B (INT_SUM[407]), .DATA_C (INT_SUM[408]), .SAVE (INT_SUM[409]), .CARRY (INT_CARRY[332]) );
smhalfadder dha33 (.DATA_A (INT_CARRY[315]), .DATA_B (INT_CARRY[316]), .SAVE (INT_SUM[410]), .CARRY (INT_CARRY[333]) );
smfulladder dfa299 (.DATA_A (INT_SUM[409]), .DATA_B (INT_SUM[410]), .DATA_C (INT_CARRY[317]), .SAVE (INT_SUM[411]), .CARRY (INT_CARRY[334]) );
assign INT_SUM[412] = INT_CARRY[318];
smfulladder dfa300 (.DATA_A (INT_SUM[411]), .DATA_B (INT_SUM[412]), .DATA_C (INT_CARRY[319]), .SAVE (INT_SUM[413]), .CARRY (INT_CARRY[320]) );
smffb dla463 (.D(INT_SUM[413]), .clk(clk), .en_d2(en_d2), .Q(SUM[37]) );
smffb dla464 (.D(INT_CARRY[320]), .clk(clk), .en_d2(en_d2), .Q(CARRY[37]) );
smffa dla465 (.D(SUMMAND[390]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[390]) );
smffa dla466 (.D(SUMMAND[391]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[391]) );
smffa dla467 (.D(SUMMAND[392]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[392]) );
smfulladder dfa301 (.DATA_A (LATCHED_PP[390]), .DATA_B (LATCHED_PP[391]), .DATA_C (LATCHED_PP[392]), .SAVE (INT_SUM[414]), .CARRY (INT_CARRY[336]) );
smffa dla468 (.D(SUMMAND[393]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[393]) );
smffa dla469 (.D(SUMMAND[394]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[394]) );
smffa dla470 (.D(SUMMAND[395]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[395]) );
smfulladder dfa302 (.DATA_A (LATCHED_PP[393]), .DATA_B (LATCHED_PP[394]), .DATA_C (LATCHED_PP[395]), .SAVE (INT_SUM[415]), .CARRY (INT_CARRY[337]) );
smffa dla471 (.D(SUMMAND[396]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[396]) );
smffa dla472 (.D(SUMMAND[397]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[397]) );
smffa dla473 (.D(SUMMAND[398]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[398]) );
smfulladder dfa303 (.DATA_A (LATCHED_PP[396]), .DATA_B (LATCHED_PP[397]), .DATA_C (LATCHED_PP[398]), .SAVE (INT_SUM[416]), .CARRY (INT_CARRY[338]) );
smffa dla474 (.D(SUMMAND[399]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[399]) );
smffa dla475 (.D(SUMMAND[400]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[400]) );
smffa dla476 (.D(SUMMAND[401]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[401]) );
smfulladder dfa304 (.DATA_A (LATCHED_PP[399]), .DATA_B (LATCHED_PP[400]), .DATA_C (LATCHED_PP[401]), .SAVE (INT_SUM[417]), .CARRY (INT_CARRY[339]) );
smffa dla477 (.D(SUMMAND[402]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[402]) );
smffa dla478 (.D(SUMMAND[403]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[403]) );
smffa dla479 (.D(SUMMAND[404]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[404]) );
smfulladder dfa305 (.DATA_A (LATCHED_PP[402]), .DATA_B (LATCHED_PP[403]), .DATA_C (LATCHED_PP[404]), .SAVE (INT_SUM[418]), .CARRY (INT_CARRY[340]) );
smfulladder dfa306 (.DATA_A (INT_SUM[414]), .DATA_B (INT_SUM[415]), .DATA_C (INT_SUM[416]), .SAVE (INT_SUM[419]), .CARRY (INT_CARRY[341]) );
smfulladder dfa307 (.DATA_A (INT_SUM[417]), .DATA_B (INT_SUM[418]), .DATA_C (INT_CARRY[321]), .SAVE (INT_SUM[420]), .CARRY (INT_CARRY[342]) );
smfulladder dfa308 (.DATA_A (INT_CARRY[322]), .DATA_B (INT_CARRY[323]), .DATA_C (INT_CARRY[324]), .SAVE (INT_SUM[421]), .CARRY (INT_CARRY[343]) );
assign INT_SUM[422] = INT_CARRY[325];
smfulladder dfa309 (.DATA_A (INT_SUM[419]), .DATA_B (INT_SUM[420]), .DATA_C (INT_SUM[421]), .SAVE (INT_SUM[423]), .CARRY (INT_CARRY[344]) );
smfulladder dfa310 (.DATA_A (INT_SUM[422]), .DATA_B (INT_CARRY[326]), .DATA_C (INT_CARRY[327]), .SAVE (INT_SUM[424]), .CARRY (INT_CARRY[345]) );
assign INT_SUM[425] = INT_CARRY[328];
smfulladder dfa311 (.DATA_A (INT_SUM[423]), .DATA_B (INT_SUM[424]), .DATA_C (INT_SUM[425]), .SAVE (INT_SUM[426]), .CARRY (INT_CARRY[346]) );
smfulladder dfa312 (.DATA_A (INT_CARRY[329]), .DATA_B (INT_CARRY[330]), .DATA_C (INT_CARRY[331]), .SAVE (INT_SUM[427]), .CARRY (INT_CARRY[347]) );
smfulladder dfa313 (.DATA_A (INT_SUM[426]), .DATA_B (INT_SUM[427]), .DATA_C (INT_CARRY[332]), .SAVE (INT_SUM[428]), .CARRY (INT_CARRY[348]) );
assign INT_SUM[429] = INT_CARRY[333];
smfulladder dfa314 (.DATA_A (INT_SUM[428]), .DATA_B (INT_SUM[429]), .DATA_C (INT_CARRY[334]), .SAVE (INT_SUM[430]), .CARRY (INT_CARRY[335]) );
smffb dla480 (.D(INT_SUM[430]), .clk(clk), .en_d2(en_d2), .Q(SUM[38]) );
smffb dla481 (.D(INT_CARRY[335]), .clk(clk), .en_d2(en_d2), .Q(CARRY[38]) );
smffa dla482 (.D(SUMMAND[405]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[405]) );
smffa dla483 (.D(SUMMAND[406]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[406]) );
smffa dla484 (.D(SUMMAND[407]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[407]) );
smfulladder dfa315 (.DATA_A (LATCHED_PP[405]), .DATA_B (LATCHED_PP[406]), .DATA_C (LATCHED_PP[407]), .SAVE (INT_SUM[431]), .CARRY (INT_CARRY[350]) );
smffa dla485 (.D(SUMMAND[408]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[408]) );
smffa dla486 (.D(SUMMAND[409]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[409]) );
smffa dla487 (.D(SUMMAND[410]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[410]) );
smfulladder dfa316 (.DATA_A (LATCHED_PP[408]), .DATA_B (LATCHED_PP[409]), .DATA_C (LATCHED_PP[410]), .SAVE (INT_SUM[432]), .CARRY (INT_CARRY[351]) );
smffa dla488 (.D(SUMMAND[411]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[411]) );
smffa dla489 (.D(SUMMAND[412]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[412]) );
smffa dla490 (.D(SUMMAND[413]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[413]) );
smfulladder dfa317 (.DATA_A (LATCHED_PP[411]), .DATA_B (LATCHED_PP[412]), .DATA_C (LATCHED_PP[413]), .SAVE (INT_SUM[433]), .CARRY (INT_CARRY[352]) );
smffa dla491 (.D(SUMMAND[414]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[414]) );
smffa dla492 (.D(SUMMAND[415]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[415]) );
smffa dla493 (.D(SUMMAND[416]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[416]) );
smfulladder dfa318 (.DATA_A (LATCHED_PP[414]), .DATA_B (LATCHED_PP[415]), .DATA_C (LATCHED_PP[416]), .SAVE (INT_SUM[434]), .CARRY (INT_CARRY[353]) );
smffa dla494 (.D(SUMMAND[417]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[417]) );
smffa dla495 (.D(SUMMAND[418]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[418]) );
smffa dla496 (.D(SUMMAND[419]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[419]) );
smfulladder dfa319 (.DATA_A (LATCHED_PP[417]), .DATA_B (LATCHED_PP[418]), .DATA_C (LATCHED_PP[419]), .SAVE (INT_SUM[435]), .CARRY (INT_CARRY[354]) );
smfulladder dfa320 (.DATA_A (INT_SUM[431]), .DATA_B (INT_SUM[432]), .DATA_C (INT_SUM[433]), .SAVE (INT_SUM[436]), .CARRY (INT_CARRY[355]) );
smfulladder dfa321 (.DATA_A (INT_SUM[434]), .DATA_B (INT_SUM[435]), .DATA_C (INT_CARRY[336]), .SAVE (INT_SUM[437]), .CARRY (INT_CARRY[356]) );
smfulladder dfa322 (.DATA_A (INT_CARRY[337]), .DATA_B (INT_CARRY[338]), .DATA_C (INT_CARRY[339]), .SAVE (INT_SUM[438]), .CARRY (INT_CARRY[357]) );
assign INT_SUM[439] = INT_CARRY[340];
smfulladder dfa323 (.DATA_A (INT_SUM[436]), .DATA_B (INT_SUM[437]), .DATA_C (INT_SUM[438]), .SAVE (INT_SUM[440]), .CARRY (INT_CARRY[358]) );
smfulladder dfa324 (.DATA_A (INT_SUM[439]), .DATA_B (INT_CARRY[341]), .DATA_C (INT_CARRY[342]), .SAVE (INT_SUM[441]), .CARRY (INT_CARRY[359]) );
assign INT_SUM[442] = INT_CARRY[343];
smfulladder dfa325 (.DATA_A (INT_SUM[440]), .DATA_B (INT_SUM[441]), .DATA_C (INT_SUM[442]), .SAVE (INT_SUM[443]), .CARRY (INT_CARRY[360]) );
smhalfadder dha34 (.DATA_A (INT_CARRY[344]), .DATA_B (INT_CARRY[345]), .SAVE (INT_SUM[444]), .CARRY (INT_CARRY[361]) );
smfulladder dfa326 (.DATA_A (INT_SUM[443]), .DATA_B (INT_SUM[444]), .DATA_C (INT_CARRY[346]), .SAVE (INT_SUM[445]), .CARRY (INT_CARRY[362]) );
assign INT_SUM[446] = INT_CARRY[347];
smfulladder dfa327 (.DATA_A (INT_SUM[445]), .DATA_B (INT_SUM[446]), .DATA_C (INT_CARRY[348]), .SAVE (INT_SUM[447]), .CARRY (INT_CARRY[349]) );
smffb dla497 (.D(INT_SUM[447]), .clk(clk), .en_d2(en_d2), .Q(SUM[39]) );
smffb dla498 (.D(INT_CARRY[349]), .clk(clk), .en_d2(en_d2), .Q(CARRY[39]) );
smffa dla499 (.D(SUMMAND[420]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[420]) );
smffa dla500 (.D(SUMMAND[421]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[421]) );
smffa dla501 (.D(SUMMAND[422]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[422]) );
smfulladder dfa328 (.DATA_A (LATCHED_PP[420]), .DATA_B (LATCHED_PP[421]), .DATA_C (LATCHED_PP[422]), .SAVE (INT_SUM[448]), .CARRY (INT_CARRY[364]) );
smffa dla502 (.D(SUMMAND[423]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[423]) );
smffa dla503 (.D(SUMMAND[424]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[424]) );
smffa dla504 (.D(SUMMAND[425]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[425]) );
smfulladder dfa329 (.DATA_A (LATCHED_PP[423]), .DATA_B (LATCHED_PP[424]), .DATA_C (LATCHED_PP[425]), .SAVE (INT_SUM[449]), .CARRY (INT_CARRY[365]) );
smffa dla505 (.D(SUMMAND[426]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[426]) );
smffa dla506 (.D(SUMMAND[427]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[427]) );
smffa dla507 (.D(SUMMAND[428]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[428]) );
smfulladder dfa330 (.DATA_A (LATCHED_PP[426]), .DATA_B (LATCHED_PP[427]), .DATA_C (LATCHED_PP[428]), .SAVE (INT_SUM[450]), .CARRY (INT_CARRY[366]) );
smffa dla508 (.D(SUMMAND[429]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[429]) );
smffa dla509 (.D(SUMMAND[430]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[430]) );
smffa dla510 (.D(SUMMAND[431]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[431]) );
smfulladder dfa331 (.DATA_A (LATCHED_PP[429]), .DATA_B (LATCHED_PP[430]), .DATA_C (LATCHED_PP[431]), .SAVE (INT_SUM[451]), .CARRY (INT_CARRY[367]) );
smffa dla511 (.D(SUMMAND[432]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[432]) );
smffa dla512 (.D(SUMMAND[433]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[433]) );
smhalfadder dha35 (.DATA_A (LATCHED_PP[432]), .DATA_B (LATCHED_PP[433]), .SAVE (INT_SUM[452]), .CARRY (INT_CARRY[368]) );
smfulladder dfa332 (.DATA_A (INT_SUM[448]), .DATA_B (INT_SUM[449]), .DATA_C (INT_SUM[450]), .SAVE (INT_SUM[453]), .CARRY (INT_CARRY[369]) );
smfulladder dfa333 (.DATA_A (INT_SUM[451]), .DATA_B (INT_SUM[452]), .DATA_C (INT_CARRY[350]), .SAVE (INT_SUM[454]), .CARRY (INT_CARRY[370]) );
smfulladder dfa334 (.DATA_A (INT_CARRY[351]), .DATA_B (INT_CARRY[352]), .DATA_C (INT_CARRY[353]), .SAVE (INT_SUM[455]), .CARRY (INT_CARRY[371]) );
assign INT_SUM[456] = INT_CARRY[354];
smfulladder dfa335 (.DATA_A (INT_SUM[453]), .DATA_B (INT_SUM[454]), .DATA_C (INT_SUM[455]), .SAVE (INT_SUM[457]), .CARRY (INT_CARRY[372]) );
smfulladder dfa336 (.DATA_A (INT_SUM[456]), .DATA_B (INT_CARRY[355]), .DATA_C (INT_CARRY[356]), .SAVE (INT_SUM[458]), .CARRY (INT_CARRY[373]) );
assign INT_SUM[459] = INT_CARRY[357];
smfulladder dfa337 (.DATA_A (INT_SUM[457]), .DATA_B (INT_SUM[458]), .DATA_C (INT_SUM[459]), .SAVE (INT_SUM[460]), .CARRY (INT_CARRY[374]) );
smhalfadder dha36 (.DATA_A (INT_CARRY[358]), .DATA_B (INT_CARRY[359]), .SAVE (INT_SUM[461]), .CARRY (INT_CARRY[375]) );
smfulladder dfa338 (.DATA_A (INT_SUM[460]), .DATA_B (INT_SUM[461]), .DATA_C (INT_CARRY[360]), .SAVE (INT_SUM[462]), .CARRY (INT_CARRY[376]) );
assign INT_SUM[463] = INT_CARRY[361];
smfulladder dfa339 (.DATA_A (INT_SUM[462]), .DATA_B (INT_SUM[463]), .DATA_C (INT_CARRY[362]), .SAVE (INT_SUM[464]), .CARRY (INT_CARRY[363]) );
smffb dla513 (.D(INT_SUM[464]), .clk(clk), .en_d2(en_d2), .Q(SUM[40]) );
smffb dla514 (.D(INT_CARRY[363]), .clk(clk), .en_d2(en_d2), .Q(CARRY[40]) );
smffa dla515 (.D(SUMMAND[434]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[434]) );
smffa dla516 (.D(SUMMAND[435]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[435]) );
smffa dla517 (.D(SUMMAND[436]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[436]) );
smfulladder dfa340 (.DATA_A (LATCHED_PP[434]), .DATA_B (LATCHED_PP[435]), .DATA_C (LATCHED_PP[436]), .SAVE (INT_SUM[465]), .CARRY (INT_CARRY[378]) );
smffa dla518 (.D(SUMMAND[437]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[437]) );
smffa dla519 (.D(SUMMAND[438]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[438]) );
smffa dla520 (.D(SUMMAND[439]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[439]) );
smfulladder dfa341 (.DATA_A (LATCHED_PP[437]), .DATA_B (LATCHED_PP[438]), .DATA_C (LATCHED_PP[439]), .SAVE (INT_SUM[466]), .CARRY (INT_CARRY[379]) );
smffa dla521 (.D(SUMMAND[440]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[440]) );
smffa dla522 (.D(SUMMAND[441]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[441]) );
smffa dla523 (.D(SUMMAND[442]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[442]) );
smfulladder dfa342 (.DATA_A (LATCHED_PP[440]), .DATA_B (LATCHED_PP[441]), .DATA_C (LATCHED_PP[442]), .SAVE (INT_SUM[467]), .CARRY (INT_CARRY[380]) );
smffa dla524 (.D(SUMMAND[443]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[443]) );
smffa dla525 (.D(SUMMAND[444]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[444]) );
smffa dla526 (.D(SUMMAND[445]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[445]) );
smfulladder dfa343 (.DATA_A (LATCHED_PP[443]), .DATA_B (LATCHED_PP[444]), .DATA_C (LATCHED_PP[445]), .SAVE (INT_SUM[468]), .CARRY (INT_CARRY[381]) );
smffa dla527 (.D(SUMMAND[446]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[446]) );
smffa dla528 (.D(SUMMAND[447]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[447]) );
smhalfadder dha37 (.DATA_A (LATCHED_PP[446]), .DATA_B (LATCHED_PP[447]), .SAVE (INT_SUM[469]), .CARRY (INT_CARRY[382]) );
smfulladder dfa344 (.DATA_A (INT_SUM[465]), .DATA_B (INT_SUM[466]), .DATA_C (INT_SUM[467]), .SAVE (INT_SUM[470]), .CARRY (INT_CARRY[383]) );
smfulladder dfa345 (.DATA_A (INT_SUM[468]), .DATA_B (INT_SUM[469]), .DATA_C (INT_CARRY[364]), .SAVE (INT_SUM[471]), .CARRY (INT_CARRY[384]) );
smfulladder dfa346 (.DATA_A (INT_CARRY[365]), .DATA_B (INT_CARRY[366]), .DATA_C (INT_CARRY[367]), .SAVE (INT_SUM[472]), .CARRY (INT_CARRY[385]) );
assign INT_SUM[473] = INT_CARRY[368];
smfulladder dfa347 (.DATA_A (INT_SUM[470]), .DATA_B (INT_SUM[471]), .DATA_C (INT_SUM[472]), .SAVE (INT_SUM[474]), .CARRY (INT_CARRY[386]) );
smfulladder dfa348 (.DATA_A (INT_SUM[473]), .DATA_B (INT_CARRY[369]), .DATA_C (INT_CARRY[370]), .SAVE (INT_SUM[475]), .CARRY (INT_CARRY[387]) );
assign INT_SUM[476] = INT_CARRY[371];
smfulladder dfa349 (.DATA_A (INT_SUM[474]), .DATA_B (INT_SUM[475]), .DATA_C (INT_SUM[476]), .SAVE (INT_SUM[477]), .CARRY (INT_CARRY[388]) );
smhalfadder dha38 (.DATA_A (INT_CARRY[372]), .DATA_B (INT_CARRY[373]), .SAVE (INT_SUM[478]), .CARRY (INT_CARRY[389]) );
smfulladder dfa350 (.DATA_A (INT_SUM[477]), .DATA_B (INT_SUM[478]), .DATA_C (INT_CARRY[374]), .SAVE (INT_SUM[479]), .CARRY (INT_CARRY[390]) );
assign INT_SUM[480] = INT_CARRY[375];
smfulladder dfa351 (.DATA_A (INT_SUM[479]), .DATA_B (INT_SUM[480]), .DATA_C (INT_CARRY[376]), .SAVE (INT_SUM[481]), .CARRY (INT_CARRY[377]) );
smffb dla529 (.D(INT_SUM[481]), .clk(clk), .en_d2(en_d2), .Q(SUM[41]) );
smffb dla530 (.D(INT_CARRY[377]), .clk(clk), .en_d2(en_d2), .Q(CARRY[41]) );
smffa dla531 (.D(SUMMAND[448]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[448]) );
smffa dla532 (.D(SUMMAND[449]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[449]) );
smffa dla533 (.D(SUMMAND[450]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[450]) );
smfulladder dfa352 (.DATA_A (LATCHED_PP[448]), .DATA_B (LATCHED_PP[449]), .DATA_C (LATCHED_PP[450]), .SAVE (INT_SUM[482]), .CARRY (INT_CARRY[392]) );
smffa dla534 (.D(SUMMAND[451]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[451]) );
smffa dla535 (.D(SUMMAND[452]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[452]) );
smffa dla536 (.D(SUMMAND[453]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[453]) );
smfulladder dfa353 (.DATA_A (LATCHED_PP[451]), .DATA_B (LATCHED_PP[452]), .DATA_C (LATCHED_PP[453]), .SAVE (INT_SUM[483]), .CARRY (INT_CARRY[393]) );
smffa dla537 (.D(SUMMAND[454]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[454]) );
smffa dla538 (.D(SUMMAND[455]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[455]) );
smffa dla539 (.D(SUMMAND[456]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[456]) );
smfulladder dfa354 (.DATA_A (LATCHED_PP[454]), .DATA_B (LATCHED_PP[455]), .DATA_C (LATCHED_PP[456]), .SAVE (INT_SUM[484]), .CARRY (INT_CARRY[394]) );
smffa dla540 (.D(SUMMAND[457]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[457]) );
smffa dla541 (.D(SUMMAND[458]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[458]) );
smffa dla542 (.D(SUMMAND[459]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[459]) );
smfulladder dfa355 (.DATA_A (LATCHED_PP[457]), .DATA_B (LATCHED_PP[458]), .DATA_C (LATCHED_PP[459]), .SAVE (INT_SUM[485]), .CARRY (INT_CARRY[395]) );
smffa dla543 (.D(SUMMAND[460]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[460]) );
assign INT_SUM[486] = LATCHED_PP[460];
smfulladder dfa356 (.DATA_A (INT_SUM[482]), .DATA_B (INT_SUM[483]), .DATA_C (INT_SUM[484]), .SAVE (INT_SUM[487]), .CARRY (INT_CARRY[396]) );
smfulladder dfa357 (.DATA_A (INT_SUM[485]), .DATA_B (INT_SUM[486]), .DATA_C (INT_CARRY[378]), .SAVE (INT_SUM[488]), .CARRY (INT_CARRY[397]) );
smfulladder dfa358 (.DATA_A (INT_CARRY[379]), .DATA_B (INT_CARRY[380]), .DATA_C (INT_CARRY[381]), .SAVE (INT_SUM[489]), .CARRY (INT_CARRY[398]) );
assign INT_SUM[490] = INT_CARRY[382];
smfulladder dfa359 (.DATA_A (INT_SUM[487]), .DATA_B (INT_SUM[488]), .DATA_C (INT_SUM[489]), .SAVE (INT_SUM[491]), .CARRY (INT_CARRY[399]) );
smfulladder dfa360 (.DATA_A (INT_SUM[490]), .DATA_B (INT_CARRY[383]), .DATA_C (INT_CARRY[384]), .SAVE (INT_SUM[492]), .CARRY (INT_CARRY[400]) );
assign INT_SUM[493] = INT_CARRY[385];
smfulladder dfa361 (.DATA_A (INT_SUM[491]), .DATA_B (INT_SUM[492]), .DATA_C (INT_SUM[493]), .SAVE (INT_SUM[494]), .CARRY (INT_CARRY[401]) );
smhalfadder dha39 (.DATA_A (INT_CARRY[386]), .DATA_B (INT_CARRY[387]), .SAVE (INT_SUM[495]), .CARRY (INT_CARRY[402]) );
smfulladder dfa362 (.DATA_A (INT_SUM[494]), .DATA_B (INT_SUM[495]), .DATA_C (INT_CARRY[388]), .SAVE (INT_SUM[496]), .CARRY (INT_CARRY[403]) );
assign INT_SUM[497] = INT_CARRY[389];
smfulladder dfa363 (.DATA_A (INT_SUM[496]), .DATA_B (INT_SUM[497]), .DATA_C (INT_CARRY[390]), .SAVE (INT_SUM[498]), .CARRY (INT_CARRY[391]) );
smffb dla544 (.D(INT_SUM[498]), .clk(clk), .en_d2(en_d2), .Q(SUM[42]) );
smffb dla545 (.D(INT_CARRY[391]), .clk(clk), .en_d2(en_d2), .Q(CARRY[42]) );
smffa dla546 (.D(SUMMAND[461]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[461]) );
smffa dla547 (.D(SUMMAND[462]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[462]) );
smffa dla548 (.D(SUMMAND[463]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[463]) );
smfulladder dfa364 (.DATA_A (LATCHED_PP[461]), .DATA_B (LATCHED_PP[462]), .DATA_C (LATCHED_PP[463]), .SAVE (INT_SUM[499]), .CARRY (INT_CARRY[405]) );
smffa dla549 (.D(SUMMAND[464]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[464]) );
smffa dla550 (.D(SUMMAND[465]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[465]) );
smffa dla551 (.D(SUMMAND[466]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[466]) );
smfulladder dfa365 (.DATA_A (LATCHED_PP[464]), .DATA_B (LATCHED_PP[465]), .DATA_C (LATCHED_PP[466]), .SAVE (INT_SUM[500]), .CARRY (INT_CARRY[406]) );
smffa dla552 (.D(SUMMAND[467]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[467]) );
smffa dla553 (.D(SUMMAND[468]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[468]) );
smffa dla554 (.D(SUMMAND[469]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[469]) );
smfulladder dfa366 (.DATA_A (LATCHED_PP[467]), .DATA_B (LATCHED_PP[468]), .DATA_C (LATCHED_PP[469]), .SAVE (INT_SUM[501]), .CARRY (INT_CARRY[407]) );
smffa dla555 (.D(SUMMAND[470]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[470]) );
smffa dla556 (.D(SUMMAND[471]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[471]) );
smffa dla557 (.D(SUMMAND[472]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[472]) );
smfulladder dfa367 (.DATA_A (LATCHED_PP[470]), .DATA_B (LATCHED_PP[471]), .DATA_C (LATCHED_PP[472]), .SAVE (INT_SUM[502]), .CARRY (INT_CARRY[408]) );
smffa dla558 (.D(SUMMAND[473]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[473]) );
smfulladder dfa368 (.DATA_A (LATCHED_PP[473]), .DATA_B (INT_CARRY[392]), .DATA_C (INT_CARRY[393]), .SAVE (INT_SUM[503]), .CARRY (INT_CARRY[409]) );
assign INT_SUM[504] = INT_CARRY[394];
assign INT_SUM[505] = INT_CARRY[395];
smfulladder dfa369 (.DATA_A (INT_SUM[499]), .DATA_B (INT_SUM[500]), .DATA_C (INT_SUM[501]), .SAVE (INT_SUM[506]), .CARRY (INT_CARRY[410]) );
smfulladder dfa370 (.DATA_A (INT_SUM[502]), .DATA_B (INT_SUM[503]), .DATA_C (INT_SUM[504]), .SAVE (INT_SUM[507]), .CARRY (INT_CARRY[411]) );
smfulladder dfa371 (.DATA_A (INT_SUM[505]), .DATA_B (INT_CARRY[396]), .DATA_C (INT_CARRY[397]), .SAVE (INT_SUM[508]), .CARRY (INT_CARRY[412]) );
assign INT_SUM[509] = INT_CARRY[398];
smfulladder dfa372 (.DATA_A (INT_SUM[506]), .DATA_B (INT_SUM[507]), .DATA_C (INT_SUM[508]), .SAVE (INT_SUM[510]), .CARRY (INT_CARRY[413]) );
smfulladder dfa373 (.DATA_A (INT_SUM[509]), .DATA_B (INT_CARRY[399]), .DATA_C (INT_CARRY[400]), .SAVE (INT_SUM[511]), .CARRY (INT_CARRY[414]) );
smfulladder dfa374 (.DATA_A (INT_SUM[510]), .DATA_B (INT_SUM[511]), .DATA_C (INT_CARRY[401]), .SAVE (INT_SUM[512]), .CARRY (INT_CARRY[415]) );
assign INT_SUM[513] = INT_CARRY[402];
smfulladder dfa375 (.DATA_A (INT_SUM[512]), .DATA_B (INT_SUM[513]), .DATA_C (INT_CARRY[403]), .SAVE (INT_SUM[514]), .CARRY (INT_CARRY[404]) );
smffb dla559 (.D(INT_SUM[514]), .clk(clk), .en_d2(en_d2), .Q(SUM[43]) );
smffb dla560 (.D(INT_CARRY[404]), .clk(clk), .en_d2(en_d2), .Q(CARRY[43]) );
smffa dla561 (.D(SUMMAND[474]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[474]) );
smffa dla562 (.D(SUMMAND[475]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[475]) );
smffa dla563 (.D(SUMMAND[476]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[476]) );
smfulladder dfa376 (.DATA_A (LATCHED_PP[474]), .DATA_B (LATCHED_PP[475]), .DATA_C (LATCHED_PP[476]), .SAVE (INT_SUM[515]), .CARRY (INT_CARRY[417]) );
smffa dla564 (.D(SUMMAND[477]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[477]) );
smffa dla565 (.D(SUMMAND[478]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[478]) );
smffa dla566 (.D(SUMMAND[479]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[479]) );
smfulladder dfa377 (.DATA_A (LATCHED_PP[477]), .DATA_B (LATCHED_PP[478]), .DATA_C (LATCHED_PP[479]), .SAVE (INT_SUM[516]), .CARRY (INT_CARRY[418]) );
smffa dla567 (.D(SUMMAND[480]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[480]) );
smffa dla568 (.D(SUMMAND[481]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[481]) );
smffa dla569 (.D(SUMMAND[482]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[482]) );
smfulladder dfa378 (.DATA_A (LATCHED_PP[480]), .DATA_B (LATCHED_PP[481]), .DATA_C (LATCHED_PP[482]), .SAVE (INT_SUM[517]), .CARRY (INT_CARRY[419]) );
smffa dla570 (.D(SUMMAND[483]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[483]) );
smffa dla571 (.D(SUMMAND[484]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[484]) );
smffa dla572 (.D(SUMMAND[485]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[485]) );
smfulladder dfa379 (.DATA_A (LATCHED_PP[483]), .DATA_B (LATCHED_PP[484]), .DATA_C (LATCHED_PP[485]), .SAVE (INT_SUM[518]), .CARRY (INT_CARRY[420]) );
smfulladder dfa380 (.DATA_A (INT_SUM[515]), .DATA_B (INT_SUM[516]), .DATA_C (INT_SUM[517]), .SAVE (INT_SUM[519]), .CARRY (INT_CARRY[421]) );
smfulladder dfa381 (.DATA_A (INT_SUM[518]), .DATA_B (INT_CARRY[405]), .DATA_C (INT_CARRY[406]), .SAVE (INT_SUM[520]), .CARRY (INT_CARRY[422]) );
smfulladder dfa382 (.DATA_A (INT_CARRY[407]), .DATA_B (INT_CARRY[408]), .DATA_C (INT_CARRY[409]), .SAVE (INT_SUM[521]), .CARRY (INT_CARRY[423]) );
smfulladder dfa383 (.DATA_A (INT_SUM[519]), .DATA_B (INT_SUM[520]), .DATA_C (INT_SUM[521]), .SAVE (INT_SUM[522]), .CARRY (INT_CARRY[424]) );
smfulladder dfa384 (.DATA_A (INT_CARRY[410]), .DATA_B (INT_CARRY[411]), .DATA_C (INT_CARRY[412]), .SAVE (INT_SUM[523]), .CARRY (INT_CARRY[425]) );
smfulladder dfa385 (.DATA_A (INT_SUM[522]), .DATA_B (INT_SUM[523]), .DATA_C (INT_CARRY[413]), .SAVE (INT_SUM[524]), .CARRY (INT_CARRY[426]) );
assign INT_SUM[525] = INT_CARRY[414];
smfulladder dfa386 (.DATA_A (INT_SUM[524]), .DATA_B (INT_SUM[525]), .DATA_C (INT_CARRY[415]), .SAVE (INT_SUM[526]), .CARRY (INT_CARRY[416]) );
smffb dla573 (.D(INT_SUM[526]), .clk(clk), .en_d2(en_d2), .Q(SUM[44]) );
smffb dla574 (.D(INT_CARRY[416]), .clk(clk), .en_d2(en_d2), .Q(CARRY[44]) );
smffa dla575 (.D(SUMMAND[486]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[486]) );
smffa dla576 (.D(SUMMAND[487]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[487]) );
smffa dla577 (.D(SUMMAND[488]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[488]) );
smfulladder dfa387 (.DATA_A (LATCHED_PP[486]), .DATA_B (LATCHED_PP[487]), .DATA_C (LATCHED_PP[488]), .SAVE (INT_SUM[527]), .CARRY (INT_CARRY[428]) );
smffa dla578 (.D(SUMMAND[489]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[489]) );
smffa dla579 (.D(SUMMAND[490]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[490]) );
smffa dla580 (.D(SUMMAND[491]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[491]) );
smfulladder dfa388 (.DATA_A (LATCHED_PP[489]), .DATA_B (LATCHED_PP[490]), .DATA_C (LATCHED_PP[491]), .SAVE (INT_SUM[528]), .CARRY (INT_CARRY[429]) );
smffa dla581 (.D(SUMMAND[492]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[492]) );
smffa dla582 (.D(SUMMAND[493]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[493]) );
smffa dla583 (.D(SUMMAND[494]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[494]) );
smfulladder dfa389 (.DATA_A (LATCHED_PP[492]), .DATA_B (LATCHED_PP[493]), .DATA_C (LATCHED_PP[494]), .SAVE (INT_SUM[529]), .CARRY (INT_CARRY[430]) );
smffa dla584 (.D(SUMMAND[495]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[495]) );
smffa dla585 (.D(SUMMAND[496]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[496]) );
smffa dla586 (.D(SUMMAND[497]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[497]) );
smfulladder dfa390 (.DATA_A (LATCHED_PP[495]), .DATA_B (LATCHED_PP[496]), .DATA_C (LATCHED_PP[497]), .SAVE (INT_SUM[530]), .CARRY (INT_CARRY[431]) );
smfulladder dfa391 (.DATA_A (INT_SUM[527]), .DATA_B (INT_SUM[528]), .DATA_C (INT_SUM[529]), .SAVE (INT_SUM[531]), .CARRY (INT_CARRY[432]) );
smfulladder dfa392 (.DATA_A (INT_SUM[530]), .DATA_B (INT_CARRY[417]), .DATA_C (INT_CARRY[418]), .SAVE (INT_SUM[532]), .CARRY (INT_CARRY[433]) );
smhalfadder dha40 (.DATA_A (INT_CARRY[419]), .DATA_B (INT_CARRY[420]), .SAVE (INT_SUM[533]), .CARRY (INT_CARRY[434]) );
smfulladder dfa393 (.DATA_A (INT_SUM[531]), .DATA_B (INT_SUM[532]), .DATA_C (INT_SUM[533]), .SAVE (INT_SUM[534]), .CARRY (INT_CARRY[435]) );
smfulladder dfa394 (.DATA_A (INT_CARRY[421]), .DATA_B (INT_CARRY[422]), .DATA_C (INT_CARRY[423]), .SAVE (INT_SUM[535]), .CARRY (INT_CARRY[436]) );
smfulladder dfa395 (.DATA_A (INT_SUM[534]), .DATA_B (INT_SUM[535]), .DATA_C (INT_CARRY[424]), .SAVE (INT_SUM[536]), .CARRY (INT_CARRY[437]) );
assign INT_SUM[537] = INT_CARRY[425];
smfulladder dfa396 (.DATA_A (INT_SUM[536]), .DATA_B (INT_SUM[537]), .DATA_C (INT_CARRY[426]), .SAVE (INT_SUM[538]), .CARRY (INT_CARRY[427]) );
smffb dla587 (.D(INT_SUM[538]), .clk(clk), .en_d2(en_d2), .Q(SUM[45]) );
smffb dla588 (.D(INT_CARRY[427]), .clk(clk), .en_d2(en_d2), .Q(CARRY[45]) );
smffa dla589 (.D(SUMMAND[498]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[498]) );
smffa dla590 (.D(SUMMAND[499]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[499]) );
smffa dla591 (.D(SUMMAND[500]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[500]) );
smfulladder dfa397 (.DATA_A (LATCHED_PP[498]), .DATA_B (LATCHED_PP[499]), .DATA_C (LATCHED_PP[500]), .SAVE (INT_SUM[539]), .CARRY (INT_CARRY[439]) );
smffa dla592 (.D(SUMMAND[501]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[501]) );
smffa dla593 (.D(SUMMAND[502]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[502]) );
smffa dla594 (.D(SUMMAND[503]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[503]) );
smfulladder dfa398 (.DATA_A (LATCHED_PP[501]), .DATA_B (LATCHED_PP[502]), .DATA_C (LATCHED_PP[503]), .SAVE (INT_SUM[540]), .CARRY (INT_CARRY[440]) );
smffa dla595 (.D(SUMMAND[504]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[504]) );
smffa dla596 (.D(SUMMAND[505]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[505]) );
smffa dla597 (.D(SUMMAND[506]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[506]) );
smfulladder dfa399 (.DATA_A (LATCHED_PP[504]), .DATA_B (LATCHED_PP[505]), .DATA_C (LATCHED_PP[506]), .SAVE (INT_SUM[541]), .CARRY (INT_CARRY[441]) );
smffa dla598 (.D(SUMMAND[507]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[507]) );
assign INT_SUM[542] = LATCHED_PP[507];
smffa dla599 (.D(SUMMAND[508]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[508]) );
assign INT_SUM[543] = LATCHED_PP[508];
smfulladder dfa400 (.DATA_A (INT_SUM[539]), .DATA_B (INT_SUM[540]), .DATA_C (INT_SUM[541]), .SAVE (INT_SUM[544]), .CARRY (INT_CARRY[442]) );
smfulladder dfa401 (.DATA_A (INT_SUM[542]), .DATA_B (INT_SUM[543]), .DATA_C (INT_CARRY[428]), .SAVE (INT_SUM[545]), .CARRY (INT_CARRY[443]) );
smfulladder dfa402 (.DATA_A (INT_CARRY[429]), .DATA_B (INT_CARRY[430]), .DATA_C (INT_CARRY[431]), .SAVE (INT_SUM[546]), .CARRY (INT_CARRY[444]) );
smfulladder dfa403 (.DATA_A (INT_SUM[544]), .DATA_B (INT_SUM[545]), .DATA_C (INT_SUM[546]), .SAVE (INT_SUM[547]), .CARRY (INT_CARRY[445]) );
smfulladder dfa404 (.DATA_A (INT_CARRY[432]), .DATA_B (INT_CARRY[433]), .DATA_C (INT_CARRY[434]), .SAVE (INT_SUM[548]), .CARRY (INT_CARRY[446]) );
smfulladder dfa405 (.DATA_A (INT_SUM[547]), .DATA_B (INT_SUM[548]), .DATA_C (INT_CARRY[435]), .SAVE (INT_SUM[549]), .CARRY (INT_CARRY[447]) );
assign INT_SUM[550] = INT_CARRY[436];
smfulladder dfa406 (.DATA_A (INT_SUM[549]), .DATA_B (INT_SUM[550]), .DATA_C (INT_CARRY[437]), .SAVE (INT_SUM[551]), .CARRY (INT_CARRY[438]) );
smffb dla600 (.D(INT_SUM[551]), .clk(clk), .en_d2(en_d2), .Q(SUM[46]) );
smffb dla601 (.D(INT_CARRY[438]), .clk(clk), .en_d2(en_d2), .Q(CARRY[46]) );
smffa dla602 (.D(SUMMAND[509]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[509]) );
smffa dla603 (.D(SUMMAND[510]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[510]) );
smffa dla604 (.D(SUMMAND[511]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[511]) );
smfulladder dfa407 (.DATA_A (LATCHED_PP[509]), .DATA_B (LATCHED_PP[510]), .DATA_C (LATCHED_PP[511]), .SAVE (INT_SUM[552]), .CARRY (INT_CARRY[449]) );
smffa dla605 (.D(SUMMAND[512]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[512]) );
smffa dla606 (.D(SUMMAND[513]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[513]) );
smffa dla607 (.D(SUMMAND[514]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[514]) );
smfulladder dfa408 (.DATA_A (LATCHED_PP[512]), .DATA_B (LATCHED_PP[513]), .DATA_C (LATCHED_PP[514]), .SAVE (INT_SUM[553]), .CARRY (INT_CARRY[450]) );
smffa dla608 (.D(SUMMAND[515]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[515]) );
smffa dla609 (.D(SUMMAND[516]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[516]) );
smffa dla610 (.D(SUMMAND[517]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[517]) );
smfulladder dfa409 (.DATA_A (LATCHED_PP[515]), .DATA_B (LATCHED_PP[516]), .DATA_C (LATCHED_PP[517]), .SAVE (INT_SUM[554]), .CARRY (INT_CARRY[451]) );
smffa dla611 (.D(SUMMAND[518]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[518]) );
smffa dla612 (.D(SUMMAND[519]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[519]) );
smhalfadder dha41 (.DATA_A (LATCHED_PP[518]), .DATA_B (LATCHED_PP[519]), .SAVE (INT_SUM[555]), .CARRY (INT_CARRY[452]) );
smfulladder dfa410 (.DATA_A (INT_SUM[552]), .DATA_B (INT_SUM[553]), .DATA_C (INT_SUM[554]), .SAVE (INT_SUM[556]), .CARRY (INT_CARRY[453]) );
smfulladder dfa411 (.DATA_A (INT_SUM[555]), .DATA_B (INT_CARRY[439]), .DATA_C (INT_CARRY[440]), .SAVE (INT_SUM[557]), .CARRY (INT_CARRY[454]) );
assign INT_SUM[558] = INT_CARRY[441];
smfulladder dfa412 (.DATA_A (INT_SUM[556]), .DATA_B (INT_SUM[557]), .DATA_C (INT_SUM[558]), .SAVE (INT_SUM[559]), .CARRY (INT_CARRY[455]) );
smfulladder dfa413 (.DATA_A (INT_CARRY[442]), .DATA_B (INT_CARRY[443]), .DATA_C (INT_CARRY[444]), .SAVE (INT_SUM[560]), .CARRY (INT_CARRY[456]) );
smfulladder dfa414 (.DATA_A (INT_SUM[559]), .DATA_B (INT_SUM[560]), .DATA_C (INT_CARRY[445]), .SAVE (INT_SUM[561]), .CARRY (INT_CARRY[457]) );
assign INT_SUM[562] = INT_CARRY[446];
smfulladder dfa415 (.DATA_A (INT_SUM[561]), .DATA_B (INT_SUM[562]), .DATA_C (INT_CARRY[447]), .SAVE (INT_SUM[563]), .CARRY (INT_CARRY[448]) );
smffb dla613 (.D(INT_SUM[563]), .clk(clk), .en_d2(en_d2), .Q(SUM[47]) );
smffb dla614 (.D(INT_CARRY[448]), .clk(clk), .en_d2(en_d2), .Q(CARRY[47]) );
smffa dla615 (.D(SUMMAND[520]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[520]) );
smffa dla616 (.D(SUMMAND[521]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[521]) );
smffa dla617 (.D(SUMMAND[522]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[522]) );
smfulladder dfa416 (.DATA_A (LATCHED_PP[520]), .DATA_B (LATCHED_PP[521]), .DATA_C (LATCHED_PP[522]), .SAVE (INT_SUM[564]), .CARRY (INT_CARRY[459]) );
smffa dla618 (.D(SUMMAND[523]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[523]) );
smffa dla619 (.D(SUMMAND[524]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[524]) );
smffa dla620 (.D(SUMMAND[525]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[525]) );
smfulladder dfa417 (.DATA_A (LATCHED_PP[523]), .DATA_B (LATCHED_PP[524]), .DATA_C (LATCHED_PP[525]), .SAVE (INT_SUM[565]), .CARRY (INT_CARRY[460]) );
smffa dla621 (.D(SUMMAND[526]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[526]) );
smffa dla622 (.D(SUMMAND[527]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[527]) );
smffa dla623 (.D(SUMMAND[528]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[528]) );
smfulladder dfa418 (.DATA_A (LATCHED_PP[526]), .DATA_B (LATCHED_PP[527]), .DATA_C (LATCHED_PP[528]), .SAVE (INT_SUM[566]), .CARRY (INT_CARRY[461]) );
smffa dla624 (.D(SUMMAND[529]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[529]) );
assign INT_SUM[567] = LATCHED_PP[529];
smfulladder dfa419 (.DATA_A (INT_SUM[564]), .DATA_B (INT_SUM[565]), .DATA_C (INT_SUM[566]), .SAVE (INT_SUM[568]), .CARRY (INT_CARRY[462]) );
smfulladder dfa420 (.DATA_A (INT_SUM[567]), .DATA_B (INT_CARRY[449]), .DATA_C (INT_CARRY[450]), .SAVE (INT_SUM[569]), .CARRY (INT_CARRY[463]) );
assign INT_SUM[570] = INT_CARRY[451];
assign INT_SUM[571] = INT_CARRY[452];
smfulladder dfa421 (.DATA_A (INT_SUM[568]), .DATA_B (INT_SUM[569]), .DATA_C (INT_SUM[570]), .SAVE (INT_SUM[572]), .CARRY (INT_CARRY[464]) );
smfulladder dfa422 (.DATA_A (INT_SUM[571]), .DATA_B (INT_CARRY[453]), .DATA_C (INT_CARRY[454]), .SAVE (INT_SUM[573]), .CARRY (INT_CARRY[465]) );
smfulladder dfa423 (.DATA_A (INT_SUM[572]), .DATA_B (INT_SUM[573]), .DATA_C (INT_CARRY[455]), .SAVE (INT_SUM[574]), .CARRY (INT_CARRY[466]) );
assign INT_SUM[575] = INT_CARRY[456];
smfulladder dfa424 (.DATA_A (INT_SUM[574]), .DATA_B (INT_SUM[575]), .DATA_C (INT_CARRY[457]), .SAVE (INT_SUM[576]), .CARRY (INT_CARRY[458]) );
smffb dla625 (.D(INT_SUM[576]), .clk(clk), .en_d2(en_d2), .Q(SUM[48]) );
smffb dla626 (.D(INT_CARRY[458]), .clk(clk), .en_d2(en_d2), .Q(CARRY[48]) );
smffa dla627 (.D(SUMMAND[530]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[530]) );
smffa dla628 (.D(SUMMAND[531]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[531]) );
smffa dla629 (.D(SUMMAND[532]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[532]) );
smfulladder dfa425 (.DATA_A (LATCHED_PP[530]), .DATA_B (LATCHED_PP[531]), .DATA_C (LATCHED_PP[532]), .SAVE (INT_SUM[577]), .CARRY (INT_CARRY[468]) );
smffa dla630 (.D(SUMMAND[533]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[533]) );
smffa dla631 (.D(SUMMAND[534]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[534]) );
smffa dla632 (.D(SUMMAND[535]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[535]) );
smfulladder dfa426 (.DATA_A (LATCHED_PP[533]), .DATA_B (LATCHED_PP[534]), .DATA_C (LATCHED_PP[535]), .SAVE (INT_SUM[578]), .CARRY (INT_CARRY[469]) );
smffa dla633 (.D(SUMMAND[536]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[536]) );
smffa dla634 (.D(SUMMAND[537]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[537]) );
smffa dla635 (.D(SUMMAND[538]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[538]) );
smfulladder dfa427 (.DATA_A (LATCHED_PP[536]), .DATA_B (LATCHED_PP[537]), .DATA_C (LATCHED_PP[538]), .SAVE (INT_SUM[579]), .CARRY (INT_CARRY[470]) );
smffa dla636 (.D(SUMMAND[539]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[539]) );
assign INT_SUM[580] = LATCHED_PP[539];
smfulladder dfa428 (.DATA_A (INT_SUM[577]), .DATA_B (INT_SUM[578]), .DATA_C (INT_SUM[579]), .SAVE (INT_SUM[581]), .CARRY (INT_CARRY[471]) );
smfulladder dfa429 (.DATA_A (INT_SUM[580]), .DATA_B (INT_CARRY[459]), .DATA_C (INT_CARRY[460]), .SAVE (INT_SUM[582]), .CARRY (INT_CARRY[472]) );
assign INT_SUM[583] = INT_CARRY[461];
smfulladder dfa430 (.DATA_A (INT_SUM[581]), .DATA_B (INT_SUM[582]), .DATA_C (INT_SUM[583]), .SAVE (INT_SUM[584]), .CARRY (INT_CARRY[473]) );
smhalfadder dha42 (.DATA_A (INT_CARRY[462]), .DATA_B (INT_CARRY[463]), .SAVE (INT_SUM[585]), .CARRY (INT_CARRY[474]) );
smfulladder dfa431 (.DATA_A (INT_SUM[584]), .DATA_B (INT_SUM[585]), .DATA_C (INT_CARRY[464]), .SAVE (INT_SUM[586]), .CARRY (INT_CARRY[475]) );
assign INT_SUM[587] = INT_CARRY[465];
smfulladder dfa432 (.DATA_A (INT_SUM[586]), .DATA_B (INT_SUM[587]), .DATA_C (INT_CARRY[466]), .SAVE (INT_SUM[588]), .CARRY (INT_CARRY[467]) );
smffb dla637 (.D(INT_SUM[588]), .clk(clk), .en_d2(en_d2), .Q(SUM[49]) );
smffb dla638 (.D(INT_CARRY[467]), .clk(clk), .en_d2(en_d2), .Q(CARRY[49]) );
smffa dla639 (.D(SUMMAND[540]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[540]) );
smffa dla640 (.D(SUMMAND[541]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[541]) );
smffa dla641 (.D(SUMMAND[542]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[542]) );
smfulladder dfa433 (.DATA_A (LATCHED_PP[540]), .DATA_B (LATCHED_PP[541]), .DATA_C (LATCHED_PP[542]), .SAVE (INT_SUM[589]), .CARRY (INT_CARRY[477]) );
smffa dla642 (.D(SUMMAND[543]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[543]) );
smffa dla643 (.D(SUMMAND[544]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[544]) );
smffa dla644 (.D(SUMMAND[545]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[545]) );
smfulladder dfa434 (.DATA_A (LATCHED_PP[543]), .DATA_B (LATCHED_PP[544]), .DATA_C (LATCHED_PP[545]), .SAVE (INT_SUM[590]), .CARRY (INT_CARRY[478]) );
smffa dla645 (.D(SUMMAND[546]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[546]) );
smffa dla646 (.D(SUMMAND[547]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[547]) );
smffa dla647 (.D(SUMMAND[548]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[548]) );
smfulladder dfa435 (.DATA_A (LATCHED_PP[546]), .DATA_B (LATCHED_PP[547]), .DATA_C (LATCHED_PP[548]), .SAVE (INT_SUM[591]), .CARRY (INT_CARRY[479]) );
smfulladder dfa436 (.DATA_A (INT_SUM[589]), .DATA_B (INT_SUM[590]), .DATA_C (INT_SUM[591]), .SAVE (INT_SUM[592]), .CARRY (INT_CARRY[480]) );
smfulladder dfa437 (.DATA_A (INT_CARRY[468]), .DATA_B (INT_CARRY[469]), .DATA_C (INT_CARRY[470]), .SAVE (INT_SUM[593]), .CARRY (INT_CARRY[481]) );
smfulladder dfa438 (.DATA_A (INT_SUM[592]), .DATA_B (INT_SUM[593]), .DATA_C (INT_CARRY[471]), .SAVE (INT_SUM[594]), .CARRY (INT_CARRY[482]) );
assign INT_SUM[595] = INT_CARRY[472];
smfulladder dfa439 (.DATA_A (INT_SUM[594]), .DATA_B (INT_SUM[595]), .DATA_C (INT_CARRY[473]), .SAVE (INT_SUM[596]), .CARRY (INT_CARRY[483]) );
assign INT_SUM[597] = INT_CARRY[474];
smfulladder dfa440 (.DATA_A (INT_SUM[596]), .DATA_B (INT_SUM[597]), .DATA_C (INT_CARRY[475]), .SAVE (INT_SUM[598]), .CARRY (INT_CARRY[476]) );
smffb dla648 (.D(INT_SUM[598]), .clk(clk), .en_d2(en_d2), .Q(SUM[50]) );
smffb dla649 (.D(INT_CARRY[476]), .clk(clk), .en_d2(en_d2), .Q(CARRY[50]) );
smffa dla650 (.D(SUMMAND[549]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[549]) );
smffa dla651 (.D(SUMMAND[550]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[550]) );
smffa dla652 (.D(SUMMAND[551]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[551]) );
smfulladder dfa441 (.DATA_A (LATCHED_PP[549]), .DATA_B (LATCHED_PP[550]), .DATA_C (LATCHED_PP[551]), .SAVE (INT_SUM[599]), .CARRY (INT_CARRY[485]) );
smffa dla653 (.D(SUMMAND[552]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[552]) );
smffa dla654 (.D(SUMMAND[553]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[553]) );
smffa dla655 (.D(SUMMAND[554]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[554]) );
smfulladder dfa442 (.DATA_A (LATCHED_PP[552]), .DATA_B (LATCHED_PP[553]), .DATA_C (LATCHED_PP[554]), .SAVE (INT_SUM[600]), .CARRY (INT_CARRY[486]) );
smffa dla656 (.D(SUMMAND[555]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[555]) );
smffa dla657 (.D(SUMMAND[556]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[556]) );
smffa dla658 (.D(SUMMAND[557]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[557]) );
smfulladder dfa443 (.DATA_A (LATCHED_PP[555]), .DATA_B (LATCHED_PP[556]), .DATA_C (LATCHED_PP[557]), .SAVE (INT_SUM[601]), .CARRY (INT_CARRY[487]) );
smfulladder dfa444 (.DATA_A (INT_SUM[599]), .DATA_B (INT_SUM[600]), .DATA_C (INT_SUM[601]), .SAVE (INT_SUM[602]), .CARRY (INT_CARRY[488]) );
smfulladder dfa445 (.DATA_A (INT_CARRY[477]), .DATA_B (INT_CARRY[478]), .DATA_C (INT_CARRY[479]), .SAVE (INT_SUM[603]), .CARRY (INT_CARRY[489]) );
smfulladder dfa446 (.DATA_A (INT_SUM[602]), .DATA_B (INT_SUM[603]), .DATA_C (INT_CARRY[480]), .SAVE (INT_SUM[604]), .CARRY (INT_CARRY[490]) );
assign INT_SUM[605] = INT_CARRY[481];
smfulladder dfa447 (.DATA_A (INT_SUM[604]), .DATA_B (INT_SUM[605]), .DATA_C (INT_CARRY[482]), .SAVE (INT_SUM[606]), .CARRY (INT_CARRY[491]) );
smhalfadder dha43 (.DATA_A (INT_SUM[606]), .DATA_B (INT_CARRY[483]), .SAVE (INT_SUM[607]), .CARRY (INT_CARRY[484]) );
smffb dla659 (.D(INT_SUM[607]), .clk(clk), .en_d2(en_d2), .Q(SUM[51]) );
smffb dla660 (.D(INT_CARRY[484]), .clk(clk), .en_d2(en_d2), .Q(CARRY[51]) );
smffa dla661 (.D(SUMMAND[558]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[558]) );
smffa dla662 (.D(SUMMAND[559]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[559]) );
smffa dla663 (.D(SUMMAND[560]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[560]) );
smfulladder dfa448 (.DATA_A (LATCHED_PP[558]), .DATA_B (LATCHED_PP[559]), .DATA_C (LATCHED_PP[560]), .SAVE (INT_SUM[608]), .CARRY (INT_CARRY[493]) );
smffa dla664 (.D(SUMMAND[561]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[561]) );
smffa dla665 (.D(SUMMAND[562]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[562]) );
smffa dla666 (.D(SUMMAND[563]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[563]) );
smfulladder dfa449 (.DATA_A (LATCHED_PP[561]), .DATA_B (LATCHED_PP[562]), .DATA_C (LATCHED_PP[563]), .SAVE (INT_SUM[609]), .CARRY (INT_CARRY[494]) );
smffa dla667 (.D(SUMMAND[564]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[564]) );
smffa dla668 (.D(SUMMAND[565]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[565]) );
smfulladder dfa450 (.DATA_A (LATCHED_PP[564]), .DATA_B (LATCHED_PP[565]), .DATA_C (INT_CARRY[485]), .SAVE (INT_SUM[610]), .CARRY (INT_CARRY[495]) );
smhalfadder dha44 (.DATA_A (INT_CARRY[486]), .DATA_B (INT_CARRY[487]), .SAVE (INT_SUM[611]), .CARRY (INT_CARRY[496]) );
smfulladder dfa451 (.DATA_A (INT_SUM[608]), .DATA_B (INT_SUM[609]), .DATA_C (INT_SUM[610]), .SAVE (INT_SUM[612]), .CARRY (INT_CARRY[497]) );
smfulladder dfa452 (.DATA_A (INT_SUM[611]), .DATA_B (INT_CARRY[488]), .DATA_C (INT_CARRY[489]), .SAVE (INT_SUM[613]), .CARRY (INT_CARRY[498]) );
smfulladder dfa453 (.DATA_A (INT_SUM[612]), .DATA_B (INT_SUM[613]), .DATA_C (INT_CARRY[490]), .SAVE (INT_SUM[614]), .CARRY (INT_CARRY[499]) );
smhalfadder dha45 (.DATA_A (INT_SUM[614]), .DATA_B (INT_CARRY[491]), .SAVE (INT_SUM[615]), .CARRY (INT_CARRY[492]) );
smffb dla669 (.D(INT_SUM[615]), .clk(clk), .en_d2(en_d2), .Q(SUM[52]) );
smffb dla670 (.D(INT_CARRY[492]), .clk(clk), .en_d2(en_d2), .Q(CARRY[52]) );
smffa dla671 (.D(SUMMAND[566]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[566]) );
smffa dla672 (.D(SUMMAND[567]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[567]) );
smffa dla673 (.D(SUMMAND[568]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[568]) );
smfulladder dfa454 (.DATA_A (LATCHED_PP[566]), .DATA_B (LATCHED_PP[567]), .DATA_C (LATCHED_PP[568]), .SAVE (INT_SUM[616]), .CARRY (INT_CARRY[501]) );
smffa dla674 (.D(SUMMAND[569]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[569]) );
smffa dla675 (.D(SUMMAND[570]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[570]) );
smffa dla676 (.D(SUMMAND[571]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[571]) );
smfulladder dfa455 (.DATA_A (LATCHED_PP[569]), .DATA_B (LATCHED_PP[570]), .DATA_C (LATCHED_PP[571]), .SAVE (INT_SUM[617]), .CARRY (INT_CARRY[502]) );
smffa dla677 (.D(SUMMAND[572]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[572]) );
assign INT_SUM[618] = LATCHED_PP[572];
smffa dla678 (.D(SUMMAND[573]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[573]) );
assign INT_SUM[619] = LATCHED_PP[573];
smfulladder dfa456 (.DATA_A (INT_SUM[616]), .DATA_B (INT_SUM[617]), .DATA_C (INT_SUM[618]), .SAVE (INT_SUM[620]), .CARRY (INT_CARRY[503]) );
assign INT_SUM[621] = INT_SUM[619];
smfulladder dfa457 (.DATA_A (INT_SUM[620]), .DATA_B (INT_SUM[621]), .DATA_C (INT_CARRY[493]), .SAVE (INT_SUM[622]), .CARRY (INT_CARRY[504]) );
smfulladder dfa458 (.DATA_A (INT_CARRY[494]), .DATA_B (INT_CARRY[495]), .DATA_C (INT_CARRY[496]), .SAVE (INT_SUM[623]), .CARRY (INT_CARRY[505]) );
smfulladder dfa459 (.DATA_A (INT_SUM[622]), .DATA_B (INT_SUM[623]), .DATA_C (INT_CARRY[497]), .SAVE (INT_SUM[624]), .CARRY (INT_CARRY[506]) );
assign INT_SUM[625] = INT_CARRY[498];
smfulladder dfa460 (.DATA_A (INT_SUM[624]), .DATA_B (INT_SUM[625]), .DATA_C (INT_CARRY[499]), .SAVE (INT_SUM[626]), .CARRY (INT_CARRY[500]) );
smffb dla679 (.D(INT_SUM[626]), .clk(clk), .en_d2(en_d2), .Q(SUM[53]) );
smffb dla680 (.D(INT_CARRY[500]), .clk(clk), .en_d2(en_d2), .Q(CARRY[53]) );
smffa dla681 (.D(SUMMAND[574]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[574]) );
smffa dla682 (.D(SUMMAND[575]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[575]) );
smffa dla683 (.D(SUMMAND[576]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[576]) );
smfulladder dfa461 (.DATA_A (LATCHED_PP[574]), .DATA_B (LATCHED_PP[575]), .DATA_C (LATCHED_PP[576]), .SAVE (INT_SUM[627]), .CARRY (INT_CARRY[508]) );
smffa dla684 (.D(SUMMAND[577]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[577]) );
smffa dla685 (.D(SUMMAND[578]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[578]) );
smffa dla686 (.D(SUMMAND[579]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[579]) );
smfulladder dfa462 (.DATA_A (LATCHED_PP[577]), .DATA_B (LATCHED_PP[578]), .DATA_C (LATCHED_PP[579]), .SAVE (INT_SUM[628]), .CARRY (INT_CARRY[509]) );
smffa dla687 (.D(SUMMAND[580]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[580]) );
smfulladder dfa463 (.DATA_A (LATCHED_PP[580]), .DATA_B (INT_CARRY[501]), .DATA_C (INT_CARRY[502]), .SAVE (INT_SUM[629]), .CARRY (INT_CARRY[510]) );
smfulladder dfa464 (.DATA_A (INT_SUM[627]), .DATA_B (INT_SUM[628]), .DATA_C (INT_SUM[629]), .SAVE (INT_SUM[630]), .CARRY (INT_CARRY[511]) );
assign INT_SUM[631] = INT_CARRY[503];
smfulladder dfa465 (.DATA_A (INT_SUM[630]), .DATA_B (INT_SUM[631]), .DATA_C (INT_CARRY[504]), .SAVE (INT_SUM[632]), .CARRY (INT_CARRY[512]) );
assign INT_SUM[633] = INT_CARRY[505];
smfulladder dfa466 (.DATA_A (INT_SUM[632]), .DATA_B (INT_SUM[633]), .DATA_C (INT_CARRY[506]), .SAVE (INT_SUM[634]), .CARRY (INT_CARRY[507]) );
smffb dla688 (.D(INT_SUM[634]), .clk(clk), .en_d2(en_d2), .Q(SUM[54]) );
smffb dla689 (.D(INT_CARRY[507]), .clk(clk), .en_d2(en_d2), .Q(CARRY[54]) );
smffa dla690 (.D(SUMMAND[581]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[581]) );
smffa dla691 (.D(SUMMAND[582]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[582]) );
smffa dla692 (.D(SUMMAND[583]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[583]) );
smfulladder dfa467 (.DATA_A (LATCHED_PP[581]), .DATA_B (LATCHED_PP[582]), .DATA_C (LATCHED_PP[583]), .SAVE (INT_SUM[635]), .CARRY (INT_CARRY[514]) );
smffa dla693 (.D(SUMMAND[584]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[584]) );
smffa dla694 (.D(SUMMAND[585]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[585]) );
smffa dla695 (.D(SUMMAND[586]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[586]) );
smfulladder dfa468 (.DATA_A (LATCHED_PP[584]), .DATA_B (LATCHED_PP[585]), .DATA_C (LATCHED_PP[586]), .SAVE (INT_SUM[636]), .CARRY (INT_CARRY[515]) );
smffa dla696 (.D(SUMMAND[587]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[587]) );
assign INT_SUM[637] = LATCHED_PP[587];
smfulladder dfa469 (.DATA_A (INT_SUM[635]), .DATA_B (INT_SUM[636]), .DATA_C (INT_SUM[637]), .SAVE (INT_SUM[638]), .CARRY (INT_CARRY[516]) );
smfulladder dfa470 (.DATA_A (INT_CARRY[508]), .DATA_B (INT_CARRY[509]), .DATA_C (INT_CARRY[510]), .SAVE (INT_SUM[639]), .CARRY (INT_CARRY[517]) );
smfulladder dfa471 (.DATA_A (INT_SUM[638]), .DATA_B (INT_SUM[639]), .DATA_C (INT_CARRY[511]), .SAVE (INT_SUM[640]), .CARRY (INT_CARRY[518]) );
smhalfadder dha46 (.DATA_A (INT_SUM[640]), .DATA_B (INT_CARRY[512]), .SAVE (INT_SUM[641]), .CARRY (INT_CARRY[513]) );
smffb dla697 (.D(INT_SUM[641]), .clk(clk), .en_d2(en_d2), .Q(SUM[55]) );
smffb dla698 (.D(INT_CARRY[513]), .clk(clk), .en_d2(en_d2), .Q(CARRY[55]) );
smffa dla699 (.D(SUMMAND[588]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[588]) );
smffa dla700 (.D(SUMMAND[589]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[589]) );
smffa dla701 (.D(SUMMAND[590]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[590]) );
smfulladder dfa472 (.DATA_A (LATCHED_PP[588]), .DATA_B (LATCHED_PP[589]), .DATA_C (LATCHED_PP[590]), .SAVE (INT_SUM[642]), .CARRY (INT_CARRY[520]) );
smffa dla702 (.D(SUMMAND[591]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[591]) );
smffa dla703 (.D(SUMMAND[592]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[592]) );
smffa dla704 (.D(SUMMAND[593]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[593]) );
smfulladder dfa473 (.DATA_A (LATCHED_PP[591]), .DATA_B (LATCHED_PP[592]), .DATA_C (LATCHED_PP[593]), .SAVE (INT_SUM[643]), .CARRY (INT_CARRY[521]) );
smfulladder dfa474 (.DATA_A (INT_SUM[642]), .DATA_B (INT_SUM[643]), .DATA_C (INT_CARRY[514]), .SAVE (INT_SUM[644]), .CARRY (INT_CARRY[522]) );
assign INT_SUM[645] = INT_CARRY[515];
smfulladder dfa475 (.DATA_A (INT_SUM[644]), .DATA_B (INT_SUM[645]), .DATA_C (INT_CARRY[516]), .SAVE (INT_SUM[646]), .CARRY (INT_CARRY[523]) );
assign INT_SUM[647] = INT_CARRY[517];
smfulladder dfa476 (.DATA_A (INT_SUM[646]), .DATA_B (INT_SUM[647]), .DATA_C (INT_CARRY[518]), .SAVE (INT_SUM[648]), .CARRY (INT_CARRY[519]) );
smffb dla705 (.D(INT_SUM[648]), .clk(clk), .en_d2(en_d2), .Q(SUM[56]) );
smffb dla706 (.D(INT_CARRY[519]), .clk(clk), .en_d2(en_d2), .Q(CARRY[56]) );
smffa dla707 (.D(SUMMAND[594]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[594]) );
smffa dla708 (.D(SUMMAND[595]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[595]) );
smffa dla709 (.D(SUMMAND[596]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[596]) );
smfulladder dfa477 (.DATA_A (LATCHED_PP[594]), .DATA_B (LATCHED_PP[595]), .DATA_C (LATCHED_PP[596]), .SAVE (INT_SUM[649]), .CARRY (INT_CARRY[525]) );
smffa dla710 (.D(SUMMAND[597]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[597]) );
smffa dla711 (.D(SUMMAND[598]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[598]) );
smffa dla712 (.D(SUMMAND[599]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[599]) );
smfulladder dfa478 (.DATA_A (LATCHED_PP[597]), .DATA_B (LATCHED_PP[598]), .DATA_C (LATCHED_PP[599]), .SAVE (INT_SUM[650]), .CARRY (INT_CARRY[526]) );
smfulladder dfa479 (.DATA_A (INT_SUM[649]), .DATA_B (INT_SUM[650]), .DATA_C (INT_CARRY[520]), .SAVE (INT_SUM[651]), .CARRY (INT_CARRY[527]) );
assign INT_SUM[652] = INT_CARRY[521];
smfulladder dfa480 (.DATA_A (INT_SUM[651]), .DATA_B (INT_SUM[652]), .DATA_C (INT_CARRY[522]), .SAVE (INT_SUM[653]), .CARRY (INT_CARRY[528]) );
smhalfadder dha47 (.DATA_A (INT_SUM[653]), .DATA_B (INT_CARRY[523]), .SAVE (INT_SUM[654]), .CARRY (INT_CARRY[524]) );
smffb dla713 (.D(INT_SUM[654]), .clk(clk), .en_d2(en_d2), .Q(SUM[57]) );
smffb dla714 (.D(INT_CARRY[524]), .clk(clk), .en_d2(en_d2), .Q(CARRY[57]) );
smffa dla715 (.D(SUMMAND[600]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[600]) );
smffa dla716 (.D(SUMMAND[601]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[601]) );
smffa dla717 (.D(SUMMAND[602]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[602]) );
smfulladder dfa481 (.DATA_A (LATCHED_PP[600]), .DATA_B (LATCHED_PP[601]), .DATA_C (LATCHED_PP[602]), .SAVE (INT_SUM[655]), .CARRY (INT_CARRY[530]) );
smffa dla718 (.D(SUMMAND[603]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[603]) );
smffa dla719 (.D(SUMMAND[604]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[604]) );
smhalfadder dha48 (.DATA_A (LATCHED_PP[603]), .DATA_B (LATCHED_PP[604]), .SAVE (INT_SUM[656]), .CARRY (INT_CARRY[531]) );
smfulladder dfa482 (.DATA_A (INT_SUM[655]), .DATA_B (INT_SUM[656]), .DATA_C (INT_CARRY[525]), .SAVE (INT_SUM[657]), .CARRY (INT_CARRY[532]) );
assign INT_SUM[658] = INT_CARRY[526];
smfulladder dfa483 (.DATA_A (INT_SUM[657]), .DATA_B (INT_SUM[658]), .DATA_C (INT_CARRY[527]), .SAVE (INT_SUM[659]), .CARRY (INT_CARRY[533]) );
smhalfadder dha49 (.DATA_A (INT_SUM[659]), .DATA_B (INT_CARRY[528]), .SAVE (INT_SUM[660]), .CARRY (INT_CARRY[529]) );
smffb dla720 (.D(INT_SUM[660]), .clk(clk), .en_d2(en_d2), .Q(SUM[58]) );
smffb dla721 (.D(INT_CARRY[529]), .clk(clk), .en_d2(en_d2), .Q(CARRY[58]) );
smffa dla722 (.D(SUMMAND[605]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[605]) );
smffa dla723 (.D(SUMMAND[606]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[606]) );
smffa dla724 (.D(SUMMAND[607]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[607]) );
smfulladder dfa484 (.DATA_A (LATCHED_PP[605]), .DATA_B (LATCHED_PP[606]), .DATA_C (LATCHED_PP[607]), .SAVE (INT_SUM[661]), .CARRY (INT_CARRY[535]) );
smffa dla725 (.D(SUMMAND[608]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[608]) );
smffa dla726 (.D(SUMMAND[609]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[609]) );
smhalfadder dha50 (.DATA_A (LATCHED_PP[608]), .DATA_B (LATCHED_PP[609]), .SAVE (INT_SUM[662]), .CARRY (INT_CARRY[536]) );
smfulladder dfa485 (.DATA_A (INT_SUM[661]), .DATA_B (INT_SUM[662]), .DATA_C (INT_CARRY[530]), .SAVE (INT_SUM[663]), .CARRY (INT_CARRY[537]) );
assign INT_SUM[664] = INT_CARRY[531];
smfulladder dfa486 (.DATA_A (INT_SUM[663]), .DATA_B (INT_SUM[664]), .DATA_C (INT_CARRY[532]), .SAVE (INT_SUM[665]), .CARRY (INT_CARRY[538]) );
smhalfadder dha51 (.DATA_A (INT_SUM[665]), .DATA_B (INT_CARRY[533]), .SAVE (INT_SUM[666]), .CARRY (INT_CARRY[534]) );
smffb dla727 (.D(INT_SUM[666]), .clk(clk), .en_d2(en_d2), .Q(SUM[59]) );
smffb dla728 (.D(INT_CARRY[534]), .clk(clk), .en_d2(en_d2), .Q(CARRY[59]) );
smffa dla729 (.D(SUMMAND[610]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[610]) );
smffa dla730 (.D(SUMMAND[611]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[611]) );
smffa dla731 (.D(SUMMAND[612]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[612]) );
smfulladder dfa487 (.DATA_A (LATCHED_PP[610]), .DATA_B (LATCHED_PP[611]), .DATA_C (LATCHED_PP[612]), .SAVE (INT_SUM[667]), .CARRY (INT_CARRY[540]) );
smffa dla732 (.D(SUMMAND[613]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[613]) );
smfulladder dfa488 (.DATA_A (LATCHED_PP[613]), .DATA_B (INT_CARRY[535]), .DATA_C (INT_CARRY[536]), .SAVE (INT_SUM[668]), .CARRY (INT_CARRY[541]) );
smfulladder dfa489 (.DATA_A (INT_SUM[667]), .DATA_B (INT_SUM[668]), .DATA_C (INT_CARRY[537]), .SAVE (INT_SUM[669]), .CARRY (INT_CARRY[542]) );
smhalfadder dha52 (.DATA_A (INT_SUM[669]), .DATA_B (INT_CARRY[538]), .SAVE (INT_SUM[670]), .CARRY (INT_CARRY[539]) );
smffb dla733 (.D(INT_SUM[670]), .clk(clk), .en_d2(en_d2), .Q(SUM[60]) );
smffb dla734 (.D(INT_CARRY[539]), .clk(clk), .en_d2(en_d2), .Q(CARRY[60]) );
smffa dla735 (.D(SUMMAND[614]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[614]) );
smffa dla736 (.D(SUMMAND[615]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[615]) );
smffa dla737 (.D(SUMMAND[616]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[616]) );
smfulladder dfa490 (.DATA_A (LATCHED_PP[614]), .DATA_B (LATCHED_PP[615]), .DATA_C (LATCHED_PP[616]), .SAVE (INT_SUM[671]), .CARRY (INT_CARRY[544]) );
smffa dla738 (.D(SUMMAND[617]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[617]) );
assign INT_SUM[672] = LATCHED_PP[617];
smfulladder dfa491 (.DATA_A (INT_SUM[671]), .DATA_B (INT_SUM[672]), .DATA_C (INT_CARRY[540]), .SAVE (INT_SUM[673]), .CARRY (INT_CARRY[545]) );
assign INT_SUM[674] = INT_CARRY[541];
smfulladder dfa492 (.DATA_A (INT_SUM[673]), .DATA_B (INT_SUM[674]), .DATA_C (INT_CARRY[542]), .SAVE (INT_SUM[675]), .CARRY (INT_CARRY[543]) );
smffb dla739 (.D(INT_SUM[675]), .clk(clk), .en_d2(en_d2), .Q(SUM[61]) );
smffb dla740 (.D(INT_CARRY[543]), .clk(clk), .en_d2(en_d2), .Q(CARRY[61]) );
smffa dla741 (.D(SUMMAND[618]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[618]) );
smffa dla742 (.D(SUMMAND[619]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[619]) );
smffa dla743 (.D(SUMMAND[620]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[620]) );
smfulladder dfa493 (.DATA_A (LATCHED_PP[618]), .DATA_B (LATCHED_PP[619]), .DATA_C (LATCHED_PP[620]), .SAVE (INT_SUM[676]), .CARRY (INT_CARRY[547]) );
assign INT_SUM[677] = INT_SUM[676];
assign INT_SUM[678] = INT_CARRY[544];
smfulladder dfa494 (.DATA_A (INT_SUM[677]), .DATA_B (INT_SUM[678]), .DATA_C (INT_CARRY[545]), .SAVE (INT_SUM[679]), .CARRY (INT_CARRY[546]) );
smffb dla744 (.D(INT_SUM[679]), .clk(clk), .en_d2(en_d2), .Q(SUM[62]) );
smffb dla745 (.D(INT_CARRY[546]), .clk(clk), .en_d2(en_d2), .Q(CARRY[62]) );
smffa dla746 (.D(SUMMAND[621]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[621]) );
smffa dla747 (.D(SUMMAND[622]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[622]) );
smffa dla748 (.D(SUMMAND[623]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[623]) );
smfulladder dfa495 (.DATA_A (LATCHED_PP[621]), .DATA_B (LATCHED_PP[622]), .DATA_C (LATCHED_PP[623]), .SAVE (INT_SUM[680]), .CARRY (INT_CARRY[549]) );
assign INT_SUM[681] = INT_CARRY[547];
smhalfadder dha53 (.DATA_A (INT_SUM[680]), .DATA_B (INT_SUM[681]), .SAVE (INT_SUM[682]), .CARRY (INT_CARRY[548]) );
smffb dla749 (.D(INT_SUM[682]), .clk(clk), .en_d2(en_d2), .Q(SUM[63]) );
smffb dla750 (.D(INT_CARRY[548]), .clk(clk), .en_d2(en_d2), .Q(CARRY[63]) );
smffa dla751 (.D(SUMMAND[624]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[624]) );
assign INT_SUM[683] = LATCHED_PP[624];
smffa dla752 (.D(SUMMAND[625]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[625]) );
assign INT_SUM[684] = LATCHED_PP[625];
smfulladder dfa496 (.DATA_A (INT_SUM[683]), .DATA_B (INT_SUM[684]), .DATA_C (INT_CARRY[549]), .SAVE (INT_SUM[685]), .CARRY (INT_CARRY[550]) );
smffb dla753 (.D(INT_SUM[685]), .clk(clk), .en_d2(en_d2), .Q(SUM[64]) );
smffb dla754 (.D(INT_CARRY[550]), .clk(clk), .en_d2(en_d2), .Q(CARRY[64]) );
smffa dla755 (.D(SUMMAND[626]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[626]) );
smffa dla756 (.D(SUMMAND[627]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[627]) );
smhalfadder dha54 (.DATA_A (LATCHED_PP[626]), .DATA_B (LATCHED_PP[627]), .SAVE (INT_SUM[686]), .CARRY (INT_CARRY[551]) );
smffb dla757 (.D(INT_SUM[686]), .clk(clk), .en_d2(en_d2), .Q(SUM[65]) );
smffb dla758 (.D(INT_CARRY[551]), .clk(clk), .en_d2(en_d2), .Q(CARRY[65]) );
smffa dla759 (.D(SUMMAND[628]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[628]) );
assign INT_SUM[687] = LATCHED_PP[628];
smffb dla760 (.D(INT_SUM[687]), .clk(clk), .en_d2(en_d2), .Q(SUM[66]) );
endmodule
module smprestage_128 ( A, B, CIN, POUT, GOUT );
input [63:0] A;
input [63:0] B;
input CIN;
output [63:0] POUT;
output [63:0] GOUT;
smblock0 d10 (A[0], B[0], POUT[0], GOUT[1] );
smblock0 d11 (A[1], B[1], POUT[1], GOUT[2] );
smblock0 d12 (A[2], B[2], POUT[2], GOUT[3] );
smblock0 d13 (A[3], B[3], POUT[3], GOUT[4] );
smblock0 d14 (A[4], B[4], POUT[4], GOUT[5] );
smblock0 d15 (A[5], B[5], POUT[5], GOUT[6] );
smblock0 d16 (A[6], B[6], POUT[6], GOUT[7] );
smblock0 d17 (A[7], B[7], POUT[7], GOUT[8] );
smblock0 d18 (A[8], B[8], POUT[8], GOUT[9] );
smblock0 d19 (A[9], B[9], POUT[9], GOUT[10] );
smblock0 d110 (A[10], B[10], POUT[10], GOUT[11] );
smblock0 d111 (A[11], B[11], POUT[11], GOUT[12] );
smblock0 d112 (A[12], B[12], POUT[12], GOUT[13] );
smblock0 d113 (A[13], B[13], POUT[13], GOUT[14] );
smblock0 d114 (A[14], B[14], POUT[14], GOUT[15] );
smblock0 d115 (A[15], B[15], POUT[15], GOUT[16] );
smblock0 d116 (A[16], B[16], POUT[16], GOUT[17] );
smblock0 d117 (A[17], B[17], POUT[17], GOUT[18] );
smblock0 d118 (A[18], B[18], POUT[18], GOUT[19] );
smblock0 d119 (A[19], B[19], POUT[19], GOUT[20] );
smblock0 d120 (A[20], B[20], POUT[20], GOUT[21] );
smblock0 d121 (A[21], B[21], POUT[21], GOUT[22] );
smblock0 d122 (A[22], B[22], POUT[22], GOUT[23] );
smblock0 d123 (A[23], B[23], POUT[23], GOUT[24] );
smblock0 d124 (A[24], B[24], POUT[24], GOUT[25] );
smblock0 d125 (A[25], B[25], POUT[25], GOUT[26] );
smblock0 d126 (A[26], B[26], POUT[26], GOUT[27] );
smblock0 d127 (A[27], B[27], POUT[27], GOUT[28] );
smblock0 d128 (A[28], B[28], POUT[28], GOUT[29] );
smblock0 d129 (A[29], B[29], POUT[29], GOUT[30] );
smblock0 d130 (A[30], B[30], POUT[30], GOUT[31] );
smblock0 d131 (A[31], B[31], POUT[31], GOUT[32] );
smblock0 d132 (A[32], B[32], POUT[32], GOUT[33] );
smblock0 d133 (A[33], B[33], POUT[33], GOUT[34] );
smblock0 d134 (A[34], B[34], POUT[34], GOUT[35] );
smblock0 d135 (A[35], B[35], POUT[35], GOUT[36] );
smblock0 d136 (A[36], B[36], POUT[36], GOUT[37] );
smblock0 d137 (A[37], B[37], POUT[37], GOUT[38] );
smblock0 d138 (A[38], B[38], POUT[38], GOUT[39] );
smblock0 d139 (A[39], B[39], POUT[39], GOUT[40] );
smblock0 d140 (A[40], B[40], POUT[40], GOUT[41] );
smblock0 d141 (A[41], B[41], POUT[41], GOUT[42] );
smblock0 d142 (A[42], B[42], POUT[42], GOUT[43] );
smblock0 d143 (A[43], B[43], POUT[43], GOUT[44] );
smblock0 d144 (A[44], B[44], POUT[44], GOUT[45] );
smblock0 d145 (A[45], B[45], POUT[45], GOUT[46] );
smblock0 d146 (A[46], B[46], POUT[46], GOUT[47] );
smblock0 d147 (A[47], B[47], POUT[47], GOUT[48] );
smblock0 d148 (A[48], B[48], POUT[48], GOUT[49] );
smblock0 d149 (A[49], B[49], POUT[49], GOUT[50] );
smblock0 d150 (A[50], B[50], POUT[50], GOUT[51] );
smblock0 d151 (A[51], B[51], POUT[51], GOUT[52] );
smblock0 d152 (A[52], B[52], POUT[52], GOUT[53] );
smblock0 d153 (A[53], B[53], POUT[53], GOUT[54] );
smblock0 d154 (A[54], B[54], POUT[54], GOUT[55] );
smblock0 d155 (A[55], B[55], POUT[55], GOUT[56] );
smblock0 d156 (A[56], B[56], POUT[56], GOUT[57] );
smblock0 d157 (A[57], B[57], POUT[57], GOUT[58] );
smblock0 d158 (A[58], B[58], POUT[58], GOUT[59] );
smblock0 d159 (A[59], B[59], POUT[59], GOUT[60] );
smblock0 d160 (A[60], B[60], POUT[60], GOUT[61] );
smblock0 d161 (A[61], B[61], POUT[61], GOUT[62] );
smblock0 d162 (A[62], B[62], POUT[62], GOUT[63] );
sminvblock d2 (CIN, GOUT[0] );
endmodule
module smdblc_0_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
smblock1a d21 (PIN[0], GIN[0], GIN[1], GOUT[1] );
smblock1 d32 (PIN[0], PIN[1], GIN[1], GIN[2], POUT[0], GOUT[2] );
smblock1 d33 (PIN[1], PIN[2], GIN[2], GIN[3], POUT[1], GOUT[3] );
smblock1 d34 (PIN[2], PIN[3], GIN[3], GIN[4], POUT[2], GOUT[4] );
smblock1 d35 (PIN[3], PIN[4], GIN[4], GIN[5], POUT[3], GOUT[5] );
smblock1 d36 (PIN[4], PIN[5], GIN[5], GIN[6], POUT[4], GOUT[6] );
smblock1 d37 (PIN[5], PIN[6], GIN[6], GIN[7], POUT[5], GOUT[7] );
smblock1 d38 (PIN[6], PIN[7], GIN[7], GIN[8], POUT[6], GOUT[8] );
smblock1 d39 (PIN[7], PIN[8], GIN[8], GIN[9], POUT[7], GOUT[9] );
smblock1 d310 (PIN[8], PIN[9], GIN[9], GIN[10], POUT[8], GOUT[10] );
smblock1 d311 (PIN[9], PIN[10], GIN[10], GIN[11], POUT[9], GOUT[11] );
smblock1 d312 (PIN[10], PIN[11], GIN[11], GIN[12], POUT[10], GOUT[12] );
smblock1 d313 (PIN[11], PIN[12], GIN[12], GIN[13], POUT[11], GOUT[13] );
smblock1 d314 (PIN[12], PIN[13], GIN[13], GIN[14], POUT[12], GOUT[14] );
smblock1 d315 (PIN[13], PIN[14], GIN[14], GIN[15], POUT[13], GOUT[15] );
smblock1 d316 (PIN[14], PIN[15], GIN[15], GIN[16], POUT[14], GOUT[16] );
smblock1 d317 (PIN[15], PIN[16], GIN[16], GIN[17], POUT[15], GOUT[17] );
smblock1 d318 (PIN[16], PIN[17], GIN[17], GIN[18], POUT[16], GOUT[18] );
smblock1 d319 (PIN[17], PIN[18], GIN[18], GIN[19], POUT[17], GOUT[19] );
smblock1 d320 (PIN[18], PIN[19], GIN[19], GIN[20], POUT[18], GOUT[20] );
smblock1 d321 (PIN[19], PIN[20], GIN[20], GIN[21], POUT[19], GOUT[21] );
smblock1 d322 (PIN[20], PIN[21], GIN[21], GIN[22], POUT[20], GOUT[22] );
smblock1 d323 (PIN[21], PIN[22], GIN[22], GIN[23], POUT[21], GOUT[23] );
smblock1 d324 (PIN[22], PIN[23], GIN[23], GIN[24], POUT[22], GOUT[24] );
smblock1 d325 (PIN[23], PIN[24], GIN[24], GIN[25], POUT[23], GOUT[25] );
smblock1 d326 (PIN[24], PIN[25], GIN[25], GIN[26], POUT[24], GOUT[26] );
smblock1 d327 (PIN[25], PIN[26], GIN[26], GIN[27], POUT[25], GOUT[27] );
smblock1 d328 (PIN[26], PIN[27], GIN[27], GIN[28], POUT[26], GOUT[28] );
smblock1 d329 (PIN[27], PIN[28], GIN[28], GIN[29], POUT[27], GOUT[29] );
smblock1 d330 (PIN[28], PIN[29], GIN[29], GIN[30], POUT[28], GOUT[30] );
smblock1 d331 (PIN[29], PIN[30], GIN[30], GIN[31], POUT[29], GOUT[31] );
smblock1 d332 (PIN[30], PIN[31], GIN[31], GIN[32], POUT[30], GOUT[32] );
smblock1 d333 (PIN[31], PIN[32], GIN[32], GIN[33], POUT[31], GOUT[33] );
smblock1 d334 (PIN[32], PIN[33], GIN[33], GIN[34], POUT[32], GOUT[34] );
smblock1 d335 (PIN[33], PIN[34], GIN[34], GIN[35], POUT[33], GOUT[35] );
smblock1 d336 (PIN[34], PIN[35], GIN[35], GIN[36], POUT[34], GOUT[36] );
smblock1 d337 (PIN[35], PIN[36], GIN[36], GIN[37], POUT[35], GOUT[37] );
smblock1 d338 (PIN[36], PIN[37], GIN[37], GIN[38], POUT[36], GOUT[38] );
smblock1 d339 (PIN[37], PIN[38], GIN[38], GIN[39], POUT[37], GOUT[39] );
smblock1 d340 (PIN[38], PIN[39], GIN[39], GIN[40], POUT[38], GOUT[40] );
smblock1 d341 (PIN[39], PIN[40], GIN[40], GIN[41], POUT[39], GOUT[41] );
smblock1 d342 (PIN[40], PIN[41], GIN[41], GIN[42], POUT[40], GOUT[42] );
smblock1 d343 (PIN[41], PIN[42], GIN[42], GIN[43], POUT[41], GOUT[43] );
smblock1 d344 (PIN[42], PIN[43], GIN[43], GIN[44], POUT[42], GOUT[44] );
smblock1 d345 (PIN[43], PIN[44], GIN[44], GIN[45], POUT[43], GOUT[45] );
smblock1 d346 (PIN[44], PIN[45], GIN[45], GIN[46], POUT[44], GOUT[46] );
smblock1 d347 (PIN[45], PIN[46], GIN[46], GIN[47], POUT[45], GOUT[47] );
smblock1 d348 (PIN[46], PIN[47], GIN[47], GIN[48], POUT[46], GOUT[48] );
smblock1 d349 (PIN[47], PIN[48], GIN[48], GIN[49], POUT[47], GOUT[49] );
smblock1 d350 (PIN[48], PIN[49], GIN[49], GIN[50], POUT[48], GOUT[50] );
smblock1 d351 (PIN[49], PIN[50], GIN[50], GIN[51], POUT[49], GOUT[51] );
smblock1 d352 (PIN[50], PIN[51], GIN[51], GIN[52], POUT[50], GOUT[52] );
smblock1 d353 (PIN[51], PIN[52], GIN[52], GIN[53], POUT[51], GOUT[53] );
smblock1 d354 (PIN[52], PIN[53], GIN[53], GIN[54], POUT[52], GOUT[54] );
smblock1 d355 (PIN[53], PIN[54], GIN[54], GIN[55], POUT[53], GOUT[55] );
smblock1 d356 (PIN[54], PIN[55], GIN[55], GIN[56], POUT[54], GOUT[56] );
smblock1 d357 (PIN[55], PIN[56], GIN[56], GIN[57], POUT[55], GOUT[57] );
smblock1 d358 (PIN[56], PIN[57], GIN[57], GIN[58], POUT[56], GOUT[58] );
smblock1 d359 (PIN[57], PIN[58], GIN[58], GIN[59], POUT[57], GOUT[59] );
smblock1 d360 (PIN[58], PIN[59], GIN[59], GIN[60], POUT[58], GOUT[60] );
smblock1 d361 (PIN[59], PIN[60], GIN[60], GIN[61], POUT[59], GOUT[61] );
smblock1 d362 (PIN[60], PIN[61], GIN[61], GIN[62], POUT[60], GOUT[62] );
smblock1 d363 (PIN[61], PIN[62], GIN[62], GIN[63], POUT[61], GOUT[63] );
endmodule
module smdblc_1_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
smblock2a d22 (PIN[0], GIN[0], GIN[2], GOUT[2] );
smblock2a d23 (PIN[1], GIN[1], GIN[3], GOUT[3] );
smblock2 d34 (PIN[0], PIN[2], GIN[2], GIN[4], POUT[0], GOUT[4] );
smblock2 d35 (PIN[1], PIN[3], GIN[3], GIN[5], POUT[1], GOUT[5] );
smblock2 d36 (PIN[2], PIN[4], GIN[4], GIN[6], POUT[2], GOUT[6] );
smblock2 d37 (PIN[3], PIN[5], GIN[5], GIN[7], POUT[3], GOUT[7] );
smblock2 d38 (PIN[4], PIN[6], GIN[6], GIN[8], POUT[4], GOUT[8] );
smblock2 d39 (PIN[5], PIN[7], GIN[7], GIN[9], POUT[5], GOUT[9] );
smblock2 d310 (PIN[6], PIN[8], GIN[8], GIN[10], POUT[6], GOUT[10] );
smblock2 d311 (PIN[7], PIN[9], GIN[9], GIN[11], POUT[7], GOUT[11] );
smblock2 d312 (PIN[8], PIN[10], GIN[10], GIN[12], POUT[8], GOUT[12] );
smblock2 d313 (PIN[9], PIN[11], GIN[11], GIN[13], POUT[9], GOUT[13] );
smblock2 d314 (PIN[10], PIN[12], GIN[12], GIN[14], POUT[10], GOUT[14] );
smblock2 d315 (PIN[11], PIN[13], GIN[13], GIN[15], POUT[11], GOUT[15] );
smblock2 d316 (PIN[12], PIN[14], GIN[14], GIN[16], POUT[12], GOUT[16] );
smblock2 d317 (PIN[13], PIN[15], GIN[15], GIN[17], POUT[13], GOUT[17] );
smblock2 d318 (PIN[14], PIN[16], GIN[16], GIN[18], POUT[14], GOUT[18] );
smblock2 d319 (PIN[15], PIN[17], GIN[17], GIN[19], POUT[15], GOUT[19] );
smblock2 d320 (PIN[16], PIN[18], GIN[18], GIN[20], POUT[16], GOUT[20] );
smblock2 d321 (PIN[17], PIN[19], GIN[19], GIN[21], POUT[17], GOUT[21] );
smblock2 d322 (PIN[18], PIN[20], GIN[20], GIN[22], POUT[18], GOUT[22] );
smblock2 d323 (PIN[19], PIN[21], GIN[21], GIN[23], POUT[19], GOUT[23] );
smblock2 d324 (PIN[20], PIN[22], GIN[22], GIN[24], POUT[20], GOUT[24] );
smblock2 d325 (PIN[21], PIN[23], GIN[23], GIN[25], POUT[21], GOUT[25] );
smblock2 d326 (PIN[22], PIN[24], GIN[24], GIN[26], POUT[22], GOUT[26] );
smblock2 d327 (PIN[23], PIN[25], GIN[25], GIN[27], POUT[23], GOUT[27] );
smblock2 d328 (PIN[24], PIN[26], GIN[26], GIN[28], POUT[24], GOUT[28] );
smblock2 d329 (PIN[25], PIN[27], GIN[27], GIN[29], POUT[25], GOUT[29] );
smblock2 d330 (PIN[26], PIN[28], GIN[28], GIN[30], POUT[26], GOUT[30] );
smblock2 d331 (PIN[27], PIN[29], GIN[29], GIN[31], POUT[27], GOUT[31] );
smblock2 d332 (PIN[28], PIN[30], GIN[30], GIN[32], POUT[28], GOUT[32] );
smblock2 d333 (PIN[29], PIN[31], GIN[31], GIN[33], POUT[29], GOUT[33] );
smblock2 d334 (PIN[30], PIN[32], GIN[32], GIN[34], POUT[30], GOUT[34] );
smblock2 d335 (PIN[31], PIN[33], GIN[33], GIN[35], POUT[31], GOUT[35] );
smblock2 d336 (PIN[32], PIN[34], GIN[34], GIN[36], POUT[32], GOUT[36] );
smblock2 d337 (PIN[33], PIN[35], GIN[35], GIN[37], POUT[33], GOUT[37] );
smblock2 d338 (PIN[34], PIN[36], GIN[36], GIN[38], POUT[34], GOUT[38] );
smblock2 d339 (PIN[35], PIN[37], GIN[37], GIN[39], POUT[35], GOUT[39] );
smblock2 d340 (PIN[36], PIN[38], GIN[38], GIN[40], POUT[36], GOUT[40] );
smblock2 d341 (PIN[37], PIN[39], GIN[39], GIN[41], POUT[37], GOUT[41] );
smblock2 d342 (PIN[38], PIN[40], GIN[40], GIN[42], POUT[38], GOUT[42] );
smblock2 d343 (PIN[39], PIN[41], GIN[41], GIN[43], POUT[39], GOUT[43] );
smblock2 d344 (PIN[40], PIN[42], GIN[42], GIN[44], POUT[40], GOUT[44] );
smblock2 d345 (PIN[41], PIN[43], GIN[43], GIN[45], POUT[41], GOUT[45] );
smblock2 d346 (PIN[42], PIN[44], GIN[44], GIN[46], POUT[42], GOUT[46] );
smblock2 d347 (PIN[43], PIN[45], GIN[45], GIN[47], POUT[43], GOUT[47] );
smblock2 d348 (PIN[44], PIN[46], GIN[46], GIN[48], POUT[44], GOUT[48] );
smblock2 d349 (PIN[45], PIN[47], GIN[47], GIN[49], POUT[45], GOUT[49] );
smblock2 d350 (PIN[46], PIN[48], GIN[48], GIN[50], POUT[46], GOUT[50] );
smblock2 d351 (PIN[47], PIN[49], GIN[49], GIN[51], POUT[47], GOUT[51] );
smblock2 d352 (PIN[48], PIN[50], GIN[50], GIN[52], POUT[48], GOUT[52] );
smblock2 d353 (PIN[49], PIN[51], GIN[51], GIN[53], POUT[49], GOUT[53] );
smblock2 d354 (PIN[50], PIN[52], GIN[52], GIN[54], POUT[50], GOUT[54] );
smblock2 d355 (PIN[51], PIN[53], GIN[53], GIN[55], POUT[51], GOUT[55] );
smblock2 d356 (PIN[52], PIN[54], GIN[54], GIN[56], POUT[52], GOUT[56] );
smblock2 d357 (PIN[53], PIN[55], GIN[55], GIN[57], POUT[53], GOUT[57] );
smblock2 d358 (PIN[54], PIN[56], GIN[56], GIN[58], POUT[54], GOUT[58] );
smblock2 d359 (PIN[55], PIN[57], GIN[57], GIN[59], POUT[55], GOUT[59] );
smblock2 d360 (PIN[56], PIN[58], GIN[58], GIN[60], POUT[56], GOUT[60] );
smblock2 d361 (PIN[57], PIN[59], GIN[59], GIN[61], POUT[57], GOUT[61] );
smblock2 d362 (PIN[58], PIN[60], GIN[60], GIN[62], POUT[58], GOUT[62] );
smblock2 d363 (PIN[59], PIN[61], GIN[61], GIN[63], POUT[59], GOUT[63] );
endmodule
module smdblc_2_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
sminvblock d12 (GIN[2], GOUT[2] );
sminvblock d13 (GIN[3], GOUT[3] );
smblock1a d24 (PIN[0], GIN[0], GIN[4], GOUT[4] );
smblock1a d25 (PIN[1], GIN[1], GIN[5], GOUT[5] );
smblock1a d26 (PIN[2], GIN[2], GIN[6], GOUT[6] );
smblock1a d27 (PIN[3], GIN[3], GIN[7], GOUT[7] );
smblock1 d38 (PIN[0], PIN[4], GIN[4], GIN[8], POUT[0], GOUT[8] );
smblock1 d39 (PIN[1], PIN[5], GIN[5], GIN[9], POUT[1], GOUT[9] );
smblock1 d310 (PIN[2], PIN[6], GIN[6], GIN[10], POUT[2], GOUT[10] );
smblock1 d311 (PIN[3], PIN[7], GIN[7], GIN[11], POUT[3], GOUT[11] );
smblock1 d312 (PIN[4], PIN[8], GIN[8], GIN[12], POUT[4], GOUT[12] );
smblock1 d313 (PIN[5], PIN[9], GIN[9], GIN[13], POUT[5], GOUT[13] );
smblock1 d314 (PIN[6], PIN[10], GIN[10], GIN[14], POUT[6], GOUT[14] );
smblock1 d315 (PIN[7], PIN[11], GIN[11], GIN[15], POUT[7], GOUT[15] );
smblock1 d316 (PIN[8], PIN[12], GIN[12], GIN[16], POUT[8], GOUT[16] );
smblock1 d317 (PIN[9], PIN[13], GIN[13], GIN[17], POUT[9], GOUT[17] );
smblock1 d318 (PIN[10], PIN[14], GIN[14], GIN[18], POUT[10], GOUT[18] );
smblock1 d319 (PIN[11], PIN[15], GIN[15], GIN[19], POUT[11], GOUT[19] );
smblock1 d320 (PIN[12], PIN[16], GIN[16], GIN[20], POUT[12], GOUT[20] );
smblock1 d321 (PIN[13], PIN[17], GIN[17], GIN[21], POUT[13], GOUT[21] );
smblock1 d322 (PIN[14], PIN[18], GIN[18], GIN[22], POUT[14], GOUT[22] );
smblock1 d323 (PIN[15], PIN[19], GIN[19], GIN[23], POUT[15], GOUT[23] );
smblock1 d324 (PIN[16], PIN[20], GIN[20], GIN[24], POUT[16], GOUT[24] );
smblock1 d325 (PIN[17], PIN[21], GIN[21], GIN[25], POUT[17], GOUT[25] );
smblock1 d326 (PIN[18], PIN[22], GIN[22], GIN[26], POUT[18], GOUT[26] );
smblock1 d327 (PIN[19], PIN[23], GIN[23], GIN[27], POUT[19], GOUT[27] );
smblock1 d328 (PIN[20], PIN[24], GIN[24], GIN[28], POUT[20], GOUT[28] );
smblock1 d329 (PIN[21], PIN[25], GIN[25], GIN[29], POUT[21], GOUT[29] );
smblock1 d330 (PIN[22], PIN[26], GIN[26], GIN[30], POUT[22], GOUT[30] );
smblock1 d331 (PIN[23], PIN[27], GIN[27], GIN[31], POUT[23], GOUT[31] );
smblock1 d332 (PIN[24], PIN[28], GIN[28], GIN[32], POUT[24], GOUT[32] );
smblock1 d333 (PIN[25], PIN[29], GIN[29], GIN[33], POUT[25], GOUT[33] );
smblock1 d334 (PIN[26], PIN[30], GIN[30], GIN[34], POUT[26], GOUT[34] );
smblock1 d335 (PIN[27], PIN[31], GIN[31], GIN[35], POUT[27], GOUT[35] );
smblock1 d336 (PIN[28], PIN[32], GIN[32], GIN[36], POUT[28], GOUT[36] );
smblock1 d337 (PIN[29], PIN[33], GIN[33], GIN[37], POUT[29], GOUT[37] );
smblock1 d338 (PIN[30], PIN[34], GIN[34], GIN[38], POUT[30], GOUT[38] );
smblock1 d339 (PIN[31], PIN[35], GIN[35], GIN[39], POUT[31], GOUT[39] );
smblock1 d340 (PIN[32], PIN[36], GIN[36], GIN[40], POUT[32], GOUT[40] );
smblock1 d341 (PIN[33], PIN[37], GIN[37], GIN[41], POUT[33], GOUT[41] );
smblock1 d342 (PIN[34], PIN[38], GIN[38], GIN[42], POUT[34], GOUT[42] );
smblock1 d343 (PIN[35], PIN[39], GIN[39], GIN[43], POUT[35], GOUT[43] );
smblock1 d344 (PIN[36], PIN[40], GIN[40], GIN[44], POUT[36], GOUT[44] );
smblock1 d345 (PIN[37], PIN[41], GIN[41], GIN[45], POUT[37], GOUT[45] );
smblock1 d346 (PIN[38], PIN[42], GIN[42], GIN[46], POUT[38], GOUT[46] );
smblock1 d347 (PIN[39], PIN[43], GIN[43], GIN[47], POUT[39], GOUT[47] );
smblock1 d348 (PIN[40], PIN[44], GIN[44], GIN[48], POUT[40], GOUT[48] );
smblock1 d349 (PIN[41], PIN[45], GIN[45], GIN[49], POUT[41], GOUT[49] );
smblock1 d350 (PIN[42], PIN[46], GIN[46], GIN[50], POUT[42], GOUT[50] );
smblock1 d351 (PIN[43], PIN[47], GIN[47], GIN[51], POUT[43], GOUT[51] );
smblock1 d352 (PIN[44], PIN[48], GIN[48], GIN[52], POUT[44], GOUT[52] );
smblock1 d353 (PIN[45], PIN[49], GIN[49], GIN[53], POUT[45], GOUT[53] );
smblock1 d354 (PIN[46], PIN[50], GIN[50], GIN[54], POUT[46], GOUT[54] );
smblock1 d355 (PIN[47], PIN[51], GIN[51], GIN[55], POUT[47], GOUT[55] );
smblock1 d356 (PIN[48], PIN[52], GIN[52], GIN[56], POUT[48], GOUT[56] );
smblock1 d357 (PIN[49], PIN[53], GIN[53], GIN[57], POUT[49], GOUT[57] );
smblock1 d358 (PIN[50], PIN[54], GIN[54], GIN[58], POUT[50], GOUT[58] );
smblock1 d359 (PIN[51], PIN[55], GIN[55], GIN[59], POUT[51], GOUT[59] );
smblock1 d360 (PIN[52], PIN[56], GIN[56], GIN[60], POUT[52], GOUT[60] );
smblock1 d361 (PIN[53], PIN[57], GIN[57], GIN[61], POUT[53], GOUT[61] );
smblock1 d362 (PIN[54], PIN[58], GIN[58], GIN[62], POUT[54], GOUT[62] );
smblock1 d363 (PIN[55], PIN[59], GIN[59], GIN[63], POUT[55], GOUT[63] );
endmodule
module smdblc_3_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
sminvblock d12 (GIN[2], GOUT[2] );
sminvblock d13 (GIN[3], GOUT[3] );
sminvblock d14 (GIN[4], GOUT[4] );
sminvblock d15 (GIN[5], GOUT[5] );
sminvblock d16 (GIN[6], GOUT[6] );
sminvblock d17 (GIN[7], GOUT[7] );
smblock2a d28 (PIN[0], GIN[0], GIN[8], GOUT[8] );
smblock2a d29 (PIN[1], GIN[1], GIN[9], GOUT[9] );
smblock2a d210 (PIN[2], GIN[2], GIN[10], GOUT[10] );
smblock2a d211 (PIN[3], GIN[3], GIN[11], GOUT[11] );
smblock2a d212 (PIN[4], GIN[4], GIN[12], GOUT[12] );
smblock2a d213 (PIN[5], GIN[5], GIN[13], GOUT[13] );
smblock2a d214 (PIN[6], GIN[6], GIN[14], GOUT[14] );
smblock2a d215 (PIN[7], GIN[7], GIN[15], GOUT[15] );
smblock2 d316 (PIN[0], PIN[8], GIN[8], GIN[16], POUT[0], GOUT[16] );
smblock2 d317 (PIN[1], PIN[9], GIN[9], GIN[17], POUT[1], GOUT[17] );
smblock2 d318 (PIN[2], PIN[10], GIN[10], GIN[18], POUT[2], GOUT[18] );
smblock2 d319 (PIN[3], PIN[11], GIN[11], GIN[19], POUT[3], GOUT[19] );
smblock2 d320 (PIN[4], PIN[12], GIN[12], GIN[20], POUT[4], GOUT[20] );
smblock2 d321 (PIN[5], PIN[13], GIN[13], GIN[21], POUT[5], GOUT[21] );
smblock2 d322 (PIN[6], PIN[14], GIN[14], GIN[22], POUT[6], GOUT[22] );
smblock2 d323 (PIN[7], PIN[15], GIN[15], GIN[23], POUT[7], GOUT[23] );
smblock2 d324 (PIN[8], PIN[16], GIN[16], GIN[24], POUT[8], GOUT[24] );
smblock2 d325 (PIN[9], PIN[17], GIN[17], GIN[25], POUT[9], GOUT[25] );
smblock2 d326 (PIN[10], PIN[18], GIN[18], GIN[26], POUT[10], GOUT[26] );
smblock2 d327 (PIN[11], PIN[19], GIN[19], GIN[27], POUT[11], GOUT[27] );
smblock2 d328 (PIN[12], PIN[20], GIN[20], GIN[28], POUT[12], GOUT[28] );
smblock2 d329 (PIN[13], PIN[21], GIN[21], GIN[29], POUT[13], GOUT[29] );
smblock2 d330 (PIN[14], PIN[22], GIN[22], GIN[30], POUT[14], GOUT[30] );
smblock2 d331 (PIN[15], PIN[23], GIN[23], GIN[31], POUT[15], GOUT[31] );
smblock2 d332 (PIN[16], PIN[24], GIN[24], GIN[32], POUT[16], GOUT[32] );
smblock2 d333 (PIN[17], PIN[25], GIN[25], GIN[33], POUT[17], GOUT[33] );
smblock2 d334 (PIN[18], PIN[26], GIN[26], GIN[34], POUT[18], GOUT[34] );
smblock2 d335 (PIN[19], PIN[27], GIN[27], GIN[35], POUT[19], GOUT[35] );
smblock2 d336 (PIN[20], PIN[28], GIN[28], GIN[36], POUT[20], GOUT[36] );
smblock2 d337 (PIN[21], PIN[29], GIN[29], GIN[37], POUT[21], GOUT[37] );
smblock2 d338 (PIN[22], PIN[30], GIN[30], GIN[38], POUT[22], GOUT[38] );
smblock2 d339 (PIN[23], PIN[31], GIN[31], GIN[39], POUT[23], GOUT[39] );
smblock2 d340 (PIN[24], PIN[32], GIN[32], GIN[40], POUT[24], GOUT[40] );
smblock2 d341 (PIN[25], PIN[33], GIN[33], GIN[41], POUT[25], GOUT[41] );
smblock2 d342 (PIN[26], PIN[34], GIN[34], GIN[42], POUT[26], GOUT[42] );
smblock2 d343 (PIN[27], PIN[35], GIN[35], GIN[43], POUT[27], GOUT[43] );
smblock2 d344 (PIN[28], PIN[36], GIN[36], GIN[44], POUT[28], GOUT[44] );
smblock2 d345 (PIN[29], PIN[37], GIN[37], GIN[45], POUT[29], GOUT[45] );
smblock2 d346 (PIN[30], PIN[38], GIN[38], GIN[46], POUT[30], GOUT[46] );
smblock2 d347 (PIN[31], PIN[39], GIN[39], GIN[47], POUT[31], GOUT[47] );
smblock2 d348 (PIN[32], PIN[40], GIN[40], GIN[48], POUT[32], GOUT[48] );
smblock2 d349 (PIN[33], PIN[41], GIN[41], GIN[49], POUT[33], GOUT[49] );
smblock2 d350 (PIN[34], PIN[42], GIN[42], GIN[50], POUT[34], GOUT[50] );
smblock2 d351 (PIN[35], PIN[43], GIN[43], GIN[51], POUT[35], GOUT[51] );
smblock2 d352 (PIN[36], PIN[44], GIN[44], GIN[52], POUT[36], GOUT[52] );
smblock2 d353 (PIN[37], PIN[45], GIN[45], GIN[53], POUT[37], GOUT[53] );
smblock2 d354 (PIN[38], PIN[46], GIN[46], GIN[54], POUT[38], GOUT[54] );
smblock2 d355 (PIN[39], PIN[47], GIN[47], GIN[55], POUT[39], GOUT[55] );
smblock2 d356 (PIN[40], PIN[48], GIN[48], GIN[56], POUT[40], GOUT[56] );
smblock2 d357 (PIN[41], PIN[49], GIN[49], GIN[57], POUT[41], GOUT[57] );
smblock2 d358 (PIN[42], PIN[50], GIN[50], GIN[58], POUT[42], GOUT[58] );
smblock2 d359 (PIN[43], PIN[51], GIN[51], GIN[59], POUT[43], GOUT[59] );
smblock2 d360 (PIN[44], PIN[52], GIN[52], GIN[60], POUT[44], GOUT[60] );
smblock2 d361 (PIN[45], PIN[53], GIN[53], GIN[61], POUT[45], GOUT[61] );
smblock2 d362 (PIN[46], PIN[54], GIN[54], GIN[62], POUT[46], GOUT[62] );
smblock2 d363 (PIN[47], PIN[55], GIN[55], GIN[63], POUT[47], GOUT[63] );
endmodule
module smdblc_4_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
sminvblock d12 (GIN[2], GOUT[2] );
sminvblock d13 (GIN[3], GOUT[3] );
sminvblock d14 (GIN[4], GOUT[4] );
sminvblock d15 (GIN[5], GOUT[5] );
sminvblock d16 (GIN[6], GOUT[6] );
sminvblock d17 (GIN[7], GOUT[7] );
sminvblock d18 (GIN[8], GOUT[8] );
sminvblock d19 (GIN[9], GOUT[9] );
sminvblock d110 (GIN[10], GOUT[10] );
sminvblock d111 (GIN[11], GOUT[11] );
sminvblock d112 (GIN[12], GOUT[12] );
sminvblock d113 (GIN[13], GOUT[13] );
sminvblock d114 (GIN[14], GOUT[14] );
sminvblock d115 (GIN[15], GOUT[15] );
smblock1a d216 (PIN[0], GIN[0], GIN[16], GOUT[16] );
smblock1a d217 (PIN[1], GIN[1], GIN[17], GOUT[17] );
smblock1a d218 (PIN[2], GIN[2], GIN[18], GOUT[18] );
smblock1a d219 (PIN[3], GIN[3], GIN[19], GOUT[19] );
smblock1a d220 (PIN[4], GIN[4], GIN[20], GOUT[20] );
smblock1a d221 (PIN[5], GIN[5], GIN[21], GOUT[21] );
smblock1a d222 (PIN[6], GIN[6], GIN[22], GOUT[22] );
smblock1a d223 (PIN[7], GIN[7], GIN[23], GOUT[23] );
smblock1a d224 (PIN[8], GIN[8], GIN[24], GOUT[24] );
smblock1a d225 (PIN[9], GIN[9], GIN[25], GOUT[25] );
smblock1a d226 (PIN[10], GIN[10], GIN[26], GOUT[26] );
smblock1a d227 (PIN[11], GIN[11], GIN[27], GOUT[27] );
smblock1a d228 (PIN[12], GIN[12], GIN[28], GOUT[28] );
smblock1a d229 (PIN[13], GIN[13], GIN[29], GOUT[29] );
smblock1a d230 (PIN[14], GIN[14], GIN[30], GOUT[30] );
smblock1a d231 (PIN[15], GIN[15], GIN[31], GOUT[31] );
smblock1 d332 (PIN[0], PIN[16], GIN[16], GIN[32], POUT[0], GOUT[32] );
smblock1 d333 (PIN[1], PIN[17], GIN[17], GIN[33], POUT[1], GOUT[33] );
smblock1 d334 (PIN[2], PIN[18], GIN[18], GIN[34], POUT[2], GOUT[34] );
smblock1 d335 (PIN[3], PIN[19], GIN[19], GIN[35], POUT[3], GOUT[35] );
smblock1 d336 (PIN[4], PIN[20], GIN[20], GIN[36], POUT[4], GOUT[36] );
smblock1 d337 (PIN[5], PIN[21], GIN[21], GIN[37], POUT[5], GOUT[37] );
smblock1 d338 (PIN[6], PIN[22], GIN[22], GIN[38], POUT[6], GOUT[38] );
smblock1 d339 (PIN[7], PIN[23], GIN[23], GIN[39], POUT[7], GOUT[39] );
smblock1 d340 (PIN[8], PIN[24], GIN[24], GIN[40], POUT[8], GOUT[40] );
smblock1 d341 (PIN[9], PIN[25], GIN[25], GIN[41], POUT[9], GOUT[41] );
smblock1 d342 (PIN[10], PIN[26], GIN[26], GIN[42], POUT[10], GOUT[42] );
smblock1 d343 (PIN[11], PIN[27], GIN[27], GIN[43], POUT[11], GOUT[43] );
smblock1 d344 (PIN[12], PIN[28], GIN[28], GIN[44], POUT[12], GOUT[44] );
smblock1 d345 (PIN[13], PIN[29], GIN[29], GIN[45], POUT[13], GOUT[45] );
smblock1 d346 (PIN[14], PIN[30], GIN[30], GIN[46], POUT[14], GOUT[46] );
smblock1 d347 (PIN[15], PIN[31], GIN[31], GIN[47], POUT[15], GOUT[47] );
smblock1 d348 (PIN[16], PIN[32], GIN[32], GIN[48], POUT[16], GOUT[48] );
smblock1 d349 (PIN[17], PIN[33], GIN[33], GIN[49], POUT[17], GOUT[49] );
smblock1 d350 (PIN[18], PIN[34], GIN[34], GIN[50], POUT[18], GOUT[50] );
smblock1 d351 (PIN[19], PIN[35], GIN[35], GIN[51], POUT[19], GOUT[51] );
smblock1 d352 (PIN[20], PIN[36], GIN[36], GIN[52], POUT[20], GOUT[52] );
smblock1 d353 (PIN[21], PIN[37], GIN[37], GIN[53], POUT[21], GOUT[53] );
smblock1 d354 (PIN[22], PIN[38], GIN[38], GIN[54], POUT[22], GOUT[54] );
smblock1 d355 (PIN[23], PIN[39], GIN[39], GIN[55], POUT[23], GOUT[55] );
smblock1 d356 (PIN[24], PIN[40], GIN[40], GIN[56], POUT[24], GOUT[56] );
smblock1 d357 (PIN[25], PIN[41], GIN[41], GIN[57], POUT[25], GOUT[57] );
smblock1 d358 (PIN[26], PIN[42], GIN[42], GIN[58], POUT[26], GOUT[58] );
smblock1 d359 (PIN[27], PIN[43], GIN[43], GIN[59], POUT[27], GOUT[59] );
smblock1 d360 (PIN[28], PIN[44], GIN[44], GIN[60], POUT[28], GOUT[60] );
smblock1 d361 (PIN[29], PIN[45], GIN[45], GIN[61], POUT[29], GOUT[61] );
smblock1 d362 (PIN[30], PIN[46], GIN[46], GIN[62], POUT[30], GOUT[62] );
smblock1 d363 (PIN[31], PIN[47], GIN[47], GIN[63], POUT[31], GOUT[63] );
endmodule
module smxorstage_128 ( A, B, PBIT, CARRY, SUM );
input [63:0] A;
input [63:0] B;
input PBIT;
input [63:0] CARRY;
output [63:0] SUM;
smxxor1 d20 (A[0], B[0], CARRY[0], SUM[0] );
smxxor1 d21 (A[1], B[1], CARRY[1], SUM[1] );
smxxor1 d22 (A[2], B[2], CARRY[2], SUM[2] );
smxxor1 d23 (A[3], B[3], CARRY[3], SUM[3] );
smxxor1 d24 (A[4], B[4], CARRY[4], SUM[4] );
smxxor1 d25 (A[5], B[5], CARRY[5], SUM[5] );
smxxor1 d26 (A[6], B[6], CARRY[6], SUM[6] );
smxxor1 d27 (A[7], B[7], CARRY[7], SUM[7] );
smxxor1 d28 (A[8], B[8], CARRY[8], SUM[8] );
smxxor1 d29 (A[9], B[9], CARRY[9], SUM[9] );
smxxor1 d210 (A[10], B[10], CARRY[10], SUM[10] );
smxxor1 d211 (A[11], B[11], CARRY[11], SUM[11] );
smxxor1 d212 (A[12], B[12], CARRY[12], SUM[12] );
smxxor1 d213 (A[13], B[13], CARRY[13], SUM[13] );
smxxor1 d214 (A[14], B[14], CARRY[14], SUM[14] );
smxxor1 d215 (A[15], B[15], CARRY[15], SUM[15] );
smxxor1 d216 (A[16], B[16], CARRY[16], SUM[16] );
smxxor1 d217 (A[17], B[17], CARRY[17], SUM[17] );
smxxor1 d218 (A[18], B[18], CARRY[18], SUM[18] );
smxxor1 d219 (A[19], B[19], CARRY[19], SUM[19] );
smxxor1 d220 (A[20], B[20], CARRY[20], SUM[20] );
smxxor1 d221 (A[21], B[21], CARRY[21], SUM[21] );
smxxor1 d222 (A[22], B[22], CARRY[22], SUM[22] );
smxxor1 d223 (A[23], B[23], CARRY[23], SUM[23] );
smxxor1 d224 (A[24], B[24], CARRY[24], SUM[24] );
smxxor1 d225 (A[25], B[25], CARRY[25], SUM[25] );
smxxor1 d226 (A[26], B[26], CARRY[26], SUM[26] );
smxxor1 d227 (A[27], B[27], CARRY[27], SUM[27] );
smxxor1 d228 (A[28], B[28], CARRY[28], SUM[28] );
smxxor1 d229 (A[29], B[29], CARRY[29], SUM[29] );
smxxor1 d230 (A[30], B[30], CARRY[30], SUM[30] );
smxxor1 d231 (A[31], B[31], CARRY[31], SUM[31] );
smxxor1 d232 (A[32], B[32], CARRY[32], SUM[32] );
smxxor1 d233 (A[33], B[33], CARRY[33], SUM[33] );
smxxor1 d234 (A[34], B[34], CARRY[34], SUM[34] );
smxxor1 d235 (A[35], B[35], CARRY[35], SUM[35] );
smxxor1 d236 (A[36], B[36], CARRY[36], SUM[36] );
smxxor1 d237 (A[37], B[37], CARRY[37], SUM[37] );
smxxor1 d238 (A[38], B[38], CARRY[38], SUM[38] );
smxxor1 d239 (A[39], B[39], CARRY[39], SUM[39] );
smxxor1 d240 (A[40], B[40], CARRY[40], SUM[40] );
smxxor1 d241 (A[41], B[41], CARRY[41], SUM[41] );
smxxor1 d242 (A[42], B[42], CARRY[42], SUM[42] );
smxxor1 d243 (A[43], B[43], CARRY[43], SUM[43] );
smxxor1 d244 (A[44], B[44], CARRY[44], SUM[44] );
smxxor1 d245 (A[45], B[45], CARRY[45], SUM[45] );
smxxor1 d246 (A[46], B[46], CARRY[46], SUM[46] );
smxxor1 d247 (A[47], B[47], CARRY[47], SUM[47] );
smxxor1 d248 (A[48], B[48], CARRY[48], SUM[48] );
smxxor1 d249 (A[49], B[49], CARRY[49], SUM[49] );
smxxor1 d250 (A[50], B[50], CARRY[50], SUM[50] );
smxxor1 d251 (A[51], B[51], CARRY[51], SUM[51] );
smxxor1 d252 (A[52], B[52], CARRY[52], SUM[52] );
smxxor1 d253 (A[53], B[53], CARRY[53], SUM[53] );
smxxor1 d254 (A[54], B[54], CARRY[54], SUM[54] );
smxxor1 d255 (A[55], B[55], CARRY[55], SUM[55] );
smxxor1 d256 (A[56], B[56], CARRY[56], SUM[56] );
smxxor1 d257 (A[57], B[57], CARRY[57], SUM[57] );
smxxor1 d258 (A[58], B[58], CARRY[58], SUM[58] );
smxxor1 d259 (A[59], B[59], CARRY[59], SUM[59] );
smxxor1 d260 (A[60], B[60], CARRY[60], SUM[60] );
smxxor1 d261 (A[61], B[61], CARRY[61], SUM[61] );
smxxor1 d262 (A[62], B[62], CARRY[62], SUM[62] );
smxxor1 d263 (A[63], B[63], CARRY[63], SUM[63] );
endmodule
module smdblc_5_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
sminvblock d12 (GIN[2], GOUT[2] );
sminvblock d13 (GIN[3], GOUT[3] );
sminvblock d14 (GIN[4], GOUT[4] );
sminvblock d15 (GIN[5], GOUT[5] );
sminvblock d16 (GIN[6], GOUT[6] );
sminvblock d17 (GIN[7], GOUT[7] );
sminvblock d18 (GIN[8], GOUT[8] );
sminvblock d19 (GIN[9], GOUT[9] );
sminvblock d110 (GIN[10], GOUT[10] );
sminvblock d111 (GIN[11], GOUT[11] );
sminvblock d112 (GIN[12], GOUT[12] );
sminvblock d113 (GIN[13], GOUT[13] );
sminvblock d114 (GIN[14], GOUT[14] );
sminvblock d115 (GIN[15], GOUT[15] );
sminvblock d116 (GIN[16], GOUT[16] );
sminvblock d117 (GIN[17], GOUT[17] );
sminvblock d118 (GIN[18], GOUT[18] );
sminvblock d119 (GIN[19], GOUT[19] );
sminvblock d120 (GIN[20], GOUT[20] );
sminvblock d121 (GIN[21], GOUT[21] );
sminvblock d122 (GIN[22], GOUT[22] );
sminvblock d123 (GIN[23], GOUT[23] );
sminvblock d124 (GIN[24], GOUT[24] );
sminvblock d125 (GIN[25], GOUT[25] );
sminvblock d126 (GIN[26], GOUT[26] );
sminvblock d127 (GIN[27], GOUT[27] );
sminvblock d128 (GIN[28], GOUT[28] );
sminvblock d129 (GIN[29], GOUT[29] );
sminvblock d130 (GIN[30], GOUT[30] );
sminvblock d131 (GIN[31], GOUT[31] );
smblock2a d232 (PIN[0], GIN[0], GIN[32], GOUT[32] );
smblock2a d233 (PIN[1], GIN[1], GIN[33], GOUT[33] );
smblock2a d234 (PIN[2], GIN[2], GIN[34], GOUT[34] );
smblock2a d235 (PIN[3], GIN[3], GIN[35], GOUT[35] );
smblock2a d236 (PIN[4], GIN[4], GIN[36], GOUT[36] );
smblock2a d237 (PIN[5], GIN[5], GIN[37], GOUT[37] );
smblock2a d238 (PIN[6], GIN[6], GIN[38], GOUT[38] );
smblock2a d239 (PIN[7], GIN[7], GIN[39], GOUT[39] );
smblock2a d240 (PIN[8], GIN[8], GIN[40], GOUT[40] );
smblock2a d241 (PIN[9], GIN[9], GIN[41], GOUT[41] );
smblock2a d242 (PIN[10], GIN[10], GIN[42], GOUT[42] );
smblock2a d243 (PIN[11], GIN[11], GIN[43], GOUT[43] );
smblock2a d244 (PIN[12], GIN[12], GIN[44], GOUT[44] );
smblock2a d245 (PIN[13], GIN[13], GIN[45], GOUT[45] );
smblock2a d246 (PIN[14], GIN[14], GIN[46], GOUT[46] );
smblock2a d247 (PIN[15], GIN[15], GIN[47], GOUT[47] );
smblock2a d248 (PIN[16], GIN[16], GIN[48], GOUT[48] );
smblock2a d249 (PIN[17], GIN[17], GIN[49], GOUT[49] );
smblock2a d250 (PIN[18], GIN[18], GIN[50], GOUT[50] );
smblock2a d251 (PIN[19], GIN[19], GIN[51], GOUT[51] );
smblock2a d252 (PIN[20], GIN[20], GIN[52], GOUT[52] );
smblock2a d253 (PIN[21], GIN[21], GIN[53], GOUT[53] );
smblock2a d254 (PIN[22], GIN[22], GIN[54], GOUT[54] );
smblock2a d255 (PIN[23], GIN[23], GIN[55], GOUT[55] );
smblock2a d256 (PIN[24], GIN[24], GIN[56], GOUT[56] );
smblock2a d257 (PIN[25], GIN[25], GIN[57], GOUT[57] );
smblock2a d258 (PIN[26], GIN[26], GIN[58], GOUT[58] );
smblock2a d259 (PIN[27], GIN[27], GIN[59], GOUT[59] );
smblock2a d260 (PIN[28], GIN[28], GIN[60], GOUT[60] );
smblock2a d261 (PIN[29], GIN[29], GIN[61], GOUT[61] );
smblock2a d262 (PIN[30], GIN[30], GIN[62], GOUT[62] );
smblock2a d263 (PIN[31], GIN[31], GIN[63], GOUT[63] );
endmodule
module smdblc_6_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [0:0] POUT;
output [63:0] GOUT;
assign GOUT[63:0] = GIN[63:0];
endmodule
module smboothcoder_34_34 ( OPA, OPB, SUMMAND );
input [33:0] OPA;
input [33:0] OPB;
output [628:0] SUMMAND;
wire [33:0] OPA_;
wire [67:0] INT_MULTIPLIER;
wire LOGIC_ONE, LOGIC_ZERO;
assign LOGIC_ONE = 1'b1;
assign LOGIC_ZERO = 1'b0;
smdecoder dDEC0 (.INA (LOGIC_ZERO), .INB (OPB[0]), .INC (OPB[1]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]) );
assign OPA_ = ~ OPA;
smpp_low dPPL0 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[0]) );
smr_gate dRGATE0 (.INA (LOGIC_ZERO), .INB (OPB[0]), .INC (OPB[1]), .PPBIT (SUMMAND[1]) );
smpp_middle dPPM0 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[2]) );
smpp_middle dPPM1 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[3]) );
smpp_middle dPPM2 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[6]) );
smpp_middle dPPM3 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[8]) );
smpp_middle dPPM4 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[12]) );
smpp_middle dPPM5 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[15]) );
smpp_middle dPPM6 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[20]) );
smpp_middle dPPM7 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[24]) );
smpp_middle dPPM8 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[30]) );
smpp_middle dPPM9 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[35]) );
smpp_middle dPPM10 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[42]) );
smpp_middle dPPM11 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[48]) );
smpp_middle dPPM12 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[56]) );
smpp_middle dPPM13 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[63]) );
smpp_middle dPPM14 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[72]) );
smpp_middle dPPM15 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[80]) );
smpp_middle dPPM16 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[90]) );
smpp_middle dPPM17 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[99]) );
smpp_middle dPPM18 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[110]) );
smpp_middle dPPM19 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[120]) );
smpp_middle dPPM20 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[132]) );
smpp_middle dPPM21 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[143]) );
smpp_middle dPPM22 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[156]) );
smpp_middle dPPM23 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[168]) );
smpp_middle dPPM24 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[182]) );
smpp_middle dPPM25 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[195]) );
smpp_middle dPPM26 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[210]) );
smpp_middle dPPM27 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[224]) );
smpp_middle dPPM28 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[240]) );
smpp_middle dPPM29 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[255]) );
smpp_middle dPPM30 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[272]) );
smpp_middle dPPM31 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[288]) );
smpp_middle dPPM32 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[306]) );
smpp_high dPPH0 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[323]) );
assign SUMMAND[324] = 1'b1;
smdecoder dDEC1 (.INA (OPB[1]), .INB (OPB[2]), .INC (OPB[3]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]) );
smpp_low dPPL1 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[4]) );
smr_gate dRGATE1 (.INA (OPB[1]), .INB (OPB[2]), .INC (OPB[3]), .PPBIT (SUMMAND[5]) );
smpp_middle dPPM33 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[7]) );
smpp_middle dPPM34 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[9]) );
smpp_middle dPPM35 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[13]) );
smpp_middle dPPM36 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[16]) );
smpp_middle dPPM37 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[21]) );
smpp_middle dPPM38 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[25]) );
smpp_middle dPPM39 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[31]) );
smpp_middle dPPM40 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[36]) );
smpp_middle dPPM41 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[43]) );
smpp_middle dPPM42 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[49]) );
smpp_middle dPPM43 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[57]) );
smpp_middle dPPM44 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[64]) );
smpp_middle dPPM45 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[73]) );
smpp_middle dPPM46 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[81]) );
smpp_middle dPPM47 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[91]) );
smpp_middle dPPM48 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[100]) );
smpp_middle dPPM49 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[111]) );
smpp_middle dPPM50 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[121]) );
smpp_middle dPPM51 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[133]) );
smpp_middle dPPM52 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[144]) );
smpp_middle dPPM53 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[157]) );
smpp_middle dPPM54 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[169]) );
smpp_middle dPPM55 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[183]) );
smpp_middle dPPM56 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[196]) );
smpp_middle dPPM57 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[211]) );
smpp_middle dPPM58 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[225]) );
smpp_middle dPPM59 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[241]) );
smpp_middle dPPM60 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[256]) );
smpp_middle dPPM61 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[273]) );
smpp_middle dPPM62 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[289]) );
smpp_middle dPPM63 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[307]) );
smpp_middle dPPM64 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[325]) );
smpp_middle dPPM65 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[341]) );
assign SUMMAND[342] = LOGIC_ONE;
smpp_high dPPH1 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[358]) );
smdecoder dDEC2 (.INA (OPB[3]), .INB (OPB[4]), .INC (OPB[5]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]) );
smpp_low dPPL2 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[10]) );
smr_gate dRGATE2 (.INA (OPB[3]), .INB (OPB[4]), .INC (OPB[5]), .PPBIT (SUMMAND[11]) );
smpp_middle dPPM66 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[14]) );
smpp_middle dPPM67 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[17]) );
smpp_middle dPPM68 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[22]) );
smpp_middle dPPM69 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[26]) );
smpp_middle dPPM70 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[32]) );
smpp_middle dPPM71 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[37]) );
smpp_middle dPPM72 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[44]) );
smpp_middle dPPM73 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[50]) );
smpp_middle dPPM74 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[58]) );
smpp_middle dPPM75 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[65]) );
smpp_middle dPPM76 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[74]) );
smpp_middle dPPM77 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[82]) );
smpp_middle dPPM78 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[92]) );
smpp_middle dPPM79 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[101]) );
smpp_middle dPPM80 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[112]) );
smpp_middle dPPM81 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[122]) );
smpp_middle dPPM82 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[134]) );
smpp_middle dPPM83 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[145]) );
smpp_middle dPPM84 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[158]) );
smpp_middle dPPM85 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[170]) );
smpp_middle dPPM86 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[184]) );
smpp_middle dPPM87 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[197]) );
smpp_middle dPPM88 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[212]) );
smpp_middle dPPM89 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[226]) );
smpp_middle dPPM90 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[242]) );
smpp_middle dPPM91 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[257]) );
smpp_middle dPPM92 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[274]) );
smpp_middle dPPM93 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[290]) );
smpp_middle dPPM94 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[308]) );
smpp_middle dPPM95 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[326]) );
smpp_middle dPPM96 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[343]) );
smpp_middle dPPM97 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[359]) );
smpp_middle dPPM98 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[374]) );
assign SUMMAND[375] = LOGIC_ONE;
smpp_high dPPH2 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[390]) );
smdecoder dDEC3 (.INA (OPB[5]), .INB (OPB[6]), .INC (OPB[7]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]) );
smpp_low dPPL3 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[18]) );
smr_gate dRGATE3 (.INA (OPB[5]), .INB (OPB[6]), .INC (OPB[7]), .PPBIT (SUMMAND[19]) );
smpp_middle dPPM99 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[23]) );
smpp_middle dPPM100 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[27]) );
smpp_middle dPPM101 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[33]) );
smpp_middle dPPM102 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[38]) );
smpp_middle dPPM103 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[45]) );
smpp_middle dPPM104 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[51]) );
smpp_middle dPPM105 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[59]) );
smpp_middle dPPM106 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[66]) );
smpp_middle dPPM107 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[75]) );
smpp_middle dPPM108 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[83]) );
smpp_middle dPPM109 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[93]) );
smpp_middle dPPM110 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[102]) );
smpp_middle dPPM111 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[113]) );
smpp_middle dPPM112 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[123]) );
smpp_middle dPPM113 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[135]) );
smpp_middle dPPM114 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[146]) );
smpp_middle dPPM115 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[159]) );
smpp_middle dPPM116 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[171]) );
smpp_middle dPPM117 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[185]) );
smpp_middle dPPM118 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[198]) );
smpp_middle dPPM119 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[213]) );
smpp_middle dPPM120 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[227]) );
smpp_middle dPPM121 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[243]) );
smpp_middle dPPM122 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[258]) );
smpp_middle dPPM123 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[275]) );
smpp_middle dPPM124 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[291]) );
smpp_middle dPPM125 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[309]) );
smpp_middle dPPM126 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[327]) );
smpp_middle dPPM127 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[344]) );
smpp_middle dPPM128 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[360]) );
smpp_middle dPPM129 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[376]) );
smpp_middle dPPM130 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[391]) );
smpp_middle dPPM131 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[405]) );
assign SUMMAND[406] = LOGIC_ONE;
smpp_high dPPH3 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[420]) );
smdecoder dDEC4 (.INA (OPB[7]), .INB (OPB[8]), .INC (OPB[9]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]) );
smpp_low dPPL4 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[28]) );
smr_gate dRGATE4 (.INA (OPB[7]), .INB (OPB[8]), .INC (OPB[9]), .PPBIT (SUMMAND[29]) );
smpp_middle dPPM132 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[34]) );
smpp_middle dPPM133 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[39]) );
smpp_middle dPPM134 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[46]) );
smpp_middle dPPM135 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[52]) );
smpp_middle dPPM136 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[60]) );
smpp_middle dPPM137 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[67]) );
smpp_middle dPPM138 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[76]) );
smpp_middle dPPM139 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[84]) );
smpp_middle dPPM140 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[94]) );
smpp_middle dPPM141 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[103]) );
smpp_middle dPPM142 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[114]) );
smpp_middle dPPM143 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[124]) );
smpp_middle dPPM144 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[136]) );
smpp_middle dPPM145 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[147]) );
smpp_middle dPPM146 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[160]) );
smpp_middle dPPM147 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[172]) );
smpp_middle dPPM148 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[186]) );
smpp_middle dPPM149 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[199]) );
smpp_middle dPPM150 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[214]) );
smpp_middle dPPM151 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[228]) );
smpp_middle dPPM152 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[244]) );
smpp_middle dPPM153 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[259]) );
smpp_middle dPPM154 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[276]) );
smpp_middle dPPM155 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[292]) );
smpp_middle dPPM156 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[310]) );
smpp_middle dPPM157 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[328]) );
smpp_middle dPPM158 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[345]) );
smpp_middle dPPM159 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[361]) );
smpp_middle dPPM160 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[377]) );
smpp_middle dPPM161 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[392]) );
smpp_middle dPPM162 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[407]) );
smpp_middle dPPM163 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[421]) );
smpp_middle dPPM164 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[434]) );
assign SUMMAND[435] = LOGIC_ONE;
smpp_high dPPH4 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[448]) );
smdecoder dDEC5 (.INA (OPB[9]), .INB (OPB[10]), .INC (OPB[11]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]) );
smpp_low dPPL5 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[40]) );
smr_gate dRGATE5 (.INA (OPB[9]), .INB (OPB[10]), .INC (OPB[11]), .PPBIT (SUMMAND[41]) );
smpp_middle dPPM165 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[47]) );
smpp_middle dPPM166 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[53]) );
smpp_middle dPPM167 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[61]) );
smpp_middle dPPM168 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[68]) );
smpp_middle dPPM169 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[77]) );
smpp_middle dPPM170 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[85]) );
smpp_middle dPPM171 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[95]) );
smpp_middle dPPM172 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[104]) );
smpp_middle dPPM173 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[115]) );
smpp_middle dPPM174 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[125]) );
smpp_middle dPPM175 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[137]) );
smpp_middle dPPM176 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[148]) );
smpp_middle dPPM177 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[161]) );
smpp_middle dPPM178 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[173]) );
smpp_middle dPPM179 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[187]) );
smpp_middle dPPM180 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[200]) );
smpp_middle dPPM181 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[215]) );
smpp_middle dPPM182 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[229]) );
smpp_middle dPPM183 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[245]) );
smpp_middle dPPM184 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[260]) );
smpp_middle dPPM185 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[277]) );
smpp_middle dPPM186 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[293]) );
smpp_middle dPPM187 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[311]) );
smpp_middle dPPM188 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[329]) );
smpp_middle dPPM189 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[346]) );
smpp_middle dPPM190 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[362]) );
smpp_middle dPPM191 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[378]) );
smpp_middle dPPM192 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[393]) );
smpp_middle dPPM193 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[408]) );
smpp_middle dPPM194 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[422]) );
smpp_middle dPPM195 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[436]) );
smpp_middle dPPM196 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[449]) );
smpp_middle dPPM197 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[461]) );
assign SUMMAND[462] = LOGIC_ONE;
smpp_high dPPH5 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[474]) );
smdecoder dDEC6 (.INA (OPB[11]), .INB (OPB[12]), .INC (OPB[13]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]) );
smpp_low dPPL6 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[54]) );
smr_gate dRGATE6 (.INA (OPB[11]), .INB (OPB[12]), .INC (OPB[13]), .PPBIT (SUMMAND[55]) );
smpp_middle dPPM198 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[62]) );
smpp_middle dPPM199 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[69]) );
smpp_middle dPPM200 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[78]) );
smpp_middle dPPM201 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[86]) );
smpp_middle dPPM202 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[96]) );
smpp_middle dPPM203 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[105]) );
smpp_middle dPPM204 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[116]) );
smpp_middle dPPM205 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[126]) );
smpp_middle dPPM206 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[138]) );
smpp_middle dPPM207 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[149]) );
smpp_middle dPPM208 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[162]) );
smpp_middle dPPM209 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[174]) );
smpp_middle dPPM210 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[188]) );
smpp_middle dPPM211 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[201]) );
smpp_middle dPPM212 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[216]) );
smpp_middle dPPM213 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[230]) );
smpp_middle dPPM214 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[246]) );
smpp_middle dPPM215 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[261]) );
smpp_middle dPPM216 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[278]) );
smpp_middle dPPM217 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[294]) );
smpp_middle dPPM218 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[312]) );
smpp_middle dPPM219 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[330]) );
smpp_middle dPPM220 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[347]) );
smpp_middle dPPM221 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[363]) );
smpp_middle dPPM222 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[379]) );
smpp_middle dPPM223 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[394]) );
smpp_middle dPPM224 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[409]) );
smpp_middle dPPM225 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[423]) );
smpp_middle dPPM226 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[437]) );
smpp_middle dPPM227 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[450]) );
smpp_middle dPPM228 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[463]) );
smpp_middle dPPM229 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[475]) );
smpp_middle dPPM230 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[486]) );
assign SUMMAND[487] = LOGIC_ONE;
smpp_high dPPH6 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[498]) );
smdecoder dDEC7 (.INA (OPB[13]), .INB (OPB[14]), .INC (OPB[15]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]) );
smpp_low dPPL7 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[70]) );
smr_gate dRGATE7 (.INA (OPB[13]), .INB (OPB[14]), .INC (OPB[15]), .PPBIT (SUMMAND[71]) );
smpp_middle dPPM231 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[79]) );
smpp_middle dPPM232 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[87]) );
smpp_middle dPPM233 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[97]) );
smpp_middle dPPM234 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[106]) );
smpp_middle dPPM235 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[117]) );
smpp_middle dPPM236 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[127]) );
smpp_middle dPPM237 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[139]) );
smpp_middle dPPM238 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[150]) );
smpp_middle dPPM239 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[163]) );
smpp_middle dPPM240 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[175]) );
smpp_middle dPPM241 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[189]) );
smpp_middle dPPM242 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[202]) );
smpp_middle dPPM243 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[217]) );
smpp_middle dPPM244 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[231]) );
smpp_middle dPPM245 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[247]) );
smpp_middle dPPM246 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[262]) );
smpp_middle dPPM247 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[279]) );
smpp_middle dPPM248 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[295]) );
smpp_middle dPPM249 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[313]) );
smpp_middle dPPM250 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[331]) );
smpp_middle dPPM251 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[348]) );
smpp_middle dPPM252 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[364]) );
smpp_middle dPPM253 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[380]) );
smpp_middle dPPM254 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[395]) );
smpp_middle dPPM255 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[410]) );
smpp_middle dPPM256 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[424]) );
smpp_middle dPPM257 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[438]) );
smpp_middle dPPM258 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[451]) );
smpp_middle dPPM259 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[464]) );
smpp_middle dPPM260 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[476]) );
smpp_middle dPPM261 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[488]) );
smpp_middle dPPM262 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[499]) );
smpp_middle dPPM263 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[509]) );
assign SUMMAND[510] = LOGIC_ONE;
smpp_high dPPH7 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[520]) );
smdecoder dDEC8 (.INA (OPB[15]), .INB (OPB[16]), .INC (OPB[17]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]) );
smpp_low dPPL8 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[88]) );
smr_gate dRGATE8 (.INA (OPB[15]), .INB (OPB[16]), .INC (OPB[17]), .PPBIT (SUMMAND[89]) );
smpp_middle dPPM264 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[98]) );
smpp_middle dPPM265 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[107]) );
smpp_middle dPPM266 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[118]) );
smpp_middle dPPM267 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[128]) );
smpp_middle dPPM268 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[140]) );
smpp_middle dPPM269 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[151]) );
smpp_middle dPPM270 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[164]) );
smpp_middle dPPM271 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[176]) );
smpp_middle dPPM272 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[190]) );
smpp_middle dPPM273 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[203]) );
smpp_middle dPPM274 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[218]) );
smpp_middle dPPM275 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[232]) );
smpp_middle dPPM276 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[248]) );
smpp_middle dPPM277 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[263]) );
smpp_middle dPPM278 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[280]) );
smpp_middle dPPM279 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[296]) );
smpp_middle dPPM280 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[314]) );
smpp_middle dPPM281 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[332]) );
smpp_middle dPPM282 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[349]) );
smpp_middle dPPM283 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[365]) );
smpp_middle dPPM284 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[381]) );
smpp_middle dPPM285 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[396]) );
smpp_middle dPPM286 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[411]) );
smpp_middle dPPM287 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[425]) );
smpp_middle dPPM288 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[439]) );
smpp_middle dPPM289 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[452]) );
smpp_middle dPPM290 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[465]) );
smpp_middle dPPM291 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[477]) );
smpp_middle dPPM292 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[489]) );
smpp_middle dPPM293 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[500]) );
smpp_middle dPPM294 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[511]) );
smpp_middle dPPM295 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[521]) );
smpp_middle dPPM296 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[530]) );
assign SUMMAND[531] = LOGIC_ONE;
smpp_high dPPH8 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[540]) );
smdecoder dDEC9 (.INA (OPB[17]), .INB (OPB[18]), .INC (OPB[19]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]) );
smpp_low dPPL9 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[108]) );
smr_gate dRGATE9 (.INA (OPB[17]), .INB (OPB[18]), .INC (OPB[19]), .PPBIT (SUMMAND[109]) );
smpp_middle dPPM297 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[119]) );
smpp_middle dPPM298 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[129]) );
smpp_middle dPPM299 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[141]) );
smpp_middle dPPM300 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[152]) );
smpp_middle dPPM301 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[165]) );
smpp_middle dPPM302 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[177]) );
smpp_middle dPPM303 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[191]) );
smpp_middle dPPM304 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[204]) );
smpp_middle dPPM305 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[219]) );
smpp_middle dPPM306 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[233]) );
smpp_middle dPPM307 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[249]) );
smpp_middle dPPM308 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[264]) );
smpp_middle dPPM309 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[281]) );
smpp_middle dPPM310 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[297]) );
smpp_middle dPPM311 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[315]) );
smpp_middle dPPM312 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[333]) );
smpp_middle dPPM313 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[350]) );
smpp_middle dPPM314 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[366]) );
smpp_middle dPPM315 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[382]) );
smpp_middle dPPM316 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[397]) );
smpp_middle dPPM317 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[412]) );
smpp_middle dPPM318 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[426]) );
smpp_middle dPPM319 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[440]) );
smpp_middle dPPM320 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[453]) );
smpp_middle dPPM321 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[466]) );
smpp_middle dPPM322 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[478]) );
smpp_middle dPPM323 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[490]) );
smpp_middle dPPM324 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[501]) );
smpp_middle dPPM325 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[512]) );
smpp_middle dPPM326 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[522]) );
smpp_middle dPPM327 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[532]) );
smpp_middle dPPM328 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[541]) );
smpp_middle dPPM329 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[549]) );
assign SUMMAND[550] = LOGIC_ONE;
smpp_high dPPH9 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[558]) );
smdecoder dDEC10 (.INA (OPB[19]), .INB (OPB[20]), .INC (OPB[21]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]) );
smpp_low dPPL10 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[130]) );
smr_gate dRGATE10 (.INA (OPB[19]), .INB (OPB[20]), .INC (OPB[21]), .PPBIT (SUMMAND[131]) );
smpp_middle dPPM330 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[142]) );
smpp_middle dPPM331 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[153]) );
smpp_middle dPPM332 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[166]) );
smpp_middle dPPM333 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[178]) );
smpp_middle dPPM334 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[192]) );
smpp_middle dPPM335 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[205]) );
smpp_middle dPPM336 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[220]) );
smpp_middle dPPM337 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[234]) );
smpp_middle dPPM338 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[250]) );
smpp_middle dPPM339 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[265]) );
smpp_middle dPPM340 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[282]) );
smpp_middle dPPM341 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[298]) );
smpp_middle dPPM342 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[316]) );
smpp_middle dPPM343 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[334]) );
smpp_middle dPPM344 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[351]) );
smpp_middle dPPM345 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[367]) );
smpp_middle dPPM346 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[383]) );
smpp_middle dPPM347 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[398]) );
smpp_middle dPPM348 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[413]) );
smpp_middle dPPM349 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[427]) );
smpp_middle dPPM350 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[441]) );
smpp_middle dPPM351 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[454]) );
smpp_middle dPPM352 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[467]) );
smpp_middle dPPM353 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[479]) );
smpp_middle dPPM354 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[491]) );
smpp_middle dPPM355 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[502]) );
smpp_middle dPPM356 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[513]) );
smpp_middle dPPM357 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[523]) );
smpp_middle dPPM358 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[533]) );
smpp_middle dPPM359 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[542]) );
smpp_middle dPPM360 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[551]) );
smpp_middle dPPM361 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[559]) );
smpp_middle dPPM362 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[566]) );
assign SUMMAND[567] = LOGIC_ONE;
smpp_high dPPH10 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[574]) );
smdecoder dDEC11 (.INA (OPB[21]), .INB (OPB[22]), .INC (OPB[23]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]) );
smpp_low dPPL11 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[154]) );
smr_gate dRGATE11 (.INA (OPB[21]), .INB (OPB[22]), .INC (OPB[23]), .PPBIT (SUMMAND[155]) );
smpp_middle dPPM363 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[167]) );
smpp_middle dPPM364 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[179]) );
smpp_middle dPPM365 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[193]) );
smpp_middle dPPM366 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[206]) );
smpp_middle dPPM367 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[221]) );
smpp_middle dPPM368 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[235]) );
smpp_middle dPPM369 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[251]) );
smpp_middle dPPM370 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[266]) );
smpp_middle dPPM371 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[283]) );
smpp_middle dPPM372 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[299]) );
smpp_middle dPPM373 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[317]) );
smpp_middle dPPM374 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[335]) );
smpp_middle dPPM375 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[352]) );
smpp_middle dPPM376 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[368]) );
smpp_middle dPPM377 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[384]) );
smpp_middle dPPM378 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[399]) );
smpp_middle dPPM379 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[414]) );
smpp_middle dPPM380 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[428]) );
smpp_middle dPPM381 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[442]) );
smpp_middle dPPM382 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[455]) );
smpp_middle dPPM383 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[468]) );
smpp_middle dPPM384 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[480]) );
smpp_middle dPPM385 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[492]) );
smpp_middle dPPM386 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[503]) );
smpp_middle dPPM387 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[514]) );
smpp_middle dPPM388 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[524]) );
smpp_middle dPPM389 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[534]) );
smpp_middle dPPM390 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[543]) );
smpp_middle dPPM391 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[552]) );
smpp_middle dPPM392 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[560]) );
smpp_middle dPPM393 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[568]) );
smpp_middle dPPM394 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[575]) );
smpp_middle dPPM395 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[581]) );
assign SUMMAND[582] = LOGIC_ONE;
smpp_high dPPH11 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[588]) );
smdecoder dDEC12 (.INA (OPB[23]), .INB (OPB[24]), .INC (OPB[25]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]) );
smpp_low dPPL12 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[180]) );
smr_gate dRGATE12 (.INA (OPB[23]), .INB (OPB[24]), .INC (OPB[25]), .PPBIT (SUMMAND[181]) );
smpp_middle dPPM396 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[194]) );
smpp_middle dPPM397 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[207]) );
smpp_middle dPPM398 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[222]) );
smpp_middle dPPM399 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[236]) );
smpp_middle dPPM400 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[252]) );
smpp_middle dPPM401 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[267]) );
smpp_middle dPPM402 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[284]) );
smpp_middle dPPM403 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[300]) );
smpp_middle dPPM404 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[318]) );
smpp_middle dPPM405 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[336]) );
smpp_middle dPPM406 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[353]) );
smpp_middle dPPM407 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[369]) );
smpp_middle dPPM408 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[385]) );
smpp_middle dPPM409 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[400]) );
smpp_middle dPPM410 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[415]) );
smpp_middle dPPM411 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[429]) );
smpp_middle dPPM412 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[443]) );
smpp_middle dPPM413 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[456]) );
smpp_middle dPPM414 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[469]) );
smpp_middle dPPM415 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[481]) );
smpp_middle dPPM416 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[493]) );
smpp_middle dPPM417 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[504]) );
smpp_middle dPPM418 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[515]) );
smpp_middle dPPM419 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[525]) );
smpp_middle dPPM420 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[535]) );
smpp_middle dPPM421 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[544]) );
smpp_middle dPPM422 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[553]) );
smpp_middle dPPM423 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[561]) );
smpp_middle dPPM424 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[569]) );
smpp_middle dPPM425 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[576]) );
smpp_middle dPPM426 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[583]) );
smpp_middle dPPM427 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[589]) );
smpp_middle dPPM428 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[594]) );
assign SUMMAND[595] = LOGIC_ONE;
smpp_high dPPH12 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[600]) );
smdecoder dDEC13 (.INA (OPB[25]), .INB (OPB[26]), .INC (OPB[27]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]) );
smpp_low dPPL13 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[208]) );
smr_gate dRGATE13 (.INA (OPB[25]), .INB (OPB[26]), .INC (OPB[27]), .PPBIT (SUMMAND[209]) );
smpp_middle dPPM429 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[223]) );
smpp_middle dPPM430 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[237]) );
smpp_middle dPPM431 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[253]) );
smpp_middle dPPM432 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[268]) );
smpp_middle dPPM433 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[285]) );
smpp_middle dPPM434 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[301]) );
smpp_middle dPPM435 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[319]) );
smpp_middle dPPM436 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[337]) );
smpp_middle dPPM437 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[354]) );
smpp_middle dPPM438 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[370]) );
smpp_middle dPPM439 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[386]) );
smpp_middle dPPM440 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[401]) );
smpp_middle dPPM441 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[416]) );
smpp_middle dPPM442 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[430]) );
smpp_middle dPPM443 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[444]) );
smpp_middle dPPM444 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[457]) );
smpp_middle dPPM445 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[470]) );
smpp_middle dPPM446 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[482]) );
smpp_middle dPPM447 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[494]) );
smpp_middle dPPM448 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[505]) );
smpp_middle dPPM449 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[516]) );
smpp_middle dPPM450 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[526]) );
smpp_middle dPPM451 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[536]) );
smpp_middle dPPM452 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[545]) );
smpp_middle dPPM453 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[554]) );
smpp_middle dPPM454 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[562]) );
smpp_middle dPPM455 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[570]) );
smpp_middle dPPM456 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[577]) );
smpp_middle dPPM457 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[584]) );
smpp_middle dPPM458 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[590]) );
smpp_middle dPPM459 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[596]) );
smpp_middle dPPM460 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[601]) );
smpp_middle dPPM461 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[605]) );
assign SUMMAND[606] = LOGIC_ONE;
smpp_high dPPH13 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[610]) );
smdecoder dDEC14 (.INA (OPB[27]), .INB (OPB[28]), .INC (OPB[29]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]) );
smpp_low dPPL14 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[238]) );
smr_gate dRGATE14 (.INA (OPB[27]), .INB (OPB[28]), .INC (OPB[29]), .PPBIT (SUMMAND[239]) );
smpp_middle dPPM462 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[254]) );
smpp_middle dPPM463 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[269]) );
smpp_middle dPPM464 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[286]) );
smpp_middle dPPM465 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[302]) );
smpp_middle dPPM466 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[320]) );
smpp_middle dPPM467 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[338]) );
smpp_middle dPPM468 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[355]) );
smpp_middle dPPM469 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[371]) );
smpp_middle dPPM470 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[387]) );
smpp_middle dPPM471 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[402]) );
smpp_middle dPPM472 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[417]) );
smpp_middle dPPM473 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[431]) );
smpp_middle dPPM474 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[445]) );
smpp_middle dPPM475 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[458]) );
smpp_middle dPPM476 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[471]) );
smpp_middle dPPM477 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[483]) );
smpp_middle dPPM478 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[495]) );
smpp_middle dPPM479 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[506]) );
smpp_middle dPPM480 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[517]) );
smpp_middle dPPM481 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[527]) );
smpp_middle dPPM482 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[537]) );
smpp_middle dPPM483 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[546]) );
smpp_middle dPPM484 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[555]) );
smpp_middle dPPM485 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[563]) );
smpp_middle dPPM486 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[571]) );
smpp_middle dPPM487 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[578]) );
smpp_middle dPPM488 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[585]) );
smpp_middle dPPM489 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[591]) );
smpp_middle dPPM490 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[597]) );
smpp_middle dPPM491 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[602]) );
smpp_middle dPPM492 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[607]) );
smpp_middle dPPM493 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[611]) );
smpp_middle dPPM494 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[614]) );
assign SUMMAND[615] = LOGIC_ONE;
smpp_high dPPH14 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[618]) );
smdecoder dDEC15 (.INA (OPB[29]), .INB (OPB[30]), .INC (OPB[31]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]) );
smpp_low dPPL15 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[270]) );
smr_gate dRGATE15 (.INA (OPB[29]), .INB (OPB[30]), .INC (OPB[31]), .PPBIT (SUMMAND[271]) );
smpp_middle dPPM495 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[287]) );
smpp_middle dPPM496 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[303]) );
smpp_middle dPPM497 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[321]) );
smpp_middle dPPM498 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[339]) );
smpp_middle dPPM499 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[356]) );
smpp_middle dPPM500 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[372]) );
smpp_middle dPPM501 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[388]) );
smpp_middle dPPM502 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[403]) );
smpp_middle dPPM503 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[418]) );
smpp_middle dPPM504 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[432]) );
smpp_middle dPPM505 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[446]) );
smpp_middle dPPM506 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[459]) );
smpp_middle dPPM507 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[472]) );
smpp_middle dPPM508 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[484]) );
smpp_middle dPPM509 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[496]) );
smpp_middle dPPM510 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[507]) );
smpp_middle dPPM511 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[518]) );
smpp_middle dPPM512 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[528]) );
smpp_middle dPPM513 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[538]) );
smpp_middle dPPM514 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[547]) );
smpp_middle dPPM515 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[556]) );
smpp_middle dPPM516 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[564]) );
smpp_middle dPPM517 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[572]) );
smpp_middle dPPM518 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[579]) );
smpp_middle dPPM519 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[586]) );
smpp_middle dPPM520 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[592]) );
smpp_middle dPPM521 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[598]) );
smpp_middle dPPM522 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[603]) );
smpp_middle dPPM523 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[608]) );
smpp_middle dPPM524 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[612]) );
smpp_middle dPPM525 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[616]) );
smpp_middle dPPM526 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[619]) );
smpp_middle dPPM527 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[621]) );
assign SUMMAND[622] = LOGIC_ONE;
smpp_high dPPH15 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[624]) );
smdecoder dDEC16 (.INA (OPB[31]), .INB (OPB[32]), .INC (OPB[33]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]) );
smpp_low dPPL16 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[304]) );
smr_gate dRGATE16 (.INA (OPB[31]), .INB (OPB[32]), .INC (OPB[33]), .PPBIT (SUMMAND[305]) );
smpp_middle dPPM528 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[322]) );
smpp_middle dPPM529 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[340]) );
smpp_middle dPPM530 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[357]) );
smpp_middle dPPM531 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[373]) );
smpp_middle dPPM532 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[389]) );
smpp_middle dPPM533 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[404]) );
smpp_middle dPPM534 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[419]) );
smpp_middle dPPM535 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[433]) );
smpp_middle dPPM536 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[447]) );
smpp_middle dPPM537 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[460]) );
smpp_middle dPPM538 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[473]) );
smpp_middle dPPM539 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[485]) );
smpp_middle dPPM540 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[497]) );
smpp_middle dPPM541 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[508]) );
smpp_middle dPPM542 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[519]) );
smpp_middle dPPM543 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[529]) );
smpp_middle dPPM544 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[539]) );
smpp_middle dPPM545 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[548]) );
smpp_middle dPPM546 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[557]) );
smpp_middle dPPM547 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[565]) );
smpp_middle dPPM548 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[573]) );
smpp_middle dPPM549 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[580]) );
smpp_middle dPPM550 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[587]) );
smpp_middle dPPM551 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[593]) );
smpp_middle dPPM552 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[599]) );
smpp_middle dPPM553 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[604]) );
smpp_middle dPPM554 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[609]) );
smpp_middle dPPM555 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[613]) );
smpp_middle dPPM556 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[617]) );
smpp_middle dPPM557 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[620]) );
smpp_middle dPPM558 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[623]) );
smpp_middle dPPM559 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[625]) );
smpp_middle dPPM560 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[626]) );
assign SUMMAND[627] = LOGIC_ONE;
smpp_high dPPH16 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[628]) );
endmodule
// Simple cells
module smpp_low ( ONEPOS, ONENEG, TWONEG, INA, INB, PPBIT );
input ONEPOS;
input ONENEG;
input TWONEG;
input INA;
input INB;
output PPBIT;
assign PPBIT = (ONEPOS & INA) | (ONENEG & INB) | TWONEG;
endmodule
module smpp_middle ( ONEPOS, ONENEG, TWOPOS, TWONEG, INA, INB, INC, IND, PPBIT );
input ONEPOS;
input ONENEG;
input TWOPOS;
input TWONEG;
input INA;
input INB;
input INC;
input IND;
output PPBIT;
assign PPBIT = ~ (( ~ (INA & TWOPOS)) & ( ~ (INB & TWONEG)) & ( ~ (INC & ONEPOS)) & ( ~ (IND & ONENEG)));
endmodule
module smpp_high ( ONEPOS, ONENEG, TWOPOS, TWONEG, INA, INB, PPBIT );
input ONEPOS;
input ONENEG;
input TWOPOS;
input TWONEG;
input INA;
input INB;
output PPBIT;
assign PPBIT = ~ ((INA & ONEPOS) | (INB & ONENEG) | (INA & TWOPOS) | (INB & TWONEG));
endmodule
module smr_gate ( INA, INB, INC, PPBIT );
input INA;
input INB;
input INC;
output PPBIT;
assign PPBIT = ( ~ (INA & INB)) & INC;
endmodule
module smdecoder ( INA, INB, INC, TWOPOS, TWONEG, ONEPOS, ONENEG );
input INA;
input INB;
input INC;
output TWOPOS;
output TWONEG;
output ONEPOS;
output ONENEG;
assign TWOPOS = ~ ( ~ (INA & INB & ( ~ INC)));
assign TWONEG = ~ ( ~ (( ~ INA) & ( ~ INB) & INC));
assign ONEPOS = (( ~ INA) & INB & ( ~ INC)) | (( ~ INC) & ( ~ INB) & INA);
assign ONENEG = (INA & ( ~ INB) & INC) | (INC & INB & ( ~ INA));
endmodule
module smfulladder ( DATA_A, DATA_B, DATA_C, SAVE, CARRY );
input DATA_A;
input DATA_B;
input DATA_C;
output SAVE;
output CARRY;
wire TMP;
assign TMP = DATA_A ^ DATA_B;
assign SAVE = TMP ^ DATA_C;
assign CARRY = ~ (( ~ (TMP & DATA_C)) & ( ~ (DATA_A & DATA_B)));
endmodule
module smhalfadder ( DATA_A, DATA_B, SAVE, CARRY );
input DATA_A;
input DATA_B;
output SAVE;
output CARRY;
assign SAVE = DATA_A ^ DATA_B;
assign CARRY = DATA_A & DATA_B;
endmodule
module smffa
(
input clk,
input en_d1,
input D,
output reg Q
);
always @ (posedge clk) begin
Q <= D;
end
endmodule
module smffb
(
input clk,
input en_d2,
input D,
output reg Q
);
always @ (posedge clk) begin
Q <= D;
end
endmodule
module sminvblock ( GIN, GOUT );
input GIN;
output GOUT;
assign GOUT = ~ GIN;
endmodule
module smxxor1 ( A, B, GIN, SUM );
input A;
input B;
input GIN;
output SUM;
assign SUM = ( ~ (A ^ B)) ^ GIN;
endmodule
module smblock0 ( A, B, POUT, GOUT );
input A;
input B;
output POUT;
output GOUT;
assign POUT = ~ (A | B);
assign GOUT = ~ (A & B);
endmodule
module smblock1 ( PIN1, PIN2, GIN1, GIN2, POUT, GOUT );
input PIN1;
input PIN2;
input GIN1;
input GIN2;
output POUT;
output GOUT;
assign POUT = ~ (PIN1 | PIN2);
assign GOUT = ~ (GIN2 & (PIN2 | GIN1));
endmodule
module smblock2 ( PIN1, PIN2, GIN1, GIN2, POUT, GOUT );
input PIN1;
input PIN2;
input GIN1;
input GIN2;
output POUT;
output GOUT;
assign POUT = ~ (PIN1 & PIN2);
assign GOUT = ~ (GIN2 | (PIN2 & GIN1));
endmodule
module smblock1a ( PIN2, GIN1, GIN2, GOUT );
input PIN2;
input GIN1;
input GIN2;
output GOUT;
assign GOUT = ~ (GIN2 & (PIN2 | GIN1));
endmodule
module smblock2a ( PIN2, GIN1, GIN2, GOUT );
input PIN2;
input GIN1;
input GIN2;
output GOUT;
assign GOUT = ~ (GIN2 | (PIN2 & GIN1));
endmodule
// Local Variables:
// compile-command: "vlint --brief --nowarn=MULTMF,MODLNM t_math_wallace_mul.v"
// End:
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2008 by Mahesh Kumashikar
module t_math_synmul_mul ( /*AUTOARG*/
// Outputs
product_d4,
// Inputs
clk, enable, negate, datA, datB
);
input clk;
input enable;
input negate;
input [31:0] datA;
input [31:0] datB;
// verilator lint_off UNOPTFLAT
output reg [64:0] product_d4;
reg [33:0] datA_d1r;
reg [33:0] datB_d1r;
always @ (posedge clk) begin
if (enable) begin
datA_d1r <= {2'b0,datA};
datB_d1r <= {2'b0,datB};
// The extra multiplier bits were for signed, for this
// test we've ripped that out
if (negate) $stop;
end
end
reg en_d1;
reg en_d2;
reg en_d3;
always @ (posedge clk) begin
en_d1 <= enable;
en_d2 <= en_d1;
en_d3 <= en_d2;
end
wire [63:0] prod_d3;
smmultiplier_34_34 mul (.OPA(datA_d1r),
.OPB(datB_d1r),
.RESULT(prod_d3),
/*AUTOINST*/
// Inputs
.clk (clk),
.en_d1 (en_d1),
.en_d2 (en_d2));
always @ (posedge clk) begin
if (en_d3) begin
product_d4 <= {1'b0,prod_d3};
end
end
endmodule
// The below was originally generated by the "Synthesizable Arithmetic Module Generator"
// at http://modgen.fysel.ntnu.no/~pihl/iwlas98/ then cleaned up by hand.
// Unfortunately the generator no longer appears available. Please contact
// us if you know otherwise.
module smmultiplier_34_34
(
input clk,
input en_d1,
input en_d2,
input [33:0] OPA,
input [33:0] OPB,
output [63:0] RESULT
);
wire [628:0] PPBIT;
wire [66:0] INT_CARRY;
wire [66:0] INT_SUM;
smboothcoder_34_34 db (.OPA(OPA[33:0]), .OPB(OPB[33:0]), .SUMMAND(PPBIT[628:0]) );
smwallace_34_34 dw (.SUMMAND(PPBIT[628:0]), .CARRY(INT_CARRY[66:1]), .SUM(INT_SUM[66:0]),
/*AUTOINST*/
// Inputs
.clk (clk),
.en_d1 (en_d1),
.en_d2 (en_d2));
assign INT_CARRY[0] = 1'b0;
smdblcadder_128_128 dd (.OPA(INT_SUM[63:0]), .OPB(INT_CARRY[63:0]), .CIN (1'b0), .SUM(RESULT));
endmodule
module smdblcadder_128_128 ( OPA, OPB, CIN, SUM );
input [63:0] OPA;
input [63:0] OPB;
input CIN;
output [63:0] SUM;
wire [63:0] INTPROP;
wire [63:0] INTGEN;
wire [0:0] PBIT;
wire [63:0] CARRY;
smprestage_128 dp (OPA[63:0], OPB[63:0], CIN, INTPROP, INTGEN );
smdblctree_128 dd (INTPROP[63:0], INTGEN[63:0], CARRY[63:0], PBIT );
smxorstage_128 dx (OPA[63:0], OPB[63:0], PBIT[0], CARRY[63:0], SUM );
endmodule
module smdblctree_128 ( PIN, GIN, GOUT, POUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] GOUT;
output [0:0] POUT;
wire [63:0] INTPROP_0;
wire [63:0] INTGEN_0;
wire [63:0] INTPROP_1;
wire [63:0] INTGEN_1;
wire [63:0] INTPROP_2;
wire [63:0] INTGEN_2;
wire [63:0] INTPROP_3;
wire [63:0] INTGEN_3;
wire [63:0] INTPROP_4;
wire [63:0] INTGEN_4;
wire [63:0] INTPROP_5;
wire [63:0] INTGEN_5;
smdblc_0_128 ddb0 (.PIN(PIN), .GIN(GIN), .POUT(INTPROP_0), .GOUT(INTGEN_0) );
smdblc_1_128 ddb1 (.PIN(INTPROP_0), .GIN(INTGEN_0), .POUT(INTPROP_1), .GOUT(INTGEN_1) );
smdblc_2_128 ddb2 (.PIN(INTPROP_1), .GIN(INTGEN_1), .POUT(INTPROP_2), .GOUT(INTGEN_2) );
smdblc_3_128 ddb3 (.PIN(INTPROP_2), .GIN(INTGEN_2), .POUT(INTPROP_3), .GOUT(INTGEN_3) );
smdblc_4_128 ddb4 (.PIN(INTPROP_3), .GIN(INTGEN_3), .POUT(INTPROP_4), .GOUT(INTGEN_4) );
smdblc_5_128 ddb5 (.PIN(INTPROP_4), .GIN(INTGEN_4), .POUT(INTPROP_5), .GOUT(INTGEN_5) );
smdblc_6_128 ddb6 (.PIN(INTPROP_5), .GIN(INTGEN_5), .POUT(POUT), .GOUT(GOUT) );
endmodule
module smwallace_34_34
(
input clk,
input en_d1,
input en_d2,
input [628:0] SUMMAND,
output [65:0] CARRY,
output [66:0] SUM
);
wire [628:0] LATCHED_PP;
wire [551:0] INT_CARRY;
wire [687:0] INT_SUM;
smffa dla0 (.D(SUMMAND[0]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[0]) );
smffa dla1 (.D(SUMMAND[1]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[1]) );
smhalfadder dha0 (.DATA_A (LATCHED_PP[0]), .DATA_B (LATCHED_PP[1]), .SAVE (INT_SUM[0]), .CARRY (INT_CARRY[0]) );
smffb dla2 (.D(INT_SUM[0]), .clk(clk), .en_d2(en_d2), .Q(SUM[0]) );
smffb dla3 (.D(INT_CARRY[0]), .clk(clk), .en_d2(en_d2), .Q(CARRY[0]) );
smffa dla4 (.D(SUMMAND[2]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[2]) );
assign INT_SUM[1] = LATCHED_PP[2];
assign CARRY[1] = 1'b0;
smffb dla5 (.D(INT_SUM[1]), .clk(clk), .en_d2(en_d2), .Q(SUM[1]) );
smffa dla6 (.D(SUMMAND[3]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[3]) );
smffa dla7 (.D(SUMMAND[4]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[4]) );
smffa dla8 (.D(SUMMAND[5]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[5]) );
smfulladder dfa0 (.DATA_A (LATCHED_PP[3]), .DATA_B (LATCHED_PP[4]), .DATA_C (LATCHED_PP[5]), .SAVE (INT_SUM[2]), .CARRY (INT_CARRY[1]) );
smffb dla9 (.D(INT_SUM[2]), .clk(clk), .en_d2(en_d2), .Q(SUM[2]) );
smffb dla10 (.D(INT_CARRY[1]), .clk(clk), .en_d2(en_d2), .Q(CARRY[2]) );
smffa dla11 (.D(SUMMAND[6]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[6]) );
smffa dla12 (.D(SUMMAND[7]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[7]) );
smhalfadder dha1 (.DATA_A (LATCHED_PP[6]), .DATA_B (LATCHED_PP[7]), .SAVE (INT_SUM[3]), .CARRY (INT_CARRY[2]) );
smffb dla13 (.D(INT_SUM[3]), .clk(clk), .en_d2(en_d2), .Q(SUM[3]) );
smffb dla14 (.D(INT_CARRY[2]), .clk(clk), .en_d2(en_d2), .Q(CARRY[3]) );
smffa dla15 (.D(SUMMAND[8]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[8]) );
smffa dla16 (.D(SUMMAND[9]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[9]) );
smffa dla17 (.D(SUMMAND[10]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[10]) );
smfulladder dfa1 (.DATA_A (LATCHED_PP[8]), .DATA_B (LATCHED_PP[9]), .DATA_C (LATCHED_PP[10]), .SAVE (INT_SUM[4]), .CARRY (INT_CARRY[4]) );
smffa dla18 (.D(SUMMAND[11]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[11]) );
assign INT_SUM[5] = LATCHED_PP[11];
smhalfadder dha2 (.DATA_A (INT_SUM[4]), .DATA_B (INT_SUM[5]), .SAVE (INT_SUM[6]), .CARRY (INT_CARRY[3]) );
smffb dla19 (.D(INT_SUM[6]), .clk(clk), .en_d2(en_d2), .Q(SUM[4]) );
smffb dla20 (.D(INT_CARRY[3]), .clk(clk), .en_d2(en_d2), .Q(CARRY[4]) );
smffa dla21 (.D(SUMMAND[12]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[12]) );
smffa dla22 (.D(SUMMAND[13]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[13]) );
smffa dla23 (.D(SUMMAND[14]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[14]) );
smfulladder dfa2 (.DATA_A (LATCHED_PP[12]), .DATA_B (LATCHED_PP[13]), .DATA_C (LATCHED_PP[14]), .SAVE (INT_SUM[7]), .CARRY (INT_CARRY[6]) );
smhalfadder dha3 (.DATA_A (INT_SUM[7]), .DATA_B (INT_CARRY[4]), .SAVE (INT_SUM[8]), .CARRY (INT_CARRY[5]) );
smffb dla24 (.D(INT_SUM[8]), .clk(clk), .en_d2(en_d2), .Q(SUM[5]) );
smffb dla25 (.D(INT_CARRY[5]), .clk(clk), .en_d2(en_d2), .Q(CARRY[5]) );
smffa dla26 (.D(SUMMAND[15]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[15]) );
smffa dla27 (.D(SUMMAND[16]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[16]) );
smffa dla28 (.D(SUMMAND[17]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[17]) );
smfulladder dfa3 (.DATA_A (LATCHED_PP[15]), .DATA_B (LATCHED_PP[16]), .DATA_C (LATCHED_PP[17]), .SAVE (INT_SUM[9]), .CARRY (INT_CARRY[8]) );
smffa dla29 (.D(SUMMAND[18]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[18]) );
smffa dla30 (.D(SUMMAND[19]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[19]) );
smhalfadder dha4 (.DATA_A (LATCHED_PP[18]), .DATA_B (LATCHED_PP[19]), .SAVE (INT_SUM[10]), .CARRY (INT_CARRY[9]) );
smfulladder dfa4 (.DATA_A (INT_SUM[9]), .DATA_B (INT_SUM[10]), .DATA_C (INT_CARRY[6]), .SAVE (INT_SUM[11]), .CARRY (INT_CARRY[7]) );
smffb dla31 (.D(INT_SUM[11]), .clk(clk), .en_d2(en_d2), .Q(SUM[6]) );
smffb dla32 (.D(INT_CARRY[7]), .clk(clk), .en_d2(en_d2), .Q(CARRY[6]) );
smffa dla33 (.D(SUMMAND[20]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[20]) );
smffa dla34 (.D(SUMMAND[21]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[21]) );
smffa dla35 (.D(SUMMAND[22]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[22]) );
smfulladder dfa5 (.DATA_A (LATCHED_PP[20]), .DATA_B (LATCHED_PP[21]), .DATA_C (LATCHED_PP[22]), .SAVE (INT_SUM[12]), .CARRY (INT_CARRY[11]) );
smffa dla36 (.D(SUMMAND[23]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[23]) );
assign INT_SUM[13] = LATCHED_PP[23];
smfulladder dfa6 (.DATA_A (INT_SUM[12]), .DATA_B (INT_SUM[13]), .DATA_C (INT_CARRY[8]), .SAVE (INT_SUM[14]), .CARRY (INT_CARRY[12]) );
assign INT_SUM[15] = INT_CARRY[9];
smhalfadder dha5 (.DATA_A (INT_SUM[14]), .DATA_B (INT_SUM[15]), .SAVE (INT_SUM[16]), .CARRY (INT_CARRY[10]) );
smffb dla37 (.D(INT_SUM[16]), .clk(clk), .en_d2(en_d2), .Q(SUM[7]) );
smffb dla38 (.D(INT_CARRY[10]), .clk(clk), .en_d2(en_d2), .Q(CARRY[7]) );
smffa dla39 (.D(SUMMAND[24]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[24]) );
smffa dla40 (.D(SUMMAND[25]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[25]) );
smffa dla41 (.D(SUMMAND[26]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[26]) );
smfulladder dfa7 (.DATA_A (LATCHED_PP[24]), .DATA_B (LATCHED_PP[25]), .DATA_C (LATCHED_PP[26]), .SAVE (INT_SUM[17]), .CARRY (INT_CARRY[14]) );
smffa dla42 (.D(SUMMAND[27]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[27]) );
smffa dla43 (.D(SUMMAND[28]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[28]) );
smffa dla44 (.D(SUMMAND[29]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[29]) );
smfulladder dfa8 (.DATA_A (LATCHED_PP[27]), .DATA_B (LATCHED_PP[28]), .DATA_C (LATCHED_PP[29]), .SAVE (INT_SUM[18]), .CARRY (INT_CARRY[15]) );
smfulladder dfa9 (.DATA_A (INT_SUM[17]), .DATA_B (INT_SUM[18]), .DATA_C (INT_CARRY[11]), .SAVE (INT_SUM[19]), .CARRY (INT_CARRY[16]) );
smhalfadder dha6 (.DATA_A (INT_SUM[19]), .DATA_B (INT_CARRY[12]), .SAVE (INT_SUM[20]), .CARRY (INT_CARRY[13]) );
smffb dla45 (.D(INT_SUM[20]), .clk(clk), .en_d2(en_d2), .Q(SUM[8]) );
smffb dla46 (.D(INT_CARRY[13]), .clk(clk), .en_d2(en_d2), .Q(CARRY[8]) );
smffa dla47 (.D(SUMMAND[30]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[30]) );
smffa dla48 (.D(SUMMAND[31]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[31]) );
smffa dla49 (.D(SUMMAND[32]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[32]) );
smfulladder dfa10 (.DATA_A (LATCHED_PP[30]), .DATA_B (LATCHED_PP[31]), .DATA_C (LATCHED_PP[32]), .SAVE (INT_SUM[21]), .CARRY (INT_CARRY[18]) );
smffa dla50 (.D(SUMMAND[33]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[33]) );
smffa dla51 (.D(SUMMAND[34]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[34]) );
smhalfadder dha7 (.DATA_A (LATCHED_PP[33]), .DATA_B (LATCHED_PP[34]), .SAVE (INT_SUM[22]), .CARRY (INT_CARRY[19]) );
smfulladder dfa11 (.DATA_A (INT_SUM[21]), .DATA_B (INT_SUM[22]), .DATA_C (INT_CARRY[14]), .SAVE (INT_SUM[23]), .CARRY (INT_CARRY[20]) );
assign INT_SUM[24] = INT_CARRY[15];
smfulladder dfa12 (.DATA_A (INT_SUM[23]), .DATA_B (INT_SUM[24]), .DATA_C (INT_CARRY[16]), .SAVE (INT_SUM[25]), .CARRY (INT_CARRY[17]) );
smffb dla52 (.D(INT_SUM[25]), .clk(clk), .en_d2(en_d2), .Q(SUM[9]) );
smffb dla53 (.D(INT_CARRY[17]), .clk(clk), .en_d2(en_d2), .Q(CARRY[9]) );
smffa dla54 (.D(SUMMAND[35]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[35]) );
smffa dla55 (.D(SUMMAND[36]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[36]) );
smffa dla56 (.D(SUMMAND[37]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[37]) );
smfulladder dfa13 (.DATA_A (LATCHED_PP[35]), .DATA_B (LATCHED_PP[36]), .DATA_C (LATCHED_PP[37]), .SAVE (INT_SUM[26]), .CARRY (INT_CARRY[22]) );
smffa dla57 (.D(SUMMAND[38]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[38]) );
smffa dla58 (.D(SUMMAND[39]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[39]) );
smffa dla59 (.D(SUMMAND[40]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[40]) );
smfulladder dfa14 (.DATA_A (LATCHED_PP[38]), .DATA_B (LATCHED_PP[39]), .DATA_C (LATCHED_PP[40]), .SAVE (INT_SUM[27]), .CARRY (INT_CARRY[23]) );
smffa dla60 (.D(SUMMAND[41]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[41]) );
assign INT_SUM[28] = LATCHED_PP[41];
smfulladder dfa15 (.DATA_A (INT_SUM[26]), .DATA_B (INT_SUM[27]), .DATA_C (INT_SUM[28]), .SAVE (INT_SUM[29]), .CARRY (INT_CARRY[24]) );
smhalfadder dha8 (.DATA_A (INT_CARRY[18]), .DATA_B (INT_CARRY[19]), .SAVE (INT_SUM[30]), .CARRY (INT_CARRY[25]) );
smfulladder dfa16 (.DATA_A (INT_SUM[29]), .DATA_B (INT_SUM[30]), .DATA_C (INT_CARRY[20]), .SAVE (INT_SUM[31]), .CARRY (INT_CARRY[21]) );
smffb dla61 (.D(INT_SUM[31]), .clk(clk), .en_d2(en_d2), .Q(SUM[10]) );
smffb dla62 (.D(INT_CARRY[21]), .clk(clk), .en_d2(en_d2), .Q(CARRY[10]) );
smffa dla63 (.D(SUMMAND[42]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[42]) );
smffa dla64 (.D(SUMMAND[43]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[43]) );
smffa dla65 (.D(SUMMAND[44]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[44]) );
smfulladder dfa17 (.DATA_A (LATCHED_PP[42]), .DATA_B (LATCHED_PP[43]), .DATA_C (LATCHED_PP[44]), .SAVE (INT_SUM[32]), .CARRY (INT_CARRY[27]) );
smffa dla66 (.D(SUMMAND[45]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[45]) );
smffa dla67 (.D(SUMMAND[46]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[46]) );
smffa dla68 (.D(SUMMAND[47]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[47]) );
smfulladder dfa18 (.DATA_A (LATCHED_PP[45]), .DATA_B (LATCHED_PP[46]), .DATA_C (LATCHED_PP[47]), .SAVE (INT_SUM[33]), .CARRY (INT_CARRY[28]) );
smfulladder dfa19 (.DATA_A (INT_SUM[32]), .DATA_B (INT_SUM[33]), .DATA_C (INT_CARRY[22]), .SAVE (INT_SUM[34]), .CARRY (INT_CARRY[29]) );
assign INT_SUM[35] = INT_CARRY[23];
smfulladder dfa20 (.DATA_A (INT_SUM[34]), .DATA_B (INT_SUM[35]), .DATA_C (INT_CARRY[24]), .SAVE (INT_SUM[36]), .CARRY (INT_CARRY[30]) );
assign INT_SUM[37] = INT_CARRY[25];
smhalfadder dha9 (.DATA_A (INT_SUM[36]), .DATA_B (INT_SUM[37]), .SAVE (INT_SUM[38]), .CARRY (INT_CARRY[26]) );
smffb dla69 (.D(INT_SUM[38]), .clk(clk), .en_d2(en_d2), .Q(SUM[11]) );
smffb dla70 (.D(INT_CARRY[26]), .clk(clk), .en_d2(en_d2), .Q(CARRY[11]) );
smffa dla71 (.D(SUMMAND[48]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[48]) );
smffa dla72 (.D(SUMMAND[49]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[49]) );
smffa dla73 (.D(SUMMAND[50]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[50]) );
smfulladder dfa21 (.DATA_A (LATCHED_PP[48]), .DATA_B (LATCHED_PP[49]), .DATA_C (LATCHED_PP[50]), .SAVE (INT_SUM[39]), .CARRY (INT_CARRY[32]) );
smffa dla74 (.D(SUMMAND[51]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[51]) );
smffa dla75 (.D(SUMMAND[52]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[52]) );
smffa dla76 (.D(SUMMAND[53]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[53]) );
smfulladder dfa22 (.DATA_A (LATCHED_PP[51]), .DATA_B (LATCHED_PP[52]), .DATA_C (LATCHED_PP[53]), .SAVE (INT_SUM[40]), .CARRY (INT_CARRY[33]) );
smffa dla77 (.D(SUMMAND[54]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[54]) );
assign INT_SUM[41] = LATCHED_PP[54];
smffa dla78 (.D(SUMMAND[55]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[55]) );
assign INT_SUM[42] = LATCHED_PP[55];
smfulladder dfa23 (.DATA_A (INT_SUM[39]), .DATA_B (INT_SUM[40]), .DATA_C (INT_SUM[41]), .SAVE (INT_SUM[43]), .CARRY (INT_CARRY[34]) );
smfulladder dfa24 (.DATA_A (INT_SUM[42]), .DATA_B (INT_CARRY[27]), .DATA_C (INT_CARRY[28]), .SAVE (INT_SUM[44]), .CARRY (INT_CARRY[35]) );
smfulladder dfa25 (.DATA_A (INT_SUM[43]), .DATA_B (INT_SUM[44]), .DATA_C (INT_CARRY[29]), .SAVE (INT_SUM[45]), .CARRY (INT_CARRY[36]) );
smhalfadder dha10 (.DATA_A (INT_SUM[45]), .DATA_B (INT_CARRY[30]), .SAVE (INT_SUM[46]), .CARRY (INT_CARRY[31]) );
smffb dla79 (.D(INT_SUM[46]), .clk(clk), .en_d2(en_d2), .Q(SUM[12]) );
smffb dla80 (.D(INT_CARRY[31]), .clk(clk), .en_d2(en_d2), .Q(CARRY[12]) );
smffa dla81 (.D(SUMMAND[56]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[56]) );
smffa dla82 (.D(SUMMAND[57]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[57]) );
smffa dla83 (.D(SUMMAND[58]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[58]) );
smfulladder dfa26 (.DATA_A (LATCHED_PP[56]), .DATA_B (LATCHED_PP[57]), .DATA_C (LATCHED_PP[58]), .SAVE (INT_SUM[47]), .CARRY (INT_CARRY[38]) );
smffa dla84 (.D(SUMMAND[59]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[59]) );
smffa dla85 (.D(SUMMAND[60]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[60]) );
smffa dla86 (.D(SUMMAND[61]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[61]) );
smfulladder dfa27 (.DATA_A (LATCHED_PP[59]), .DATA_B (LATCHED_PP[60]), .DATA_C (LATCHED_PP[61]), .SAVE (INT_SUM[48]), .CARRY (INT_CARRY[39]) );
smffa dla87 (.D(SUMMAND[62]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[62]) );
assign INT_SUM[49] = LATCHED_PP[62];
smfulladder dfa28 (.DATA_A (INT_SUM[47]), .DATA_B (INT_SUM[48]), .DATA_C (INT_SUM[49]), .SAVE (INT_SUM[50]), .CARRY (INT_CARRY[40]) );
smhalfadder dha11 (.DATA_A (INT_CARRY[32]), .DATA_B (INT_CARRY[33]), .SAVE (INT_SUM[51]), .CARRY (INT_CARRY[41]) );
smfulladder dfa29 (.DATA_A (INT_SUM[50]), .DATA_B (INT_SUM[51]), .DATA_C (INT_CARRY[34]), .SAVE (INT_SUM[52]), .CARRY (INT_CARRY[42]) );
assign INT_SUM[53] = INT_CARRY[35];
smfulladder dfa30 (.DATA_A (INT_SUM[52]), .DATA_B (INT_SUM[53]), .DATA_C (INT_CARRY[36]), .SAVE (INT_SUM[54]), .CARRY (INT_CARRY[37]) );
smffb dla88 (.D(INT_SUM[54]), .clk(clk), .en_d2(en_d2), .Q(SUM[13]) );
smffb dla89 (.D(INT_CARRY[37]), .clk(clk), .en_d2(en_d2), .Q(CARRY[13]) );
smffa dla90 (.D(SUMMAND[63]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[63]) );
smffa dla91 (.D(SUMMAND[64]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[64]) );
smffa dla92 (.D(SUMMAND[65]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[65]) );
smfulladder dfa31 (.DATA_A (LATCHED_PP[63]), .DATA_B (LATCHED_PP[64]), .DATA_C (LATCHED_PP[65]), .SAVE (INT_SUM[55]), .CARRY (INT_CARRY[44]) );
smffa dla93 (.D(SUMMAND[66]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[66]) );
smffa dla94 (.D(SUMMAND[67]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[67]) );
smffa dla95 (.D(SUMMAND[68]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[68]) );
smfulladder dfa32 (.DATA_A (LATCHED_PP[66]), .DATA_B (LATCHED_PP[67]), .DATA_C (LATCHED_PP[68]), .SAVE (INT_SUM[56]), .CARRY (INT_CARRY[45]) );
smffa dla96 (.D(SUMMAND[69]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[69]) );
smffa dla97 (.D(SUMMAND[70]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[70]) );
smffa dla98 (.D(SUMMAND[71]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[71]) );
smfulladder dfa33 (.DATA_A (LATCHED_PP[69]), .DATA_B (LATCHED_PP[70]), .DATA_C (LATCHED_PP[71]), .SAVE (INT_SUM[57]), .CARRY (INT_CARRY[46]) );
smfulladder dfa34 (.DATA_A (INT_SUM[55]), .DATA_B (INT_SUM[56]), .DATA_C (INT_SUM[57]), .SAVE (INT_SUM[58]), .CARRY (INT_CARRY[47]) );
smhalfadder dha12 (.DATA_A (INT_CARRY[38]), .DATA_B (INT_CARRY[39]), .SAVE (INT_SUM[59]), .CARRY (INT_CARRY[48]) );
smfulladder dfa35 (.DATA_A (INT_SUM[58]), .DATA_B (INT_SUM[59]), .DATA_C (INT_CARRY[40]), .SAVE (INT_SUM[60]), .CARRY (INT_CARRY[49]) );
assign INT_SUM[61] = INT_CARRY[41];
smfulladder dfa36 (.DATA_A (INT_SUM[60]), .DATA_B (INT_SUM[61]), .DATA_C (INT_CARRY[42]), .SAVE (INT_SUM[62]), .CARRY (INT_CARRY[43]) );
smffb dla99 (.D(INT_SUM[62]), .clk(clk), .en_d2(en_d2), .Q(SUM[14]) );
smffb dla100 (.D(INT_CARRY[43]), .clk(clk), .en_d2(en_d2), .Q(CARRY[14]) );
smffa dla101 (.D(SUMMAND[72]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[72]) );
smffa dla102 (.D(SUMMAND[73]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[73]) );
smffa dla103 (.D(SUMMAND[74]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[74]) );
smfulladder dfa37 (.DATA_A (LATCHED_PP[72]), .DATA_B (LATCHED_PP[73]), .DATA_C (LATCHED_PP[74]), .SAVE (INT_SUM[63]), .CARRY (INT_CARRY[51]) );
smffa dla104 (.D(SUMMAND[75]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[75]) );
smffa dla105 (.D(SUMMAND[76]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[76]) );
smffa dla106 (.D(SUMMAND[77]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[77]) );
smfulladder dfa38 (.DATA_A (LATCHED_PP[75]), .DATA_B (LATCHED_PP[76]), .DATA_C (LATCHED_PP[77]), .SAVE (INT_SUM[64]), .CARRY (INT_CARRY[52]) );
smffa dla107 (.D(SUMMAND[78]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[78]) );
smffa dla108 (.D(SUMMAND[79]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[79]) );
smhalfadder dha13 (.DATA_A (LATCHED_PP[78]), .DATA_B (LATCHED_PP[79]), .SAVE (INT_SUM[65]), .CARRY (INT_CARRY[53]) );
smfulladder dfa39 (.DATA_A (INT_SUM[63]), .DATA_B (INT_SUM[64]), .DATA_C (INT_SUM[65]), .SAVE (INT_SUM[66]), .CARRY (INT_CARRY[54]) );
smfulladder dfa40 (.DATA_A (INT_CARRY[44]), .DATA_B (INT_CARRY[45]), .DATA_C (INT_CARRY[46]), .SAVE (INT_SUM[67]), .CARRY (INT_CARRY[55]) );
smfulladder dfa41 (.DATA_A (INT_SUM[66]), .DATA_B (INT_SUM[67]), .DATA_C (INT_CARRY[47]), .SAVE (INT_SUM[68]), .CARRY (INT_CARRY[56]) );
assign INT_SUM[69] = INT_CARRY[48];
smfulladder dfa42 (.DATA_A (INT_SUM[68]), .DATA_B (INT_SUM[69]), .DATA_C (INT_CARRY[49]), .SAVE (INT_SUM[70]), .CARRY (INT_CARRY[50]) );
smffb dla109 (.D(INT_SUM[70]), .clk(clk), .en_d2(en_d2), .Q(SUM[15]) );
smffb dla110 (.D(INT_CARRY[50]), .clk(clk), .en_d2(en_d2), .Q(CARRY[15]) );
smffa dla111 (.D(SUMMAND[80]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[80]) );
smffa dla112 (.D(SUMMAND[81]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[81]) );
smffa dla113 (.D(SUMMAND[82]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[82]) );
smfulladder dfa43 (.DATA_A (LATCHED_PP[80]), .DATA_B (LATCHED_PP[81]), .DATA_C (LATCHED_PP[82]), .SAVE (INT_SUM[71]), .CARRY (INT_CARRY[58]) );
smffa dla114 (.D(SUMMAND[83]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[83]) );
smffa dla115 (.D(SUMMAND[84]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[84]) );
smffa dla116 (.D(SUMMAND[85]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[85]) );
smfulladder dfa44 (.DATA_A (LATCHED_PP[83]), .DATA_B (LATCHED_PP[84]), .DATA_C (LATCHED_PP[85]), .SAVE (INT_SUM[72]), .CARRY (INT_CARRY[59]) );
smffa dla117 (.D(SUMMAND[86]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[86]) );
smffa dla118 (.D(SUMMAND[87]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[87]) );
smffa dla119 (.D(SUMMAND[88]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[88]) );
smfulladder dfa45 (.DATA_A (LATCHED_PP[86]), .DATA_B (LATCHED_PP[87]), .DATA_C (LATCHED_PP[88]), .SAVE (INT_SUM[73]), .CARRY (INT_CARRY[60]) );
smffa dla120 (.D(SUMMAND[89]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[89]) );
assign INT_SUM[74] = LATCHED_PP[89];
smfulladder dfa46 (.DATA_A (INT_SUM[71]), .DATA_B (INT_SUM[72]), .DATA_C (INT_SUM[73]), .SAVE (INT_SUM[75]), .CARRY (INT_CARRY[61]) );
smfulladder dfa47 (.DATA_A (INT_SUM[74]), .DATA_B (INT_CARRY[51]), .DATA_C (INT_CARRY[52]), .SAVE (INT_SUM[76]), .CARRY (INT_CARRY[62]) );
assign INT_SUM[77] = INT_CARRY[53];
smfulladder dfa48 (.DATA_A (INT_SUM[75]), .DATA_B (INT_SUM[76]), .DATA_C (INT_SUM[77]), .SAVE (INT_SUM[78]), .CARRY (INT_CARRY[63]) );
smhalfadder dha14 (.DATA_A (INT_CARRY[54]), .DATA_B (INT_CARRY[55]), .SAVE (INT_SUM[79]), .CARRY (INT_CARRY[64]) );
smfulladder dfa49 (.DATA_A (INT_SUM[78]), .DATA_B (INT_SUM[79]), .DATA_C (INT_CARRY[56]), .SAVE (INT_SUM[80]), .CARRY (INT_CARRY[57]) );
smffb dla121 (.D(INT_SUM[80]), .clk(clk), .en_d2(en_d2), .Q(SUM[16]) );
smffb dla122 (.D(INT_CARRY[57]), .clk(clk), .en_d2(en_d2), .Q(CARRY[16]) );
smffa dla123 (.D(SUMMAND[90]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[90]) );
smffa dla124 (.D(SUMMAND[91]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[91]) );
smffa dla125 (.D(SUMMAND[92]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[92]) );
smfulladder dfa50 (.DATA_A (LATCHED_PP[90]), .DATA_B (LATCHED_PP[91]), .DATA_C (LATCHED_PP[92]), .SAVE (INT_SUM[81]), .CARRY (INT_CARRY[66]) );
smffa dla126 (.D(SUMMAND[93]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[93]) );
smffa dla127 (.D(SUMMAND[94]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[94]) );
smffa dla128 (.D(SUMMAND[95]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[95]) );
smfulladder dfa51 (.DATA_A (LATCHED_PP[93]), .DATA_B (LATCHED_PP[94]), .DATA_C (LATCHED_PP[95]), .SAVE (INT_SUM[82]), .CARRY (INT_CARRY[67]) );
smffa dla129 (.D(SUMMAND[96]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[96]) );
smffa dla130 (.D(SUMMAND[97]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[97]) );
smffa dla131 (.D(SUMMAND[98]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[98]) );
smfulladder dfa52 (.DATA_A (LATCHED_PP[96]), .DATA_B (LATCHED_PP[97]), .DATA_C (LATCHED_PP[98]), .SAVE (INT_SUM[83]), .CARRY (INT_CARRY[68]) );
smfulladder dfa53 (.DATA_A (INT_SUM[81]), .DATA_B (INT_SUM[82]), .DATA_C (INT_SUM[83]), .SAVE (INT_SUM[84]), .CARRY (INT_CARRY[69]) );
smfulladder dfa54 (.DATA_A (INT_CARRY[58]), .DATA_B (INT_CARRY[59]), .DATA_C (INT_CARRY[60]), .SAVE (INT_SUM[85]), .CARRY (INT_CARRY[70]) );
smfulladder dfa55 (.DATA_A (INT_SUM[84]), .DATA_B (INT_SUM[85]), .DATA_C (INT_CARRY[61]), .SAVE (INT_SUM[86]), .CARRY (INT_CARRY[71]) );
assign INT_SUM[87] = INT_CARRY[62];
smfulladder dfa56 (.DATA_A (INT_SUM[86]), .DATA_B (INT_SUM[87]), .DATA_C (INT_CARRY[63]), .SAVE (INT_SUM[88]), .CARRY (INT_CARRY[72]) );
assign INT_SUM[89] = INT_CARRY[64];
smhalfadder dha15 (.DATA_A (INT_SUM[88]), .DATA_B (INT_SUM[89]), .SAVE (INT_SUM[90]), .CARRY (INT_CARRY[65]) );
smffb dla132 (.D(INT_SUM[90]), .clk(clk), .en_d2(en_d2), .Q(SUM[17]) );
smffb dla133 (.D(INT_CARRY[65]), .clk(clk), .en_d2(en_d2), .Q(CARRY[17]) );
smffa dla134 (.D(SUMMAND[99]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[99]) );
smffa dla135 (.D(SUMMAND[100]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[100]) );
smffa dla136 (.D(SUMMAND[101]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[101]) );
smfulladder dfa57 (.DATA_A (LATCHED_PP[99]), .DATA_B (LATCHED_PP[100]), .DATA_C (LATCHED_PP[101]), .SAVE (INT_SUM[91]), .CARRY (INT_CARRY[74]) );
smffa dla137 (.D(SUMMAND[102]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[102]) );
smffa dla138 (.D(SUMMAND[103]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[103]) );
smffa dla139 (.D(SUMMAND[104]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[104]) );
smfulladder dfa58 (.DATA_A (LATCHED_PP[102]), .DATA_B (LATCHED_PP[103]), .DATA_C (LATCHED_PP[104]), .SAVE (INT_SUM[92]), .CARRY (INT_CARRY[75]) );
smffa dla140 (.D(SUMMAND[105]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[105]) );
smffa dla141 (.D(SUMMAND[106]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[106]) );
smffa dla142 (.D(SUMMAND[107]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[107]) );
smfulladder dfa59 (.DATA_A (LATCHED_PP[105]), .DATA_B (LATCHED_PP[106]), .DATA_C (LATCHED_PP[107]), .SAVE (INT_SUM[93]), .CARRY (INT_CARRY[76]) );
smffa dla143 (.D(SUMMAND[108]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[108]) );
assign INT_SUM[94] = LATCHED_PP[108];
smffa dla144 (.D(SUMMAND[109]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[109]) );
assign INT_SUM[95] = LATCHED_PP[109];
smfulladder dfa60 (.DATA_A (INT_SUM[91]), .DATA_B (INT_SUM[92]), .DATA_C (INT_SUM[93]), .SAVE (INT_SUM[96]), .CARRY (INT_CARRY[77]) );
smfulladder dfa61 (.DATA_A (INT_SUM[94]), .DATA_B (INT_SUM[95]), .DATA_C (INT_CARRY[66]), .SAVE (INT_SUM[97]), .CARRY (INT_CARRY[78]) );
assign INT_SUM[98] = INT_CARRY[67];
assign INT_SUM[99] = INT_CARRY[68];
smfulladder dfa62 (.DATA_A (INT_SUM[96]), .DATA_B (INT_SUM[97]), .DATA_C (INT_SUM[98]), .SAVE (INT_SUM[100]), .CARRY (INT_CARRY[79]) );
smfulladder dfa63 (.DATA_A (INT_SUM[99]), .DATA_B (INT_CARRY[69]), .DATA_C (INT_CARRY[70]), .SAVE (INT_SUM[101]), .CARRY (INT_CARRY[80]) );
smfulladder dfa64 (.DATA_A (INT_SUM[100]), .DATA_B (INT_SUM[101]), .DATA_C (INT_CARRY[71]), .SAVE (INT_SUM[102]), .CARRY (INT_CARRY[81]) );
smhalfadder dha16 (.DATA_A (INT_SUM[102]), .DATA_B (INT_CARRY[72]), .SAVE (INT_SUM[103]), .CARRY (INT_CARRY[73]) );
smffb dla145 (.D(INT_SUM[103]), .clk(clk), .en_d2(en_d2), .Q(SUM[18]) );
smffb dla146 (.D(INT_CARRY[73]), .clk(clk), .en_d2(en_d2), .Q(CARRY[18]) );
smffa dla147 (.D(SUMMAND[110]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[110]) );
smffa dla148 (.D(SUMMAND[111]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[111]) );
smffa dla149 (.D(SUMMAND[112]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[112]) );
smfulladder dfa65 (.DATA_A (LATCHED_PP[110]), .DATA_B (LATCHED_PP[111]), .DATA_C (LATCHED_PP[112]), .SAVE (INT_SUM[104]), .CARRY (INT_CARRY[83]) );
smffa dla150 (.D(SUMMAND[113]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[113]) );
smffa dla151 (.D(SUMMAND[114]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[114]) );
smffa dla152 (.D(SUMMAND[115]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[115]) );
smfulladder dfa66 (.DATA_A (LATCHED_PP[113]), .DATA_B (LATCHED_PP[114]), .DATA_C (LATCHED_PP[115]), .SAVE (INT_SUM[105]), .CARRY (INT_CARRY[84]) );
smffa dla153 (.D(SUMMAND[116]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[116]) );
smffa dla154 (.D(SUMMAND[117]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[117]) );
smffa dla155 (.D(SUMMAND[118]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[118]) );
smfulladder dfa67 (.DATA_A (LATCHED_PP[116]), .DATA_B (LATCHED_PP[117]), .DATA_C (LATCHED_PP[118]), .SAVE (INT_SUM[106]), .CARRY (INT_CARRY[85]) );
smffa dla156 (.D(SUMMAND[119]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[119]) );
assign INT_SUM[107] = LATCHED_PP[119];
smfulladder dfa68 (.DATA_A (INT_SUM[104]), .DATA_B (INT_SUM[105]), .DATA_C (INT_SUM[106]), .SAVE (INT_SUM[108]), .CARRY (INT_CARRY[86]) );
smfulladder dfa69 (.DATA_A (INT_SUM[107]), .DATA_B (INT_CARRY[74]), .DATA_C (INT_CARRY[75]), .SAVE (INT_SUM[109]), .CARRY (INT_CARRY[87]) );
assign INT_SUM[110] = INT_CARRY[76];
smfulladder dfa70 (.DATA_A (INT_SUM[108]), .DATA_B (INT_SUM[109]), .DATA_C (INT_SUM[110]), .SAVE (INT_SUM[111]), .CARRY (INT_CARRY[88]) );
smhalfadder dha17 (.DATA_A (INT_CARRY[77]), .DATA_B (INT_CARRY[78]), .SAVE (INT_SUM[112]), .CARRY (INT_CARRY[89]) );
smfulladder dfa71 (.DATA_A (INT_SUM[111]), .DATA_B (INT_SUM[112]), .DATA_C (INT_CARRY[79]), .SAVE (INT_SUM[113]), .CARRY (INT_CARRY[90]) );
assign INT_SUM[114] = INT_CARRY[80];
smfulladder dfa72 (.DATA_A (INT_SUM[113]), .DATA_B (INT_SUM[114]), .DATA_C (INT_CARRY[81]), .SAVE (INT_SUM[115]), .CARRY (INT_CARRY[82]) );
smffb dla157 (.D(INT_SUM[115]), .clk(clk), .en_d2(en_d2), .Q(SUM[19]) );
smffb dla158 (.D(INT_CARRY[82]), .clk(clk), .en_d2(en_d2), .Q(CARRY[19]) );
smffa dla159 (.D(SUMMAND[120]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[120]) );
smffa dla160 (.D(SUMMAND[121]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[121]) );
smffa dla161 (.D(SUMMAND[122]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[122]) );
smfulladder dfa73 (.DATA_A (LATCHED_PP[120]), .DATA_B (LATCHED_PP[121]), .DATA_C (LATCHED_PP[122]), .SAVE (INT_SUM[116]), .CARRY (INT_CARRY[92]) );
smffa dla162 (.D(SUMMAND[123]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[123]) );
smffa dla163 (.D(SUMMAND[124]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[124]) );
smffa dla164 (.D(SUMMAND[125]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[125]) );
smfulladder dfa74 (.DATA_A (LATCHED_PP[123]), .DATA_B (LATCHED_PP[124]), .DATA_C (LATCHED_PP[125]), .SAVE (INT_SUM[117]), .CARRY (INT_CARRY[93]) );
smffa dla165 (.D(SUMMAND[126]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[126]) );
smffa dla166 (.D(SUMMAND[127]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[127]) );
smffa dla167 (.D(SUMMAND[128]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[128]) );
smfulladder dfa75 (.DATA_A (LATCHED_PP[126]), .DATA_B (LATCHED_PP[127]), .DATA_C (LATCHED_PP[128]), .SAVE (INT_SUM[118]), .CARRY (INT_CARRY[94]) );
smffa dla168 (.D(SUMMAND[129]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[129]) );
smffa dla169 (.D(SUMMAND[130]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[130]) );
smffa dla170 (.D(SUMMAND[131]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[131]) );
smfulladder dfa76 (.DATA_A (LATCHED_PP[129]), .DATA_B (LATCHED_PP[130]), .DATA_C (LATCHED_PP[131]), .SAVE (INT_SUM[119]), .CARRY (INT_CARRY[95]) );
smfulladder dfa77 (.DATA_A (INT_SUM[116]), .DATA_B (INT_SUM[117]), .DATA_C (INT_SUM[118]), .SAVE (INT_SUM[120]), .CARRY (INT_CARRY[96]) );
smfulladder dfa78 (.DATA_A (INT_SUM[119]), .DATA_B (INT_CARRY[83]), .DATA_C (INT_CARRY[84]), .SAVE (INT_SUM[121]), .CARRY (INT_CARRY[97]) );
assign INT_SUM[122] = INT_CARRY[85];
smfulladder dfa79 (.DATA_A (INT_SUM[120]), .DATA_B (INT_SUM[121]), .DATA_C (INT_SUM[122]), .SAVE (INT_SUM[123]), .CARRY (INT_CARRY[98]) );
smhalfadder dha18 (.DATA_A (INT_CARRY[86]), .DATA_B (INT_CARRY[87]), .SAVE (INT_SUM[124]), .CARRY (INT_CARRY[99]) );
smfulladder dfa80 (.DATA_A (INT_SUM[123]), .DATA_B (INT_SUM[124]), .DATA_C (INT_CARRY[88]), .SAVE (INT_SUM[125]), .CARRY (INT_CARRY[100]) );
assign INT_SUM[126] = INT_CARRY[89];
smfulladder dfa81 (.DATA_A (INT_SUM[125]), .DATA_B (INT_SUM[126]), .DATA_C (INT_CARRY[90]), .SAVE (INT_SUM[127]), .CARRY (INT_CARRY[91]) );
smffb dla171 (.D(INT_SUM[127]), .clk(clk), .en_d2(en_d2), .Q(SUM[20]) );
smffb dla172 (.D(INT_CARRY[91]), .clk(clk), .en_d2(en_d2), .Q(CARRY[20]) );
smffa dla173 (.D(SUMMAND[132]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[132]) );
smffa dla174 (.D(SUMMAND[133]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[133]) );
smffa dla175 (.D(SUMMAND[134]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[134]) );
smfulladder dfa82 (.DATA_A (LATCHED_PP[132]), .DATA_B (LATCHED_PP[133]), .DATA_C (LATCHED_PP[134]), .SAVE (INT_SUM[128]), .CARRY (INT_CARRY[102]) );
smffa dla176 (.D(SUMMAND[135]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[135]) );
smffa dla177 (.D(SUMMAND[136]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[136]) );
smffa dla178 (.D(SUMMAND[137]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[137]) );
smfulladder dfa83 (.DATA_A (LATCHED_PP[135]), .DATA_B (LATCHED_PP[136]), .DATA_C (LATCHED_PP[137]), .SAVE (INT_SUM[129]), .CARRY (INT_CARRY[103]) );
smffa dla179 (.D(SUMMAND[138]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[138]) );
smffa dla180 (.D(SUMMAND[139]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[139]) );
smffa dla181 (.D(SUMMAND[140]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[140]) );
smfulladder dfa84 (.DATA_A (LATCHED_PP[138]), .DATA_B (LATCHED_PP[139]), .DATA_C (LATCHED_PP[140]), .SAVE (INT_SUM[130]), .CARRY (INT_CARRY[104]) );
smffa dla182 (.D(SUMMAND[141]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[141]) );
assign INT_SUM[131] = LATCHED_PP[141];
smffa dla183 (.D(SUMMAND[142]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[142]) );
assign INT_SUM[132] = LATCHED_PP[142];
smfulladder dfa85 (.DATA_A (INT_SUM[128]), .DATA_B (INT_SUM[129]), .DATA_C (INT_SUM[130]), .SAVE (INT_SUM[133]), .CARRY (INT_CARRY[105]) );
smfulladder dfa86 (.DATA_A (INT_SUM[131]), .DATA_B (INT_SUM[132]), .DATA_C (INT_CARRY[92]), .SAVE (INT_SUM[134]), .CARRY (INT_CARRY[106]) );
smfulladder dfa87 (.DATA_A (INT_CARRY[93]), .DATA_B (INT_CARRY[94]), .DATA_C (INT_CARRY[95]), .SAVE (INT_SUM[135]), .CARRY (INT_CARRY[107]) );
smfulladder dfa88 (.DATA_A (INT_SUM[133]), .DATA_B (INT_SUM[134]), .DATA_C (INT_SUM[135]), .SAVE (INT_SUM[136]), .CARRY (INT_CARRY[108]) );
smhalfadder dha19 (.DATA_A (INT_CARRY[96]), .DATA_B (INT_CARRY[97]), .SAVE (INT_SUM[137]), .CARRY (INT_CARRY[109]) );
smfulladder dfa89 (.DATA_A (INT_SUM[136]), .DATA_B (INT_SUM[137]), .DATA_C (INT_CARRY[98]), .SAVE (INT_SUM[138]), .CARRY (INT_CARRY[110]) );
assign INT_SUM[139] = INT_CARRY[99];
smfulladder dfa90 (.DATA_A (INT_SUM[138]), .DATA_B (INT_SUM[139]), .DATA_C (INT_CARRY[100]), .SAVE (INT_SUM[140]), .CARRY (INT_CARRY[101]) );
smffb dla184 (.D(INT_SUM[140]), .clk(clk), .en_d2(en_d2), .Q(SUM[21]) );
smffb dla185 (.D(INT_CARRY[101]), .clk(clk), .en_d2(en_d2), .Q(CARRY[21]) );
smffa dla186 (.D(SUMMAND[143]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[143]) );
smffa dla187 (.D(SUMMAND[144]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[144]) );
smffa dla188 (.D(SUMMAND[145]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[145]) );
smfulladder dfa91 (.DATA_A (LATCHED_PP[143]), .DATA_B (LATCHED_PP[144]), .DATA_C (LATCHED_PP[145]), .SAVE (INT_SUM[141]), .CARRY (INT_CARRY[112]) );
smffa dla189 (.D(SUMMAND[146]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[146]) );
smffa dla190 (.D(SUMMAND[147]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[147]) );
smffa dla191 (.D(SUMMAND[148]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[148]) );
smfulladder dfa92 (.DATA_A (LATCHED_PP[146]), .DATA_B (LATCHED_PP[147]), .DATA_C (LATCHED_PP[148]), .SAVE (INT_SUM[142]), .CARRY (INT_CARRY[113]) );
smffa dla192 (.D(SUMMAND[149]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[149]) );
smffa dla193 (.D(SUMMAND[150]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[150]) );
smffa dla194 (.D(SUMMAND[151]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[151]) );
smfulladder dfa93 (.DATA_A (LATCHED_PP[149]), .DATA_B (LATCHED_PP[150]), .DATA_C (LATCHED_PP[151]), .SAVE (INT_SUM[143]), .CARRY (INT_CARRY[114]) );
smffa dla195 (.D(SUMMAND[152]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[152]) );
smffa dla196 (.D(SUMMAND[153]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[153]) );
smffa dla197 (.D(SUMMAND[154]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[154]) );
smfulladder dfa94 (.DATA_A (LATCHED_PP[152]), .DATA_B (LATCHED_PP[153]), .DATA_C (LATCHED_PP[154]), .SAVE (INT_SUM[144]), .CARRY (INT_CARRY[115]) );
smffa dla198 (.D(SUMMAND[155]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[155]) );
assign INT_SUM[145] = LATCHED_PP[155];
smfulladder dfa95 (.DATA_A (INT_SUM[141]), .DATA_B (INT_SUM[142]), .DATA_C (INT_SUM[143]), .SAVE (INT_SUM[146]), .CARRY (INT_CARRY[116]) );
smfulladder dfa96 (.DATA_A (INT_SUM[144]), .DATA_B (INT_SUM[145]), .DATA_C (INT_CARRY[102]), .SAVE (INT_SUM[147]), .CARRY (INT_CARRY[117]) );
smhalfadder dha20 (.DATA_A (INT_CARRY[103]), .DATA_B (INT_CARRY[104]), .SAVE (INT_SUM[148]), .CARRY (INT_CARRY[118]) );
smfulladder dfa97 (.DATA_A (INT_SUM[146]), .DATA_B (INT_SUM[147]), .DATA_C (INT_SUM[148]), .SAVE (INT_SUM[149]), .CARRY (INT_CARRY[119]) );
smfulladder dfa98 (.DATA_A (INT_CARRY[105]), .DATA_B (INT_CARRY[106]), .DATA_C (INT_CARRY[107]), .SAVE (INT_SUM[150]), .CARRY (INT_CARRY[120]) );
smfulladder dfa99 (.DATA_A (INT_SUM[149]), .DATA_B (INT_SUM[150]), .DATA_C (INT_CARRY[108]), .SAVE (INT_SUM[151]), .CARRY (INT_CARRY[121]) );
assign INT_SUM[152] = INT_CARRY[109];
smfulladder dfa100 (.DATA_A (INT_SUM[151]), .DATA_B (INT_SUM[152]), .DATA_C (INT_CARRY[110]), .SAVE (INT_SUM[153]), .CARRY (INT_CARRY[111]) );
smffb dla199 (.D(INT_SUM[153]), .clk(clk), .en_d2(en_d2), .Q(SUM[22]) );
smffb dla200 (.D(INT_CARRY[111]), .clk(clk), .en_d2(en_d2), .Q(CARRY[22]) );
smffa dla201 (.D(SUMMAND[156]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[156]) );
smffa dla202 (.D(SUMMAND[157]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[157]) );
smffa dla203 (.D(SUMMAND[158]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[158]) );
smfulladder dfa101 (.DATA_A (LATCHED_PP[156]), .DATA_B (LATCHED_PP[157]), .DATA_C (LATCHED_PP[158]), .SAVE (INT_SUM[154]), .CARRY (INT_CARRY[123]) );
smffa dla204 (.D(SUMMAND[159]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[159]) );
smffa dla205 (.D(SUMMAND[160]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[160]) );
smffa dla206 (.D(SUMMAND[161]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[161]) );
smfulladder dfa102 (.DATA_A (LATCHED_PP[159]), .DATA_B (LATCHED_PP[160]), .DATA_C (LATCHED_PP[161]), .SAVE (INT_SUM[155]), .CARRY (INT_CARRY[124]) );
smffa dla207 (.D(SUMMAND[162]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[162]) );
smffa dla208 (.D(SUMMAND[163]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[163]) );
smffa dla209 (.D(SUMMAND[164]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[164]) );
smfulladder dfa103 (.DATA_A (LATCHED_PP[162]), .DATA_B (LATCHED_PP[163]), .DATA_C (LATCHED_PP[164]), .SAVE (INT_SUM[156]), .CARRY (INT_CARRY[125]) );
smffa dla210 (.D(SUMMAND[165]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[165]) );
smffa dla211 (.D(SUMMAND[166]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[166]) );
smffa dla212 (.D(SUMMAND[167]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[167]) );
smfulladder dfa104 (.DATA_A (LATCHED_PP[165]), .DATA_B (LATCHED_PP[166]), .DATA_C (LATCHED_PP[167]), .SAVE (INT_SUM[157]), .CARRY (INT_CARRY[126]) );
smfulladder dfa105 (.DATA_A (INT_SUM[154]), .DATA_B (INT_SUM[155]), .DATA_C (INT_SUM[156]), .SAVE (INT_SUM[158]), .CARRY (INT_CARRY[127]) );
smfulladder dfa106 (.DATA_A (INT_SUM[157]), .DATA_B (INT_CARRY[112]), .DATA_C (INT_CARRY[113]), .SAVE (INT_SUM[159]), .CARRY (INT_CARRY[128]) );
smhalfadder dha21 (.DATA_A (INT_CARRY[114]), .DATA_B (INT_CARRY[115]), .SAVE (INT_SUM[160]), .CARRY (INT_CARRY[129]) );
smfulladder dfa107 (.DATA_A (INT_SUM[158]), .DATA_B (INT_SUM[159]), .DATA_C (INT_SUM[160]), .SAVE (INT_SUM[161]), .CARRY (INT_CARRY[130]) );
smfulladder dfa108 (.DATA_A (INT_CARRY[116]), .DATA_B (INT_CARRY[117]), .DATA_C (INT_CARRY[118]), .SAVE (INT_SUM[162]), .CARRY (INT_CARRY[131]) );
smfulladder dfa109 (.DATA_A (INT_SUM[161]), .DATA_B (INT_SUM[162]), .DATA_C (INT_CARRY[119]), .SAVE (INT_SUM[163]), .CARRY (INT_CARRY[132]) );
assign INT_SUM[164] = INT_CARRY[120];
smfulladder dfa110 (.DATA_A (INT_SUM[163]), .DATA_B (INT_SUM[164]), .DATA_C (INT_CARRY[121]), .SAVE (INT_SUM[165]), .CARRY (INT_CARRY[122]) );
smffb dla213 (.D(INT_SUM[165]), .clk(clk), .en_d2(en_d2), .Q(SUM[23]) );
smffb dla214 (.D(INT_CARRY[122]), .clk(clk), .en_d2(en_d2), .Q(CARRY[23]) );
smffa dla215 (.D(SUMMAND[168]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[168]) );
smffa dla216 (.D(SUMMAND[169]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[169]) );
smffa dla217 (.D(SUMMAND[170]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[170]) );
smfulladder dfa111 (.DATA_A (LATCHED_PP[168]), .DATA_B (LATCHED_PP[169]), .DATA_C (LATCHED_PP[170]), .SAVE (INT_SUM[166]), .CARRY (INT_CARRY[134]) );
smffa dla218 (.D(SUMMAND[171]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[171]) );
smffa dla219 (.D(SUMMAND[172]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[172]) );
smffa dla220 (.D(SUMMAND[173]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[173]) );
smfulladder dfa112 (.DATA_A (LATCHED_PP[171]), .DATA_B (LATCHED_PP[172]), .DATA_C (LATCHED_PP[173]), .SAVE (INT_SUM[167]), .CARRY (INT_CARRY[135]) );
smffa dla221 (.D(SUMMAND[174]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[174]) );
smffa dla222 (.D(SUMMAND[175]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[175]) );
smffa dla223 (.D(SUMMAND[176]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[176]) );
smfulladder dfa113 (.DATA_A (LATCHED_PP[174]), .DATA_B (LATCHED_PP[175]), .DATA_C (LATCHED_PP[176]), .SAVE (INT_SUM[168]), .CARRY (INT_CARRY[136]) );
smffa dla224 (.D(SUMMAND[177]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[177]) );
smffa dla225 (.D(SUMMAND[178]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[178]) );
smffa dla226 (.D(SUMMAND[179]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[179]) );
smfulladder dfa114 (.DATA_A (LATCHED_PP[177]), .DATA_B (LATCHED_PP[178]), .DATA_C (LATCHED_PP[179]), .SAVE (INT_SUM[169]), .CARRY (INT_CARRY[137]) );
smffa dla227 (.D(SUMMAND[180]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[180]) );
smffa dla228 (.D(SUMMAND[181]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[181]) );
smhalfadder dha22 (.DATA_A (LATCHED_PP[180]), .DATA_B (LATCHED_PP[181]), .SAVE (INT_SUM[170]), .CARRY (INT_CARRY[138]) );
smfulladder dfa115 (.DATA_A (INT_SUM[166]), .DATA_B (INT_SUM[167]), .DATA_C (INT_SUM[168]), .SAVE (INT_SUM[171]), .CARRY (INT_CARRY[139]) );
smfulladder dfa116 (.DATA_A (INT_SUM[169]), .DATA_B (INT_SUM[170]), .DATA_C (INT_CARRY[123]), .SAVE (INT_SUM[172]), .CARRY (INT_CARRY[140]) );
smfulladder dfa117 (.DATA_A (INT_CARRY[124]), .DATA_B (INT_CARRY[125]), .DATA_C (INT_CARRY[126]), .SAVE (INT_SUM[173]), .CARRY (INT_CARRY[141]) );
smfulladder dfa118 (.DATA_A (INT_SUM[171]), .DATA_B (INT_SUM[172]), .DATA_C (INT_SUM[173]), .SAVE (INT_SUM[174]), .CARRY (INT_CARRY[142]) );
smfulladder dfa119 (.DATA_A (INT_CARRY[127]), .DATA_B (INT_CARRY[128]), .DATA_C (INT_CARRY[129]), .SAVE (INT_SUM[175]), .CARRY (INT_CARRY[143]) );
smfulladder dfa120 (.DATA_A (INT_SUM[174]), .DATA_B (INT_SUM[175]), .DATA_C (INT_CARRY[130]), .SAVE (INT_SUM[176]), .CARRY (INT_CARRY[144]) );
assign INT_SUM[177] = INT_CARRY[131];
smfulladder dfa121 (.DATA_A (INT_SUM[176]), .DATA_B (INT_SUM[177]), .DATA_C (INT_CARRY[132]), .SAVE (INT_SUM[178]), .CARRY (INT_CARRY[133]) );
smffb dla229 (.D(INT_SUM[178]), .clk(clk), .en_d2(en_d2), .Q(SUM[24]) );
smffb dla230 (.D(INT_CARRY[133]), .clk(clk), .en_d2(en_d2), .Q(CARRY[24]) );
smffa dla231 (.D(SUMMAND[182]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[182]) );
smffa dla232 (.D(SUMMAND[183]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[183]) );
smffa dla233 (.D(SUMMAND[184]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[184]) );
smfulladder dfa122 (.DATA_A (LATCHED_PP[182]), .DATA_B (LATCHED_PP[183]), .DATA_C (LATCHED_PP[184]), .SAVE (INT_SUM[179]), .CARRY (INT_CARRY[146]) );
smffa dla234 (.D(SUMMAND[185]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[185]) );
smffa dla235 (.D(SUMMAND[186]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[186]) );
smffa dla236 (.D(SUMMAND[187]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[187]) );
smfulladder dfa123 (.DATA_A (LATCHED_PP[185]), .DATA_B (LATCHED_PP[186]), .DATA_C (LATCHED_PP[187]), .SAVE (INT_SUM[180]), .CARRY (INT_CARRY[147]) );
smffa dla237 (.D(SUMMAND[188]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[188]) );
smffa dla238 (.D(SUMMAND[189]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[189]) );
smffa dla239 (.D(SUMMAND[190]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[190]) );
smfulladder dfa124 (.DATA_A (LATCHED_PP[188]), .DATA_B (LATCHED_PP[189]), .DATA_C (LATCHED_PP[190]), .SAVE (INT_SUM[181]), .CARRY (INT_CARRY[148]) );
smffa dla240 (.D(SUMMAND[191]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[191]) );
smffa dla241 (.D(SUMMAND[192]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[192]) );
smffa dla242 (.D(SUMMAND[193]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[193]) );
smfulladder dfa125 (.DATA_A (LATCHED_PP[191]), .DATA_B (LATCHED_PP[192]), .DATA_C (LATCHED_PP[193]), .SAVE (INT_SUM[182]), .CARRY (INT_CARRY[149]) );
smffa dla243 (.D(SUMMAND[194]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[194]) );
assign INT_SUM[183] = LATCHED_PP[194];
smfulladder dfa126 (.DATA_A (INT_SUM[179]), .DATA_B (INT_SUM[180]), .DATA_C (INT_SUM[181]), .SAVE (INT_SUM[184]), .CARRY (INT_CARRY[150]) );
smfulladder dfa127 (.DATA_A (INT_SUM[182]), .DATA_B (INT_SUM[183]), .DATA_C (INT_CARRY[134]), .SAVE (INT_SUM[185]), .CARRY (INT_CARRY[151]) );
smfulladder dfa128 (.DATA_A (INT_CARRY[135]), .DATA_B (INT_CARRY[136]), .DATA_C (INT_CARRY[137]), .SAVE (INT_SUM[186]), .CARRY (INT_CARRY[152]) );
assign INT_SUM[187] = INT_CARRY[138];
smfulladder dfa129 (.DATA_A (INT_SUM[184]), .DATA_B (INT_SUM[185]), .DATA_C (INT_SUM[186]), .SAVE (INT_SUM[188]), .CARRY (INT_CARRY[153]) );
smfulladder dfa130 (.DATA_A (INT_SUM[187]), .DATA_B (INT_CARRY[139]), .DATA_C (INT_CARRY[140]), .SAVE (INT_SUM[189]), .CARRY (INT_CARRY[154]) );
assign INT_SUM[190] = INT_CARRY[141];
smfulladder dfa131 (.DATA_A (INT_SUM[188]), .DATA_B (INT_SUM[189]), .DATA_C (INT_SUM[190]), .SAVE (INT_SUM[191]), .CARRY (INT_CARRY[155]) );
smhalfadder dha23 (.DATA_A (INT_CARRY[142]), .DATA_B (INT_CARRY[143]), .SAVE (INT_SUM[192]), .CARRY (INT_CARRY[156]) );
smfulladder dfa132 (.DATA_A (INT_SUM[191]), .DATA_B (INT_SUM[192]), .DATA_C (INT_CARRY[144]), .SAVE (INT_SUM[193]), .CARRY (INT_CARRY[145]) );
smffb dla244 (.D(INT_SUM[193]), .clk(clk), .en_d2(en_d2), .Q(SUM[25]) );
smffb dla245 (.D(INT_CARRY[145]), .clk(clk), .en_d2(en_d2), .Q(CARRY[25]) );
smffa dla246 (.D(SUMMAND[195]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[195]) );
smffa dla247 (.D(SUMMAND[196]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[196]) );
smffa dla248 (.D(SUMMAND[197]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[197]) );
smfulladder dfa133 (.DATA_A (LATCHED_PP[195]), .DATA_B (LATCHED_PP[196]), .DATA_C (LATCHED_PP[197]), .SAVE (INT_SUM[194]), .CARRY (INT_CARRY[158]) );
smffa dla249 (.D(SUMMAND[198]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[198]) );
smffa dla250 (.D(SUMMAND[199]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[199]) );
smffa dla251 (.D(SUMMAND[200]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[200]) );
smfulladder dfa134 (.DATA_A (LATCHED_PP[198]), .DATA_B (LATCHED_PP[199]), .DATA_C (LATCHED_PP[200]), .SAVE (INT_SUM[195]), .CARRY (INT_CARRY[159]) );
smffa dla252 (.D(SUMMAND[201]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[201]) );
smffa dla253 (.D(SUMMAND[202]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[202]) );
smffa dla254 (.D(SUMMAND[203]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[203]) );
smfulladder dfa135 (.DATA_A (LATCHED_PP[201]), .DATA_B (LATCHED_PP[202]), .DATA_C (LATCHED_PP[203]), .SAVE (INT_SUM[196]), .CARRY (INT_CARRY[160]) );
smffa dla255 (.D(SUMMAND[204]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[204]) );
smffa dla256 (.D(SUMMAND[205]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[205]) );
smffa dla257 (.D(SUMMAND[206]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[206]) );
smfulladder dfa136 (.DATA_A (LATCHED_PP[204]), .DATA_B (LATCHED_PP[205]), .DATA_C (LATCHED_PP[206]), .SAVE (INT_SUM[197]), .CARRY (INT_CARRY[161]) );
smffa dla258 (.D(SUMMAND[207]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[207]) );
smffa dla259 (.D(SUMMAND[208]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[208]) );
smffa dla260 (.D(SUMMAND[209]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[209]) );
smfulladder dfa137 (.DATA_A (LATCHED_PP[207]), .DATA_B (LATCHED_PP[208]), .DATA_C (LATCHED_PP[209]), .SAVE (INT_SUM[198]), .CARRY (INT_CARRY[162]) );
smfulladder dfa138 (.DATA_A (INT_SUM[194]), .DATA_B (INT_SUM[195]), .DATA_C (INT_SUM[196]), .SAVE (INT_SUM[199]), .CARRY (INT_CARRY[163]) );
smfulladder dfa139 (.DATA_A (INT_SUM[197]), .DATA_B (INT_SUM[198]), .DATA_C (INT_CARRY[146]), .SAVE (INT_SUM[200]), .CARRY (INT_CARRY[164]) );
smfulladder dfa140 (.DATA_A (INT_CARRY[147]), .DATA_B (INT_CARRY[148]), .DATA_C (INT_CARRY[149]), .SAVE (INT_SUM[201]), .CARRY (INT_CARRY[165]) );
smfulladder dfa141 (.DATA_A (INT_SUM[199]), .DATA_B (INT_SUM[200]), .DATA_C (INT_SUM[201]), .SAVE (INT_SUM[202]), .CARRY (INT_CARRY[166]) );
smfulladder dfa142 (.DATA_A (INT_CARRY[150]), .DATA_B (INT_CARRY[151]), .DATA_C (INT_CARRY[152]), .SAVE (INT_SUM[203]), .CARRY (INT_CARRY[167]) );
smfulladder dfa143 (.DATA_A (INT_SUM[202]), .DATA_B (INT_SUM[203]), .DATA_C (INT_CARRY[153]), .SAVE (INT_SUM[204]), .CARRY (INT_CARRY[168]) );
assign INT_SUM[205] = INT_CARRY[154];
smfulladder dfa144 (.DATA_A (INT_SUM[204]), .DATA_B (INT_SUM[205]), .DATA_C (INT_CARRY[155]), .SAVE (INT_SUM[206]), .CARRY (INT_CARRY[169]) );
assign INT_SUM[207] = INT_CARRY[156];
smhalfadder dha24 (.DATA_A (INT_SUM[206]), .DATA_B (INT_SUM[207]), .SAVE (INT_SUM[208]), .CARRY (INT_CARRY[157]) );
smffb dla261 (.D(INT_SUM[208]), .clk(clk), .en_d2(en_d2), .Q(SUM[26]) );
smffb dla262 (.D(INT_CARRY[157]), .clk(clk), .en_d2(en_d2), .Q(CARRY[26]) );
smffa dla263 (.D(SUMMAND[210]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[210]) );
smffa dla264 (.D(SUMMAND[211]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[211]) );
smffa dla265 (.D(SUMMAND[212]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[212]) );
smfulladder dfa145 (.DATA_A (LATCHED_PP[210]), .DATA_B (LATCHED_PP[211]), .DATA_C (LATCHED_PP[212]), .SAVE (INT_SUM[209]), .CARRY (INT_CARRY[171]) );
smffa dla266 (.D(SUMMAND[213]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[213]) );
smffa dla267 (.D(SUMMAND[214]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[214]) );
smffa dla268 (.D(SUMMAND[215]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[215]) );
smfulladder dfa146 (.DATA_A (LATCHED_PP[213]), .DATA_B (LATCHED_PP[214]), .DATA_C (LATCHED_PP[215]), .SAVE (INT_SUM[210]), .CARRY (INT_CARRY[172]) );
smffa dla269 (.D(SUMMAND[216]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[216]) );
smffa dla270 (.D(SUMMAND[217]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[217]) );
smffa dla271 (.D(SUMMAND[218]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[218]) );
smfulladder dfa147 (.DATA_A (LATCHED_PP[216]), .DATA_B (LATCHED_PP[217]), .DATA_C (LATCHED_PP[218]), .SAVE (INT_SUM[211]), .CARRY (INT_CARRY[173]) );
smffa dla272 (.D(SUMMAND[219]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[219]) );
smffa dla273 (.D(SUMMAND[220]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[220]) );
smffa dla274 (.D(SUMMAND[221]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[221]) );
smfulladder dfa148 (.DATA_A (LATCHED_PP[219]), .DATA_B (LATCHED_PP[220]), .DATA_C (LATCHED_PP[221]), .SAVE (INT_SUM[212]), .CARRY (INT_CARRY[174]) );
smffa dla275 (.D(SUMMAND[222]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[222]) );
smffa dla276 (.D(SUMMAND[223]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[223]) );
smhalfadder dha25 (.DATA_A (LATCHED_PP[222]), .DATA_B (LATCHED_PP[223]), .SAVE (INT_SUM[213]), .CARRY (INT_CARRY[175]) );
smfulladder dfa149 (.DATA_A (INT_SUM[209]), .DATA_B (INT_SUM[210]), .DATA_C (INT_SUM[211]), .SAVE (INT_SUM[214]), .CARRY (INT_CARRY[176]) );
smfulladder dfa150 (.DATA_A (INT_SUM[212]), .DATA_B (INT_SUM[213]), .DATA_C (INT_CARRY[158]), .SAVE (INT_SUM[215]), .CARRY (INT_CARRY[177]) );
smfulladder dfa151 (.DATA_A (INT_CARRY[159]), .DATA_B (INT_CARRY[160]), .DATA_C (INT_CARRY[161]), .SAVE (INT_SUM[216]), .CARRY (INT_CARRY[178]) );
assign INT_SUM[217] = INT_CARRY[162];
smfulladder dfa152 (.DATA_A (INT_SUM[214]), .DATA_B (INT_SUM[215]), .DATA_C (INT_SUM[216]), .SAVE (INT_SUM[218]), .CARRY (INT_CARRY[179]) );
smfulladder dfa153 (.DATA_A (INT_SUM[217]), .DATA_B (INT_CARRY[163]), .DATA_C (INT_CARRY[164]), .SAVE (INT_SUM[219]), .CARRY (INT_CARRY[180]) );
assign INT_SUM[220] = INT_CARRY[165];
smfulladder dfa154 (.DATA_A (INT_SUM[218]), .DATA_B (INT_SUM[219]), .DATA_C (INT_SUM[220]), .SAVE (INT_SUM[221]), .CARRY (INT_CARRY[181]) );
assign INT_SUM[222] = INT_CARRY[166];
assign INT_SUM[223] = INT_CARRY[167];
smfulladder dfa155 (.DATA_A (INT_SUM[221]), .DATA_B (INT_SUM[222]), .DATA_C (INT_SUM[223]), .SAVE (INT_SUM[224]), .CARRY (INT_CARRY[182]) );
assign INT_SUM[225] = INT_CARRY[168];
smfulladder dfa156 (.DATA_A (INT_SUM[224]), .DATA_B (INT_SUM[225]), .DATA_C (INT_CARRY[169]), .SAVE (INT_SUM[226]), .CARRY (INT_CARRY[170]) );
smffb dla277 (.D(INT_SUM[226]), .clk(clk), .en_d2(en_d2), .Q(SUM[27]) );
smffb dla278 (.D(INT_CARRY[170]), .clk(clk), .en_d2(en_d2), .Q(CARRY[27]) );
smffa dla279 (.D(SUMMAND[224]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[224]) );
smffa dla280 (.D(SUMMAND[225]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[225]) );
smffa dla281 (.D(SUMMAND[226]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[226]) );
smfulladder dfa157 (.DATA_A (LATCHED_PP[224]), .DATA_B (LATCHED_PP[225]), .DATA_C (LATCHED_PP[226]), .SAVE (INT_SUM[227]), .CARRY (INT_CARRY[184]) );
smffa dla282 (.D(SUMMAND[227]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[227]) );
smffa dla283 (.D(SUMMAND[228]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[228]) );
smffa dla284 (.D(SUMMAND[229]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[229]) );
smfulladder dfa158 (.DATA_A (LATCHED_PP[227]), .DATA_B (LATCHED_PP[228]), .DATA_C (LATCHED_PP[229]), .SAVE (INT_SUM[228]), .CARRY (INT_CARRY[185]) );
smffa dla285 (.D(SUMMAND[230]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[230]) );
smffa dla286 (.D(SUMMAND[231]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[231]) );
smffa dla287 (.D(SUMMAND[232]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[232]) );
smfulladder dfa159 (.DATA_A (LATCHED_PP[230]), .DATA_B (LATCHED_PP[231]), .DATA_C (LATCHED_PP[232]), .SAVE (INT_SUM[229]), .CARRY (INT_CARRY[186]) );
smffa dla288 (.D(SUMMAND[233]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[233]) );
smffa dla289 (.D(SUMMAND[234]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[234]) );
smffa dla290 (.D(SUMMAND[235]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[235]) );
smfulladder dfa160 (.DATA_A (LATCHED_PP[233]), .DATA_B (LATCHED_PP[234]), .DATA_C (LATCHED_PP[235]), .SAVE (INT_SUM[230]), .CARRY (INT_CARRY[187]) );
smffa dla291 (.D(SUMMAND[236]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[236]) );
smffa dla292 (.D(SUMMAND[237]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[237]) );
smffa dla293 (.D(SUMMAND[238]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[238]) );
smfulladder dfa161 (.DATA_A (LATCHED_PP[236]), .DATA_B (LATCHED_PP[237]), .DATA_C (LATCHED_PP[238]), .SAVE (INT_SUM[231]), .CARRY (INT_CARRY[188]) );
smffa dla294 (.D(SUMMAND[239]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[239]) );
assign INT_SUM[232] = LATCHED_PP[239];
smfulladder dfa162 (.DATA_A (INT_SUM[227]), .DATA_B (INT_SUM[228]), .DATA_C (INT_SUM[229]), .SAVE (INT_SUM[233]), .CARRY (INT_CARRY[189]) );
smfulladder dfa163 (.DATA_A (INT_SUM[230]), .DATA_B (INT_SUM[231]), .DATA_C (INT_SUM[232]), .SAVE (INT_SUM[234]), .CARRY (INT_CARRY[190]) );
smfulladder dfa164 (.DATA_A (INT_CARRY[171]), .DATA_B (INT_CARRY[172]), .DATA_C (INT_CARRY[173]), .SAVE (INT_SUM[235]), .CARRY (INT_CARRY[191]) );
assign INT_SUM[236] = INT_CARRY[174];
assign INT_SUM[237] = INT_CARRY[175];
smfulladder dfa165 (.DATA_A (INT_SUM[233]), .DATA_B (INT_SUM[234]), .DATA_C (INT_SUM[235]), .SAVE (INT_SUM[238]), .CARRY (INT_CARRY[192]) );
smfulladder dfa166 (.DATA_A (INT_SUM[236]), .DATA_B (INT_SUM[237]), .DATA_C (INT_CARRY[176]), .SAVE (INT_SUM[239]), .CARRY (INT_CARRY[193]) );
assign INT_SUM[240] = INT_CARRY[177];
assign INT_SUM[241] = INT_CARRY[178];
smfulladder dfa167 (.DATA_A (INT_SUM[238]), .DATA_B (INT_SUM[239]), .DATA_C (INT_SUM[240]), .SAVE (INT_SUM[242]), .CARRY (INT_CARRY[194]) );
smfulladder dfa168 (.DATA_A (INT_SUM[241]), .DATA_B (INT_CARRY[179]), .DATA_C (INT_CARRY[180]), .SAVE (INT_SUM[243]), .CARRY (INT_CARRY[195]) );
smfulladder dfa169 (.DATA_A (INT_SUM[242]), .DATA_B (INT_SUM[243]), .DATA_C (INT_CARRY[181]), .SAVE (INT_SUM[244]), .CARRY (INT_CARRY[196]) );
smhalfadder dha26 (.DATA_A (INT_SUM[244]), .DATA_B (INT_CARRY[182]), .SAVE (INT_SUM[245]), .CARRY (INT_CARRY[183]) );
smffb dla295 (.D(INT_SUM[245]), .clk(clk), .en_d2(en_d2), .Q(SUM[28]) );
smffb dla296 (.D(INT_CARRY[183]), .clk(clk), .en_d2(en_d2), .Q(CARRY[28]) );
smffa dla297 (.D(SUMMAND[240]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[240]) );
smffa dla298 (.D(SUMMAND[241]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[241]) );
smffa dla299 (.D(SUMMAND[242]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[242]) );
smfulladder dfa170 (.DATA_A (LATCHED_PP[240]), .DATA_B (LATCHED_PP[241]), .DATA_C (LATCHED_PP[242]), .SAVE (INT_SUM[246]), .CARRY (INT_CARRY[198]) );
smffa dla300 (.D(SUMMAND[243]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[243]) );
smffa dla301 (.D(SUMMAND[244]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[244]) );
smffa dla302 (.D(SUMMAND[245]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[245]) );
smfulladder dfa171 (.DATA_A (LATCHED_PP[243]), .DATA_B (LATCHED_PP[244]), .DATA_C (LATCHED_PP[245]), .SAVE (INT_SUM[247]), .CARRY (INT_CARRY[199]) );
smffa dla303 (.D(SUMMAND[246]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[246]) );
smffa dla304 (.D(SUMMAND[247]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[247]) );
smffa dla305 (.D(SUMMAND[248]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[248]) );
smfulladder dfa172 (.DATA_A (LATCHED_PP[246]), .DATA_B (LATCHED_PP[247]), .DATA_C (LATCHED_PP[248]), .SAVE (INT_SUM[248]), .CARRY (INT_CARRY[200]) );
smffa dla306 (.D(SUMMAND[249]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[249]) );
smffa dla307 (.D(SUMMAND[250]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[250]) );
smffa dla308 (.D(SUMMAND[251]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[251]) );
smfulladder dfa173 (.DATA_A (LATCHED_PP[249]), .DATA_B (LATCHED_PP[250]), .DATA_C (LATCHED_PP[251]), .SAVE (INT_SUM[249]), .CARRY (INT_CARRY[201]) );
smffa dla309 (.D(SUMMAND[252]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[252]) );
smffa dla310 (.D(SUMMAND[253]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[253]) );
smffa dla311 (.D(SUMMAND[254]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[254]) );
smfulladder dfa174 (.DATA_A (LATCHED_PP[252]), .DATA_B (LATCHED_PP[253]), .DATA_C (LATCHED_PP[254]), .SAVE (INT_SUM[250]), .CARRY (INT_CARRY[202]) );
smfulladder dfa175 (.DATA_A (INT_SUM[246]), .DATA_B (INT_SUM[247]), .DATA_C (INT_SUM[248]), .SAVE (INT_SUM[251]), .CARRY (INT_CARRY[203]) );
smfulladder dfa176 (.DATA_A (INT_SUM[249]), .DATA_B (INT_SUM[250]), .DATA_C (INT_CARRY[184]), .SAVE (INT_SUM[252]), .CARRY (INT_CARRY[204]) );
smfulladder dfa177 (.DATA_A (INT_CARRY[185]), .DATA_B (INT_CARRY[186]), .DATA_C (INT_CARRY[187]), .SAVE (INT_SUM[253]), .CARRY (INT_CARRY[205]) );
assign INT_SUM[254] = INT_CARRY[188];
smfulladder dfa178 (.DATA_A (INT_SUM[251]), .DATA_B (INT_SUM[252]), .DATA_C (INT_SUM[253]), .SAVE (INT_SUM[255]), .CARRY (INT_CARRY[206]) );
smfulladder dfa179 (.DATA_A (INT_SUM[254]), .DATA_B (INT_CARRY[189]), .DATA_C (INT_CARRY[190]), .SAVE (INT_SUM[256]), .CARRY (INT_CARRY[207]) );
assign INT_SUM[257] = INT_CARRY[191];
smfulladder dfa180 (.DATA_A (INT_SUM[255]), .DATA_B (INT_SUM[256]), .DATA_C (INT_SUM[257]), .SAVE (INT_SUM[258]), .CARRY (INT_CARRY[208]) );
smhalfadder dha27 (.DATA_A (INT_CARRY[192]), .DATA_B (INT_CARRY[193]), .SAVE (INT_SUM[259]), .CARRY (INT_CARRY[209]) );
smfulladder dfa181 (.DATA_A (INT_SUM[258]), .DATA_B (INT_SUM[259]), .DATA_C (INT_CARRY[194]), .SAVE (INT_SUM[260]), .CARRY (INT_CARRY[210]) );
assign INT_SUM[261] = INT_CARRY[195];
smfulladder dfa182 (.DATA_A (INT_SUM[260]), .DATA_B (INT_SUM[261]), .DATA_C (INT_CARRY[196]), .SAVE (INT_SUM[262]), .CARRY (INT_CARRY[197]) );
smffb dla312 (.D(INT_SUM[262]), .clk(clk), .en_d2(en_d2), .Q(SUM[29]) );
smffb dla313 (.D(INT_CARRY[197]), .clk(clk), .en_d2(en_d2), .Q(CARRY[29]) );
smffa dla314 (.D(SUMMAND[255]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[255]) );
smffa dla315 (.D(SUMMAND[256]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[256]) );
smffa dla316 (.D(SUMMAND[257]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[257]) );
smfulladder dfa183 (.DATA_A (LATCHED_PP[255]), .DATA_B (LATCHED_PP[256]), .DATA_C (LATCHED_PP[257]), .SAVE (INT_SUM[263]), .CARRY (INT_CARRY[212]) );
smffa dla317 (.D(SUMMAND[258]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[258]) );
smffa dla318 (.D(SUMMAND[259]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[259]) );
smffa dla319 (.D(SUMMAND[260]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[260]) );
smfulladder dfa184 (.DATA_A (LATCHED_PP[258]), .DATA_B (LATCHED_PP[259]), .DATA_C (LATCHED_PP[260]), .SAVE (INT_SUM[264]), .CARRY (INT_CARRY[213]) );
smffa dla320 (.D(SUMMAND[261]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[261]) );
smffa dla321 (.D(SUMMAND[262]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[262]) );
smffa dla322 (.D(SUMMAND[263]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[263]) );
smfulladder dfa185 (.DATA_A (LATCHED_PP[261]), .DATA_B (LATCHED_PP[262]), .DATA_C (LATCHED_PP[263]), .SAVE (INT_SUM[265]), .CARRY (INT_CARRY[214]) );
smffa dla323 (.D(SUMMAND[264]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[264]) );
smffa dla324 (.D(SUMMAND[265]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[265]) );
smffa dla325 (.D(SUMMAND[266]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[266]) );
smfulladder dfa186 (.DATA_A (LATCHED_PP[264]), .DATA_B (LATCHED_PP[265]), .DATA_C (LATCHED_PP[266]), .SAVE (INT_SUM[266]), .CARRY (INT_CARRY[215]) );
smffa dla326 (.D(SUMMAND[267]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[267]) );
smffa dla327 (.D(SUMMAND[268]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[268]) );
smffa dla328 (.D(SUMMAND[269]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[269]) );
smfulladder dfa187 (.DATA_A (LATCHED_PP[267]), .DATA_B (LATCHED_PP[268]), .DATA_C (LATCHED_PP[269]), .SAVE (INT_SUM[267]), .CARRY (INT_CARRY[216]) );
smffa dla329 (.D(SUMMAND[270]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[270]) );
assign INT_SUM[268] = LATCHED_PP[270];
smffa dla330 (.D(SUMMAND[271]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[271]) );
assign INT_SUM[269] = LATCHED_PP[271];
smfulladder dfa188 (.DATA_A (INT_SUM[263]), .DATA_B (INT_SUM[264]), .DATA_C (INT_SUM[265]), .SAVE (INT_SUM[270]), .CARRY (INT_CARRY[217]) );
smfulladder dfa189 (.DATA_A (INT_SUM[266]), .DATA_B (INT_SUM[267]), .DATA_C (INT_SUM[268]), .SAVE (INT_SUM[271]), .CARRY (INT_CARRY[218]) );
smfulladder dfa190 (.DATA_A (INT_SUM[269]), .DATA_B (INT_CARRY[198]), .DATA_C (INT_CARRY[199]), .SAVE (INT_SUM[272]), .CARRY (INT_CARRY[219]) );
smfulladder dfa191 (.DATA_A (INT_CARRY[200]), .DATA_B (INT_CARRY[201]), .DATA_C (INT_CARRY[202]), .SAVE (INT_SUM[273]), .CARRY (INT_CARRY[220]) );
smfulladder dfa192 (.DATA_A (INT_SUM[270]), .DATA_B (INT_SUM[271]), .DATA_C (INT_SUM[272]), .SAVE (INT_SUM[274]), .CARRY (INT_CARRY[221]) );
smfulladder dfa193 (.DATA_A (INT_SUM[273]), .DATA_B (INT_CARRY[203]), .DATA_C (INT_CARRY[204]), .SAVE (INT_SUM[275]), .CARRY (INT_CARRY[222]) );
assign INT_SUM[276] = INT_CARRY[205];
smfulladder dfa194 (.DATA_A (INT_SUM[274]), .DATA_B (INT_SUM[275]), .DATA_C (INT_SUM[276]), .SAVE (INT_SUM[277]), .CARRY (INT_CARRY[223]) );
smhalfadder dha28 (.DATA_A (INT_CARRY[206]), .DATA_B (INT_CARRY[207]), .SAVE (INT_SUM[278]), .CARRY (INT_CARRY[224]) );
smfulladder dfa195 (.DATA_A (INT_SUM[277]), .DATA_B (INT_SUM[278]), .DATA_C (INT_CARRY[208]), .SAVE (INT_SUM[279]), .CARRY (INT_CARRY[225]) );
assign INT_SUM[280] = INT_CARRY[209];
smfulladder dfa196 (.DATA_A (INT_SUM[279]), .DATA_B (INT_SUM[280]), .DATA_C (INT_CARRY[210]), .SAVE (INT_SUM[281]), .CARRY (INT_CARRY[211]) );
smffb dla331 (.D(INT_SUM[281]), .clk(clk), .en_d2(en_d2), .Q(SUM[30]) );
smffb dla332 (.D(INT_CARRY[211]), .clk(clk), .en_d2(en_d2), .Q(CARRY[30]) );
smffa dla333 (.D(SUMMAND[272]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[272]) );
smffa dla334 (.D(SUMMAND[273]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[273]) );
smffa dla335 (.D(SUMMAND[274]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[274]) );
smfulladder dfa197 (.DATA_A (LATCHED_PP[272]), .DATA_B (LATCHED_PP[273]), .DATA_C (LATCHED_PP[274]), .SAVE (INT_SUM[282]), .CARRY (INT_CARRY[227]) );
smffa dla336 (.D(SUMMAND[275]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[275]) );
smffa dla337 (.D(SUMMAND[276]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[276]) );
smffa dla338 (.D(SUMMAND[277]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[277]) );
smfulladder dfa198 (.DATA_A (LATCHED_PP[275]), .DATA_B (LATCHED_PP[276]), .DATA_C (LATCHED_PP[277]), .SAVE (INT_SUM[283]), .CARRY (INT_CARRY[228]) );
smffa dla339 (.D(SUMMAND[278]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[278]) );
smffa dla340 (.D(SUMMAND[279]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[279]) );
smffa dla341 (.D(SUMMAND[280]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[280]) );
smfulladder dfa199 (.DATA_A (LATCHED_PP[278]), .DATA_B (LATCHED_PP[279]), .DATA_C (LATCHED_PP[280]), .SAVE (INT_SUM[284]), .CARRY (INT_CARRY[229]) );
smffa dla342 (.D(SUMMAND[281]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[281]) );
smffa dla343 (.D(SUMMAND[282]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[282]) );
smffa dla344 (.D(SUMMAND[283]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[283]) );
smfulladder dfa200 (.DATA_A (LATCHED_PP[281]), .DATA_B (LATCHED_PP[282]), .DATA_C (LATCHED_PP[283]), .SAVE (INT_SUM[285]), .CARRY (INT_CARRY[230]) );
smffa dla345 (.D(SUMMAND[284]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[284]) );
smffa dla346 (.D(SUMMAND[285]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[285]) );
smffa dla347 (.D(SUMMAND[286]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[286]) );
smfulladder dfa201 (.DATA_A (LATCHED_PP[284]), .DATA_B (LATCHED_PP[285]), .DATA_C (LATCHED_PP[286]), .SAVE (INT_SUM[286]), .CARRY (INT_CARRY[231]) );
smffa dla348 (.D(SUMMAND[287]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[287]) );
assign INT_SUM[287] = LATCHED_PP[287];
smfulladder dfa202 (.DATA_A (INT_SUM[282]), .DATA_B (INT_SUM[283]), .DATA_C (INT_SUM[284]), .SAVE (INT_SUM[288]), .CARRY (INT_CARRY[232]) );
smfulladder dfa203 (.DATA_A (INT_SUM[285]), .DATA_B (INT_SUM[286]), .DATA_C (INT_SUM[287]), .SAVE (INT_SUM[289]), .CARRY (INT_CARRY[233]) );
smfulladder dfa204 (.DATA_A (INT_CARRY[212]), .DATA_B (INT_CARRY[213]), .DATA_C (INT_CARRY[214]), .SAVE (INT_SUM[290]), .CARRY (INT_CARRY[234]) );
assign INT_SUM[291] = INT_CARRY[215];
assign INT_SUM[292] = INT_CARRY[216];
smfulladder dfa205 (.DATA_A (INT_SUM[288]), .DATA_B (INT_SUM[289]), .DATA_C (INT_SUM[290]), .SAVE (INT_SUM[293]), .CARRY (INT_CARRY[235]) );
smfulladder dfa206 (.DATA_A (INT_SUM[291]), .DATA_B (INT_SUM[292]), .DATA_C (INT_CARRY[217]), .SAVE (INT_SUM[294]), .CARRY (INT_CARRY[236]) );
smfulladder dfa207 (.DATA_A (INT_CARRY[218]), .DATA_B (INT_CARRY[219]), .DATA_C (INT_CARRY[220]), .SAVE (INT_SUM[295]), .CARRY (INT_CARRY[237]) );
smfulladder dfa208 (.DATA_A (INT_SUM[293]), .DATA_B (INT_SUM[294]), .DATA_C (INT_SUM[295]), .SAVE (INT_SUM[296]), .CARRY (INT_CARRY[238]) );
smhalfadder dha29 (.DATA_A (INT_CARRY[221]), .DATA_B (INT_CARRY[222]), .SAVE (INT_SUM[297]), .CARRY (INT_CARRY[239]) );
smfulladder dfa209 (.DATA_A (INT_SUM[296]), .DATA_B (INT_SUM[297]), .DATA_C (INT_CARRY[223]), .SAVE (INT_SUM[298]), .CARRY (INT_CARRY[240]) );
assign INT_SUM[299] = INT_CARRY[224];
smfulladder dfa210 (.DATA_A (INT_SUM[298]), .DATA_B (INT_SUM[299]), .DATA_C (INT_CARRY[225]), .SAVE (INT_SUM[300]), .CARRY (INT_CARRY[226]) );
smffb dla349 (.D(INT_SUM[300]), .clk(clk), .en_d2(en_d2), .Q(SUM[31]) );
smffb dla350 (.D(INT_CARRY[226]), .clk(clk), .en_d2(en_d2), .Q(CARRY[31]) );
smffa dla351 (.D(SUMMAND[288]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[288]) );
smffa dla352 (.D(SUMMAND[289]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[289]) );
smffa dla353 (.D(SUMMAND[290]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[290]) );
smfulladder dfa211 (.DATA_A (LATCHED_PP[288]), .DATA_B (LATCHED_PP[289]), .DATA_C (LATCHED_PP[290]), .SAVE (INT_SUM[301]), .CARRY (INT_CARRY[242]) );
smffa dla354 (.D(SUMMAND[291]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[291]) );
smffa dla355 (.D(SUMMAND[292]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[292]) );
smffa dla356 (.D(SUMMAND[293]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[293]) );
smfulladder dfa212 (.DATA_A (LATCHED_PP[291]), .DATA_B (LATCHED_PP[292]), .DATA_C (LATCHED_PP[293]), .SAVE (INT_SUM[302]), .CARRY (INT_CARRY[243]) );
smffa dla357 (.D(SUMMAND[294]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[294]) );
smffa dla358 (.D(SUMMAND[295]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[295]) );
smffa dla359 (.D(SUMMAND[296]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[296]) );
smfulladder dfa213 (.DATA_A (LATCHED_PP[294]), .DATA_B (LATCHED_PP[295]), .DATA_C (LATCHED_PP[296]), .SAVE (INT_SUM[303]), .CARRY (INT_CARRY[244]) );
smffa dla360 (.D(SUMMAND[297]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[297]) );
smffa dla361 (.D(SUMMAND[298]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[298]) );
smffa dla362 (.D(SUMMAND[299]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[299]) );
smfulladder dfa214 (.DATA_A (LATCHED_PP[297]), .DATA_B (LATCHED_PP[298]), .DATA_C (LATCHED_PP[299]), .SAVE (INT_SUM[304]), .CARRY (INT_CARRY[245]) );
smffa dla363 (.D(SUMMAND[300]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[300]) );
smffa dla364 (.D(SUMMAND[301]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[301]) );
smffa dla365 (.D(SUMMAND[302]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[302]) );
smfulladder dfa215 (.DATA_A (LATCHED_PP[300]), .DATA_B (LATCHED_PP[301]), .DATA_C (LATCHED_PP[302]), .SAVE (INT_SUM[305]), .CARRY (INT_CARRY[246]) );
smffa dla366 (.D(SUMMAND[303]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[303]) );
smffa dla367 (.D(SUMMAND[304]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[304]) );
smffa dla368 (.D(SUMMAND[305]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[305]) );
smfulladder dfa216 (.DATA_A (LATCHED_PP[303]), .DATA_B (LATCHED_PP[304]), .DATA_C (LATCHED_PP[305]), .SAVE (INT_SUM[306]), .CARRY (INT_CARRY[247]) );
smfulladder dfa217 (.DATA_A (INT_SUM[301]), .DATA_B (INT_SUM[302]), .DATA_C (INT_SUM[303]), .SAVE (INT_SUM[307]), .CARRY (INT_CARRY[248]) );
smfulladder dfa218 (.DATA_A (INT_SUM[304]), .DATA_B (INT_SUM[305]), .DATA_C (INT_SUM[306]), .SAVE (INT_SUM[308]), .CARRY (INT_CARRY[249]) );
smfulladder dfa219 (.DATA_A (INT_CARRY[227]), .DATA_B (INT_CARRY[228]), .DATA_C (INT_CARRY[229]), .SAVE (INT_SUM[309]), .CARRY (INT_CARRY[250]) );
smhalfadder dha30 (.DATA_A (INT_CARRY[230]), .DATA_B (INT_CARRY[231]), .SAVE (INT_SUM[310]), .CARRY (INT_CARRY[251]) );
smfulladder dfa220 (.DATA_A (INT_SUM[307]), .DATA_B (INT_SUM[308]), .DATA_C (INT_SUM[309]), .SAVE (INT_SUM[311]), .CARRY (INT_CARRY[252]) );
smfulladder dfa221 (.DATA_A (INT_SUM[310]), .DATA_B (INT_CARRY[232]), .DATA_C (INT_CARRY[233]), .SAVE (INT_SUM[312]), .CARRY (INT_CARRY[253]) );
assign INT_SUM[313] = INT_CARRY[234];
smfulladder dfa222 (.DATA_A (INT_SUM[311]), .DATA_B (INT_SUM[312]), .DATA_C (INT_SUM[313]), .SAVE (INT_SUM[314]), .CARRY (INT_CARRY[254]) );
smfulladder dfa223 (.DATA_A (INT_CARRY[235]), .DATA_B (INT_CARRY[236]), .DATA_C (INT_CARRY[237]), .SAVE (INT_SUM[315]), .CARRY (INT_CARRY[255]) );
smfulladder dfa224 (.DATA_A (INT_SUM[314]), .DATA_B (INT_SUM[315]), .DATA_C (INT_CARRY[238]), .SAVE (INT_SUM[316]), .CARRY (INT_CARRY[256]) );
assign INT_SUM[317] = INT_CARRY[239];
smfulladder dfa225 (.DATA_A (INT_SUM[316]), .DATA_B (INT_SUM[317]), .DATA_C (INT_CARRY[240]), .SAVE (INT_SUM[318]), .CARRY (INT_CARRY[241]) );
smffb dla369 (.D(INT_SUM[318]), .clk(clk), .en_d2(en_d2), .Q(SUM[32]) );
smffb dla370 (.D(INT_CARRY[241]), .clk(clk), .en_d2(en_d2), .Q(CARRY[32]) );
smffa dla371 (.D(SUMMAND[306]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[306]) );
smffa dla372 (.D(SUMMAND[307]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[307]) );
smffa dla373 (.D(SUMMAND[308]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[308]) );
smfulladder dfa226 (.DATA_A (LATCHED_PP[306]), .DATA_B (LATCHED_PP[307]), .DATA_C (LATCHED_PP[308]), .SAVE (INT_SUM[319]), .CARRY (INT_CARRY[258]) );
smffa dla374 (.D(SUMMAND[309]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[309]) );
smffa dla375 (.D(SUMMAND[310]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[310]) );
smffa dla376 (.D(SUMMAND[311]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[311]) );
smfulladder dfa227 (.DATA_A (LATCHED_PP[309]), .DATA_B (LATCHED_PP[310]), .DATA_C (LATCHED_PP[311]), .SAVE (INT_SUM[320]), .CARRY (INT_CARRY[259]) );
smffa dla377 (.D(SUMMAND[312]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[312]) );
smffa dla378 (.D(SUMMAND[313]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[313]) );
smffa dla379 (.D(SUMMAND[314]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[314]) );
smfulladder dfa228 (.DATA_A (LATCHED_PP[312]), .DATA_B (LATCHED_PP[313]), .DATA_C (LATCHED_PP[314]), .SAVE (INT_SUM[321]), .CARRY (INT_CARRY[260]) );
smffa dla380 (.D(SUMMAND[315]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[315]) );
smffa dla381 (.D(SUMMAND[316]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[316]) );
smffa dla382 (.D(SUMMAND[317]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[317]) );
smfulladder dfa229 (.DATA_A (LATCHED_PP[315]), .DATA_B (LATCHED_PP[316]), .DATA_C (LATCHED_PP[317]), .SAVE (INT_SUM[322]), .CARRY (INT_CARRY[261]) );
smffa dla383 (.D(SUMMAND[318]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[318]) );
smffa dla384 (.D(SUMMAND[319]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[319]) );
smffa dla385 (.D(SUMMAND[320]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[320]) );
smfulladder dfa230 (.DATA_A (LATCHED_PP[318]), .DATA_B (LATCHED_PP[319]), .DATA_C (LATCHED_PP[320]), .SAVE (INT_SUM[323]), .CARRY (INT_CARRY[262]) );
smffa dla386 (.D(SUMMAND[321]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[321]) );
assign INT_SUM[324] = LATCHED_PP[321];
smffa dla387 (.D(SUMMAND[322]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[322]) );
assign INT_SUM[325] = LATCHED_PP[322];
smfulladder dfa231 (.DATA_A (INT_SUM[319]), .DATA_B (INT_SUM[320]), .DATA_C (INT_SUM[321]), .SAVE (INT_SUM[326]), .CARRY (INT_CARRY[263]) );
smfulladder dfa232 (.DATA_A (INT_SUM[322]), .DATA_B (INT_SUM[323]), .DATA_C (INT_SUM[324]), .SAVE (INT_SUM[327]), .CARRY (INT_CARRY[264]) );
smfulladder dfa233 (.DATA_A (INT_SUM[325]), .DATA_B (INT_CARRY[242]), .DATA_C (INT_CARRY[243]), .SAVE (INT_SUM[328]), .CARRY (INT_CARRY[265]) );
smfulladder dfa234 (.DATA_A (INT_CARRY[244]), .DATA_B (INT_CARRY[245]), .DATA_C (INT_CARRY[246]), .SAVE (INT_SUM[329]), .CARRY (INT_CARRY[266]) );
assign INT_SUM[330] = INT_CARRY[247];
smfulladder dfa235 (.DATA_A (INT_SUM[326]), .DATA_B (INT_SUM[327]), .DATA_C (INT_SUM[328]), .SAVE (INT_SUM[331]), .CARRY (INT_CARRY[267]) );
smfulladder dfa236 (.DATA_A (INT_SUM[329]), .DATA_B (INT_SUM[330]), .DATA_C (INT_CARRY[248]), .SAVE (INT_SUM[332]), .CARRY (INT_CARRY[268]) );
smfulladder dfa237 (.DATA_A (INT_CARRY[249]), .DATA_B (INT_CARRY[250]), .DATA_C (INT_CARRY[251]), .SAVE (INT_SUM[333]), .CARRY (INT_CARRY[269]) );
smfulladder dfa238 (.DATA_A (INT_SUM[331]), .DATA_B (INT_SUM[332]), .DATA_C (INT_SUM[333]), .SAVE (INT_SUM[334]), .CARRY (INT_CARRY[270]) );
smhalfadder dha31 (.DATA_A (INT_CARRY[252]), .DATA_B (INT_CARRY[253]), .SAVE (INT_SUM[335]), .CARRY (INT_CARRY[271]) );
smfulladder dfa239 (.DATA_A (INT_SUM[334]), .DATA_B (INT_SUM[335]), .DATA_C (INT_CARRY[254]), .SAVE (INT_SUM[336]), .CARRY (INT_CARRY[272]) );
assign INT_SUM[337] = INT_CARRY[255];
smfulladder dfa240 (.DATA_A (INT_SUM[336]), .DATA_B (INT_SUM[337]), .DATA_C (INT_CARRY[256]), .SAVE (INT_SUM[338]), .CARRY (INT_CARRY[257]) );
smffb dla388 (.D(INT_SUM[338]), .clk(clk), .en_d2(en_d2), .Q(SUM[33]) );
smffb dla389 (.D(INT_CARRY[257]), .clk(clk), .en_d2(en_d2), .Q(CARRY[33]) );
smffa dla390 (.D(SUMMAND[323]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[323]) );
smffa dla391 (.D(SUMMAND[324]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[324]) );
smffa dla392 (.D(SUMMAND[325]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[325]) );
smfulladder dfa241 (.DATA_A (LATCHED_PP[323]), .DATA_B (LATCHED_PP[324]), .DATA_C (LATCHED_PP[325]), .SAVE (INT_SUM[339]), .CARRY (INT_CARRY[274]) );
smffa dla393 (.D(SUMMAND[326]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[326]) );
smffa dla394 (.D(SUMMAND[327]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[327]) );
smffa dla395 (.D(SUMMAND[328]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[328]) );
smfulladder dfa242 (.DATA_A (LATCHED_PP[326]), .DATA_B (LATCHED_PP[327]), .DATA_C (LATCHED_PP[328]), .SAVE (INT_SUM[340]), .CARRY (INT_CARRY[275]) );
smffa dla396 (.D(SUMMAND[329]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[329]) );
smffa dla397 (.D(SUMMAND[330]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[330]) );
smffa dla398 (.D(SUMMAND[331]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[331]) );
smfulladder dfa243 (.DATA_A (LATCHED_PP[329]), .DATA_B (LATCHED_PP[330]), .DATA_C (LATCHED_PP[331]), .SAVE (INT_SUM[341]), .CARRY (INT_CARRY[276]) );
smffa dla399 (.D(SUMMAND[332]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[332]) );
smffa dla400 (.D(SUMMAND[333]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[333]) );
smffa dla401 (.D(SUMMAND[334]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[334]) );
smfulladder dfa244 (.DATA_A (LATCHED_PP[332]), .DATA_B (LATCHED_PP[333]), .DATA_C (LATCHED_PP[334]), .SAVE (INT_SUM[342]), .CARRY (INT_CARRY[277]) );
smffa dla402 (.D(SUMMAND[335]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[335]) );
smffa dla403 (.D(SUMMAND[336]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[336]) );
smffa dla404 (.D(SUMMAND[337]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[337]) );
smfulladder dfa245 (.DATA_A (LATCHED_PP[335]), .DATA_B (LATCHED_PP[336]), .DATA_C (LATCHED_PP[337]), .SAVE (INT_SUM[343]), .CARRY (INT_CARRY[278]) );
smffa dla405 (.D(SUMMAND[338]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[338]) );
smffa dla406 (.D(SUMMAND[339]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[339]) );
smffa dla407 (.D(SUMMAND[340]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[340]) );
smfulladder dfa246 (.DATA_A (LATCHED_PP[338]), .DATA_B (LATCHED_PP[339]), .DATA_C (LATCHED_PP[340]), .SAVE (INT_SUM[344]), .CARRY (INT_CARRY[279]) );
smfulladder dfa247 (.DATA_A (INT_SUM[339]), .DATA_B (INT_SUM[340]), .DATA_C (INT_SUM[341]), .SAVE (INT_SUM[345]), .CARRY (INT_CARRY[280]) );
smfulladder dfa248 (.DATA_A (INT_SUM[342]), .DATA_B (INT_SUM[343]), .DATA_C (INT_SUM[344]), .SAVE (INT_SUM[346]), .CARRY (INT_CARRY[281]) );
smfulladder dfa249 (.DATA_A (INT_CARRY[258]), .DATA_B (INT_CARRY[259]), .DATA_C (INT_CARRY[260]), .SAVE (INT_SUM[347]), .CARRY (INT_CARRY[282]) );
assign INT_SUM[348] = INT_CARRY[261];
assign INT_SUM[349] = INT_CARRY[262];
smfulladder dfa250 (.DATA_A (INT_SUM[345]), .DATA_B (INT_SUM[346]), .DATA_C (INT_SUM[347]), .SAVE (INT_SUM[350]), .CARRY (INT_CARRY[283]) );
smfulladder dfa251 (.DATA_A (INT_SUM[348]), .DATA_B (INT_SUM[349]), .DATA_C (INT_CARRY[263]), .SAVE (INT_SUM[351]), .CARRY (INT_CARRY[284]) );
smfulladder dfa252 (.DATA_A (INT_CARRY[264]), .DATA_B (INT_CARRY[265]), .DATA_C (INT_CARRY[266]), .SAVE (INT_SUM[352]), .CARRY (INT_CARRY[285]) );
smfulladder dfa253 (.DATA_A (INT_SUM[350]), .DATA_B (INT_SUM[351]), .DATA_C (INT_SUM[352]), .SAVE (INT_SUM[353]), .CARRY (INT_CARRY[286]) );
smfulladder dfa254 (.DATA_A (INT_CARRY[267]), .DATA_B (INT_CARRY[268]), .DATA_C (INT_CARRY[269]), .SAVE (INT_SUM[354]), .CARRY (INT_CARRY[287]) );
smfulladder dfa255 (.DATA_A (INT_SUM[353]), .DATA_B (INT_SUM[354]), .DATA_C (INT_CARRY[270]), .SAVE (INT_SUM[355]), .CARRY (INT_CARRY[288]) );
assign INT_SUM[356] = INT_CARRY[271];
smfulladder dfa256 (.DATA_A (INT_SUM[355]), .DATA_B (INT_SUM[356]), .DATA_C (INT_CARRY[272]), .SAVE (INT_SUM[357]), .CARRY (INT_CARRY[273]) );
smffb dla408 (.D(INT_SUM[357]), .clk(clk), .en_d2(en_d2), .Q(SUM[34]) );
smffb dla409 (.D(INT_CARRY[273]), .clk(clk), .en_d2(en_d2), .Q(CARRY[34]) );
smffa dla410 (.D(SUMMAND[341]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[341]) );
smffa dla411 (.D(SUMMAND[342]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[342]) );
smffa dla412 (.D(SUMMAND[343]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[343]) );
smfulladder dfa257 (.DATA_A (LATCHED_PP[341]), .DATA_B (LATCHED_PP[342]), .DATA_C (LATCHED_PP[343]), .SAVE (INT_SUM[358]), .CARRY (INT_CARRY[290]) );
smffa dla413 (.D(SUMMAND[344]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[344]) );
smffa dla414 (.D(SUMMAND[345]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[345]) );
smffa dla415 (.D(SUMMAND[346]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[346]) );
smfulladder dfa258 (.DATA_A (LATCHED_PP[344]), .DATA_B (LATCHED_PP[345]), .DATA_C (LATCHED_PP[346]), .SAVE (INT_SUM[359]), .CARRY (INT_CARRY[291]) );
smffa dla416 (.D(SUMMAND[347]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[347]) );
smffa dla417 (.D(SUMMAND[348]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[348]) );
smffa dla418 (.D(SUMMAND[349]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[349]) );
smfulladder dfa259 (.DATA_A (LATCHED_PP[347]), .DATA_B (LATCHED_PP[348]), .DATA_C (LATCHED_PP[349]), .SAVE (INT_SUM[360]), .CARRY (INT_CARRY[292]) );
smffa dla419 (.D(SUMMAND[350]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[350]) );
smffa dla420 (.D(SUMMAND[351]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[351]) );
smffa dla421 (.D(SUMMAND[352]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[352]) );
smfulladder dfa260 (.DATA_A (LATCHED_PP[350]), .DATA_B (LATCHED_PP[351]), .DATA_C (LATCHED_PP[352]), .SAVE (INT_SUM[361]), .CARRY (INT_CARRY[293]) );
smffa dla422 (.D(SUMMAND[353]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[353]) );
smffa dla423 (.D(SUMMAND[354]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[354]) );
smffa dla424 (.D(SUMMAND[355]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[355]) );
smfulladder dfa261 (.DATA_A (LATCHED_PP[353]), .DATA_B (LATCHED_PP[354]), .DATA_C (LATCHED_PP[355]), .SAVE (INT_SUM[362]), .CARRY (INT_CARRY[294]) );
smffa dla425 (.D(SUMMAND[356]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[356]) );
smffa dla426 (.D(SUMMAND[357]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[357]) );
smhalfadder dha32 (.DATA_A (LATCHED_PP[356]), .DATA_B (LATCHED_PP[357]), .SAVE (INT_SUM[363]), .CARRY (INT_CARRY[295]) );
smfulladder dfa262 (.DATA_A (INT_SUM[358]), .DATA_B (INT_SUM[359]), .DATA_C (INT_SUM[360]), .SAVE (INT_SUM[364]), .CARRY (INT_CARRY[296]) );
smfulladder dfa263 (.DATA_A (INT_SUM[361]), .DATA_B (INT_SUM[362]), .DATA_C (INT_SUM[363]), .SAVE (INT_SUM[365]), .CARRY (INT_CARRY[297]) );
smfulladder dfa264 (.DATA_A (INT_CARRY[274]), .DATA_B (INT_CARRY[275]), .DATA_C (INT_CARRY[276]), .SAVE (INT_SUM[366]), .CARRY (INT_CARRY[298]) );
smfulladder dfa265 (.DATA_A (INT_CARRY[277]), .DATA_B (INT_CARRY[278]), .DATA_C (INT_CARRY[279]), .SAVE (INT_SUM[367]), .CARRY (INT_CARRY[299]) );
smfulladder dfa266 (.DATA_A (INT_SUM[364]), .DATA_B (INT_SUM[365]), .DATA_C (INT_SUM[366]), .SAVE (INT_SUM[368]), .CARRY (INT_CARRY[300]) );
smfulladder dfa267 (.DATA_A (INT_SUM[367]), .DATA_B (INT_CARRY[280]), .DATA_C (INT_CARRY[281]), .SAVE (INT_SUM[369]), .CARRY (INT_CARRY[301]) );
assign INT_SUM[370] = INT_CARRY[282];
smfulladder dfa268 (.DATA_A (INT_SUM[368]), .DATA_B (INT_SUM[369]), .DATA_C (INT_SUM[370]), .SAVE (INT_SUM[371]), .CARRY (INT_CARRY[302]) );
smfulladder dfa269 (.DATA_A (INT_CARRY[283]), .DATA_B (INT_CARRY[284]), .DATA_C (INT_CARRY[285]), .SAVE (INT_SUM[372]), .CARRY (INT_CARRY[303]) );
smfulladder dfa270 (.DATA_A (INT_SUM[371]), .DATA_B (INT_SUM[372]), .DATA_C (INT_CARRY[286]), .SAVE (INT_SUM[373]), .CARRY (INT_CARRY[304]) );
assign INT_SUM[374] = INT_CARRY[287];
smfulladder dfa271 (.DATA_A (INT_SUM[373]), .DATA_B (INT_SUM[374]), .DATA_C (INT_CARRY[288]), .SAVE (INT_SUM[375]), .CARRY (INT_CARRY[289]) );
smffb dla427 (.D(INT_SUM[375]), .clk(clk), .en_d2(en_d2), .Q(SUM[35]) );
smffb dla428 (.D(INT_CARRY[289]), .clk(clk), .en_d2(en_d2), .Q(CARRY[35]) );
smffa dla429 (.D(SUMMAND[358]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[358]) );
smffa dla430 (.D(SUMMAND[359]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[359]) );
smffa dla431 (.D(SUMMAND[360]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[360]) );
smfulladder dfa272 (.DATA_A (LATCHED_PP[358]), .DATA_B (LATCHED_PP[359]), .DATA_C (LATCHED_PP[360]), .SAVE (INT_SUM[376]), .CARRY (INT_CARRY[306]) );
smffa dla432 (.D(SUMMAND[361]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[361]) );
smffa dla433 (.D(SUMMAND[362]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[362]) );
smffa dla434 (.D(SUMMAND[363]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[363]) );
smfulladder dfa273 (.DATA_A (LATCHED_PP[361]), .DATA_B (LATCHED_PP[362]), .DATA_C (LATCHED_PP[363]), .SAVE (INT_SUM[377]), .CARRY (INT_CARRY[307]) );
smffa dla435 (.D(SUMMAND[364]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[364]) );
smffa dla436 (.D(SUMMAND[365]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[365]) );
smffa dla437 (.D(SUMMAND[366]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[366]) );
smfulladder dfa274 (.DATA_A (LATCHED_PP[364]), .DATA_B (LATCHED_PP[365]), .DATA_C (LATCHED_PP[366]), .SAVE (INT_SUM[378]), .CARRY (INT_CARRY[308]) );
smffa dla438 (.D(SUMMAND[367]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[367]) );
smffa dla439 (.D(SUMMAND[368]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[368]) );
smffa dla440 (.D(SUMMAND[369]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[369]) );
smfulladder dfa275 (.DATA_A (LATCHED_PP[367]), .DATA_B (LATCHED_PP[368]), .DATA_C (LATCHED_PP[369]), .SAVE (INT_SUM[379]), .CARRY (INT_CARRY[309]) );
smffa dla441 (.D(SUMMAND[370]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[370]) );
smffa dla442 (.D(SUMMAND[371]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[371]) );
smffa dla443 (.D(SUMMAND[372]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[372]) );
smfulladder dfa276 (.DATA_A (LATCHED_PP[370]), .DATA_B (LATCHED_PP[371]), .DATA_C (LATCHED_PP[372]), .SAVE (INT_SUM[380]), .CARRY (INT_CARRY[310]) );
smffa dla444 (.D(SUMMAND[373]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[373]) );
assign INT_SUM[381] = LATCHED_PP[373];
smfulladder dfa277 (.DATA_A (INT_SUM[376]), .DATA_B (INT_SUM[377]), .DATA_C (INT_SUM[378]), .SAVE (INT_SUM[382]), .CARRY (INT_CARRY[311]) );
smfulladder dfa278 (.DATA_A (INT_SUM[379]), .DATA_B (INT_SUM[380]), .DATA_C (INT_SUM[381]), .SAVE (INT_SUM[383]), .CARRY (INT_CARRY[312]) );
smfulladder dfa279 (.DATA_A (INT_CARRY[290]), .DATA_B (INT_CARRY[291]), .DATA_C (INT_CARRY[292]), .SAVE (INT_SUM[384]), .CARRY (INT_CARRY[313]) );
smfulladder dfa280 (.DATA_A (INT_CARRY[293]), .DATA_B (INT_CARRY[294]), .DATA_C (INT_CARRY[295]), .SAVE (INT_SUM[385]), .CARRY (INT_CARRY[314]) );
smfulladder dfa281 (.DATA_A (INT_SUM[382]), .DATA_B (INT_SUM[383]), .DATA_C (INT_SUM[384]), .SAVE (INT_SUM[386]), .CARRY (INT_CARRY[315]) );
smfulladder dfa282 (.DATA_A (INT_SUM[385]), .DATA_B (INT_CARRY[296]), .DATA_C (INT_CARRY[297]), .SAVE (INT_SUM[387]), .CARRY (INT_CARRY[316]) );
assign INT_SUM[388] = INT_CARRY[298];
assign INT_SUM[389] = INT_CARRY[299];
smfulladder dfa283 (.DATA_A (INT_SUM[386]), .DATA_B (INT_SUM[387]), .DATA_C (INT_SUM[388]), .SAVE (INT_SUM[390]), .CARRY (INT_CARRY[317]) );
smfulladder dfa284 (.DATA_A (INT_SUM[389]), .DATA_B (INT_CARRY[300]), .DATA_C (INT_CARRY[301]), .SAVE (INT_SUM[391]), .CARRY (INT_CARRY[318]) );
smfulladder dfa285 (.DATA_A (INT_SUM[390]), .DATA_B (INT_SUM[391]), .DATA_C (INT_CARRY[302]), .SAVE (INT_SUM[392]), .CARRY (INT_CARRY[319]) );
assign INT_SUM[393] = INT_CARRY[303];
smfulladder dfa286 (.DATA_A (INT_SUM[392]), .DATA_B (INT_SUM[393]), .DATA_C (INT_CARRY[304]), .SAVE (INT_SUM[394]), .CARRY (INT_CARRY[305]) );
smffb dla445 (.D(INT_SUM[394]), .clk(clk), .en_d2(en_d2), .Q(SUM[36]) );
smffb dla446 (.D(INT_CARRY[305]), .clk(clk), .en_d2(en_d2), .Q(CARRY[36]) );
smffa dla447 (.D(SUMMAND[374]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[374]) );
smffa dla448 (.D(SUMMAND[375]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[375]) );
smffa dla449 (.D(SUMMAND[376]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[376]) );
smfulladder dfa287 (.DATA_A (LATCHED_PP[374]), .DATA_B (LATCHED_PP[375]), .DATA_C (LATCHED_PP[376]), .SAVE (INT_SUM[395]), .CARRY (INT_CARRY[321]) );
smffa dla450 (.D(SUMMAND[377]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[377]) );
smffa dla451 (.D(SUMMAND[378]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[378]) );
smffa dla452 (.D(SUMMAND[379]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[379]) );
smfulladder dfa288 (.DATA_A (LATCHED_PP[377]), .DATA_B (LATCHED_PP[378]), .DATA_C (LATCHED_PP[379]), .SAVE (INT_SUM[396]), .CARRY (INT_CARRY[322]) );
smffa dla453 (.D(SUMMAND[380]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[380]) );
smffa dla454 (.D(SUMMAND[381]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[381]) );
smffa dla455 (.D(SUMMAND[382]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[382]) );
smfulladder dfa289 (.DATA_A (LATCHED_PP[380]), .DATA_B (LATCHED_PP[381]), .DATA_C (LATCHED_PP[382]), .SAVE (INT_SUM[397]), .CARRY (INT_CARRY[323]) );
smffa dla456 (.D(SUMMAND[383]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[383]) );
smffa dla457 (.D(SUMMAND[384]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[384]) );
smffa dla458 (.D(SUMMAND[385]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[385]) );
smfulladder dfa290 (.DATA_A (LATCHED_PP[383]), .DATA_B (LATCHED_PP[384]), .DATA_C (LATCHED_PP[385]), .SAVE (INT_SUM[398]), .CARRY (INT_CARRY[324]) );
smffa dla459 (.D(SUMMAND[386]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[386]) );
smffa dla460 (.D(SUMMAND[387]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[387]) );
smffa dla461 (.D(SUMMAND[388]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[388]) );
smfulladder dfa291 (.DATA_A (LATCHED_PP[386]), .DATA_B (LATCHED_PP[387]), .DATA_C (LATCHED_PP[388]), .SAVE (INT_SUM[399]), .CARRY (INT_CARRY[325]) );
smffa dla462 (.D(SUMMAND[389]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[389]) );
assign INT_SUM[400] = LATCHED_PP[389];
smfulladder dfa292 (.DATA_A (INT_SUM[395]), .DATA_B (INT_SUM[396]), .DATA_C (INT_SUM[397]), .SAVE (INT_SUM[401]), .CARRY (INT_CARRY[326]) );
smfulladder dfa293 (.DATA_A (INT_SUM[398]), .DATA_B (INT_SUM[399]), .DATA_C (INT_SUM[400]), .SAVE (INT_SUM[402]), .CARRY (INT_CARRY[327]) );
smfulladder dfa294 (.DATA_A (INT_CARRY[306]), .DATA_B (INT_CARRY[307]), .DATA_C (INT_CARRY[308]), .SAVE (INT_SUM[403]), .CARRY (INT_CARRY[328]) );
assign INT_SUM[404] = INT_CARRY[309];
assign INT_SUM[405] = INT_CARRY[310];
smfulladder dfa295 (.DATA_A (INT_SUM[401]), .DATA_B (INT_SUM[402]), .DATA_C (INT_SUM[403]), .SAVE (INT_SUM[406]), .CARRY (INT_CARRY[329]) );
smfulladder dfa296 (.DATA_A (INT_SUM[404]), .DATA_B (INT_SUM[405]), .DATA_C (INT_CARRY[311]), .SAVE (INT_SUM[407]), .CARRY (INT_CARRY[330]) );
smfulladder dfa297 (.DATA_A (INT_CARRY[312]), .DATA_B (INT_CARRY[313]), .DATA_C (INT_CARRY[314]), .SAVE (INT_SUM[408]), .CARRY (INT_CARRY[331]) );
smfulladder dfa298 (.DATA_A (INT_SUM[406]), .DATA_B (INT_SUM[407]), .DATA_C (INT_SUM[408]), .SAVE (INT_SUM[409]), .CARRY (INT_CARRY[332]) );
smhalfadder dha33 (.DATA_A (INT_CARRY[315]), .DATA_B (INT_CARRY[316]), .SAVE (INT_SUM[410]), .CARRY (INT_CARRY[333]) );
smfulladder dfa299 (.DATA_A (INT_SUM[409]), .DATA_B (INT_SUM[410]), .DATA_C (INT_CARRY[317]), .SAVE (INT_SUM[411]), .CARRY (INT_CARRY[334]) );
assign INT_SUM[412] = INT_CARRY[318];
smfulladder dfa300 (.DATA_A (INT_SUM[411]), .DATA_B (INT_SUM[412]), .DATA_C (INT_CARRY[319]), .SAVE (INT_SUM[413]), .CARRY (INT_CARRY[320]) );
smffb dla463 (.D(INT_SUM[413]), .clk(clk), .en_d2(en_d2), .Q(SUM[37]) );
smffb dla464 (.D(INT_CARRY[320]), .clk(clk), .en_d2(en_d2), .Q(CARRY[37]) );
smffa dla465 (.D(SUMMAND[390]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[390]) );
smffa dla466 (.D(SUMMAND[391]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[391]) );
smffa dla467 (.D(SUMMAND[392]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[392]) );
smfulladder dfa301 (.DATA_A (LATCHED_PP[390]), .DATA_B (LATCHED_PP[391]), .DATA_C (LATCHED_PP[392]), .SAVE (INT_SUM[414]), .CARRY (INT_CARRY[336]) );
smffa dla468 (.D(SUMMAND[393]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[393]) );
smffa dla469 (.D(SUMMAND[394]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[394]) );
smffa dla470 (.D(SUMMAND[395]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[395]) );
smfulladder dfa302 (.DATA_A (LATCHED_PP[393]), .DATA_B (LATCHED_PP[394]), .DATA_C (LATCHED_PP[395]), .SAVE (INT_SUM[415]), .CARRY (INT_CARRY[337]) );
smffa dla471 (.D(SUMMAND[396]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[396]) );
smffa dla472 (.D(SUMMAND[397]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[397]) );
smffa dla473 (.D(SUMMAND[398]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[398]) );
smfulladder dfa303 (.DATA_A (LATCHED_PP[396]), .DATA_B (LATCHED_PP[397]), .DATA_C (LATCHED_PP[398]), .SAVE (INT_SUM[416]), .CARRY (INT_CARRY[338]) );
smffa dla474 (.D(SUMMAND[399]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[399]) );
smffa dla475 (.D(SUMMAND[400]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[400]) );
smffa dla476 (.D(SUMMAND[401]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[401]) );
smfulladder dfa304 (.DATA_A (LATCHED_PP[399]), .DATA_B (LATCHED_PP[400]), .DATA_C (LATCHED_PP[401]), .SAVE (INT_SUM[417]), .CARRY (INT_CARRY[339]) );
smffa dla477 (.D(SUMMAND[402]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[402]) );
smffa dla478 (.D(SUMMAND[403]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[403]) );
smffa dla479 (.D(SUMMAND[404]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[404]) );
smfulladder dfa305 (.DATA_A (LATCHED_PP[402]), .DATA_B (LATCHED_PP[403]), .DATA_C (LATCHED_PP[404]), .SAVE (INT_SUM[418]), .CARRY (INT_CARRY[340]) );
smfulladder dfa306 (.DATA_A (INT_SUM[414]), .DATA_B (INT_SUM[415]), .DATA_C (INT_SUM[416]), .SAVE (INT_SUM[419]), .CARRY (INT_CARRY[341]) );
smfulladder dfa307 (.DATA_A (INT_SUM[417]), .DATA_B (INT_SUM[418]), .DATA_C (INT_CARRY[321]), .SAVE (INT_SUM[420]), .CARRY (INT_CARRY[342]) );
smfulladder dfa308 (.DATA_A (INT_CARRY[322]), .DATA_B (INT_CARRY[323]), .DATA_C (INT_CARRY[324]), .SAVE (INT_SUM[421]), .CARRY (INT_CARRY[343]) );
assign INT_SUM[422] = INT_CARRY[325];
smfulladder dfa309 (.DATA_A (INT_SUM[419]), .DATA_B (INT_SUM[420]), .DATA_C (INT_SUM[421]), .SAVE (INT_SUM[423]), .CARRY (INT_CARRY[344]) );
smfulladder dfa310 (.DATA_A (INT_SUM[422]), .DATA_B (INT_CARRY[326]), .DATA_C (INT_CARRY[327]), .SAVE (INT_SUM[424]), .CARRY (INT_CARRY[345]) );
assign INT_SUM[425] = INT_CARRY[328];
smfulladder dfa311 (.DATA_A (INT_SUM[423]), .DATA_B (INT_SUM[424]), .DATA_C (INT_SUM[425]), .SAVE (INT_SUM[426]), .CARRY (INT_CARRY[346]) );
smfulladder dfa312 (.DATA_A (INT_CARRY[329]), .DATA_B (INT_CARRY[330]), .DATA_C (INT_CARRY[331]), .SAVE (INT_SUM[427]), .CARRY (INT_CARRY[347]) );
smfulladder dfa313 (.DATA_A (INT_SUM[426]), .DATA_B (INT_SUM[427]), .DATA_C (INT_CARRY[332]), .SAVE (INT_SUM[428]), .CARRY (INT_CARRY[348]) );
assign INT_SUM[429] = INT_CARRY[333];
smfulladder dfa314 (.DATA_A (INT_SUM[428]), .DATA_B (INT_SUM[429]), .DATA_C (INT_CARRY[334]), .SAVE (INT_SUM[430]), .CARRY (INT_CARRY[335]) );
smffb dla480 (.D(INT_SUM[430]), .clk(clk), .en_d2(en_d2), .Q(SUM[38]) );
smffb dla481 (.D(INT_CARRY[335]), .clk(clk), .en_d2(en_d2), .Q(CARRY[38]) );
smffa dla482 (.D(SUMMAND[405]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[405]) );
smffa dla483 (.D(SUMMAND[406]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[406]) );
smffa dla484 (.D(SUMMAND[407]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[407]) );
smfulladder dfa315 (.DATA_A (LATCHED_PP[405]), .DATA_B (LATCHED_PP[406]), .DATA_C (LATCHED_PP[407]), .SAVE (INT_SUM[431]), .CARRY (INT_CARRY[350]) );
smffa dla485 (.D(SUMMAND[408]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[408]) );
smffa dla486 (.D(SUMMAND[409]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[409]) );
smffa dla487 (.D(SUMMAND[410]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[410]) );
smfulladder dfa316 (.DATA_A (LATCHED_PP[408]), .DATA_B (LATCHED_PP[409]), .DATA_C (LATCHED_PP[410]), .SAVE (INT_SUM[432]), .CARRY (INT_CARRY[351]) );
smffa dla488 (.D(SUMMAND[411]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[411]) );
smffa dla489 (.D(SUMMAND[412]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[412]) );
smffa dla490 (.D(SUMMAND[413]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[413]) );
smfulladder dfa317 (.DATA_A (LATCHED_PP[411]), .DATA_B (LATCHED_PP[412]), .DATA_C (LATCHED_PP[413]), .SAVE (INT_SUM[433]), .CARRY (INT_CARRY[352]) );
smffa dla491 (.D(SUMMAND[414]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[414]) );
smffa dla492 (.D(SUMMAND[415]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[415]) );
smffa dla493 (.D(SUMMAND[416]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[416]) );
smfulladder dfa318 (.DATA_A (LATCHED_PP[414]), .DATA_B (LATCHED_PP[415]), .DATA_C (LATCHED_PP[416]), .SAVE (INT_SUM[434]), .CARRY (INT_CARRY[353]) );
smffa dla494 (.D(SUMMAND[417]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[417]) );
smffa dla495 (.D(SUMMAND[418]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[418]) );
smffa dla496 (.D(SUMMAND[419]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[419]) );
smfulladder dfa319 (.DATA_A (LATCHED_PP[417]), .DATA_B (LATCHED_PP[418]), .DATA_C (LATCHED_PP[419]), .SAVE (INT_SUM[435]), .CARRY (INT_CARRY[354]) );
smfulladder dfa320 (.DATA_A (INT_SUM[431]), .DATA_B (INT_SUM[432]), .DATA_C (INT_SUM[433]), .SAVE (INT_SUM[436]), .CARRY (INT_CARRY[355]) );
smfulladder dfa321 (.DATA_A (INT_SUM[434]), .DATA_B (INT_SUM[435]), .DATA_C (INT_CARRY[336]), .SAVE (INT_SUM[437]), .CARRY (INT_CARRY[356]) );
smfulladder dfa322 (.DATA_A (INT_CARRY[337]), .DATA_B (INT_CARRY[338]), .DATA_C (INT_CARRY[339]), .SAVE (INT_SUM[438]), .CARRY (INT_CARRY[357]) );
assign INT_SUM[439] = INT_CARRY[340];
smfulladder dfa323 (.DATA_A (INT_SUM[436]), .DATA_B (INT_SUM[437]), .DATA_C (INT_SUM[438]), .SAVE (INT_SUM[440]), .CARRY (INT_CARRY[358]) );
smfulladder dfa324 (.DATA_A (INT_SUM[439]), .DATA_B (INT_CARRY[341]), .DATA_C (INT_CARRY[342]), .SAVE (INT_SUM[441]), .CARRY (INT_CARRY[359]) );
assign INT_SUM[442] = INT_CARRY[343];
smfulladder dfa325 (.DATA_A (INT_SUM[440]), .DATA_B (INT_SUM[441]), .DATA_C (INT_SUM[442]), .SAVE (INT_SUM[443]), .CARRY (INT_CARRY[360]) );
smhalfadder dha34 (.DATA_A (INT_CARRY[344]), .DATA_B (INT_CARRY[345]), .SAVE (INT_SUM[444]), .CARRY (INT_CARRY[361]) );
smfulladder dfa326 (.DATA_A (INT_SUM[443]), .DATA_B (INT_SUM[444]), .DATA_C (INT_CARRY[346]), .SAVE (INT_SUM[445]), .CARRY (INT_CARRY[362]) );
assign INT_SUM[446] = INT_CARRY[347];
smfulladder dfa327 (.DATA_A (INT_SUM[445]), .DATA_B (INT_SUM[446]), .DATA_C (INT_CARRY[348]), .SAVE (INT_SUM[447]), .CARRY (INT_CARRY[349]) );
smffb dla497 (.D(INT_SUM[447]), .clk(clk), .en_d2(en_d2), .Q(SUM[39]) );
smffb dla498 (.D(INT_CARRY[349]), .clk(clk), .en_d2(en_d2), .Q(CARRY[39]) );
smffa dla499 (.D(SUMMAND[420]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[420]) );
smffa dla500 (.D(SUMMAND[421]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[421]) );
smffa dla501 (.D(SUMMAND[422]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[422]) );
smfulladder dfa328 (.DATA_A (LATCHED_PP[420]), .DATA_B (LATCHED_PP[421]), .DATA_C (LATCHED_PP[422]), .SAVE (INT_SUM[448]), .CARRY (INT_CARRY[364]) );
smffa dla502 (.D(SUMMAND[423]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[423]) );
smffa dla503 (.D(SUMMAND[424]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[424]) );
smffa dla504 (.D(SUMMAND[425]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[425]) );
smfulladder dfa329 (.DATA_A (LATCHED_PP[423]), .DATA_B (LATCHED_PP[424]), .DATA_C (LATCHED_PP[425]), .SAVE (INT_SUM[449]), .CARRY (INT_CARRY[365]) );
smffa dla505 (.D(SUMMAND[426]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[426]) );
smffa dla506 (.D(SUMMAND[427]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[427]) );
smffa dla507 (.D(SUMMAND[428]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[428]) );
smfulladder dfa330 (.DATA_A (LATCHED_PP[426]), .DATA_B (LATCHED_PP[427]), .DATA_C (LATCHED_PP[428]), .SAVE (INT_SUM[450]), .CARRY (INT_CARRY[366]) );
smffa dla508 (.D(SUMMAND[429]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[429]) );
smffa dla509 (.D(SUMMAND[430]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[430]) );
smffa dla510 (.D(SUMMAND[431]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[431]) );
smfulladder dfa331 (.DATA_A (LATCHED_PP[429]), .DATA_B (LATCHED_PP[430]), .DATA_C (LATCHED_PP[431]), .SAVE (INT_SUM[451]), .CARRY (INT_CARRY[367]) );
smffa dla511 (.D(SUMMAND[432]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[432]) );
smffa dla512 (.D(SUMMAND[433]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[433]) );
smhalfadder dha35 (.DATA_A (LATCHED_PP[432]), .DATA_B (LATCHED_PP[433]), .SAVE (INT_SUM[452]), .CARRY (INT_CARRY[368]) );
smfulladder dfa332 (.DATA_A (INT_SUM[448]), .DATA_B (INT_SUM[449]), .DATA_C (INT_SUM[450]), .SAVE (INT_SUM[453]), .CARRY (INT_CARRY[369]) );
smfulladder dfa333 (.DATA_A (INT_SUM[451]), .DATA_B (INT_SUM[452]), .DATA_C (INT_CARRY[350]), .SAVE (INT_SUM[454]), .CARRY (INT_CARRY[370]) );
smfulladder dfa334 (.DATA_A (INT_CARRY[351]), .DATA_B (INT_CARRY[352]), .DATA_C (INT_CARRY[353]), .SAVE (INT_SUM[455]), .CARRY (INT_CARRY[371]) );
assign INT_SUM[456] = INT_CARRY[354];
smfulladder dfa335 (.DATA_A (INT_SUM[453]), .DATA_B (INT_SUM[454]), .DATA_C (INT_SUM[455]), .SAVE (INT_SUM[457]), .CARRY (INT_CARRY[372]) );
smfulladder dfa336 (.DATA_A (INT_SUM[456]), .DATA_B (INT_CARRY[355]), .DATA_C (INT_CARRY[356]), .SAVE (INT_SUM[458]), .CARRY (INT_CARRY[373]) );
assign INT_SUM[459] = INT_CARRY[357];
smfulladder dfa337 (.DATA_A (INT_SUM[457]), .DATA_B (INT_SUM[458]), .DATA_C (INT_SUM[459]), .SAVE (INT_SUM[460]), .CARRY (INT_CARRY[374]) );
smhalfadder dha36 (.DATA_A (INT_CARRY[358]), .DATA_B (INT_CARRY[359]), .SAVE (INT_SUM[461]), .CARRY (INT_CARRY[375]) );
smfulladder dfa338 (.DATA_A (INT_SUM[460]), .DATA_B (INT_SUM[461]), .DATA_C (INT_CARRY[360]), .SAVE (INT_SUM[462]), .CARRY (INT_CARRY[376]) );
assign INT_SUM[463] = INT_CARRY[361];
smfulladder dfa339 (.DATA_A (INT_SUM[462]), .DATA_B (INT_SUM[463]), .DATA_C (INT_CARRY[362]), .SAVE (INT_SUM[464]), .CARRY (INT_CARRY[363]) );
smffb dla513 (.D(INT_SUM[464]), .clk(clk), .en_d2(en_d2), .Q(SUM[40]) );
smffb dla514 (.D(INT_CARRY[363]), .clk(clk), .en_d2(en_d2), .Q(CARRY[40]) );
smffa dla515 (.D(SUMMAND[434]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[434]) );
smffa dla516 (.D(SUMMAND[435]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[435]) );
smffa dla517 (.D(SUMMAND[436]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[436]) );
smfulladder dfa340 (.DATA_A (LATCHED_PP[434]), .DATA_B (LATCHED_PP[435]), .DATA_C (LATCHED_PP[436]), .SAVE (INT_SUM[465]), .CARRY (INT_CARRY[378]) );
smffa dla518 (.D(SUMMAND[437]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[437]) );
smffa dla519 (.D(SUMMAND[438]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[438]) );
smffa dla520 (.D(SUMMAND[439]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[439]) );
smfulladder dfa341 (.DATA_A (LATCHED_PP[437]), .DATA_B (LATCHED_PP[438]), .DATA_C (LATCHED_PP[439]), .SAVE (INT_SUM[466]), .CARRY (INT_CARRY[379]) );
smffa dla521 (.D(SUMMAND[440]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[440]) );
smffa dla522 (.D(SUMMAND[441]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[441]) );
smffa dla523 (.D(SUMMAND[442]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[442]) );
smfulladder dfa342 (.DATA_A (LATCHED_PP[440]), .DATA_B (LATCHED_PP[441]), .DATA_C (LATCHED_PP[442]), .SAVE (INT_SUM[467]), .CARRY (INT_CARRY[380]) );
smffa dla524 (.D(SUMMAND[443]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[443]) );
smffa dla525 (.D(SUMMAND[444]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[444]) );
smffa dla526 (.D(SUMMAND[445]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[445]) );
smfulladder dfa343 (.DATA_A (LATCHED_PP[443]), .DATA_B (LATCHED_PP[444]), .DATA_C (LATCHED_PP[445]), .SAVE (INT_SUM[468]), .CARRY (INT_CARRY[381]) );
smffa dla527 (.D(SUMMAND[446]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[446]) );
smffa dla528 (.D(SUMMAND[447]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[447]) );
smhalfadder dha37 (.DATA_A (LATCHED_PP[446]), .DATA_B (LATCHED_PP[447]), .SAVE (INT_SUM[469]), .CARRY (INT_CARRY[382]) );
smfulladder dfa344 (.DATA_A (INT_SUM[465]), .DATA_B (INT_SUM[466]), .DATA_C (INT_SUM[467]), .SAVE (INT_SUM[470]), .CARRY (INT_CARRY[383]) );
smfulladder dfa345 (.DATA_A (INT_SUM[468]), .DATA_B (INT_SUM[469]), .DATA_C (INT_CARRY[364]), .SAVE (INT_SUM[471]), .CARRY (INT_CARRY[384]) );
smfulladder dfa346 (.DATA_A (INT_CARRY[365]), .DATA_B (INT_CARRY[366]), .DATA_C (INT_CARRY[367]), .SAVE (INT_SUM[472]), .CARRY (INT_CARRY[385]) );
assign INT_SUM[473] = INT_CARRY[368];
smfulladder dfa347 (.DATA_A (INT_SUM[470]), .DATA_B (INT_SUM[471]), .DATA_C (INT_SUM[472]), .SAVE (INT_SUM[474]), .CARRY (INT_CARRY[386]) );
smfulladder dfa348 (.DATA_A (INT_SUM[473]), .DATA_B (INT_CARRY[369]), .DATA_C (INT_CARRY[370]), .SAVE (INT_SUM[475]), .CARRY (INT_CARRY[387]) );
assign INT_SUM[476] = INT_CARRY[371];
smfulladder dfa349 (.DATA_A (INT_SUM[474]), .DATA_B (INT_SUM[475]), .DATA_C (INT_SUM[476]), .SAVE (INT_SUM[477]), .CARRY (INT_CARRY[388]) );
smhalfadder dha38 (.DATA_A (INT_CARRY[372]), .DATA_B (INT_CARRY[373]), .SAVE (INT_SUM[478]), .CARRY (INT_CARRY[389]) );
smfulladder dfa350 (.DATA_A (INT_SUM[477]), .DATA_B (INT_SUM[478]), .DATA_C (INT_CARRY[374]), .SAVE (INT_SUM[479]), .CARRY (INT_CARRY[390]) );
assign INT_SUM[480] = INT_CARRY[375];
smfulladder dfa351 (.DATA_A (INT_SUM[479]), .DATA_B (INT_SUM[480]), .DATA_C (INT_CARRY[376]), .SAVE (INT_SUM[481]), .CARRY (INT_CARRY[377]) );
smffb dla529 (.D(INT_SUM[481]), .clk(clk), .en_d2(en_d2), .Q(SUM[41]) );
smffb dla530 (.D(INT_CARRY[377]), .clk(clk), .en_d2(en_d2), .Q(CARRY[41]) );
smffa dla531 (.D(SUMMAND[448]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[448]) );
smffa dla532 (.D(SUMMAND[449]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[449]) );
smffa dla533 (.D(SUMMAND[450]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[450]) );
smfulladder dfa352 (.DATA_A (LATCHED_PP[448]), .DATA_B (LATCHED_PP[449]), .DATA_C (LATCHED_PP[450]), .SAVE (INT_SUM[482]), .CARRY (INT_CARRY[392]) );
smffa dla534 (.D(SUMMAND[451]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[451]) );
smffa dla535 (.D(SUMMAND[452]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[452]) );
smffa dla536 (.D(SUMMAND[453]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[453]) );
smfulladder dfa353 (.DATA_A (LATCHED_PP[451]), .DATA_B (LATCHED_PP[452]), .DATA_C (LATCHED_PP[453]), .SAVE (INT_SUM[483]), .CARRY (INT_CARRY[393]) );
smffa dla537 (.D(SUMMAND[454]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[454]) );
smffa dla538 (.D(SUMMAND[455]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[455]) );
smffa dla539 (.D(SUMMAND[456]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[456]) );
smfulladder dfa354 (.DATA_A (LATCHED_PP[454]), .DATA_B (LATCHED_PP[455]), .DATA_C (LATCHED_PP[456]), .SAVE (INT_SUM[484]), .CARRY (INT_CARRY[394]) );
smffa dla540 (.D(SUMMAND[457]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[457]) );
smffa dla541 (.D(SUMMAND[458]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[458]) );
smffa dla542 (.D(SUMMAND[459]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[459]) );
smfulladder dfa355 (.DATA_A (LATCHED_PP[457]), .DATA_B (LATCHED_PP[458]), .DATA_C (LATCHED_PP[459]), .SAVE (INT_SUM[485]), .CARRY (INT_CARRY[395]) );
smffa dla543 (.D(SUMMAND[460]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[460]) );
assign INT_SUM[486] = LATCHED_PP[460];
smfulladder dfa356 (.DATA_A (INT_SUM[482]), .DATA_B (INT_SUM[483]), .DATA_C (INT_SUM[484]), .SAVE (INT_SUM[487]), .CARRY (INT_CARRY[396]) );
smfulladder dfa357 (.DATA_A (INT_SUM[485]), .DATA_B (INT_SUM[486]), .DATA_C (INT_CARRY[378]), .SAVE (INT_SUM[488]), .CARRY (INT_CARRY[397]) );
smfulladder dfa358 (.DATA_A (INT_CARRY[379]), .DATA_B (INT_CARRY[380]), .DATA_C (INT_CARRY[381]), .SAVE (INT_SUM[489]), .CARRY (INT_CARRY[398]) );
assign INT_SUM[490] = INT_CARRY[382];
smfulladder dfa359 (.DATA_A (INT_SUM[487]), .DATA_B (INT_SUM[488]), .DATA_C (INT_SUM[489]), .SAVE (INT_SUM[491]), .CARRY (INT_CARRY[399]) );
smfulladder dfa360 (.DATA_A (INT_SUM[490]), .DATA_B (INT_CARRY[383]), .DATA_C (INT_CARRY[384]), .SAVE (INT_SUM[492]), .CARRY (INT_CARRY[400]) );
assign INT_SUM[493] = INT_CARRY[385];
smfulladder dfa361 (.DATA_A (INT_SUM[491]), .DATA_B (INT_SUM[492]), .DATA_C (INT_SUM[493]), .SAVE (INT_SUM[494]), .CARRY (INT_CARRY[401]) );
smhalfadder dha39 (.DATA_A (INT_CARRY[386]), .DATA_B (INT_CARRY[387]), .SAVE (INT_SUM[495]), .CARRY (INT_CARRY[402]) );
smfulladder dfa362 (.DATA_A (INT_SUM[494]), .DATA_B (INT_SUM[495]), .DATA_C (INT_CARRY[388]), .SAVE (INT_SUM[496]), .CARRY (INT_CARRY[403]) );
assign INT_SUM[497] = INT_CARRY[389];
smfulladder dfa363 (.DATA_A (INT_SUM[496]), .DATA_B (INT_SUM[497]), .DATA_C (INT_CARRY[390]), .SAVE (INT_SUM[498]), .CARRY (INT_CARRY[391]) );
smffb dla544 (.D(INT_SUM[498]), .clk(clk), .en_d2(en_d2), .Q(SUM[42]) );
smffb dla545 (.D(INT_CARRY[391]), .clk(clk), .en_d2(en_d2), .Q(CARRY[42]) );
smffa dla546 (.D(SUMMAND[461]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[461]) );
smffa dla547 (.D(SUMMAND[462]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[462]) );
smffa dla548 (.D(SUMMAND[463]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[463]) );
smfulladder dfa364 (.DATA_A (LATCHED_PP[461]), .DATA_B (LATCHED_PP[462]), .DATA_C (LATCHED_PP[463]), .SAVE (INT_SUM[499]), .CARRY (INT_CARRY[405]) );
smffa dla549 (.D(SUMMAND[464]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[464]) );
smffa dla550 (.D(SUMMAND[465]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[465]) );
smffa dla551 (.D(SUMMAND[466]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[466]) );
smfulladder dfa365 (.DATA_A (LATCHED_PP[464]), .DATA_B (LATCHED_PP[465]), .DATA_C (LATCHED_PP[466]), .SAVE (INT_SUM[500]), .CARRY (INT_CARRY[406]) );
smffa dla552 (.D(SUMMAND[467]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[467]) );
smffa dla553 (.D(SUMMAND[468]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[468]) );
smffa dla554 (.D(SUMMAND[469]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[469]) );
smfulladder dfa366 (.DATA_A (LATCHED_PP[467]), .DATA_B (LATCHED_PP[468]), .DATA_C (LATCHED_PP[469]), .SAVE (INT_SUM[501]), .CARRY (INT_CARRY[407]) );
smffa dla555 (.D(SUMMAND[470]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[470]) );
smffa dla556 (.D(SUMMAND[471]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[471]) );
smffa dla557 (.D(SUMMAND[472]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[472]) );
smfulladder dfa367 (.DATA_A (LATCHED_PP[470]), .DATA_B (LATCHED_PP[471]), .DATA_C (LATCHED_PP[472]), .SAVE (INT_SUM[502]), .CARRY (INT_CARRY[408]) );
smffa dla558 (.D(SUMMAND[473]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[473]) );
smfulladder dfa368 (.DATA_A (LATCHED_PP[473]), .DATA_B (INT_CARRY[392]), .DATA_C (INT_CARRY[393]), .SAVE (INT_SUM[503]), .CARRY (INT_CARRY[409]) );
assign INT_SUM[504] = INT_CARRY[394];
assign INT_SUM[505] = INT_CARRY[395];
smfulladder dfa369 (.DATA_A (INT_SUM[499]), .DATA_B (INT_SUM[500]), .DATA_C (INT_SUM[501]), .SAVE (INT_SUM[506]), .CARRY (INT_CARRY[410]) );
smfulladder dfa370 (.DATA_A (INT_SUM[502]), .DATA_B (INT_SUM[503]), .DATA_C (INT_SUM[504]), .SAVE (INT_SUM[507]), .CARRY (INT_CARRY[411]) );
smfulladder dfa371 (.DATA_A (INT_SUM[505]), .DATA_B (INT_CARRY[396]), .DATA_C (INT_CARRY[397]), .SAVE (INT_SUM[508]), .CARRY (INT_CARRY[412]) );
assign INT_SUM[509] = INT_CARRY[398];
smfulladder dfa372 (.DATA_A (INT_SUM[506]), .DATA_B (INT_SUM[507]), .DATA_C (INT_SUM[508]), .SAVE (INT_SUM[510]), .CARRY (INT_CARRY[413]) );
smfulladder dfa373 (.DATA_A (INT_SUM[509]), .DATA_B (INT_CARRY[399]), .DATA_C (INT_CARRY[400]), .SAVE (INT_SUM[511]), .CARRY (INT_CARRY[414]) );
smfulladder dfa374 (.DATA_A (INT_SUM[510]), .DATA_B (INT_SUM[511]), .DATA_C (INT_CARRY[401]), .SAVE (INT_SUM[512]), .CARRY (INT_CARRY[415]) );
assign INT_SUM[513] = INT_CARRY[402];
smfulladder dfa375 (.DATA_A (INT_SUM[512]), .DATA_B (INT_SUM[513]), .DATA_C (INT_CARRY[403]), .SAVE (INT_SUM[514]), .CARRY (INT_CARRY[404]) );
smffb dla559 (.D(INT_SUM[514]), .clk(clk), .en_d2(en_d2), .Q(SUM[43]) );
smffb dla560 (.D(INT_CARRY[404]), .clk(clk), .en_d2(en_d2), .Q(CARRY[43]) );
smffa dla561 (.D(SUMMAND[474]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[474]) );
smffa dla562 (.D(SUMMAND[475]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[475]) );
smffa dla563 (.D(SUMMAND[476]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[476]) );
smfulladder dfa376 (.DATA_A (LATCHED_PP[474]), .DATA_B (LATCHED_PP[475]), .DATA_C (LATCHED_PP[476]), .SAVE (INT_SUM[515]), .CARRY (INT_CARRY[417]) );
smffa dla564 (.D(SUMMAND[477]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[477]) );
smffa dla565 (.D(SUMMAND[478]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[478]) );
smffa dla566 (.D(SUMMAND[479]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[479]) );
smfulladder dfa377 (.DATA_A (LATCHED_PP[477]), .DATA_B (LATCHED_PP[478]), .DATA_C (LATCHED_PP[479]), .SAVE (INT_SUM[516]), .CARRY (INT_CARRY[418]) );
smffa dla567 (.D(SUMMAND[480]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[480]) );
smffa dla568 (.D(SUMMAND[481]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[481]) );
smffa dla569 (.D(SUMMAND[482]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[482]) );
smfulladder dfa378 (.DATA_A (LATCHED_PP[480]), .DATA_B (LATCHED_PP[481]), .DATA_C (LATCHED_PP[482]), .SAVE (INT_SUM[517]), .CARRY (INT_CARRY[419]) );
smffa dla570 (.D(SUMMAND[483]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[483]) );
smffa dla571 (.D(SUMMAND[484]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[484]) );
smffa dla572 (.D(SUMMAND[485]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[485]) );
smfulladder dfa379 (.DATA_A (LATCHED_PP[483]), .DATA_B (LATCHED_PP[484]), .DATA_C (LATCHED_PP[485]), .SAVE (INT_SUM[518]), .CARRY (INT_CARRY[420]) );
smfulladder dfa380 (.DATA_A (INT_SUM[515]), .DATA_B (INT_SUM[516]), .DATA_C (INT_SUM[517]), .SAVE (INT_SUM[519]), .CARRY (INT_CARRY[421]) );
smfulladder dfa381 (.DATA_A (INT_SUM[518]), .DATA_B (INT_CARRY[405]), .DATA_C (INT_CARRY[406]), .SAVE (INT_SUM[520]), .CARRY (INT_CARRY[422]) );
smfulladder dfa382 (.DATA_A (INT_CARRY[407]), .DATA_B (INT_CARRY[408]), .DATA_C (INT_CARRY[409]), .SAVE (INT_SUM[521]), .CARRY (INT_CARRY[423]) );
smfulladder dfa383 (.DATA_A (INT_SUM[519]), .DATA_B (INT_SUM[520]), .DATA_C (INT_SUM[521]), .SAVE (INT_SUM[522]), .CARRY (INT_CARRY[424]) );
smfulladder dfa384 (.DATA_A (INT_CARRY[410]), .DATA_B (INT_CARRY[411]), .DATA_C (INT_CARRY[412]), .SAVE (INT_SUM[523]), .CARRY (INT_CARRY[425]) );
smfulladder dfa385 (.DATA_A (INT_SUM[522]), .DATA_B (INT_SUM[523]), .DATA_C (INT_CARRY[413]), .SAVE (INT_SUM[524]), .CARRY (INT_CARRY[426]) );
assign INT_SUM[525] = INT_CARRY[414];
smfulladder dfa386 (.DATA_A (INT_SUM[524]), .DATA_B (INT_SUM[525]), .DATA_C (INT_CARRY[415]), .SAVE (INT_SUM[526]), .CARRY (INT_CARRY[416]) );
smffb dla573 (.D(INT_SUM[526]), .clk(clk), .en_d2(en_d2), .Q(SUM[44]) );
smffb dla574 (.D(INT_CARRY[416]), .clk(clk), .en_d2(en_d2), .Q(CARRY[44]) );
smffa dla575 (.D(SUMMAND[486]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[486]) );
smffa dla576 (.D(SUMMAND[487]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[487]) );
smffa dla577 (.D(SUMMAND[488]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[488]) );
smfulladder dfa387 (.DATA_A (LATCHED_PP[486]), .DATA_B (LATCHED_PP[487]), .DATA_C (LATCHED_PP[488]), .SAVE (INT_SUM[527]), .CARRY (INT_CARRY[428]) );
smffa dla578 (.D(SUMMAND[489]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[489]) );
smffa dla579 (.D(SUMMAND[490]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[490]) );
smffa dla580 (.D(SUMMAND[491]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[491]) );
smfulladder dfa388 (.DATA_A (LATCHED_PP[489]), .DATA_B (LATCHED_PP[490]), .DATA_C (LATCHED_PP[491]), .SAVE (INT_SUM[528]), .CARRY (INT_CARRY[429]) );
smffa dla581 (.D(SUMMAND[492]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[492]) );
smffa dla582 (.D(SUMMAND[493]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[493]) );
smffa dla583 (.D(SUMMAND[494]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[494]) );
smfulladder dfa389 (.DATA_A (LATCHED_PP[492]), .DATA_B (LATCHED_PP[493]), .DATA_C (LATCHED_PP[494]), .SAVE (INT_SUM[529]), .CARRY (INT_CARRY[430]) );
smffa dla584 (.D(SUMMAND[495]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[495]) );
smffa dla585 (.D(SUMMAND[496]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[496]) );
smffa dla586 (.D(SUMMAND[497]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[497]) );
smfulladder dfa390 (.DATA_A (LATCHED_PP[495]), .DATA_B (LATCHED_PP[496]), .DATA_C (LATCHED_PP[497]), .SAVE (INT_SUM[530]), .CARRY (INT_CARRY[431]) );
smfulladder dfa391 (.DATA_A (INT_SUM[527]), .DATA_B (INT_SUM[528]), .DATA_C (INT_SUM[529]), .SAVE (INT_SUM[531]), .CARRY (INT_CARRY[432]) );
smfulladder dfa392 (.DATA_A (INT_SUM[530]), .DATA_B (INT_CARRY[417]), .DATA_C (INT_CARRY[418]), .SAVE (INT_SUM[532]), .CARRY (INT_CARRY[433]) );
smhalfadder dha40 (.DATA_A (INT_CARRY[419]), .DATA_B (INT_CARRY[420]), .SAVE (INT_SUM[533]), .CARRY (INT_CARRY[434]) );
smfulladder dfa393 (.DATA_A (INT_SUM[531]), .DATA_B (INT_SUM[532]), .DATA_C (INT_SUM[533]), .SAVE (INT_SUM[534]), .CARRY (INT_CARRY[435]) );
smfulladder dfa394 (.DATA_A (INT_CARRY[421]), .DATA_B (INT_CARRY[422]), .DATA_C (INT_CARRY[423]), .SAVE (INT_SUM[535]), .CARRY (INT_CARRY[436]) );
smfulladder dfa395 (.DATA_A (INT_SUM[534]), .DATA_B (INT_SUM[535]), .DATA_C (INT_CARRY[424]), .SAVE (INT_SUM[536]), .CARRY (INT_CARRY[437]) );
assign INT_SUM[537] = INT_CARRY[425];
smfulladder dfa396 (.DATA_A (INT_SUM[536]), .DATA_B (INT_SUM[537]), .DATA_C (INT_CARRY[426]), .SAVE (INT_SUM[538]), .CARRY (INT_CARRY[427]) );
smffb dla587 (.D(INT_SUM[538]), .clk(clk), .en_d2(en_d2), .Q(SUM[45]) );
smffb dla588 (.D(INT_CARRY[427]), .clk(clk), .en_d2(en_d2), .Q(CARRY[45]) );
smffa dla589 (.D(SUMMAND[498]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[498]) );
smffa dla590 (.D(SUMMAND[499]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[499]) );
smffa dla591 (.D(SUMMAND[500]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[500]) );
smfulladder dfa397 (.DATA_A (LATCHED_PP[498]), .DATA_B (LATCHED_PP[499]), .DATA_C (LATCHED_PP[500]), .SAVE (INT_SUM[539]), .CARRY (INT_CARRY[439]) );
smffa dla592 (.D(SUMMAND[501]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[501]) );
smffa dla593 (.D(SUMMAND[502]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[502]) );
smffa dla594 (.D(SUMMAND[503]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[503]) );
smfulladder dfa398 (.DATA_A (LATCHED_PP[501]), .DATA_B (LATCHED_PP[502]), .DATA_C (LATCHED_PP[503]), .SAVE (INT_SUM[540]), .CARRY (INT_CARRY[440]) );
smffa dla595 (.D(SUMMAND[504]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[504]) );
smffa dla596 (.D(SUMMAND[505]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[505]) );
smffa dla597 (.D(SUMMAND[506]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[506]) );
smfulladder dfa399 (.DATA_A (LATCHED_PP[504]), .DATA_B (LATCHED_PP[505]), .DATA_C (LATCHED_PP[506]), .SAVE (INT_SUM[541]), .CARRY (INT_CARRY[441]) );
smffa dla598 (.D(SUMMAND[507]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[507]) );
assign INT_SUM[542] = LATCHED_PP[507];
smffa dla599 (.D(SUMMAND[508]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[508]) );
assign INT_SUM[543] = LATCHED_PP[508];
smfulladder dfa400 (.DATA_A (INT_SUM[539]), .DATA_B (INT_SUM[540]), .DATA_C (INT_SUM[541]), .SAVE (INT_SUM[544]), .CARRY (INT_CARRY[442]) );
smfulladder dfa401 (.DATA_A (INT_SUM[542]), .DATA_B (INT_SUM[543]), .DATA_C (INT_CARRY[428]), .SAVE (INT_SUM[545]), .CARRY (INT_CARRY[443]) );
smfulladder dfa402 (.DATA_A (INT_CARRY[429]), .DATA_B (INT_CARRY[430]), .DATA_C (INT_CARRY[431]), .SAVE (INT_SUM[546]), .CARRY (INT_CARRY[444]) );
smfulladder dfa403 (.DATA_A (INT_SUM[544]), .DATA_B (INT_SUM[545]), .DATA_C (INT_SUM[546]), .SAVE (INT_SUM[547]), .CARRY (INT_CARRY[445]) );
smfulladder dfa404 (.DATA_A (INT_CARRY[432]), .DATA_B (INT_CARRY[433]), .DATA_C (INT_CARRY[434]), .SAVE (INT_SUM[548]), .CARRY (INT_CARRY[446]) );
smfulladder dfa405 (.DATA_A (INT_SUM[547]), .DATA_B (INT_SUM[548]), .DATA_C (INT_CARRY[435]), .SAVE (INT_SUM[549]), .CARRY (INT_CARRY[447]) );
assign INT_SUM[550] = INT_CARRY[436];
smfulladder dfa406 (.DATA_A (INT_SUM[549]), .DATA_B (INT_SUM[550]), .DATA_C (INT_CARRY[437]), .SAVE (INT_SUM[551]), .CARRY (INT_CARRY[438]) );
smffb dla600 (.D(INT_SUM[551]), .clk(clk), .en_d2(en_d2), .Q(SUM[46]) );
smffb dla601 (.D(INT_CARRY[438]), .clk(clk), .en_d2(en_d2), .Q(CARRY[46]) );
smffa dla602 (.D(SUMMAND[509]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[509]) );
smffa dla603 (.D(SUMMAND[510]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[510]) );
smffa dla604 (.D(SUMMAND[511]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[511]) );
smfulladder dfa407 (.DATA_A (LATCHED_PP[509]), .DATA_B (LATCHED_PP[510]), .DATA_C (LATCHED_PP[511]), .SAVE (INT_SUM[552]), .CARRY (INT_CARRY[449]) );
smffa dla605 (.D(SUMMAND[512]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[512]) );
smffa dla606 (.D(SUMMAND[513]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[513]) );
smffa dla607 (.D(SUMMAND[514]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[514]) );
smfulladder dfa408 (.DATA_A (LATCHED_PP[512]), .DATA_B (LATCHED_PP[513]), .DATA_C (LATCHED_PP[514]), .SAVE (INT_SUM[553]), .CARRY (INT_CARRY[450]) );
smffa dla608 (.D(SUMMAND[515]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[515]) );
smffa dla609 (.D(SUMMAND[516]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[516]) );
smffa dla610 (.D(SUMMAND[517]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[517]) );
smfulladder dfa409 (.DATA_A (LATCHED_PP[515]), .DATA_B (LATCHED_PP[516]), .DATA_C (LATCHED_PP[517]), .SAVE (INT_SUM[554]), .CARRY (INT_CARRY[451]) );
smffa dla611 (.D(SUMMAND[518]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[518]) );
smffa dla612 (.D(SUMMAND[519]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[519]) );
smhalfadder dha41 (.DATA_A (LATCHED_PP[518]), .DATA_B (LATCHED_PP[519]), .SAVE (INT_SUM[555]), .CARRY (INT_CARRY[452]) );
smfulladder dfa410 (.DATA_A (INT_SUM[552]), .DATA_B (INT_SUM[553]), .DATA_C (INT_SUM[554]), .SAVE (INT_SUM[556]), .CARRY (INT_CARRY[453]) );
smfulladder dfa411 (.DATA_A (INT_SUM[555]), .DATA_B (INT_CARRY[439]), .DATA_C (INT_CARRY[440]), .SAVE (INT_SUM[557]), .CARRY (INT_CARRY[454]) );
assign INT_SUM[558] = INT_CARRY[441];
smfulladder dfa412 (.DATA_A (INT_SUM[556]), .DATA_B (INT_SUM[557]), .DATA_C (INT_SUM[558]), .SAVE (INT_SUM[559]), .CARRY (INT_CARRY[455]) );
smfulladder dfa413 (.DATA_A (INT_CARRY[442]), .DATA_B (INT_CARRY[443]), .DATA_C (INT_CARRY[444]), .SAVE (INT_SUM[560]), .CARRY (INT_CARRY[456]) );
smfulladder dfa414 (.DATA_A (INT_SUM[559]), .DATA_B (INT_SUM[560]), .DATA_C (INT_CARRY[445]), .SAVE (INT_SUM[561]), .CARRY (INT_CARRY[457]) );
assign INT_SUM[562] = INT_CARRY[446];
smfulladder dfa415 (.DATA_A (INT_SUM[561]), .DATA_B (INT_SUM[562]), .DATA_C (INT_CARRY[447]), .SAVE (INT_SUM[563]), .CARRY (INT_CARRY[448]) );
smffb dla613 (.D(INT_SUM[563]), .clk(clk), .en_d2(en_d2), .Q(SUM[47]) );
smffb dla614 (.D(INT_CARRY[448]), .clk(clk), .en_d2(en_d2), .Q(CARRY[47]) );
smffa dla615 (.D(SUMMAND[520]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[520]) );
smffa dla616 (.D(SUMMAND[521]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[521]) );
smffa dla617 (.D(SUMMAND[522]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[522]) );
smfulladder dfa416 (.DATA_A (LATCHED_PP[520]), .DATA_B (LATCHED_PP[521]), .DATA_C (LATCHED_PP[522]), .SAVE (INT_SUM[564]), .CARRY (INT_CARRY[459]) );
smffa dla618 (.D(SUMMAND[523]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[523]) );
smffa dla619 (.D(SUMMAND[524]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[524]) );
smffa dla620 (.D(SUMMAND[525]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[525]) );
smfulladder dfa417 (.DATA_A (LATCHED_PP[523]), .DATA_B (LATCHED_PP[524]), .DATA_C (LATCHED_PP[525]), .SAVE (INT_SUM[565]), .CARRY (INT_CARRY[460]) );
smffa dla621 (.D(SUMMAND[526]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[526]) );
smffa dla622 (.D(SUMMAND[527]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[527]) );
smffa dla623 (.D(SUMMAND[528]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[528]) );
smfulladder dfa418 (.DATA_A (LATCHED_PP[526]), .DATA_B (LATCHED_PP[527]), .DATA_C (LATCHED_PP[528]), .SAVE (INT_SUM[566]), .CARRY (INT_CARRY[461]) );
smffa dla624 (.D(SUMMAND[529]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[529]) );
assign INT_SUM[567] = LATCHED_PP[529];
smfulladder dfa419 (.DATA_A (INT_SUM[564]), .DATA_B (INT_SUM[565]), .DATA_C (INT_SUM[566]), .SAVE (INT_SUM[568]), .CARRY (INT_CARRY[462]) );
smfulladder dfa420 (.DATA_A (INT_SUM[567]), .DATA_B (INT_CARRY[449]), .DATA_C (INT_CARRY[450]), .SAVE (INT_SUM[569]), .CARRY (INT_CARRY[463]) );
assign INT_SUM[570] = INT_CARRY[451];
assign INT_SUM[571] = INT_CARRY[452];
smfulladder dfa421 (.DATA_A (INT_SUM[568]), .DATA_B (INT_SUM[569]), .DATA_C (INT_SUM[570]), .SAVE (INT_SUM[572]), .CARRY (INT_CARRY[464]) );
smfulladder dfa422 (.DATA_A (INT_SUM[571]), .DATA_B (INT_CARRY[453]), .DATA_C (INT_CARRY[454]), .SAVE (INT_SUM[573]), .CARRY (INT_CARRY[465]) );
smfulladder dfa423 (.DATA_A (INT_SUM[572]), .DATA_B (INT_SUM[573]), .DATA_C (INT_CARRY[455]), .SAVE (INT_SUM[574]), .CARRY (INT_CARRY[466]) );
assign INT_SUM[575] = INT_CARRY[456];
smfulladder dfa424 (.DATA_A (INT_SUM[574]), .DATA_B (INT_SUM[575]), .DATA_C (INT_CARRY[457]), .SAVE (INT_SUM[576]), .CARRY (INT_CARRY[458]) );
smffb dla625 (.D(INT_SUM[576]), .clk(clk), .en_d2(en_d2), .Q(SUM[48]) );
smffb dla626 (.D(INT_CARRY[458]), .clk(clk), .en_d2(en_d2), .Q(CARRY[48]) );
smffa dla627 (.D(SUMMAND[530]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[530]) );
smffa dla628 (.D(SUMMAND[531]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[531]) );
smffa dla629 (.D(SUMMAND[532]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[532]) );
smfulladder dfa425 (.DATA_A (LATCHED_PP[530]), .DATA_B (LATCHED_PP[531]), .DATA_C (LATCHED_PP[532]), .SAVE (INT_SUM[577]), .CARRY (INT_CARRY[468]) );
smffa dla630 (.D(SUMMAND[533]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[533]) );
smffa dla631 (.D(SUMMAND[534]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[534]) );
smffa dla632 (.D(SUMMAND[535]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[535]) );
smfulladder dfa426 (.DATA_A (LATCHED_PP[533]), .DATA_B (LATCHED_PP[534]), .DATA_C (LATCHED_PP[535]), .SAVE (INT_SUM[578]), .CARRY (INT_CARRY[469]) );
smffa dla633 (.D(SUMMAND[536]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[536]) );
smffa dla634 (.D(SUMMAND[537]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[537]) );
smffa dla635 (.D(SUMMAND[538]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[538]) );
smfulladder dfa427 (.DATA_A (LATCHED_PP[536]), .DATA_B (LATCHED_PP[537]), .DATA_C (LATCHED_PP[538]), .SAVE (INT_SUM[579]), .CARRY (INT_CARRY[470]) );
smffa dla636 (.D(SUMMAND[539]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[539]) );
assign INT_SUM[580] = LATCHED_PP[539];
smfulladder dfa428 (.DATA_A (INT_SUM[577]), .DATA_B (INT_SUM[578]), .DATA_C (INT_SUM[579]), .SAVE (INT_SUM[581]), .CARRY (INT_CARRY[471]) );
smfulladder dfa429 (.DATA_A (INT_SUM[580]), .DATA_B (INT_CARRY[459]), .DATA_C (INT_CARRY[460]), .SAVE (INT_SUM[582]), .CARRY (INT_CARRY[472]) );
assign INT_SUM[583] = INT_CARRY[461];
smfulladder dfa430 (.DATA_A (INT_SUM[581]), .DATA_B (INT_SUM[582]), .DATA_C (INT_SUM[583]), .SAVE (INT_SUM[584]), .CARRY (INT_CARRY[473]) );
smhalfadder dha42 (.DATA_A (INT_CARRY[462]), .DATA_B (INT_CARRY[463]), .SAVE (INT_SUM[585]), .CARRY (INT_CARRY[474]) );
smfulladder dfa431 (.DATA_A (INT_SUM[584]), .DATA_B (INT_SUM[585]), .DATA_C (INT_CARRY[464]), .SAVE (INT_SUM[586]), .CARRY (INT_CARRY[475]) );
assign INT_SUM[587] = INT_CARRY[465];
smfulladder dfa432 (.DATA_A (INT_SUM[586]), .DATA_B (INT_SUM[587]), .DATA_C (INT_CARRY[466]), .SAVE (INT_SUM[588]), .CARRY (INT_CARRY[467]) );
smffb dla637 (.D(INT_SUM[588]), .clk(clk), .en_d2(en_d2), .Q(SUM[49]) );
smffb dla638 (.D(INT_CARRY[467]), .clk(clk), .en_d2(en_d2), .Q(CARRY[49]) );
smffa dla639 (.D(SUMMAND[540]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[540]) );
smffa dla640 (.D(SUMMAND[541]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[541]) );
smffa dla641 (.D(SUMMAND[542]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[542]) );
smfulladder dfa433 (.DATA_A (LATCHED_PP[540]), .DATA_B (LATCHED_PP[541]), .DATA_C (LATCHED_PP[542]), .SAVE (INT_SUM[589]), .CARRY (INT_CARRY[477]) );
smffa dla642 (.D(SUMMAND[543]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[543]) );
smffa dla643 (.D(SUMMAND[544]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[544]) );
smffa dla644 (.D(SUMMAND[545]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[545]) );
smfulladder dfa434 (.DATA_A (LATCHED_PP[543]), .DATA_B (LATCHED_PP[544]), .DATA_C (LATCHED_PP[545]), .SAVE (INT_SUM[590]), .CARRY (INT_CARRY[478]) );
smffa dla645 (.D(SUMMAND[546]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[546]) );
smffa dla646 (.D(SUMMAND[547]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[547]) );
smffa dla647 (.D(SUMMAND[548]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[548]) );
smfulladder dfa435 (.DATA_A (LATCHED_PP[546]), .DATA_B (LATCHED_PP[547]), .DATA_C (LATCHED_PP[548]), .SAVE (INT_SUM[591]), .CARRY (INT_CARRY[479]) );
smfulladder dfa436 (.DATA_A (INT_SUM[589]), .DATA_B (INT_SUM[590]), .DATA_C (INT_SUM[591]), .SAVE (INT_SUM[592]), .CARRY (INT_CARRY[480]) );
smfulladder dfa437 (.DATA_A (INT_CARRY[468]), .DATA_B (INT_CARRY[469]), .DATA_C (INT_CARRY[470]), .SAVE (INT_SUM[593]), .CARRY (INT_CARRY[481]) );
smfulladder dfa438 (.DATA_A (INT_SUM[592]), .DATA_B (INT_SUM[593]), .DATA_C (INT_CARRY[471]), .SAVE (INT_SUM[594]), .CARRY (INT_CARRY[482]) );
assign INT_SUM[595] = INT_CARRY[472];
smfulladder dfa439 (.DATA_A (INT_SUM[594]), .DATA_B (INT_SUM[595]), .DATA_C (INT_CARRY[473]), .SAVE (INT_SUM[596]), .CARRY (INT_CARRY[483]) );
assign INT_SUM[597] = INT_CARRY[474];
smfulladder dfa440 (.DATA_A (INT_SUM[596]), .DATA_B (INT_SUM[597]), .DATA_C (INT_CARRY[475]), .SAVE (INT_SUM[598]), .CARRY (INT_CARRY[476]) );
smffb dla648 (.D(INT_SUM[598]), .clk(clk), .en_d2(en_d2), .Q(SUM[50]) );
smffb dla649 (.D(INT_CARRY[476]), .clk(clk), .en_d2(en_d2), .Q(CARRY[50]) );
smffa dla650 (.D(SUMMAND[549]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[549]) );
smffa dla651 (.D(SUMMAND[550]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[550]) );
smffa dla652 (.D(SUMMAND[551]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[551]) );
smfulladder dfa441 (.DATA_A (LATCHED_PP[549]), .DATA_B (LATCHED_PP[550]), .DATA_C (LATCHED_PP[551]), .SAVE (INT_SUM[599]), .CARRY (INT_CARRY[485]) );
smffa dla653 (.D(SUMMAND[552]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[552]) );
smffa dla654 (.D(SUMMAND[553]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[553]) );
smffa dla655 (.D(SUMMAND[554]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[554]) );
smfulladder dfa442 (.DATA_A (LATCHED_PP[552]), .DATA_B (LATCHED_PP[553]), .DATA_C (LATCHED_PP[554]), .SAVE (INT_SUM[600]), .CARRY (INT_CARRY[486]) );
smffa dla656 (.D(SUMMAND[555]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[555]) );
smffa dla657 (.D(SUMMAND[556]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[556]) );
smffa dla658 (.D(SUMMAND[557]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[557]) );
smfulladder dfa443 (.DATA_A (LATCHED_PP[555]), .DATA_B (LATCHED_PP[556]), .DATA_C (LATCHED_PP[557]), .SAVE (INT_SUM[601]), .CARRY (INT_CARRY[487]) );
smfulladder dfa444 (.DATA_A (INT_SUM[599]), .DATA_B (INT_SUM[600]), .DATA_C (INT_SUM[601]), .SAVE (INT_SUM[602]), .CARRY (INT_CARRY[488]) );
smfulladder dfa445 (.DATA_A (INT_CARRY[477]), .DATA_B (INT_CARRY[478]), .DATA_C (INT_CARRY[479]), .SAVE (INT_SUM[603]), .CARRY (INT_CARRY[489]) );
smfulladder dfa446 (.DATA_A (INT_SUM[602]), .DATA_B (INT_SUM[603]), .DATA_C (INT_CARRY[480]), .SAVE (INT_SUM[604]), .CARRY (INT_CARRY[490]) );
assign INT_SUM[605] = INT_CARRY[481];
smfulladder dfa447 (.DATA_A (INT_SUM[604]), .DATA_B (INT_SUM[605]), .DATA_C (INT_CARRY[482]), .SAVE (INT_SUM[606]), .CARRY (INT_CARRY[491]) );
smhalfadder dha43 (.DATA_A (INT_SUM[606]), .DATA_B (INT_CARRY[483]), .SAVE (INT_SUM[607]), .CARRY (INT_CARRY[484]) );
smffb dla659 (.D(INT_SUM[607]), .clk(clk), .en_d2(en_d2), .Q(SUM[51]) );
smffb dla660 (.D(INT_CARRY[484]), .clk(clk), .en_d2(en_d2), .Q(CARRY[51]) );
smffa dla661 (.D(SUMMAND[558]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[558]) );
smffa dla662 (.D(SUMMAND[559]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[559]) );
smffa dla663 (.D(SUMMAND[560]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[560]) );
smfulladder dfa448 (.DATA_A (LATCHED_PP[558]), .DATA_B (LATCHED_PP[559]), .DATA_C (LATCHED_PP[560]), .SAVE (INT_SUM[608]), .CARRY (INT_CARRY[493]) );
smffa dla664 (.D(SUMMAND[561]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[561]) );
smffa dla665 (.D(SUMMAND[562]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[562]) );
smffa dla666 (.D(SUMMAND[563]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[563]) );
smfulladder dfa449 (.DATA_A (LATCHED_PP[561]), .DATA_B (LATCHED_PP[562]), .DATA_C (LATCHED_PP[563]), .SAVE (INT_SUM[609]), .CARRY (INT_CARRY[494]) );
smffa dla667 (.D(SUMMAND[564]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[564]) );
smffa dla668 (.D(SUMMAND[565]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[565]) );
smfulladder dfa450 (.DATA_A (LATCHED_PP[564]), .DATA_B (LATCHED_PP[565]), .DATA_C (INT_CARRY[485]), .SAVE (INT_SUM[610]), .CARRY (INT_CARRY[495]) );
smhalfadder dha44 (.DATA_A (INT_CARRY[486]), .DATA_B (INT_CARRY[487]), .SAVE (INT_SUM[611]), .CARRY (INT_CARRY[496]) );
smfulladder dfa451 (.DATA_A (INT_SUM[608]), .DATA_B (INT_SUM[609]), .DATA_C (INT_SUM[610]), .SAVE (INT_SUM[612]), .CARRY (INT_CARRY[497]) );
smfulladder dfa452 (.DATA_A (INT_SUM[611]), .DATA_B (INT_CARRY[488]), .DATA_C (INT_CARRY[489]), .SAVE (INT_SUM[613]), .CARRY (INT_CARRY[498]) );
smfulladder dfa453 (.DATA_A (INT_SUM[612]), .DATA_B (INT_SUM[613]), .DATA_C (INT_CARRY[490]), .SAVE (INT_SUM[614]), .CARRY (INT_CARRY[499]) );
smhalfadder dha45 (.DATA_A (INT_SUM[614]), .DATA_B (INT_CARRY[491]), .SAVE (INT_SUM[615]), .CARRY (INT_CARRY[492]) );
smffb dla669 (.D(INT_SUM[615]), .clk(clk), .en_d2(en_d2), .Q(SUM[52]) );
smffb dla670 (.D(INT_CARRY[492]), .clk(clk), .en_d2(en_d2), .Q(CARRY[52]) );
smffa dla671 (.D(SUMMAND[566]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[566]) );
smffa dla672 (.D(SUMMAND[567]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[567]) );
smffa dla673 (.D(SUMMAND[568]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[568]) );
smfulladder dfa454 (.DATA_A (LATCHED_PP[566]), .DATA_B (LATCHED_PP[567]), .DATA_C (LATCHED_PP[568]), .SAVE (INT_SUM[616]), .CARRY (INT_CARRY[501]) );
smffa dla674 (.D(SUMMAND[569]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[569]) );
smffa dla675 (.D(SUMMAND[570]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[570]) );
smffa dla676 (.D(SUMMAND[571]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[571]) );
smfulladder dfa455 (.DATA_A (LATCHED_PP[569]), .DATA_B (LATCHED_PP[570]), .DATA_C (LATCHED_PP[571]), .SAVE (INT_SUM[617]), .CARRY (INT_CARRY[502]) );
smffa dla677 (.D(SUMMAND[572]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[572]) );
assign INT_SUM[618] = LATCHED_PP[572];
smffa dla678 (.D(SUMMAND[573]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[573]) );
assign INT_SUM[619] = LATCHED_PP[573];
smfulladder dfa456 (.DATA_A (INT_SUM[616]), .DATA_B (INT_SUM[617]), .DATA_C (INT_SUM[618]), .SAVE (INT_SUM[620]), .CARRY (INT_CARRY[503]) );
assign INT_SUM[621] = INT_SUM[619];
smfulladder dfa457 (.DATA_A (INT_SUM[620]), .DATA_B (INT_SUM[621]), .DATA_C (INT_CARRY[493]), .SAVE (INT_SUM[622]), .CARRY (INT_CARRY[504]) );
smfulladder dfa458 (.DATA_A (INT_CARRY[494]), .DATA_B (INT_CARRY[495]), .DATA_C (INT_CARRY[496]), .SAVE (INT_SUM[623]), .CARRY (INT_CARRY[505]) );
smfulladder dfa459 (.DATA_A (INT_SUM[622]), .DATA_B (INT_SUM[623]), .DATA_C (INT_CARRY[497]), .SAVE (INT_SUM[624]), .CARRY (INT_CARRY[506]) );
assign INT_SUM[625] = INT_CARRY[498];
smfulladder dfa460 (.DATA_A (INT_SUM[624]), .DATA_B (INT_SUM[625]), .DATA_C (INT_CARRY[499]), .SAVE (INT_SUM[626]), .CARRY (INT_CARRY[500]) );
smffb dla679 (.D(INT_SUM[626]), .clk(clk), .en_d2(en_d2), .Q(SUM[53]) );
smffb dla680 (.D(INT_CARRY[500]), .clk(clk), .en_d2(en_d2), .Q(CARRY[53]) );
smffa dla681 (.D(SUMMAND[574]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[574]) );
smffa dla682 (.D(SUMMAND[575]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[575]) );
smffa dla683 (.D(SUMMAND[576]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[576]) );
smfulladder dfa461 (.DATA_A (LATCHED_PP[574]), .DATA_B (LATCHED_PP[575]), .DATA_C (LATCHED_PP[576]), .SAVE (INT_SUM[627]), .CARRY (INT_CARRY[508]) );
smffa dla684 (.D(SUMMAND[577]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[577]) );
smffa dla685 (.D(SUMMAND[578]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[578]) );
smffa dla686 (.D(SUMMAND[579]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[579]) );
smfulladder dfa462 (.DATA_A (LATCHED_PP[577]), .DATA_B (LATCHED_PP[578]), .DATA_C (LATCHED_PP[579]), .SAVE (INT_SUM[628]), .CARRY (INT_CARRY[509]) );
smffa dla687 (.D(SUMMAND[580]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[580]) );
smfulladder dfa463 (.DATA_A (LATCHED_PP[580]), .DATA_B (INT_CARRY[501]), .DATA_C (INT_CARRY[502]), .SAVE (INT_SUM[629]), .CARRY (INT_CARRY[510]) );
smfulladder dfa464 (.DATA_A (INT_SUM[627]), .DATA_B (INT_SUM[628]), .DATA_C (INT_SUM[629]), .SAVE (INT_SUM[630]), .CARRY (INT_CARRY[511]) );
assign INT_SUM[631] = INT_CARRY[503];
smfulladder dfa465 (.DATA_A (INT_SUM[630]), .DATA_B (INT_SUM[631]), .DATA_C (INT_CARRY[504]), .SAVE (INT_SUM[632]), .CARRY (INT_CARRY[512]) );
assign INT_SUM[633] = INT_CARRY[505];
smfulladder dfa466 (.DATA_A (INT_SUM[632]), .DATA_B (INT_SUM[633]), .DATA_C (INT_CARRY[506]), .SAVE (INT_SUM[634]), .CARRY (INT_CARRY[507]) );
smffb dla688 (.D(INT_SUM[634]), .clk(clk), .en_d2(en_d2), .Q(SUM[54]) );
smffb dla689 (.D(INT_CARRY[507]), .clk(clk), .en_d2(en_d2), .Q(CARRY[54]) );
smffa dla690 (.D(SUMMAND[581]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[581]) );
smffa dla691 (.D(SUMMAND[582]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[582]) );
smffa dla692 (.D(SUMMAND[583]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[583]) );
smfulladder dfa467 (.DATA_A (LATCHED_PP[581]), .DATA_B (LATCHED_PP[582]), .DATA_C (LATCHED_PP[583]), .SAVE (INT_SUM[635]), .CARRY (INT_CARRY[514]) );
smffa dla693 (.D(SUMMAND[584]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[584]) );
smffa dla694 (.D(SUMMAND[585]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[585]) );
smffa dla695 (.D(SUMMAND[586]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[586]) );
smfulladder dfa468 (.DATA_A (LATCHED_PP[584]), .DATA_B (LATCHED_PP[585]), .DATA_C (LATCHED_PP[586]), .SAVE (INT_SUM[636]), .CARRY (INT_CARRY[515]) );
smffa dla696 (.D(SUMMAND[587]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[587]) );
assign INT_SUM[637] = LATCHED_PP[587];
smfulladder dfa469 (.DATA_A (INT_SUM[635]), .DATA_B (INT_SUM[636]), .DATA_C (INT_SUM[637]), .SAVE (INT_SUM[638]), .CARRY (INT_CARRY[516]) );
smfulladder dfa470 (.DATA_A (INT_CARRY[508]), .DATA_B (INT_CARRY[509]), .DATA_C (INT_CARRY[510]), .SAVE (INT_SUM[639]), .CARRY (INT_CARRY[517]) );
smfulladder dfa471 (.DATA_A (INT_SUM[638]), .DATA_B (INT_SUM[639]), .DATA_C (INT_CARRY[511]), .SAVE (INT_SUM[640]), .CARRY (INT_CARRY[518]) );
smhalfadder dha46 (.DATA_A (INT_SUM[640]), .DATA_B (INT_CARRY[512]), .SAVE (INT_SUM[641]), .CARRY (INT_CARRY[513]) );
smffb dla697 (.D(INT_SUM[641]), .clk(clk), .en_d2(en_d2), .Q(SUM[55]) );
smffb dla698 (.D(INT_CARRY[513]), .clk(clk), .en_d2(en_d2), .Q(CARRY[55]) );
smffa dla699 (.D(SUMMAND[588]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[588]) );
smffa dla700 (.D(SUMMAND[589]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[589]) );
smffa dla701 (.D(SUMMAND[590]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[590]) );
smfulladder dfa472 (.DATA_A (LATCHED_PP[588]), .DATA_B (LATCHED_PP[589]), .DATA_C (LATCHED_PP[590]), .SAVE (INT_SUM[642]), .CARRY (INT_CARRY[520]) );
smffa dla702 (.D(SUMMAND[591]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[591]) );
smffa dla703 (.D(SUMMAND[592]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[592]) );
smffa dla704 (.D(SUMMAND[593]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[593]) );
smfulladder dfa473 (.DATA_A (LATCHED_PP[591]), .DATA_B (LATCHED_PP[592]), .DATA_C (LATCHED_PP[593]), .SAVE (INT_SUM[643]), .CARRY (INT_CARRY[521]) );
smfulladder dfa474 (.DATA_A (INT_SUM[642]), .DATA_B (INT_SUM[643]), .DATA_C (INT_CARRY[514]), .SAVE (INT_SUM[644]), .CARRY (INT_CARRY[522]) );
assign INT_SUM[645] = INT_CARRY[515];
smfulladder dfa475 (.DATA_A (INT_SUM[644]), .DATA_B (INT_SUM[645]), .DATA_C (INT_CARRY[516]), .SAVE (INT_SUM[646]), .CARRY (INT_CARRY[523]) );
assign INT_SUM[647] = INT_CARRY[517];
smfulladder dfa476 (.DATA_A (INT_SUM[646]), .DATA_B (INT_SUM[647]), .DATA_C (INT_CARRY[518]), .SAVE (INT_SUM[648]), .CARRY (INT_CARRY[519]) );
smffb dla705 (.D(INT_SUM[648]), .clk(clk), .en_d2(en_d2), .Q(SUM[56]) );
smffb dla706 (.D(INT_CARRY[519]), .clk(clk), .en_d2(en_d2), .Q(CARRY[56]) );
smffa dla707 (.D(SUMMAND[594]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[594]) );
smffa dla708 (.D(SUMMAND[595]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[595]) );
smffa dla709 (.D(SUMMAND[596]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[596]) );
smfulladder dfa477 (.DATA_A (LATCHED_PP[594]), .DATA_B (LATCHED_PP[595]), .DATA_C (LATCHED_PP[596]), .SAVE (INT_SUM[649]), .CARRY (INT_CARRY[525]) );
smffa dla710 (.D(SUMMAND[597]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[597]) );
smffa dla711 (.D(SUMMAND[598]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[598]) );
smffa dla712 (.D(SUMMAND[599]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[599]) );
smfulladder dfa478 (.DATA_A (LATCHED_PP[597]), .DATA_B (LATCHED_PP[598]), .DATA_C (LATCHED_PP[599]), .SAVE (INT_SUM[650]), .CARRY (INT_CARRY[526]) );
smfulladder dfa479 (.DATA_A (INT_SUM[649]), .DATA_B (INT_SUM[650]), .DATA_C (INT_CARRY[520]), .SAVE (INT_SUM[651]), .CARRY (INT_CARRY[527]) );
assign INT_SUM[652] = INT_CARRY[521];
smfulladder dfa480 (.DATA_A (INT_SUM[651]), .DATA_B (INT_SUM[652]), .DATA_C (INT_CARRY[522]), .SAVE (INT_SUM[653]), .CARRY (INT_CARRY[528]) );
smhalfadder dha47 (.DATA_A (INT_SUM[653]), .DATA_B (INT_CARRY[523]), .SAVE (INT_SUM[654]), .CARRY (INT_CARRY[524]) );
smffb dla713 (.D(INT_SUM[654]), .clk(clk), .en_d2(en_d2), .Q(SUM[57]) );
smffb dla714 (.D(INT_CARRY[524]), .clk(clk), .en_d2(en_d2), .Q(CARRY[57]) );
smffa dla715 (.D(SUMMAND[600]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[600]) );
smffa dla716 (.D(SUMMAND[601]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[601]) );
smffa dla717 (.D(SUMMAND[602]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[602]) );
smfulladder dfa481 (.DATA_A (LATCHED_PP[600]), .DATA_B (LATCHED_PP[601]), .DATA_C (LATCHED_PP[602]), .SAVE (INT_SUM[655]), .CARRY (INT_CARRY[530]) );
smffa dla718 (.D(SUMMAND[603]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[603]) );
smffa dla719 (.D(SUMMAND[604]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[604]) );
smhalfadder dha48 (.DATA_A (LATCHED_PP[603]), .DATA_B (LATCHED_PP[604]), .SAVE (INT_SUM[656]), .CARRY (INT_CARRY[531]) );
smfulladder dfa482 (.DATA_A (INT_SUM[655]), .DATA_B (INT_SUM[656]), .DATA_C (INT_CARRY[525]), .SAVE (INT_SUM[657]), .CARRY (INT_CARRY[532]) );
assign INT_SUM[658] = INT_CARRY[526];
smfulladder dfa483 (.DATA_A (INT_SUM[657]), .DATA_B (INT_SUM[658]), .DATA_C (INT_CARRY[527]), .SAVE (INT_SUM[659]), .CARRY (INT_CARRY[533]) );
smhalfadder dha49 (.DATA_A (INT_SUM[659]), .DATA_B (INT_CARRY[528]), .SAVE (INT_SUM[660]), .CARRY (INT_CARRY[529]) );
smffb dla720 (.D(INT_SUM[660]), .clk(clk), .en_d2(en_d2), .Q(SUM[58]) );
smffb dla721 (.D(INT_CARRY[529]), .clk(clk), .en_d2(en_d2), .Q(CARRY[58]) );
smffa dla722 (.D(SUMMAND[605]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[605]) );
smffa dla723 (.D(SUMMAND[606]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[606]) );
smffa dla724 (.D(SUMMAND[607]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[607]) );
smfulladder dfa484 (.DATA_A (LATCHED_PP[605]), .DATA_B (LATCHED_PP[606]), .DATA_C (LATCHED_PP[607]), .SAVE (INT_SUM[661]), .CARRY (INT_CARRY[535]) );
smffa dla725 (.D(SUMMAND[608]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[608]) );
smffa dla726 (.D(SUMMAND[609]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[609]) );
smhalfadder dha50 (.DATA_A (LATCHED_PP[608]), .DATA_B (LATCHED_PP[609]), .SAVE (INT_SUM[662]), .CARRY (INT_CARRY[536]) );
smfulladder dfa485 (.DATA_A (INT_SUM[661]), .DATA_B (INT_SUM[662]), .DATA_C (INT_CARRY[530]), .SAVE (INT_SUM[663]), .CARRY (INT_CARRY[537]) );
assign INT_SUM[664] = INT_CARRY[531];
smfulladder dfa486 (.DATA_A (INT_SUM[663]), .DATA_B (INT_SUM[664]), .DATA_C (INT_CARRY[532]), .SAVE (INT_SUM[665]), .CARRY (INT_CARRY[538]) );
smhalfadder dha51 (.DATA_A (INT_SUM[665]), .DATA_B (INT_CARRY[533]), .SAVE (INT_SUM[666]), .CARRY (INT_CARRY[534]) );
smffb dla727 (.D(INT_SUM[666]), .clk(clk), .en_d2(en_d2), .Q(SUM[59]) );
smffb dla728 (.D(INT_CARRY[534]), .clk(clk), .en_d2(en_d2), .Q(CARRY[59]) );
smffa dla729 (.D(SUMMAND[610]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[610]) );
smffa dla730 (.D(SUMMAND[611]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[611]) );
smffa dla731 (.D(SUMMAND[612]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[612]) );
smfulladder dfa487 (.DATA_A (LATCHED_PP[610]), .DATA_B (LATCHED_PP[611]), .DATA_C (LATCHED_PP[612]), .SAVE (INT_SUM[667]), .CARRY (INT_CARRY[540]) );
smffa dla732 (.D(SUMMAND[613]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[613]) );
smfulladder dfa488 (.DATA_A (LATCHED_PP[613]), .DATA_B (INT_CARRY[535]), .DATA_C (INT_CARRY[536]), .SAVE (INT_SUM[668]), .CARRY (INT_CARRY[541]) );
smfulladder dfa489 (.DATA_A (INT_SUM[667]), .DATA_B (INT_SUM[668]), .DATA_C (INT_CARRY[537]), .SAVE (INT_SUM[669]), .CARRY (INT_CARRY[542]) );
smhalfadder dha52 (.DATA_A (INT_SUM[669]), .DATA_B (INT_CARRY[538]), .SAVE (INT_SUM[670]), .CARRY (INT_CARRY[539]) );
smffb dla733 (.D(INT_SUM[670]), .clk(clk), .en_d2(en_d2), .Q(SUM[60]) );
smffb dla734 (.D(INT_CARRY[539]), .clk(clk), .en_d2(en_d2), .Q(CARRY[60]) );
smffa dla735 (.D(SUMMAND[614]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[614]) );
smffa dla736 (.D(SUMMAND[615]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[615]) );
smffa dla737 (.D(SUMMAND[616]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[616]) );
smfulladder dfa490 (.DATA_A (LATCHED_PP[614]), .DATA_B (LATCHED_PP[615]), .DATA_C (LATCHED_PP[616]), .SAVE (INT_SUM[671]), .CARRY (INT_CARRY[544]) );
smffa dla738 (.D(SUMMAND[617]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[617]) );
assign INT_SUM[672] = LATCHED_PP[617];
smfulladder dfa491 (.DATA_A (INT_SUM[671]), .DATA_B (INT_SUM[672]), .DATA_C (INT_CARRY[540]), .SAVE (INT_SUM[673]), .CARRY (INT_CARRY[545]) );
assign INT_SUM[674] = INT_CARRY[541];
smfulladder dfa492 (.DATA_A (INT_SUM[673]), .DATA_B (INT_SUM[674]), .DATA_C (INT_CARRY[542]), .SAVE (INT_SUM[675]), .CARRY (INT_CARRY[543]) );
smffb dla739 (.D(INT_SUM[675]), .clk(clk), .en_d2(en_d2), .Q(SUM[61]) );
smffb dla740 (.D(INT_CARRY[543]), .clk(clk), .en_d2(en_d2), .Q(CARRY[61]) );
smffa dla741 (.D(SUMMAND[618]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[618]) );
smffa dla742 (.D(SUMMAND[619]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[619]) );
smffa dla743 (.D(SUMMAND[620]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[620]) );
smfulladder dfa493 (.DATA_A (LATCHED_PP[618]), .DATA_B (LATCHED_PP[619]), .DATA_C (LATCHED_PP[620]), .SAVE (INT_SUM[676]), .CARRY (INT_CARRY[547]) );
assign INT_SUM[677] = INT_SUM[676];
assign INT_SUM[678] = INT_CARRY[544];
smfulladder dfa494 (.DATA_A (INT_SUM[677]), .DATA_B (INT_SUM[678]), .DATA_C (INT_CARRY[545]), .SAVE (INT_SUM[679]), .CARRY (INT_CARRY[546]) );
smffb dla744 (.D(INT_SUM[679]), .clk(clk), .en_d2(en_d2), .Q(SUM[62]) );
smffb dla745 (.D(INT_CARRY[546]), .clk(clk), .en_d2(en_d2), .Q(CARRY[62]) );
smffa dla746 (.D(SUMMAND[621]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[621]) );
smffa dla747 (.D(SUMMAND[622]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[622]) );
smffa dla748 (.D(SUMMAND[623]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[623]) );
smfulladder dfa495 (.DATA_A (LATCHED_PP[621]), .DATA_B (LATCHED_PP[622]), .DATA_C (LATCHED_PP[623]), .SAVE (INT_SUM[680]), .CARRY (INT_CARRY[549]) );
assign INT_SUM[681] = INT_CARRY[547];
smhalfadder dha53 (.DATA_A (INT_SUM[680]), .DATA_B (INT_SUM[681]), .SAVE (INT_SUM[682]), .CARRY (INT_CARRY[548]) );
smffb dla749 (.D(INT_SUM[682]), .clk(clk), .en_d2(en_d2), .Q(SUM[63]) );
smffb dla750 (.D(INT_CARRY[548]), .clk(clk), .en_d2(en_d2), .Q(CARRY[63]) );
smffa dla751 (.D(SUMMAND[624]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[624]) );
assign INT_SUM[683] = LATCHED_PP[624];
smffa dla752 (.D(SUMMAND[625]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[625]) );
assign INT_SUM[684] = LATCHED_PP[625];
smfulladder dfa496 (.DATA_A (INT_SUM[683]), .DATA_B (INT_SUM[684]), .DATA_C (INT_CARRY[549]), .SAVE (INT_SUM[685]), .CARRY (INT_CARRY[550]) );
smffb dla753 (.D(INT_SUM[685]), .clk(clk), .en_d2(en_d2), .Q(SUM[64]) );
smffb dla754 (.D(INT_CARRY[550]), .clk(clk), .en_d2(en_d2), .Q(CARRY[64]) );
smffa dla755 (.D(SUMMAND[626]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[626]) );
smffa dla756 (.D(SUMMAND[627]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[627]) );
smhalfadder dha54 (.DATA_A (LATCHED_PP[626]), .DATA_B (LATCHED_PP[627]), .SAVE (INT_SUM[686]), .CARRY (INT_CARRY[551]) );
smffb dla757 (.D(INT_SUM[686]), .clk(clk), .en_d2(en_d2), .Q(SUM[65]) );
smffb dla758 (.D(INT_CARRY[551]), .clk(clk), .en_d2(en_d2), .Q(CARRY[65]) );
smffa dla759 (.D(SUMMAND[628]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[628]) );
assign INT_SUM[687] = LATCHED_PP[628];
smffb dla760 (.D(INT_SUM[687]), .clk(clk), .en_d2(en_d2), .Q(SUM[66]) );
endmodule
module smprestage_128 ( A, B, CIN, POUT, GOUT );
input [63:0] A;
input [63:0] B;
input CIN;
output [63:0] POUT;
output [63:0] GOUT;
smblock0 d10 (A[0], B[0], POUT[0], GOUT[1] );
smblock0 d11 (A[1], B[1], POUT[1], GOUT[2] );
smblock0 d12 (A[2], B[2], POUT[2], GOUT[3] );
smblock0 d13 (A[3], B[3], POUT[3], GOUT[4] );
smblock0 d14 (A[4], B[4], POUT[4], GOUT[5] );
smblock0 d15 (A[5], B[5], POUT[5], GOUT[6] );
smblock0 d16 (A[6], B[6], POUT[6], GOUT[7] );
smblock0 d17 (A[7], B[7], POUT[7], GOUT[8] );
smblock0 d18 (A[8], B[8], POUT[8], GOUT[9] );
smblock0 d19 (A[9], B[9], POUT[9], GOUT[10] );
smblock0 d110 (A[10], B[10], POUT[10], GOUT[11] );
smblock0 d111 (A[11], B[11], POUT[11], GOUT[12] );
smblock0 d112 (A[12], B[12], POUT[12], GOUT[13] );
smblock0 d113 (A[13], B[13], POUT[13], GOUT[14] );
smblock0 d114 (A[14], B[14], POUT[14], GOUT[15] );
smblock0 d115 (A[15], B[15], POUT[15], GOUT[16] );
smblock0 d116 (A[16], B[16], POUT[16], GOUT[17] );
smblock0 d117 (A[17], B[17], POUT[17], GOUT[18] );
smblock0 d118 (A[18], B[18], POUT[18], GOUT[19] );
smblock0 d119 (A[19], B[19], POUT[19], GOUT[20] );
smblock0 d120 (A[20], B[20], POUT[20], GOUT[21] );
smblock0 d121 (A[21], B[21], POUT[21], GOUT[22] );
smblock0 d122 (A[22], B[22], POUT[22], GOUT[23] );
smblock0 d123 (A[23], B[23], POUT[23], GOUT[24] );
smblock0 d124 (A[24], B[24], POUT[24], GOUT[25] );
smblock0 d125 (A[25], B[25], POUT[25], GOUT[26] );
smblock0 d126 (A[26], B[26], POUT[26], GOUT[27] );
smblock0 d127 (A[27], B[27], POUT[27], GOUT[28] );
smblock0 d128 (A[28], B[28], POUT[28], GOUT[29] );
smblock0 d129 (A[29], B[29], POUT[29], GOUT[30] );
smblock0 d130 (A[30], B[30], POUT[30], GOUT[31] );
smblock0 d131 (A[31], B[31], POUT[31], GOUT[32] );
smblock0 d132 (A[32], B[32], POUT[32], GOUT[33] );
smblock0 d133 (A[33], B[33], POUT[33], GOUT[34] );
smblock0 d134 (A[34], B[34], POUT[34], GOUT[35] );
smblock0 d135 (A[35], B[35], POUT[35], GOUT[36] );
smblock0 d136 (A[36], B[36], POUT[36], GOUT[37] );
smblock0 d137 (A[37], B[37], POUT[37], GOUT[38] );
smblock0 d138 (A[38], B[38], POUT[38], GOUT[39] );
smblock0 d139 (A[39], B[39], POUT[39], GOUT[40] );
smblock0 d140 (A[40], B[40], POUT[40], GOUT[41] );
smblock0 d141 (A[41], B[41], POUT[41], GOUT[42] );
smblock0 d142 (A[42], B[42], POUT[42], GOUT[43] );
smblock0 d143 (A[43], B[43], POUT[43], GOUT[44] );
smblock0 d144 (A[44], B[44], POUT[44], GOUT[45] );
smblock0 d145 (A[45], B[45], POUT[45], GOUT[46] );
smblock0 d146 (A[46], B[46], POUT[46], GOUT[47] );
smblock0 d147 (A[47], B[47], POUT[47], GOUT[48] );
smblock0 d148 (A[48], B[48], POUT[48], GOUT[49] );
smblock0 d149 (A[49], B[49], POUT[49], GOUT[50] );
smblock0 d150 (A[50], B[50], POUT[50], GOUT[51] );
smblock0 d151 (A[51], B[51], POUT[51], GOUT[52] );
smblock0 d152 (A[52], B[52], POUT[52], GOUT[53] );
smblock0 d153 (A[53], B[53], POUT[53], GOUT[54] );
smblock0 d154 (A[54], B[54], POUT[54], GOUT[55] );
smblock0 d155 (A[55], B[55], POUT[55], GOUT[56] );
smblock0 d156 (A[56], B[56], POUT[56], GOUT[57] );
smblock0 d157 (A[57], B[57], POUT[57], GOUT[58] );
smblock0 d158 (A[58], B[58], POUT[58], GOUT[59] );
smblock0 d159 (A[59], B[59], POUT[59], GOUT[60] );
smblock0 d160 (A[60], B[60], POUT[60], GOUT[61] );
smblock0 d161 (A[61], B[61], POUT[61], GOUT[62] );
smblock0 d162 (A[62], B[62], POUT[62], GOUT[63] );
sminvblock d2 (CIN, GOUT[0] );
endmodule
module smdblc_0_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
smblock1a d21 (PIN[0], GIN[0], GIN[1], GOUT[1] );
smblock1 d32 (PIN[0], PIN[1], GIN[1], GIN[2], POUT[0], GOUT[2] );
smblock1 d33 (PIN[1], PIN[2], GIN[2], GIN[3], POUT[1], GOUT[3] );
smblock1 d34 (PIN[2], PIN[3], GIN[3], GIN[4], POUT[2], GOUT[4] );
smblock1 d35 (PIN[3], PIN[4], GIN[4], GIN[5], POUT[3], GOUT[5] );
smblock1 d36 (PIN[4], PIN[5], GIN[5], GIN[6], POUT[4], GOUT[6] );
smblock1 d37 (PIN[5], PIN[6], GIN[6], GIN[7], POUT[5], GOUT[7] );
smblock1 d38 (PIN[6], PIN[7], GIN[7], GIN[8], POUT[6], GOUT[8] );
smblock1 d39 (PIN[7], PIN[8], GIN[8], GIN[9], POUT[7], GOUT[9] );
smblock1 d310 (PIN[8], PIN[9], GIN[9], GIN[10], POUT[8], GOUT[10] );
smblock1 d311 (PIN[9], PIN[10], GIN[10], GIN[11], POUT[9], GOUT[11] );
smblock1 d312 (PIN[10], PIN[11], GIN[11], GIN[12], POUT[10], GOUT[12] );
smblock1 d313 (PIN[11], PIN[12], GIN[12], GIN[13], POUT[11], GOUT[13] );
smblock1 d314 (PIN[12], PIN[13], GIN[13], GIN[14], POUT[12], GOUT[14] );
smblock1 d315 (PIN[13], PIN[14], GIN[14], GIN[15], POUT[13], GOUT[15] );
smblock1 d316 (PIN[14], PIN[15], GIN[15], GIN[16], POUT[14], GOUT[16] );
smblock1 d317 (PIN[15], PIN[16], GIN[16], GIN[17], POUT[15], GOUT[17] );
smblock1 d318 (PIN[16], PIN[17], GIN[17], GIN[18], POUT[16], GOUT[18] );
smblock1 d319 (PIN[17], PIN[18], GIN[18], GIN[19], POUT[17], GOUT[19] );
smblock1 d320 (PIN[18], PIN[19], GIN[19], GIN[20], POUT[18], GOUT[20] );
smblock1 d321 (PIN[19], PIN[20], GIN[20], GIN[21], POUT[19], GOUT[21] );
smblock1 d322 (PIN[20], PIN[21], GIN[21], GIN[22], POUT[20], GOUT[22] );
smblock1 d323 (PIN[21], PIN[22], GIN[22], GIN[23], POUT[21], GOUT[23] );
smblock1 d324 (PIN[22], PIN[23], GIN[23], GIN[24], POUT[22], GOUT[24] );
smblock1 d325 (PIN[23], PIN[24], GIN[24], GIN[25], POUT[23], GOUT[25] );
smblock1 d326 (PIN[24], PIN[25], GIN[25], GIN[26], POUT[24], GOUT[26] );
smblock1 d327 (PIN[25], PIN[26], GIN[26], GIN[27], POUT[25], GOUT[27] );
smblock1 d328 (PIN[26], PIN[27], GIN[27], GIN[28], POUT[26], GOUT[28] );
smblock1 d329 (PIN[27], PIN[28], GIN[28], GIN[29], POUT[27], GOUT[29] );
smblock1 d330 (PIN[28], PIN[29], GIN[29], GIN[30], POUT[28], GOUT[30] );
smblock1 d331 (PIN[29], PIN[30], GIN[30], GIN[31], POUT[29], GOUT[31] );
smblock1 d332 (PIN[30], PIN[31], GIN[31], GIN[32], POUT[30], GOUT[32] );
smblock1 d333 (PIN[31], PIN[32], GIN[32], GIN[33], POUT[31], GOUT[33] );
smblock1 d334 (PIN[32], PIN[33], GIN[33], GIN[34], POUT[32], GOUT[34] );
smblock1 d335 (PIN[33], PIN[34], GIN[34], GIN[35], POUT[33], GOUT[35] );
smblock1 d336 (PIN[34], PIN[35], GIN[35], GIN[36], POUT[34], GOUT[36] );
smblock1 d337 (PIN[35], PIN[36], GIN[36], GIN[37], POUT[35], GOUT[37] );
smblock1 d338 (PIN[36], PIN[37], GIN[37], GIN[38], POUT[36], GOUT[38] );
smblock1 d339 (PIN[37], PIN[38], GIN[38], GIN[39], POUT[37], GOUT[39] );
smblock1 d340 (PIN[38], PIN[39], GIN[39], GIN[40], POUT[38], GOUT[40] );
smblock1 d341 (PIN[39], PIN[40], GIN[40], GIN[41], POUT[39], GOUT[41] );
smblock1 d342 (PIN[40], PIN[41], GIN[41], GIN[42], POUT[40], GOUT[42] );
smblock1 d343 (PIN[41], PIN[42], GIN[42], GIN[43], POUT[41], GOUT[43] );
smblock1 d344 (PIN[42], PIN[43], GIN[43], GIN[44], POUT[42], GOUT[44] );
smblock1 d345 (PIN[43], PIN[44], GIN[44], GIN[45], POUT[43], GOUT[45] );
smblock1 d346 (PIN[44], PIN[45], GIN[45], GIN[46], POUT[44], GOUT[46] );
smblock1 d347 (PIN[45], PIN[46], GIN[46], GIN[47], POUT[45], GOUT[47] );
smblock1 d348 (PIN[46], PIN[47], GIN[47], GIN[48], POUT[46], GOUT[48] );
smblock1 d349 (PIN[47], PIN[48], GIN[48], GIN[49], POUT[47], GOUT[49] );
smblock1 d350 (PIN[48], PIN[49], GIN[49], GIN[50], POUT[48], GOUT[50] );
smblock1 d351 (PIN[49], PIN[50], GIN[50], GIN[51], POUT[49], GOUT[51] );
smblock1 d352 (PIN[50], PIN[51], GIN[51], GIN[52], POUT[50], GOUT[52] );
smblock1 d353 (PIN[51], PIN[52], GIN[52], GIN[53], POUT[51], GOUT[53] );
smblock1 d354 (PIN[52], PIN[53], GIN[53], GIN[54], POUT[52], GOUT[54] );
smblock1 d355 (PIN[53], PIN[54], GIN[54], GIN[55], POUT[53], GOUT[55] );
smblock1 d356 (PIN[54], PIN[55], GIN[55], GIN[56], POUT[54], GOUT[56] );
smblock1 d357 (PIN[55], PIN[56], GIN[56], GIN[57], POUT[55], GOUT[57] );
smblock1 d358 (PIN[56], PIN[57], GIN[57], GIN[58], POUT[56], GOUT[58] );
smblock1 d359 (PIN[57], PIN[58], GIN[58], GIN[59], POUT[57], GOUT[59] );
smblock1 d360 (PIN[58], PIN[59], GIN[59], GIN[60], POUT[58], GOUT[60] );
smblock1 d361 (PIN[59], PIN[60], GIN[60], GIN[61], POUT[59], GOUT[61] );
smblock1 d362 (PIN[60], PIN[61], GIN[61], GIN[62], POUT[60], GOUT[62] );
smblock1 d363 (PIN[61], PIN[62], GIN[62], GIN[63], POUT[61], GOUT[63] );
endmodule
module smdblc_1_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
smblock2a d22 (PIN[0], GIN[0], GIN[2], GOUT[2] );
smblock2a d23 (PIN[1], GIN[1], GIN[3], GOUT[3] );
smblock2 d34 (PIN[0], PIN[2], GIN[2], GIN[4], POUT[0], GOUT[4] );
smblock2 d35 (PIN[1], PIN[3], GIN[3], GIN[5], POUT[1], GOUT[5] );
smblock2 d36 (PIN[2], PIN[4], GIN[4], GIN[6], POUT[2], GOUT[6] );
smblock2 d37 (PIN[3], PIN[5], GIN[5], GIN[7], POUT[3], GOUT[7] );
smblock2 d38 (PIN[4], PIN[6], GIN[6], GIN[8], POUT[4], GOUT[8] );
smblock2 d39 (PIN[5], PIN[7], GIN[7], GIN[9], POUT[5], GOUT[9] );
smblock2 d310 (PIN[6], PIN[8], GIN[8], GIN[10], POUT[6], GOUT[10] );
smblock2 d311 (PIN[7], PIN[9], GIN[9], GIN[11], POUT[7], GOUT[11] );
smblock2 d312 (PIN[8], PIN[10], GIN[10], GIN[12], POUT[8], GOUT[12] );
smblock2 d313 (PIN[9], PIN[11], GIN[11], GIN[13], POUT[9], GOUT[13] );
smblock2 d314 (PIN[10], PIN[12], GIN[12], GIN[14], POUT[10], GOUT[14] );
smblock2 d315 (PIN[11], PIN[13], GIN[13], GIN[15], POUT[11], GOUT[15] );
smblock2 d316 (PIN[12], PIN[14], GIN[14], GIN[16], POUT[12], GOUT[16] );
smblock2 d317 (PIN[13], PIN[15], GIN[15], GIN[17], POUT[13], GOUT[17] );
smblock2 d318 (PIN[14], PIN[16], GIN[16], GIN[18], POUT[14], GOUT[18] );
smblock2 d319 (PIN[15], PIN[17], GIN[17], GIN[19], POUT[15], GOUT[19] );
smblock2 d320 (PIN[16], PIN[18], GIN[18], GIN[20], POUT[16], GOUT[20] );
smblock2 d321 (PIN[17], PIN[19], GIN[19], GIN[21], POUT[17], GOUT[21] );
smblock2 d322 (PIN[18], PIN[20], GIN[20], GIN[22], POUT[18], GOUT[22] );
smblock2 d323 (PIN[19], PIN[21], GIN[21], GIN[23], POUT[19], GOUT[23] );
smblock2 d324 (PIN[20], PIN[22], GIN[22], GIN[24], POUT[20], GOUT[24] );
smblock2 d325 (PIN[21], PIN[23], GIN[23], GIN[25], POUT[21], GOUT[25] );
smblock2 d326 (PIN[22], PIN[24], GIN[24], GIN[26], POUT[22], GOUT[26] );
smblock2 d327 (PIN[23], PIN[25], GIN[25], GIN[27], POUT[23], GOUT[27] );
smblock2 d328 (PIN[24], PIN[26], GIN[26], GIN[28], POUT[24], GOUT[28] );
smblock2 d329 (PIN[25], PIN[27], GIN[27], GIN[29], POUT[25], GOUT[29] );
smblock2 d330 (PIN[26], PIN[28], GIN[28], GIN[30], POUT[26], GOUT[30] );
smblock2 d331 (PIN[27], PIN[29], GIN[29], GIN[31], POUT[27], GOUT[31] );
smblock2 d332 (PIN[28], PIN[30], GIN[30], GIN[32], POUT[28], GOUT[32] );
smblock2 d333 (PIN[29], PIN[31], GIN[31], GIN[33], POUT[29], GOUT[33] );
smblock2 d334 (PIN[30], PIN[32], GIN[32], GIN[34], POUT[30], GOUT[34] );
smblock2 d335 (PIN[31], PIN[33], GIN[33], GIN[35], POUT[31], GOUT[35] );
smblock2 d336 (PIN[32], PIN[34], GIN[34], GIN[36], POUT[32], GOUT[36] );
smblock2 d337 (PIN[33], PIN[35], GIN[35], GIN[37], POUT[33], GOUT[37] );
smblock2 d338 (PIN[34], PIN[36], GIN[36], GIN[38], POUT[34], GOUT[38] );
smblock2 d339 (PIN[35], PIN[37], GIN[37], GIN[39], POUT[35], GOUT[39] );
smblock2 d340 (PIN[36], PIN[38], GIN[38], GIN[40], POUT[36], GOUT[40] );
smblock2 d341 (PIN[37], PIN[39], GIN[39], GIN[41], POUT[37], GOUT[41] );
smblock2 d342 (PIN[38], PIN[40], GIN[40], GIN[42], POUT[38], GOUT[42] );
smblock2 d343 (PIN[39], PIN[41], GIN[41], GIN[43], POUT[39], GOUT[43] );
smblock2 d344 (PIN[40], PIN[42], GIN[42], GIN[44], POUT[40], GOUT[44] );
smblock2 d345 (PIN[41], PIN[43], GIN[43], GIN[45], POUT[41], GOUT[45] );
smblock2 d346 (PIN[42], PIN[44], GIN[44], GIN[46], POUT[42], GOUT[46] );
smblock2 d347 (PIN[43], PIN[45], GIN[45], GIN[47], POUT[43], GOUT[47] );
smblock2 d348 (PIN[44], PIN[46], GIN[46], GIN[48], POUT[44], GOUT[48] );
smblock2 d349 (PIN[45], PIN[47], GIN[47], GIN[49], POUT[45], GOUT[49] );
smblock2 d350 (PIN[46], PIN[48], GIN[48], GIN[50], POUT[46], GOUT[50] );
smblock2 d351 (PIN[47], PIN[49], GIN[49], GIN[51], POUT[47], GOUT[51] );
smblock2 d352 (PIN[48], PIN[50], GIN[50], GIN[52], POUT[48], GOUT[52] );
smblock2 d353 (PIN[49], PIN[51], GIN[51], GIN[53], POUT[49], GOUT[53] );
smblock2 d354 (PIN[50], PIN[52], GIN[52], GIN[54], POUT[50], GOUT[54] );
smblock2 d355 (PIN[51], PIN[53], GIN[53], GIN[55], POUT[51], GOUT[55] );
smblock2 d356 (PIN[52], PIN[54], GIN[54], GIN[56], POUT[52], GOUT[56] );
smblock2 d357 (PIN[53], PIN[55], GIN[55], GIN[57], POUT[53], GOUT[57] );
smblock2 d358 (PIN[54], PIN[56], GIN[56], GIN[58], POUT[54], GOUT[58] );
smblock2 d359 (PIN[55], PIN[57], GIN[57], GIN[59], POUT[55], GOUT[59] );
smblock2 d360 (PIN[56], PIN[58], GIN[58], GIN[60], POUT[56], GOUT[60] );
smblock2 d361 (PIN[57], PIN[59], GIN[59], GIN[61], POUT[57], GOUT[61] );
smblock2 d362 (PIN[58], PIN[60], GIN[60], GIN[62], POUT[58], GOUT[62] );
smblock2 d363 (PIN[59], PIN[61], GIN[61], GIN[63], POUT[59], GOUT[63] );
endmodule
module smdblc_2_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
sminvblock d12 (GIN[2], GOUT[2] );
sminvblock d13 (GIN[3], GOUT[3] );
smblock1a d24 (PIN[0], GIN[0], GIN[4], GOUT[4] );
smblock1a d25 (PIN[1], GIN[1], GIN[5], GOUT[5] );
smblock1a d26 (PIN[2], GIN[2], GIN[6], GOUT[6] );
smblock1a d27 (PIN[3], GIN[3], GIN[7], GOUT[7] );
smblock1 d38 (PIN[0], PIN[4], GIN[4], GIN[8], POUT[0], GOUT[8] );
smblock1 d39 (PIN[1], PIN[5], GIN[5], GIN[9], POUT[1], GOUT[9] );
smblock1 d310 (PIN[2], PIN[6], GIN[6], GIN[10], POUT[2], GOUT[10] );
smblock1 d311 (PIN[3], PIN[7], GIN[7], GIN[11], POUT[3], GOUT[11] );
smblock1 d312 (PIN[4], PIN[8], GIN[8], GIN[12], POUT[4], GOUT[12] );
smblock1 d313 (PIN[5], PIN[9], GIN[9], GIN[13], POUT[5], GOUT[13] );
smblock1 d314 (PIN[6], PIN[10], GIN[10], GIN[14], POUT[6], GOUT[14] );
smblock1 d315 (PIN[7], PIN[11], GIN[11], GIN[15], POUT[7], GOUT[15] );
smblock1 d316 (PIN[8], PIN[12], GIN[12], GIN[16], POUT[8], GOUT[16] );
smblock1 d317 (PIN[9], PIN[13], GIN[13], GIN[17], POUT[9], GOUT[17] );
smblock1 d318 (PIN[10], PIN[14], GIN[14], GIN[18], POUT[10], GOUT[18] );
smblock1 d319 (PIN[11], PIN[15], GIN[15], GIN[19], POUT[11], GOUT[19] );
smblock1 d320 (PIN[12], PIN[16], GIN[16], GIN[20], POUT[12], GOUT[20] );
smblock1 d321 (PIN[13], PIN[17], GIN[17], GIN[21], POUT[13], GOUT[21] );
smblock1 d322 (PIN[14], PIN[18], GIN[18], GIN[22], POUT[14], GOUT[22] );
smblock1 d323 (PIN[15], PIN[19], GIN[19], GIN[23], POUT[15], GOUT[23] );
smblock1 d324 (PIN[16], PIN[20], GIN[20], GIN[24], POUT[16], GOUT[24] );
smblock1 d325 (PIN[17], PIN[21], GIN[21], GIN[25], POUT[17], GOUT[25] );
smblock1 d326 (PIN[18], PIN[22], GIN[22], GIN[26], POUT[18], GOUT[26] );
smblock1 d327 (PIN[19], PIN[23], GIN[23], GIN[27], POUT[19], GOUT[27] );
smblock1 d328 (PIN[20], PIN[24], GIN[24], GIN[28], POUT[20], GOUT[28] );
smblock1 d329 (PIN[21], PIN[25], GIN[25], GIN[29], POUT[21], GOUT[29] );
smblock1 d330 (PIN[22], PIN[26], GIN[26], GIN[30], POUT[22], GOUT[30] );
smblock1 d331 (PIN[23], PIN[27], GIN[27], GIN[31], POUT[23], GOUT[31] );
smblock1 d332 (PIN[24], PIN[28], GIN[28], GIN[32], POUT[24], GOUT[32] );
smblock1 d333 (PIN[25], PIN[29], GIN[29], GIN[33], POUT[25], GOUT[33] );
smblock1 d334 (PIN[26], PIN[30], GIN[30], GIN[34], POUT[26], GOUT[34] );
smblock1 d335 (PIN[27], PIN[31], GIN[31], GIN[35], POUT[27], GOUT[35] );
smblock1 d336 (PIN[28], PIN[32], GIN[32], GIN[36], POUT[28], GOUT[36] );
smblock1 d337 (PIN[29], PIN[33], GIN[33], GIN[37], POUT[29], GOUT[37] );
smblock1 d338 (PIN[30], PIN[34], GIN[34], GIN[38], POUT[30], GOUT[38] );
smblock1 d339 (PIN[31], PIN[35], GIN[35], GIN[39], POUT[31], GOUT[39] );
smblock1 d340 (PIN[32], PIN[36], GIN[36], GIN[40], POUT[32], GOUT[40] );
smblock1 d341 (PIN[33], PIN[37], GIN[37], GIN[41], POUT[33], GOUT[41] );
smblock1 d342 (PIN[34], PIN[38], GIN[38], GIN[42], POUT[34], GOUT[42] );
smblock1 d343 (PIN[35], PIN[39], GIN[39], GIN[43], POUT[35], GOUT[43] );
smblock1 d344 (PIN[36], PIN[40], GIN[40], GIN[44], POUT[36], GOUT[44] );
smblock1 d345 (PIN[37], PIN[41], GIN[41], GIN[45], POUT[37], GOUT[45] );
smblock1 d346 (PIN[38], PIN[42], GIN[42], GIN[46], POUT[38], GOUT[46] );
smblock1 d347 (PIN[39], PIN[43], GIN[43], GIN[47], POUT[39], GOUT[47] );
smblock1 d348 (PIN[40], PIN[44], GIN[44], GIN[48], POUT[40], GOUT[48] );
smblock1 d349 (PIN[41], PIN[45], GIN[45], GIN[49], POUT[41], GOUT[49] );
smblock1 d350 (PIN[42], PIN[46], GIN[46], GIN[50], POUT[42], GOUT[50] );
smblock1 d351 (PIN[43], PIN[47], GIN[47], GIN[51], POUT[43], GOUT[51] );
smblock1 d352 (PIN[44], PIN[48], GIN[48], GIN[52], POUT[44], GOUT[52] );
smblock1 d353 (PIN[45], PIN[49], GIN[49], GIN[53], POUT[45], GOUT[53] );
smblock1 d354 (PIN[46], PIN[50], GIN[50], GIN[54], POUT[46], GOUT[54] );
smblock1 d355 (PIN[47], PIN[51], GIN[51], GIN[55], POUT[47], GOUT[55] );
smblock1 d356 (PIN[48], PIN[52], GIN[52], GIN[56], POUT[48], GOUT[56] );
smblock1 d357 (PIN[49], PIN[53], GIN[53], GIN[57], POUT[49], GOUT[57] );
smblock1 d358 (PIN[50], PIN[54], GIN[54], GIN[58], POUT[50], GOUT[58] );
smblock1 d359 (PIN[51], PIN[55], GIN[55], GIN[59], POUT[51], GOUT[59] );
smblock1 d360 (PIN[52], PIN[56], GIN[56], GIN[60], POUT[52], GOUT[60] );
smblock1 d361 (PIN[53], PIN[57], GIN[57], GIN[61], POUT[53], GOUT[61] );
smblock1 d362 (PIN[54], PIN[58], GIN[58], GIN[62], POUT[54], GOUT[62] );
smblock1 d363 (PIN[55], PIN[59], GIN[59], GIN[63], POUT[55], GOUT[63] );
endmodule
module smdblc_3_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
sminvblock d12 (GIN[2], GOUT[2] );
sminvblock d13 (GIN[3], GOUT[3] );
sminvblock d14 (GIN[4], GOUT[4] );
sminvblock d15 (GIN[5], GOUT[5] );
sminvblock d16 (GIN[6], GOUT[6] );
sminvblock d17 (GIN[7], GOUT[7] );
smblock2a d28 (PIN[0], GIN[0], GIN[8], GOUT[8] );
smblock2a d29 (PIN[1], GIN[1], GIN[9], GOUT[9] );
smblock2a d210 (PIN[2], GIN[2], GIN[10], GOUT[10] );
smblock2a d211 (PIN[3], GIN[3], GIN[11], GOUT[11] );
smblock2a d212 (PIN[4], GIN[4], GIN[12], GOUT[12] );
smblock2a d213 (PIN[5], GIN[5], GIN[13], GOUT[13] );
smblock2a d214 (PIN[6], GIN[6], GIN[14], GOUT[14] );
smblock2a d215 (PIN[7], GIN[7], GIN[15], GOUT[15] );
smblock2 d316 (PIN[0], PIN[8], GIN[8], GIN[16], POUT[0], GOUT[16] );
smblock2 d317 (PIN[1], PIN[9], GIN[9], GIN[17], POUT[1], GOUT[17] );
smblock2 d318 (PIN[2], PIN[10], GIN[10], GIN[18], POUT[2], GOUT[18] );
smblock2 d319 (PIN[3], PIN[11], GIN[11], GIN[19], POUT[3], GOUT[19] );
smblock2 d320 (PIN[4], PIN[12], GIN[12], GIN[20], POUT[4], GOUT[20] );
smblock2 d321 (PIN[5], PIN[13], GIN[13], GIN[21], POUT[5], GOUT[21] );
smblock2 d322 (PIN[6], PIN[14], GIN[14], GIN[22], POUT[6], GOUT[22] );
smblock2 d323 (PIN[7], PIN[15], GIN[15], GIN[23], POUT[7], GOUT[23] );
smblock2 d324 (PIN[8], PIN[16], GIN[16], GIN[24], POUT[8], GOUT[24] );
smblock2 d325 (PIN[9], PIN[17], GIN[17], GIN[25], POUT[9], GOUT[25] );
smblock2 d326 (PIN[10], PIN[18], GIN[18], GIN[26], POUT[10], GOUT[26] );
smblock2 d327 (PIN[11], PIN[19], GIN[19], GIN[27], POUT[11], GOUT[27] );
smblock2 d328 (PIN[12], PIN[20], GIN[20], GIN[28], POUT[12], GOUT[28] );
smblock2 d329 (PIN[13], PIN[21], GIN[21], GIN[29], POUT[13], GOUT[29] );
smblock2 d330 (PIN[14], PIN[22], GIN[22], GIN[30], POUT[14], GOUT[30] );
smblock2 d331 (PIN[15], PIN[23], GIN[23], GIN[31], POUT[15], GOUT[31] );
smblock2 d332 (PIN[16], PIN[24], GIN[24], GIN[32], POUT[16], GOUT[32] );
smblock2 d333 (PIN[17], PIN[25], GIN[25], GIN[33], POUT[17], GOUT[33] );
smblock2 d334 (PIN[18], PIN[26], GIN[26], GIN[34], POUT[18], GOUT[34] );
smblock2 d335 (PIN[19], PIN[27], GIN[27], GIN[35], POUT[19], GOUT[35] );
smblock2 d336 (PIN[20], PIN[28], GIN[28], GIN[36], POUT[20], GOUT[36] );
smblock2 d337 (PIN[21], PIN[29], GIN[29], GIN[37], POUT[21], GOUT[37] );
smblock2 d338 (PIN[22], PIN[30], GIN[30], GIN[38], POUT[22], GOUT[38] );
smblock2 d339 (PIN[23], PIN[31], GIN[31], GIN[39], POUT[23], GOUT[39] );
smblock2 d340 (PIN[24], PIN[32], GIN[32], GIN[40], POUT[24], GOUT[40] );
smblock2 d341 (PIN[25], PIN[33], GIN[33], GIN[41], POUT[25], GOUT[41] );
smblock2 d342 (PIN[26], PIN[34], GIN[34], GIN[42], POUT[26], GOUT[42] );
smblock2 d343 (PIN[27], PIN[35], GIN[35], GIN[43], POUT[27], GOUT[43] );
smblock2 d344 (PIN[28], PIN[36], GIN[36], GIN[44], POUT[28], GOUT[44] );
smblock2 d345 (PIN[29], PIN[37], GIN[37], GIN[45], POUT[29], GOUT[45] );
smblock2 d346 (PIN[30], PIN[38], GIN[38], GIN[46], POUT[30], GOUT[46] );
smblock2 d347 (PIN[31], PIN[39], GIN[39], GIN[47], POUT[31], GOUT[47] );
smblock2 d348 (PIN[32], PIN[40], GIN[40], GIN[48], POUT[32], GOUT[48] );
smblock2 d349 (PIN[33], PIN[41], GIN[41], GIN[49], POUT[33], GOUT[49] );
smblock2 d350 (PIN[34], PIN[42], GIN[42], GIN[50], POUT[34], GOUT[50] );
smblock2 d351 (PIN[35], PIN[43], GIN[43], GIN[51], POUT[35], GOUT[51] );
smblock2 d352 (PIN[36], PIN[44], GIN[44], GIN[52], POUT[36], GOUT[52] );
smblock2 d353 (PIN[37], PIN[45], GIN[45], GIN[53], POUT[37], GOUT[53] );
smblock2 d354 (PIN[38], PIN[46], GIN[46], GIN[54], POUT[38], GOUT[54] );
smblock2 d355 (PIN[39], PIN[47], GIN[47], GIN[55], POUT[39], GOUT[55] );
smblock2 d356 (PIN[40], PIN[48], GIN[48], GIN[56], POUT[40], GOUT[56] );
smblock2 d357 (PIN[41], PIN[49], GIN[49], GIN[57], POUT[41], GOUT[57] );
smblock2 d358 (PIN[42], PIN[50], GIN[50], GIN[58], POUT[42], GOUT[58] );
smblock2 d359 (PIN[43], PIN[51], GIN[51], GIN[59], POUT[43], GOUT[59] );
smblock2 d360 (PIN[44], PIN[52], GIN[52], GIN[60], POUT[44], GOUT[60] );
smblock2 d361 (PIN[45], PIN[53], GIN[53], GIN[61], POUT[45], GOUT[61] );
smblock2 d362 (PIN[46], PIN[54], GIN[54], GIN[62], POUT[46], GOUT[62] );
smblock2 d363 (PIN[47], PIN[55], GIN[55], GIN[63], POUT[47], GOUT[63] );
endmodule
module smdblc_4_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
sminvblock d12 (GIN[2], GOUT[2] );
sminvblock d13 (GIN[3], GOUT[3] );
sminvblock d14 (GIN[4], GOUT[4] );
sminvblock d15 (GIN[5], GOUT[5] );
sminvblock d16 (GIN[6], GOUT[6] );
sminvblock d17 (GIN[7], GOUT[7] );
sminvblock d18 (GIN[8], GOUT[8] );
sminvblock d19 (GIN[9], GOUT[9] );
sminvblock d110 (GIN[10], GOUT[10] );
sminvblock d111 (GIN[11], GOUT[11] );
sminvblock d112 (GIN[12], GOUT[12] );
sminvblock d113 (GIN[13], GOUT[13] );
sminvblock d114 (GIN[14], GOUT[14] );
sminvblock d115 (GIN[15], GOUT[15] );
smblock1a d216 (PIN[0], GIN[0], GIN[16], GOUT[16] );
smblock1a d217 (PIN[1], GIN[1], GIN[17], GOUT[17] );
smblock1a d218 (PIN[2], GIN[2], GIN[18], GOUT[18] );
smblock1a d219 (PIN[3], GIN[3], GIN[19], GOUT[19] );
smblock1a d220 (PIN[4], GIN[4], GIN[20], GOUT[20] );
smblock1a d221 (PIN[5], GIN[5], GIN[21], GOUT[21] );
smblock1a d222 (PIN[6], GIN[6], GIN[22], GOUT[22] );
smblock1a d223 (PIN[7], GIN[7], GIN[23], GOUT[23] );
smblock1a d224 (PIN[8], GIN[8], GIN[24], GOUT[24] );
smblock1a d225 (PIN[9], GIN[9], GIN[25], GOUT[25] );
smblock1a d226 (PIN[10], GIN[10], GIN[26], GOUT[26] );
smblock1a d227 (PIN[11], GIN[11], GIN[27], GOUT[27] );
smblock1a d228 (PIN[12], GIN[12], GIN[28], GOUT[28] );
smblock1a d229 (PIN[13], GIN[13], GIN[29], GOUT[29] );
smblock1a d230 (PIN[14], GIN[14], GIN[30], GOUT[30] );
smblock1a d231 (PIN[15], GIN[15], GIN[31], GOUT[31] );
smblock1 d332 (PIN[0], PIN[16], GIN[16], GIN[32], POUT[0], GOUT[32] );
smblock1 d333 (PIN[1], PIN[17], GIN[17], GIN[33], POUT[1], GOUT[33] );
smblock1 d334 (PIN[2], PIN[18], GIN[18], GIN[34], POUT[2], GOUT[34] );
smblock1 d335 (PIN[3], PIN[19], GIN[19], GIN[35], POUT[3], GOUT[35] );
smblock1 d336 (PIN[4], PIN[20], GIN[20], GIN[36], POUT[4], GOUT[36] );
smblock1 d337 (PIN[5], PIN[21], GIN[21], GIN[37], POUT[5], GOUT[37] );
smblock1 d338 (PIN[6], PIN[22], GIN[22], GIN[38], POUT[6], GOUT[38] );
smblock1 d339 (PIN[7], PIN[23], GIN[23], GIN[39], POUT[7], GOUT[39] );
smblock1 d340 (PIN[8], PIN[24], GIN[24], GIN[40], POUT[8], GOUT[40] );
smblock1 d341 (PIN[9], PIN[25], GIN[25], GIN[41], POUT[9], GOUT[41] );
smblock1 d342 (PIN[10], PIN[26], GIN[26], GIN[42], POUT[10], GOUT[42] );
smblock1 d343 (PIN[11], PIN[27], GIN[27], GIN[43], POUT[11], GOUT[43] );
smblock1 d344 (PIN[12], PIN[28], GIN[28], GIN[44], POUT[12], GOUT[44] );
smblock1 d345 (PIN[13], PIN[29], GIN[29], GIN[45], POUT[13], GOUT[45] );
smblock1 d346 (PIN[14], PIN[30], GIN[30], GIN[46], POUT[14], GOUT[46] );
smblock1 d347 (PIN[15], PIN[31], GIN[31], GIN[47], POUT[15], GOUT[47] );
smblock1 d348 (PIN[16], PIN[32], GIN[32], GIN[48], POUT[16], GOUT[48] );
smblock1 d349 (PIN[17], PIN[33], GIN[33], GIN[49], POUT[17], GOUT[49] );
smblock1 d350 (PIN[18], PIN[34], GIN[34], GIN[50], POUT[18], GOUT[50] );
smblock1 d351 (PIN[19], PIN[35], GIN[35], GIN[51], POUT[19], GOUT[51] );
smblock1 d352 (PIN[20], PIN[36], GIN[36], GIN[52], POUT[20], GOUT[52] );
smblock1 d353 (PIN[21], PIN[37], GIN[37], GIN[53], POUT[21], GOUT[53] );
smblock1 d354 (PIN[22], PIN[38], GIN[38], GIN[54], POUT[22], GOUT[54] );
smblock1 d355 (PIN[23], PIN[39], GIN[39], GIN[55], POUT[23], GOUT[55] );
smblock1 d356 (PIN[24], PIN[40], GIN[40], GIN[56], POUT[24], GOUT[56] );
smblock1 d357 (PIN[25], PIN[41], GIN[41], GIN[57], POUT[25], GOUT[57] );
smblock1 d358 (PIN[26], PIN[42], GIN[42], GIN[58], POUT[26], GOUT[58] );
smblock1 d359 (PIN[27], PIN[43], GIN[43], GIN[59], POUT[27], GOUT[59] );
smblock1 d360 (PIN[28], PIN[44], GIN[44], GIN[60], POUT[28], GOUT[60] );
smblock1 d361 (PIN[29], PIN[45], GIN[45], GIN[61], POUT[29], GOUT[61] );
smblock1 d362 (PIN[30], PIN[46], GIN[46], GIN[62], POUT[30], GOUT[62] );
smblock1 d363 (PIN[31], PIN[47], GIN[47], GIN[63], POUT[31], GOUT[63] );
endmodule
module smxorstage_128 ( A, B, PBIT, CARRY, SUM );
input [63:0] A;
input [63:0] B;
input PBIT;
input [63:0] CARRY;
output [63:0] SUM;
smxxor1 d20 (A[0], B[0], CARRY[0], SUM[0] );
smxxor1 d21 (A[1], B[1], CARRY[1], SUM[1] );
smxxor1 d22 (A[2], B[2], CARRY[2], SUM[2] );
smxxor1 d23 (A[3], B[3], CARRY[3], SUM[3] );
smxxor1 d24 (A[4], B[4], CARRY[4], SUM[4] );
smxxor1 d25 (A[5], B[5], CARRY[5], SUM[5] );
smxxor1 d26 (A[6], B[6], CARRY[6], SUM[6] );
smxxor1 d27 (A[7], B[7], CARRY[7], SUM[7] );
smxxor1 d28 (A[8], B[8], CARRY[8], SUM[8] );
smxxor1 d29 (A[9], B[9], CARRY[9], SUM[9] );
smxxor1 d210 (A[10], B[10], CARRY[10], SUM[10] );
smxxor1 d211 (A[11], B[11], CARRY[11], SUM[11] );
smxxor1 d212 (A[12], B[12], CARRY[12], SUM[12] );
smxxor1 d213 (A[13], B[13], CARRY[13], SUM[13] );
smxxor1 d214 (A[14], B[14], CARRY[14], SUM[14] );
smxxor1 d215 (A[15], B[15], CARRY[15], SUM[15] );
smxxor1 d216 (A[16], B[16], CARRY[16], SUM[16] );
smxxor1 d217 (A[17], B[17], CARRY[17], SUM[17] );
smxxor1 d218 (A[18], B[18], CARRY[18], SUM[18] );
smxxor1 d219 (A[19], B[19], CARRY[19], SUM[19] );
smxxor1 d220 (A[20], B[20], CARRY[20], SUM[20] );
smxxor1 d221 (A[21], B[21], CARRY[21], SUM[21] );
smxxor1 d222 (A[22], B[22], CARRY[22], SUM[22] );
smxxor1 d223 (A[23], B[23], CARRY[23], SUM[23] );
smxxor1 d224 (A[24], B[24], CARRY[24], SUM[24] );
smxxor1 d225 (A[25], B[25], CARRY[25], SUM[25] );
smxxor1 d226 (A[26], B[26], CARRY[26], SUM[26] );
smxxor1 d227 (A[27], B[27], CARRY[27], SUM[27] );
smxxor1 d228 (A[28], B[28], CARRY[28], SUM[28] );
smxxor1 d229 (A[29], B[29], CARRY[29], SUM[29] );
smxxor1 d230 (A[30], B[30], CARRY[30], SUM[30] );
smxxor1 d231 (A[31], B[31], CARRY[31], SUM[31] );
smxxor1 d232 (A[32], B[32], CARRY[32], SUM[32] );
smxxor1 d233 (A[33], B[33], CARRY[33], SUM[33] );
smxxor1 d234 (A[34], B[34], CARRY[34], SUM[34] );
smxxor1 d235 (A[35], B[35], CARRY[35], SUM[35] );
smxxor1 d236 (A[36], B[36], CARRY[36], SUM[36] );
smxxor1 d237 (A[37], B[37], CARRY[37], SUM[37] );
smxxor1 d238 (A[38], B[38], CARRY[38], SUM[38] );
smxxor1 d239 (A[39], B[39], CARRY[39], SUM[39] );
smxxor1 d240 (A[40], B[40], CARRY[40], SUM[40] );
smxxor1 d241 (A[41], B[41], CARRY[41], SUM[41] );
smxxor1 d242 (A[42], B[42], CARRY[42], SUM[42] );
smxxor1 d243 (A[43], B[43], CARRY[43], SUM[43] );
smxxor1 d244 (A[44], B[44], CARRY[44], SUM[44] );
smxxor1 d245 (A[45], B[45], CARRY[45], SUM[45] );
smxxor1 d246 (A[46], B[46], CARRY[46], SUM[46] );
smxxor1 d247 (A[47], B[47], CARRY[47], SUM[47] );
smxxor1 d248 (A[48], B[48], CARRY[48], SUM[48] );
smxxor1 d249 (A[49], B[49], CARRY[49], SUM[49] );
smxxor1 d250 (A[50], B[50], CARRY[50], SUM[50] );
smxxor1 d251 (A[51], B[51], CARRY[51], SUM[51] );
smxxor1 d252 (A[52], B[52], CARRY[52], SUM[52] );
smxxor1 d253 (A[53], B[53], CARRY[53], SUM[53] );
smxxor1 d254 (A[54], B[54], CARRY[54], SUM[54] );
smxxor1 d255 (A[55], B[55], CARRY[55], SUM[55] );
smxxor1 d256 (A[56], B[56], CARRY[56], SUM[56] );
smxxor1 d257 (A[57], B[57], CARRY[57], SUM[57] );
smxxor1 d258 (A[58], B[58], CARRY[58], SUM[58] );
smxxor1 d259 (A[59], B[59], CARRY[59], SUM[59] );
smxxor1 d260 (A[60], B[60], CARRY[60], SUM[60] );
smxxor1 d261 (A[61], B[61], CARRY[61], SUM[61] );
smxxor1 d262 (A[62], B[62], CARRY[62], SUM[62] );
smxxor1 d263 (A[63], B[63], CARRY[63], SUM[63] );
endmodule
module smdblc_5_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
sminvblock d12 (GIN[2], GOUT[2] );
sminvblock d13 (GIN[3], GOUT[3] );
sminvblock d14 (GIN[4], GOUT[4] );
sminvblock d15 (GIN[5], GOUT[5] );
sminvblock d16 (GIN[6], GOUT[6] );
sminvblock d17 (GIN[7], GOUT[7] );
sminvblock d18 (GIN[8], GOUT[8] );
sminvblock d19 (GIN[9], GOUT[9] );
sminvblock d110 (GIN[10], GOUT[10] );
sminvblock d111 (GIN[11], GOUT[11] );
sminvblock d112 (GIN[12], GOUT[12] );
sminvblock d113 (GIN[13], GOUT[13] );
sminvblock d114 (GIN[14], GOUT[14] );
sminvblock d115 (GIN[15], GOUT[15] );
sminvblock d116 (GIN[16], GOUT[16] );
sminvblock d117 (GIN[17], GOUT[17] );
sminvblock d118 (GIN[18], GOUT[18] );
sminvblock d119 (GIN[19], GOUT[19] );
sminvblock d120 (GIN[20], GOUT[20] );
sminvblock d121 (GIN[21], GOUT[21] );
sminvblock d122 (GIN[22], GOUT[22] );
sminvblock d123 (GIN[23], GOUT[23] );
sminvblock d124 (GIN[24], GOUT[24] );
sminvblock d125 (GIN[25], GOUT[25] );
sminvblock d126 (GIN[26], GOUT[26] );
sminvblock d127 (GIN[27], GOUT[27] );
sminvblock d128 (GIN[28], GOUT[28] );
sminvblock d129 (GIN[29], GOUT[29] );
sminvblock d130 (GIN[30], GOUT[30] );
sminvblock d131 (GIN[31], GOUT[31] );
smblock2a d232 (PIN[0], GIN[0], GIN[32], GOUT[32] );
smblock2a d233 (PIN[1], GIN[1], GIN[33], GOUT[33] );
smblock2a d234 (PIN[2], GIN[2], GIN[34], GOUT[34] );
smblock2a d235 (PIN[3], GIN[3], GIN[35], GOUT[35] );
smblock2a d236 (PIN[4], GIN[4], GIN[36], GOUT[36] );
smblock2a d237 (PIN[5], GIN[5], GIN[37], GOUT[37] );
smblock2a d238 (PIN[6], GIN[6], GIN[38], GOUT[38] );
smblock2a d239 (PIN[7], GIN[7], GIN[39], GOUT[39] );
smblock2a d240 (PIN[8], GIN[8], GIN[40], GOUT[40] );
smblock2a d241 (PIN[9], GIN[9], GIN[41], GOUT[41] );
smblock2a d242 (PIN[10], GIN[10], GIN[42], GOUT[42] );
smblock2a d243 (PIN[11], GIN[11], GIN[43], GOUT[43] );
smblock2a d244 (PIN[12], GIN[12], GIN[44], GOUT[44] );
smblock2a d245 (PIN[13], GIN[13], GIN[45], GOUT[45] );
smblock2a d246 (PIN[14], GIN[14], GIN[46], GOUT[46] );
smblock2a d247 (PIN[15], GIN[15], GIN[47], GOUT[47] );
smblock2a d248 (PIN[16], GIN[16], GIN[48], GOUT[48] );
smblock2a d249 (PIN[17], GIN[17], GIN[49], GOUT[49] );
smblock2a d250 (PIN[18], GIN[18], GIN[50], GOUT[50] );
smblock2a d251 (PIN[19], GIN[19], GIN[51], GOUT[51] );
smblock2a d252 (PIN[20], GIN[20], GIN[52], GOUT[52] );
smblock2a d253 (PIN[21], GIN[21], GIN[53], GOUT[53] );
smblock2a d254 (PIN[22], GIN[22], GIN[54], GOUT[54] );
smblock2a d255 (PIN[23], GIN[23], GIN[55], GOUT[55] );
smblock2a d256 (PIN[24], GIN[24], GIN[56], GOUT[56] );
smblock2a d257 (PIN[25], GIN[25], GIN[57], GOUT[57] );
smblock2a d258 (PIN[26], GIN[26], GIN[58], GOUT[58] );
smblock2a d259 (PIN[27], GIN[27], GIN[59], GOUT[59] );
smblock2a d260 (PIN[28], GIN[28], GIN[60], GOUT[60] );
smblock2a d261 (PIN[29], GIN[29], GIN[61], GOUT[61] );
smblock2a d262 (PIN[30], GIN[30], GIN[62], GOUT[62] );
smblock2a d263 (PIN[31], GIN[31], GIN[63], GOUT[63] );
endmodule
module smdblc_6_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [0:0] POUT;
output [63:0] GOUT;
assign GOUT[63:0] = GIN[63:0];
endmodule
module smboothcoder_34_34 ( OPA, OPB, SUMMAND );
input [33:0] OPA;
input [33:0] OPB;
output [628:0] SUMMAND;
wire [33:0] OPA_;
wire [67:0] INT_MULTIPLIER;
wire LOGIC_ONE, LOGIC_ZERO;
assign LOGIC_ONE = 1'b1;
assign LOGIC_ZERO = 1'b0;
smdecoder dDEC0 (.INA (LOGIC_ZERO), .INB (OPB[0]), .INC (OPB[1]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]) );
assign OPA_ = ~ OPA;
smpp_low dPPL0 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[0]) );
smr_gate dRGATE0 (.INA (LOGIC_ZERO), .INB (OPB[0]), .INC (OPB[1]), .PPBIT (SUMMAND[1]) );
smpp_middle dPPM0 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[2]) );
smpp_middle dPPM1 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[3]) );
smpp_middle dPPM2 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[6]) );
smpp_middle dPPM3 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[8]) );
smpp_middle dPPM4 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[12]) );
smpp_middle dPPM5 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[15]) );
smpp_middle dPPM6 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[20]) );
smpp_middle dPPM7 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[24]) );
smpp_middle dPPM8 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[30]) );
smpp_middle dPPM9 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[35]) );
smpp_middle dPPM10 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[42]) );
smpp_middle dPPM11 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[48]) );
smpp_middle dPPM12 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[56]) );
smpp_middle dPPM13 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[63]) );
smpp_middle dPPM14 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[72]) );
smpp_middle dPPM15 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[80]) );
smpp_middle dPPM16 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[90]) );
smpp_middle dPPM17 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[99]) );
smpp_middle dPPM18 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[110]) );
smpp_middle dPPM19 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[120]) );
smpp_middle dPPM20 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[132]) );
smpp_middle dPPM21 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[143]) );
smpp_middle dPPM22 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[156]) );
smpp_middle dPPM23 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[168]) );
smpp_middle dPPM24 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[182]) );
smpp_middle dPPM25 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[195]) );
smpp_middle dPPM26 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[210]) );
smpp_middle dPPM27 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[224]) );
smpp_middle dPPM28 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[240]) );
smpp_middle dPPM29 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[255]) );
smpp_middle dPPM30 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[272]) );
smpp_middle dPPM31 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[288]) );
smpp_middle dPPM32 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[306]) );
smpp_high dPPH0 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[323]) );
assign SUMMAND[324] = 1'b1;
smdecoder dDEC1 (.INA (OPB[1]), .INB (OPB[2]), .INC (OPB[3]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]) );
smpp_low dPPL1 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[4]) );
smr_gate dRGATE1 (.INA (OPB[1]), .INB (OPB[2]), .INC (OPB[3]), .PPBIT (SUMMAND[5]) );
smpp_middle dPPM33 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[7]) );
smpp_middle dPPM34 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[9]) );
smpp_middle dPPM35 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[13]) );
smpp_middle dPPM36 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[16]) );
smpp_middle dPPM37 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[21]) );
smpp_middle dPPM38 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[25]) );
smpp_middle dPPM39 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[31]) );
smpp_middle dPPM40 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[36]) );
smpp_middle dPPM41 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[43]) );
smpp_middle dPPM42 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[49]) );
smpp_middle dPPM43 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[57]) );
smpp_middle dPPM44 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[64]) );
smpp_middle dPPM45 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[73]) );
smpp_middle dPPM46 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[81]) );
smpp_middle dPPM47 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[91]) );
smpp_middle dPPM48 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[100]) );
smpp_middle dPPM49 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[111]) );
smpp_middle dPPM50 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[121]) );
smpp_middle dPPM51 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[133]) );
smpp_middle dPPM52 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[144]) );
smpp_middle dPPM53 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[157]) );
smpp_middle dPPM54 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[169]) );
smpp_middle dPPM55 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[183]) );
smpp_middle dPPM56 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[196]) );
smpp_middle dPPM57 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[211]) );
smpp_middle dPPM58 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[225]) );
smpp_middle dPPM59 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[241]) );
smpp_middle dPPM60 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[256]) );
smpp_middle dPPM61 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[273]) );
smpp_middle dPPM62 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[289]) );
smpp_middle dPPM63 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[307]) );
smpp_middle dPPM64 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[325]) );
smpp_middle dPPM65 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[341]) );
assign SUMMAND[342] = LOGIC_ONE;
smpp_high dPPH1 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[358]) );
smdecoder dDEC2 (.INA (OPB[3]), .INB (OPB[4]), .INC (OPB[5]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]) );
smpp_low dPPL2 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[10]) );
smr_gate dRGATE2 (.INA (OPB[3]), .INB (OPB[4]), .INC (OPB[5]), .PPBIT (SUMMAND[11]) );
smpp_middle dPPM66 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[14]) );
smpp_middle dPPM67 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[17]) );
smpp_middle dPPM68 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[22]) );
smpp_middle dPPM69 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[26]) );
smpp_middle dPPM70 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[32]) );
smpp_middle dPPM71 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[37]) );
smpp_middle dPPM72 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[44]) );
smpp_middle dPPM73 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[50]) );
smpp_middle dPPM74 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[58]) );
smpp_middle dPPM75 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[65]) );
smpp_middle dPPM76 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[74]) );
smpp_middle dPPM77 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[82]) );
smpp_middle dPPM78 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[92]) );
smpp_middle dPPM79 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[101]) );
smpp_middle dPPM80 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[112]) );
smpp_middle dPPM81 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[122]) );
smpp_middle dPPM82 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[134]) );
smpp_middle dPPM83 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[145]) );
smpp_middle dPPM84 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[158]) );
smpp_middle dPPM85 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[170]) );
smpp_middle dPPM86 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[184]) );
smpp_middle dPPM87 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[197]) );
smpp_middle dPPM88 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[212]) );
smpp_middle dPPM89 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[226]) );
smpp_middle dPPM90 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[242]) );
smpp_middle dPPM91 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[257]) );
smpp_middle dPPM92 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[274]) );
smpp_middle dPPM93 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[290]) );
smpp_middle dPPM94 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[308]) );
smpp_middle dPPM95 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[326]) );
smpp_middle dPPM96 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[343]) );
smpp_middle dPPM97 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[359]) );
smpp_middle dPPM98 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[374]) );
assign SUMMAND[375] = LOGIC_ONE;
smpp_high dPPH2 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[390]) );
smdecoder dDEC3 (.INA (OPB[5]), .INB (OPB[6]), .INC (OPB[7]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]) );
smpp_low dPPL3 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[18]) );
smr_gate dRGATE3 (.INA (OPB[5]), .INB (OPB[6]), .INC (OPB[7]), .PPBIT (SUMMAND[19]) );
smpp_middle dPPM99 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[23]) );
smpp_middle dPPM100 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[27]) );
smpp_middle dPPM101 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[33]) );
smpp_middle dPPM102 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[38]) );
smpp_middle dPPM103 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[45]) );
smpp_middle dPPM104 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[51]) );
smpp_middle dPPM105 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[59]) );
smpp_middle dPPM106 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[66]) );
smpp_middle dPPM107 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[75]) );
smpp_middle dPPM108 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[83]) );
smpp_middle dPPM109 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[93]) );
smpp_middle dPPM110 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[102]) );
smpp_middle dPPM111 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[113]) );
smpp_middle dPPM112 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[123]) );
smpp_middle dPPM113 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[135]) );
smpp_middle dPPM114 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[146]) );
smpp_middle dPPM115 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[159]) );
smpp_middle dPPM116 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[171]) );
smpp_middle dPPM117 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[185]) );
smpp_middle dPPM118 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[198]) );
smpp_middle dPPM119 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[213]) );
smpp_middle dPPM120 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[227]) );
smpp_middle dPPM121 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[243]) );
smpp_middle dPPM122 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[258]) );
smpp_middle dPPM123 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[275]) );
smpp_middle dPPM124 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[291]) );
smpp_middle dPPM125 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[309]) );
smpp_middle dPPM126 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[327]) );
smpp_middle dPPM127 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[344]) );
smpp_middle dPPM128 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[360]) );
smpp_middle dPPM129 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[376]) );
smpp_middle dPPM130 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[391]) );
smpp_middle dPPM131 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[405]) );
assign SUMMAND[406] = LOGIC_ONE;
smpp_high dPPH3 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[420]) );
smdecoder dDEC4 (.INA (OPB[7]), .INB (OPB[8]), .INC (OPB[9]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]) );
smpp_low dPPL4 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[28]) );
smr_gate dRGATE4 (.INA (OPB[7]), .INB (OPB[8]), .INC (OPB[9]), .PPBIT (SUMMAND[29]) );
smpp_middle dPPM132 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[34]) );
smpp_middle dPPM133 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[39]) );
smpp_middle dPPM134 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[46]) );
smpp_middle dPPM135 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[52]) );
smpp_middle dPPM136 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[60]) );
smpp_middle dPPM137 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[67]) );
smpp_middle dPPM138 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[76]) );
smpp_middle dPPM139 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[84]) );
smpp_middle dPPM140 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[94]) );
smpp_middle dPPM141 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[103]) );
smpp_middle dPPM142 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[114]) );
smpp_middle dPPM143 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[124]) );
smpp_middle dPPM144 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[136]) );
smpp_middle dPPM145 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[147]) );
smpp_middle dPPM146 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[160]) );
smpp_middle dPPM147 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[172]) );
smpp_middle dPPM148 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[186]) );
smpp_middle dPPM149 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[199]) );
smpp_middle dPPM150 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[214]) );
smpp_middle dPPM151 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[228]) );
smpp_middle dPPM152 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[244]) );
smpp_middle dPPM153 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[259]) );
smpp_middle dPPM154 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[276]) );
smpp_middle dPPM155 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[292]) );
smpp_middle dPPM156 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[310]) );
smpp_middle dPPM157 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[328]) );
smpp_middle dPPM158 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[345]) );
smpp_middle dPPM159 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[361]) );
smpp_middle dPPM160 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[377]) );
smpp_middle dPPM161 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[392]) );
smpp_middle dPPM162 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[407]) );
smpp_middle dPPM163 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[421]) );
smpp_middle dPPM164 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[434]) );
assign SUMMAND[435] = LOGIC_ONE;
smpp_high dPPH4 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[448]) );
smdecoder dDEC5 (.INA (OPB[9]), .INB (OPB[10]), .INC (OPB[11]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]) );
smpp_low dPPL5 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[40]) );
smr_gate dRGATE5 (.INA (OPB[9]), .INB (OPB[10]), .INC (OPB[11]), .PPBIT (SUMMAND[41]) );
smpp_middle dPPM165 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[47]) );
smpp_middle dPPM166 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[53]) );
smpp_middle dPPM167 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[61]) );
smpp_middle dPPM168 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[68]) );
smpp_middle dPPM169 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[77]) );
smpp_middle dPPM170 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[85]) );
smpp_middle dPPM171 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[95]) );
smpp_middle dPPM172 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[104]) );
smpp_middle dPPM173 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[115]) );
smpp_middle dPPM174 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[125]) );
smpp_middle dPPM175 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[137]) );
smpp_middle dPPM176 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[148]) );
smpp_middle dPPM177 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[161]) );
smpp_middle dPPM178 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[173]) );
smpp_middle dPPM179 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[187]) );
smpp_middle dPPM180 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[200]) );
smpp_middle dPPM181 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[215]) );
smpp_middle dPPM182 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[229]) );
smpp_middle dPPM183 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[245]) );
smpp_middle dPPM184 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[260]) );
smpp_middle dPPM185 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[277]) );
smpp_middle dPPM186 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[293]) );
smpp_middle dPPM187 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[311]) );
smpp_middle dPPM188 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[329]) );
smpp_middle dPPM189 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[346]) );
smpp_middle dPPM190 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[362]) );
smpp_middle dPPM191 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[378]) );
smpp_middle dPPM192 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[393]) );
smpp_middle dPPM193 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[408]) );
smpp_middle dPPM194 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[422]) );
smpp_middle dPPM195 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[436]) );
smpp_middle dPPM196 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[449]) );
smpp_middle dPPM197 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[461]) );
assign SUMMAND[462] = LOGIC_ONE;
smpp_high dPPH5 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[474]) );
smdecoder dDEC6 (.INA (OPB[11]), .INB (OPB[12]), .INC (OPB[13]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]) );
smpp_low dPPL6 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[54]) );
smr_gate dRGATE6 (.INA (OPB[11]), .INB (OPB[12]), .INC (OPB[13]), .PPBIT (SUMMAND[55]) );
smpp_middle dPPM198 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[62]) );
smpp_middle dPPM199 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[69]) );
smpp_middle dPPM200 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[78]) );
smpp_middle dPPM201 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[86]) );
smpp_middle dPPM202 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[96]) );
smpp_middle dPPM203 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[105]) );
smpp_middle dPPM204 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[116]) );
smpp_middle dPPM205 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[126]) );
smpp_middle dPPM206 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[138]) );
smpp_middle dPPM207 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[149]) );
smpp_middle dPPM208 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[162]) );
smpp_middle dPPM209 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[174]) );
smpp_middle dPPM210 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[188]) );
smpp_middle dPPM211 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[201]) );
smpp_middle dPPM212 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[216]) );
smpp_middle dPPM213 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[230]) );
smpp_middle dPPM214 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[246]) );
smpp_middle dPPM215 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[261]) );
smpp_middle dPPM216 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[278]) );
smpp_middle dPPM217 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[294]) );
smpp_middle dPPM218 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[312]) );
smpp_middle dPPM219 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[330]) );
smpp_middle dPPM220 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[347]) );
smpp_middle dPPM221 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[363]) );
smpp_middle dPPM222 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[379]) );
smpp_middle dPPM223 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[394]) );
smpp_middle dPPM224 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[409]) );
smpp_middle dPPM225 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[423]) );
smpp_middle dPPM226 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[437]) );
smpp_middle dPPM227 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[450]) );
smpp_middle dPPM228 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[463]) );
smpp_middle dPPM229 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[475]) );
smpp_middle dPPM230 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[486]) );
assign SUMMAND[487] = LOGIC_ONE;
smpp_high dPPH6 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[498]) );
smdecoder dDEC7 (.INA (OPB[13]), .INB (OPB[14]), .INC (OPB[15]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]) );
smpp_low dPPL7 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[70]) );
smr_gate dRGATE7 (.INA (OPB[13]), .INB (OPB[14]), .INC (OPB[15]), .PPBIT (SUMMAND[71]) );
smpp_middle dPPM231 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[79]) );
smpp_middle dPPM232 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[87]) );
smpp_middle dPPM233 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[97]) );
smpp_middle dPPM234 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[106]) );
smpp_middle dPPM235 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[117]) );
smpp_middle dPPM236 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[127]) );
smpp_middle dPPM237 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[139]) );
smpp_middle dPPM238 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[150]) );
smpp_middle dPPM239 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[163]) );
smpp_middle dPPM240 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[175]) );
smpp_middle dPPM241 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[189]) );
smpp_middle dPPM242 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[202]) );
smpp_middle dPPM243 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[217]) );
smpp_middle dPPM244 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[231]) );
smpp_middle dPPM245 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[247]) );
smpp_middle dPPM246 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[262]) );
smpp_middle dPPM247 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[279]) );
smpp_middle dPPM248 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[295]) );
smpp_middle dPPM249 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[313]) );
smpp_middle dPPM250 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[331]) );
smpp_middle dPPM251 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[348]) );
smpp_middle dPPM252 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[364]) );
smpp_middle dPPM253 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[380]) );
smpp_middle dPPM254 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[395]) );
smpp_middle dPPM255 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[410]) );
smpp_middle dPPM256 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[424]) );
smpp_middle dPPM257 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[438]) );
smpp_middle dPPM258 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[451]) );
smpp_middle dPPM259 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[464]) );
smpp_middle dPPM260 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[476]) );
smpp_middle dPPM261 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[488]) );
smpp_middle dPPM262 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[499]) );
smpp_middle dPPM263 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[509]) );
assign SUMMAND[510] = LOGIC_ONE;
smpp_high dPPH7 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[520]) );
smdecoder dDEC8 (.INA (OPB[15]), .INB (OPB[16]), .INC (OPB[17]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]) );
smpp_low dPPL8 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[88]) );
smr_gate dRGATE8 (.INA (OPB[15]), .INB (OPB[16]), .INC (OPB[17]), .PPBIT (SUMMAND[89]) );
smpp_middle dPPM264 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[98]) );
smpp_middle dPPM265 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[107]) );
smpp_middle dPPM266 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[118]) );
smpp_middle dPPM267 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[128]) );
smpp_middle dPPM268 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[140]) );
smpp_middle dPPM269 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[151]) );
smpp_middle dPPM270 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[164]) );
smpp_middle dPPM271 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[176]) );
smpp_middle dPPM272 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[190]) );
smpp_middle dPPM273 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[203]) );
smpp_middle dPPM274 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[218]) );
smpp_middle dPPM275 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[232]) );
smpp_middle dPPM276 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[248]) );
smpp_middle dPPM277 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[263]) );
smpp_middle dPPM278 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[280]) );
smpp_middle dPPM279 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[296]) );
smpp_middle dPPM280 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[314]) );
smpp_middle dPPM281 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[332]) );
smpp_middle dPPM282 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[349]) );
smpp_middle dPPM283 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[365]) );
smpp_middle dPPM284 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[381]) );
smpp_middle dPPM285 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[396]) );
smpp_middle dPPM286 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[411]) );
smpp_middle dPPM287 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[425]) );
smpp_middle dPPM288 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[439]) );
smpp_middle dPPM289 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[452]) );
smpp_middle dPPM290 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[465]) );
smpp_middle dPPM291 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[477]) );
smpp_middle dPPM292 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[489]) );
smpp_middle dPPM293 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[500]) );
smpp_middle dPPM294 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[511]) );
smpp_middle dPPM295 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[521]) );
smpp_middle dPPM296 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[530]) );
assign SUMMAND[531] = LOGIC_ONE;
smpp_high dPPH8 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[540]) );
smdecoder dDEC9 (.INA (OPB[17]), .INB (OPB[18]), .INC (OPB[19]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]) );
smpp_low dPPL9 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[108]) );
smr_gate dRGATE9 (.INA (OPB[17]), .INB (OPB[18]), .INC (OPB[19]), .PPBIT (SUMMAND[109]) );
smpp_middle dPPM297 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[119]) );
smpp_middle dPPM298 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[129]) );
smpp_middle dPPM299 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[141]) );
smpp_middle dPPM300 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[152]) );
smpp_middle dPPM301 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[165]) );
smpp_middle dPPM302 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[177]) );
smpp_middle dPPM303 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[191]) );
smpp_middle dPPM304 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[204]) );
smpp_middle dPPM305 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[219]) );
smpp_middle dPPM306 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[233]) );
smpp_middle dPPM307 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[249]) );
smpp_middle dPPM308 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[264]) );
smpp_middle dPPM309 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[281]) );
smpp_middle dPPM310 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[297]) );
smpp_middle dPPM311 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[315]) );
smpp_middle dPPM312 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[333]) );
smpp_middle dPPM313 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[350]) );
smpp_middle dPPM314 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[366]) );
smpp_middle dPPM315 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[382]) );
smpp_middle dPPM316 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[397]) );
smpp_middle dPPM317 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[412]) );
smpp_middle dPPM318 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[426]) );
smpp_middle dPPM319 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[440]) );
smpp_middle dPPM320 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[453]) );
smpp_middle dPPM321 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[466]) );
smpp_middle dPPM322 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[478]) );
smpp_middle dPPM323 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[490]) );
smpp_middle dPPM324 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[501]) );
smpp_middle dPPM325 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[512]) );
smpp_middle dPPM326 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[522]) );
smpp_middle dPPM327 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[532]) );
smpp_middle dPPM328 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[541]) );
smpp_middle dPPM329 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[549]) );
assign SUMMAND[550] = LOGIC_ONE;
smpp_high dPPH9 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[558]) );
smdecoder dDEC10 (.INA (OPB[19]), .INB (OPB[20]), .INC (OPB[21]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]) );
smpp_low dPPL10 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[130]) );
smr_gate dRGATE10 (.INA (OPB[19]), .INB (OPB[20]), .INC (OPB[21]), .PPBIT (SUMMAND[131]) );
smpp_middle dPPM330 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[142]) );
smpp_middle dPPM331 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[153]) );
smpp_middle dPPM332 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[166]) );
smpp_middle dPPM333 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[178]) );
smpp_middle dPPM334 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[192]) );
smpp_middle dPPM335 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[205]) );
smpp_middle dPPM336 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[220]) );
smpp_middle dPPM337 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[234]) );
smpp_middle dPPM338 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[250]) );
smpp_middle dPPM339 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[265]) );
smpp_middle dPPM340 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[282]) );
smpp_middle dPPM341 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[298]) );
smpp_middle dPPM342 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[316]) );
smpp_middle dPPM343 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[334]) );
smpp_middle dPPM344 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[351]) );
smpp_middle dPPM345 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[367]) );
smpp_middle dPPM346 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[383]) );
smpp_middle dPPM347 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[398]) );
smpp_middle dPPM348 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[413]) );
smpp_middle dPPM349 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[427]) );
smpp_middle dPPM350 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[441]) );
smpp_middle dPPM351 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[454]) );
smpp_middle dPPM352 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[467]) );
smpp_middle dPPM353 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[479]) );
smpp_middle dPPM354 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[491]) );
smpp_middle dPPM355 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[502]) );
smpp_middle dPPM356 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[513]) );
smpp_middle dPPM357 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[523]) );
smpp_middle dPPM358 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[533]) );
smpp_middle dPPM359 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[542]) );
smpp_middle dPPM360 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[551]) );
smpp_middle dPPM361 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[559]) );
smpp_middle dPPM362 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[566]) );
assign SUMMAND[567] = LOGIC_ONE;
smpp_high dPPH10 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[574]) );
smdecoder dDEC11 (.INA (OPB[21]), .INB (OPB[22]), .INC (OPB[23]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]) );
smpp_low dPPL11 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[154]) );
smr_gate dRGATE11 (.INA (OPB[21]), .INB (OPB[22]), .INC (OPB[23]), .PPBIT (SUMMAND[155]) );
smpp_middle dPPM363 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[167]) );
smpp_middle dPPM364 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[179]) );
smpp_middle dPPM365 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[193]) );
smpp_middle dPPM366 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[206]) );
smpp_middle dPPM367 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[221]) );
smpp_middle dPPM368 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[235]) );
smpp_middle dPPM369 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[251]) );
smpp_middle dPPM370 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[266]) );
smpp_middle dPPM371 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[283]) );
smpp_middle dPPM372 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[299]) );
smpp_middle dPPM373 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[317]) );
smpp_middle dPPM374 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[335]) );
smpp_middle dPPM375 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[352]) );
smpp_middle dPPM376 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[368]) );
smpp_middle dPPM377 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[384]) );
smpp_middle dPPM378 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[399]) );
smpp_middle dPPM379 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[414]) );
smpp_middle dPPM380 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[428]) );
smpp_middle dPPM381 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[442]) );
smpp_middle dPPM382 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[455]) );
smpp_middle dPPM383 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[468]) );
smpp_middle dPPM384 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[480]) );
smpp_middle dPPM385 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[492]) );
smpp_middle dPPM386 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[503]) );
smpp_middle dPPM387 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[514]) );
smpp_middle dPPM388 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[524]) );
smpp_middle dPPM389 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[534]) );
smpp_middle dPPM390 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[543]) );
smpp_middle dPPM391 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[552]) );
smpp_middle dPPM392 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[560]) );
smpp_middle dPPM393 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[568]) );
smpp_middle dPPM394 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[575]) );
smpp_middle dPPM395 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[581]) );
assign SUMMAND[582] = LOGIC_ONE;
smpp_high dPPH11 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[588]) );
smdecoder dDEC12 (.INA (OPB[23]), .INB (OPB[24]), .INC (OPB[25]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]) );
smpp_low dPPL12 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[180]) );
smr_gate dRGATE12 (.INA (OPB[23]), .INB (OPB[24]), .INC (OPB[25]), .PPBIT (SUMMAND[181]) );
smpp_middle dPPM396 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[194]) );
smpp_middle dPPM397 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[207]) );
smpp_middle dPPM398 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[222]) );
smpp_middle dPPM399 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[236]) );
smpp_middle dPPM400 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[252]) );
smpp_middle dPPM401 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[267]) );
smpp_middle dPPM402 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[284]) );
smpp_middle dPPM403 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[300]) );
smpp_middle dPPM404 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[318]) );
smpp_middle dPPM405 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[336]) );
smpp_middle dPPM406 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[353]) );
smpp_middle dPPM407 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[369]) );
smpp_middle dPPM408 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[385]) );
smpp_middle dPPM409 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[400]) );
smpp_middle dPPM410 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[415]) );
smpp_middle dPPM411 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[429]) );
smpp_middle dPPM412 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[443]) );
smpp_middle dPPM413 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[456]) );
smpp_middle dPPM414 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[469]) );
smpp_middle dPPM415 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[481]) );
smpp_middle dPPM416 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[493]) );
smpp_middle dPPM417 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[504]) );
smpp_middle dPPM418 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[515]) );
smpp_middle dPPM419 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[525]) );
smpp_middle dPPM420 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[535]) );
smpp_middle dPPM421 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[544]) );
smpp_middle dPPM422 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[553]) );
smpp_middle dPPM423 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[561]) );
smpp_middle dPPM424 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[569]) );
smpp_middle dPPM425 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[576]) );
smpp_middle dPPM426 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[583]) );
smpp_middle dPPM427 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[589]) );
smpp_middle dPPM428 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[594]) );
assign SUMMAND[595] = LOGIC_ONE;
smpp_high dPPH12 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[600]) );
smdecoder dDEC13 (.INA (OPB[25]), .INB (OPB[26]), .INC (OPB[27]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]) );
smpp_low dPPL13 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[208]) );
smr_gate dRGATE13 (.INA (OPB[25]), .INB (OPB[26]), .INC (OPB[27]), .PPBIT (SUMMAND[209]) );
smpp_middle dPPM429 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[223]) );
smpp_middle dPPM430 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[237]) );
smpp_middle dPPM431 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[253]) );
smpp_middle dPPM432 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[268]) );
smpp_middle dPPM433 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[285]) );
smpp_middle dPPM434 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[301]) );
smpp_middle dPPM435 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[319]) );
smpp_middle dPPM436 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[337]) );
smpp_middle dPPM437 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[354]) );
smpp_middle dPPM438 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[370]) );
smpp_middle dPPM439 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[386]) );
smpp_middle dPPM440 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[401]) );
smpp_middle dPPM441 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[416]) );
smpp_middle dPPM442 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[430]) );
smpp_middle dPPM443 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[444]) );
smpp_middle dPPM444 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[457]) );
smpp_middle dPPM445 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[470]) );
smpp_middle dPPM446 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[482]) );
smpp_middle dPPM447 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[494]) );
smpp_middle dPPM448 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[505]) );
smpp_middle dPPM449 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[516]) );
smpp_middle dPPM450 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[526]) );
smpp_middle dPPM451 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[536]) );
smpp_middle dPPM452 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[545]) );
smpp_middle dPPM453 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[554]) );
smpp_middle dPPM454 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[562]) );
smpp_middle dPPM455 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[570]) );
smpp_middle dPPM456 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[577]) );
smpp_middle dPPM457 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[584]) );
smpp_middle dPPM458 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[590]) );
smpp_middle dPPM459 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[596]) );
smpp_middle dPPM460 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[601]) );
smpp_middle dPPM461 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[605]) );
assign SUMMAND[606] = LOGIC_ONE;
smpp_high dPPH13 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[610]) );
smdecoder dDEC14 (.INA (OPB[27]), .INB (OPB[28]), .INC (OPB[29]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]) );
smpp_low dPPL14 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[238]) );
smr_gate dRGATE14 (.INA (OPB[27]), .INB (OPB[28]), .INC (OPB[29]), .PPBIT (SUMMAND[239]) );
smpp_middle dPPM462 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[254]) );
smpp_middle dPPM463 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[269]) );
smpp_middle dPPM464 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[286]) );
smpp_middle dPPM465 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[302]) );
smpp_middle dPPM466 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[320]) );
smpp_middle dPPM467 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[338]) );
smpp_middle dPPM468 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[355]) );
smpp_middle dPPM469 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[371]) );
smpp_middle dPPM470 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[387]) );
smpp_middle dPPM471 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[402]) );
smpp_middle dPPM472 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[417]) );
smpp_middle dPPM473 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[431]) );
smpp_middle dPPM474 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[445]) );
smpp_middle dPPM475 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[458]) );
smpp_middle dPPM476 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[471]) );
smpp_middle dPPM477 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[483]) );
smpp_middle dPPM478 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[495]) );
smpp_middle dPPM479 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[506]) );
smpp_middle dPPM480 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[517]) );
smpp_middle dPPM481 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[527]) );
smpp_middle dPPM482 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[537]) );
smpp_middle dPPM483 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[546]) );
smpp_middle dPPM484 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[555]) );
smpp_middle dPPM485 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[563]) );
smpp_middle dPPM486 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[571]) );
smpp_middle dPPM487 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[578]) );
smpp_middle dPPM488 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[585]) );
smpp_middle dPPM489 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[591]) );
smpp_middle dPPM490 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[597]) );
smpp_middle dPPM491 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[602]) );
smpp_middle dPPM492 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[607]) );
smpp_middle dPPM493 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[611]) );
smpp_middle dPPM494 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[614]) );
assign SUMMAND[615] = LOGIC_ONE;
smpp_high dPPH14 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[618]) );
smdecoder dDEC15 (.INA (OPB[29]), .INB (OPB[30]), .INC (OPB[31]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]) );
smpp_low dPPL15 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[270]) );
smr_gate dRGATE15 (.INA (OPB[29]), .INB (OPB[30]), .INC (OPB[31]), .PPBIT (SUMMAND[271]) );
smpp_middle dPPM495 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[287]) );
smpp_middle dPPM496 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[303]) );
smpp_middle dPPM497 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[321]) );
smpp_middle dPPM498 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[339]) );
smpp_middle dPPM499 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[356]) );
smpp_middle dPPM500 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[372]) );
smpp_middle dPPM501 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[388]) );
smpp_middle dPPM502 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[403]) );
smpp_middle dPPM503 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[418]) );
smpp_middle dPPM504 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[432]) );
smpp_middle dPPM505 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[446]) );
smpp_middle dPPM506 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[459]) );
smpp_middle dPPM507 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[472]) );
smpp_middle dPPM508 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[484]) );
smpp_middle dPPM509 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[496]) );
smpp_middle dPPM510 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[507]) );
smpp_middle dPPM511 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[518]) );
smpp_middle dPPM512 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[528]) );
smpp_middle dPPM513 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[538]) );
smpp_middle dPPM514 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[547]) );
smpp_middle dPPM515 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[556]) );
smpp_middle dPPM516 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[564]) );
smpp_middle dPPM517 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[572]) );
smpp_middle dPPM518 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[579]) );
smpp_middle dPPM519 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[586]) );
smpp_middle dPPM520 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[592]) );
smpp_middle dPPM521 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[598]) );
smpp_middle dPPM522 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[603]) );
smpp_middle dPPM523 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[608]) );
smpp_middle dPPM524 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[612]) );
smpp_middle dPPM525 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[616]) );
smpp_middle dPPM526 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[619]) );
smpp_middle dPPM527 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[621]) );
assign SUMMAND[622] = LOGIC_ONE;
smpp_high dPPH15 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[624]) );
smdecoder dDEC16 (.INA (OPB[31]), .INB (OPB[32]), .INC (OPB[33]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]) );
smpp_low dPPL16 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[304]) );
smr_gate dRGATE16 (.INA (OPB[31]), .INB (OPB[32]), .INC (OPB[33]), .PPBIT (SUMMAND[305]) );
smpp_middle dPPM528 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[322]) );
smpp_middle dPPM529 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[340]) );
smpp_middle dPPM530 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[357]) );
smpp_middle dPPM531 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[373]) );
smpp_middle dPPM532 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[389]) );
smpp_middle dPPM533 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[404]) );
smpp_middle dPPM534 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[419]) );
smpp_middle dPPM535 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[433]) );
smpp_middle dPPM536 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[447]) );
smpp_middle dPPM537 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[460]) );
smpp_middle dPPM538 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[473]) );
smpp_middle dPPM539 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[485]) );
smpp_middle dPPM540 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[497]) );
smpp_middle dPPM541 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[508]) );
smpp_middle dPPM542 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[519]) );
smpp_middle dPPM543 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[529]) );
smpp_middle dPPM544 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[539]) );
smpp_middle dPPM545 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[548]) );
smpp_middle dPPM546 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[557]) );
smpp_middle dPPM547 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[565]) );
smpp_middle dPPM548 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[573]) );
smpp_middle dPPM549 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[580]) );
smpp_middle dPPM550 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[587]) );
smpp_middle dPPM551 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[593]) );
smpp_middle dPPM552 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[599]) );
smpp_middle dPPM553 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[604]) );
smpp_middle dPPM554 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[609]) );
smpp_middle dPPM555 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[613]) );
smpp_middle dPPM556 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[617]) );
smpp_middle dPPM557 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[620]) );
smpp_middle dPPM558 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[623]) );
smpp_middle dPPM559 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[625]) );
smpp_middle dPPM560 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[626]) );
assign SUMMAND[627] = LOGIC_ONE;
smpp_high dPPH16 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[628]) );
endmodule
// Simple cells
module smpp_low ( ONEPOS, ONENEG, TWONEG, INA, INB, PPBIT );
input ONEPOS;
input ONENEG;
input TWONEG;
input INA;
input INB;
output PPBIT;
assign PPBIT = (ONEPOS & INA) | (ONENEG & INB) | TWONEG;
endmodule
module smpp_middle ( ONEPOS, ONENEG, TWOPOS, TWONEG, INA, INB, INC, IND, PPBIT );
input ONEPOS;
input ONENEG;
input TWOPOS;
input TWONEG;
input INA;
input INB;
input INC;
input IND;
output PPBIT;
assign PPBIT = ~ (( ~ (INA & TWOPOS)) & ( ~ (INB & TWONEG)) & ( ~ (INC & ONEPOS)) & ( ~ (IND & ONENEG)));
endmodule
module smpp_high ( ONEPOS, ONENEG, TWOPOS, TWONEG, INA, INB, PPBIT );
input ONEPOS;
input ONENEG;
input TWOPOS;
input TWONEG;
input INA;
input INB;
output PPBIT;
assign PPBIT = ~ ((INA & ONEPOS) | (INB & ONENEG) | (INA & TWOPOS) | (INB & TWONEG));
endmodule
module smr_gate ( INA, INB, INC, PPBIT );
input INA;
input INB;
input INC;
output PPBIT;
assign PPBIT = ( ~ (INA & INB)) & INC;
endmodule
module smdecoder ( INA, INB, INC, TWOPOS, TWONEG, ONEPOS, ONENEG );
input INA;
input INB;
input INC;
output TWOPOS;
output TWONEG;
output ONEPOS;
output ONENEG;
assign TWOPOS = ~ ( ~ (INA & INB & ( ~ INC)));
assign TWONEG = ~ ( ~ (( ~ INA) & ( ~ INB) & INC));
assign ONEPOS = (( ~ INA) & INB & ( ~ INC)) | (( ~ INC) & ( ~ INB) & INA);
assign ONENEG = (INA & ( ~ INB) & INC) | (INC & INB & ( ~ INA));
endmodule
module smfulladder ( DATA_A, DATA_B, DATA_C, SAVE, CARRY );
input DATA_A;
input DATA_B;
input DATA_C;
output SAVE;
output CARRY;
wire TMP;
assign TMP = DATA_A ^ DATA_B;
assign SAVE = TMP ^ DATA_C;
assign CARRY = ~ (( ~ (TMP & DATA_C)) & ( ~ (DATA_A & DATA_B)));
endmodule
module smhalfadder ( DATA_A, DATA_B, SAVE, CARRY );
input DATA_A;
input DATA_B;
output SAVE;
output CARRY;
assign SAVE = DATA_A ^ DATA_B;
assign CARRY = DATA_A & DATA_B;
endmodule
module smffa
(
input clk,
input en_d1,
input D,
output reg Q
);
always @ (posedge clk) begin
Q <= D;
end
endmodule
module smffb
(
input clk,
input en_d2,
input D,
output reg Q
);
always @ (posedge clk) begin
Q <= D;
end
endmodule
module sminvblock ( GIN, GOUT );
input GIN;
output GOUT;
assign GOUT = ~ GIN;
endmodule
module smxxor1 ( A, B, GIN, SUM );
input A;
input B;
input GIN;
output SUM;
assign SUM = ( ~ (A ^ B)) ^ GIN;
endmodule
module smblock0 ( A, B, POUT, GOUT );
input A;
input B;
output POUT;
output GOUT;
assign POUT = ~ (A | B);
assign GOUT = ~ (A & B);
endmodule
module smblock1 ( PIN1, PIN2, GIN1, GIN2, POUT, GOUT );
input PIN1;
input PIN2;
input GIN1;
input GIN2;
output POUT;
output GOUT;
assign POUT = ~ (PIN1 | PIN2);
assign GOUT = ~ (GIN2 & (PIN2 | GIN1));
endmodule
module smblock2 ( PIN1, PIN2, GIN1, GIN2, POUT, GOUT );
input PIN1;
input PIN2;
input GIN1;
input GIN2;
output POUT;
output GOUT;
assign POUT = ~ (PIN1 & PIN2);
assign GOUT = ~ (GIN2 | (PIN2 & GIN1));
endmodule
module smblock1a ( PIN2, GIN1, GIN2, GOUT );
input PIN2;
input GIN1;
input GIN2;
output GOUT;
assign GOUT = ~ (GIN2 & (PIN2 | GIN1));
endmodule
module smblock2a ( PIN2, GIN1, GIN2, GOUT );
input PIN2;
input GIN1;
input GIN2;
output GOUT;
assign GOUT = ~ (GIN2 | (PIN2 & GIN1));
endmodule
// Local Variables:
// compile-command: "vlint --brief --nowarn=MULTMF,MODLNM t_math_wallace_mul.v"
// End:
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2008 by Mahesh Kumashikar
module t_math_synmul_mul ( /*AUTOARG*/
// Outputs
product_d4,
// Inputs
clk, enable, negate, datA, datB
);
input clk;
input enable;
input negate;
input [31:0] datA;
input [31:0] datB;
// verilator lint_off UNOPTFLAT
output reg [64:0] product_d4;
reg [33:0] datA_d1r;
reg [33:0] datB_d1r;
always @ (posedge clk) begin
if (enable) begin
datA_d1r <= {2'b0,datA};
datB_d1r <= {2'b0,datB};
// The extra multiplier bits were for signed, for this
// test we've ripped that out
if (negate) $stop;
end
end
reg en_d1;
reg en_d2;
reg en_d3;
always @ (posedge clk) begin
en_d1 <= enable;
en_d2 <= en_d1;
en_d3 <= en_d2;
end
wire [63:0] prod_d3;
smmultiplier_34_34 mul (.OPA(datA_d1r),
.OPB(datB_d1r),
.RESULT(prod_d3),
/*AUTOINST*/
// Inputs
.clk (clk),
.en_d1 (en_d1),
.en_d2 (en_d2));
always @ (posedge clk) begin
if (en_d3) begin
product_d4 <= {1'b0,prod_d3};
end
end
endmodule
// The below was originally generated by the "Synthesizable Arithmetic Module Generator"
// at http://modgen.fysel.ntnu.no/~pihl/iwlas98/ then cleaned up by hand.
// Unfortunately the generator no longer appears available. Please contact
// us if you know otherwise.
module smmultiplier_34_34
(
input clk,
input en_d1,
input en_d2,
input [33:0] OPA,
input [33:0] OPB,
output [63:0] RESULT
);
wire [628:0] PPBIT;
wire [66:0] INT_CARRY;
wire [66:0] INT_SUM;
smboothcoder_34_34 db (.OPA(OPA[33:0]), .OPB(OPB[33:0]), .SUMMAND(PPBIT[628:0]) );
smwallace_34_34 dw (.SUMMAND(PPBIT[628:0]), .CARRY(INT_CARRY[66:1]), .SUM(INT_SUM[66:0]),
/*AUTOINST*/
// Inputs
.clk (clk),
.en_d1 (en_d1),
.en_d2 (en_d2));
assign INT_CARRY[0] = 1'b0;
smdblcadder_128_128 dd (.OPA(INT_SUM[63:0]), .OPB(INT_CARRY[63:0]), .CIN (1'b0), .SUM(RESULT));
endmodule
module smdblcadder_128_128 ( OPA, OPB, CIN, SUM );
input [63:0] OPA;
input [63:0] OPB;
input CIN;
output [63:0] SUM;
wire [63:0] INTPROP;
wire [63:0] INTGEN;
wire [0:0] PBIT;
wire [63:0] CARRY;
smprestage_128 dp (OPA[63:0], OPB[63:0], CIN, INTPROP, INTGEN );
smdblctree_128 dd (INTPROP[63:0], INTGEN[63:0], CARRY[63:0], PBIT );
smxorstage_128 dx (OPA[63:0], OPB[63:0], PBIT[0], CARRY[63:0], SUM );
endmodule
module smdblctree_128 ( PIN, GIN, GOUT, POUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] GOUT;
output [0:0] POUT;
wire [63:0] INTPROP_0;
wire [63:0] INTGEN_0;
wire [63:0] INTPROP_1;
wire [63:0] INTGEN_1;
wire [63:0] INTPROP_2;
wire [63:0] INTGEN_2;
wire [63:0] INTPROP_3;
wire [63:0] INTGEN_3;
wire [63:0] INTPROP_4;
wire [63:0] INTGEN_4;
wire [63:0] INTPROP_5;
wire [63:0] INTGEN_5;
smdblc_0_128 ddb0 (.PIN(PIN), .GIN(GIN), .POUT(INTPROP_0), .GOUT(INTGEN_0) );
smdblc_1_128 ddb1 (.PIN(INTPROP_0), .GIN(INTGEN_0), .POUT(INTPROP_1), .GOUT(INTGEN_1) );
smdblc_2_128 ddb2 (.PIN(INTPROP_1), .GIN(INTGEN_1), .POUT(INTPROP_2), .GOUT(INTGEN_2) );
smdblc_3_128 ddb3 (.PIN(INTPROP_2), .GIN(INTGEN_2), .POUT(INTPROP_3), .GOUT(INTGEN_3) );
smdblc_4_128 ddb4 (.PIN(INTPROP_3), .GIN(INTGEN_3), .POUT(INTPROP_4), .GOUT(INTGEN_4) );
smdblc_5_128 ddb5 (.PIN(INTPROP_4), .GIN(INTGEN_4), .POUT(INTPROP_5), .GOUT(INTGEN_5) );
smdblc_6_128 ddb6 (.PIN(INTPROP_5), .GIN(INTGEN_5), .POUT(POUT), .GOUT(GOUT) );
endmodule
module smwallace_34_34
(
input clk,
input en_d1,
input en_d2,
input [628:0] SUMMAND,
output [65:0] CARRY,
output [66:0] SUM
);
wire [628:0] LATCHED_PP;
wire [551:0] INT_CARRY;
wire [687:0] INT_SUM;
smffa dla0 (.D(SUMMAND[0]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[0]) );
smffa dla1 (.D(SUMMAND[1]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[1]) );
smhalfadder dha0 (.DATA_A (LATCHED_PP[0]), .DATA_B (LATCHED_PP[1]), .SAVE (INT_SUM[0]), .CARRY (INT_CARRY[0]) );
smffb dla2 (.D(INT_SUM[0]), .clk(clk), .en_d2(en_d2), .Q(SUM[0]) );
smffb dla3 (.D(INT_CARRY[0]), .clk(clk), .en_d2(en_d2), .Q(CARRY[0]) );
smffa dla4 (.D(SUMMAND[2]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[2]) );
assign INT_SUM[1] = LATCHED_PP[2];
assign CARRY[1] = 1'b0;
smffb dla5 (.D(INT_SUM[1]), .clk(clk), .en_d2(en_d2), .Q(SUM[1]) );
smffa dla6 (.D(SUMMAND[3]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[3]) );
smffa dla7 (.D(SUMMAND[4]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[4]) );
smffa dla8 (.D(SUMMAND[5]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[5]) );
smfulladder dfa0 (.DATA_A (LATCHED_PP[3]), .DATA_B (LATCHED_PP[4]), .DATA_C (LATCHED_PP[5]), .SAVE (INT_SUM[2]), .CARRY (INT_CARRY[1]) );
smffb dla9 (.D(INT_SUM[2]), .clk(clk), .en_d2(en_d2), .Q(SUM[2]) );
smffb dla10 (.D(INT_CARRY[1]), .clk(clk), .en_d2(en_d2), .Q(CARRY[2]) );
smffa dla11 (.D(SUMMAND[6]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[6]) );
smffa dla12 (.D(SUMMAND[7]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[7]) );
smhalfadder dha1 (.DATA_A (LATCHED_PP[6]), .DATA_B (LATCHED_PP[7]), .SAVE (INT_SUM[3]), .CARRY (INT_CARRY[2]) );
smffb dla13 (.D(INT_SUM[3]), .clk(clk), .en_d2(en_d2), .Q(SUM[3]) );
smffb dla14 (.D(INT_CARRY[2]), .clk(clk), .en_d2(en_d2), .Q(CARRY[3]) );
smffa dla15 (.D(SUMMAND[8]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[8]) );
smffa dla16 (.D(SUMMAND[9]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[9]) );
smffa dla17 (.D(SUMMAND[10]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[10]) );
smfulladder dfa1 (.DATA_A (LATCHED_PP[8]), .DATA_B (LATCHED_PP[9]), .DATA_C (LATCHED_PP[10]), .SAVE (INT_SUM[4]), .CARRY (INT_CARRY[4]) );
smffa dla18 (.D(SUMMAND[11]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[11]) );
assign INT_SUM[5] = LATCHED_PP[11];
smhalfadder dha2 (.DATA_A (INT_SUM[4]), .DATA_B (INT_SUM[5]), .SAVE (INT_SUM[6]), .CARRY (INT_CARRY[3]) );
smffb dla19 (.D(INT_SUM[6]), .clk(clk), .en_d2(en_d2), .Q(SUM[4]) );
smffb dla20 (.D(INT_CARRY[3]), .clk(clk), .en_d2(en_d2), .Q(CARRY[4]) );
smffa dla21 (.D(SUMMAND[12]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[12]) );
smffa dla22 (.D(SUMMAND[13]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[13]) );
smffa dla23 (.D(SUMMAND[14]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[14]) );
smfulladder dfa2 (.DATA_A (LATCHED_PP[12]), .DATA_B (LATCHED_PP[13]), .DATA_C (LATCHED_PP[14]), .SAVE (INT_SUM[7]), .CARRY (INT_CARRY[6]) );
smhalfadder dha3 (.DATA_A (INT_SUM[7]), .DATA_B (INT_CARRY[4]), .SAVE (INT_SUM[8]), .CARRY (INT_CARRY[5]) );
smffb dla24 (.D(INT_SUM[8]), .clk(clk), .en_d2(en_d2), .Q(SUM[5]) );
smffb dla25 (.D(INT_CARRY[5]), .clk(clk), .en_d2(en_d2), .Q(CARRY[5]) );
smffa dla26 (.D(SUMMAND[15]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[15]) );
smffa dla27 (.D(SUMMAND[16]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[16]) );
smffa dla28 (.D(SUMMAND[17]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[17]) );
smfulladder dfa3 (.DATA_A (LATCHED_PP[15]), .DATA_B (LATCHED_PP[16]), .DATA_C (LATCHED_PP[17]), .SAVE (INT_SUM[9]), .CARRY (INT_CARRY[8]) );
smffa dla29 (.D(SUMMAND[18]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[18]) );
smffa dla30 (.D(SUMMAND[19]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[19]) );
smhalfadder dha4 (.DATA_A (LATCHED_PP[18]), .DATA_B (LATCHED_PP[19]), .SAVE (INT_SUM[10]), .CARRY (INT_CARRY[9]) );
smfulladder dfa4 (.DATA_A (INT_SUM[9]), .DATA_B (INT_SUM[10]), .DATA_C (INT_CARRY[6]), .SAVE (INT_SUM[11]), .CARRY (INT_CARRY[7]) );
smffb dla31 (.D(INT_SUM[11]), .clk(clk), .en_d2(en_d2), .Q(SUM[6]) );
smffb dla32 (.D(INT_CARRY[7]), .clk(clk), .en_d2(en_d2), .Q(CARRY[6]) );
smffa dla33 (.D(SUMMAND[20]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[20]) );
smffa dla34 (.D(SUMMAND[21]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[21]) );
smffa dla35 (.D(SUMMAND[22]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[22]) );
smfulladder dfa5 (.DATA_A (LATCHED_PP[20]), .DATA_B (LATCHED_PP[21]), .DATA_C (LATCHED_PP[22]), .SAVE (INT_SUM[12]), .CARRY (INT_CARRY[11]) );
smffa dla36 (.D(SUMMAND[23]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[23]) );
assign INT_SUM[13] = LATCHED_PP[23];
smfulladder dfa6 (.DATA_A (INT_SUM[12]), .DATA_B (INT_SUM[13]), .DATA_C (INT_CARRY[8]), .SAVE (INT_SUM[14]), .CARRY (INT_CARRY[12]) );
assign INT_SUM[15] = INT_CARRY[9];
smhalfadder dha5 (.DATA_A (INT_SUM[14]), .DATA_B (INT_SUM[15]), .SAVE (INT_SUM[16]), .CARRY (INT_CARRY[10]) );
smffb dla37 (.D(INT_SUM[16]), .clk(clk), .en_d2(en_d2), .Q(SUM[7]) );
smffb dla38 (.D(INT_CARRY[10]), .clk(clk), .en_d2(en_d2), .Q(CARRY[7]) );
smffa dla39 (.D(SUMMAND[24]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[24]) );
smffa dla40 (.D(SUMMAND[25]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[25]) );
smffa dla41 (.D(SUMMAND[26]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[26]) );
smfulladder dfa7 (.DATA_A (LATCHED_PP[24]), .DATA_B (LATCHED_PP[25]), .DATA_C (LATCHED_PP[26]), .SAVE (INT_SUM[17]), .CARRY (INT_CARRY[14]) );
smffa dla42 (.D(SUMMAND[27]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[27]) );
smffa dla43 (.D(SUMMAND[28]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[28]) );
smffa dla44 (.D(SUMMAND[29]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[29]) );
smfulladder dfa8 (.DATA_A (LATCHED_PP[27]), .DATA_B (LATCHED_PP[28]), .DATA_C (LATCHED_PP[29]), .SAVE (INT_SUM[18]), .CARRY (INT_CARRY[15]) );
smfulladder dfa9 (.DATA_A (INT_SUM[17]), .DATA_B (INT_SUM[18]), .DATA_C (INT_CARRY[11]), .SAVE (INT_SUM[19]), .CARRY (INT_CARRY[16]) );
smhalfadder dha6 (.DATA_A (INT_SUM[19]), .DATA_B (INT_CARRY[12]), .SAVE (INT_SUM[20]), .CARRY (INT_CARRY[13]) );
smffb dla45 (.D(INT_SUM[20]), .clk(clk), .en_d2(en_d2), .Q(SUM[8]) );
smffb dla46 (.D(INT_CARRY[13]), .clk(clk), .en_d2(en_d2), .Q(CARRY[8]) );
smffa dla47 (.D(SUMMAND[30]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[30]) );
smffa dla48 (.D(SUMMAND[31]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[31]) );
smffa dla49 (.D(SUMMAND[32]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[32]) );
smfulladder dfa10 (.DATA_A (LATCHED_PP[30]), .DATA_B (LATCHED_PP[31]), .DATA_C (LATCHED_PP[32]), .SAVE (INT_SUM[21]), .CARRY (INT_CARRY[18]) );
smffa dla50 (.D(SUMMAND[33]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[33]) );
smffa dla51 (.D(SUMMAND[34]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[34]) );
smhalfadder dha7 (.DATA_A (LATCHED_PP[33]), .DATA_B (LATCHED_PP[34]), .SAVE (INT_SUM[22]), .CARRY (INT_CARRY[19]) );
smfulladder dfa11 (.DATA_A (INT_SUM[21]), .DATA_B (INT_SUM[22]), .DATA_C (INT_CARRY[14]), .SAVE (INT_SUM[23]), .CARRY (INT_CARRY[20]) );
assign INT_SUM[24] = INT_CARRY[15];
smfulladder dfa12 (.DATA_A (INT_SUM[23]), .DATA_B (INT_SUM[24]), .DATA_C (INT_CARRY[16]), .SAVE (INT_SUM[25]), .CARRY (INT_CARRY[17]) );
smffb dla52 (.D(INT_SUM[25]), .clk(clk), .en_d2(en_d2), .Q(SUM[9]) );
smffb dla53 (.D(INT_CARRY[17]), .clk(clk), .en_d2(en_d2), .Q(CARRY[9]) );
smffa dla54 (.D(SUMMAND[35]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[35]) );
smffa dla55 (.D(SUMMAND[36]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[36]) );
smffa dla56 (.D(SUMMAND[37]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[37]) );
smfulladder dfa13 (.DATA_A (LATCHED_PP[35]), .DATA_B (LATCHED_PP[36]), .DATA_C (LATCHED_PP[37]), .SAVE (INT_SUM[26]), .CARRY (INT_CARRY[22]) );
smffa dla57 (.D(SUMMAND[38]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[38]) );
smffa dla58 (.D(SUMMAND[39]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[39]) );
smffa dla59 (.D(SUMMAND[40]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[40]) );
smfulladder dfa14 (.DATA_A (LATCHED_PP[38]), .DATA_B (LATCHED_PP[39]), .DATA_C (LATCHED_PP[40]), .SAVE (INT_SUM[27]), .CARRY (INT_CARRY[23]) );
smffa dla60 (.D(SUMMAND[41]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[41]) );
assign INT_SUM[28] = LATCHED_PP[41];
smfulladder dfa15 (.DATA_A (INT_SUM[26]), .DATA_B (INT_SUM[27]), .DATA_C (INT_SUM[28]), .SAVE (INT_SUM[29]), .CARRY (INT_CARRY[24]) );
smhalfadder dha8 (.DATA_A (INT_CARRY[18]), .DATA_B (INT_CARRY[19]), .SAVE (INT_SUM[30]), .CARRY (INT_CARRY[25]) );
smfulladder dfa16 (.DATA_A (INT_SUM[29]), .DATA_B (INT_SUM[30]), .DATA_C (INT_CARRY[20]), .SAVE (INT_SUM[31]), .CARRY (INT_CARRY[21]) );
smffb dla61 (.D(INT_SUM[31]), .clk(clk), .en_d2(en_d2), .Q(SUM[10]) );
smffb dla62 (.D(INT_CARRY[21]), .clk(clk), .en_d2(en_d2), .Q(CARRY[10]) );
smffa dla63 (.D(SUMMAND[42]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[42]) );
smffa dla64 (.D(SUMMAND[43]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[43]) );
smffa dla65 (.D(SUMMAND[44]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[44]) );
smfulladder dfa17 (.DATA_A (LATCHED_PP[42]), .DATA_B (LATCHED_PP[43]), .DATA_C (LATCHED_PP[44]), .SAVE (INT_SUM[32]), .CARRY (INT_CARRY[27]) );
smffa dla66 (.D(SUMMAND[45]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[45]) );
smffa dla67 (.D(SUMMAND[46]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[46]) );
smffa dla68 (.D(SUMMAND[47]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[47]) );
smfulladder dfa18 (.DATA_A (LATCHED_PP[45]), .DATA_B (LATCHED_PP[46]), .DATA_C (LATCHED_PP[47]), .SAVE (INT_SUM[33]), .CARRY (INT_CARRY[28]) );
smfulladder dfa19 (.DATA_A (INT_SUM[32]), .DATA_B (INT_SUM[33]), .DATA_C (INT_CARRY[22]), .SAVE (INT_SUM[34]), .CARRY (INT_CARRY[29]) );
assign INT_SUM[35] = INT_CARRY[23];
smfulladder dfa20 (.DATA_A (INT_SUM[34]), .DATA_B (INT_SUM[35]), .DATA_C (INT_CARRY[24]), .SAVE (INT_SUM[36]), .CARRY (INT_CARRY[30]) );
assign INT_SUM[37] = INT_CARRY[25];
smhalfadder dha9 (.DATA_A (INT_SUM[36]), .DATA_B (INT_SUM[37]), .SAVE (INT_SUM[38]), .CARRY (INT_CARRY[26]) );
smffb dla69 (.D(INT_SUM[38]), .clk(clk), .en_d2(en_d2), .Q(SUM[11]) );
smffb dla70 (.D(INT_CARRY[26]), .clk(clk), .en_d2(en_d2), .Q(CARRY[11]) );
smffa dla71 (.D(SUMMAND[48]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[48]) );
smffa dla72 (.D(SUMMAND[49]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[49]) );
smffa dla73 (.D(SUMMAND[50]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[50]) );
smfulladder dfa21 (.DATA_A (LATCHED_PP[48]), .DATA_B (LATCHED_PP[49]), .DATA_C (LATCHED_PP[50]), .SAVE (INT_SUM[39]), .CARRY (INT_CARRY[32]) );
smffa dla74 (.D(SUMMAND[51]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[51]) );
smffa dla75 (.D(SUMMAND[52]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[52]) );
smffa dla76 (.D(SUMMAND[53]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[53]) );
smfulladder dfa22 (.DATA_A (LATCHED_PP[51]), .DATA_B (LATCHED_PP[52]), .DATA_C (LATCHED_PP[53]), .SAVE (INT_SUM[40]), .CARRY (INT_CARRY[33]) );
smffa dla77 (.D(SUMMAND[54]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[54]) );
assign INT_SUM[41] = LATCHED_PP[54];
smffa dla78 (.D(SUMMAND[55]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[55]) );
assign INT_SUM[42] = LATCHED_PP[55];
smfulladder dfa23 (.DATA_A (INT_SUM[39]), .DATA_B (INT_SUM[40]), .DATA_C (INT_SUM[41]), .SAVE (INT_SUM[43]), .CARRY (INT_CARRY[34]) );
smfulladder dfa24 (.DATA_A (INT_SUM[42]), .DATA_B (INT_CARRY[27]), .DATA_C (INT_CARRY[28]), .SAVE (INT_SUM[44]), .CARRY (INT_CARRY[35]) );
smfulladder dfa25 (.DATA_A (INT_SUM[43]), .DATA_B (INT_SUM[44]), .DATA_C (INT_CARRY[29]), .SAVE (INT_SUM[45]), .CARRY (INT_CARRY[36]) );
smhalfadder dha10 (.DATA_A (INT_SUM[45]), .DATA_B (INT_CARRY[30]), .SAVE (INT_SUM[46]), .CARRY (INT_CARRY[31]) );
smffb dla79 (.D(INT_SUM[46]), .clk(clk), .en_d2(en_d2), .Q(SUM[12]) );
smffb dla80 (.D(INT_CARRY[31]), .clk(clk), .en_d2(en_d2), .Q(CARRY[12]) );
smffa dla81 (.D(SUMMAND[56]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[56]) );
smffa dla82 (.D(SUMMAND[57]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[57]) );
smffa dla83 (.D(SUMMAND[58]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[58]) );
smfulladder dfa26 (.DATA_A (LATCHED_PP[56]), .DATA_B (LATCHED_PP[57]), .DATA_C (LATCHED_PP[58]), .SAVE (INT_SUM[47]), .CARRY (INT_CARRY[38]) );
smffa dla84 (.D(SUMMAND[59]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[59]) );
smffa dla85 (.D(SUMMAND[60]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[60]) );
smffa dla86 (.D(SUMMAND[61]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[61]) );
smfulladder dfa27 (.DATA_A (LATCHED_PP[59]), .DATA_B (LATCHED_PP[60]), .DATA_C (LATCHED_PP[61]), .SAVE (INT_SUM[48]), .CARRY (INT_CARRY[39]) );
smffa dla87 (.D(SUMMAND[62]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[62]) );
assign INT_SUM[49] = LATCHED_PP[62];
smfulladder dfa28 (.DATA_A (INT_SUM[47]), .DATA_B (INT_SUM[48]), .DATA_C (INT_SUM[49]), .SAVE (INT_SUM[50]), .CARRY (INT_CARRY[40]) );
smhalfadder dha11 (.DATA_A (INT_CARRY[32]), .DATA_B (INT_CARRY[33]), .SAVE (INT_SUM[51]), .CARRY (INT_CARRY[41]) );
smfulladder dfa29 (.DATA_A (INT_SUM[50]), .DATA_B (INT_SUM[51]), .DATA_C (INT_CARRY[34]), .SAVE (INT_SUM[52]), .CARRY (INT_CARRY[42]) );
assign INT_SUM[53] = INT_CARRY[35];
smfulladder dfa30 (.DATA_A (INT_SUM[52]), .DATA_B (INT_SUM[53]), .DATA_C (INT_CARRY[36]), .SAVE (INT_SUM[54]), .CARRY (INT_CARRY[37]) );
smffb dla88 (.D(INT_SUM[54]), .clk(clk), .en_d2(en_d2), .Q(SUM[13]) );
smffb dla89 (.D(INT_CARRY[37]), .clk(clk), .en_d2(en_d2), .Q(CARRY[13]) );
smffa dla90 (.D(SUMMAND[63]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[63]) );
smffa dla91 (.D(SUMMAND[64]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[64]) );
smffa dla92 (.D(SUMMAND[65]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[65]) );
smfulladder dfa31 (.DATA_A (LATCHED_PP[63]), .DATA_B (LATCHED_PP[64]), .DATA_C (LATCHED_PP[65]), .SAVE (INT_SUM[55]), .CARRY (INT_CARRY[44]) );
smffa dla93 (.D(SUMMAND[66]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[66]) );
smffa dla94 (.D(SUMMAND[67]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[67]) );
smffa dla95 (.D(SUMMAND[68]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[68]) );
smfulladder dfa32 (.DATA_A (LATCHED_PP[66]), .DATA_B (LATCHED_PP[67]), .DATA_C (LATCHED_PP[68]), .SAVE (INT_SUM[56]), .CARRY (INT_CARRY[45]) );
smffa dla96 (.D(SUMMAND[69]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[69]) );
smffa dla97 (.D(SUMMAND[70]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[70]) );
smffa dla98 (.D(SUMMAND[71]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[71]) );
smfulladder dfa33 (.DATA_A (LATCHED_PP[69]), .DATA_B (LATCHED_PP[70]), .DATA_C (LATCHED_PP[71]), .SAVE (INT_SUM[57]), .CARRY (INT_CARRY[46]) );
smfulladder dfa34 (.DATA_A (INT_SUM[55]), .DATA_B (INT_SUM[56]), .DATA_C (INT_SUM[57]), .SAVE (INT_SUM[58]), .CARRY (INT_CARRY[47]) );
smhalfadder dha12 (.DATA_A (INT_CARRY[38]), .DATA_B (INT_CARRY[39]), .SAVE (INT_SUM[59]), .CARRY (INT_CARRY[48]) );
smfulladder dfa35 (.DATA_A (INT_SUM[58]), .DATA_B (INT_SUM[59]), .DATA_C (INT_CARRY[40]), .SAVE (INT_SUM[60]), .CARRY (INT_CARRY[49]) );
assign INT_SUM[61] = INT_CARRY[41];
smfulladder dfa36 (.DATA_A (INT_SUM[60]), .DATA_B (INT_SUM[61]), .DATA_C (INT_CARRY[42]), .SAVE (INT_SUM[62]), .CARRY (INT_CARRY[43]) );
smffb dla99 (.D(INT_SUM[62]), .clk(clk), .en_d2(en_d2), .Q(SUM[14]) );
smffb dla100 (.D(INT_CARRY[43]), .clk(clk), .en_d2(en_d2), .Q(CARRY[14]) );
smffa dla101 (.D(SUMMAND[72]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[72]) );
smffa dla102 (.D(SUMMAND[73]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[73]) );
smffa dla103 (.D(SUMMAND[74]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[74]) );
smfulladder dfa37 (.DATA_A (LATCHED_PP[72]), .DATA_B (LATCHED_PP[73]), .DATA_C (LATCHED_PP[74]), .SAVE (INT_SUM[63]), .CARRY (INT_CARRY[51]) );
smffa dla104 (.D(SUMMAND[75]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[75]) );
smffa dla105 (.D(SUMMAND[76]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[76]) );
smffa dla106 (.D(SUMMAND[77]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[77]) );
smfulladder dfa38 (.DATA_A (LATCHED_PP[75]), .DATA_B (LATCHED_PP[76]), .DATA_C (LATCHED_PP[77]), .SAVE (INT_SUM[64]), .CARRY (INT_CARRY[52]) );
smffa dla107 (.D(SUMMAND[78]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[78]) );
smffa dla108 (.D(SUMMAND[79]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[79]) );
smhalfadder dha13 (.DATA_A (LATCHED_PP[78]), .DATA_B (LATCHED_PP[79]), .SAVE (INT_SUM[65]), .CARRY (INT_CARRY[53]) );
smfulladder dfa39 (.DATA_A (INT_SUM[63]), .DATA_B (INT_SUM[64]), .DATA_C (INT_SUM[65]), .SAVE (INT_SUM[66]), .CARRY (INT_CARRY[54]) );
smfulladder dfa40 (.DATA_A (INT_CARRY[44]), .DATA_B (INT_CARRY[45]), .DATA_C (INT_CARRY[46]), .SAVE (INT_SUM[67]), .CARRY (INT_CARRY[55]) );
smfulladder dfa41 (.DATA_A (INT_SUM[66]), .DATA_B (INT_SUM[67]), .DATA_C (INT_CARRY[47]), .SAVE (INT_SUM[68]), .CARRY (INT_CARRY[56]) );
assign INT_SUM[69] = INT_CARRY[48];
smfulladder dfa42 (.DATA_A (INT_SUM[68]), .DATA_B (INT_SUM[69]), .DATA_C (INT_CARRY[49]), .SAVE (INT_SUM[70]), .CARRY (INT_CARRY[50]) );
smffb dla109 (.D(INT_SUM[70]), .clk(clk), .en_d2(en_d2), .Q(SUM[15]) );
smffb dla110 (.D(INT_CARRY[50]), .clk(clk), .en_d2(en_d2), .Q(CARRY[15]) );
smffa dla111 (.D(SUMMAND[80]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[80]) );
smffa dla112 (.D(SUMMAND[81]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[81]) );
smffa dla113 (.D(SUMMAND[82]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[82]) );
smfulladder dfa43 (.DATA_A (LATCHED_PP[80]), .DATA_B (LATCHED_PP[81]), .DATA_C (LATCHED_PP[82]), .SAVE (INT_SUM[71]), .CARRY (INT_CARRY[58]) );
smffa dla114 (.D(SUMMAND[83]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[83]) );
smffa dla115 (.D(SUMMAND[84]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[84]) );
smffa dla116 (.D(SUMMAND[85]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[85]) );
smfulladder dfa44 (.DATA_A (LATCHED_PP[83]), .DATA_B (LATCHED_PP[84]), .DATA_C (LATCHED_PP[85]), .SAVE (INT_SUM[72]), .CARRY (INT_CARRY[59]) );
smffa dla117 (.D(SUMMAND[86]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[86]) );
smffa dla118 (.D(SUMMAND[87]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[87]) );
smffa dla119 (.D(SUMMAND[88]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[88]) );
smfulladder dfa45 (.DATA_A (LATCHED_PP[86]), .DATA_B (LATCHED_PP[87]), .DATA_C (LATCHED_PP[88]), .SAVE (INT_SUM[73]), .CARRY (INT_CARRY[60]) );
smffa dla120 (.D(SUMMAND[89]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[89]) );
assign INT_SUM[74] = LATCHED_PP[89];
smfulladder dfa46 (.DATA_A (INT_SUM[71]), .DATA_B (INT_SUM[72]), .DATA_C (INT_SUM[73]), .SAVE (INT_SUM[75]), .CARRY (INT_CARRY[61]) );
smfulladder dfa47 (.DATA_A (INT_SUM[74]), .DATA_B (INT_CARRY[51]), .DATA_C (INT_CARRY[52]), .SAVE (INT_SUM[76]), .CARRY (INT_CARRY[62]) );
assign INT_SUM[77] = INT_CARRY[53];
smfulladder dfa48 (.DATA_A (INT_SUM[75]), .DATA_B (INT_SUM[76]), .DATA_C (INT_SUM[77]), .SAVE (INT_SUM[78]), .CARRY (INT_CARRY[63]) );
smhalfadder dha14 (.DATA_A (INT_CARRY[54]), .DATA_B (INT_CARRY[55]), .SAVE (INT_SUM[79]), .CARRY (INT_CARRY[64]) );
smfulladder dfa49 (.DATA_A (INT_SUM[78]), .DATA_B (INT_SUM[79]), .DATA_C (INT_CARRY[56]), .SAVE (INT_SUM[80]), .CARRY (INT_CARRY[57]) );
smffb dla121 (.D(INT_SUM[80]), .clk(clk), .en_d2(en_d2), .Q(SUM[16]) );
smffb dla122 (.D(INT_CARRY[57]), .clk(clk), .en_d2(en_d2), .Q(CARRY[16]) );
smffa dla123 (.D(SUMMAND[90]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[90]) );
smffa dla124 (.D(SUMMAND[91]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[91]) );
smffa dla125 (.D(SUMMAND[92]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[92]) );
smfulladder dfa50 (.DATA_A (LATCHED_PP[90]), .DATA_B (LATCHED_PP[91]), .DATA_C (LATCHED_PP[92]), .SAVE (INT_SUM[81]), .CARRY (INT_CARRY[66]) );
smffa dla126 (.D(SUMMAND[93]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[93]) );
smffa dla127 (.D(SUMMAND[94]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[94]) );
smffa dla128 (.D(SUMMAND[95]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[95]) );
smfulladder dfa51 (.DATA_A (LATCHED_PP[93]), .DATA_B (LATCHED_PP[94]), .DATA_C (LATCHED_PP[95]), .SAVE (INT_SUM[82]), .CARRY (INT_CARRY[67]) );
smffa dla129 (.D(SUMMAND[96]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[96]) );
smffa dla130 (.D(SUMMAND[97]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[97]) );
smffa dla131 (.D(SUMMAND[98]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[98]) );
smfulladder dfa52 (.DATA_A (LATCHED_PP[96]), .DATA_B (LATCHED_PP[97]), .DATA_C (LATCHED_PP[98]), .SAVE (INT_SUM[83]), .CARRY (INT_CARRY[68]) );
smfulladder dfa53 (.DATA_A (INT_SUM[81]), .DATA_B (INT_SUM[82]), .DATA_C (INT_SUM[83]), .SAVE (INT_SUM[84]), .CARRY (INT_CARRY[69]) );
smfulladder dfa54 (.DATA_A (INT_CARRY[58]), .DATA_B (INT_CARRY[59]), .DATA_C (INT_CARRY[60]), .SAVE (INT_SUM[85]), .CARRY (INT_CARRY[70]) );
smfulladder dfa55 (.DATA_A (INT_SUM[84]), .DATA_B (INT_SUM[85]), .DATA_C (INT_CARRY[61]), .SAVE (INT_SUM[86]), .CARRY (INT_CARRY[71]) );
assign INT_SUM[87] = INT_CARRY[62];
smfulladder dfa56 (.DATA_A (INT_SUM[86]), .DATA_B (INT_SUM[87]), .DATA_C (INT_CARRY[63]), .SAVE (INT_SUM[88]), .CARRY (INT_CARRY[72]) );
assign INT_SUM[89] = INT_CARRY[64];
smhalfadder dha15 (.DATA_A (INT_SUM[88]), .DATA_B (INT_SUM[89]), .SAVE (INT_SUM[90]), .CARRY (INT_CARRY[65]) );
smffb dla132 (.D(INT_SUM[90]), .clk(clk), .en_d2(en_d2), .Q(SUM[17]) );
smffb dla133 (.D(INT_CARRY[65]), .clk(clk), .en_d2(en_d2), .Q(CARRY[17]) );
smffa dla134 (.D(SUMMAND[99]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[99]) );
smffa dla135 (.D(SUMMAND[100]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[100]) );
smffa dla136 (.D(SUMMAND[101]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[101]) );
smfulladder dfa57 (.DATA_A (LATCHED_PP[99]), .DATA_B (LATCHED_PP[100]), .DATA_C (LATCHED_PP[101]), .SAVE (INT_SUM[91]), .CARRY (INT_CARRY[74]) );
smffa dla137 (.D(SUMMAND[102]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[102]) );
smffa dla138 (.D(SUMMAND[103]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[103]) );
smffa dla139 (.D(SUMMAND[104]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[104]) );
smfulladder dfa58 (.DATA_A (LATCHED_PP[102]), .DATA_B (LATCHED_PP[103]), .DATA_C (LATCHED_PP[104]), .SAVE (INT_SUM[92]), .CARRY (INT_CARRY[75]) );
smffa dla140 (.D(SUMMAND[105]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[105]) );
smffa dla141 (.D(SUMMAND[106]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[106]) );
smffa dla142 (.D(SUMMAND[107]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[107]) );
smfulladder dfa59 (.DATA_A (LATCHED_PP[105]), .DATA_B (LATCHED_PP[106]), .DATA_C (LATCHED_PP[107]), .SAVE (INT_SUM[93]), .CARRY (INT_CARRY[76]) );
smffa dla143 (.D(SUMMAND[108]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[108]) );
assign INT_SUM[94] = LATCHED_PP[108];
smffa dla144 (.D(SUMMAND[109]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[109]) );
assign INT_SUM[95] = LATCHED_PP[109];
smfulladder dfa60 (.DATA_A (INT_SUM[91]), .DATA_B (INT_SUM[92]), .DATA_C (INT_SUM[93]), .SAVE (INT_SUM[96]), .CARRY (INT_CARRY[77]) );
smfulladder dfa61 (.DATA_A (INT_SUM[94]), .DATA_B (INT_SUM[95]), .DATA_C (INT_CARRY[66]), .SAVE (INT_SUM[97]), .CARRY (INT_CARRY[78]) );
assign INT_SUM[98] = INT_CARRY[67];
assign INT_SUM[99] = INT_CARRY[68];
smfulladder dfa62 (.DATA_A (INT_SUM[96]), .DATA_B (INT_SUM[97]), .DATA_C (INT_SUM[98]), .SAVE (INT_SUM[100]), .CARRY (INT_CARRY[79]) );
smfulladder dfa63 (.DATA_A (INT_SUM[99]), .DATA_B (INT_CARRY[69]), .DATA_C (INT_CARRY[70]), .SAVE (INT_SUM[101]), .CARRY (INT_CARRY[80]) );
smfulladder dfa64 (.DATA_A (INT_SUM[100]), .DATA_B (INT_SUM[101]), .DATA_C (INT_CARRY[71]), .SAVE (INT_SUM[102]), .CARRY (INT_CARRY[81]) );
smhalfadder dha16 (.DATA_A (INT_SUM[102]), .DATA_B (INT_CARRY[72]), .SAVE (INT_SUM[103]), .CARRY (INT_CARRY[73]) );
smffb dla145 (.D(INT_SUM[103]), .clk(clk), .en_d2(en_d2), .Q(SUM[18]) );
smffb dla146 (.D(INT_CARRY[73]), .clk(clk), .en_d2(en_d2), .Q(CARRY[18]) );
smffa dla147 (.D(SUMMAND[110]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[110]) );
smffa dla148 (.D(SUMMAND[111]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[111]) );
smffa dla149 (.D(SUMMAND[112]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[112]) );
smfulladder dfa65 (.DATA_A (LATCHED_PP[110]), .DATA_B (LATCHED_PP[111]), .DATA_C (LATCHED_PP[112]), .SAVE (INT_SUM[104]), .CARRY (INT_CARRY[83]) );
smffa dla150 (.D(SUMMAND[113]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[113]) );
smffa dla151 (.D(SUMMAND[114]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[114]) );
smffa dla152 (.D(SUMMAND[115]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[115]) );
smfulladder dfa66 (.DATA_A (LATCHED_PP[113]), .DATA_B (LATCHED_PP[114]), .DATA_C (LATCHED_PP[115]), .SAVE (INT_SUM[105]), .CARRY (INT_CARRY[84]) );
smffa dla153 (.D(SUMMAND[116]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[116]) );
smffa dla154 (.D(SUMMAND[117]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[117]) );
smffa dla155 (.D(SUMMAND[118]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[118]) );
smfulladder dfa67 (.DATA_A (LATCHED_PP[116]), .DATA_B (LATCHED_PP[117]), .DATA_C (LATCHED_PP[118]), .SAVE (INT_SUM[106]), .CARRY (INT_CARRY[85]) );
smffa dla156 (.D(SUMMAND[119]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[119]) );
assign INT_SUM[107] = LATCHED_PP[119];
smfulladder dfa68 (.DATA_A (INT_SUM[104]), .DATA_B (INT_SUM[105]), .DATA_C (INT_SUM[106]), .SAVE (INT_SUM[108]), .CARRY (INT_CARRY[86]) );
smfulladder dfa69 (.DATA_A (INT_SUM[107]), .DATA_B (INT_CARRY[74]), .DATA_C (INT_CARRY[75]), .SAVE (INT_SUM[109]), .CARRY (INT_CARRY[87]) );
assign INT_SUM[110] = INT_CARRY[76];
smfulladder dfa70 (.DATA_A (INT_SUM[108]), .DATA_B (INT_SUM[109]), .DATA_C (INT_SUM[110]), .SAVE (INT_SUM[111]), .CARRY (INT_CARRY[88]) );
smhalfadder dha17 (.DATA_A (INT_CARRY[77]), .DATA_B (INT_CARRY[78]), .SAVE (INT_SUM[112]), .CARRY (INT_CARRY[89]) );
smfulladder dfa71 (.DATA_A (INT_SUM[111]), .DATA_B (INT_SUM[112]), .DATA_C (INT_CARRY[79]), .SAVE (INT_SUM[113]), .CARRY (INT_CARRY[90]) );
assign INT_SUM[114] = INT_CARRY[80];
smfulladder dfa72 (.DATA_A (INT_SUM[113]), .DATA_B (INT_SUM[114]), .DATA_C (INT_CARRY[81]), .SAVE (INT_SUM[115]), .CARRY (INT_CARRY[82]) );
smffb dla157 (.D(INT_SUM[115]), .clk(clk), .en_d2(en_d2), .Q(SUM[19]) );
smffb dla158 (.D(INT_CARRY[82]), .clk(clk), .en_d2(en_d2), .Q(CARRY[19]) );
smffa dla159 (.D(SUMMAND[120]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[120]) );
smffa dla160 (.D(SUMMAND[121]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[121]) );
smffa dla161 (.D(SUMMAND[122]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[122]) );
smfulladder dfa73 (.DATA_A (LATCHED_PP[120]), .DATA_B (LATCHED_PP[121]), .DATA_C (LATCHED_PP[122]), .SAVE (INT_SUM[116]), .CARRY (INT_CARRY[92]) );
smffa dla162 (.D(SUMMAND[123]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[123]) );
smffa dla163 (.D(SUMMAND[124]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[124]) );
smffa dla164 (.D(SUMMAND[125]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[125]) );
smfulladder dfa74 (.DATA_A (LATCHED_PP[123]), .DATA_B (LATCHED_PP[124]), .DATA_C (LATCHED_PP[125]), .SAVE (INT_SUM[117]), .CARRY (INT_CARRY[93]) );
smffa dla165 (.D(SUMMAND[126]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[126]) );
smffa dla166 (.D(SUMMAND[127]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[127]) );
smffa dla167 (.D(SUMMAND[128]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[128]) );
smfulladder dfa75 (.DATA_A (LATCHED_PP[126]), .DATA_B (LATCHED_PP[127]), .DATA_C (LATCHED_PP[128]), .SAVE (INT_SUM[118]), .CARRY (INT_CARRY[94]) );
smffa dla168 (.D(SUMMAND[129]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[129]) );
smffa dla169 (.D(SUMMAND[130]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[130]) );
smffa dla170 (.D(SUMMAND[131]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[131]) );
smfulladder dfa76 (.DATA_A (LATCHED_PP[129]), .DATA_B (LATCHED_PP[130]), .DATA_C (LATCHED_PP[131]), .SAVE (INT_SUM[119]), .CARRY (INT_CARRY[95]) );
smfulladder dfa77 (.DATA_A (INT_SUM[116]), .DATA_B (INT_SUM[117]), .DATA_C (INT_SUM[118]), .SAVE (INT_SUM[120]), .CARRY (INT_CARRY[96]) );
smfulladder dfa78 (.DATA_A (INT_SUM[119]), .DATA_B (INT_CARRY[83]), .DATA_C (INT_CARRY[84]), .SAVE (INT_SUM[121]), .CARRY (INT_CARRY[97]) );
assign INT_SUM[122] = INT_CARRY[85];
smfulladder dfa79 (.DATA_A (INT_SUM[120]), .DATA_B (INT_SUM[121]), .DATA_C (INT_SUM[122]), .SAVE (INT_SUM[123]), .CARRY (INT_CARRY[98]) );
smhalfadder dha18 (.DATA_A (INT_CARRY[86]), .DATA_B (INT_CARRY[87]), .SAVE (INT_SUM[124]), .CARRY (INT_CARRY[99]) );
smfulladder dfa80 (.DATA_A (INT_SUM[123]), .DATA_B (INT_SUM[124]), .DATA_C (INT_CARRY[88]), .SAVE (INT_SUM[125]), .CARRY (INT_CARRY[100]) );
assign INT_SUM[126] = INT_CARRY[89];
smfulladder dfa81 (.DATA_A (INT_SUM[125]), .DATA_B (INT_SUM[126]), .DATA_C (INT_CARRY[90]), .SAVE (INT_SUM[127]), .CARRY (INT_CARRY[91]) );
smffb dla171 (.D(INT_SUM[127]), .clk(clk), .en_d2(en_d2), .Q(SUM[20]) );
smffb dla172 (.D(INT_CARRY[91]), .clk(clk), .en_d2(en_d2), .Q(CARRY[20]) );
smffa dla173 (.D(SUMMAND[132]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[132]) );
smffa dla174 (.D(SUMMAND[133]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[133]) );
smffa dla175 (.D(SUMMAND[134]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[134]) );
smfulladder dfa82 (.DATA_A (LATCHED_PP[132]), .DATA_B (LATCHED_PP[133]), .DATA_C (LATCHED_PP[134]), .SAVE (INT_SUM[128]), .CARRY (INT_CARRY[102]) );
smffa dla176 (.D(SUMMAND[135]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[135]) );
smffa dla177 (.D(SUMMAND[136]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[136]) );
smffa dla178 (.D(SUMMAND[137]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[137]) );
smfulladder dfa83 (.DATA_A (LATCHED_PP[135]), .DATA_B (LATCHED_PP[136]), .DATA_C (LATCHED_PP[137]), .SAVE (INT_SUM[129]), .CARRY (INT_CARRY[103]) );
smffa dla179 (.D(SUMMAND[138]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[138]) );
smffa dla180 (.D(SUMMAND[139]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[139]) );
smffa dla181 (.D(SUMMAND[140]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[140]) );
smfulladder dfa84 (.DATA_A (LATCHED_PP[138]), .DATA_B (LATCHED_PP[139]), .DATA_C (LATCHED_PP[140]), .SAVE (INT_SUM[130]), .CARRY (INT_CARRY[104]) );
smffa dla182 (.D(SUMMAND[141]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[141]) );
assign INT_SUM[131] = LATCHED_PP[141];
smffa dla183 (.D(SUMMAND[142]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[142]) );
assign INT_SUM[132] = LATCHED_PP[142];
smfulladder dfa85 (.DATA_A (INT_SUM[128]), .DATA_B (INT_SUM[129]), .DATA_C (INT_SUM[130]), .SAVE (INT_SUM[133]), .CARRY (INT_CARRY[105]) );
smfulladder dfa86 (.DATA_A (INT_SUM[131]), .DATA_B (INT_SUM[132]), .DATA_C (INT_CARRY[92]), .SAVE (INT_SUM[134]), .CARRY (INT_CARRY[106]) );
smfulladder dfa87 (.DATA_A (INT_CARRY[93]), .DATA_B (INT_CARRY[94]), .DATA_C (INT_CARRY[95]), .SAVE (INT_SUM[135]), .CARRY (INT_CARRY[107]) );
smfulladder dfa88 (.DATA_A (INT_SUM[133]), .DATA_B (INT_SUM[134]), .DATA_C (INT_SUM[135]), .SAVE (INT_SUM[136]), .CARRY (INT_CARRY[108]) );
smhalfadder dha19 (.DATA_A (INT_CARRY[96]), .DATA_B (INT_CARRY[97]), .SAVE (INT_SUM[137]), .CARRY (INT_CARRY[109]) );
smfulladder dfa89 (.DATA_A (INT_SUM[136]), .DATA_B (INT_SUM[137]), .DATA_C (INT_CARRY[98]), .SAVE (INT_SUM[138]), .CARRY (INT_CARRY[110]) );
assign INT_SUM[139] = INT_CARRY[99];
smfulladder dfa90 (.DATA_A (INT_SUM[138]), .DATA_B (INT_SUM[139]), .DATA_C (INT_CARRY[100]), .SAVE (INT_SUM[140]), .CARRY (INT_CARRY[101]) );
smffb dla184 (.D(INT_SUM[140]), .clk(clk), .en_d2(en_d2), .Q(SUM[21]) );
smffb dla185 (.D(INT_CARRY[101]), .clk(clk), .en_d2(en_d2), .Q(CARRY[21]) );
smffa dla186 (.D(SUMMAND[143]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[143]) );
smffa dla187 (.D(SUMMAND[144]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[144]) );
smffa dla188 (.D(SUMMAND[145]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[145]) );
smfulladder dfa91 (.DATA_A (LATCHED_PP[143]), .DATA_B (LATCHED_PP[144]), .DATA_C (LATCHED_PP[145]), .SAVE (INT_SUM[141]), .CARRY (INT_CARRY[112]) );
smffa dla189 (.D(SUMMAND[146]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[146]) );
smffa dla190 (.D(SUMMAND[147]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[147]) );
smffa dla191 (.D(SUMMAND[148]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[148]) );
smfulladder dfa92 (.DATA_A (LATCHED_PP[146]), .DATA_B (LATCHED_PP[147]), .DATA_C (LATCHED_PP[148]), .SAVE (INT_SUM[142]), .CARRY (INT_CARRY[113]) );
smffa dla192 (.D(SUMMAND[149]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[149]) );
smffa dla193 (.D(SUMMAND[150]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[150]) );
smffa dla194 (.D(SUMMAND[151]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[151]) );
smfulladder dfa93 (.DATA_A (LATCHED_PP[149]), .DATA_B (LATCHED_PP[150]), .DATA_C (LATCHED_PP[151]), .SAVE (INT_SUM[143]), .CARRY (INT_CARRY[114]) );
smffa dla195 (.D(SUMMAND[152]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[152]) );
smffa dla196 (.D(SUMMAND[153]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[153]) );
smffa dla197 (.D(SUMMAND[154]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[154]) );
smfulladder dfa94 (.DATA_A (LATCHED_PP[152]), .DATA_B (LATCHED_PP[153]), .DATA_C (LATCHED_PP[154]), .SAVE (INT_SUM[144]), .CARRY (INT_CARRY[115]) );
smffa dla198 (.D(SUMMAND[155]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[155]) );
assign INT_SUM[145] = LATCHED_PP[155];
smfulladder dfa95 (.DATA_A (INT_SUM[141]), .DATA_B (INT_SUM[142]), .DATA_C (INT_SUM[143]), .SAVE (INT_SUM[146]), .CARRY (INT_CARRY[116]) );
smfulladder dfa96 (.DATA_A (INT_SUM[144]), .DATA_B (INT_SUM[145]), .DATA_C (INT_CARRY[102]), .SAVE (INT_SUM[147]), .CARRY (INT_CARRY[117]) );
smhalfadder dha20 (.DATA_A (INT_CARRY[103]), .DATA_B (INT_CARRY[104]), .SAVE (INT_SUM[148]), .CARRY (INT_CARRY[118]) );
smfulladder dfa97 (.DATA_A (INT_SUM[146]), .DATA_B (INT_SUM[147]), .DATA_C (INT_SUM[148]), .SAVE (INT_SUM[149]), .CARRY (INT_CARRY[119]) );
smfulladder dfa98 (.DATA_A (INT_CARRY[105]), .DATA_B (INT_CARRY[106]), .DATA_C (INT_CARRY[107]), .SAVE (INT_SUM[150]), .CARRY (INT_CARRY[120]) );
smfulladder dfa99 (.DATA_A (INT_SUM[149]), .DATA_B (INT_SUM[150]), .DATA_C (INT_CARRY[108]), .SAVE (INT_SUM[151]), .CARRY (INT_CARRY[121]) );
assign INT_SUM[152] = INT_CARRY[109];
smfulladder dfa100 (.DATA_A (INT_SUM[151]), .DATA_B (INT_SUM[152]), .DATA_C (INT_CARRY[110]), .SAVE (INT_SUM[153]), .CARRY (INT_CARRY[111]) );
smffb dla199 (.D(INT_SUM[153]), .clk(clk), .en_d2(en_d2), .Q(SUM[22]) );
smffb dla200 (.D(INT_CARRY[111]), .clk(clk), .en_d2(en_d2), .Q(CARRY[22]) );
smffa dla201 (.D(SUMMAND[156]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[156]) );
smffa dla202 (.D(SUMMAND[157]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[157]) );
smffa dla203 (.D(SUMMAND[158]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[158]) );
smfulladder dfa101 (.DATA_A (LATCHED_PP[156]), .DATA_B (LATCHED_PP[157]), .DATA_C (LATCHED_PP[158]), .SAVE (INT_SUM[154]), .CARRY (INT_CARRY[123]) );
smffa dla204 (.D(SUMMAND[159]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[159]) );
smffa dla205 (.D(SUMMAND[160]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[160]) );
smffa dla206 (.D(SUMMAND[161]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[161]) );
smfulladder dfa102 (.DATA_A (LATCHED_PP[159]), .DATA_B (LATCHED_PP[160]), .DATA_C (LATCHED_PP[161]), .SAVE (INT_SUM[155]), .CARRY (INT_CARRY[124]) );
smffa dla207 (.D(SUMMAND[162]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[162]) );
smffa dla208 (.D(SUMMAND[163]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[163]) );
smffa dla209 (.D(SUMMAND[164]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[164]) );
smfulladder dfa103 (.DATA_A (LATCHED_PP[162]), .DATA_B (LATCHED_PP[163]), .DATA_C (LATCHED_PP[164]), .SAVE (INT_SUM[156]), .CARRY (INT_CARRY[125]) );
smffa dla210 (.D(SUMMAND[165]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[165]) );
smffa dla211 (.D(SUMMAND[166]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[166]) );
smffa dla212 (.D(SUMMAND[167]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[167]) );
smfulladder dfa104 (.DATA_A (LATCHED_PP[165]), .DATA_B (LATCHED_PP[166]), .DATA_C (LATCHED_PP[167]), .SAVE (INT_SUM[157]), .CARRY (INT_CARRY[126]) );
smfulladder dfa105 (.DATA_A (INT_SUM[154]), .DATA_B (INT_SUM[155]), .DATA_C (INT_SUM[156]), .SAVE (INT_SUM[158]), .CARRY (INT_CARRY[127]) );
smfulladder dfa106 (.DATA_A (INT_SUM[157]), .DATA_B (INT_CARRY[112]), .DATA_C (INT_CARRY[113]), .SAVE (INT_SUM[159]), .CARRY (INT_CARRY[128]) );
smhalfadder dha21 (.DATA_A (INT_CARRY[114]), .DATA_B (INT_CARRY[115]), .SAVE (INT_SUM[160]), .CARRY (INT_CARRY[129]) );
smfulladder dfa107 (.DATA_A (INT_SUM[158]), .DATA_B (INT_SUM[159]), .DATA_C (INT_SUM[160]), .SAVE (INT_SUM[161]), .CARRY (INT_CARRY[130]) );
smfulladder dfa108 (.DATA_A (INT_CARRY[116]), .DATA_B (INT_CARRY[117]), .DATA_C (INT_CARRY[118]), .SAVE (INT_SUM[162]), .CARRY (INT_CARRY[131]) );
smfulladder dfa109 (.DATA_A (INT_SUM[161]), .DATA_B (INT_SUM[162]), .DATA_C (INT_CARRY[119]), .SAVE (INT_SUM[163]), .CARRY (INT_CARRY[132]) );
assign INT_SUM[164] = INT_CARRY[120];
smfulladder dfa110 (.DATA_A (INT_SUM[163]), .DATA_B (INT_SUM[164]), .DATA_C (INT_CARRY[121]), .SAVE (INT_SUM[165]), .CARRY (INT_CARRY[122]) );
smffb dla213 (.D(INT_SUM[165]), .clk(clk), .en_d2(en_d2), .Q(SUM[23]) );
smffb dla214 (.D(INT_CARRY[122]), .clk(clk), .en_d2(en_d2), .Q(CARRY[23]) );
smffa dla215 (.D(SUMMAND[168]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[168]) );
smffa dla216 (.D(SUMMAND[169]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[169]) );
smffa dla217 (.D(SUMMAND[170]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[170]) );
smfulladder dfa111 (.DATA_A (LATCHED_PP[168]), .DATA_B (LATCHED_PP[169]), .DATA_C (LATCHED_PP[170]), .SAVE (INT_SUM[166]), .CARRY (INT_CARRY[134]) );
smffa dla218 (.D(SUMMAND[171]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[171]) );
smffa dla219 (.D(SUMMAND[172]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[172]) );
smffa dla220 (.D(SUMMAND[173]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[173]) );
smfulladder dfa112 (.DATA_A (LATCHED_PP[171]), .DATA_B (LATCHED_PP[172]), .DATA_C (LATCHED_PP[173]), .SAVE (INT_SUM[167]), .CARRY (INT_CARRY[135]) );
smffa dla221 (.D(SUMMAND[174]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[174]) );
smffa dla222 (.D(SUMMAND[175]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[175]) );
smffa dla223 (.D(SUMMAND[176]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[176]) );
smfulladder dfa113 (.DATA_A (LATCHED_PP[174]), .DATA_B (LATCHED_PP[175]), .DATA_C (LATCHED_PP[176]), .SAVE (INT_SUM[168]), .CARRY (INT_CARRY[136]) );
smffa dla224 (.D(SUMMAND[177]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[177]) );
smffa dla225 (.D(SUMMAND[178]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[178]) );
smffa dla226 (.D(SUMMAND[179]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[179]) );
smfulladder dfa114 (.DATA_A (LATCHED_PP[177]), .DATA_B (LATCHED_PP[178]), .DATA_C (LATCHED_PP[179]), .SAVE (INT_SUM[169]), .CARRY (INT_CARRY[137]) );
smffa dla227 (.D(SUMMAND[180]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[180]) );
smffa dla228 (.D(SUMMAND[181]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[181]) );
smhalfadder dha22 (.DATA_A (LATCHED_PP[180]), .DATA_B (LATCHED_PP[181]), .SAVE (INT_SUM[170]), .CARRY (INT_CARRY[138]) );
smfulladder dfa115 (.DATA_A (INT_SUM[166]), .DATA_B (INT_SUM[167]), .DATA_C (INT_SUM[168]), .SAVE (INT_SUM[171]), .CARRY (INT_CARRY[139]) );
smfulladder dfa116 (.DATA_A (INT_SUM[169]), .DATA_B (INT_SUM[170]), .DATA_C (INT_CARRY[123]), .SAVE (INT_SUM[172]), .CARRY (INT_CARRY[140]) );
smfulladder dfa117 (.DATA_A (INT_CARRY[124]), .DATA_B (INT_CARRY[125]), .DATA_C (INT_CARRY[126]), .SAVE (INT_SUM[173]), .CARRY (INT_CARRY[141]) );
smfulladder dfa118 (.DATA_A (INT_SUM[171]), .DATA_B (INT_SUM[172]), .DATA_C (INT_SUM[173]), .SAVE (INT_SUM[174]), .CARRY (INT_CARRY[142]) );
smfulladder dfa119 (.DATA_A (INT_CARRY[127]), .DATA_B (INT_CARRY[128]), .DATA_C (INT_CARRY[129]), .SAVE (INT_SUM[175]), .CARRY (INT_CARRY[143]) );
smfulladder dfa120 (.DATA_A (INT_SUM[174]), .DATA_B (INT_SUM[175]), .DATA_C (INT_CARRY[130]), .SAVE (INT_SUM[176]), .CARRY (INT_CARRY[144]) );
assign INT_SUM[177] = INT_CARRY[131];
smfulladder dfa121 (.DATA_A (INT_SUM[176]), .DATA_B (INT_SUM[177]), .DATA_C (INT_CARRY[132]), .SAVE (INT_SUM[178]), .CARRY (INT_CARRY[133]) );
smffb dla229 (.D(INT_SUM[178]), .clk(clk), .en_d2(en_d2), .Q(SUM[24]) );
smffb dla230 (.D(INT_CARRY[133]), .clk(clk), .en_d2(en_d2), .Q(CARRY[24]) );
smffa dla231 (.D(SUMMAND[182]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[182]) );
smffa dla232 (.D(SUMMAND[183]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[183]) );
smffa dla233 (.D(SUMMAND[184]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[184]) );
smfulladder dfa122 (.DATA_A (LATCHED_PP[182]), .DATA_B (LATCHED_PP[183]), .DATA_C (LATCHED_PP[184]), .SAVE (INT_SUM[179]), .CARRY (INT_CARRY[146]) );
smffa dla234 (.D(SUMMAND[185]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[185]) );
smffa dla235 (.D(SUMMAND[186]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[186]) );
smffa dla236 (.D(SUMMAND[187]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[187]) );
smfulladder dfa123 (.DATA_A (LATCHED_PP[185]), .DATA_B (LATCHED_PP[186]), .DATA_C (LATCHED_PP[187]), .SAVE (INT_SUM[180]), .CARRY (INT_CARRY[147]) );
smffa dla237 (.D(SUMMAND[188]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[188]) );
smffa dla238 (.D(SUMMAND[189]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[189]) );
smffa dla239 (.D(SUMMAND[190]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[190]) );
smfulladder dfa124 (.DATA_A (LATCHED_PP[188]), .DATA_B (LATCHED_PP[189]), .DATA_C (LATCHED_PP[190]), .SAVE (INT_SUM[181]), .CARRY (INT_CARRY[148]) );
smffa dla240 (.D(SUMMAND[191]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[191]) );
smffa dla241 (.D(SUMMAND[192]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[192]) );
smffa dla242 (.D(SUMMAND[193]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[193]) );
smfulladder dfa125 (.DATA_A (LATCHED_PP[191]), .DATA_B (LATCHED_PP[192]), .DATA_C (LATCHED_PP[193]), .SAVE (INT_SUM[182]), .CARRY (INT_CARRY[149]) );
smffa dla243 (.D(SUMMAND[194]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[194]) );
assign INT_SUM[183] = LATCHED_PP[194];
smfulladder dfa126 (.DATA_A (INT_SUM[179]), .DATA_B (INT_SUM[180]), .DATA_C (INT_SUM[181]), .SAVE (INT_SUM[184]), .CARRY (INT_CARRY[150]) );
smfulladder dfa127 (.DATA_A (INT_SUM[182]), .DATA_B (INT_SUM[183]), .DATA_C (INT_CARRY[134]), .SAVE (INT_SUM[185]), .CARRY (INT_CARRY[151]) );
smfulladder dfa128 (.DATA_A (INT_CARRY[135]), .DATA_B (INT_CARRY[136]), .DATA_C (INT_CARRY[137]), .SAVE (INT_SUM[186]), .CARRY (INT_CARRY[152]) );
assign INT_SUM[187] = INT_CARRY[138];
smfulladder dfa129 (.DATA_A (INT_SUM[184]), .DATA_B (INT_SUM[185]), .DATA_C (INT_SUM[186]), .SAVE (INT_SUM[188]), .CARRY (INT_CARRY[153]) );
smfulladder dfa130 (.DATA_A (INT_SUM[187]), .DATA_B (INT_CARRY[139]), .DATA_C (INT_CARRY[140]), .SAVE (INT_SUM[189]), .CARRY (INT_CARRY[154]) );
assign INT_SUM[190] = INT_CARRY[141];
smfulladder dfa131 (.DATA_A (INT_SUM[188]), .DATA_B (INT_SUM[189]), .DATA_C (INT_SUM[190]), .SAVE (INT_SUM[191]), .CARRY (INT_CARRY[155]) );
smhalfadder dha23 (.DATA_A (INT_CARRY[142]), .DATA_B (INT_CARRY[143]), .SAVE (INT_SUM[192]), .CARRY (INT_CARRY[156]) );
smfulladder dfa132 (.DATA_A (INT_SUM[191]), .DATA_B (INT_SUM[192]), .DATA_C (INT_CARRY[144]), .SAVE (INT_SUM[193]), .CARRY (INT_CARRY[145]) );
smffb dla244 (.D(INT_SUM[193]), .clk(clk), .en_d2(en_d2), .Q(SUM[25]) );
smffb dla245 (.D(INT_CARRY[145]), .clk(clk), .en_d2(en_d2), .Q(CARRY[25]) );
smffa dla246 (.D(SUMMAND[195]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[195]) );
smffa dla247 (.D(SUMMAND[196]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[196]) );
smffa dla248 (.D(SUMMAND[197]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[197]) );
smfulladder dfa133 (.DATA_A (LATCHED_PP[195]), .DATA_B (LATCHED_PP[196]), .DATA_C (LATCHED_PP[197]), .SAVE (INT_SUM[194]), .CARRY (INT_CARRY[158]) );
smffa dla249 (.D(SUMMAND[198]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[198]) );
smffa dla250 (.D(SUMMAND[199]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[199]) );
smffa dla251 (.D(SUMMAND[200]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[200]) );
smfulladder dfa134 (.DATA_A (LATCHED_PP[198]), .DATA_B (LATCHED_PP[199]), .DATA_C (LATCHED_PP[200]), .SAVE (INT_SUM[195]), .CARRY (INT_CARRY[159]) );
smffa dla252 (.D(SUMMAND[201]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[201]) );
smffa dla253 (.D(SUMMAND[202]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[202]) );
smffa dla254 (.D(SUMMAND[203]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[203]) );
smfulladder dfa135 (.DATA_A (LATCHED_PP[201]), .DATA_B (LATCHED_PP[202]), .DATA_C (LATCHED_PP[203]), .SAVE (INT_SUM[196]), .CARRY (INT_CARRY[160]) );
smffa dla255 (.D(SUMMAND[204]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[204]) );
smffa dla256 (.D(SUMMAND[205]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[205]) );
smffa dla257 (.D(SUMMAND[206]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[206]) );
smfulladder dfa136 (.DATA_A (LATCHED_PP[204]), .DATA_B (LATCHED_PP[205]), .DATA_C (LATCHED_PP[206]), .SAVE (INT_SUM[197]), .CARRY (INT_CARRY[161]) );
smffa dla258 (.D(SUMMAND[207]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[207]) );
smffa dla259 (.D(SUMMAND[208]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[208]) );
smffa dla260 (.D(SUMMAND[209]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[209]) );
smfulladder dfa137 (.DATA_A (LATCHED_PP[207]), .DATA_B (LATCHED_PP[208]), .DATA_C (LATCHED_PP[209]), .SAVE (INT_SUM[198]), .CARRY (INT_CARRY[162]) );
smfulladder dfa138 (.DATA_A (INT_SUM[194]), .DATA_B (INT_SUM[195]), .DATA_C (INT_SUM[196]), .SAVE (INT_SUM[199]), .CARRY (INT_CARRY[163]) );
smfulladder dfa139 (.DATA_A (INT_SUM[197]), .DATA_B (INT_SUM[198]), .DATA_C (INT_CARRY[146]), .SAVE (INT_SUM[200]), .CARRY (INT_CARRY[164]) );
smfulladder dfa140 (.DATA_A (INT_CARRY[147]), .DATA_B (INT_CARRY[148]), .DATA_C (INT_CARRY[149]), .SAVE (INT_SUM[201]), .CARRY (INT_CARRY[165]) );
smfulladder dfa141 (.DATA_A (INT_SUM[199]), .DATA_B (INT_SUM[200]), .DATA_C (INT_SUM[201]), .SAVE (INT_SUM[202]), .CARRY (INT_CARRY[166]) );
smfulladder dfa142 (.DATA_A (INT_CARRY[150]), .DATA_B (INT_CARRY[151]), .DATA_C (INT_CARRY[152]), .SAVE (INT_SUM[203]), .CARRY (INT_CARRY[167]) );
smfulladder dfa143 (.DATA_A (INT_SUM[202]), .DATA_B (INT_SUM[203]), .DATA_C (INT_CARRY[153]), .SAVE (INT_SUM[204]), .CARRY (INT_CARRY[168]) );
assign INT_SUM[205] = INT_CARRY[154];
smfulladder dfa144 (.DATA_A (INT_SUM[204]), .DATA_B (INT_SUM[205]), .DATA_C (INT_CARRY[155]), .SAVE (INT_SUM[206]), .CARRY (INT_CARRY[169]) );
assign INT_SUM[207] = INT_CARRY[156];
smhalfadder dha24 (.DATA_A (INT_SUM[206]), .DATA_B (INT_SUM[207]), .SAVE (INT_SUM[208]), .CARRY (INT_CARRY[157]) );
smffb dla261 (.D(INT_SUM[208]), .clk(clk), .en_d2(en_d2), .Q(SUM[26]) );
smffb dla262 (.D(INT_CARRY[157]), .clk(clk), .en_d2(en_d2), .Q(CARRY[26]) );
smffa dla263 (.D(SUMMAND[210]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[210]) );
smffa dla264 (.D(SUMMAND[211]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[211]) );
smffa dla265 (.D(SUMMAND[212]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[212]) );
smfulladder dfa145 (.DATA_A (LATCHED_PP[210]), .DATA_B (LATCHED_PP[211]), .DATA_C (LATCHED_PP[212]), .SAVE (INT_SUM[209]), .CARRY (INT_CARRY[171]) );
smffa dla266 (.D(SUMMAND[213]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[213]) );
smffa dla267 (.D(SUMMAND[214]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[214]) );
smffa dla268 (.D(SUMMAND[215]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[215]) );
smfulladder dfa146 (.DATA_A (LATCHED_PP[213]), .DATA_B (LATCHED_PP[214]), .DATA_C (LATCHED_PP[215]), .SAVE (INT_SUM[210]), .CARRY (INT_CARRY[172]) );
smffa dla269 (.D(SUMMAND[216]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[216]) );
smffa dla270 (.D(SUMMAND[217]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[217]) );
smffa dla271 (.D(SUMMAND[218]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[218]) );
smfulladder dfa147 (.DATA_A (LATCHED_PP[216]), .DATA_B (LATCHED_PP[217]), .DATA_C (LATCHED_PP[218]), .SAVE (INT_SUM[211]), .CARRY (INT_CARRY[173]) );
smffa dla272 (.D(SUMMAND[219]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[219]) );
smffa dla273 (.D(SUMMAND[220]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[220]) );
smffa dla274 (.D(SUMMAND[221]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[221]) );
smfulladder dfa148 (.DATA_A (LATCHED_PP[219]), .DATA_B (LATCHED_PP[220]), .DATA_C (LATCHED_PP[221]), .SAVE (INT_SUM[212]), .CARRY (INT_CARRY[174]) );
smffa dla275 (.D(SUMMAND[222]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[222]) );
smffa dla276 (.D(SUMMAND[223]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[223]) );
smhalfadder dha25 (.DATA_A (LATCHED_PP[222]), .DATA_B (LATCHED_PP[223]), .SAVE (INT_SUM[213]), .CARRY (INT_CARRY[175]) );
smfulladder dfa149 (.DATA_A (INT_SUM[209]), .DATA_B (INT_SUM[210]), .DATA_C (INT_SUM[211]), .SAVE (INT_SUM[214]), .CARRY (INT_CARRY[176]) );
smfulladder dfa150 (.DATA_A (INT_SUM[212]), .DATA_B (INT_SUM[213]), .DATA_C (INT_CARRY[158]), .SAVE (INT_SUM[215]), .CARRY (INT_CARRY[177]) );
smfulladder dfa151 (.DATA_A (INT_CARRY[159]), .DATA_B (INT_CARRY[160]), .DATA_C (INT_CARRY[161]), .SAVE (INT_SUM[216]), .CARRY (INT_CARRY[178]) );
assign INT_SUM[217] = INT_CARRY[162];
smfulladder dfa152 (.DATA_A (INT_SUM[214]), .DATA_B (INT_SUM[215]), .DATA_C (INT_SUM[216]), .SAVE (INT_SUM[218]), .CARRY (INT_CARRY[179]) );
smfulladder dfa153 (.DATA_A (INT_SUM[217]), .DATA_B (INT_CARRY[163]), .DATA_C (INT_CARRY[164]), .SAVE (INT_SUM[219]), .CARRY (INT_CARRY[180]) );
assign INT_SUM[220] = INT_CARRY[165];
smfulladder dfa154 (.DATA_A (INT_SUM[218]), .DATA_B (INT_SUM[219]), .DATA_C (INT_SUM[220]), .SAVE (INT_SUM[221]), .CARRY (INT_CARRY[181]) );
assign INT_SUM[222] = INT_CARRY[166];
assign INT_SUM[223] = INT_CARRY[167];
smfulladder dfa155 (.DATA_A (INT_SUM[221]), .DATA_B (INT_SUM[222]), .DATA_C (INT_SUM[223]), .SAVE (INT_SUM[224]), .CARRY (INT_CARRY[182]) );
assign INT_SUM[225] = INT_CARRY[168];
smfulladder dfa156 (.DATA_A (INT_SUM[224]), .DATA_B (INT_SUM[225]), .DATA_C (INT_CARRY[169]), .SAVE (INT_SUM[226]), .CARRY (INT_CARRY[170]) );
smffb dla277 (.D(INT_SUM[226]), .clk(clk), .en_d2(en_d2), .Q(SUM[27]) );
smffb dla278 (.D(INT_CARRY[170]), .clk(clk), .en_d2(en_d2), .Q(CARRY[27]) );
smffa dla279 (.D(SUMMAND[224]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[224]) );
smffa dla280 (.D(SUMMAND[225]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[225]) );
smffa dla281 (.D(SUMMAND[226]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[226]) );
smfulladder dfa157 (.DATA_A (LATCHED_PP[224]), .DATA_B (LATCHED_PP[225]), .DATA_C (LATCHED_PP[226]), .SAVE (INT_SUM[227]), .CARRY (INT_CARRY[184]) );
smffa dla282 (.D(SUMMAND[227]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[227]) );
smffa dla283 (.D(SUMMAND[228]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[228]) );
smffa dla284 (.D(SUMMAND[229]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[229]) );
smfulladder dfa158 (.DATA_A (LATCHED_PP[227]), .DATA_B (LATCHED_PP[228]), .DATA_C (LATCHED_PP[229]), .SAVE (INT_SUM[228]), .CARRY (INT_CARRY[185]) );
smffa dla285 (.D(SUMMAND[230]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[230]) );
smffa dla286 (.D(SUMMAND[231]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[231]) );
smffa dla287 (.D(SUMMAND[232]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[232]) );
smfulladder dfa159 (.DATA_A (LATCHED_PP[230]), .DATA_B (LATCHED_PP[231]), .DATA_C (LATCHED_PP[232]), .SAVE (INT_SUM[229]), .CARRY (INT_CARRY[186]) );
smffa dla288 (.D(SUMMAND[233]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[233]) );
smffa dla289 (.D(SUMMAND[234]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[234]) );
smffa dla290 (.D(SUMMAND[235]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[235]) );
smfulladder dfa160 (.DATA_A (LATCHED_PP[233]), .DATA_B (LATCHED_PP[234]), .DATA_C (LATCHED_PP[235]), .SAVE (INT_SUM[230]), .CARRY (INT_CARRY[187]) );
smffa dla291 (.D(SUMMAND[236]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[236]) );
smffa dla292 (.D(SUMMAND[237]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[237]) );
smffa dla293 (.D(SUMMAND[238]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[238]) );
smfulladder dfa161 (.DATA_A (LATCHED_PP[236]), .DATA_B (LATCHED_PP[237]), .DATA_C (LATCHED_PP[238]), .SAVE (INT_SUM[231]), .CARRY (INT_CARRY[188]) );
smffa dla294 (.D(SUMMAND[239]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[239]) );
assign INT_SUM[232] = LATCHED_PP[239];
smfulladder dfa162 (.DATA_A (INT_SUM[227]), .DATA_B (INT_SUM[228]), .DATA_C (INT_SUM[229]), .SAVE (INT_SUM[233]), .CARRY (INT_CARRY[189]) );
smfulladder dfa163 (.DATA_A (INT_SUM[230]), .DATA_B (INT_SUM[231]), .DATA_C (INT_SUM[232]), .SAVE (INT_SUM[234]), .CARRY (INT_CARRY[190]) );
smfulladder dfa164 (.DATA_A (INT_CARRY[171]), .DATA_B (INT_CARRY[172]), .DATA_C (INT_CARRY[173]), .SAVE (INT_SUM[235]), .CARRY (INT_CARRY[191]) );
assign INT_SUM[236] = INT_CARRY[174];
assign INT_SUM[237] = INT_CARRY[175];
smfulladder dfa165 (.DATA_A (INT_SUM[233]), .DATA_B (INT_SUM[234]), .DATA_C (INT_SUM[235]), .SAVE (INT_SUM[238]), .CARRY (INT_CARRY[192]) );
smfulladder dfa166 (.DATA_A (INT_SUM[236]), .DATA_B (INT_SUM[237]), .DATA_C (INT_CARRY[176]), .SAVE (INT_SUM[239]), .CARRY (INT_CARRY[193]) );
assign INT_SUM[240] = INT_CARRY[177];
assign INT_SUM[241] = INT_CARRY[178];
smfulladder dfa167 (.DATA_A (INT_SUM[238]), .DATA_B (INT_SUM[239]), .DATA_C (INT_SUM[240]), .SAVE (INT_SUM[242]), .CARRY (INT_CARRY[194]) );
smfulladder dfa168 (.DATA_A (INT_SUM[241]), .DATA_B (INT_CARRY[179]), .DATA_C (INT_CARRY[180]), .SAVE (INT_SUM[243]), .CARRY (INT_CARRY[195]) );
smfulladder dfa169 (.DATA_A (INT_SUM[242]), .DATA_B (INT_SUM[243]), .DATA_C (INT_CARRY[181]), .SAVE (INT_SUM[244]), .CARRY (INT_CARRY[196]) );
smhalfadder dha26 (.DATA_A (INT_SUM[244]), .DATA_B (INT_CARRY[182]), .SAVE (INT_SUM[245]), .CARRY (INT_CARRY[183]) );
smffb dla295 (.D(INT_SUM[245]), .clk(clk), .en_d2(en_d2), .Q(SUM[28]) );
smffb dla296 (.D(INT_CARRY[183]), .clk(clk), .en_d2(en_d2), .Q(CARRY[28]) );
smffa dla297 (.D(SUMMAND[240]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[240]) );
smffa dla298 (.D(SUMMAND[241]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[241]) );
smffa dla299 (.D(SUMMAND[242]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[242]) );
smfulladder dfa170 (.DATA_A (LATCHED_PP[240]), .DATA_B (LATCHED_PP[241]), .DATA_C (LATCHED_PP[242]), .SAVE (INT_SUM[246]), .CARRY (INT_CARRY[198]) );
smffa dla300 (.D(SUMMAND[243]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[243]) );
smffa dla301 (.D(SUMMAND[244]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[244]) );
smffa dla302 (.D(SUMMAND[245]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[245]) );
smfulladder dfa171 (.DATA_A (LATCHED_PP[243]), .DATA_B (LATCHED_PP[244]), .DATA_C (LATCHED_PP[245]), .SAVE (INT_SUM[247]), .CARRY (INT_CARRY[199]) );
smffa dla303 (.D(SUMMAND[246]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[246]) );
smffa dla304 (.D(SUMMAND[247]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[247]) );
smffa dla305 (.D(SUMMAND[248]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[248]) );
smfulladder dfa172 (.DATA_A (LATCHED_PP[246]), .DATA_B (LATCHED_PP[247]), .DATA_C (LATCHED_PP[248]), .SAVE (INT_SUM[248]), .CARRY (INT_CARRY[200]) );
smffa dla306 (.D(SUMMAND[249]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[249]) );
smffa dla307 (.D(SUMMAND[250]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[250]) );
smffa dla308 (.D(SUMMAND[251]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[251]) );
smfulladder dfa173 (.DATA_A (LATCHED_PP[249]), .DATA_B (LATCHED_PP[250]), .DATA_C (LATCHED_PP[251]), .SAVE (INT_SUM[249]), .CARRY (INT_CARRY[201]) );
smffa dla309 (.D(SUMMAND[252]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[252]) );
smffa dla310 (.D(SUMMAND[253]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[253]) );
smffa dla311 (.D(SUMMAND[254]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[254]) );
smfulladder dfa174 (.DATA_A (LATCHED_PP[252]), .DATA_B (LATCHED_PP[253]), .DATA_C (LATCHED_PP[254]), .SAVE (INT_SUM[250]), .CARRY (INT_CARRY[202]) );
smfulladder dfa175 (.DATA_A (INT_SUM[246]), .DATA_B (INT_SUM[247]), .DATA_C (INT_SUM[248]), .SAVE (INT_SUM[251]), .CARRY (INT_CARRY[203]) );
smfulladder dfa176 (.DATA_A (INT_SUM[249]), .DATA_B (INT_SUM[250]), .DATA_C (INT_CARRY[184]), .SAVE (INT_SUM[252]), .CARRY (INT_CARRY[204]) );
smfulladder dfa177 (.DATA_A (INT_CARRY[185]), .DATA_B (INT_CARRY[186]), .DATA_C (INT_CARRY[187]), .SAVE (INT_SUM[253]), .CARRY (INT_CARRY[205]) );
assign INT_SUM[254] = INT_CARRY[188];
smfulladder dfa178 (.DATA_A (INT_SUM[251]), .DATA_B (INT_SUM[252]), .DATA_C (INT_SUM[253]), .SAVE (INT_SUM[255]), .CARRY (INT_CARRY[206]) );
smfulladder dfa179 (.DATA_A (INT_SUM[254]), .DATA_B (INT_CARRY[189]), .DATA_C (INT_CARRY[190]), .SAVE (INT_SUM[256]), .CARRY (INT_CARRY[207]) );
assign INT_SUM[257] = INT_CARRY[191];
smfulladder dfa180 (.DATA_A (INT_SUM[255]), .DATA_B (INT_SUM[256]), .DATA_C (INT_SUM[257]), .SAVE (INT_SUM[258]), .CARRY (INT_CARRY[208]) );
smhalfadder dha27 (.DATA_A (INT_CARRY[192]), .DATA_B (INT_CARRY[193]), .SAVE (INT_SUM[259]), .CARRY (INT_CARRY[209]) );
smfulladder dfa181 (.DATA_A (INT_SUM[258]), .DATA_B (INT_SUM[259]), .DATA_C (INT_CARRY[194]), .SAVE (INT_SUM[260]), .CARRY (INT_CARRY[210]) );
assign INT_SUM[261] = INT_CARRY[195];
smfulladder dfa182 (.DATA_A (INT_SUM[260]), .DATA_B (INT_SUM[261]), .DATA_C (INT_CARRY[196]), .SAVE (INT_SUM[262]), .CARRY (INT_CARRY[197]) );
smffb dla312 (.D(INT_SUM[262]), .clk(clk), .en_d2(en_d2), .Q(SUM[29]) );
smffb dla313 (.D(INT_CARRY[197]), .clk(clk), .en_d2(en_d2), .Q(CARRY[29]) );
smffa dla314 (.D(SUMMAND[255]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[255]) );
smffa dla315 (.D(SUMMAND[256]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[256]) );
smffa dla316 (.D(SUMMAND[257]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[257]) );
smfulladder dfa183 (.DATA_A (LATCHED_PP[255]), .DATA_B (LATCHED_PP[256]), .DATA_C (LATCHED_PP[257]), .SAVE (INT_SUM[263]), .CARRY (INT_CARRY[212]) );
smffa dla317 (.D(SUMMAND[258]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[258]) );
smffa dla318 (.D(SUMMAND[259]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[259]) );
smffa dla319 (.D(SUMMAND[260]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[260]) );
smfulladder dfa184 (.DATA_A (LATCHED_PP[258]), .DATA_B (LATCHED_PP[259]), .DATA_C (LATCHED_PP[260]), .SAVE (INT_SUM[264]), .CARRY (INT_CARRY[213]) );
smffa dla320 (.D(SUMMAND[261]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[261]) );
smffa dla321 (.D(SUMMAND[262]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[262]) );
smffa dla322 (.D(SUMMAND[263]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[263]) );
smfulladder dfa185 (.DATA_A (LATCHED_PP[261]), .DATA_B (LATCHED_PP[262]), .DATA_C (LATCHED_PP[263]), .SAVE (INT_SUM[265]), .CARRY (INT_CARRY[214]) );
smffa dla323 (.D(SUMMAND[264]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[264]) );
smffa dla324 (.D(SUMMAND[265]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[265]) );
smffa dla325 (.D(SUMMAND[266]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[266]) );
smfulladder dfa186 (.DATA_A (LATCHED_PP[264]), .DATA_B (LATCHED_PP[265]), .DATA_C (LATCHED_PP[266]), .SAVE (INT_SUM[266]), .CARRY (INT_CARRY[215]) );
smffa dla326 (.D(SUMMAND[267]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[267]) );
smffa dla327 (.D(SUMMAND[268]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[268]) );
smffa dla328 (.D(SUMMAND[269]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[269]) );
smfulladder dfa187 (.DATA_A (LATCHED_PP[267]), .DATA_B (LATCHED_PP[268]), .DATA_C (LATCHED_PP[269]), .SAVE (INT_SUM[267]), .CARRY (INT_CARRY[216]) );
smffa dla329 (.D(SUMMAND[270]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[270]) );
assign INT_SUM[268] = LATCHED_PP[270];
smffa dla330 (.D(SUMMAND[271]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[271]) );
assign INT_SUM[269] = LATCHED_PP[271];
smfulladder dfa188 (.DATA_A (INT_SUM[263]), .DATA_B (INT_SUM[264]), .DATA_C (INT_SUM[265]), .SAVE (INT_SUM[270]), .CARRY (INT_CARRY[217]) );
smfulladder dfa189 (.DATA_A (INT_SUM[266]), .DATA_B (INT_SUM[267]), .DATA_C (INT_SUM[268]), .SAVE (INT_SUM[271]), .CARRY (INT_CARRY[218]) );
smfulladder dfa190 (.DATA_A (INT_SUM[269]), .DATA_B (INT_CARRY[198]), .DATA_C (INT_CARRY[199]), .SAVE (INT_SUM[272]), .CARRY (INT_CARRY[219]) );
smfulladder dfa191 (.DATA_A (INT_CARRY[200]), .DATA_B (INT_CARRY[201]), .DATA_C (INT_CARRY[202]), .SAVE (INT_SUM[273]), .CARRY (INT_CARRY[220]) );
smfulladder dfa192 (.DATA_A (INT_SUM[270]), .DATA_B (INT_SUM[271]), .DATA_C (INT_SUM[272]), .SAVE (INT_SUM[274]), .CARRY (INT_CARRY[221]) );
smfulladder dfa193 (.DATA_A (INT_SUM[273]), .DATA_B (INT_CARRY[203]), .DATA_C (INT_CARRY[204]), .SAVE (INT_SUM[275]), .CARRY (INT_CARRY[222]) );
assign INT_SUM[276] = INT_CARRY[205];
smfulladder dfa194 (.DATA_A (INT_SUM[274]), .DATA_B (INT_SUM[275]), .DATA_C (INT_SUM[276]), .SAVE (INT_SUM[277]), .CARRY (INT_CARRY[223]) );
smhalfadder dha28 (.DATA_A (INT_CARRY[206]), .DATA_B (INT_CARRY[207]), .SAVE (INT_SUM[278]), .CARRY (INT_CARRY[224]) );
smfulladder dfa195 (.DATA_A (INT_SUM[277]), .DATA_B (INT_SUM[278]), .DATA_C (INT_CARRY[208]), .SAVE (INT_SUM[279]), .CARRY (INT_CARRY[225]) );
assign INT_SUM[280] = INT_CARRY[209];
smfulladder dfa196 (.DATA_A (INT_SUM[279]), .DATA_B (INT_SUM[280]), .DATA_C (INT_CARRY[210]), .SAVE (INT_SUM[281]), .CARRY (INT_CARRY[211]) );
smffb dla331 (.D(INT_SUM[281]), .clk(clk), .en_d2(en_d2), .Q(SUM[30]) );
smffb dla332 (.D(INT_CARRY[211]), .clk(clk), .en_d2(en_d2), .Q(CARRY[30]) );
smffa dla333 (.D(SUMMAND[272]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[272]) );
smffa dla334 (.D(SUMMAND[273]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[273]) );
smffa dla335 (.D(SUMMAND[274]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[274]) );
smfulladder dfa197 (.DATA_A (LATCHED_PP[272]), .DATA_B (LATCHED_PP[273]), .DATA_C (LATCHED_PP[274]), .SAVE (INT_SUM[282]), .CARRY (INT_CARRY[227]) );
smffa dla336 (.D(SUMMAND[275]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[275]) );
smffa dla337 (.D(SUMMAND[276]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[276]) );
smffa dla338 (.D(SUMMAND[277]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[277]) );
smfulladder dfa198 (.DATA_A (LATCHED_PP[275]), .DATA_B (LATCHED_PP[276]), .DATA_C (LATCHED_PP[277]), .SAVE (INT_SUM[283]), .CARRY (INT_CARRY[228]) );
smffa dla339 (.D(SUMMAND[278]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[278]) );
smffa dla340 (.D(SUMMAND[279]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[279]) );
smffa dla341 (.D(SUMMAND[280]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[280]) );
smfulladder dfa199 (.DATA_A (LATCHED_PP[278]), .DATA_B (LATCHED_PP[279]), .DATA_C (LATCHED_PP[280]), .SAVE (INT_SUM[284]), .CARRY (INT_CARRY[229]) );
smffa dla342 (.D(SUMMAND[281]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[281]) );
smffa dla343 (.D(SUMMAND[282]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[282]) );
smffa dla344 (.D(SUMMAND[283]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[283]) );
smfulladder dfa200 (.DATA_A (LATCHED_PP[281]), .DATA_B (LATCHED_PP[282]), .DATA_C (LATCHED_PP[283]), .SAVE (INT_SUM[285]), .CARRY (INT_CARRY[230]) );
smffa dla345 (.D(SUMMAND[284]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[284]) );
smffa dla346 (.D(SUMMAND[285]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[285]) );
smffa dla347 (.D(SUMMAND[286]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[286]) );
smfulladder dfa201 (.DATA_A (LATCHED_PP[284]), .DATA_B (LATCHED_PP[285]), .DATA_C (LATCHED_PP[286]), .SAVE (INT_SUM[286]), .CARRY (INT_CARRY[231]) );
smffa dla348 (.D(SUMMAND[287]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[287]) );
assign INT_SUM[287] = LATCHED_PP[287];
smfulladder dfa202 (.DATA_A (INT_SUM[282]), .DATA_B (INT_SUM[283]), .DATA_C (INT_SUM[284]), .SAVE (INT_SUM[288]), .CARRY (INT_CARRY[232]) );
smfulladder dfa203 (.DATA_A (INT_SUM[285]), .DATA_B (INT_SUM[286]), .DATA_C (INT_SUM[287]), .SAVE (INT_SUM[289]), .CARRY (INT_CARRY[233]) );
smfulladder dfa204 (.DATA_A (INT_CARRY[212]), .DATA_B (INT_CARRY[213]), .DATA_C (INT_CARRY[214]), .SAVE (INT_SUM[290]), .CARRY (INT_CARRY[234]) );
assign INT_SUM[291] = INT_CARRY[215];
assign INT_SUM[292] = INT_CARRY[216];
smfulladder dfa205 (.DATA_A (INT_SUM[288]), .DATA_B (INT_SUM[289]), .DATA_C (INT_SUM[290]), .SAVE (INT_SUM[293]), .CARRY (INT_CARRY[235]) );
smfulladder dfa206 (.DATA_A (INT_SUM[291]), .DATA_B (INT_SUM[292]), .DATA_C (INT_CARRY[217]), .SAVE (INT_SUM[294]), .CARRY (INT_CARRY[236]) );
smfulladder dfa207 (.DATA_A (INT_CARRY[218]), .DATA_B (INT_CARRY[219]), .DATA_C (INT_CARRY[220]), .SAVE (INT_SUM[295]), .CARRY (INT_CARRY[237]) );
smfulladder dfa208 (.DATA_A (INT_SUM[293]), .DATA_B (INT_SUM[294]), .DATA_C (INT_SUM[295]), .SAVE (INT_SUM[296]), .CARRY (INT_CARRY[238]) );
smhalfadder dha29 (.DATA_A (INT_CARRY[221]), .DATA_B (INT_CARRY[222]), .SAVE (INT_SUM[297]), .CARRY (INT_CARRY[239]) );
smfulladder dfa209 (.DATA_A (INT_SUM[296]), .DATA_B (INT_SUM[297]), .DATA_C (INT_CARRY[223]), .SAVE (INT_SUM[298]), .CARRY (INT_CARRY[240]) );
assign INT_SUM[299] = INT_CARRY[224];
smfulladder dfa210 (.DATA_A (INT_SUM[298]), .DATA_B (INT_SUM[299]), .DATA_C (INT_CARRY[225]), .SAVE (INT_SUM[300]), .CARRY (INT_CARRY[226]) );
smffb dla349 (.D(INT_SUM[300]), .clk(clk), .en_d2(en_d2), .Q(SUM[31]) );
smffb dla350 (.D(INT_CARRY[226]), .clk(clk), .en_d2(en_d2), .Q(CARRY[31]) );
smffa dla351 (.D(SUMMAND[288]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[288]) );
smffa dla352 (.D(SUMMAND[289]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[289]) );
smffa dla353 (.D(SUMMAND[290]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[290]) );
smfulladder dfa211 (.DATA_A (LATCHED_PP[288]), .DATA_B (LATCHED_PP[289]), .DATA_C (LATCHED_PP[290]), .SAVE (INT_SUM[301]), .CARRY (INT_CARRY[242]) );
smffa dla354 (.D(SUMMAND[291]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[291]) );
smffa dla355 (.D(SUMMAND[292]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[292]) );
smffa dla356 (.D(SUMMAND[293]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[293]) );
smfulladder dfa212 (.DATA_A (LATCHED_PP[291]), .DATA_B (LATCHED_PP[292]), .DATA_C (LATCHED_PP[293]), .SAVE (INT_SUM[302]), .CARRY (INT_CARRY[243]) );
smffa dla357 (.D(SUMMAND[294]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[294]) );
smffa dla358 (.D(SUMMAND[295]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[295]) );
smffa dla359 (.D(SUMMAND[296]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[296]) );
smfulladder dfa213 (.DATA_A (LATCHED_PP[294]), .DATA_B (LATCHED_PP[295]), .DATA_C (LATCHED_PP[296]), .SAVE (INT_SUM[303]), .CARRY (INT_CARRY[244]) );
smffa dla360 (.D(SUMMAND[297]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[297]) );
smffa dla361 (.D(SUMMAND[298]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[298]) );
smffa dla362 (.D(SUMMAND[299]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[299]) );
smfulladder dfa214 (.DATA_A (LATCHED_PP[297]), .DATA_B (LATCHED_PP[298]), .DATA_C (LATCHED_PP[299]), .SAVE (INT_SUM[304]), .CARRY (INT_CARRY[245]) );
smffa dla363 (.D(SUMMAND[300]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[300]) );
smffa dla364 (.D(SUMMAND[301]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[301]) );
smffa dla365 (.D(SUMMAND[302]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[302]) );
smfulladder dfa215 (.DATA_A (LATCHED_PP[300]), .DATA_B (LATCHED_PP[301]), .DATA_C (LATCHED_PP[302]), .SAVE (INT_SUM[305]), .CARRY (INT_CARRY[246]) );
smffa dla366 (.D(SUMMAND[303]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[303]) );
smffa dla367 (.D(SUMMAND[304]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[304]) );
smffa dla368 (.D(SUMMAND[305]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[305]) );
smfulladder dfa216 (.DATA_A (LATCHED_PP[303]), .DATA_B (LATCHED_PP[304]), .DATA_C (LATCHED_PP[305]), .SAVE (INT_SUM[306]), .CARRY (INT_CARRY[247]) );
smfulladder dfa217 (.DATA_A (INT_SUM[301]), .DATA_B (INT_SUM[302]), .DATA_C (INT_SUM[303]), .SAVE (INT_SUM[307]), .CARRY (INT_CARRY[248]) );
smfulladder dfa218 (.DATA_A (INT_SUM[304]), .DATA_B (INT_SUM[305]), .DATA_C (INT_SUM[306]), .SAVE (INT_SUM[308]), .CARRY (INT_CARRY[249]) );
smfulladder dfa219 (.DATA_A (INT_CARRY[227]), .DATA_B (INT_CARRY[228]), .DATA_C (INT_CARRY[229]), .SAVE (INT_SUM[309]), .CARRY (INT_CARRY[250]) );
smhalfadder dha30 (.DATA_A (INT_CARRY[230]), .DATA_B (INT_CARRY[231]), .SAVE (INT_SUM[310]), .CARRY (INT_CARRY[251]) );
smfulladder dfa220 (.DATA_A (INT_SUM[307]), .DATA_B (INT_SUM[308]), .DATA_C (INT_SUM[309]), .SAVE (INT_SUM[311]), .CARRY (INT_CARRY[252]) );
smfulladder dfa221 (.DATA_A (INT_SUM[310]), .DATA_B (INT_CARRY[232]), .DATA_C (INT_CARRY[233]), .SAVE (INT_SUM[312]), .CARRY (INT_CARRY[253]) );
assign INT_SUM[313] = INT_CARRY[234];
smfulladder dfa222 (.DATA_A (INT_SUM[311]), .DATA_B (INT_SUM[312]), .DATA_C (INT_SUM[313]), .SAVE (INT_SUM[314]), .CARRY (INT_CARRY[254]) );
smfulladder dfa223 (.DATA_A (INT_CARRY[235]), .DATA_B (INT_CARRY[236]), .DATA_C (INT_CARRY[237]), .SAVE (INT_SUM[315]), .CARRY (INT_CARRY[255]) );
smfulladder dfa224 (.DATA_A (INT_SUM[314]), .DATA_B (INT_SUM[315]), .DATA_C (INT_CARRY[238]), .SAVE (INT_SUM[316]), .CARRY (INT_CARRY[256]) );
assign INT_SUM[317] = INT_CARRY[239];
smfulladder dfa225 (.DATA_A (INT_SUM[316]), .DATA_B (INT_SUM[317]), .DATA_C (INT_CARRY[240]), .SAVE (INT_SUM[318]), .CARRY (INT_CARRY[241]) );
smffb dla369 (.D(INT_SUM[318]), .clk(clk), .en_d2(en_d2), .Q(SUM[32]) );
smffb dla370 (.D(INT_CARRY[241]), .clk(clk), .en_d2(en_d2), .Q(CARRY[32]) );
smffa dla371 (.D(SUMMAND[306]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[306]) );
smffa dla372 (.D(SUMMAND[307]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[307]) );
smffa dla373 (.D(SUMMAND[308]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[308]) );
smfulladder dfa226 (.DATA_A (LATCHED_PP[306]), .DATA_B (LATCHED_PP[307]), .DATA_C (LATCHED_PP[308]), .SAVE (INT_SUM[319]), .CARRY (INT_CARRY[258]) );
smffa dla374 (.D(SUMMAND[309]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[309]) );
smffa dla375 (.D(SUMMAND[310]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[310]) );
smffa dla376 (.D(SUMMAND[311]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[311]) );
smfulladder dfa227 (.DATA_A (LATCHED_PP[309]), .DATA_B (LATCHED_PP[310]), .DATA_C (LATCHED_PP[311]), .SAVE (INT_SUM[320]), .CARRY (INT_CARRY[259]) );
smffa dla377 (.D(SUMMAND[312]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[312]) );
smffa dla378 (.D(SUMMAND[313]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[313]) );
smffa dla379 (.D(SUMMAND[314]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[314]) );
smfulladder dfa228 (.DATA_A (LATCHED_PP[312]), .DATA_B (LATCHED_PP[313]), .DATA_C (LATCHED_PP[314]), .SAVE (INT_SUM[321]), .CARRY (INT_CARRY[260]) );
smffa dla380 (.D(SUMMAND[315]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[315]) );
smffa dla381 (.D(SUMMAND[316]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[316]) );
smffa dla382 (.D(SUMMAND[317]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[317]) );
smfulladder dfa229 (.DATA_A (LATCHED_PP[315]), .DATA_B (LATCHED_PP[316]), .DATA_C (LATCHED_PP[317]), .SAVE (INT_SUM[322]), .CARRY (INT_CARRY[261]) );
smffa dla383 (.D(SUMMAND[318]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[318]) );
smffa dla384 (.D(SUMMAND[319]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[319]) );
smffa dla385 (.D(SUMMAND[320]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[320]) );
smfulladder dfa230 (.DATA_A (LATCHED_PP[318]), .DATA_B (LATCHED_PP[319]), .DATA_C (LATCHED_PP[320]), .SAVE (INT_SUM[323]), .CARRY (INT_CARRY[262]) );
smffa dla386 (.D(SUMMAND[321]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[321]) );
assign INT_SUM[324] = LATCHED_PP[321];
smffa dla387 (.D(SUMMAND[322]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[322]) );
assign INT_SUM[325] = LATCHED_PP[322];
smfulladder dfa231 (.DATA_A (INT_SUM[319]), .DATA_B (INT_SUM[320]), .DATA_C (INT_SUM[321]), .SAVE (INT_SUM[326]), .CARRY (INT_CARRY[263]) );
smfulladder dfa232 (.DATA_A (INT_SUM[322]), .DATA_B (INT_SUM[323]), .DATA_C (INT_SUM[324]), .SAVE (INT_SUM[327]), .CARRY (INT_CARRY[264]) );
smfulladder dfa233 (.DATA_A (INT_SUM[325]), .DATA_B (INT_CARRY[242]), .DATA_C (INT_CARRY[243]), .SAVE (INT_SUM[328]), .CARRY (INT_CARRY[265]) );
smfulladder dfa234 (.DATA_A (INT_CARRY[244]), .DATA_B (INT_CARRY[245]), .DATA_C (INT_CARRY[246]), .SAVE (INT_SUM[329]), .CARRY (INT_CARRY[266]) );
assign INT_SUM[330] = INT_CARRY[247];
smfulladder dfa235 (.DATA_A (INT_SUM[326]), .DATA_B (INT_SUM[327]), .DATA_C (INT_SUM[328]), .SAVE (INT_SUM[331]), .CARRY (INT_CARRY[267]) );
smfulladder dfa236 (.DATA_A (INT_SUM[329]), .DATA_B (INT_SUM[330]), .DATA_C (INT_CARRY[248]), .SAVE (INT_SUM[332]), .CARRY (INT_CARRY[268]) );
smfulladder dfa237 (.DATA_A (INT_CARRY[249]), .DATA_B (INT_CARRY[250]), .DATA_C (INT_CARRY[251]), .SAVE (INT_SUM[333]), .CARRY (INT_CARRY[269]) );
smfulladder dfa238 (.DATA_A (INT_SUM[331]), .DATA_B (INT_SUM[332]), .DATA_C (INT_SUM[333]), .SAVE (INT_SUM[334]), .CARRY (INT_CARRY[270]) );
smhalfadder dha31 (.DATA_A (INT_CARRY[252]), .DATA_B (INT_CARRY[253]), .SAVE (INT_SUM[335]), .CARRY (INT_CARRY[271]) );
smfulladder dfa239 (.DATA_A (INT_SUM[334]), .DATA_B (INT_SUM[335]), .DATA_C (INT_CARRY[254]), .SAVE (INT_SUM[336]), .CARRY (INT_CARRY[272]) );
assign INT_SUM[337] = INT_CARRY[255];
smfulladder dfa240 (.DATA_A (INT_SUM[336]), .DATA_B (INT_SUM[337]), .DATA_C (INT_CARRY[256]), .SAVE (INT_SUM[338]), .CARRY (INT_CARRY[257]) );
smffb dla388 (.D(INT_SUM[338]), .clk(clk), .en_d2(en_d2), .Q(SUM[33]) );
smffb dla389 (.D(INT_CARRY[257]), .clk(clk), .en_d2(en_d2), .Q(CARRY[33]) );
smffa dla390 (.D(SUMMAND[323]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[323]) );
smffa dla391 (.D(SUMMAND[324]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[324]) );
smffa dla392 (.D(SUMMAND[325]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[325]) );
smfulladder dfa241 (.DATA_A (LATCHED_PP[323]), .DATA_B (LATCHED_PP[324]), .DATA_C (LATCHED_PP[325]), .SAVE (INT_SUM[339]), .CARRY (INT_CARRY[274]) );
smffa dla393 (.D(SUMMAND[326]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[326]) );
smffa dla394 (.D(SUMMAND[327]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[327]) );
smffa dla395 (.D(SUMMAND[328]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[328]) );
smfulladder dfa242 (.DATA_A (LATCHED_PP[326]), .DATA_B (LATCHED_PP[327]), .DATA_C (LATCHED_PP[328]), .SAVE (INT_SUM[340]), .CARRY (INT_CARRY[275]) );
smffa dla396 (.D(SUMMAND[329]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[329]) );
smffa dla397 (.D(SUMMAND[330]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[330]) );
smffa dla398 (.D(SUMMAND[331]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[331]) );
smfulladder dfa243 (.DATA_A (LATCHED_PP[329]), .DATA_B (LATCHED_PP[330]), .DATA_C (LATCHED_PP[331]), .SAVE (INT_SUM[341]), .CARRY (INT_CARRY[276]) );
smffa dla399 (.D(SUMMAND[332]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[332]) );
smffa dla400 (.D(SUMMAND[333]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[333]) );
smffa dla401 (.D(SUMMAND[334]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[334]) );
smfulladder dfa244 (.DATA_A (LATCHED_PP[332]), .DATA_B (LATCHED_PP[333]), .DATA_C (LATCHED_PP[334]), .SAVE (INT_SUM[342]), .CARRY (INT_CARRY[277]) );
smffa dla402 (.D(SUMMAND[335]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[335]) );
smffa dla403 (.D(SUMMAND[336]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[336]) );
smffa dla404 (.D(SUMMAND[337]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[337]) );
smfulladder dfa245 (.DATA_A (LATCHED_PP[335]), .DATA_B (LATCHED_PP[336]), .DATA_C (LATCHED_PP[337]), .SAVE (INT_SUM[343]), .CARRY (INT_CARRY[278]) );
smffa dla405 (.D(SUMMAND[338]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[338]) );
smffa dla406 (.D(SUMMAND[339]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[339]) );
smffa dla407 (.D(SUMMAND[340]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[340]) );
smfulladder dfa246 (.DATA_A (LATCHED_PP[338]), .DATA_B (LATCHED_PP[339]), .DATA_C (LATCHED_PP[340]), .SAVE (INT_SUM[344]), .CARRY (INT_CARRY[279]) );
smfulladder dfa247 (.DATA_A (INT_SUM[339]), .DATA_B (INT_SUM[340]), .DATA_C (INT_SUM[341]), .SAVE (INT_SUM[345]), .CARRY (INT_CARRY[280]) );
smfulladder dfa248 (.DATA_A (INT_SUM[342]), .DATA_B (INT_SUM[343]), .DATA_C (INT_SUM[344]), .SAVE (INT_SUM[346]), .CARRY (INT_CARRY[281]) );
smfulladder dfa249 (.DATA_A (INT_CARRY[258]), .DATA_B (INT_CARRY[259]), .DATA_C (INT_CARRY[260]), .SAVE (INT_SUM[347]), .CARRY (INT_CARRY[282]) );
assign INT_SUM[348] = INT_CARRY[261];
assign INT_SUM[349] = INT_CARRY[262];
smfulladder dfa250 (.DATA_A (INT_SUM[345]), .DATA_B (INT_SUM[346]), .DATA_C (INT_SUM[347]), .SAVE (INT_SUM[350]), .CARRY (INT_CARRY[283]) );
smfulladder dfa251 (.DATA_A (INT_SUM[348]), .DATA_B (INT_SUM[349]), .DATA_C (INT_CARRY[263]), .SAVE (INT_SUM[351]), .CARRY (INT_CARRY[284]) );
smfulladder dfa252 (.DATA_A (INT_CARRY[264]), .DATA_B (INT_CARRY[265]), .DATA_C (INT_CARRY[266]), .SAVE (INT_SUM[352]), .CARRY (INT_CARRY[285]) );
smfulladder dfa253 (.DATA_A (INT_SUM[350]), .DATA_B (INT_SUM[351]), .DATA_C (INT_SUM[352]), .SAVE (INT_SUM[353]), .CARRY (INT_CARRY[286]) );
smfulladder dfa254 (.DATA_A (INT_CARRY[267]), .DATA_B (INT_CARRY[268]), .DATA_C (INT_CARRY[269]), .SAVE (INT_SUM[354]), .CARRY (INT_CARRY[287]) );
smfulladder dfa255 (.DATA_A (INT_SUM[353]), .DATA_B (INT_SUM[354]), .DATA_C (INT_CARRY[270]), .SAVE (INT_SUM[355]), .CARRY (INT_CARRY[288]) );
assign INT_SUM[356] = INT_CARRY[271];
smfulladder dfa256 (.DATA_A (INT_SUM[355]), .DATA_B (INT_SUM[356]), .DATA_C (INT_CARRY[272]), .SAVE (INT_SUM[357]), .CARRY (INT_CARRY[273]) );
smffb dla408 (.D(INT_SUM[357]), .clk(clk), .en_d2(en_d2), .Q(SUM[34]) );
smffb dla409 (.D(INT_CARRY[273]), .clk(clk), .en_d2(en_d2), .Q(CARRY[34]) );
smffa dla410 (.D(SUMMAND[341]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[341]) );
smffa dla411 (.D(SUMMAND[342]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[342]) );
smffa dla412 (.D(SUMMAND[343]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[343]) );
smfulladder dfa257 (.DATA_A (LATCHED_PP[341]), .DATA_B (LATCHED_PP[342]), .DATA_C (LATCHED_PP[343]), .SAVE (INT_SUM[358]), .CARRY (INT_CARRY[290]) );
smffa dla413 (.D(SUMMAND[344]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[344]) );
smffa dla414 (.D(SUMMAND[345]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[345]) );
smffa dla415 (.D(SUMMAND[346]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[346]) );
smfulladder dfa258 (.DATA_A (LATCHED_PP[344]), .DATA_B (LATCHED_PP[345]), .DATA_C (LATCHED_PP[346]), .SAVE (INT_SUM[359]), .CARRY (INT_CARRY[291]) );
smffa dla416 (.D(SUMMAND[347]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[347]) );
smffa dla417 (.D(SUMMAND[348]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[348]) );
smffa dla418 (.D(SUMMAND[349]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[349]) );
smfulladder dfa259 (.DATA_A (LATCHED_PP[347]), .DATA_B (LATCHED_PP[348]), .DATA_C (LATCHED_PP[349]), .SAVE (INT_SUM[360]), .CARRY (INT_CARRY[292]) );
smffa dla419 (.D(SUMMAND[350]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[350]) );
smffa dla420 (.D(SUMMAND[351]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[351]) );
smffa dla421 (.D(SUMMAND[352]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[352]) );
smfulladder dfa260 (.DATA_A (LATCHED_PP[350]), .DATA_B (LATCHED_PP[351]), .DATA_C (LATCHED_PP[352]), .SAVE (INT_SUM[361]), .CARRY (INT_CARRY[293]) );
smffa dla422 (.D(SUMMAND[353]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[353]) );
smffa dla423 (.D(SUMMAND[354]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[354]) );
smffa dla424 (.D(SUMMAND[355]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[355]) );
smfulladder dfa261 (.DATA_A (LATCHED_PP[353]), .DATA_B (LATCHED_PP[354]), .DATA_C (LATCHED_PP[355]), .SAVE (INT_SUM[362]), .CARRY (INT_CARRY[294]) );
smffa dla425 (.D(SUMMAND[356]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[356]) );
smffa dla426 (.D(SUMMAND[357]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[357]) );
smhalfadder dha32 (.DATA_A (LATCHED_PP[356]), .DATA_B (LATCHED_PP[357]), .SAVE (INT_SUM[363]), .CARRY (INT_CARRY[295]) );
smfulladder dfa262 (.DATA_A (INT_SUM[358]), .DATA_B (INT_SUM[359]), .DATA_C (INT_SUM[360]), .SAVE (INT_SUM[364]), .CARRY (INT_CARRY[296]) );
smfulladder dfa263 (.DATA_A (INT_SUM[361]), .DATA_B (INT_SUM[362]), .DATA_C (INT_SUM[363]), .SAVE (INT_SUM[365]), .CARRY (INT_CARRY[297]) );
smfulladder dfa264 (.DATA_A (INT_CARRY[274]), .DATA_B (INT_CARRY[275]), .DATA_C (INT_CARRY[276]), .SAVE (INT_SUM[366]), .CARRY (INT_CARRY[298]) );
smfulladder dfa265 (.DATA_A (INT_CARRY[277]), .DATA_B (INT_CARRY[278]), .DATA_C (INT_CARRY[279]), .SAVE (INT_SUM[367]), .CARRY (INT_CARRY[299]) );
smfulladder dfa266 (.DATA_A (INT_SUM[364]), .DATA_B (INT_SUM[365]), .DATA_C (INT_SUM[366]), .SAVE (INT_SUM[368]), .CARRY (INT_CARRY[300]) );
smfulladder dfa267 (.DATA_A (INT_SUM[367]), .DATA_B (INT_CARRY[280]), .DATA_C (INT_CARRY[281]), .SAVE (INT_SUM[369]), .CARRY (INT_CARRY[301]) );
assign INT_SUM[370] = INT_CARRY[282];
smfulladder dfa268 (.DATA_A (INT_SUM[368]), .DATA_B (INT_SUM[369]), .DATA_C (INT_SUM[370]), .SAVE (INT_SUM[371]), .CARRY (INT_CARRY[302]) );
smfulladder dfa269 (.DATA_A (INT_CARRY[283]), .DATA_B (INT_CARRY[284]), .DATA_C (INT_CARRY[285]), .SAVE (INT_SUM[372]), .CARRY (INT_CARRY[303]) );
smfulladder dfa270 (.DATA_A (INT_SUM[371]), .DATA_B (INT_SUM[372]), .DATA_C (INT_CARRY[286]), .SAVE (INT_SUM[373]), .CARRY (INT_CARRY[304]) );
assign INT_SUM[374] = INT_CARRY[287];
smfulladder dfa271 (.DATA_A (INT_SUM[373]), .DATA_B (INT_SUM[374]), .DATA_C (INT_CARRY[288]), .SAVE (INT_SUM[375]), .CARRY (INT_CARRY[289]) );
smffb dla427 (.D(INT_SUM[375]), .clk(clk), .en_d2(en_d2), .Q(SUM[35]) );
smffb dla428 (.D(INT_CARRY[289]), .clk(clk), .en_d2(en_d2), .Q(CARRY[35]) );
smffa dla429 (.D(SUMMAND[358]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[358]) );
smffa dla430 (.D(SUMMAND[359]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[359]) );
smffa dla431 (.D(SUMMAND[360]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[360]) );
smfulladder dfa272 (.DATA_A (LATCHED_PP[358]), .DATA_B (LATCHED_PP[359]), .DATA_C (LATCHED_PP[360]), .SAVE (INT_SUM[376]), .CARRY (INT_CARRY[306]) );
smffa dla432 (.D(SUMMAND[361]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[361]) );
smffa dla433 (.D(SUMMAND[362]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[362]) );
smffa dla434 (.D(SUMMAND[363]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[363]) );
smfulladder dfa273 (.DATA_A (LATCHED_PP[361]), .DATA_B (LATCHED_PP[362]), .DATA_C (LATCHED_PP[363]), .SAVE (INT_SUM[377]), .CARRY (INT_CARRY[307]) );
smffa dla435 (.D(SUMMAND[364]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[364]) );
smffa dla436 (.D(SUMMAND[365]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[365]) );
smffa dla437 (.D(SUMMAND[366]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[366]) );
smfulladder dfa274 (.DATA_A (LATCHED_PP[364]), .DATA_B (LATCHED_PP[365]), .DATA_C (LATCHED_PP[366]), .SAVE (INT_SUM[378]), .CARRY (INT_CARRY[308]) );
smffa dla438 (.D(SUMMAND[367]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[367]) );
smffa dla439 (.D(SUMMAND[368]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[368]) );
smffa dla440 (.D(SUMMAND[369]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[369]) );
smfulladder dfa275 (.DATA_A (LATCHED_PP[367]), .DATA_B (LATCHED_PP[368]), .DATA_C (LATCHED_PP[369]), .SAVE (INT_SUM[379]), .CARRY (INT_CARRY[309]) );
smffa dla441 (.D(SUMMAND[370]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[370]) );
smffa dla442 (.D(SUMMAND[371]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[371]) );
smffa dla443 (.D(SUMMAND[372]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[372]) );
smfulladder dfa276 (.DATA_A (LATCHED_PP[370]), .DATA_B (LATCHED_PP[371]), .DATA_C (LATCHED_PP[372]), .SAVE (INT_SUM[380]), .CARRY (INT_CARRY[310]) );
smffa dla444 (.D(SUMMAND[373]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[373]) );
assign INT_SUM[381] = LATCHED_PP[373];
smfulladder dfa277 (.DATA_A (INT_SUM[376]), .DATA_B (INT_SUM[377]), .DATA_C (INT_SUM[378]), .SAVE (INT_SUM[382]), .CARRY (INT_CARRY[311]) );
smfulladder dfa278 (.DATA_A (INT_SUM[379]), .DATA_B (INT_SUM[380]), .DATA_C (INT_SUM[381]), .SAVE (INT_SUM[383]), .CARRY (INT_CARRY[312]) );
smfulladder dfa279 (.DATA_A (INT_CARRY[290]), .DATA_B (INT_CARRY[291]), .DATA_C (INT_CARRY[292]), .SAVE (INT_SUM[384]), .CARRY (INT_CARRY[313]) );
smfulladder dfa280 (.DATA_A (INT_CARRY[293]), .DATA_B (INT_CARRY[294]), .DATA_C (INT_CARRY[295]), .SAVE (INT_SUM[385]), .CARRY (INT_CARRY[314]) );
smfulladder dfa281 (.DATA_A (INT_SUM[382]), .DATA_B (INT_SUM[383]), .DATA_C (INT_SUM[384]), .SAVE (INT_SUM[386]), .CARRY (INT_CARRY[315]) );
smfulladder dfa282 (.DATA_A (INT_SUM[385]), .DATA_B (INT_CARRY[296]), .DATA_C (INT_CARRY[297]), .SAVE (INT_SUM[387]), .CARRY (INT_CARRY[316]) );
assign INT_SUM[388] = INT_CARRY[298];
assign INT_SUM[389] = INT_CARRY[299];
smfulladder dfa283 (.DATA_A (INT_SUM[386]), .DATA_B (INT_SUM[387]), .DATA_C (INT_SUM[388]), .SAVE (INT_SUM[390]), .CARRY (INT_CARRY[317]) );
smfulladder dfa284 (.DATA_A (INT_SUM[389]), .DATA_B (INT_CARRY[300]), .DATA_C (INT_CARRY[301]), .SAVE (INT_SUM[391]), .CARRY (INT_CARRY[318]) );
smfulladder dfa285 (.DATA_A (INT_SUM[390]), .DATA_B (INT_SUM[391]), .DATA_C (INT_CARRY[302]), .SAVE (INT_SUM[392]), .CARRY (INT_CARRY[319]) );
assign INT_SUM[393] = INT_CARRY[303];
smfulladder dfa286 (.DATA_A (INT_SUM[392]), .DATA_B (INT_SUM[393]), .DATA_C (INT_CARRY[304]), .SAVE (INT_SUM[394]), .CARRY (INT_CARRY[305]) );
smffb dla445 (.D(INT_SUM[394]), .clk(clk), .en_d2(en_d2), .Q(SUM[36]) );
smffb dla446 (.D(INT_CARRY[305]), .clk(clk), .en_d2(en_d2), .Q(CARRY[36]) );
smffa dla447 (.D(SUMMAND[374]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[374]) );
smffa dla448 (.D(SUMMAND[375]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[375]) );
smffa dla449 (.D(SUMMAND[376]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[376]) );
smfulladder dfa287 (.DATA_A (LATCHED_PP[374]), .DATA_B (LATCHED_PP[375]), .DATA_C (LATCHED_PP[376]), .SAVE (INT_SUM[395]), .CARRY (INT_CARRY[321]) );
smffa dla450 (.D(SUMMAND[377]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[377]) );
smffa dla451 (.D(SUMMAND[378]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[378]) );
smffa dla452 (.D(SUMMAND[379]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[379]) );
smfulladder dfa288 (.DATA_A (LATCHED_PP[377]), .DATA_B (LATCHED_PP[378]), .DATA_C (LATCHED_PP[379]), .SAVE (INT_SUM[396]), .CARRY (INT_CARRY[322]) );
smffa dla453 (.D(SUMMAND[380]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[380]) );
smffa dla454 (.D(SUMMAND[381]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[381]) );
smffa dla455 (.D(SUMMAND[382]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[382]) );
smfulladder dfa289 (.DATA_A (LATCHED_PP[380]), .DATA_B (LATCHED_PP[381]), .DATA_C (LATCHED_PP[382]), .SAVE (INT_SUM[397]), .CARRY (INT_CARRY[323]) );
smffa dla456 (.D(SUMMAND[383]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[383]) );
smffa dla457 (.D(SUMMAND[384]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[384]) );
smffa dla458 (.D(SUMMAND[385]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[385]) );
smfulladder dfa290 (.DATA_A (LATCHED_PP[383]), .DATA_B (LATCHED_PP[384]), .DATA_C (LATCHED_PP[385]), .SAVE (INT_SUM[398]), .CARRY (INT_CARRY[324]) );
smffa dla459 (.D(SUMMAND[386]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[386]) );
smffa dla460 (.D(SUMMAND[387]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[387]) );
smffa dla461 (.D(SUMMAND[388]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[388]) );
smfulladder dfa291 (.DATA_A (LATCHED_PP[386]), .DATA_B (LATCHED_PP[387]), .DATA_C (LATCHED_PP[388]), .SAVE (INT_SUM[399]), .CARRY (INT_CARRY[325]) );
smffa dla462 (.D(SUMMAND[389]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[389]) );
assign INT_SUM[400] = LATCHED_PP[389];
smfulladder dfa292 (.DATA_A (INT_SUM[395]), .DATA_B (INT_SUM[396]), .DATA_C (INT_SUM[397]), .SAVE (INT_SUM[401]), .CARRY (INT_CARRY[326]) );
smfulladder dfa293 (.DATA_A (INT_SUM[398]), .DATA_B (INT_SUM[399]), .DATA_C (INT_SUM[400]), .SAVE (INT_SUM[402]), .CARRY (INT_CARRY[327]) );
smfulladder dfa294 (.DATA_A (INT_CARRY[306]), .DATA_B (INT_CARRY[307]), .DATA_C (INT_CARRY[308]), .SAVE (INT_SUM[403]), .CARRY (INT_CARRY[328]) );
assign INT_SUM[404] = INT_CARRY[309];
assign INT_SUM[405] = INT_CARRY[310];
smfulladder dfa295 (.DATA_A (INT_SUM[401]), .DATA_B (INT_SUM[402]), .DATA_C (INT_SUM[403]), .SAVE (INT_SUM[406]), .CARRY (INT_CARRY[329]) );
smfulladder dfa296 (.DATA_A (INT_SUM[404]), .DATA_B (INT_SUM[405]), .DATA_C (INT_CARRY[311]), .SAVE (INT_SUM[407]), .CARRY (INT_CARRY[330]) );
smfulladder dfa297 (.DATA_A (INT_CARRY[312]), .DATA_B (INT_CARRY[313]), .DATA_C (INT_CARRY[314]), .SAVE (INT_SUM[408]), .CARRY (INT_CARRY[331]) );
smfulladder dfa298 (.DATA_A (INT_SUM[406]), .DATA_B (INT_SUM[407]), .DATA_C (INT_SUM[408]), .SAVE (INT_SUM[409]), .CARRY (INT_CARRY[332]) );
smhalfadder dha33 (.DATA_A (INT_CARRY[315]), .DATA_B (INT_CARRY[316]), .SAVE (INT_SUM[410]), .CARRY (INT_CARRY[333]) );
smfulladder dfa299 (.DATA_A (INT_SUM[409]), .DATA_B (INT_SUM[410]), .DATA_C (INT_CARRY[317]), .SAVE (INT_SUM[411]), .CARRY (INT_CARRY[334]) );
assign INT_SUM[412] = INT_CARRY[318];
smfulladder dfa300 (.DATA_A (INT_SUM[411]), .DATA_B (INT_SUM[412]), .DATA_C (INT_CARRY[319]), .SAVE (INT_SUM[413]), .CARRY (INT_CARRY[320]) );
smffb dla463 (.D(INT_SUM[413]), .clk(clk), .en_d2(en_d2), .Q(SUM[37]) );
smffb dla464 (.D(INT_CARRY[320]), .clk(clk), .en_d2(en_d2), .Q(CARRY[37]) );
smffa dla465 (.D(SUMMAND[390]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[390]) );
smffa dla466 (.D(SUMMAND[391]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[391]) );
smffa dla467 (.D(SUMMAND[392]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[392]) );
smfulladder dfa301 (.DATA_A (LATCHED_PP[390]), .DATA_B (LATCHED_PP[391]), .DATA_C (LATCHED_PP[392]), .SAVE (INT_SUM[414]), .CARRY (INT_CARRY[336]) );
smffa dla468 (.D(SUMMAND[393]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[393]) );
smffa dla469 (.D(SUMMAND[394]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[394]) );
smffa dla470 (.D(SUMMAND[395]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[395]) );
smfulladder dfa302 (.DATA_A (LATCHED_PP[393]), .DATA_B (LATCHED_PP[394]), .DATA_C (LATCHED_PP[395]), .SAVE (INT_SUM[415]), .CARRY (INT_CARRY[337]) );
smffa dla471 (.D(SUMMAND[396]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[396]) );
smffa dla472 (.D(SUMMAND[397]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[397]) );
smffa dla473 (.D(SUMMAND[398]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[398]) );
smfulladder dfa303 (.DATA_A (LATCHED_PP[396]), .DATA_B (LATCHED_PP[397]), .DATA_C (LATCHED_PP[398]), .SAVE (INT_SUM[416]), .CARRY (INT_CARRY[338]) );
smffa dla474 (.D(SUMMAND[399]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[399]) );
smffa dla475 (.D(SUMMAND[400]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[400]) );
smffa dla476 (.D(SUMMAND[401]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[401]) );
smfulladder dfa304 (.DATA_A (LATCHED_PP[399]), .DATA_B (LATCHED_PP[400]), .DATA_C (LATCHED_PP[401]), .SAVE (INT_SUM[417]), .CARRY (INT_CARRY[339]) );
smffa dla477 (.D(SUMMAND[402]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[402]) );
smffa dla478 (.D(SUMMAND[403]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[403]) );
smffa dla479 (.D(SUMMAND[404]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[404]) );
smfulladder dfa305 (.DATA_A (LATCHED_PP[402]), .DATA_B (LATCHED_PP[403]), .DATA_C (LATCHED_PP[404]), .SAVE (INT_SUM[418]), .CARRY (INT_CARRY[340]) );
smfulladder dfa306 (.DATA_A (INT_SUM[414]), .DATA_B (INT_SUM[415]), .DATA_C (INT_SUM[416]), .SAVE (INT_SUM[419]), .CARRY (INT_CARRY[341]) );
smfulladder dfa307 (.DATA_A (INT_SUM[417]), .DATA_B (INT_SUM[418]), .DATA_C (INT_CARRY[321]), .SAVE (INT_SUM[420]), .CARRY (INT_CARRY[342]) );
smfulladder dfa308 (.DATA_A (INT_CARRY[322]), .DATA_B (INT_CARRY[323]), .DATA_C (INT_CARRY[324]), .SAVE (INT_SUM[421]), .CARRY (INT_CARRY[343]) );
assign INT_SUM[422] = INT_CARRY[325];
smfulladder dfa309 (.DATA_A (INT_SUM[419]), .DATA_B (INT_SUM[420]), .DATA_C (INT_SUM[421]), .SAVE (INT_SUM[423]), .CARRY (INT_CARRY[344]) );
smfulladder dfa310 (.DATA_A (INT_SUM[422]), .DATA_B (INT_CARRY[326]), .DATA_C (INT_CARRY[327]), .SAVE (INT_SUM[424]), .CARRY (INT_CARRY[345]) );
assign INT_SUM[425] = INT_CARRY[328];
smfulladder dfa311 (.DATA_A (INT_SUM[423]), .DATA_B (INT_SUM[424]), .DATA_C (INT_SUM[425]), .SAVE (INT_SUM[426]), .CARRY (INT_CARRY[346]) );
smfulladder dfa312 (.DATA_A (INT_CARRY[329]), .DATA_B (INT_CARRY[330]), .DATA_C (INT_CARRY[331]), .SAVE (INT_SUM[427]), .CARRY (INT_CARRY[347]) );
smfulladder dfa313 (.DATA_A (INT_SUM[426]), .DATA_B (INT_SUM[427]), .DATA_C (INT_CARRY[332]), .SAVE (INT_SUM[428]), .CARRY (INT_CARRY[348]) );
assign INT_SUM[429] = INT_CARRY[333];
smfulladder dfa314 (.DATA_A (INT_SUM[428]), .DATA_B (INT_SUM[429]), .DATA_C (INT_CARRY[334]), .SAVE (INT_SUM[430]), .CARRY (INT_CARRY[335]) );
smffb dla480 (.D(INT_SUM[430]), .clk(clk), .en_d2(en_d2), .Q(SUM[38]) );
smffb dla481 (.D(INT_CARRY[335]), .clk(clk), .en_d2(en_d2), .Q(CARRY[38]) );
smffa dla482 (.D(SUMMAND[405]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[405]) );
smffa dla483 (.D(SUMMAND[406]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[406]) );
smffa dla484 (.D(SUMMAND[407]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[407]) );
smfulladder dfa315 (.DATA_A (LATCHED_PP[405]), .DATA_B (LATCHED_PP[406]), .DATA_C (LATCHED_PP[407]), .SAVE (INT_SUM[431]), .CARRY (INT_CARRY[350]) );
smffa dla485 (.D(SUMMAND[408]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[408]) );
smffa dla486 (.D(SUMMAND[409]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[409]) );
smffa dla487 (.D(SUMMAND[410]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[410]) );
smfulladder dfa316 (.DATA_A (LATCHED_PP[408]), .DATA_B (LATCHED_PP[409]), .DATA_C (LATCHED_PP[410]), .SAVE (INT_SUM[432]), .CARRY (INT_CARRY[351]) );
smffa dla488 (.D(SUMMAND[411]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[411]) );
smffa dla489 (.D(SUMMAND[412]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[412]) );
smffa dla490 (.D(SUMMAND[413]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[413]) );
smfulladder dfa317 (.DATA_A (LATCHED_PP[411]), .DATA_B (LATCHED_PP[412]), .DATA_C (LATCHED_PP[413]), .SAVE (INT_SUM[433]), .CARRY (INT_CARRY[352]) );
smffa dla491 (.D(SUMMAND[414]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[414]) );
smffa dla492 (.D(SUMMAND[415]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[415]) );
smffa dla493 (.D(SUMMAND[416]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[416]) );
smfulladder dfa318 (.DATA_A (LATCHED_PP[414]), .DATA_B (LATCHED_PP[415]), .DATA_C (LATCHED_PP[416]), .SAVE (INT_SUM[434]), .CARRY (INT_CARRY[353]) );
smffa dla494 (.D(SUMMAND[417]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[417]) );
smffa dla495 (.D(SUMMAND[418]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[418]) );
smffa dla496 (.D(SUMMAND[419]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[419]) );
smfulladder dfa319 (.DATA_A (LATCHED_PP[417]), .DATA_B (LATCHED_PP[418]), .DATA_C (LATCHED_PP[419]), .SAVE (INT_SUM[435]), .CARRY (INT_CARRY[354]) );
smfulladder dfa320 (.DATA_A (INT_SUM[431]), .DATA_B (INT_SUM[432]), .DATA_C (INT_SUM[433]), .SAVE (INT_SUM[436]), .CARRY (INT_CARRY[355]) );
smfulladder dfa321 (.DATA_A (INT_SUM[434]), .DATA_B (INT_SUM[435]), .DATA_C (INT_CARRY[336]), .SAVE (INT_SUM[437]), .CARRY (INT_CARRY[356]) );
smfulladder dfa322 (.DATA_A (INT_CARRY[337]), .DATA_B (INT_CARRY[338]), .DATA_C (INT_CARRY[339]), .SAVE (INT_SUM[438]), .CARRY (INT_CARRY[357]) );
assign INT_SUM[439] = INT_CARRY[340];
smfulladder dfa323 (.DATA_A (INT_SUM[436]), .DATA_B (INT_SUM[437]), .DATA_C (INT_SUM[438]), .SAVE (INT_SUM[440]), .CARRY (INT_CARRY[358]) );
smfulladder dfa324 (.DATA_A (INT_SUM[439]), .DATA_B (INT_CARRY[341]), .DATA_C (INT_CARRY[342]), .SAVE (INT_SUM[441]), .CARRY (INT_CARRY[359]) );
assign INT_SUM[442] = INT_CARRY[343];
smfulladder dfa325 (.DATA_A (INT_SUM[440]), .DATA_B (INT_SUM[441]), .DATA_C (INT_SUM[442]), .SAVE (INT_SUM[443]), .CARRY (INT_CARRY[360]) );
smhalfadder dha34 (.DATA_A (INT_CARRY[344]), .DATA_B (INT_CARRY[345]), .SAVE (INT_SUM[444]), .CARRY (INT_CARRY[361]) );
smfulladder dfa326 (.DATA_A (INT_SUM[443]), .DATA_B (INT_SUM[444]), .DATA_C (INT_CARRY[346]), .SAVE (INT_SUM[445]), .CARRY (INT_CARRY[362]) );
assign INT_SUM[446] = INT_CARRY[347];
smfulladder dfa327 (.DATA_A (INT_SUM[445]), .DATA_B (INT_SUM[446]), .DATA_C (INT_CARRY[348]), .SAVE (INT_SUM[447]), .CARRY (INT_CARRY[349]) );
smffb dla497 (.D(INT_SUM[447]), .clk(clk), .en_d2(en_d2), .Q(SUM[39]) );
smffb dla498 (.D(INT_CARRY[349]), .clk(clk), .en_d2(en_d2), .Q(CARRY[39]) );
smffa dla499 (.D(SUMMAND[420]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[420]) );
smffa dla500 (.D(SUMMAND[421]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[421]) );
smffa dla501 (.D(SUMMAND[422]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[422]) );
smfulladder dfa328 (.DATA_A (LATCHED_PP[420]), .DATA_B (LATCHED_PP[421]), .DATA_C (LATCHED_PP[422]), .SAVE (INT_SUM[448]), .CARRY (INT_CARRY[364]) );
smffa dla502 (.D(SUMMAND[423]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[423]) );
smffa dla503 (.D(SUMMAND[424]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[424]) );
smffa dla504 (.D(SUMMAND[425]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[425]) );
smfulladder dfa329 (.DATA_A (LATCHED_PP[423]), .DATA_B (LATCHED_PP[424]), .DATA_C (LATCHED_PP[425]), .SAVE (INT_SUM[449]), .CARRY (INT_CARRY[365]) );
smffa dla505 (.D(SUMMAND[426]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[426]) );
smffa dla506 (.D(SUMMAND[427]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[427]) );
smffa dla507 (.D(SUMMAND[428]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[428]) );
smfulladder dfa330 (.DATA_A (LATCHED_PP[426]), .DATA_B (LATCHED_PP[427]), .DATA_C (LATCHED_PP[428]), .SAVE (INT_SUM[450]), .CARRY (INT_CARRY[366]) );
smffa dla508 (.D(SUMMAND[429]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[429]) );
smffa dla509 (.D(SUMMAND[430]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[430]) );
smffa dla510 (.D(SUMMAND[431]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[431]) );
smfulladder dfa331 (.DATA_A (LATCHED_PP[429]), .DATA_B (LATCHED_PP[430]), .DATA_C (LATCHED_PP[431]), .SAVE (INT_SUM[451]), .CARRY (INT_CARRY[367]) );
smffa dla511 (.D(SUMMAND[432]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[432]) );
smffa dla512 (.D(SUMMAND[433]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[433]) );
smhalfadder dha35 (.DATA_A (LATCHED_PP[432]), .DATA_B (LATCHED_PP[433]), .SAVE (INT_SUM[452]), .CARRY (INT_CARRY[368]) );
smfulladder dfa332 (.DATA_A (INT_SUM[448]), .DATA_B (INT_SUM[449]), .DATA_C (INT_SUM[450]), .SAVE (INT_SUM[453]), .CARRY (INT_CARRY[369]) );
smfulladder dfa333 (.DATA_A (INT_SUM[451]), .DATA_B (INT_SUM[452]), .DATA_C (INT_CARRY[350]), .SAVE (INT_SUM[454]), .CARRY (INT_CARRY[370]) );
smfulladder dfa334 (.DATA_A (INT_CARRY[351]), .DATA_B (INT_CARRY[352]), .DATA_C (INT_CARRY[353]), .SAVE (INT_SUM[455]), .CARRY (INT_CARRY[371]) );
assign INT_SUM[456] = INT_CARRY[354];
smfulladder dfa335 (.DATA_A (INT_SUM[453]), .DATA_B (INT_SUM[454]), .DATA_C (INT_SUM[455]), .SAVE (INT_SUM[457]), .CARRY (INT_CARRY[372]) );
smfulladder dfa336 (.DATA_A (INT_SUM[456]), .DATA_B (INT_CARRY[355]), .DATA_C (INT_CARRY[356]), .SAVE (INT_SUM[458]), .CARRY (INT_CARRY[373]) );
assign INT_SUM[459] = INT_CARRY[357];
smfulladder dfa337 (.DATA_A (INT_SUM[457]), .DATA_B (INT_SUM[458]), .DATA_C (INT_SUM[459]), .SAVE (INT_SUM[460]), .CARRY (INT_CARRY[374]) );
smhalfadder dha36 (.DATA_A (INT_CARRY[358]), .DATA_B (INT_CARRY[359]), .SAVE (INT_SUM[461]), .CARRY (INT_CARRY[375]) );
smfulladder dfa338 (.DATA_A (INT_SUM[460]), .DATA_B (INT_SUM[461]), .DATA_C (INT_CARRY[360]), .SAVE (INT_SUM[462]), .CARRY (INT_CARRY[376]) );
assign INT_SUM[463] = INT_CARRY[361];
smfulladder dfa339 (.DATA_A (INT_SUM[462]), .DATA_B (INT_SUM[463]), .DATA_C (INT_CARRY[362]), .SAVE (INT_SUM[464]), .CARRY (INT_CARRY[363]) );
smffb dla513 (.D(INT_SUM[464]), .clk(clk), .en_d2(en_d2), .Q(SUM[40]) );
smffb dla514 (.D(INT_CARRY[363]), .clk(clk), .en_d2(en_d2), .Q(CARRY[40]) );
smffa dla515 (.D(SUMMAND[434]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[434]) );
smffa dla516 (.D(SUMMAND[435]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[435]) );
smffa dla517 (.D(SUMMAND[436]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[436]) );
smfulladder dfa340 (.DATA_A (LATCHED_PP[434]), .DATA_B (LATCHED_PP[435]), .DATA_C (LATCHED_PP[436]), .SAVE (INT_SUM[465]), .CARRY (INT_CARRY[378]) );
smffa dla518 (.D(SUMMAND[437]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[437]) );
smffa dla519 (.D(SUMMAND[438]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[438]) );
smffa dla520 (.D(SUMMAND[439]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[439]) );
smfulladder dfa341 (.DATA_A (LATCHED_PP[437]), .DATA_B (LATCHED_PP[438]), .DATA_C (LATCHED_PP[439]), .SAVE (INT_SUM[466]), .CARRY (INT_CARRY[379]) );
smffa dla521 (.D(SUMMAND[440]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[440]) );
smffa dla522 (.D(SUMMAND[441]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[441]) );
smffa dla523 (.D(SUMMAND[442]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[442]) );
smfulladder dfa342 (.DATA_A (LATCHED_PP[440]), .DATA_B (LATCHED_PP[441]), .DATA_C (LATCHED_PP[442]), .SAVE (INT_SUM[467]), .CARRY (INT_CARRY[380]) );
smffa dla524 (.D(SUMMAND[443]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[443]) );
smffa dla525 (.D(SUMMAND[444]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[444]) );
smffa dla526 (.D(SUMMAND[445]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[445]) );
smfulladder dfa343 (.DATA_A (LATCHED_PP[443]), .DATA_B (LATCHED_PP[444]), .DATA_C (LATCHED_PP[445]), .SAVE (INT_SUM[468]), .CARRY (INT_CARRY[381]) );
smffa dla527 (.D(SUMMAND[446]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[446]) );
smffa dla528 (.D(SUMMAND[447]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[447]) );
smhalfadder dha37 (.DATA_A (LATCHED_PP[446]), .DATA_B (LATCHED_PP[447]), .SAVE (INT_SUM[469]), .CARRY (INT_CARRY[382]) );
smfulladder dfa344 (.DATA_A (INT_SUM[465]), .DATA_B (INT_SUM[466]), .DATA_C (INT_SUM[467]), .SAVE (INT_SUM[470]), .CARRY (INT_CARRY[383]) );
smfulladder dfa345 (.DATA_A (INT_SUM[468]), .DATA_B (INT_SUM[469]), .DATA_C (INT_CARRY[364]), .SAVE (INT_SUM[471]), .CARRY (INT_CARRY[384]) );
smfulladder dfa346 (.DATA_A (INT_CARRY[365]), .DATA_B (INT_CARRY[366]), .DATA_C (INT_CARRY[367]), .SAVE (INT_SUM[472]), .CARRY (INT_CARRY[385]) );
assign INT_SUM[473] = INT_CARRY[368];
smfulladder dfa347 (.DATA_A (INT_SUM[470]), .DATA_B (INT_SUM[471]), .DATA_C (INT_SUM[472]), .SAVE (INT_SUM[474]), .CARRY (INT_CARRY[386]) );
smfulladder dfa348 (.DATA_A (INT_SUM[473]), .DATA_B (INT_CARRY[369]), .DATA_C (INT_CARRY[370]), .SAVE (INT_SUM[475]), .CARRY (INT_CARRY[387]) );
assign INT_SUM[476] = INT_CARRY[371];
smfulladder dfa349 (.DATA_A (INT_SUM[474]), .DATA_B (INT_SUM[475]), .DATA_C (INT_SUM[476]), .SAVE (INT_SUM[477]), .CARRY (INT_CARRY[388]) );
smhalfadder dha38 (.DATA_A (INT_CARRY[372]), .DATA_B (INT_CARRY[373]), .SAVE (INT_SUM[478]), .CARRY (INT_CARRY[389]) );
smfulladder dfa350 (.DATA_A (INT_SUM[477]), .DATA_B (INT_SUM[478]), .DATA_C (INT_CARRY[374]), .SAVE (INT_SUM[479]), .CARRY (INT_CARRY[390]) );
assign INT_SUM[480] = INT_CARRY[375];
smfulladder dfa351 (.DATA_A (INT_SUM[479]), .DATA_B (INT_SUM[480]), .DATA_C (INT_CARRY[376]), .SAVE (INT_SUM[481]), .CARRY (INT_CARRY[377]) );
smffb dla529 (.D(INT_SUM[481]), .clk(clk), .en_d2(en_d2), .Q(SUM[41]) );
smffb dla530 (.D(INT_CARRY[377]), .clk(clk), .en_d2(en_d2), .Q(CARRY[41]) );
smffa dla531 (.D(SUMMAND[448]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[448]) );
smffa dla532 (.D(SUMMAND[449]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[449]) );
smffa dla533 (.D(SUMMAND[450]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[450]) );
smfulladder dfa352 (.DATA_A (LATCHED_PP[448]), .DATA_B (LATCHED_PP[449]), .DATA_C (LATCHED_PP[450]), .SAVE (INT_SUM[482]), .CARRY (INT_CARRY[392]) );
smffa dla534 (.D(SUMMAND[451]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[451]) );
smffa dla535 (.D(SUMMAND[452]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[452]) );
smffa dla536 (.D(SUMMAND[453]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[453]) );
smfulladder dfa353 (.DATA_A (LATCHED_PP[451]), .DATA_B (LATCHED_PP[452]), .DATA_C (LATCHED_PP[453]), .SAVE (INT_SUM[483]), .CARRY (INT_CARRY[393]) );
smffa dla537 (.D(SUMMAND[454]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[454]) );
smffa dla538 (.D(SUMMAND[455]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[455]) );
smffa dla539 (.D(SUMMAND[456]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[456]) );
smfulladder dfa354 (.DATA_A (LATCHED_PP[454]), .DATA_B (LATCHED_PP[455]), .DATA_C (LATCHED_PP[456]), .SAVE (INT_SUM[484]), .CARRY (INT_CARRY[394]) );
smffa dla540 (.D(SUMMAND[457]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[457]) );
smffa dla541 (.D(SUMMAND[458]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[458]) );
smffa dla542 (.D(SUMMAND[459]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[459]) );
smfulladder dfa355 (.DATA_A (LATCHED_PP[457]), .DATA_B (LATCHED_PP[458]), .DATA_C (LATCHED_PP[459]), .SAVE (INT_SUM[485]), .CARRY (INT_CARRY[395]) );
smffa dla543 (.D(SUMMAND[460]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[460]) );
assign INT_SUM[486] = LATCHED_PP[460];
smfulladder dfa356 (.DATA_A (INT_SUM[482]), .DATA_B (INT_SUM[483]), .DATA_C (INT_SUM[484]), .SAVE (INT_SUM[487]), .CARRY (INT_CARRY[396]) );
smfulladder dfa357 (.DATA_A (INT_SUM[485]), .DATA_B (INT_SUM[486]), .DATA_C (INT_CARRY[378]), .SAVE (INT_SUM[488]), .CARRY (INT_CARRY[397]) );
smfulladder dfa358 (.DATA_A (INT_CARRY[379]), .DATA_B (INT_CARRY[380]), .DATA_C (INT_CARRY[381]), .SAVE (INT_SUM[489]), .CARRY (INT_CARRY[398]) );
assign INT_SUM[490] = INT_CARRY[382];
smfulladder dfa359 (.DATA_A (INT_SUM[487]), .DATA_B (INT_SUM[488]), .DATA_C (INT_SUM[489]), .SAVE (INT_SUM[491]), .CARRY (INT_CARRY[399]) );
smfulladder dfa360 (.DATA_A (INT_SUM[490]), .DATA_B (INT_CARRY[383]), .DATA_C (INT_CARRY[384]), .SAVE (INT_SUM[492]), .CARRY (INT_CARRY[400]) );
assign INT_SUM[493] = INT_CARRY[385];
smfulladder dfa361 (.DATA_A (INT_SUM[491]), .DATA_B (INT_SUM[492]), .DATA_C (INT_SUM[493]), .SAVE (INT_SUM[494]), .CARRY (INT_CARRY[401]) );
smhalfadder dha39 (.DATA_A (INT_CARRY[386]), .DATA_B (INT_CARRY[387]), .SAVE (INT_SUM[495]), .CARRY (INT_CARRY[402]) );
smfulladder dfa362 (.DATA_A (INT_SUM[494]), .DATA_B (INT_SUM[495]), .DATA_C (INT_CARRY[388]), .SAVE (INT_SUM[496]), .CARRY (INT_CARRY[403]) );
assign INT_SUM[497] = INT_CARRY[389];
smfulladder dfa363 (.DATA_A (INT_SUM[496]), .DATA_B (INT_SUM[497]), .DATA_C (INT_CARRY[390]), .SAVE (INT_SUM[498]), .CARRY (INT_CARRY[391]) );
smffb dla544 (.D(INT_SUM[498]), .clk(clk), .en_d2(en_d2), .Q(SUM[42]) );
smffb dla545 (.D(INT_CARRY[391]), .clk(clk), .en_d2(en_d2), .Q(CARRY[42]) );
smffa dla546 (.D(SUMMAND[461]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[461]) );
smffa dla547 (.D(SUMMAND[462]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[462]) );
smffa dla548 (.D(SUMMAND[463]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[463]) );
smfulladder dfa364 (.DATA_A (LATCHED_PP[461]), .DATA_B (LATCHED_PP[462]), .DATA_C (LATCHED_PP[463]), .SAVE (INT_SUM[499]), .CARRY (INT_CARRY[405]) );
smffa dla549 (.D(SUMMAND[464]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[464]) );
smffa dla550 (.D(SUMMAND[465]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[465]) );
smffa dla551 (.D(SUMMAND[466]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[466]) );
smfulladder dfa365 (.DATA_A (LATCHED_PP[464]), .DATA_B (LATCHED_PP[465]), .DATA_C (LATCHED_PP[466]), .SAVE (INT_SUM[500]), .CARRY (INT_CARRY[406]) );
smffa dla552 (.D(SUMMAND[467]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[467]) );
smffa dla553 (.D(SUMMAND[468]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[468]) );
smffa dla554 (.D(SUMMAND[469]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[469]) );
smfulladder dfa366 (.DATA_A (LATCHED_PP[467]), .DATA_B (LATCHED_PP[468]), .DATA_C (LATCHED_PP[469]), .SAVE (INT_SUM[501]), .CARRY (INT_CARRY[407]) );
smffa dla555 (.D(SUMMAND[470]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[470]) );
smffa dla556 (.D(SUMMAND[471]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[471]) );
smffa dla557 (.D(SUMMAND[472]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[472]) );
smfulladder dfa367 (.DATA_A (LATCHED_PP[470]), .DATA_B (LATCHED_PP[471]), .DATA_C (LATCHED_PP[472]), .SAVE (INT_SUM[502]), .CARRY (INT_CARRY[408]) );
smffa dla558 (.D(SUMMAND[473]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[473]) );
smfulladder dfa368 (.DATA_A (LATCHED_PP[473]), .DATA_B (INT_CARRY[392]), .DATA_C (INT_CARRY[393]), .SAVE (INT_SUM[503]), .CARRY (INT_CARRY[409]) );
assign INT_SUM[504] = INT_CARRY[394];
assign INT_SUM[505] = INT_CARRY[395];
smfulladder dfa369 (.DATA_A (INT_SUM[499]), .DATA_B (INT_SUM[500]), .DATA_C (INT_SUM[501]), .SAVE (INT_SUM[506]), .CARRY (INT_CARRY[410]) );
smfulladder dfa370 (.DATA_A (INT_SUM[502]), .DATA_B (INT_SUM[503]), .DATA_C (INT_SUM[504]), .SAVE (INT_SUM[507]), .CARRY (INT_CARRY[411]) );
smfulladder dfa371 (.DATA_A (INT_SUM[505]), .DATA_B (INT_CARRY[396]), .DATA_C (INT_CARRY[397]), .SAVE (INT_SUM[508]), .CARRY (INT_CARRY[412]) );
assign INT_SUM[509] = INT_CARRY[398];
smfulladder dfa372 (.DATA_A (INT_SUM[506]), .DATA_B (INT_SUM[507]), .DATA_C (INT_SUM[508]), .SAVE (INT_SUM[510]), .CARRY (INT_CARRY[413]) );
smfulladder dfa373 (.DATA_A (INT_SUM[509]), .DATA_B (INT_CARRY[399]), .DATA_C (INT_CARRY[400]), .SAVE (INT_SUM[511]), .CARRY (INT_CARRY[414]) );
smfulladder dfa374 (.DATA_A (INT_SUM[510]), .DATA_B (INT_SUM[511]), .DATA_C (INT_CARRY[401]), .SAVE (INT_SUM[512]), .CARRY (INT_CARRY[415]) );
assign INT_SUM[513] = INT_CARRY[402];
smfulladder dfa375 (.DATA_A (INT_SUM[512]), .DATA_B (INT_SUM[513]), .DATA_C (INT_CARRY[403]), .SAVE (INT_SUM[514]), .CARRY (INT_CARRY[404]) );
smffb dla559 (.D(INT_SUM[514]), .clk(clk), .en_d2(en_d2), .Q(SUM[43]) );
smffb dla560 (.D(INT_CARRY[404]), .clk(clk), .en_d2(en_d2), .Q(CARRY[43]) );
smffa dla561 (.D(SUMMAND[474]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[474]) );
smffa dla562 (.D(SUMMAND[475]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[475]) );
smffa dla563 (.D(SUMMAND[476]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[476]) );
smfulladder dfa376 (.DATA_A (LATCHED_PP[474]), .DATA_B (LATCHED_PP[475]), .DATA_C (LATCHED_PP[476]), .SAVE (INT_SUM[515]), .CARRY (INT_CARRY[417]) );
smffa dla564 (.D(SUMMAND[477]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[477]) );
smffa dla565 (.D(SUMMAND[478]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[478]) );
smffa dla566 (.D(SUMMAND[479]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[479]) );
smfulladder dfa377 (.DATA_A (LATCHED_PP[477]), .DATA_B (LATCHED_PP[478]), .DATA_C (LATCHED_PP[479]), .SAVE (INT_SUM[516]), .CARRY (INT_CARRY[418]) );
smffa dla567 (.D(SUMMAND[480]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[480]) );
smffa dla568 (.D(SUMMAND[481]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[481]) );
smffa dla569 (.D(SUMMAND[482]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[482]) );
smfulladder dfa378 (.DATA_A (LATCHED_PP[480]), .DATA_B (LATCHED_PP[481]), .DATA_C (LATCHED_PP[482]), .SAVE (INT_SUM[517]), .CARRY (INT_CARRY[419]) );
smffa dla570 (.D(SUMMAND[483]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[483]) );
smffa dla571 (.D(SUMMAND[484]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[484]) );
smffa dla572 (.D(SUMMAND[485]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[485]) );
smfulladder dfa379 (.DATA_A (LATCHED_PP[483]), .DATA_B (LATCHED_PP[484]), .DATA_C (LATCHED_PP[485]), .SAVE (INT_SUM[518]), .CARRY (INT_CARRY[420]) );
smfulladder dfa380 (.DATA_A (INT_SUM[515]), .DATA_B (INT_SUM[516]), .DATA_C (INT_SUM[517]), .SAVE (INT_SUM[519]), .CARRY (INT_CARRY[421]) );
smfulladder dfa381 (.DATA_A (INT_SUM[518]), .DATA_B (INT_CARRY[405]), .DATA_C (INT_CARRY[406]), .SAVE (INT_SUM[520]), .CARRY (INT_CARRY[422]) );
smfulladder dfa382 (.DATA_A (INT_CARRY[407]), .DATA_B (INT_CARRY[408]), .DATA_C (INT_CARRY[409]), .SAVE (INT_SUM[521]), .CARRY (INT_CARRY[423]) );
smfulladder dfa383 (.DATA_A (INT_SUM[519]), .DATA_B (INT_SUM[520]), .DATA_C (INT_SUM[521]), .SAVE (INT_SUM[522]), .CARRY (INT_CARRY[424]) );
smfulladder dfa384 (.DATA_A (INT_CARRY[410]), .DATA_B (INT_CARRY[411]), .DATA_C (INT_CARRY[412]), .SAVE (INT_SUM[523]), .CARRY (INT_CARRY[425]) );
smfulladder dfa385 (.DATA_A (INT_SUM[522]), .DATA_B (INT_SUM[523]), .DATA_C (INT_CARRY[413]), .SAVE (INT_SUM[524]), .CARRY (INT_CARRY[426]) );
assign INT_SUM[525] = INT_CARRY[414];
smfulladder dfa386 (.DATA_A (INT_SUM[524]), .DATA_B (INT_SUM[525]), .DATA_C (INT_CARRY[415]), .SAVE (INT_SUM[526]), .CARRY (INT_CARRY[416]) );
smffb dla573 (.D(INT_SUM[526]), .clk(clk), .en_d2(en_d2), .Q(SUM[44]) );
smffb dla574 (.D(INT_CARRY[416]), .clk(clk), .en_d2(en_d2), .Q(CARRY[44]) );
smffa dla575 (.D(SUMMAND[486]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[486]) );
smffa dla576 (.D(SUMMAND[487]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[487]) );
smffa dla577 (.D(SUMMAND[488]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[488]) );
smfulladder dfa387 (.DATA_A (LATCHED_PP[486]), .DATA_B (LATCHED_PP[487]), .DATA_C (LATCHED_PP[488]), .SAVE (INT_SUM[527]), .CARRY (INT_CARRY[428]) );
smffa dla578 (.D(SUMMAND[489]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[489]) );
smffa dla579 (.D(SUMMAND[490]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[490]) );
smffa dla580 (.D(SUMMAND[491]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[491]) );
smfulladder dfa388 (.DATA_A (LATCHED_PP[489]), .DATA_B (LATCHED_PP[490]), .DATA_C (LATCHED_PP[491]), .SAVE (INT_SUM[528]), .CARRY (INT_CARRY[429]) );
smffa dla581 (.D(SUMMAND[492]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[492]) );
smffa dla582 (.D(SUMMAND[493]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[493]) );
smffa dla583 (.D(SUMMAND[494]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[494]) );
smfulladder dfa389 (.DATA_A (LATCHED_PP[492]), .DATA_B (LATCHED_PP[493]), .DATA_C (LATCHED_PP[494]), .SAVE (INT_SUM[529]), .CARRY (INT_CARRY[430]) );
smffa dla584 (.D(SUMMAND[495]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[495]) );
smffa dla585 (.D(SUMMAND[496]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[496]) );
smffa dla586 (.D(SUMMAND[497]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[497]) );
smfulladder dfa390 (.DATA_A (LATCHED_PP[495]), .DATA_B (LATCHED_PP[496]), .DATA_C (LATCHED_PP[497]), .SAVE (INT_SUM[530]), .CARRY (INT_CARRY[431]) );
smfulladder dfa391 (.DATA_A (INT_SUM[527]), .DATA_B (INT_SUM[528]), .DATA_C (INT_SUM[529]), .SAVE (INT_SUM[531]), .CARRY (INT_CARRY[432]) );
smfulladder dfa392 (.DATA_A (INT_SUM[530]), .DATA_B (INT_CARRY[417]), .DATA_C (INT_CARRY[418]), .SAVE (INT_SUM[532]), .CARRY (INT_CARRY[433]) );
smhalfadder dha40 (.DATA_A (INT_CARRY[419]), .DATA_B (INT_CARRY[420]), .SAVE (INT_SUM[533]), .CARRY (INT_CARRY[434]) );
smfulladder dfa393 (.DATA_A (INT_SUM[531]), .DATA_B (INT_SUM[532]), .DATA_C (INT_SUM[533]), .SAVE (INT_SUM[534]), .CARRY (INT_CARRY[435]) );
smfulladder dfa394 (.DATA_A (INT_CARRY[421]), .DATA_B (INT_CARRY[422]), .DATA_C (INT_CARRY[423]), .SAVE (INT_SUM[535]), .CARRY (INT_CARRY[436]) );
smfulladder dfa395 (.DATA_A (INT_SUM[534]), .DATA_B (INT_SUM[535]), .DATA_C (INT_CARRY[424]), .SAVE (INT_SUM[536]), .CARRY (INT_CARRY[437]) );
assign INT_SUM[537] = INT_CARRY[425];
smfulladder dfa396 (.DATA_A (INT_SUM[536]), .DATA_B (INT_SUM[537]), .DATA_C (INT_CARRY[426]), .SAVE (INT_SUM[538]), .CARRY (INT_CARRY[427]) );
smffb dla587 (.D(INT_SUM[538]), .clk(clk), .en_d2(en_d2), .Q(SUM[45]) );
smffb dla588 (.D(INT_CARRY[427]), .clk(clk), .en_d2(en_d2), .Q(CARRY[45]) );
smffa dla589 (.D(SUMMAND[498]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[498]) );
smffa dla590 (.D(SUMMAND[499]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[499]) );
smffa dla591 (.D(SUMMAND[500]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[500]) );
smfulladder dfa397 (.DATA_A (LATCHED_PP[498]), .DATA_B (LATCHED_PP[499]), .DATA_C (LATCHED_PP[500]), .SAVE (INT_SUM[539]), .CARRY (INT_CARRY[439]) );
smffa dla592 (.D(SUMMAND[501]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[501]) );
smffa dla593 (.D(SUMMAND[502]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[502]) );
smffa dla594 (.D(SUMMAND[503]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[503]) );
smfulladder dfa398 (.DATA_A (LATCHED_PP[501]), .DATA_B (LATCHED_PP[502]), .DATA_C (LATCHED_PP[503]), .SAVE (INT_SUM[540]), .CARRY (INT_CARRY[440]) );
smffa dla595 (.D(SUMMAND[504]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[504]) );
smffa dla596 (.D(SUMMAND[505]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[505]) );
smffa dla597 (.D(SUMMAND[506]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[506]) );
smfulladder dfa399 (.DATA_A (LATCHED_PP[504]), .DATA_B (LATCHED_PP[505]), .DATA_C (LATCHED_PP[506]), .SAVE (INT_SUM[541]), .CARRY (INT_CARRY[441]) );
smffa dla598 (.D(SUMMAND[507]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[507]) );
assign INT_SUM[542] = LATCHED_PP[507];
smffa dla599 (.D(SUMMAND[508]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[508]) );
assign INT_SUM[543] = LATCHED_PP[508];
smfulladder dfa400 (.DATA_A (INT_SUM[539]), .DATA_B (INT_SUM[540]), .DATA_C (INT_SUM[541]), .SAVE (INT_SUM[544]), .CARRY (INT_CARRY[442]) );
smfulladder dfa401 (.DATA_A (INT_SUM[542]), .DATA_B (INT_SUM[543]), .DATA_C (INT_CARRY[428]), .SAVE (INT_SUM[545]), .CARRY (INT_CARRY[443]) );
smfulladder dfa402 (.DATA_A (INT_CARRY[429]), .DATA_B (INT_CARRY[430]), .DATA_C (INT_CARRY[431]), .SAVE (INT_SUM[546]), .CARRY (INT_CARRY[444]) );
smfulladder dfa403 (.DATA_A (INT_SUM[544]), .DATA_B (INT_SUM[545]), .DATA_C (INT_SUM[546]), .SAVE (INT_SUM[547]), .CARRY (INT_CARRY[445]) );
smfulladder dfa404 (.DATA_A (INT_CARRY[432]), .DATA_B (INT_CARRY[433]), .DATA_C (INT_CARRY[434]), .SAVE (INT_SUM[548]), .CARRY (INT_CARRY[446]) );
smfulladder dfa405 (.DATA_A (INT_SUM[547]), .DATA_B (INT_SUM[548]), .DATA_C (INT_CARRY[435]), .SAVE (INT_SUM[549]), .CARRY (INT_CARRY[447]) );
assign INT_SUM[550] = INT_CARRY[436];
smfulladder dfa406 (.DATA_A (INT_SUM[549]), .DATA_B (INT_SUM[550]), .DATA_C (INT_CARRY[437]), .SAVE (INT_SUM[551]), .CARRY (INT_CARRY[438]) );
smffb dla600 (.D(INT_SUM[551]), .clk(clk), .en_d2(en_d2), .Q(SUM[46]) );
smffb dla601 (.D(INT_CARRY[438]), .clk(clk), .en_d2(en_d2), .Q(CARRY[46]) );
smffa dla602 (.D(SUMMAND[509]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[509]) );
smffa dla603 (.D(SUMMAND[510]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[510]) );
smffa dla604 (.D(SUMMAND[511]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[511]) );
smfulladder dfa407 (.DATA_A (LATCHED_PP[509]), .DATA_B (LATCHED_PP[510]), .DATA_C (LATCHED_PP[511]), .SAVE (INT_SUM[552]), .CARRY (INT_CARRY[449]) );
smffa dla605 (.D(SUMMAND[512]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[512]) );
smffa dla606 (.D(SUMMAND[513]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[513]) );
smffa dla607 (.D(SUMMAND[514]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[514]) );
smfulladder dfa408 (.DATA_A (LATCHED_PP[512]), .DATA_B (LATCHED_PP[513]), .DATA_C (LATCHED_PP[514]), .SAVE (INT_SUM[553]), .CARRY (INT_CARRY[450]) );
smffa dla608 (.D(SUMMAND[515]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[515]) );
smffa dla609 (.D(SUMMAND[516]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[516]) );
smffa dla610 (.D(SUMMAND[517]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[517]) );
smfulladder dfa409 (.DATA_A (LATCHED_PP[515]), .DATA_B (LATCHED_PP[516]), .DATA_C (LATCHED_PP[517]), .SAVE (INT_SUM[554]), .CARRY (INT_CARRY[451]) );
smffa dla611 (.D(SUMMAND[518]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[518]) );
smffa dla612 (.D(SUMMAND[519]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[519]) );
smhalfadder dha41 (.DATA_A (LATCHED_PP[518]), .DATA_B (LATCHED_PP[519]), .SAVE (INT_SUM[555]), .CARRY (INT_CARRY[452]) );
smfulladder dfa410 (.DATA_A (INT_SUM[552]), .DATA_B (INT_SUM[553]), .DATA_C (INT_SUM[554]), .SAVE (INT_SUM[556]), .CARRY (INT_CARRY[453]) );
smfulladder dfa411 (.DATA_A (INT_SUM[555]), .DATA_B (INT_CARRY[439]), .DATA_C (INT_CARRY[440]), .SAVE (INT_SUM[557]), .CARRY (INT_CARRY[454]) );
assign INT_SUM[558] = INT_CARRY[441];
smfulladder dfa412 (.DATA_A (INT_SUM[556]), .DATA_B (INT_SUM[557]), .DATA_C (INT_SUM[558]), .SAVE (INT_SUM[559]), .CARRY (INT_CARRY[455]) );
smfulladder dfa413 (.DATA_A (INT_CARRY[442]), .DATA_B (INT_CARRY[443]), .DATA_C (INT_CARRY[444]), .SAVE (INT_SUM[560]), .CARRY (INT_CARRY[456]) );
smfulladder dfa414 (.DATA_A (INT_SUM[559]), .DATA_B (INT_SUM[560]), .DATA_C (INT_CARRY[445]), .SAVE (INT_SUM[561]), .CARRY (INT_CARRY[457]) );
assign INT_SUM[562] = INT_CARRY[446];
smfulladder dfa415 (.DATA_A (INT_SUM[561]), .DATA_B (INT_SUM[562]), .DATA_C (INT_CARRY[447]), .SAVE (INT_SUM[563]), .CARRY (INT_CARRY[448]) );
smffb dla613 (.D(INT_SUM[563]), .clk(clk), .en_d2(en_d2), .Q(SUM[47]) );
smffb dla614 (.D(INT_CARRY[448]), .clk(clk), .en_d2(en_d2), .Q(CARRY[47]) );
smffa dla615 (.D(SUMMAND[520]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[520]) );
smffa dla616 (.D(SUMMAND[521]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[521]) );
smffa dla617 (.D(SUMMAND[522]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[522]) );
smfulladder dfa416 (.DATA_A (LATCHED_PP[520]), .DATA_B (LATCHED_PP[521]), .DATA_C (LATCHED_PP[522]), .SAVE (INT_SUM[564]), .CARRY (INT_CARRY[459]) );
smffa dla618 (.D(SUMMAND[523]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[523]) );
smffa dla619 (.D(SUMMAND[524]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[524]) );
smffa dla620 (.D(SUMMAND[525]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[525]) );
smfulladder dfa417 (.DATA_A (LATCHED_PP[523]), .DATA_B (LATCHED_PP[524]), .DATA_C (LATCHED_PP[525]), .SAVE (INT_SUM[565]), .CARRY (INT_CARRY[460]) );
smffa dla621 (.D(SUMMAND[526]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[526]) );
smffa dla622 (.D(SUMMAND[527]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[527]) );
smffa dla623 (.D(SUMMAND[528]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[528]) );
smfulladder dfa418 (.DATA_A (LATCHED_PP[526]), .DATA_B (LATCHED_PP[527]), .DATA_C (LATCHED_PP[528]), .SAVE (INT_SUM[566]), .CARRY (INT_CARRY[461]) );
smffa dla624 (.D(SUMMAND[529]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[529]) );
assign INT_SUM[567] = LATCHED_PP[529];
smfulladder dfa419 (.DATA_A (INT_SUM[564]), .DATA_B (INT_SUM[565]), .DATA_C (INT_SUM[566]), .SAVE (INT_SUM[568]), .CARRY (INT_CARRY[462]) );
smfulladder dfa420 (.DATA_A (INT_SUM[567]), .DATA_B (INT_CARRY[449]), .DATA_C (INT_CARRY[450]), .SAVE (INT_SUM[569]), .CARRY (INT_CARRY[463]) );
assign INT_SUM[570] = INT_CARRY[451];
assign INT_SUM[571] = INT_CARRY[452];
smfulladder dfa421 (.DATA_A (INT_SUM[568]), .DATA_B (INT_SUM[569]), .DATA_C (INT_SUM[570]), .SAVE (INT_SUM[572]), .CARRY (INT_CARRY[464]) );
smfulladder dfa422 (.DATA_A (INT_SUM[571]), .DATA_B (INT_CARRY[453]), .DATA_C (INT_CARRY[454]), .SAVE (INT_SUM[573]), .CARRY (INT_CARRY[465]) );
smfulladder dfa423 (.DATA_A (INT_SUM[572]), .DATA_B (INT_SUM[573]), .DATA_C (INT_CARRY[455]), .SAVE (INT_SUM[574]), .CARRY (INT_CARRY[466]) );
assign INT_SUM[575] = INT_CARRY[456];
smfulladder dfa424 (.DATA_A (INT_SUM[574]), .DATA_B (INT_SUM[575]), .DATA_C (INT_CARRY[457]), .SAVE (INT_SUM[576]), .CARRY (INT_CARRY[458]) );
smffb dla625 (.D(INT_SUM[576]), .clk(clk), .en_d2(en_d2), .Q(SUM[48]) );
smffb dla626 (.D(INT_CARRY[458]), .clk(clk), .en_d2(en_d2), .Q(CARRY[48]) );
smffa dla627 (.D(SUMMAND[530]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[530]) );
smffa dla628 (.D(SUMMAND[531]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[531]) );
smffa dla629 (.D(SUMMAND[532]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[532]) );
smfulladder dfa425 (.DATA_A (LATCHED_PP[530]), .DATA_B (LATCHED_PP[531]), .DATA_C (LATCHED_PP[532]), .SAVE (INT_SUM[577]), .CARRY (INT_CARRY[468]) );
smffa dla630 (.D(SUMMAND[533]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[533]) );
smffa dla631 (.D(SUMMAND[534]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[534]) );
smffa dla632 (.D(SUMMAND[535]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[535]) );
smfulladder dfa426 (.DATA_A (LATCHED_PP[533]), .DATA_B (LATCHED_PP[534]), .DATA_C (LATCHED_PP[535]), .SAVE (INT_SUM[578]), .CARRY (INT_CARRY[469]) );
smffa dla633 (.D(SUMMAND[536]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[536]) );
smffa dla634 (.D(SUMMAND[537]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[537]) );
smffa dla635 (.D(SUMMAND[538]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[538]) );
smfulladder dfa427 (.DATA_A (LATCHED_PP[536]), .DATA_B (LATCHED_PP[537]), .DATA_C (LATCHED_PP[538]), .SAVE (INT_SUM[579]), .CARRY (INT_CARRY[470]) );
smffa dla636 (.D(SUMMAND[539]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[539]) );
assign INT_SUM[580] = LATCHED_PP[539];
smfulladder dfa428 (.DATA_A (INT_SUM[577]), .DATA_B (INT_SUM[578]), .DATA_C (INT_SUM[579]), .SAVE (INT_SUM[581]), .CARRY (INT_CARRY[471]) );
smfulladder dfa429 (.DATA_A (INT_SUM[580]), .DATA_B (INT_CARRY[459]), .DATA_C (INT_CARRY[460]), .SAVE (INT_SUM[582]), .CARRY (INT_CARRY[472]) );
assign INT_SUM[583] = INT_CARRY[461];
smfulladder dfa430 (.DATA_A (INT_SUM[581]), .DATA_B (INT_SUM[582]), .DATA_C (INT_SUM[583]), .SAVE (INT_SUM[584]), .CARRY (INT_CARRY[473]) );
smhalfadder dha42 (.DATA_A (INT_CARRY[462]), .DATA_B (INT_CARRY[463]), .SAVE (INT_SUM[585]), .CARRY (INT_CARRY[474]) );
smfulladder dfa431 (.DATA_A (INT_SUM[584]), .DATA_B (INT_SUM[585]), .DATA_C (INT_CARRY[464]), .SAVE (INT_SUM[586]), .CARRY (INT_CARRY[475]) );
assign INT_SUM[587] = INT_CARRY[465];
smfulladder dfa432 (.DATA_A (INT_SUM[586]), .DATA_B (INT_SUM[587]), .DATA_C (INT_CARRY[466]), .SAVE (INT_SUM[588]), .CARRY (INT_CARRY[467]) );
smffb dla637 (.D(INT_SUM[588]), .clk(clk), .en_d2(en_d2), .Q(SUM[49]) );
smffb dla638 (.D(INT_CARRY[467]), .clk(clk), .en_d2(en_d2), .Q(CARRY[49]) );
smffa dla639 (.D(SUMMAND[540]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[540]) );
smffa dla640 (.D(SUMMAND[541]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[541]) );
smffa dla641 (.D(SUMMAND[542]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[542]) );
smfulladder dfa433 (.DATA_A (LATCHED_PP[540]), .DATA_B (LATCHED_PP[541]), .DATA_C (LATCHED_PP[542]), .SAVE (INT_SUM[589]), .CARRY (INT_CARRY[477]) );
smffa dla642 (.D(SUMMAND[543]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[543]) );
smffa dla643 (.D(SUMMAND[544]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[544]) );
smffa dla644 (.D(SUMMAND[545]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[545]) );
smfulladder dfa434 (.DATA_A (LATCHED_PP[543]), .DATA_B (LATCHED_PP[544]), .DATA_C (LATCHED_PP[545]), .SAVE (INT_SUM[590]), .CARRY (INT_CARRY[478]) );
smffa dla645 (.D(SUMMAND[546]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[546]) );
smffa dla646 (.D(SUMMAND[547]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[547]) );
smffa dla647 (.D(SUMMAND[548]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[548]) );
smfulladder dfa435 (.DATA_A (LATCHED_PP[546]), .DATA_B (LATCHED_PP[547]), .DATA_C (LATCHED_PP[548]), .SAVE (INT_SUM[591]), .CARRY (INT_CARRY[479]) );
smfulladder dfa436 (.DATA_A (INT_SUM[589]), .DATA_B (INT_SUM[590]), .DATA_C (INT_SUM[591]), .SAVE (INT_SUM[592]), .CARRY (INT_CARRY[480]) );
smfulladder dfa437 (.DATA_A (INT_CARRY[468]), .DATA_B (INT_CARRY[469]), .DATA_C (INT_CARRY[470]), .SAVE (INT_SUM[593]), .CARRY (INT_CARRY[481]) );
smfulladder dfa438 (.DATA_A (INT_SUM[592]), .DATA_B (INT_SUM[593]), .DATA_C (INT_CARRY[471]), .SAVE (INT_SUM[594]), .CARRY (INT_CARRY[482]) );
assign INT_SUM[595] = INT_CARRY[472];
smfulladder dfa439 (.DATA_A (INT_SUM[594]), .DATA_B (INT_SUM[595]), .DATA_C (INT_CARRY[473]), .SAVE (INT_SUM[596]), .CARRY (INT_CARRY[483]) );
assign INT_SUM[597] = INT_CARRY[474];
smfulladder dfa440 (.DATA_A (INT_SUM[596]), .DATA_B (INT_SUM[597]), .DATA_C (INT_CARRY[475]), .SAVE (INT_SUM[598]), .CARRY (INT_CARRY[476]) );
smffb dla648 (.D(INT_SUM[598]), .clk(clk), .en_d2(en_d2), .Q(SUM[50]) );
smffb dla649 (.D(INT_CARRY[476]), .clk(clk), .en_d2(en_d2), .Q(CARRY[50]) );
smffa dla650 (.D(SUMMAND[549]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[549]) );
smffa dla651 (.D(SUMMAND[550]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[550]) );
smffa dla652 (.D(SUMMAND[551]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[551]) );
smfulladder dfa441 (.DATA_A (LATCHED_PP[549]), .DATA_B (LATCHED_PP[550]), .DATA_C (LATCHED_PP[551]), .SAVE (INT_SUM[599]), .CARRY (INT_CARRY[485]) );
smffa dla653 (.D(SUMMAND[552]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[552]) );
smffa dla654 (.D(SUMMAND[553]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[553]) );
smffa dla655 (.D(SUMMAND[554]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[554]) );
smfulladder dfa442 (.DATA_A (LATCHED_PP[552]), .DATA_B (LATCHED_PP[553]), .DATA_C (LATCHED_PP[554]), .SAVE (INT_SUM[600]), .CARRY (INT_CARRY[486]) );
smffa dla656 (.D(SUMMAND[555]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[555]) );
smffa dla657 (.D(SUMMAND[556]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[556]) );
smffa dla658 (.D(SUMMAND[557]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[557]) );
smfulladder dfa443 (.DATA_A (LATCHED_PP[555]), .DATA_B (LATCHED_PP[556]), .DATA_C (LATCHED_PP[557]), .SAVE (INT_SUM[601]), .CARRY (INT_CARRY[487]) );
smfulladder dfa444 (.DATA_A (INT_SUM[599]), .DATA_B (INT_SUM[600]), .DATA_C (INT_SUM[601]), .SAVE (INT_SUM[602]), .CARRY (INT_CARRY[488]) );
smfulladder dfa445 (.DATA_A (INT_CARRY[477]), .DATA_B (INT_CARRY[478]), .DATA_C (INT_CARRY[479]), .SAVE (INT_SUM[603]), .CARRY (INT_CARRY[489]) );
smfulladder dfa446 (.DATA_A (INT_SUM[602]), .DATA_B (INT_SUM[603]), .DATA_C (INT_CARRY[480]), .SAVE (INT_SUM[604]), .CARRY (INT_CARRY[490]) );
assign INT_SUM[605] = INT_CARRY[481];
smfulladder dfa447 (.DATA_A (INT_SUM[604]), .DATA_B (INT_SUM[605]), .DATA_C (INT_CARRY[482]), .SAVE (INT_SUM[606]), .CARRY (INT_CARRY[491]) );
smhalfadder dha43 (.DATA_A (INT_SUM[606]), .DATA_B (INT_CARRY[483]), .SAVE (INT_SUM[607]), .CARRY (INT_CARRY[484]) );
smffb dla659 (.D(INT_SUM[607]), .clk(clk), .en_d2(en_d2), .Q(SUM[51]) );
smffb dla660 (.D(INT_CARRY[484]), .clk(clk), .en_d2(en_d2), .Q(CARRY[51]) );
smffa dla661 (.D(SUMMAND[558]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[558]) );
smffa dla662 (.D(SUMMAND[559]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[559]) );
smffa dla663 (.D(SUMMAND[560]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[560]) );
smfulladder dfa448 (.DATA_A (LATCHED_PP[558]), .DATA_B (LATCHED_PP[559]), .DATA_C (LATCHED_PP[560]), .SAVE (INT_SUM[608]), .CARRY (INT_CARRY[493]) );
smffa dla664 (.D(SUMMAND[561]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[561]) );
smffa dla665 (.D(SUMMAND[562]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[562]) );
smffa dla666 (.D(SUMMAND[563]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[563]) );
smfulladder dfa449 (.DATA_A (LATCHED_PP[561]), .DATA_B (LATCHED_PP[562]), .DATA_C (LATCHED_PP[563]), .SAVE (INT_SUM[609]), .CARRY (INT_CARRY[494]) );
smffa dla667 (.D(SUMMAND[564]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[564]) );
smffa dla668 (.D(SUMMAND[565]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[565]) );
smfulladder dfa450 (.DATA_A (LATCHED_PP[564]), .DATA_B (LATCHED_PP[565]), .DATA_C (INT_CARRY[485]), .SAVE (INT_SUM[610]), .CARRY (INT_CARRY[495]) );
smhalfadder dha44 (.DATA_A (INT_CARRY[486]), .DATA_B (INT_CARRY[487]), .SAVE (INT_SUM[611]), .CARRY (INT_CARRY[496]) );
smfulladder dfa451 (.DATA_A (INT_SUM[608]), .DATA_B (INT_SUM[609]), .DATA_C (INT_SUM[610]), .SAVE (INT_SUM[612]), .CARRY (INT_CARRY[497]) );
smfulladder dfa452 (.DATA_A (INT_SUM[611]), .DATA_B (INT_CARRY[488]), .DATA_C (INT_CARRY[489]), .SAVE (INT_SUM[613]), .CARRY (INT_CARRY[498]) );
smfulladder dfa453 (.DATA_A (INT_SUM[612]), .DATA_B (INT_SUM[613]), .DATA_C (INT_CARRY[490]), .SAVE (INT_SUM[614]), .CARRY (INT_CARRY[499]) );
smhalfadder dha45 (.DATA_A (INT_SUM[614]), .DATA_B (INT_CARRY[491]), .SAVE (INT_SUM[615]), .CARRY (INT_CARRY[492]) );
smffb dla669 (.D(INT_SUM[615]), .clk(clk), .en_d2(en_d2), .Q(SUM[52]) );
smffb dla670 (.D(INT_CARRY[492]), .clk(clk), .en_d2(en_d2), .Q(CARRY[52]) );
smffa dla671 (.D(SUMMAND[566]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[566]) );
smffa dla672 (.D(SUMMAND[567]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[567]) );
smffa dla673 (.D(SUMMAND[568]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[568]) );
smfulladder dfa454 (.DATA_A (LATCHED_PP[566]), .DATA_B (LATCHED_PP[567]), .DATA_C (LATCHED_PP[568]), .SAVE (INT_SUM[616]), .CARRY (INT_CARRY[501]) );
smffa dla674 (.D(SUMMAND[569]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[569]) );
smffa dla675 (.D(SUMMAND[570]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[570]) );
smffa dla676 (.D(SUMMAND[571]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[571]) );
smfulladder dfa455 (.DATA_A (LATCHED_PP[569]), .DATA_B (LATCHED_PP[570]), .DATA_C (LATCHED_PP[571]), .SAVE (INT_SUM[617]), .CARRY (INT_CARRY[502]) );
smffa dla677 (.D(SUMMAND[572]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[572]) );
assign INT_SUM[618] = LATCHED_PP[572];
smffa dla678 (.D(SUMMAND[573]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[573]) );
assign INT_SUM[619] = LATCHED_PP[573];
smfulladder dfa456 (.DATA_A (INT_SUM[616]), .DATA_B (INT_SUM[617]), .DATA_C (INT_SUM[618]), .SAVE (INT_SUM[620]), .CARRY (INT_CARRY[503]) );
assign INT_SUM[621] = INT_SUM[619];
smfulladder dfa457 (.DATA_A (INT_SUM[620]), .DATA_B (INT_SUM[621]), .DATA_C (INT_CARRY[493]), .SAVE (INT_SUM[622]), .CARRY (INT_CARRY[504]) );
smfulladder dfa458 (.DATA_A (INT_CARRY[494]), .DATA_B (INT_CARRY[495]), .DATA_C (INT_CARRY[496]), .SAVE (INT_SUM[623]), .CARRY (INT_CARRY[505]) );
smfulladder dfa459 (.DATA_A (INT_SUM[622]), .DATA_B (INT_SUM[623]), .DATA_C (INT_CARRY[497]), .SAVE (INT_SUM[624]), .CARRY (INT_CARRY[506]) );
assign INT_SUM[625] = INT_CARRY[498];
smfulladder dfa460 (.DATA_A (INT_SUM[624]), .DATA_B (INT_SUM[625]), .DATA_C (INT_CARRY[499]), .SAVE (INT_SUM[626]), .CARRY (INT_CARRY[500]) );
smffb dla679 (.D(INT_SUM[626]), .clk(clk), .en_d2(en_d2), .Q(SUM[53]) );
smffb dla680 (.D(INT_CARRY[500]), .clk(clk), .en_d2(en_d2), .Q(CARRY[53]) );
smffa dla681 (.D(SUMMAND[574]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[574]) );
smffa dla682 (.D(SUMMAND[575]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[575]) );
smffa dla683 (.D(SUMMAND[576]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[576]) );
smfulladder dfa461 (.DATA_A (LATCHED_PP[574]), .DATA_B (LATCHED_PP[575]), .DATA_C (LATCHED_PP[576]), .SAVE (INT_SUM[627]), .CARRY (INT_CARRY[508]) );
smffa dla684 (.D(SUMMAND[577]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[577]) );
smffa dla685 (.D(SUMMAND[578]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[578]) );
smffa dla686 (.D(SUMMAND[579]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[579]) );
smfulladder dfa462 (.DATA_A (LATCHED_PP[577]), .DATA_B (LATCHED_PP[578]), .DATA_C (LATCHED_PP[579]), .SAVE (INT_SUM[628]), .CARRY (INT_CARRY[509]) );
smffa dla687 (.D(SUMMAND[580]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[580]) );
smfulladder dfa463 (.DATA_A (LATCHED_PP[580]), .DATA_B (INT_CARRY[501]), .DATA_C (INT_CARRY[502]), .SAVE (INT_SUM[629]), .CARRY (INT_CARRY[510]) );
smfulladder dfa464 (.DATA_A (INT_SUM[627]), .DATA_B (INT_SUM[628]), .DATA_C (INT_SUM[629]), .SAVE (INT_SUM[630]), .CARRY (INT_CARRY[511]) );
assign INT_SUM[631] = INT_CARRY[503];
smfulladder dfa465 (.DATA_A (INT_SUM[630]), .DATA_B (INT_SUM[631]), .DATA_C (INT_CARRY[504]), .SAVE (INT_SUM[632]), .CARRY (INT_CARRY[512]) );
assign INT_SUM[633] = INT_CARRY[505];
smfulladder dfa466 (.DATA_A (INT_SUM[632]), .DATA_B (INT_SUM[633]), .DATA_C (INT_CARRY[506]), .SAVE (INT_SUM[634]), .CARRY (INT_CARRY[507]) );
smffb dla688 (.D(INT_SUM[634]), .clk(clk), .en_d2(en_d2), .Q(SUM[54]) );
smffb dla689 (.D(INT_CARRY[507]), .clk(clk), .en_d2(en_d2), .Q(CARRY[54]) );
smffa dla690 (.D(SUMMAND[581]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[581]) );
smffa dla691 (.D(SUMMAND[582]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[582]) );
smffa dla692 (.D(SUMMAND[583]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[583]) );
smfulladder dfa467 (.DATA_A (LATCHED_PP[581]), .DATA_B (LATCHED_PP[582]), .DATA_C (LATCHED_PP[583]), .SAVE (INT_SUM[635]), .CARRY (INT_CARRY[514]) );
smffa dla693 (.D(SUMMAND[584]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[584]) );
smffa dla694 (.D(SUMMAND[585]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[585]) );
smffa dla695 (.D(SUMMAND[586]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[586]) );
smfulladder dfa468 (.DATA_A (LATCHED_PP[584]), .DATA_B (LATCHED_PP[585]), .DATA_C (LATCHED_PP[586]), .SAVE (INT_SUM[636]), .CARRY (INT_CARRY[515]) );
smffa dla696 (.D(SUMMAND[587]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[587]) );
assign INT_SUM[637] = LATCHED_PP[587];
smfulladder dfa469 (.DATA_A (INT_SUM[635]), .DATA_B (INT_SUM[636]), .DATA_C (INT_SUM[637]), .SAVE (INT_SUM[638]), .CARRY (INT_CARRY[516]) );
smfulladder dfa470 (.DATA_A (INT_CARRY[508]), .DATA_B (INT_CARRY[509]), .DATA_C (INT_CARRY[510]), .SAVE (INT_SUM[639]), .CARRY (INT_CARRY[517]) );
smfulladder dfa471 (.DATA_A (INT_SUM[638]), .DATA_B (INT_SUM[639]), .DATA_C (INT_CARRY[511]), .SAVE (INT_SUM[640]), .CARRY (INT_CARRY[518]) );
smhalfadder dha46 (.DATA_A (INT_SUM[640]), .DATA_B (INT_CARRY[512]), .SAVE (INT_SUM[641]), .CARRY (INT_CARRY[513]) );
smffb dla697 (.D(INT_SUM[641]), .clk(clk), .en_d2(en_d2), .Q(SUM[55]) );
smffb dla698 (.D(INT_CARRY[513]), .clk(clk), .en_d2(en_d2), .Q(CARRY[55]) );
smffa dla699 (.D(SUMMAND[588]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[588]) );
smffa dla700 (.D(SUMMAND[589]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[589]) );
smffa dla701 (.D(SUMMAND[590]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[590]) );
smfulladder dfa472 (.DATA_A (LATCHED_PP[588]), .DATA_B (LATCHED_PP[589]), .DATA_C (LATCHED_PP[590]), .SAVE (INT_SUM[642]), .CARRY (INT_CARRY[520]) );
smffa dla702 (.D(SUMMAND[591]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[591]) );
smffa dla703 (.D(SUMMAND[592]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[592]) );
smffa dla704 (.D(SUMMAND[593]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[593]) );
smfulladder dfa473 (.DATA_A (LATCHED_PP[591]), .DATA_B (LATCHED_PP[592]), .DATA_C (LATCHED_PP[593]), .SAVE (INT_SUM[643]), .CARRY (INT_CARRY[521]) );
smfulladder dfa474 (.DATA_A (INT_SUM[642]), .DATA_B (INT_SUM[643]), .DATA_C (INT_CARRY[514]), .SAVE (INT_SUM[644]), .CARRY (INT_CARRY[522]) );
assign INT_SUM[645] = INT_CARRY[515];
smfulladder dfa475 (.DATA_A (INT_SUM[644]), .DATA_B (INT_SUM[645]), .DATA_C (INT_CARRY[516]), .SAVE (INT_SUM[646]), .CARRY (INT_CARRY[523]) );
assign INT_SUM[647] = INT_CARRY[517];
smfulladder dfa476 (.DATA_A (INT_SUM[646]), .DATA_B (INT_SUM[647]), .DATA_C (INT_CARRY[518]), .SAVE (INT_SUM[648]), .CARRY (INT_CARRY[519]) );
smffb dla705 (.D(INT_SUM[648]), .clk(clk), .en_d2(en_d2), .Q(SUM[56]) );
smffb dla706 (.D(INT_CARRY[519]), .clk(clk), .en_d2(en_d2), .Q(CARRY[56]) );
smffa dla707 (.D(SUMMAND[594]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[594]) );
smffa dla708 (.D(SUMMAND[595]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[595]) );
smffa dla709 (.D(SUMMAND[596]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[596]) );
smfulladder dfa477 (.DATA_A (LATCHED_PP[594]), .DATA_B (LATCHED_PP[595]), .DATA_C (LATCHED_PP[596]), .SAVE (INT_SUM[649]), .CARRY (INT_CARRY[525]) );
smffa dla710 (.D(SUMMAND[597]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[597]) );
smffa dla711 (.D(SUMMAND[598]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[598]) );
smffa dla712 (.D(SUMMAND[599]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[599]) );
smfulladder dfa478 (.DATA_A (LATCHED_PP[597]), .DATA_B (LATCHED_PP[598]), .DATA_C (LATCHED_PP[599]), .SAVE (INT_SUM[650]), .CARRY (INT_CARRY[526]) );
smfulladder dfa479 (.DATA_A (INT_SUM[649]), .DATA_B (INT_SUM[650]), .DATA_C (INT_CARRY[520]), .SAVE (INT_SUM[651]), .CARRY (INT_CARRY[527]) );
assign INT_SUM[652] = INT_CARRY[521];
smfulladder dfa480 (.DATA_A (INT_SUM[651]), .DATA_B (INT_SUM[652]), .DATA_C (INT_CARRY[522]), .SAVE (INT_SUM[653]), .CARRY (INT_CARRY[528]) );
smhalfadder dha47 (.DATA_A (INT_SUM[653]), .DATA_B (INT_CARRY[523]), .SAVE (INT_SUM[654]), .CARRY (INT_CARRY[524]) );
smffb dla713 (.D(INT_SUM[654]), .clk(clk), .en_d2(en_d2), .Q(SUM[57]) );
smffb dla714 (.D(INT_CARRY[524]), .clk(clk), .en_d2(en_d2), .Q(CARRY[57]) );
smffa dla715 (.D(SUMMAND[600]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[600]) );
smffa dla716 (.D(SUMMAND[601]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[601]) );
smffa dla717 (.D(SUMMAND[602]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[602]) );
smfulladder dfa481 (.DATA_A (LATCHED_PP[600]), .DATA_B (LATCHED_PP[601]), .DATA_C (LATCHED_PP[602]), .SAVE (INT_SUM[655]), .CARRY (INT_CARRY[530]) );
smffa dla718 (.D(SUMMAND[603]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[603]) );
smffa dla719 (.D(SUMMAND[604]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[604]) );
smhalfadder dha48 (.DATA_A (LATCHED_PP[603]), .DATA_B (LATCHED_PP[604]), .SAVE (INT_SUM[656]), .CARRY (INT_CARRY[531]) );
smfulladder dfa482 (.DATA_A (INT_SUM[655]), .DATA_B (INT_SUM[656]), .DATA_C (INT_CARRY[525]), .SAVE (INT_SUM[657]), .CARRY (INT_CARRY[532]) );
assign INT_SUM[658] = INT_CARRY[526];
smfulladder dfa483 (.DATA_A (INT_SUM[657]), .DATA_B (INT_SUM[658]), .DATA_C (INT_CARRY[527]), .SAVE (INT_SUM[659]), .CARRY (INT_CARRY[533]) );
smhalfadder dha49 (.DATA_A (INT_SUM[659]), .DATA_B (INT_CARRY[528]), .SAVE (INT_SUM[660]), .CARRY (INT_CARRY[529]) );
smffb dla720 (.D(INT_SUM[660]), .clk(clk), .en_d2(en_d2), .Q(SUM[58]) );
smffb dla721 (.D(INT_CARRY[529]), .clk(clk), .en_d2(en_d2), .Q(CARRY[58]) );
smffa dla722 (.D(SUMMAND[605]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[605]) );
smffa dla723 (.D(SUMMAND[606]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[606]) );
smffa dla724 (.D(SUMMAND[607]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[607]) );
smfulladder dfa484 (.DATA_A (LATCHED_PP[605]), .DATA_B (LATCHED_PP[606]), .DATA_C (LATCHED_PP[607]), .SAVE (INT_SUM[661]), .CARRY (INT_CARRY[535]) );
smffa dla725 (.D(SUMMAND[608]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[608]) );
smffa dla726 (.D(SUMMAND[609]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[609]) );
smhalfadder dha50 (.DATA_A (LATCHED_PP[608]), .DATA_B (LATCHED_PP[609]), .SAVE (INT_SUM[662]), .CARRY (INT_CARRY[536]) );
smfulladder dfa485 (.DATA_A (INT_SUM[661]), .DATA_B (INT_SUM[662]), .DATA_C (INT_CARRY[530]), .SAVE (INT_SUM[663]), .CARRY (INT_CARRY[537]) );
assign INT_SUM[664] = INT_CARRY[531];
smfulladder dfa486 (.DATA_A (INT_SUM[663]), .DATA_B (INT_SUM[664]), .DATA_C (INT_CARRY[532]), .SAVE (INT_SUM[665]), .CARRY (INT_CARRY[538]) );
smhalfadder dha51 (.DATA_A (INT_SUM[665]), .DATA_B (INT_CARRY[533]), .SAVE (INT_SUM[666]), .CARRY (INT_CARRY[534]) );
smffb dla727 (.D(INT_SUM[666]), .clk(clk), .en_d2(en_d2), .Q(SUM[59]) );
smffb dla728 (.D(INT_CARRY[534]), .clk(clk), .en_d2(en_d2), .Q(CARRY[59]) );
smffa dla729 (.D(SUMMAND[610]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[610]) );
smffa dla730 (.D(SUMMAND[611]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[611]) );
smffa dla731 (.D(SUMMAND[612]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[612]) );
smfulladder dfa487 (.DATA_A (LATCHED_PP[610]), .DATA_B (LATCHED_PP[611]), .DATA_C (LATCHED_PP[612]), .SAVE (INT_SUM[667]), .CARRY (INT_CARRY[540]) );
smffa dla732 (.D(SUMMAND[613]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[613]) );
smfulladder dfa488 (.DATA_A (LATCHED_PP[613]), .DATA_B (INT_CARRY[535]), .DATA_C (INT_CARRY[536]), .SAVE (INT_SUM[668]), .CARRY (INT_CARRY[541]) );
smfulladder dfa489 (.DATA_A (INT_SUM[667]), .DATA_B (INT_SUM[668]), .DATA_C (INT_CARRY[537]), .SAVE (INT_SUM[669]), .CARRY (INT_CARRY[542]) );
smhalfadder dha52 (.DATA_A (INT_SUM[669]), .DATA_B (INT_CARRY[538]), .SAVE (INT_SUM[670]), .CARRY (INT_CARRY[539]) );
smffb dla733 (.D(INT_SUM[670]), .clk(clk), .en_d2(en_d2), .Q(SUM[60]) );
smffb dla734 (.D(INT_CARRY[539]), .clk(clk), .en_d2(en_d2), .Q(CARRY[60]) );
smffa dla735 (.D(SUMMAND[614]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[614]) );
smffa dla736 (.D(SUMMAND[615]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[615]) );
smffa dla737 (.D(SUMMAND[616]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[616]) );
smfulladder dfa490 (.DATA_A (LATCHED_PP[614]), .DATA_B (LATCHED_PP[615]), .DATA_C (LATCHED_PP[616]), .SAVE (INT_SUM[671]), .CARRY (INT_CARRY[544]) );
smffa dla738 (.D(SUMMAND[617]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[617]) );
assign INT_SUM[672] = LATCHED_PP[617];
smfulladder dfa491 (.DATA_A (INT_SUM[671]), .DATA_B (INT_SUM[672]), .DATA_C (INT_CARRY[540]), .SAVE (INT_SUM[673]), .CARRY (INT_CARRY[545]) );
assign INT_SUM[674] = INT_CARRY[541];
smfulladder dfa492 (.DATA_A (INT_SUM[673]), .DATA_B (INT_SUM[674]), .DATA_C (INT_CARRY[542]), .SAVE (INT_SUM[675]), .CARRY (INT_CARRY[543]) );
smffb dla739 (.D(INT_SUM[675]), .clk(clk), .en_d2(en_d2), .Q(SUM[61]) );
smffb dla740 (.D(INT_CARRY[543]), .clk(clk), .en_d2(en_d2), .Q(CARRY[61]) );
smffa dla741 (.D(SUMMAND[618]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[618]) );
smffa dla742 (.D(SUMMAND[619]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[619]) );
smffa dla743 (.D(SUMMAND[620]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[620]) );
smfulladder dfa493 (.DATA_A (LATCHED_PP[618]), .DATA_B (LATCHED_PP[619]), .DATA_C (LATCHED_PP[620]), .SAVE (INT_SUM[676]), .CARRY (INT_CARRY[547]) );
assign INT_SUM[677] = INT_SUM[676];
assign INT_SUM[678] = INT_CARRY[544];
smfulladder dfa494 (.DATA_A (INT_SUM[677]), .DATA_B (INT_SUM[678]), .DATA_C (INT_CARRY[545]), .SAVE (INT_SUM[679]), .CARRY (INT_CARRY[546]) );
smffb dla744 (.D(INT_SUM[679]), .clk(clk), .en_d2(en_d2), .Q(SUM[62]) );
smffb dla745 (.D(INT_CARRY[546]), .clk(clk), .en_d2(en_d2), .Q(CARRY[62]) );
smffa dla746 (.D(SUMMAND[621]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[621]) );
smffa dla747 (.D(SUMMAND[622]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[622]) );
smffa dla748 (.D(SUMMAND[623]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[623]) );
smfulladder dfa495 (.DATA_A (LATCHED_PP[621]), .DATA_B (LATCHED_PP[622]), .DATA_C (LATCHED_PP[623]), .SAVE (INT_SUM[680]), .CARRY (INT_CARRY[549]) );
assign INT_SUM[681] = INT_CARRY[547];
smhalfadder dha53 (.DATA_A (INT_SUM[680]), .DATA_B (INT_SUM[681]), .SAVE (INT_SUM[682]), .CARRY (INT_CARRY[548]) );
smffb dla749 (.D(INT_SUM[682]), .clk(clk), .en_d2(en_d2), .Q(SUM[63]) );
smffb dla750 (.D(INT_CARRY[548]), .clk(clk), .en_d2(en_d2), .Q(CARRY[63]) );
smffa dla751 (.D(SUMMAND[624]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[624]) );
assign INT_SUM[683] = LATCHED_PP[624];
smffa dla752 (.D(SUMMAND[625]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[625]) );
assign INT_SUM[684] = LATCHED_PP[625];
smfulladder dfa496 (.DATA_A (INT_SUM[683]), .DATA_B (INT_SUM[684]), .DATA_C (INT_CARRY[549]), .SAVE (INT_SUM[685]), .CARRY (INT_CARRY[550]) );
smffb dla753 (.D(INT_SUM[685]), .clk(clk), .en_d2(en_d2), .Q(SUM[64]) );
smffb dla754 (.D(INT_CARRY[550]), .clk(clk), .en_d2(en_d2), .Q(CARRY[64]) );
smffa dla755 (.D(SUMMAND[626]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[626]) );
smffa dla756 (.D(SUMMAND[627]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[627]) );
smhalfadder dha54 (.DATA_A (LATCHED_PP[626]), .DATA_B (LATCHED_PP[627]), .SAVE (INT_SUM[686]), .CARRY (INT_CARRY[551]) );
smffb dla757 (.D(INT_SUM[686]), .clk(clk), .en_d2(en_d2), .Q(SUM[65]) );
smffb dla758 (.D(INT_CARRY[551]), .clk(clk), .en_d2(en_d2), .Q(CARRY[65]) );
smffa dla759 (.D(SUMMAND[628]), .clk(clk), .en_d1(en_d1), .Q(LATCHED_PP[628]) );
assign INT_SUM[687] = LATCHED_PP[628];
smffb dla760 (.D(INT_SUM[687]), .clk(clk), .en_d2(en_d2), .Q(SUM[66]) );
endmodule
module smprestage_128 ( A, B, CIN, POUT, GOUT );
input [63:0] A;
input [63:0] B;
input CIN;
output [63:0] POUT;
output [63:0] GOUT;
smblock0 d10 (A[0], B[0], POUT[0], GOUT[1] );
smblock0 d11 (A[1], B[1], POUT[1], GOUT[2] );
smblock0 d12 (A[2], B[2], POUT[2], GOUT[3] );
smblock0 d13 (A[3], B[3], POUT[3], GOUT[4] );
smblock0 d14 (A[4], B[4], POUT[4], GOUT[5] );
smblock0 d15 (A[5], B[5], POUT[5], GOUT[6] );
smblock0 d16 (A[6], B[6], POUT[6], GOUT[7] );
smblock0 d17 (A[7], B[7], POUT[7], GOUT[8] );
smblock0 d18 (A[8], B[8], POUT[8], GOUT[9] );
smblock0 d19 (A[9], B[9], POUT[9], GOUT[10] );
smblock0 d110 (A[10], B[10], POUT[10], GOUT[11] );
smblock0 d111 (A[11], B[11], POUT[11], GOUT[12] );
smblock0 d112 (A[12], B[12], POUT[12], GOUT[13] );
smblock0 d113 (A[13], B[13], POUT[13], GOUT[14] );
smblock0 d114 (A[14], B[14], POUT[14], GOUT[15] );
smblock0 d115 (A[15], B[15], POUT[15], GOUT[16] );
smblock0 d116 (A[16], B[16], POUT[16], GOUT[17] );
smblock0 d117 (A[17], B[17], POUT[17], GOUT[18] );
smblock0 d118 (A[18], B[18], POUT[18], GOUT[19] );
smblock0 d119 (A[19], B[19], POUT[19], GOUT[20] );
smblock0 d120 (A[20], B[20], POUT[20], GOUT[21] );
smblock0 d121 (A[21], B[21], POUT[21], GOUT[22] );
smblock0 d122 (A[22], B[22], POUT[22], GOUT[23] );
smblock0 d123 (A[23], B[23], POUT[23], GOUT[24] );
smblock0 d124 (A[24], B[24], POUT[24], GOUT[25] );
smblock0 d125 (A[25], B[25], POUT[25], GOUT[26] );
smblock0 d126 (A[26], B[26], POUT[26], GOUT[27] );
smblock0 d127 (A[27], B[27], POUT[27], GOUT[28] );
smblock0 d128 (A[28], B[28], POUT[28], GOUT[29] );
smblock0 d129 (A[29], B[29], POUT[29], GOUT[30] );
smblock0 d130 (A[30], B[30], POUT[30], GOUT[31] );
smblock0 d131 (A[31], B[31], POUT[31], GOUT[32] );
smblock0 d132 (A[32], B[32], POUT[32], GOUT[33] );
smblock0 d133 (A[33], B[33], POUT[33], GOUT[34] );
smblock0 d134 (A[34], B[34], POUT[34], GOUT[35] );
smblock0 d135 (A[35], B[35], POUT[35], GOUT[36] );
smblock0 d136 (A[36], B[36], POUT[36], GOUT[37] );
smblock0 d137 (A[37], B[37], POUT[37], GOUT[38] );
smblock0 d138 (A[38], B[38], POUT[38], GOUT[39] );
smblock0 d139 (A[39], B[39], POUT[39], GOUT[40] );
smblock0 d140 (A[40], B[40], POUT[40], GOUT[41] );
smblock0 d141 (A[41], B[41], POUT[41], GOUT[42] );
smblock0 d142 (A[42], B[42], POUT[42], GOUT[43] );
smblock0 d143 (A[43], B[43], POUT[43], GOUT[44] );
smblock0 d144 (A[44], B[44], POUT[44], GOUT[45] );
smblock0 d145 (A[45], B[45], POUT[45], GOUT[46] );
smblock0 d146 (A[46], B[46], POUT[46], GOUT[47] );
smblock0 d147 (A[47], B[47], POUT[47], GOUT[48] );
smblock0 d148 (A[48], B[48], POUT[48], GOUT[49] );
smblock0 d149 (A[49], B[49], POUT[49], GOUT[50] );
smblock0 d150 (A[50], B[50], POUT[50], GOUT[51] );
smblock0 d151 (A[51], B[51], POUT[51], GOUT[52] );
smblock0 d152 (A[52], B[52], POUT[52], GOUT[53] );
smblock0 d153 (A[53], B[53], POUT[53], GOUT[54] );
smblock0 d154 (A[54], B[54], POUT[54], GOUT[55] );
smblock0 d155 (A[55], B[55], POUT[55], GOUT[56] );
smblock0 d156 (A[56], B[56], POUT[56], GOUT[57] );
smblock0 d157 (A[57], B[57], POUT[57], GOUT[58] );
smblock0 d158 (A[58], B[58], POUT[58], GOUT[59] );
smblock0 d159 (A[59], B[59], POUT[59], GOUT[60] );
smblock0 d160 (A[60], B[60], POUT[60], GOUT[61] );
smblock0 d161 (A[61], B[61], POUT[61], GOUT[62] );
smblock0 d162 (A[62], B[62], POUT[62], GOUT[63] );
sminvblock d2 (CIN, GOUT[0] );
endmodule
module smdblc_0_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
smblock1a d21 (PIN[0], GIN[0], GIN[1], GOUT[1] );
smblock1 d32 (PIN[0], PIN[1], GIN[1], GIN[2], POUT[0], GOUT[2] );
smblock1 d33 (PIN[1], PIN[2], GIN[2], GIN[3], POUT[1], GOUT[3] );
smblock1 d34 (PIN[2], PIN[3], GIN[3], GIN[4], POUT[2], GOUT[4] );
smblock1 d35 (PIN[3], PIN[4], GIN[4], GIN[5], POUT[3], GOUT[5] );
smblock1 d36 (PIN[4], PIN[5], GIN[5], GIN[6], POUT[4], GOUT[6] );
smblock1 d37 (PIN[5], PIN[6], GIN[6], GIN[7], POUT[5], GOUT[7] );
smblock1 d38 (PIN[6], PIN[7], GIN[7], GIN[8], POUT[6], GOUT[8] );
smblock1 d39 (PIN[7], PIN[8], GIN[8], GIN[9], POUT[7], GOUT[9] );
smblock1 d310 (PIN[8], PIN[9], GIN[9], GIN[10], POUT[8], GOUT[10] );
smblock1 d311 (PIN[9], PIN[10], GIN[10], GIN[11], POUT[9], GOUT[11] );
smblock1 d312 (PIN[10], PIN[11], GIN[11], GIN[12], POUT[10], GOUT[12] );
smblock1 d313 (PIN[11], PIN[12], GIN[12], GIN[13], POUT[11], GOUT[13] );
smblock1 d314 (PIN[12], PIN[13], GIN[13], GIN[14], POUT[12], GOUT[14] );
smblock1 d315 (PIN[13], PIN[14], GIN[14], GIN[15], POUT[13], GOUT[15] );
smblock1 d316 (PIN[14], PIN[15], GIN[15], GIN[16], POUT[14], GOUT[16] );
smblock1 d317 (PIN[15], PIN[16], GIN[16], GIN[17], POUT[15], GOUT[17] );
smblock1 d318 (PIN[16], PIN[17], GIN[17], GIN[18], POUT[16], GOUT[18] );
smblock1 d319 (PIN[17], PIN[18], GIN[18], GIN[19], POUT[17], GOUT[19] );
smblock1 d320 (PIN[18], PIN[19], GIN[19], GIN[20], POUT[18], GOUT[20] );
smblock1 d321 (PIN[19], PIN[20], GIN[20], GIN[21], POUT[19], GOUT[21] );
smblock1 d322 (PIN[20], PIN[21], GIN[21], GIN[22], POUT[20], GOUT[22] );
smblock1 d323 (PIN[21], PIN[22], GIN[22], GIN[23], POUT[21], GOUT[23] );
smblock1 d324 (PIN[22], PIN[23], GIN[23], GIN[24], POUT[22], GOUT[24] );
smblock1 d325 (PIN[23], PIN[24], GIN[24], GIN[25], POUT[23], GOUT[25] );
smblock1 d326 (PIN[24], PIN[25], GIN[25], GIN[26], POUT[24], GOUT[26] );
smblock1 d327 (PIN[25], PIN[26], GIN[26], GIN[27], POUT[25], GOUT[27] );
smblock1 d328 (PIN[26], PIN[27], GIN[27], GIN[28], POUT[26], GOUT[28] );
smblock1 d329 (PIN[27], PIN[28], GIN[28], GIN[29], POUT[27], GOUT[29] );
smblock1 d330 (PIN[28], PIN[29], GIN[29], GIN[30], POUT[28], GOUT[30] );
smblock1 d331 (PIN[29], PIN[30], GIN[30], GIN[31], POUT[29], GOUT[31] );
smblock1 d332 (PIN[30], PIN[31], GIN[31], GIN[32], POUT[30], GOUT[32] );
smblock1 d333 (PIN[31], PIN[32], GIN[32], GIN[33], POUT[31], GOUT[33] );
smblock1 d334 (PIN[32], PIN[33], GIN[33], GIN[34], POUT[32], GOUT[34] );
smblock1 d335 (PIN[33], PIN[34], GIN[34], GIN[35], POUT[33], GOUT[35] );
smblock1 d336 (PIN[34], PIN[35], GIN[35], GIN[36], POUT[34], GOUT[36] );
smblock1 d337 (PIN[35], PIN[36], GIN[36], GIN[37], POUT[35], GOUT[37] );
smblock1 d338 (PIN[36], PIN[37], GIN[37], GIN[38], POUT[36], GOUT[38] );
smblock1 d339 (PIN[37], PIN[38], GIN[38], GIN[39], POUT[37], GOUT[39] );
smblock1 d340 (PIN[38], PIN[39], GIN[39], GIN[40], POUT[38], GOUT[40] );
smblock1 d341 (PIN[39], PIN[40], GIN[40], GIN[41], POUT[39], GOUT[41] );
smblock1 d342 (PIN[40], PIN[41], GIN[41], GIN[42], POUT[40], GOUT[42] );
smblock1 d343 (PIN[41], PIN[42], GIN[42], GIN[43], POUT[41], GOUT[43] );
smblock1 d344 (PIN[42], PIN[43], GIN[43], GIN[44], POUT[42], GOUT[44] );
smblock1 d345 (PIN[43], PIN[44], GIN[44], GIN[45], POUT[43], GOUT[45] );
smblock1 d346 (PIN[44], PIN[45], GIN[45], GIN[46], POUT[44], GOUT[46] );
smblock1 d347 (PIN[45], PIN[46], GIN[46], GIN[47], POUT[45], GOUT[47] );
smblock1 d348 (PIN[46], PIN[47], GIN[47], GIN[48], POUT[46], GOUT[48] );
smblock1 d349 (PIN[47], PIN[48], GIN[48], GIN[49], POUT[47], GOUT[49] );
smblock1 d350 (PIN[48], PIN[49], GIN[49], GIN[50], POUT[48], GOUT[50] );
smblock1 d351 (PIN[49], PIN[50], GIN[50], GIN[51], POUT[49], GOUT[51] );
smblock1 d352 (PIN[50], PIN[51], GIN[51], GIN[52], POUT[50], GOUT[52] );
smblock1 d353 (PIN[51], PIN[52], GIN[52], GIN[53], POUT[51], GOUT[53] );
smblock1 d354 (PIN[52], PIN[53], GIN[53], GIN[54], POUT[52], GOUT[54] );
smblock1 d355 (PIN[53], PIN[54], GIN[54], GIN[55], POUT[53], GOUT[55] );
smblock1 d356 (PIN[54], PIN[55], GIN[55], GIN[56], POUT[54], GOUT[56] );
smblock1 d357 (PIN[55], PIN[56], GIN[56], GIN[57], POUT[55], GOUT[57] );
smblock1 d358 (PIN[56], PIN[57], GIN[57], GIN[58], POUT[56], GOUT[58] );
smblock1 d359 (PIN[57], PIN[58], GIN[58], GIN[59], POUT[57], GOUT[59] );
smblock1 d360 (PIN[58], PIN[59], GIN[59], GIN[60], POUT[58], GOUT[60] );
smblock1 d361 (PIN[59], PIN[60], GIN[60], GIN[61], POUT[59], GOUT[61] );
smblock1 d362 (PIN[60], PIN[61], GIN[61], GIN[62], POUT[60], GOUT[62] );
smblock1 d363 (PIN[61], PIN[62], GIN[62], GIN[63], POUT[61], GOUT[63] );
endmodule
module smdblc_1_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
smblock2a d22 (PIN[0], GIN[0], GIN[2], GOUT[2] );
smblock2a d23 (PIN[1], GIN[1], GIN[3], GOUT[3] );
smblock2 d34 (PIN[0], PIN[2], GIN[2], GIN[4], POUT[0], GOUT[4] );
smblock2 d35 (PIN[1], PIN[3], GIN[3], GIN[5], POUT[1], GOUT[5] );
smblock2 d36 (PIN[2], PIN[4], GIN[4], GIN[6], POUT[2], GOUT[6] );
smblock2 d37 (PIN[3], PIN[5], GIN[5], GIN[7], POUT[3], GOUT[7] );
smblock2 d38 (PIN[4], PIN[6], GIN[6], GIN[8], POUT[4], GOUT[8] );
smblock2 d39 (PIN[5], PIN[7], GIN[7], GIN[9], POUT[5], GOUT[9] );
smblock2 d310 (PIN[6], PIN[8], GIN[8], GIN[10], POUT[6], GOUT[10] );
smblock2 d311 (PIN[7], PIN[9], GIN[9], GIN[11], POUT[7], GOUT[11] );
smblock2 d312 (PIN[8], PIN[10], GIN[10], GIN[12], POUT[8], GOUT[12] );
smblock2 d313 (PIN[9], PIN[11], GIN[11], GIN[13], POUT[9], GOUT[13] );
smblock2 d314 (PIN[10], PIN[12], GIN[12], GIN[14], POUT[10], GOUT[14] );
smblock2 d315 (PIN[11], PIN[13], GIN[13], GIN[15], POUT[11], GOUT[15] );
smblock2 d316 (PIN[12], PIN[14], GIN[14], GIN[16], POUT[12], GOUT[16] );
smblock2 d317 (PIN[13], PIN[15], GIN[15], GIN[17], POUT[13], GOUT[17] );
smblock2 d318 (PIN[14], PIN[16], GIN[16], GIN[18], POUT[14], GOUT[18] );
smblock2 d319 (PIN[15], PIN[17], GIN[17], GIN[19], POUT[15], GOUT[19] );
smblock2 d320 (PIN[16], PIN[18], GIN[18], GIN[20], POUT[16], GOUT[20] );
smblock2 d321 (PIN[17], PIN[19], GIN[19], GIN[21], POUT[17], GOUT[21] );
smblock2 d322 (PIN[18], PIN[20], GIN[20], GIN[22], POUT[18], GOUT[22] );
smblock2 d323 (PIN[19], PIN[21], GIN[21], GIN[23], POUT[19], GOUT[23] );
smblock2 d324 (PIN[20], PIN[22], GIN[22], GIN[24], POUT[20], GOUT[24] );
smblock2 d325 (PIN[21], PIN[23], GIN[23], GIN[25], POUT[21], GOUT[25] );
smblock2 d326 (PIN[22], PIN[24], GIN[24], GIN[26], POUT[22], GOUT[26] );
smblock2 d327 (PIN[23], PIN[25], GIN[25], GIN[27], POUT[23], GOUT[27] );
smblock2 d328 (PIN[24], PIN[26], GIN[26], GIN[28], POUT[24], GOUT[28] );
smblock2 d329 (PIN[25], PIN[27], GIN[27], GIN[29], POUT[25], GOUT[29] );
smblock2 d330 (PIN[26], PIN[28], GIN[28], GIN[30], POUT[26], GOUT[30] );
smblock2 d331 (PIN[27], PIN[29], GIN[29], GIN[31], POUT[27], GOUT[31] );
smblock2 d332 (PIN[28], PIN[30], GIN[30], GIN[32], POUT[28], GOUT[32] );
smblock2 d333 (PIN[29], PIN[31], GIN[31], GIN[33], POUT[29], GOUT[33] );
smblock2 d334 (PIN[30], PIN[32], GIN[32], GIN[34], POUT[30], GOUT[34] );
smblock2 d335 (PIN[31], PIN[33], GIN[33], GIN[35], POUT[31], GOUT[35] );
smblock2 d336 (PIN[32], PIN[34], GIN[34], GIN[36], POUT[32], GOUT[36] );
smblock2 d337 (PIN[33], PIN[35], GIN[35], GIN[37], POUT[33], GOUT[37] );
smblock2 d338 (PIN[34], PIN[36], GIN[36], GIN[38], POUT[34], GOUT[38] );
smblock2 d339 (PIN[35], PIN[37], GIN[37], GIN[39], POUT[35], GOUT[39] );
smblock2 d340 (PIN[36], PIN[38], GIN[38], GIN[40], POUT[36], GOUT[40] );
smblock2 d341 (PIN[37], PIN[39], GIN[39], GIN[41], POUT[37], GOUT[41] );
smblock2 d342 (PIN[38], PIN[40], GIN[40], GIN[42], POUT[38], GOUT[42] );
smblock2 d343 (PIN[39], PIN[41], GIN[41], GIN[43], POUT[39], GOUT[43] );
smblock2 d344 (PIN[40], PIN[42], GIN[42], GIN[44], POUT[40], GOUT[44] );
smblock2 d345 (PIN[41], PIN[43], GIN[43], GIN[45], POUT[41], GOUT[45] );
smblock2 d346 (PIN[42], PIN[44], GIN[44], GIN[46], POUT[42], GOUT[46] );
smblock2 d347 (PIN[43], PIN[45], GIN[45], GIN[47], POUT[43], GOUT[47] );
smblock2 d348 (PIN[44], PIN[46], GIN[46], GIN[48], POUT[44], GOUT[48] );
smblock2 d349 (PIN[45], PIN[47], GIN[47], GIN[49], POUT[45], GOUT[49] );
smblock2 d350 (PIN[46], PIN[48], GIN[48], GIN[50], POUT[46], GOUT[50] );
smblock2 d351 (PIN[47], PIN[49], GIN[49], GIN[51], POUT[47], GOUT[51] );
smblock2 d352 (PIN[48], PIN[50], GIN[50], GIN[52], POUT[48], GOUT[52] );
smblock2 d353 (PIN[49], PIN[51], GIN[51], GIN[53], POUT[49], GOUT[53] );
smblock2 d354 (PIN[50], PIN[52], GIN[52], GIN[54], POUT[50], GOUT[54] );
smblock2 d355 (PIN[51], PIN[53], GIN[53], GIN[55], POUT[51], GOUT[55] );
smblock2 d356 (PIN[52], PIN[54], GIN[54], GIN[56], POUT[52], GOUT[56] );
smblock2 d357 (PIN[53], PIN[55], GIN[55], GIN[57], POUT[53], GOUT[57] );
smblock2 d358 (PIN[54], PIN[56], GIN[56], GIN[58], POUT[54], GOUT[58] );
smblock2 d359 (PIN[55], PIN[57], GIN[57], GIN[59], POUT[55], GOUT[59] );
smblock2 d360 (PIN[56], PIN[58], GIN[58], GIN[60], POUT[56], GOUT[60] );
smblock2 d361 (PIN[57], PIN[59], GIN[59], GIN[61], POUT[57], GOUT[61] );
smblock2 d362 (PIN[58], PIN[60], GIN[60], GIN[62], POUT[58], GOUT[62] );
smblock2 d363 (PIN[59], PIN[61], GIN[61], GIN[63], POUT[59], GOUT[63] );
endmodule
module smdblc_2_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
sminvblock d12 (GIN[2], GOUT[2] );
sminvblock d13 (GIN[3], GOUT[3] );
smblock1a d24 (PIN[0], GIN[0], GIN[4], GOUT[4] );
smblock1a d25 (PIN[1], GIN[1], GIN[5], GOUT[5] );
smblock1a d26 (PIN[2], GIN[2], GIN[6], GOUT[6] );
smblock1a d27 (PIN[3], GIN[3], GIN[7], GOUT[7] );
smblock1 d38 (PIN[0], PIN[4], GIN[4], GIN[8], POUT[0], GOUT[8] );
smblock1 d39 (PIN[1], PIN[5], GIN[5], GIN[9], POUT[1], GOUT[9] );
smblock1 d310 (PIN[2], PIN[6], GIN[6], GIN[10], POUT[2], GOUT[10] );
smblock1 d311 (PIN[3], PIN[7], GIN[7], GIN[11], POUT[3], GOUT[11] );
smblock1 d312 (PIN[4], PIN[8], GIN[8], GIN[12], POUT[4], GOUT[12] );
smblock1 d313 (PIN[5], PIN[9], GIN[9], GIN[13], POUT[5], GOUT[13] );
smblock1 d314 (PIN[6], PIN[10], GIN[10], GIN[14], POUT[6], GOUT[14] );
smblock1 d315 (PIN[7], PIN[11], GIN[11], GIN[15], POUT[7], GOUT[15] );
smblock1 d316 (PIN[8], PIN[12], GIN[12], GIN[16], POUT[8], GOUT[16] );
smblock1 d317 (PIN[9], PIN[13], GIN[13], GIN[17], POUT[9], GOUT[17] );
smblock1 d318 (PIN[10], PIN[14], GIN[14], GIN[18], POUT[10], GOUT[18] );
smblock1 d319 (PIN[11], PIN[15], GIN[15], GIN[19], POUT[11], GOUT[19] );
smblock1 d320 (PIN[12], PIN[16], GIN[16], GIN[20], POUT[12], GOUT[20] );
smblock1 d321 (PIN[13], PIN[17], GIN[17], GIN[21], POUT[13], GOUT[21] );
smblock1 d322 (PIN[14], PIN[18], GIN[18], GIN[22], POUT[14], GOUT[22] );
smblock1 d323 (PIN[15], PIN[19], GIN[19], GIN[23], POUT[15], GOUT[23] );
smblock1 d324 (PIN[16], PIN[20], GIN[20], GIN[24], POUT[16], GOUT[24] );
smblock1 d325 (PIN[17], PIN[21], GIN[21], GIN[25], POUT[17], GOUT[25] );
smblock1 d326 (PIN[18], PIN[22], GIN[22], GIN[26], POUT[18], GOUT[26] );
smblock1 d327 (PIN[19], PIN[23], GIN[23], GIN[27], POUT[19], GOUT[27] );
smblock1 d328 (PIN[20], PIN[24], GIN[24], GIN[28], POUT[20], GOUT[28] );
smblock1 d329 (PIN[21], PIN[25], GIN[25], GIN[29], POUT[21], GOUT[29] );
smblock1 d330 (PIN[22], PIN[26], GIN[26], GIN[30], POUT[22], GOUT[30] );
smblock1 d331 (PIN[23], PIN[27], GIN[27], GIN[31], POUT[23], GOUT[31] );
smblock1 d332 (PIN[24], PIN[28], GIN[28], GIN[32], POUT[24], GOUT[32] );
smblock1 d333 (PIN[25], PIN[29], GIN[29], GIN[33], POUT[25], GOUT[33] );
smblock1 d334 (PIN[26], PIN[30], GIN[30], GIN[34], POUT[26], GOUT[34] );
smblock1 d335 (PIN[27], PIN[31], GIN[31], GIN[35], POUT[27], GOUT[35] );
smblock1 d336 (PIN[28], PIN[32], GIN[32], GIN[36], POUT[28], GOUT[36] );
smblock1 d337 (PIN[29], PIN[33], GIN[33], GIN[37], POUT[29], GOUT[37] );
smblock1 d338 (PIN[30], PIN[34], GIN[34], GIN[38], POUT[30], GOUT[38] );
smblock1 d339 (PIN[31], PIN[35], GIN[35], GIN[39], POUT[31], GOUT[39] );
smblock1 d340 (PIN[32], PIN[36], GIN[36], GIN[40], POUT[32], GOUT[40] );
smblock1 d341 (PIN[33], PIN[37], GIN[37], GIN[41], POUT[33], GOUT[41] );
smblock1 d342 (PIN[34], PIN[38], GIN[38], GIN[42], POUT[34], GOUT[42] );
smblock1 d343 (PIN[35], PIN[39], GIN[39], GIN[43], POUT[35], GOUT[43] );
smblock1 d344 (PIN[36], PIN[40], GIN[40], GIN[44], POUT[36], GOUT[44] );
smblock1 d345 (PIN[37], PIN[41], GIN[41], GIN[45], POUT[37], GOUT[45] );
smblock1 d346 (PIN[38], PIN[42], GIN[42], GIN[46], POUT[38], GOUT[46] );
smblock1 d347 (PIN[39], PIN[43], GIN[43], GIN[47], POUT[39], GOUT[47] );
smblock1 d348 (PIN[40], PIN[44], GIN[44], GIN[48], POUT[40], GOUT[48] );
smblock1 d349 (PIN[41], PIN[45], GIN[45], GIN[49], POUT[41], GOUT[49] );
smblock1 d350 (PIN[42], PIN[46], GIN[46], GIN[50], POUT[42], GOUT[50] );
smblock1 d351 (PIN[43], PIN[47], GIN[47], GIN[51], POUT[43], GOUT[51] );
smblock1 d352 (PIN[44], PIN[48], GIN[48], GIN[52], POUT[44], GOUT[52] );
smblock1 d353 (PIN[45], PIN[49], GIN[49], GIN[53], POUT[45], GOUT[53] );
smblock1 d354 (PIN[46], PIN[50], GIN[50], GIN[54], POUT[46], GOUT[54] );
smblock1 d355 (PIN[47], PIN[51], GIN[51], GIN[55], POUT[47], GOUT[55] );
smblock1 d356 (PIN[48], PIN[52], GIN[52], GIN[56], POUT[48], GOUT[56] );
smblock1 d357 (PIN[49], PIN[53], GIN[53], GIN[57], POUT[49], GOUT[57] );
smblock1 d358 (PIN[50], PIN[54], GIN[54], GIN[58], POUT[50], GOUT[58] );
smblock1 d359 (PIN[51], PIN[55], GIN[55], GIN[59], POUT[51], GOUT[59] );
smblock1 d360 (PIN[52], PIN[56], GIN[56], GIN[60], POUT[52], GOUT[60] );
smblock1 d361 (PIN[53], PIN[57], GIN[57], GIN[61], POUT[53], GOUT[61] );
smblock1 d362 (PIN[54], PIN[58], GIN[58], GIN[62], POUT[54], GOUT[62] );
smblock1 d363 (PIN[55], PIN[59], GIN[59], GIN[63], POUT[55], GOUT[63] );
endmodule
module smdblc_3_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
sminvblock d12 (GIN[2], GOUT[2] );
sminvblock d13 (GIN[3], GOUT[3] );
sminvblock d14 (GIN[4], GOUT[4] );
sminvblock d15 (GIN[5], GOUT[5] );
sminvblock d16 (GIN[6], GOUT[6] );
sminvblock d17 (GIN[7], GOUT[7] );
smblock2a d28 (PIN[0], GIN[0], GIN[8], GOUT[8] );
smblock2a d29 (PIN[1], GIN[1], GIN[9], GOUT[9] );
smblock2a d210 (PIN[2], GIN[2], GIN[10], GOUT[10] );
smblock2a d211 (PIN[3], GIN[3], GIN[11], GOUT[11] );
smblock2a d212 (PIN[4], GIN[4], GIN[12], GOUT[12] );
smblock2a d213 (PIN[5], GIN[5], GIN[13], GOUT[13] );
smblock2a d214 (PIN[6], GIN[6], GIN[14], GOUT[14] );
smblock2a d215 (PIN[7], GIN[7], GIN[15], GOUT[15] );
smblock2 d316 (PIN[0], PIN[8], GIN[8], GIN[16], POUT[0], GOUT[16] );
smblock2 d317 (PIN[1], PIN[9], GIN[9], GIN[17], POUT[1], GOUT[17] );
smblock2 d318 (PIN[2], PIN[10], GIN[10], GIN[18], POUT[2], GOUT[18] );
smblock2 d319 (PIN[3], PIN[11], GIN[11], GIN[19], POUT[3], GOUT[19] );
smblock2 d320 (PIN[4], PIN[12], GIN[12], GIN[20], POUT[4], GOUT[20] );
smblock2 d321 (PIN[5], PIN[13], GIN[13], GIN[21], POUT[5], GOUT[21] );
smblock2 d322 (PIN[6], PIN[14], GIN[14], GIN[22], POUT[6], GOUT[22] );
smblock2 d323 (PIN[7], PIN[15], GIN[15], GIN[23], POUT[7], GOUT[23] );
smblock2 d324 (PIN[8], PIN[16], GIN[16], GIN[24], POUT[8], GOUT[24] );
smblock2 d325 (PIN[9], PIN[17], GIN[17], GIN[25], POUT[9], GOUT[25] );
smblock2 d326 (PIN[10], PIN[18], GIN[18], GIN[26], POUT[10], GOUT[26] );
smblock2 d327 (PIN[11], PIN[19], GIN[19], GIN[27], POUT[11], GOUT[27] );
smblock2 d328 (PIN[12], PIN[20], GIN[20], GIN[28], POUT[12], GOUT[28] );
smblock2 d329 (PIN[13], PIN[21], GIN[21], GIN[29], POUT[13], GOUT[29] );
smblock2 d330 (PIN[14], PIN[22], GIN[22], GIN[30], POUT[14], GOUT[30] );
smblock2 d331 (PIN[15], PIN[23], GIN[23], GIN[31], POUT[15], GOUT[31] );
smblock2 d332 (PIN[16], PIN[24], GIN[24], GIN[32], POUT[16], GOUT[32] );
smblock2 d333 (PIN[17], PIN[25], GIN[25], GIN[33], POUT[17], GOUT[33] );
smblock2 d334 (PIN[18], PIN[26], GIN[26], GIN[34], POUT[18], GOUT[34] );
smblock2 d335 (PIN[19], PIN[27], GIN[27], GIN[35], POUT[19], GOUT[35] );
smblock2 d336 (PIN[20], PIN[28], GIN[28], GIN[36], POUT[20], GOUT[36] );
smblock2 d337 (PIN[21], PIN[29], GIN[29], GIN[37], POUT[21], GOUT[37] );
smblock2 d338 (PIN[22], PIN[30], GIN[30], GIN[38], POUT[22], GOUT[38] );
smblock2 d339 (PIN[23], PIN[31], GIN[31], GIN[39], POUT[23], GOUT[39] );
smblock2 d340 (PIN[24], PIN[32], GIN[32], GIN[40], POUT[24], GOUT[40] );
smblock2 d341 (PIN[25], PIN[33], GIN[33], GIN[41], POUT[25], GOUT[41] );
smblock2 d342 (PIN[26], PIN[34], GIN[34], GIN[42], POUT[26], GOUT[42] );
smblock2 d343 (PIN[27], PIN[35], GIN[35], GIN[43], POUT[27], GOUT[43] );
smblock2 d344 (PIN[28], PIN[36], GIN[36], GIN[44], POUT[28], GOUT[44] );
smblock2 d345 (PIN[29], PIN[37], GIN[37], GIN[45], POUT[29], GOUT[45] );
smblock2 d346 (PIN[30], PIN[38], GIN[38], GIN[46], POUT[30], GOUT[46] );
smblock2 d347 (PIN[31], PIN[39], GIN[39], GIN[47], POUT[31], GOUT[47] );
smblock2 d348 (PIN[32], PIN[40], GIN[40], GIN[48], POUT[32], GOUT[48] );
smblock2 d349 (PIN[33], PIN[41], GIN[41], GIN[49], POUT[33], GOUT[49] );
smblock2 d350 (PIN[34], PIN[42], GIN[42], GIN[50], POUT[34], GOUT[50] );
smblock2 d351 (PIN[35], PIN[43], GIN[43], GIN[51], POUT[35], GOUT[51] );
smblock2 d352 (PIN[36], PIN[44], GIN[44], GIN[52], POUT[36], GOUT[52] );
smblock2 d353 (PIN[37], PIN[45], GIN[45], GIN[53], POUT[37], GOUT[53] );
smblock2 d354 (PIN[38], PIN[46], GIN[46], GIN[54], POUT[38], GOUT[54] );
smblock2 d355 (PIN[39], PIN[47], GIN[47], GIN[55], POUT[39], GOUT[55] );
smblock2 d356 (PIN[40], PIN[48], GIN[48], GIN[56], POUT[40], GOUT[56] );
smblock2 d357 (PIN[41], PIN[49], GIN[49], GIN[57], POUT[41], GOUT[57] );
smblock2 d358 (PIN[42], PIN[50], GIN[50], GIN[58], POUT[42], GOUT[58] );
smblock2 d359 (PIN[43], PIN[51], GIN[51], GIN[59], POUT[43], GOUT[59] );
smblock2 d360 (PIN[44], PIN[52], GIN[52], GIN[60], POUT[44], GOUT[60] );
smblock2 d361 (PIN[45], PIN[53], GIN[53], GIN[61], POUT[45], GOUT[61] );
smblock2 d362 (PIN[46], PIN[54], GIN[54], GIN[62], POUT[46], GOUT[62] );
smblock2 d363 (PIN[47], PIN[55], GIN[55], GIN[63], POUT[47], GOUT[63] );
endmodule
module smdblc_4_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
sminvblock d12 (GIN[2], GOUT[2] );
sminvblock d13 (GIN[3], GOUT[3] );
sminvblock d14 (GIN[4], GOUT[4] );
sminvblock d15 (GIN[5], GOUT[5] );
sminvblock d16 (GIN[6], GOUT[6] );
sminvblock d17 (GIN[7], GOUT[7] );
sminvblock d18 (GIN[8], GOUT[8] );
sminvblock d19 (GIN[9], GOUT[9] );
sminvblock d110 (GIN[10], GOUT[10] );
sminvblock d111 (GIN[11], GOUT[11] );
sminvblock d112 (GIN[12], GOUT[12] );
sminvblock d113 (GIN[13], GOUT[13] );
sminvblock d114 (GIN[14], GOUT[14] );
sminvblock d115 (GIN[15], GOUT[15] );
smblock1a d216 (PIN[0], GIN[0], GIN[16], GOUT[16] );
smblock1a d217 (PIN[1], GIN[1], GIN[17], GOUT[17] );
smblock1a d218 (PIN[2], GIN[2], GIN[18], GOUT[18] );
smblock1a d219 (PIN[3], GIN[3], GIN[19], GOUT[19] );
smblock1a d220 (PIN[4], GIN[4], GIN[20], GOUT[20] );
smblock1a d221 (PIN[5], GIN[5], GIN[21], GOUT[21] );
smblock1a d222 (PIN[6], GIN[6], GIN[22], GOUT[22] );
smblock1a d223 (PIN[7], GIN[7], GIN[23], GOUT[23] );
smblock1a d224 (PIN[8], GIN[8], GIN[24], GOUT[24] );
smblock1a d225 (PIN[9], GIN[9], GIN[25], GOUT[25] );
smblock1a d226 (PIN[10], GIN[10], GIN[26], GOUT[26] );
smblock1a d227 (PIN[11], GIN[11], GIN[27], GOUT[27] );
smblock1a d228 (PIN[12], GIN[12], GIN[28], GOUT[28] );
smblock1a d229 (PIN[13], GIN[13], GIN[29], GOUT[29] );
smblock1a d230 (PIN[14], GIN[14], GIN[30], GOUT[30] );
smblock1a d231 (PIN[15], GIN[15], GIN[31], GOUT[31] );
smblock1 d332 (PIN[0], PIN[16], GIN[16], GIN[32], POUT[0], GOUT[32] );
smblock1 d333 (PIN[1], PIN[17], GIN[17], GIN[33], POUT[1], GOUT[33] );
smblock1 d334 (PIN[2], PIN[18], GIN[18], GIN[34], POUT[2], GOUT[34] );
smblock1 d335 (PIN[3], PIN[19], GIN[19], GIN[35], POUT[3], GOUT[35] );
smblock1 d336 (PIN[4], PIN[20], GIN[20], GIN[36], POUT[4], GOUT[36] );
smblock1 d337 (PIN[5], PIN[21], GIN[21], GIN[37], POUT[5], GOUT[37] );
smblock1 d338 (PIN[6], PIN[22], GIN[22], GIN[38], POUT[6], GOUT[38] );
smblock1 d339 (PIN[7], PIN[23], GIN[23], GIN[39], POUT[7], GOUT[39] );
smblock1 d340 (PIN[8], PIN[24], GIN[24], GIN[40], POUT[8], GOUT[40] );
smblock1 d341 (PIN[9], PIN[25], GIN[25], GIN[41], POUT[9], GOUT[41] );
smblock1 d342 (PIN[10], PIN[26], GIN[26], GIN[42], POUT[10], GOUT[42] );
smblock1 d343 (PIN[11], PIN[27], GIN[27], GIN[43], POUT[11], GOUT[43] );
smblock1 d344 (PIN[12], PIN[28], GIN[28], GIN[44], POUT[12], GOUT[44] );
smblock1 d345 (PIN[13], PIN[29], GIN[29], GIN[45], POUT[13], GOUT[45] );
smblock1 d346 (PIN[14], PIN[30], GIN[30], GIN[46], POUT[14], GOUT[46] );
smblock1 d347 (PIN[15], PIN[31], GIN[31], GIN[47], POUT[15], GOUT[47] );
smblock1 d348 (PIN[16], PIN[32], GIN[32], GIN[48], POUT[16], GOUT[48] );
smblock1 d349 (PIN[17], PIN[33], GIN[33], GIN[49], POUT[17], GOUT[49] );
smblock1 d350 (PIN[18], PIN[34], GIN[34], GIN[50], POUT[18], GOUT[50] );
smblock1 d351 (PIN[19], PIN[35], GIN[35], GIN[51], POUT[19], GOUT[51] );
smblock1 d352 (PIN[20], PIN[36], GIN[36], GIN[52], POUT[20], GOUT[52] );
smblock1 d353 (PIN[21], PIN[37], GIN[37], GIN[53], POUT[21], GOUT[53] );
smblock1 d354 (PIN[22], PIN[38], GIN[38], GIN[54], POUT[22], GOUT[54] );
smblock1 d355 (PIN[23], PIN[39], GIN[39], GIN[55], POUT[23], GOUT[55] );
smblock1 d356 (PIN[24], PIN[40], GIN[40], GIN[56], POUT[24], GOUT[56] );
smblock1 d357 (PIN[25], PIN[41], GIN[41], GIN[57], POUT[25], GOUT[57] );
smblock1 d358 (PIN[26], PIN[42], GIN[42], GIN[58], POUT[26], GOUT[58] );
smblock1 d359 (PIN[27], PIN[43], GIN[43], GIN[59], POUT[27], GOUT[59] );
smblock1 d360 (PIN[28], PIN[44], GIN[44], GIN[60], POUT[28], GOUT[60] );
smblock1 d361 (PIN[29], PIN[45], GIN[45], GIN[61], POUT[29], GOUT[61] );
smblock1 d362 (PIN[30], PIN[46], GIN[46], GIN[62], POUT[30], GOUT[62] );
smblock1 d363 (PIN[31], PIN[47], GIN[47], GIN[63], POUT[31], GOUT[63] );
endmodule
module smxorstage_128 ( A, B, PBIT, CARRY, SUM );
input [63:0] A;
input [63:0] B;
input PBIT;
input [63:0] CARRY;
output [63:0] SUM;
smxxor1 d20 (A[0], B[0], CARRY[0], SUM[0] );
smxxor1 d21 (A[1], B[1], CARRY[1], SUM[1] );
smxxor1 d22 (A[2], B[2], CARRY[2], SUM[2] );
smxxor1 d23 (A[3], B[3], CARRY[3], SUM[3] );
smxxor1 d24 (A[4], B[4], CARRY[4], SUM[4] );
smxxor1 d25 (A[5], B[5], CARRY[5], SUM[5] );
smxxor1 d26 (A[6], B[6], CARRY[6], SUM[6] );
smxxor1 d27 (A[7], B[7], CARRY[7], SUM[7] );
smxxor1 d28 (A[8], B[8], CARRY[8], SUM[8] );
smxxor1 d29 (A[9], B[9], CARRY[9], SUM[9] );
smxxor1 d210 (A[10], B[10], CARRY[10], SUM[10] );
smxxor1 d211 (A[11], B[11], CARRY[11], SUM[11] );
smxxor1 d212 (A[12], B[12], CARRY[12], SUM[12] );
smxxor1 d213 (A[13], B[13], CARRY[13], SUM[13] );
smxxor1 d214 (A[14], B[14], CARRY[14], SUM[14] );
smxxor1 d215 (A[15], B[15], CARRY[15], SUM[15] );
smxxor1 d216 (A[16], B[16], CARRY[16], SUM[16] );
smxxor1 d217 (A[17], B[17], CARRY[17], SUM[17] );
smxxor1 d218 (A[18], B[18], CARRY[18], SUM[18] );
smxxor1 d219 (A[19], B[19], CARRY[19], SUM[19] );
smxxor1 d220 (A[20], B[20], CARRY[20], SUM[20] );
smxxor1 d221 (A[21], B[21], CARRY[21], SUM[21] );
smxxor1 d222 (A[22], B[22], CARRY[22], SUM[22] );
smxxor1 d223 (A[23], B[23], CARRY[23], SUM[23] );
smxxor1 d224 (A[24], B[24], CARRY[24], SUM[24] );
smxxor1 d225 (A[25], B[25], CARRY[25], SUM[25] );
smxxor1 d226 (A[26], B[26], CARRY[26], SUM[26] );
smxxor1 d227 (A[27], B[27], CARRY[27], SUM[27] );
smxxor1 d228 (A[28], B[28], CARRY[28], SUM[28] );
smxxor1 d229 (A[29], B[29], CARRY[29], SUM[29] );
smxxor1 d230 (A[30], B[30], CARRY[30], SUM[30] );
smxxor1 d231 (A[31], B[31], CARRY[31], SUM[31] );
smxxor1 d232 (A[32], B[32], CARRY[32], SUM[32] );
smxxor1 d233 (A[33], B[33], CARRY[33], SUM[33] );
smxxor1 d234 (A[34], B[34], CARRY[34], SUM[34] );
smxxor1 d235 (A[35], B[35], CARRY[35], SUM[35] );
smxxor1 d236 (A[36], B[36], CARRY[36], SUM[36] );
smxxor1 d237 (A[37], B[37], CARRY[37], SUM[37] );
smxxor1 d238 (A[38], B[38], CARRY[38], SUM[38] );
smxxor1 d239 (A[39], B[39], CARRY[39], SUM[39] );
smxxor1 d240 (A[40], B[40], CARRY[40], SUM[40] );
smxxor1 d241 (A[41], B[41], CARRY[41], SUM[41] );
smxxor1 d242 (A[42], B[42], CARRY[42], SUM[42] );
smxxor1 d243 (A[43], B[43], CARRY[43], SUM[43] );
smxxor1 d244 (A[44], B[44], CARRY[44], SUM[44] );
smxxor1 d245 (A[45], B[45], CARRY[45], SUM[45] );
smxxor1 d246 (A[46], B[46], CARRY[46], SUM[46] );
smxxor1 d247 (A[47], B[47], CARRY[47], SUM[47] );
smxxor1 d248 (A[48], B[48], CARRY[48], SUM[48] );
smxxor1 d249 (A[49], B[49], CARRY[49], SUM[49] );
smxxor1 d250 (A[50], B[50], CARRY[50], SUM[50] );
smxxor1 d251 (A[51], B[51], CARRY[51], SUM[51] );
smxxor1 d252 (A[52], B[52], CARRY[52], SUM[52] );
smxxor1 d253 (A[53], B[53], CARRY[53], SUM[53] );
smxxor1 d254 (A[54], B[54], CARRY[54], SUM[54] );
smxxor1 d255 (A[55], B[55], CARRY[55], SUM[55] );
smxxor1 d256 (A[56], B[56], CARRY[56], SUM[56] );
smxxor1 d257 (A[57], B[57], CARRY[57], SUM[57] );
smxxor1 d258 (A[58], B[58], CARRY[58], SUM[58] );
smxxor1 d259 (A[59], B[59], CARRY[59], SUM[59] );
smxxor1 d260 (A[60], B[60], CARRY[60], SUM[60] );
smxxor1 d261 (A[61], B[61], CARRY[61], SUM[61] );
smxxor1 d262 (A[62], B[62], CARRY[62], SUM[62] );
smxxor1 d263 (A[63], B[63], CARRY[63], SUM[63] );
endmodule
module smdblc_5_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [63:0] POUT;
output [63:0] GOUT;
sminvblock d10 (GIN[0], GOUT[0] );
sminvblock d11 (GIN[1], GOUT[1] );
sminvblock d12 (GIN[2], GOUT[2] );
sminvblock d13 (GIN[3], GOUT[3] );
sminvblock d14 (GIN[4], GOUT[4] );
sminvblock d15 (GIN[5], GOUT[5] );
sminvblock d16 (GIN[6], GOUT[6] );
sminvblock d17 (GIN[7], GOUT[7] );
sminvblock d18 (GIN[8], GOUT[8] );
sminvblock d19 (GIN[9], GOUT[9] );
sminvblock d110 (GIN[10], GOUT[10] );
sminvblock d111 (GIN[11], GOUT[11] );
sminvblock d112 (GIN[12], GOUT[12] );
sminvblock d113 (GIN[13], GOUT[13] );
sminvblock d114 (GIN[14], GOUT[14] );
sminvblock d115 (GIN[15], GOUT[15] );
sminvblock d116 (GIN[16], GOUT[16] );
sminvblock d117 (GIN[17], GOUT[17] );
sminvblock d118 (GIN[18], GOUT[18] );
sminvblock d119 (GIN[19], GOUT[19] );
sminvblock d120 (GIN[20], GOUT[20] );
sminvblock d121 (GIN[21], GOUT[21] );
sminvblock d122 (GIN[22], GOUT[22] );
sminvblock d123 (GIN[23], GOUT[23] );
sminvblock d124 (GIN[24], GOUT[24] );
sminvblock d125 (GIN[25], GOUT[25] );
sminvblock d126 (GIN[26], GOUT[26] );
sminvblock d127 (GIN[27], GOUT[27] );
sminvblock d128 (GIN[28], GOUT[28] );
sminvblock d129 (GIN[29], GOUT[29] );
sminvblock d130 (GIN[30], GOUT[30] );
sminvblock d131 (GIN[31], GOUT[31] );
smblock2a d232 (PIN[0], GIN[0], GIN[32], GOUT[32] );
smblock2a d233 (PIN[1], GIN[1], GIN[33], GOUT[33] );
smblock2a d234 (PIN[2], GIN[2], GIN[34], GOUT[34] );
smblock2a d235 (PIN[3], GIN[3], GIN[35], GOUT[35] );
smblock2a d236 (PIN[4], GIN[4], GIN[36], GOUT[36] );
smblock2a d237 (PIN[5], GIN[5], GIN[37], GOUT[37] );
smblock2a d238 (PIN[6], GIN[6], GIN[38], GOUT[38] );
smblock2a d239 (PIN[7], GIN[7], GIN[39], GOUT[39] );
smblock2a d240 (PIN[8], GIN[8], GIN[40], GOUT[40] );
smblock2a d241 (PIN[9], GIN[9], GIN[41], GOUT[41] );
smblock2a d242 (PIN[10], GIN[10], GIN[42], GOUT[42] );
smblock2a d243 (PIN[11], GIN[11], GIN[43], GOUT[43] );
smblock2a d244 (PIN[12], GIN[12], GIN[44], GOUT[44] );
smblock2a d245 (PIN[13], GIN[13], GIN[45], GOUT[45] );
smblock2a d246 (PIN[14], GIN[14], GIN[46], GOUT[46] );
smblock2a d247 (PIN[15], GIN[15], GIN[47], GOUT[47] );
smblock2a d248 (PIN[16], GIN[16], GIN[48], GOUT[48] );
smblock2a d249 (PIN[17], GIN[17], GIN[49], GOUT[49] );
smblock2a d250 (PIN[18], GIN[18], GIN[50], GOUT[50] );
smblock2a d251 (PIN[19], GIN[19], GIN[51], GOUT[51] );
smblock2a d252 (PIN[20], GIN[20], GIN[52], GOUT[52] );
smblock2a d253 (PIN[21], GIN[21], GIN[53], GOUT[53] );
smblock2a d254 (PIN[22], GIN[22], GIN[54], GOUT[54] );
smblock2a d255 (PIN[23], GIN[23], GIN[55], GOUT[55] );
smblock2a d256 (PIN[24], GIN[24], GIN[56], GOUT[56] );
smblock2a d257 (PIN[25], GIN[25], GIN[57], GOUT[57] );
smblock2a d258 (PIN[26], GIN[26], GIN[58], GOUT[58] );
smblock2a d259 (PIN[27], GIN[27], GIN[59], GOUT[59] );
smblock2a d260 (PIN[28], GIN[28], GIN[60], GOUT[60] );
smblock2a d261 (PIN[29], GIN[29], GIN[61], GOUT[61] );
smblock2a d262 (PIN[30], GIN[30], GIN[62], GOUT[62] );
smblock2a d263 (PIN[31], GIN[31], GIN[63], GOUT[63] );
endmodule
module smdblc_6_128 ( PIN, GIN, POUT, GOUT );
input [63:0] PIN;
input [63:0] GIN;
output [0:0] POUT;
output [63:0] GOUT;
assign GOUT[63:0] = GIN[63:0];
endmodule
module smboothcoder_34_34 ( OPA, OPB, SUMMAND );
input [33:0] OPA;
input [33:0] OPB;
output [628:0] SUMMAND;
wire [33:0] OPA_;
wire [67:0] INT_MULTIPLIER;
wire LOGIC_ONE, LOGIC_ZERO;
assign LOGIC_ONE = 1'b1;
assign LOGIC_ZERO = 1'b0;
smdecoder dDEC0 (.INA (LOGIC_ZERO), .INB (OPB[0]), .INC (OPB[1]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]) );
assign OPA_ = ~ OPA;
smpp_low dPPL0 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[0]) );
smr_gate dRGATE0 (.INA (LOGIC_ZERO), .INB (OPB[0]), .INC (OPB[1]), .PPBIT (SUMMAND[1]) );
smpp_middle dPPM0 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[2]) );
smpp_middle dPPM1 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[3]) );
smpp_middle dPPM2 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[6]) );
smpp_middle dPPM3 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[8]) );
smpp_middle dPPM4 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[12]) );
smpp_middle dPPM5 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[15]) );
smpp_middle dPPM6 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[20]) );
smpp_middle dPPM7 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[24]) );
smpp_middle dPPM8 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[30]) );
smpp_middle dPPM9 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[35]) );
smpp_middle dPPM10 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[42]) );
smpp_middle dPPM11 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[48]) );
smpp_middle dPPM12 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[56]) );
smpp_middle dPPM13 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[63]) );
smpp_middle dPPM14 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[72]) );
smpp_middle dPPM15 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[80]) );
smpp_middle dPPM16 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[90]) );
smpp_middle dPPM17 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[99]) );
smpp_middle dPPM18 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[110]) );
smpp_middle dPPM19 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[120]) );
smpp_middle dPPM20 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[132]) );
smpp_middle dPPM21 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[143]) );
smpp_middle dPPM22 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[156]) );
smpp_middle dPPM23 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[168]) );
smpp_middle dPPM24 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[182]) );
smpp_middle dPPM25 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[195]) );
smpp_middle dPPM26 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[210]) );
smpp_middle dPPM27 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[224]) );
smpp_middle dPPM28 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[240]) );
smpp_middle dPPM29 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[255]) );
smpp_middle dPPM30 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[272]) );
smpp_middle dPPM31 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[288]) );
smpp_middle dPPM32 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[306]) );
smpp_high dPPH0 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[0]), .TWONEG (INT_MULTIPLIER[1]), .ONEPOS (INT_MULTIPLIER[2]), .ONENEG (INT_MULTIPLIER[3]), .PPBIT (SUMMAND[323]) );
assign SUMMAND[324] = 1'b1;
smdecoder dDEC1 (.INA (OPB[1]), .INB (OPB[2]), .INC (OPB[3]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]) );
smpp_low dPPL1 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[4]) );
smr_gate dRGATE1 (.INA (OPB[1]), .INB (OPB[2]), .INC (OPB[3]), .PPBIT (SUMMAND[5]) );
smpp_middle dPPM33 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[7]) );
smpp_middle dPPM34 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[9]) );
smpp_middle dPPM35 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[13]) );
smpp_middle dPPM36 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[16]) );
smpp_middle dPPM37 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[21]) );
smpp_middle dPPM38 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[25]) );
smpp_middle dPPM39 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[31]) );
smpp_middle dPPM40 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[36]) );
smpp_middle dPPM41 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[43]) );
smpp_middle dPPM42 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[49]) );
smpp_middle dPPM43 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[57]) );
smpp_middle dPPM44 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[64]) );
smpp_middle dPPM45 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[73]) );
smpp_middle dPPM46 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[81]) );
smpp_middle dPPM47 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[91]) );
smpp_middle dPPM48 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[100]) );
smpp_middle dPPM49 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[111]) );
smpp_middle dPPM50 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[121]) );
smpp_middle dPPM51 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[133]) );
smpp_middle dPPM52 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[144]) );
smpp_middle dPPM53 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[157]) );
smpp_middle dPPM54 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[169]) );
smpp_middle dPPM55 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[183]) );
smpp_middle dPPM56 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[196]) );
smpp_middle dPPM57 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[211]) );
smpp_middle dPPM58 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[225]) );
smpp_middle dPPM59 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[241]) );
smpp_middle dPPM60 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[256]) );
smpp_middle dPPM61 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[273]) );
smpp_middle dPPM62 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[289]) );
smpp_middle dPPM63 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[307]) );
smpp_middle dPPM64 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[325]) );
smpp_middle dPPM65 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[341]) );
assign SUMMAND[342] = LOGIC_ONE;
smpp_high dPPH1 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[4]), .TWONEG (INT_MULTIPLIER[5]), .ONEPOS (INT_MULTIPLIER[6]), .ONENEG (INT_MULTIPLIER[7]), .PPBIT (SUMMAND[358]) );
smdecoder dDEC2 (.INA (OPB[3]), .INB (OPB[4]), .INC (OPB[5]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]) );
smpp_low dPPL2 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[10]) );
smr_gate dRGATE2 (.INA (OPB[3]), .INB (OPB[4]), .INC (OPB[5]), .PPBIT (SUMMAND[11]) );
smpp_middle dPPM66 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[14]) );
smpp_middle dPPM67 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[17]) );
smpp_middle dPPM68 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[22]) );
smpp_middle dPPM69 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[26]) );
smpp_middle dPPM70 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[32]) );
smpp_middle dPPM71 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[37]) );
smpp_middle dPPM72 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[44]) );
smpp_middle dPPM73 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[50]) );
smpp_middle dPPM74 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[58]) );
smpp_middle dPPM75 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[65]) );
smpp_middle dPPM76 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[74]) );
smpp_middle dPPM77 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[82]) );
smpp_middle dPPM78 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[92]) );
smpp_middle dPPM79 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[101]) );
smpp_middle dPPM80 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[112]) );
smpp_middle dPPM81 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[122]) );
smpp_middle dPPM82 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[134]) );
smpp_middle dPPM83 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[145]) );
smpp_middle dPPM84 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[158]) );
smpp_middle dPPM85 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[170]) );
smpp_middle dPPM86 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[184]) );
smpp_middle dPPM87 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[197]) );
smpp_middle dPPM88 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[212]) );
smpp_middle dPPM89 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[226]) );
smpp_middle dPPM90 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[242]) );
smpp_middle dPPM91 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[257]) );
smpp_middle dPPM92 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[274]) );
smpp_middle dPPM93 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[290]) );
smpp_middle dPPM94 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[308]) );
smpp_middle dPPM95 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[326]) );
smpp_middle dPPM96 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[343]) );
smpp_middle dPPM97 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[359]) );
smpp_middle dPPM98 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[374]) );
assign SUMMAND[375] = LOGIC_ONE;
smpp_high dPPH2 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[8]), .TWONEG (INT_MULTIPLIER[9]), .ONEPOS (INT_MULTIPLIER[10]), .ONENEG (INT_MULTIPLIER[11]), .PPBIT (SUMMAND[390]) );
smdecoder dDEC3 (.INA (OPB[5]), .INB (OPB[6]), .INC (OPB[7]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]) );
smpp_low dPPL3 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[18]) );
smr_gate dRGATE3 (.INA (OPB[5]), .INB (OPB[6]), .INC (OPB[7]), .PPBIT (SUMMAND[19]) );
smpp_middle dPPM99 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[23]) );
smpp_middle dPPM100 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[27]) );
smpp_middle dPPM101 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[33]) );
smpp_middle dPPM102 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[38]) );
smpp_middle dPPM103 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[45]) );
smpp_middle dPPM104 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[51]) );
smpp_middle dPPM105 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[59]) );
smpp_middle dPPM106 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[66]) );
smpp_middle dPPM107 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[75]) );
smpp_middle dPPM108 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[83]) );
smpp_middle dPPM109 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[93]) );
smpp_middle dPPM110 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[102]) );
smpp_middle dPPM111 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[113]) );
smpp_middle dPPM112 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[123]) );
smpp_middle dPPM113 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[135]) );
smpp_middle dPPM114 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[146]) );
smpp_middle dPPM115 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[159]) );
smpp_middle dPPM116 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[171]) );
smpp_middle dPPM117 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[185]) );
smpp_middle dPPM118 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[198]) );
smpp_middle dPPM119 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[213]) );
smpp_middle dPPM120 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[227]) );
smpp_middle dPPM121 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[243]) );
smpp_middle dPPM122 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[258]) );
smpp_middle dPPM123 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[275]) );
smpp_middle dPPM124 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[291]) );
smpp_middle dPPM125 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[309]) );
smpp_middle dPPM126 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[327]) );
smpp_middle dPPM127 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[344]) );
smpp_middle dPPM128 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[360]) );
smpp_middle dPPM129 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[376]) );
smpp_middle dPPM130 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[391]) );
smpp_middle dPPM131 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[405]) );
assign SUMMAND[406] = LOGIC_ONE;
smpp_high dPPH3 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[12]), .TWONEG (INT_MULTIPLIER[13]), .ONEPOS (INT_MULTIPLIER[14]), .ONENEG (INT_MULTIPLIER[15]), .PPBIT (SUMMAND[420]) );
smdecoder dDEC4 (.INA (OPB[7]), .INB (OPB[8]), .INC (OPB[9]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]) );
smpp_low dPPL4 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[28]) );
smr_gate dRGATE4 (.INA (OPB[7]), .INB (OPB[8]), .INC (OPB[9]), .PPBIT (SUMMAND[29]) );
smpp_middle dPPM132 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[34]) );
smpp_middle dPPM133 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[39]) );
smpp_middle dPPM134 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[46]) );
smpp_middle dPPM135 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[52]) );
smpp_middle dPPM136 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[60]) );
smpp_middle dPPM137 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[67]) );
smpp_middle dPPM138 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[76]) );
smpp_middle dPPM139 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[84]) );
smpp_middle dPPM140 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[94]) );
smpp_middle dPPM141 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[103]) );
smpp_middle dPPM142 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[114]) );
smpp_middle dPPM143 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[124]) );
smpp_middle dPPM144 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[136]) );
smpp_middle dPPM145 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[147]) );
smpp_middle dPPM146 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[160]) );
smpp_middle dPPM147 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[172]) );
smpp_middle dPPM148 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[186]) );
smpp_middle dPPM149 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[199]) );
smpp_middle dPPM150 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[214]) );
smpp_middle dPPM151 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[228]) );
smpp_middle dPPM152 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[244]) );
smpp_middle dPPM153 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[259]) );
smpp_middle dPPM154 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[276]) );
smpp_middle dPPM155 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[292]) );
smpp_middle dPPM156 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[310]) );
smpp_middle dPPM157 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[328]) );
smpp_middle dPPM158 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[345]) );
smpp_middle dPPM159 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[361]) );
smpp_middle dPPM160 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[377]) );
smpp_middle dPPM161 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[392]) );
smpp_middle dPPM162 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[407]) );
smpp_middle dPPM163 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[421]) );
smpp_middle dPPM164 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[434]) );
assign SUMMAND[435] = LOGIC_ONE;
smpp_high dPPH4 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[16]), .TWONEG (INT_MULTIPLIER[17]), .ONEPOS (INT_MULTIPLIER[18]), .ONENEG (INT_MULTIPLIER[19]), .PPBIT (SUMMAND[448]) );
smdecoder dDEC5 (.INA (OPB[9]), .INB (OPB[10]), .INC (OPB[11]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]) );
smpp_low dPPL5 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[40]) );
smr_gate dRGATE5 (.INA (OPB[9]), .INB (OPB[10]), .INC (OPB[11]), .PPBIT (SUMMAND[41]) );
smpp_middle dPPM165 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[47]) );
smpp_middle dPPM166 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[53]) );
smpp_middle dPPM167 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[61]) );
smpp_middle dPPM168 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[68]) );
smpp_middle dPPM169 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[77]) );
smpp_middle dPPM170 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[85]) );
smpp_middle dPPM171 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[95]) );
smpp_middle dPPM172 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[104]) );
smpp_middle dPPM173 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[115]) );
smpp_middle dPPM174 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[125]) );
smpp_middle dPPM175 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[137]) );
smpp_middle dPPM176 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[148]) );
smpp_middle dPPM177 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[161]) );
smpp_middle dPPM178 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[173]) );
smpp_middle dPPM179 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[187]) );
smpp_middle dPPM180 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[200]) );
smpp_middle dPPM181 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[215]) );
smpp_middle dPPM182 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[229]) );
smpp_middle dPPM183 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[245]) );
smpp_middle dPPM184 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[260]) );
smpp_middle dPPM185 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[277]) );
smpp_middle dPPM186 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[293]) );
smpp_middle dPPM187 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[311]) );
smpp_middle dPPM188 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[329]) );
smpp_middle dPPM189 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[346]) );
smpp_middle dPPM190 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[362]) );
smpp_middle dPPM191 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[378]) );
smpp_middle dPPM192 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[393]) );
smpp_middle dPPM193 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[408]) );
smpp_middle dPPM194 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[422]) );
smpp_middle dPPM195 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[436]) );
smpp_middle dPPM196 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[449]) );
smpp_middle dPPM197 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[461]) );
assign SUMMAND[462] = LOGIC_ONE;
smpp_high dPPH5 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[20]), .TWONEG (INT_MULTIPLIER[21]), .ONEPOS (INT_MULTIPLIER[22]), .ONENEG (INT_MULTIPLIER[23]), .PPBIT (SUMMAND[474]) );
smdecoder dDEC6 (.INA (OPB[11]), .INB (OPB[12]), .INC (OPB[13]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]) );
smpp_low dPPL6 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[54]) );
smr_gate dRGATE6 (.INA (OPB[11]), .INB (OPB[12]), .INC (OPB[13]), .PPBIT (SUMMAND[55]) );
smpp_middle dPPM198 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[62]) );
smpp_middle dPPM199 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[69]) );
smpp_middle dPPM200 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[78]) );
smpp_middle dPPM201 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[86]) );
smpp_middle dPPM202 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[96]) );
smpp_middle dPPM203 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[105]) );
smpp_middle dPPM204 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[116]) );
smpp_middle dPPM205 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[126]) );
smpp_middle dPPM206 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[138]) );
smpp_middle dPPM207 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[149]) );
smpp_middle dPPM208 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[162]) );
smpp_middle dPPM209 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[174]) );
smpp_middle dPPM210 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[188]) );
smpp_middle dPPM211 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[201]) );
smpp_middle dPPM212 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[216]) );
smpp_middle dPPM213 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[230]) );
smpp_middle dPPM214 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[246]) );
smpp_middle dPPM215 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[261]) );
smpp_middle dPPM216 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[278]) );
smpp_middle dPPM217 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[294]) );
smpp_middle dPPM218 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[312]) );
smpp_middle dPPM219 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[330]) );
smpp_middle dPPM220 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[347]) );
smpp_middle dPPM221 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[363]) );
smpp_middle dPPM222 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[379]) );
smpp_middle dPPM223 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[394]) );
smpp_middle dPPM224 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[409]) );
smpp_middle dPPM225 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[423]) );
smpp_middle dPPM226 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[437]) );
smpp_middle dPPM227 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[450]) );
smpp_middle dPPM228 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[463]) );
smpp_middle dPPM229 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[475]) );
smpp_middle dPPM230 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[486]) );
assign SUMMAND[487] = LOGIC_ONE;
smpp_high dPPH6 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[24]), .TWONEG (INT_MULTIPLIER[25]), .ONEPOS (INT_MULTIPLIER[26]), .ONENEG (INT_MULTIPLIER[27]), .PPBIT (SUMMAND[498]) );
smdecoder dDEC7 (.INA (OPB[13]), .INB (OPB[14]), .INC (OPB[15]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]) );
smpp_low dPPL7 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[70]) );
smr_gate dRGATE7 (.INA (OPB[13]), .INB (OPB[14]), .INC (OPB[15]), .PPBIT (SUMMAND[71]) );
smpp_middle dPPM231 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[79]) );
smpp_middle dPPM232 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[87]) );
smpp_middle dPPM233 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[97]) );
smpp_middle dPPM234 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[106]) );
smpp_middle dPPM235 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[117]) );
smpp_middle dPPM236 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[127]) );
smpp_middle dPPM237 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[139]) );
smpp_middle dPPM238 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[150]) );
smpp_middle dPPM239 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[163]) );
smpp_middle dPPM240 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[175]) );
smpp_middle dPPM241 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[189]) );
smpp_middle dPPM242 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[202]) );
smpp_middle dPPM243 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[217]) );
smpp_middle dPPM244 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[231]) );
smpp_middle dPPM245 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[247]) );
smpp_middle dPPM246 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[262]) );
smpp_middle dPPM247 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[279]) );
smpp_middle dPPM248 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[295]) );
smpp_middle dPPM249 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[313]) );
smpp_middle dPPM250 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[331]) );
smpp_middle dPPM251 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[348]) );
smpp_middle dPPM252 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[364]) );
smpp_middle dPPM253 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[380]) );
smpp_middle dPPM254 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[395]) );
smpp_middle dPPM255 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[410]) );
smpp_middle dPPM256 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[424]) );
smpp_middle dPPM257 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[438]) );
smpp_middle dPPM258 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[451]) );
smpp_middle dPPM259 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[464]) );
smpp_middle dPPM260 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[476]) );
smpp_middle dPPM261 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[488]) );
smpp_middle dPPM262 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[499]) );
smpp_middle dPPM263 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[509]) );
assign SUMMAND[510] = LOGIC_ONE;
smpp_high dPPH7 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[28]), .TWONEG (INT_MULTIPLIER[29]), .ONEPOS (INT_MULTIPLIER[30]), .ONENEG (INT_MULTIPLIER[31]), .PPBIT (SUMMAND[520]) );
smdecoder dDEC8 (.INA (OPB[15]), .INB (OPB[16]), .INC (OPB[17]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]) );
smpp_low dPPL8 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[88]) );
smr_gate dRGATE8 (.INA (OPB[15]), .INB (OPB[16]), .INC (OPB[17]), .PPBIT (SUMMAND[89]) );
smpp_middle dPPM264 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[98]) );
smpp_middle dPPM265 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[107]) );
smpp_middle dPPM266 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[118]) );
smpp_middle dPPM267 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[128]) );
smpp_middle dPPM268 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[140]) );
smpp_middle dPPM269 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[151]) );
smpp_middle dPPM270 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[164]) );
smpp_middle dPPM271 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[176]) );
smpp_middle dPPM272 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[190]) );
smpp_middle dPPM273 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[203]) );
smpp_middle dPPM274 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[218]) );
smpp_middle dPPM275 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[232]) );
smpp_middle dPPM276 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[248]) );
smpp_middle dPPM277 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[263]) );
smpp_middle dPPM278 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[280]) );
smpp_middle dPPM279 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[296]) );
smpp_middle dPPM280 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[314]) );
smpp_middle dPPM281 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[332]) );
smpp_middle dPPM282 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[349]) );
smpp_middle dPPM283 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[365]) );
smpp_middle dPPM284 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[381]) );
smpp_middle dPPM285 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[396]) );
smpp_middle dPPM286 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[411]) );
smpp_middle dPPM287 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[425]) );
smpp_middle dPPM288 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[439]) );
smpp_middle dPPM289 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[452]) );
smpp_middle dPPM290 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[465]) );
smpp_middle dPPM291 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[477]) );
smpp_middle dPPM292 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[489]) );
smpp_middle dPPM293 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[500]) );
smpp_middle dPPM294 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[511]) );
smpp_middle dPPM295 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[521]) );
smpp_middle dPPM296 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[530]) );
assign SUMMAND[531] = LOGIC_ONE;
smpp_high dPPH8 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[32]), .TWONEG (INT_MULTIPLIER[33]), .ONEPOS (INT_MULTIPLIER[34]), .ONENEG (INT_MULTIPLIER[35]), .PPBIT (SUMMAND[540]) );
smdecoder dDEC9 (.INA (OPB[17]), .INB (OPB[18]), .INC (OPB[19]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]) );
smpp_low dPPL9 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[108]) );
smr_gate dRGATE9 (.INA (OPB[17]), .INB (OPB[18]), .INC (OPB[19]), .PPBIT (SUMMAND[109]) );
smpp_middle dPPM297 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[119]) );
smpp_middle dPPM298 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[129]) );
smpp_middle dPPM299 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[141]) );
smpp_middle dPPM300 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[152]) );
smpp_middle dPPM301 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[165]) );
smpp_middle dPPM302 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[177]) );
smpp_middle dPPM303 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[191]) );
smpp_middle dPPM304 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[204]) );
smpp_middle dPPM305 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[219]) );
smpp_middle dPPM306 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[233]) );
smpp_middle dPPM307 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[249]) );
smpp_middle dPPM308 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[264]) );
smpp_middle dPPM309 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[281]) );
smpp_middle dPPM310 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[297]) );
smpp_middle dPPM311 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[315]) );
smpp_middle dPPM312 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[333]) );
smpp_middle dPPM313 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[350]) );
smpp_middle dPPM314 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[366]) );
smpp_middle dPPM315 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[382]) );
smpp_middle dPPM316 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[397]) );
smpp_middle dPPM317 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[412]) );
smpp_middle dPPM318 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[426]) );
smpp_middle dPPM319 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[440]) );
smpp_middle dPPM320 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[453]) );
smpp_middle dPPM321 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[466]) );
smpp_middle dPPM322 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[478]) );
smpp_middle dPPM323 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[490]) );
smpp_middle dPPM324 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[501]) );
smpp_middle dPPM325 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[512]) );
smpp_middle dPPM326 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[522]) );
smpp_middle dPPM327 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[532]) );
smpp_middle dPPM328 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[541]) );
smpp_middle dPPM329 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[549]) );
assign SUMMAND[550] = LOGIC_ONE;
smpp_high dPPH9 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[36]), .TWONEG (INT_MULTIPLIER[37]), .ONEPOS (INT_MULTIPLIER[38]), .ONENEG (INT_MULTIPLIER[39]), .PPBIT (SUMMAND[558]) );
smdecoder dDEC10 (.INA (OPB[19]), .INB (OPB[20]), .INC (OPB[21]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]) );
smpp_low dPPL10 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[130]) );
smr_gate dRGATE10 (.INA (OPB[19]), .INB (OPB[20]), .INC (OPB[21]), .PPBIT (SUMMAND[131]) );
smpp_middle dPPM330 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[142]) );
smpp_middle dPPM331 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[153]) );
smpp_middle dPPM332 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[166]) );
smpp_middle dPPM333 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[178]) );
smpp_middle dPPM334 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[192]) );
smpp_middle dPPM335 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[205]) );
smpp_middle dPPM336 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[220]) );
smpp_middle dPPM337 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[234]) );
smpp_middle dPPM338 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[250]) );
smpp_middle dPPM339 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[265]) );
smpp_middle dPPM340 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[282]) );
smpp_middle dPPM341 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[298]) );
smpp_middle dPPM342 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[316]) );
smpp_middle dPPM343 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[334]) );
smpp_middle dPPM344 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[351]) );
smpp_middle dPPM345 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[367]) );
smpp_middle dPPM346 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[383]) );
smpp_middle dPPM347 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[398]) );
smpp_middle dPPM348 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[413]) );
smpp_middle dPPM349 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[427]) );
smpp_middle dPPM350 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[441]) );
smpp_middle dPPM351 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[454]) );
smpp_middle dPPM352 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[467]) );
smpp_middle dPPM353 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[479]) );
smpp_middle dPPM354 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[491]) );
smpp_middle dPPM355 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[502]) );
smpp_middle dPPM356 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[513]) );
smpp_middle dPPM357 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[523]) );
smpp_middle dPPM358 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[533]) );
smpp_middle dPPM359 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[542]) );
smpp_middle dPPM360 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[551]) );
smpp_middle dPPM361 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[559]) );
smpp_middle dPPM362 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[566]) );
assign SUMMAND[567] = LOGIC_ONE;
smpp_high dPPH10 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[40]), .TWONEG (INT_MULTIPLIER[41]), .ONEPOS (INT_MULTIPLIER[42]), .ONENEG (INT_MULTIPLIER[43]), .PPBIT (SUMMAND[574]) );
smdecoder dDEC11 (.INA (OPB[21]), .INB (OPB[22]), .INC (OPB[23]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]) );
smpp_low dPPL11 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[154]) );
smr_gate dRGATE11 (.INA (OPB[21]), .INB (OPB[22]), .INC (OPB[23]), .PPBIT (SUMMAND[155]) );
smpp_middle dPPM363 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[167]) );
smpp_middle dPPM364 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[179]) );
smpp_middle dPPM365 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[193]) );
smpp_middle dPPM366 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[206]) );
smpp_middle dPPM367 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[221]) );
smpp_middle dPPM368 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[235]) );
smpp_middle dPPM369 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[251]) );
smpp_middle dPPM370 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[266]) );
smpp_middle dPPM371 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[283]) );
smpp_middle dPPM372 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[299]) );
smpp_middle dPPM373 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[317]) );
smpp_middle dPPM374 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[335]) );
smpp_middle dPPM375 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[352]) );
smpp_middle dPPM376 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[368]) );
smpp_middle dPPM377 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[384]) );
smpp_middle dPPM378 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[399]) );
smpp_middle dPPM379 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[414]) );
smpp_middle dPPM380 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[428]) );
smpp_middle dPPM381 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[442]) );
smpp_middle dPPM382 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[455]) );
smpp_middle dPPM383 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[468]) );
smpp_middle dPPM384 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[480]) );
smpp_middle dPPM385 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[492]) );
smpp_middle dPPM386 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[503]) );
smpp_middle dPPM387 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[514]) );
smpp_middle dPPM388 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[524]) );
smpp_middle dPPM389 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[534]) );
smpp_middle dPPM390 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[543]) );
smpp_middle dPPM391 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[552]) );
smpp_middle dPPM392 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[560]) );
smpp_middle dPPM393 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[568]) );
smpp_middle dPPM394 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[575]) );
smpp_middle dPPM395 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[581]) );
assign SUMMAND[582] = LOGIC_ONE;
smpp_high dPPH11 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[44]), .TWONEG (INT_MULTIPLIER[45]), .ONEPOS (INT_MULTIPLIER[46]), .ONENEG (INT_MULTIPLIER[47]), .PPBIT (SUMMAND[588]) );
smdecoder dDEC12 (.INA (OPB[23]), .INB (OPB[24]), .INC (OPB[25]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]) );
smpp_low dPPL12 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[180]) );
smr_gate dRGATE12 (.INA (OPB[23]), .INB (OPB[24]), .INC (OPB[25]), .PPBIT (SUMMAND[181]) );
smpp_middle dPPM396 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[194]) );
smpp_middle dPPM397 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[207]) );
smpp_middle dPPM398 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[222]) );
smpp_middle dPPM399 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[236]) );
smpp_middle dPPM400 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[252]) );
smpp_middle dPPM401 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[267]) );
smpp_middle dPPM402 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[284]) );
smpp_middle dPPM403 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[300]) );
smpp_middle dPPM404 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[318]) );
smpp_middle dPPM405 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[336]) );
smpp_middle dPPM406 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[353]) );
smpp_middle dPPM407 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[369]) );
smpp_middle dPPM408 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[385]) );
smpp_middle dPPM409 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[400]) );
smpp_middle dPPM410 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[415]) );
smpp_middle dPPM411 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[429]) );
smpp_middle dPPM412 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[443]) );
smpp_middle dPPM413 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[456]) );
smpp_middle dPPM414 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[469]) );
smpp_middle dPPM415 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[481]) );
smpp_middle dPPM416 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[493]) );
smpp_middle dPPM417 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[504]) );
smpp_middle dPPM418 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[515]) );
smpp_middle dPPM419 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[525]) );
smpp_middle dPPM420 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[535]) );
smpp_middle dPPM421 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[544]) );
smpp_middle dPPM422 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[553]) );
smpp_middle dPPM423 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[561]) );
smpp_middle dPPM424 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[569]) );
smpp_middle dPPM425 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[576]) );
smpp_middle dPPM426 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[583]) );
smpp_middle dPPM427 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[589]) );
smpp_middle dPPM428 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[594]) );
assign SUMMAND[595] = LOGIC_ONE;
smpp_high dPPH12 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[48]), .TWONEG (INT_MULTIPLIER[49]), .ONEPOS (INT_MULTIPLIER[50]), .ONENEG (INT_MULTIPLIER[51]), .PPBIT (SUMMAND[600]) );
smdecoder dDEC13 (.INA (OPB[25]), .INB (OPB[26]), .INC (OPB[27]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]) );
smpp_low dPPL13 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[208]) );
smr_gate dRGATE13 (.INA (OPB[25]), .INB (OPB[26]), .INC (OPB[27]), .PPBIT (SUMMAND[209]) );
smpp_middle dPPM429 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[223]) );
smpp_middle dPPM430 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[237]) );
smpp_middle dPPM431 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[253]) );
smpp_middle dPPM432 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[268]) );
smpp_middle dPPM433 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[285]) );
smpp_middle dPPM434 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[301]) );
smpp_middle dPPM435 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[319]) );
smpp_middle dPPM436 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[337]) );
smpp_middle dPPM437 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[354]) );
smpp_middle dPPM438 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[370]) );
smpp_middle dPPM439 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[386]) );
smpp_middle dPPM440 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[401]) );
smpp_middle dPPM441 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[416]) );
smpp_middle dPPM442 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[430]) );
smpp_middle dPPM443 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[444]) );
smpp_middle dPPM444 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[457]) );
smpp_middle dPPM445 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[470]) );
smpp_middle dPPM446 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[482]) );
smpp_middle dPPM447 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[494]) );
smpp_middle dPPM448 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[505]) );
smpp_middle dPPM449 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[516]) );
smpp_middle dPPM450 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[526]) );
smpp_middle dPPM451 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[536]) );
smpp_middle dPPM452 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[545]) );
smpp_middle dPPM453 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[554]) );
smpp_middle dPPM454 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[562]) );
smpp_middle dPPM455 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[570]) );
smpp_middle dPPM456 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[577]) );
smpp_middle dPPM457 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[584]) );
smpp_middle dPPM458 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[590]) );
smpp_middle dPPM459 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[596]) );
smpp_middle dPPM460 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[601]) );
smpp_middle dPPM461 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[605]) );
assign SUMMAND[606] = LOGIC_ONE;
smpp_high dPPH13 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[52]), .TWONEG (INT_MULTIPLIER[53]), .ONEPOS (INT_MULTIPLIER[54]), .ONENEG (INT_MULTIPLIER[55]), .PPBIT (SUMMAND[610]) );
smdecoder dDEC14 (.INA (OPB[27]), .INB (OPB[28]), .INC (OPB[29]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]) );
smpp_low dPPL14 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[238]) );
smr_gate dRGATE14 (.INA (OPB[27]), .INB (OPB[28]), .INC (OPB[29]), .PPBIT (SUMMAND[239]) );
smpp_middle dPPM462 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[254]) );
smpp_middle dPPM463 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[269]) );
smpp_middle dPPM464 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[286]) );
smpp_middle dPPM465 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[302]) );
smpp_middle dPPM466 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[320]) );
smpp_middle dPPM467 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[338]) );
smpp_middle dPPM468 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[355]) );
smpp_middle dPPM469 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[371]) );
smpp_middle dPPM470 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[387]) );
smpp_middle dPPM471 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[402]) );
smpp_middle dPPM472 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[417]) );
smpp_middle dPPM473 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[431]) );
smpp_middle dPPM474 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[445]) );
smpp_middle dPPM475 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[458]) );
smpp_middle dPPM476 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[471]) );
smpp_middle dPPM477 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[483]) );
smpp_middle dPPM478 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[495]) );
smpp_middle dPPM479 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[506]) );
smpp_middle dPPM480 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[517]) );
smpp_middle dPPM481 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[527]) );
smpp_middle dPPM482 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[537]) );
smpp_middle dPPM483 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[546]) );
smpp_middle dPPM484 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[555]) );
smpp_middle dPPM485 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[563]) );
smpp_middle dPPM486 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[571]) );
smpp_middle dPPM487 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[578]) );
smpp_middle dPPM488 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[585]) );
smpp_middle dPPM489 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[591]) );
smpp_middle dPPM490 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[597]) );
smpp_middle dPPM491 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[602]) );
smpp_middle dPPM492 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[607]) );
smpp_middle dPPM493 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[611]) );
smpp_middle dPPM494 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[614]) );
assign SUMMAND[615] = LOGIC_ONE;
smpp_high dPPH14 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[56]), .TWONEG (INT_MULTIPLIER[57]), .ONEPOS (INT_MULTIPLIER[58]), .ONENEG (INT_MULTIPLIER[59]), .PPBIT (SUMMAND[618]) );
smdecoder dDEC15 (.INA (OPB[29]), .INB (OPB[30]), .INC (OPB[31]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]) );
smpp_low dPPL15 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[270]) );
smr_gate dRGATE15 (.INA (OPB[29]), .INB (OPB[30]), .INC (OPB[31]), .PPBIT (SUMMAND[271]) );
smpp_middle dPPM495 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[287]) );
smpp_middle dPPM496 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[303]) );
smpp_middle dPPM497 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[321]) );
smpp_middle dPPM498 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[339]) );
smpp_middle dPPM499 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[356]) );
smpp_middle dPPM500 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[372]) );
smpp_middle dPPM501 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[388]) );
smpp_middle dPPM502 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[403]) );
smpp_middle dPPM503 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[418]) );
smpp_middle dPPM504 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[432]) );
smpp_middle dPPM505 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[446]) );
smpp_middle dPPM506 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[459]) );
smpp_middle dPPM507 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[472]) );
smpp_middle dPPM508 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[484]) );
smpp_middle dPPM509 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[496]) );
smpp_middle dPPM510 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[507]) );
smpp_middle dPPM511 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[518]) );
smpp_middle dPPM512 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[528]) );
smpp_middle dPPM513 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[538]) );
smpp_middle dPPM514 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[547]) );
smpp_middle dPPM515 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[556]) );
smpp_middle dPPM516 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[564]) );
smpp_middle dPPM517 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[572]) );
smpp_middle dPPM518 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[579]) );
smpp_middle dPPM519 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[586]) );
smpp_middle dPPM520 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[592]) );
smpp_middle dPPM521 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[598]) );
smpp_middle dPPM522 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[603]) );
smpp_middle dPPM523 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[608]) );
smpp_middle dPPM524 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[612]) );
smpp_middle dPPM525 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[616]) );
smpp_middle dPPM526 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[619]) );
smpp_middle dPPM527 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[621]) );
assign SUMMAND[622] = LOGIC_ONE;
smpp_high dPPH15 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[60]), .TWONEG (INT_MULTIPLIER[61]), .ONEPOS (INT_MULTIPLIER[62]), .ONENEG (INT_MULTIPLIER[63]), .PPBIT (SUMMAND[624]) );
smdecoder dDEC16 (.INA (OPB[31]), .INB (OPB[32]), .INC (OPB[33]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]) );
smpp_low dPPL16 (.INA (OPA[0]), .INB (OPA_[0]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[304]) );
smr_gate dRGATE16 (.INA (OPB[31]), .INB (OPB[32]), .INC (OPB[33]), .PPBIT (SUMMAND[305]) );
smpp_middle dPPM528 (.INA (OPA[0]), .INB (OPA_[0]), .INC (OPA[1]), .IND (OPA_[1]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[322]) );
smpp_middle dPPM529 (.INA (OPA[1]), .INB (OPA_[1]), .INC (OPA[2]), .IND (OPA_[2]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[340]) );
smpp_middle dPPM530 (.INA (OPA[2]), .INB (OPA_[2]), .INC (OPA[3]), .IND (OPA_[3]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[357]) );
smpp_middle dPPM531 (.INA (OPA[3]), .INB (OPA_[3]), .INC (OPA[4]), .IND (OPA_[4]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[373]) );
smpp_middle dPPM532 (.INA (OPA[4]), .INB (OPA_[4]), .INC (OPA[5]), .IND (OPA_[5]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[389]) );
smpp_middle dPPM533 (.INA (OPA[5]), .INB (OPA_[5]), .INC (OPA[6]), .IND (OPA_[6]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[404]) );
smpp_middle dPPM534 (.INA (OPA[6]), .INB (OPA_[6]), .INC (OPA[7]), .IND (OPA_[7]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[419]) );
smpp_middle dPPM535 (.INA (OPA[7]), .INB (OPA_[7]), .INC (OPA[8]), .IND (OPA_[8]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[433]) );
smpp_middle dPPM536 (.INA (OPA[8]), .INB (OPA_[8]), .INC (OPA[9]), .IND (OPA_[9]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[447]) );
smpp_middle dPPM537 (.INA (OPA[9]), .INB (OPA_[9]), .INC (OPA[10]), .IND (OPA_[10]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[460]) );
smpp_middle dPPM538 (.INA (OPA[10]), .INB (OPA_[10]), .INC (OPA[11]), .IND (OPA_[11]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[473]) );
smpp_middle dPPM539 (.INA (OPA[11]), .INB (OPA_[11]), .INC (OPA[12]), .IND (OPA_[12]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[485]) );
smpp_middle dPPM540 (.INA (OPA[12]), .INB (OPA_[12]), .INC (OPA[13]), .IND (OPA_[13]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[497]) );
smpp_middle dPPM541 (.INA (OPA[13]), .INB (OPA_[13]), .INC (OPA[14]), .IND (OPA_[14]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[508]) );
smpp_middle dPPM542 (.INA (OPA[14]), .INB (OPA_[14]), .INC (OPA[15]), .IND (OPA_[15]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[519]) );
smpp_middle dPPM543 (.INA (OPA[15]), .INB (OPA_[15]), .INC (OPA[16]), .IND (OPA_[16]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[529]) );
smpp_middle dPPM544 (.INA (OPA[16]), .INB (OPA_[16]), .INC (OPA[17]), .IND (OPA_[17]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[539]) );
smpp_middle dPPM545 (.INA (OPA[17]), .INB (OPA_[17]), .INC (OPA[18]), .IND (OPA_[18]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[548]) );
smpp_middle dPPM546 (.INA (OPA[18]), .INB (OPA_[18]), .INC (OPA[19]), .IND (OPA_[19]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[557]) );
smpp_middle dPPM547 (.INA (OPA[19]), .INB (OPA_[19]), .INC (OPA[20]), .IND (OPA_[20]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[565]) );
smpp_middle dPPM548 (.INA (OPA[20]), .INB (OPA_[20]), .INC (OPA[21]), .IND (OPA_[21]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[573]) );
smpp_middle dPPM549 (.INA (OPA[21]), .INB (OPA_[21]), .INC (OPA[22]), .IND (OPA_[22]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[580]) );
smpp_middle dPPM550 (.INA (OPA[22]), .INB (OPA_[22]), .INC (OPA[23]), .IND (OPA_[23]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[587]) );
smpp_middle dPPM551 (.INA (OPA[23]), .INB (OPA_[23]), .INC (OPA[24]), .IND (OPA_[24]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[593]) );
smpp_middle dPPM552 (.INA (OPA[24]), .INB (OPA_[24]), .INC (OPA[25]), .IND (OPA_[25]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[599]) );
smpp_middle dPPM553 (.INA (OPA[25]), .INB (OPA_[25]), .INC (OPA[26]), .IND (OPA_[26]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[604]) );
smpp_middle dPPM554 (.INA (OPA[26]), .INB (OPA_[26]), .INC (OPA[27]), .IND (OPA_[27]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[609]) );
smpp_middle dPPM555 (.INA (OPA[27]), .INB (OPA_[27]), .INC (OPA[28]), .IND (OPA_[28]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[613]) );
smpp_middle dPPM556 (.INA (OPA[28]), .INB (OPA_[28]), .INC (OPA[29]), .IND (OPA_[29]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[617]) );
smpp_middle dPPM557 (.INA (OPA[29]), .INB (OPA_[29]), .INC (OPA[30]), .IND (OPA_[30]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[620]) );
smpp_middle dPPM558 (.INA (OPA[30]), .INB (OPA_[30]), .INC (OPA[31]), .IND (OPA_[31]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[623]) );
smpp_middle dPPM559 (.INA (OPA[31]), .INB (OPA_[31]), .INC (OPA[32]), .IND (OPA_[32]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[625]) );
smpp_middle dPPM560 (.INA (OPA[32]), .INB (OPA_[32]), .INC (OPA[33]), .IND (OPA_[33]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[626]) );
assign SUMMAND[627] = LOGIC_ONE;
smpp_high dPPH16 (.INA (OPA[33]), .INB (OPA_[33]), .TWOPOS (INT_MULTIPLIER[64]), .TWONEG (INT_MULTIPLIER[65]), .ONEPOS (INT_MULTIPLIER[66]), .ONENEG (INT_MULTIPLIER[67]), .PPBIT (SUMMAND[628]) );
endmodule
// Simple cells
module smpp_low ( ONEPOS, ONENEG, TWONEG, INA, INB, PPBIT );
input ONEPOS;
input ONENEG;
input TWONEG;
input INA;
input INB;
output PPBIT;
assign PPBIT = (ONEPOS & INA) | (ONENEG & INB) | TWONEG;
endmodule
module smpp_middle ( ONEPOS, ONENEG, TWOPOS, TWONEG, INA, INB, INC, IND, PPBIT );
input ONEPOS;
input ONENEG;
input TWOPOS;
input TWONEG;
input INA;
input INB;
input INC;
input IND;
output PPBIT;
assign PPBIT = ~ (( ~ (INA & TWOPOS)) & ( ~ (INB & TWONEG)) & ( ~ (INC & ONEPOS)) & ( ~ (IND & ONENEG)));
endmodule
module smpp_high ( ONEPOS, ONENEG, TWOPOS, TWONEG, INA, INB, PPBIT );
input ONEPOS;
input ONENEG;
input TWOPOS;
input TWONEG;
input INA;
input INB;
output PPBIT;
assign PPBIT = ~ ((INA & ONEPOS) | (INB & ONENEG) | (INA & TWOPOS) | (INB & TWONEG));
endmodule
module smr_gate ( INA, INB, INC, PPBIT );
input INA;
input INB;
input INC;
output PPBIT;
assign PPBIT = ( ~ (INA & INB)) & INC;
endmodule
module smdecoder ( INA, INB, INC, TWOPOS, TWONEG, ONEPOS, ONENEG );
input INA;
input INB;
input INC;
output TWOPOS;
output TWONEG;
output ONEPOS;
output ONENEG;
assign TWOPOS = ~ ( ~ (INA & INB & ( ~ INC)));
assign TWONEG = ~ ( ~ (( ~ INA) & ( ~ INB) & INC));
assign ONEPOS = (( ~ INA) & INB & ( ~ INC)) | (( ~ INC) & ( ~ INB) & INA);
assign ONENEG = (INA & ( ~ INB) & INC) | (INC & INB & ( ~ INA));
endmodule
module smfulladder ( DATA_A, DATA_B, DATA_C, SAVE, CARRY );
input DATA_A;
input DATA_B;
input DATA_C;
output SAVE;
output CARRY;
wire TMP;
assign TMP = DATA_A ^ DATA_B;
assign SAVE = TMP ^ DATA_C;
assign CARRY = ~ (( ~ (TMP & DATA_C)) & ( ~ (DATA_A & DATA_B)));
endmodule
module smhalfadder ( DATA_A, DATA_B, SAVE, CARRY );
input DATA_A;
input DATA_B;
output SAVE;
output CARRY;
assign SAVE = DATA_A ^ DATA_B;
assign CARRY = DATA_A & DATA_B;
endmodule
module smffa
(
input clk,
input en_d1,
input D,
output reg Q
);
always @ (posedge clk) begin
Q <= D;
end
endmodule
module smffb
(
input clk,
input en_d2,
input D,
output reg Q
);
always @ (posedge clk) begin
Q <= D;
end
endmodule
module sminvblock ( GIN, GOUT );
input GIN;
output GOUT;
assign GOUT = ~ GIN;
endmodule
module smxxor1 ( A, B, GIN, SUM );
input A;
input B;
input GIN;
output SUM;
assign SUM = ( ~ (A ^ B)) ^ GIN;
endmodule
module smblock0 ( A, B, POUT, GOUT );
input A;
input B;
output POUT;
output GOUT;
assign POUT = ~ (A | B);
assign GOUT = ~ (A & B);
endmodule
module smblock1 ( PIN1, PIN2, GIN1, GIN2, POUT, GOUT );
input PIN1;
input PIN2;
input GIN1;
input GIN2;
output POUT;
output GOUT;
assign POUT = ~ (PIN1 | PIN2);
assign GOUT = ~ (GIN2 & (PIN2 | GIN1));
endmodule
module smblock2 ( PIN1, PIN2, GIN1, GIN2, POUT, GOUT );
input PIN1;
input PIN2;
input GIN1;
input GIN2;
output POUT;
output GOUT;
assign POUT = ~ (PIN1 & PIN2);
assign GOUT = ~ (GIN2 | (PIN2 & GIN1));
endmodule
module smblock1a ( PIN2, GIN1, GIN2, GOUT );
input PIN2;
input GIN1;
input GIN2;
output GOUT;
assign GOUT = ~ (GIN2 & (PIN2 | GIN1));
endmodule
module smblock2a ( PIN2, GIN1, GIN2, GOUT );
input PIN2;
input GIN1;
input GIN2;
output GOUT;
assign GOUT = ~ (GIN2 | (PIN2 & GIN1));
endmodule
// Local Variables:
// compile-command: "vlint --brief --nowarn=MULTMF,MODLNM t_math_wallace_mul.v"
// End:
|
/*
----------------------------------------------------------------------------------
Copyright (c) 2013-2014
Embedded and Network Computing Lab.
Open SSD Project
Hanyang University
All rights reserved.
----------------------------------------------------------------------------------
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. All advertising materials mentioning features or use of this source code
must display the following acknowledgement:
This product includes source code developed
by the Embedded and Network Computing Lab. and the Open SSD Project.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
----------------------------------------------------------------------------------
http://enclab.hanyang.ac.kr/
http://www.openssd-project.org/
http://www.hanyang.ac.kr/
----------------------------------------------------------------------------------
*/
`timescale 1ns / 1ps
module pcie_irq_gen # (
parameter C_PCIE_DATA_WIDTH = 128,
parameter C_PCIE_ADDR_WIDTH = 36
)
(
input pcie_user_clk,
input pcie_user_rst_n,
input [15:0] cfg_command,
output cfg_interrupt,
input cfg_interrupt_rdy,
output cfg_interrupt_assert,
output [7:0] cfg_interrupt_di,
input [7:0] cfg_interrupt_do,
input [2:0] cfg_interrupt_mmenable,
input cfg_interrupt_msienable,
input cfg_interrupt_msixenable,
input cfg_interrupt_msixfm,
output cfg_interrupt_stat,
output [4:0] cfg_pciecap_interrupt_msgnum,
input pcie_legacy_irq_set,
input pcie_msi_irq_set,
input [2:0] pcie_irq_vector,
input pcie_legacy_irq_clear,
output pcie_irq_done
);
localparam S_IDLE = 7'b0000001;
localparam S_SEND_MSI = 7'b0000010;
localparam S_LEGACY_ASSERT = 7'b0000100;
localparam S_LEGACY_ASSERT_HOLD = 7'b0001000;
localparam S_LEGACY_DEASSERT = 7'b0010000;
localparam S_WAIT_RDY_N = 7'b0100000;
localparam S_IRQ_DONE = 7'b1000000;
reg [6:0] cur_state;
reg [6:0] next_state;
reg r_cfg_interrupt;
reg r_cfg_interrupt_assert;
reg [7:0] r_cfg_interrupt_di;
reg [2:0] r_pcie_irq_vector;
reg r_pcie_irq_done;
assign cfg_interrupt = r_cfg_interrupt;
assign cfg_interrupt_assert = r_cfg_interrupt_assert;
assign cfg_interrupt_di = r_cfg_interrupt_di;
assign cfg_interrupt_stat = 1'b0;
assign cfg_pciecap_interrupt_msgnum = 5'b0;
assign pcie_irq_done = r_pcie_irq_done;
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0)
cur_state <= S_IDLE;
else
cur_state <= next_state;
end
always @ (*)
begin
case(cur_state)
S_IDLE: begin
if(pcie_msi_irq_set == 1)
next_state <= S_SEND_MSI;
else if(pcie_legacy_irq_set == 1)
next_state <= S_LEGACY_ASSERT;
else
next_state <= S_IDLE;
end
S_SEND_MSI: begin
if(cfg_interrupt_rdy == 1)
next_state <= S_WAIT_RDY_N;
else
next_state <= S_SEND_MSI;
end
S_LEGACY_ASSERT: begin
if(cfg_interrupt_rdy == 1)
next_state <= S_LEGACY_ASSERT_HOLD;
else
next_state <= S_LEGACY_ASSERT;
end
S_LEGACY_ASSERT_HOLD: begin
if(pcie_legacy_irq_clear == 1)
next_state <= S_LEGACY_DEASSERT;
else
next_state <= S_LEGACY_ASSERT_HOLD;
end
S_LEGACY_DEASSERT: begin
if(cfg_interrupt_rdy == 1)
next_state <= S_WAIT_RDY_N;
else
next_state <= S_LEGACY_DEASSERT;
end
S_WAIT_RDY_N: begin
if(cfg_interrupt_rdy == 0)
next_state <= S_IRQ_DONE;
else
next_state <= S_WAIT_RDY_N;
end
S_IRQ_DONE: begin
next_state <= S_IDLE;
end
default: begin
next_state <= S_IDLE;
end
endcase
end
always @ (posedge pcie_user_clk)
begin
case(cur_state)
S_IDLE: begin
r_pcie_irq_vector <= pcie_irq_vector;
end
S_SEND_MSI: begin
end
S_LEGACY_ASSERT: begin
end
S_LEGACY_ASSERT_HOLD: begin
end
S_LEGACY_DEASSERT: begin
end
S_WAIT_RDY_N: begin
end
S_IRQ_DONE: begin
end
default: begin
end
endcase
end
always @ (*)
begin
case(cur_state)
S_IDLE: begin
r_cfg_interrupt <= 0;
r_cfg_interrupt_assert <= 0;
r_cfg_interrupt_di <= 0;
r_pcie_irq_done <= 0;
end
S_SEND_MSI: begin
r_cfg_interrupt <= 1;
r_cfg_interrupt_assert <= 0;
r_cfg_interrupt_di <= {5'b0, r_pcie_irq_vector};
r_pcie_irq_done <= 0;
end
S_LEGACY_ASSERT: begin
r_cfg_interrupt <= 1;
r_cfg_interrupt_assert <= 1;
r_cfg_interrupt_di <= 0;
r_pcie_irq_done <= 0;
end
S_LEGACY_ASSERT_HOLD: begin
r_cfg_interrupt <= 0;
r_cfg_interrupt_assert <= 1;
r_cfg_interrupt_di <= 0;
r_pcie_irq_done <= 0;
end
S_LEGACY_DEASSERT: begin
r_cfg_interrupt <= 1;
r_cfg_interrupt_assert <= 0;
r_cfg_interrupt_di <= 0;
r_pcie_irq_done <= 0;
end
S_WAIT_RDY_N: begin
r_cfg_interrupt <= 1;
r_cfg_interrupt_assert <= 0;
r_cfg_interrupt_di <= 0;
r_pcie_irq_done <= 0;
end
S_IRQ_DONE: begin
r_cfg_interrupt <= 0;
r_cfg_interrupt_assert <= 0;
r_cfg_interrupt_di <= 0;
r_pcie_irq_done <= 1;
end
default: begin
r_cfg_interrupt <= 0;
r_cfg_interrupt_assert <= 0;
r_cfg_interrupt_di <= 0;
r_pcie_irq_done <= 0;
end
endcase
end
endmodule
|
/*
----------------------------------------------------------------------------------
Copyright (c) 2013-2014
Embedded and Network Computing Lab.
Open SSD Project
Hanyang University
All rights reserved.
----------------------------------------------------------------------------------
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. All advertising materials mentioning features or use of this source code
must display the following acknowledgement:
This product includes source code developed
by the Embedded and Network Computing Lab. and the Open SSD Project.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
----------------------------------------------------------------------------------
http://enclab.hanyang.ac.kr/
http://www.openssd-project.org/
http://www.hanyang.ac.kr/
----------------------------------------------------------------------------------
*/
`timescale 1ns / 1ps
module pcie_hcmd_cq_req # (
parameter C_PCIE_DATA_WIDTH = 128,
parameter C_PCIE_ADDR_WIDTH = 36
)
(
input pcie_user_clk,
input pcie_user_rst_n,
output hcmd_cq_rd_en,
input [34:0] hcmd_cq_rd_data,
input hcmd_cq_empty_n,
output [6:0] hcmd_cid_rd_addr,
input [19:0] hcmd_cid_rd_data,
input [3:0] io_sq1_cq_vec,
input [3:0] io_sq2_cq_vec,
input [3:0] io_sq3_cq_vec,
input [3:0] io_sq4_cq_vec,
input [3:0] io_sq5_cq_vec,
input [3:0] io_sq6_cq_vec,
input [3:0] io_sq7_cq_vec,
input [3:0] io_sq8_cq_vec,
input [8:0] sq_valid,
input [8:0] cq_rst_n,
input [8:0] cq_valid,
input [7:0] admin_cq_size,
input [7:0] io_cq1_size,
input [7:0] io_cq2_size,
input [7:0] io_cq3_size,
input [7:0] io_cq4_size,
input [7:0] io_cq5_size,
input [7:0] io_cq6_size,
input [7:0] io_cq7_size,
input [7:0] io_cq8_size,
input [C_PCIE_ADDR_WIDTH-1:2] admin_cq_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq1_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq2_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq3_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq4_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq5_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq6_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq7_bs_addr,
input [C_PCIE_ADDR_WIDTH-1:2] io_cq8_bs_addr,
output [7:0] admin_cq_tail_ptr,
output [7:0] io_cq1_tail_ptr,
output [7:0] io_cq2_tail_ptr,
output [7:0] io_cq3_tail_ptr,
output [7:0] io_cq4_tail_ptr,
output [7:0] io_cq5_tail_ptr,
output [7:0] io_cq6_tail_ptr,
output [7:0] io_cq7_tail_ptr,
output [7:0] io_cq8_tail_ptr,
input [7:0] admin_sq_head_ptr,
input [7:0] io_sq1_head_ptr,
input [7:0] io_sq2_head_ptr,
input [7:0] io_sq3_head_ptr,
input [7:0] io_sq4_head_ptr,
input [7:0] io_sq5_head_ptr,
input [7:0] io_sq6_head_ptr,
input [7:0] io_sq7_head_ptr,
input [7:0] io_sq8_head_ptr,
output hcmd_slot_free_en,
output [6:0] hcmd_slot_invalid_tag,
output tx_cq_mwr_req,
output [7:0] tx_cq_mwr_tag,
output [11:2] tx_cq_mwr_len,
output [C_PCIE_ADDR_WIDTH-1:2] tx_cq_mwr_addr,
input tx_cq_mwr_req_ack,
input tx_cq_mwr_rd_en,
output [C_PCIE_DATA_WIDTH-1:0] tx_cq_mwr_rd_data,
input tx_cq_mwr_data_last
);
localparam LP_CPL_PCIE_TAG_PREFIX = 8'b00000000;
localparam LP_CPL_SIZE = 10'h04;
localparam S_IDLE = 11'b00000000001;
localparam S_CPL_STATUS0 = 11'b00000000010;
localparam S_CPL_STATUS1 = 11'b00000000100;
localparam S_CPL_STATUS2 = 11'b00000001000;
localparam S_CPL_STATUS3 = 11'b00000010000;
localparam S_HEAD_PTR = 11'b00000100000;
localparam S_PCIE_ADDR = 11'b00001000000;
localparam S_PCIE_MWR_REQ = 11'b00010000000;
localparam S_PCIE_MWR_DATA_LAST = 11'b00100000000;
localparam S_PCIE_MWR_DONE = 11'b01000000000;
localparam S_PCIE_SLOT_RELEASE = 11'b10000000000;
reg [10:0] cur_state;
reg [10:0] next_state;
reg r_sq_is_valid;
reg r_cq_is_valid;
reg [7:0] r_admin_cq_tail_ptr;
reg [7:0] r_io_cq1_tail_ptr;
reg [7:0] r_io_cq2_tail_ptr;
reg [7:0] r_io_cq3_tail_ptr;
reg [7:0] r_io_cq4_tail_ptr;
reg [7:0] r_io_cq5_tail_ptr;
reg [7:0] r_io_cq6_tail_ptr;
reg [7:0] r_io_cq7_tail_ptr;
reg [7:0] r_io_cq8_tail_ptr;
reg [8:0] r_cq_phase_tag;
reg [3:0] r_sq_cq_vec;
reg [8:0] r_cq_valid_entry;
reg [8:0] r_cq_update_entry;
reg r_hcmd_cq_rd_en;
wire [6:0] w_hcmd_slot_tag;
reg r_hcmd_slot_free_en;
reg [1:0] r_cql_type;
reg [19:0] r_cql_info;
reg [3:0] r_cpl_sq_qid;
reg [15:0] r_cpl_cid;
reg [14:0] r_cpl_status;
reg [31:0] r_cpl_specific;
reg [7:0] r_cq_tail_ptr;
reg [7:0] r_sq_head_ptr;
reg r_phase_tag;
reg r_tx_cq_mwr_req;
reg [C_PCIE_ADDR_WIDTH-1:2] r_tx_cq_mwr_addr;
wire [31:0] w_cpl_dw0;
wire [31:0] w_cpl_dw1;
wire [31:0] w_cpl_dw2;
wire [31:0] w_cpl_dw3;
wire [8:0] w_cq_rst_n;
assign admin_cq_tail_ptr = r_admin_cq_tail_ptr;
assign io_cq1_tail_ptr = r_io_cq1_tail_ptr;
assign io_cq2_tail_ptr = r_io_cq2_tail_ptr;
assign io_cq3_tail_ptr = r_io_cq3_tail_ptr;
assign io_cq4_tail_ptr = r_io_cq4_tail_ptr;
assign io_cq5_tail_ptr = r_io_cq5_tail_ptr;
assign io_cq6_tail_ptr = r_io_cq6_tail_ptr;
assign io_cq7_tail_ptr = r_io_cq7_tail_ptr;
assign io_cq8_tail_ptr = r_io_cq8_tail_ptr;
assign hcmd_cq_rd_en = r_hcmd_cq_rd_en;
assign hcmd_cid_rd_addr = w_hcmd_slot_tag;
assign hcmd_slot_free_en = r_hcmd_slot_free_en;
assign hcmd_slot_invalid_tag = w_hcmd_slot_tag;
assign w_cpl_dw0 = r_cpl_specific;
assign w_cpl_dw1 = 0;
assign w_cpl_dw2 = {12'b0, r_cpl_sq_qid, 8'b0, r_sq_head_ptr};
assign w_cpl_dw3 = {r_cpl_status, r_phase_tag, r_cpl_cid};
assign tx_cq_mwr_req = r_tx_cq_mwr_req;
assign tx_cq_mwr_tag = LP_CPL_PCIE_TAG_PREFIX;
assign tx_cq_mwr_len = LP_CPL_SIZE;
assign tx_cq_mwr_addr = r_tx_cq_mwr_addr;
assign tx_cq_mwr_rd_data = {w_cpl_dw3, w_cpl_dw2, w_cpl_dw1, w_cpl_dw0};
always @ (posedge pcie_user_clk or negedge pcie_user_rst_n)
begin
if(pcie_user_rst_n == 0)
cur_state <= S_IDLE;
else
cur_state <= next_state;
end
always @ (*)
begin
case(cur_state)
S_IDLE: begin
if(hcmd_cq_empty_n == 1)
next_state <= S_CPL_STATUS0;
else
next_state <= S_IDLE;
end
S_CPL_STATUS0: begin
next_state <= S_CPL_STATUS1;
end
S_CPL_STATUS1: begin
if(r_cql_type[0] == 1)
next_state <= S_CPL_STATUS2;
else if(r_cql_type[1] == 1)
next_state <= S_PCIE_SLOT_RELEASE;
else
next_state <= S_CPL_STATUS3;
end
S_CPL_STATUS2: begin
next_state <= S_CPL_STATUS3;
end
S_CPL_STATUS3: begin
next_state <= S_HEAD_PTR;
end
S_HEAD_PTR: begin
if(r_sq_is_valid == 1)
next_state <= S_PCIE_ADDR;
else
next_state <= S_IDLE;
end
S_PCIE_ADDR: begin
if(r_cq_is_valid == 1)
next_state <= S_PCIE_MWR_REQ;
else
next_state <= S_IDLE;
end
S_PCIE_MWR_REQ: begin
next_state <= S_PCIE_MWR_DATA_LAST;
end
S_PCIE_MWR_DATA_LAST: begin
if(tx_cq_mwr_data_last == 1)
next_state <= S_PCIE_MWR_DONE;
else
next_state <= S_PCIE_MWR_DATA_LAST;
end
S_PCIE_MWR_DONE: begin
if(r_cql_type[0] == 1)
next_state <= S_PCIE_SLOT_RELEASE;
else
next_state <= S_IDLE;
end
S_PCIE_SLOT_RELEASE: begin
next_state <= S_IDLE;
end
default: begin
next_state <= S_IDLE;
end
endcase
end
assign w_hcmd_slot_tag = r_cql_info[6:0];
always @ (posedge pcie_user_clk)
begin
case(cur_state)
S_IDLE: begin
end
S_CPL_STATUS0: begin
r_cql_type <= hcmd_cq_rd_data[1:0];
r_cql_info <= hcmd_cq_rd_data[21:2];
r_cpl_status[12:0] <= hcmd_cq_rd_data[34:22];
end
S_CPL_STATUS1: begin
r_cpl_cid <= r_cql_info[15:0];
r_cpl_sq_qid <= r_cql_info[19:16];
r_cpl_status[14:13] <= hcmd_cq_rd_data[1:0];
r_cpl_specific[31:0] <= hcmd_cq_rd_data[33:2];
end
S_CPL_STATUS2: begin
r_cpl_cid <= hcmd_cid_rd_data[15:0];
r_cpl_sq_qid <= hcmd_cid_rd_data[19:16];
end
S_CPL_STATUS3: begin
case(r_cpl_sq_qid) // synthesis parallel_case full_case
4'h0: begin
r_sq_is_valid <= sq_valid[0];
r_sq_cq_vec <= 4'h0;
r_sq_head_ptr <= admin_sq_head_ptr;
end
4'h1: begin
r_sq_is_valid <= sq_valid[1];
r_sq_cq_vec <= io_sq1_cq_vec;
r_sq_head_ptr <= io_sq1_head_ptr;
end
4'h2: begin
r_sq_is_valid <= sq_valid[2];
r_sq_cq_vec <= io_sq2_cq_vec;
r_sq_head_ptr <= io_sq2_head_ptr;
end
4'h3: begin
r_sq_is_valid <= sq_valid[3];
r_sq_cq_vec <= io_sq3_cq_vec;
r_sq_head_ptr <= io_sq3_head_ptr;
end
4'h4: begin
r_sq_is_valid <= sq_valid[4];
r_sq_cq_vec <= io_sq4_cq_vec;
r_sq_head_ptr <= io_sq4_head_ptr;
end
4'h5: begin
r_sq_is_valid <= sq_valid[5];
r_sq_cq_vec <= io_sq5_cq_vec;
r_sq_head_ptr <= io_sq5_head_ptr;
end
4'h6: begin
r_sq_is_valid <= sq_valid[6];
r_sq_cq_vec <= io_sq6_cq_vec;
r_sq_head_ptr <= io_sq6_head_ptr;
end
4'h7: begin
r_sq_is_valid <= sq_valid[7];
r_sq_cq_vec <= io_sq7_cq_vec;
r_sq_head_ptr <= io_sq7_head_ptr;
end
4'h8: begin
r_sq_is_valid <= sq_valid[8];
r_sq_cq_vec <= io_sq8_cq_vec;
r_sq_head_ptr <= io_sq8_head_ptr;
end
endcase
end
S_HEAD_PTR: begin
case(r_sq_cq_vec) // synthesis parallel_case full_case
4'h0: begin
r_cq_is_valid <= cq_valid[0];
r_tx_cq_mwr_addr <= admin_cq_bs_addr;
r_cq_tail_ptr <= r_admin_cq_tail_ptr;
r_phase_tag <= r_cq_phase_tag[0];
r_cq_valid_entry <= 9'b000000001;
end
4'h1: begin
r_cq_is_valid <= cq_valid[1];
r_tx_cq_mwr_addr <= io_cq1_bs_addr;
r_cq_tail_ptr <= r_io_cq1_tail_ptr;
r_phase_tag <= r_cq_phase_tag[1];
r_cq_valid_entry <= 9'b000000010;
end
4'h2: begin
r_cq_is_valid <= cq_valid[2];
r_tx_cq_mwr_addr <= io_cq2_bs_addr;
r_cq_tail_ptr <= r_io_cq2_tail_ptr;
r_phase_tag <= r_cq_phase_tag[2];
r_sq_head_ptr <= io_sq2_head_ptr;
r_cq_valid_entry <= 9'b000000100;
end
4'h3: begin
r_cq_is_valid <= cq_valid[3];
r_tx_cq_mwr_addr <= io_cq3_bs_addr;
r_cq_tail_ptr <= r_io_cq3_tail_ptr;
r_phase_tag <= r_cq_phase_tag[3];
r_sq_head_ptr <= io_sq3_head_ptr;
r_cq_valid_entry <= 9'b000001000;
end
4'h4: begin
r_cq_is_valid <= cq_valid[4];
r_tx_cq_mwr_addr <= io_cq4_bs_addr;
r_cq_tail_ptr <= r_io_cq4_tail_ptr;
r_phase_tag <= r_cq_phase_tag[4];
r_sq_head_ptr <= io_sq4_head_ptr;
r_cq_valid_entry <= 9'b000010000;
end
4'h5: begin
r_cq_is_valid <= cq_valid[5];
r_tx_cq_mwr_addr <= io_cq5_bs_addr;
r_cq_tail_ptr <= r_io_cq5_tail_ptr;
r_phase_tag <= r_cq_phase_tag[5];
r_sq_head_ptr <= io_sq5_head_ptr;
r_cq_valid_entry <= 9'b000100000;
end
4'h6: begin
r_cq_is_valid <= cq_valid[6];
r_tx_cq_mwr_addr <= io_cq6_bs_addr;
r_cq_tail_ptr <= r_io_cq6_tail_ptr;
r_phase_tag <= r_cq_phase_tag[6];
r_sq_head_ptr <= io_sq6_head_ptr;
r_cq_valid_entry <= 9'b001000000;
end
4'h7: begin
r_cq_is_valid <= cq_valid[7];
r_tx_cq_mwr_addr <= io_cq7_bs_addr;
r_cq_tail_ptr <= r_io_cq7_tail_ptr;
r_phase_tag <= r_cq_phase_tag[7];
r_sq_head_ptr <= io_sq7_head_ptr;
r_cq_valid_entry <= 9'b010000000;
end
4'h8: begin
r_cq_is_valid <= cq_valid[8];
r_tx_cq_mwr_addr <= io_cq8_bs_addr;
r_cq_tail_ptr <= r_io_cq8_tail_ptr;
r_phase_tag <= r_cq_phase_tag[8];
r_sq_head_ptr <= io_sq8_head_ptr;
r_cq_valid_entry <= 9'b100000000;
end
endcase
end
S_PCIE_ADDR: begin
r_tx_cq_mwr_addr <= r_tx_cq_mwr_addr + {r_cq_tail_ptr, 2'b0};
r_cq_tail_ptr <= r_cq_tail_ptr + 1;
end
S_PCIE_MWR_REQ: begin
end
S_PCIE_MWR_DATA_LAST: begin
end
S_PCIE_MWR_DONE: begin
end
S_PCIE_SLOT_RELEASE: begin
end
default: begin
end
endcase
end
always @ (*)
begin
case(cur_state)
S_IDLE: begin
r_hcmd_cq_rd_en <= 0;
r_tx_cq_mwr_req <= 0;
r_cq_update_entry <= 0;
r_hcmd_slot_free_en <= 0;
end
S_CPL_STATUS0: begin
r_hcmd_cq_rd_en <= 1;
r_tx_cq_mwr_req <= 0;
r_cq_update_entry <= 0;
r_hcmd_slot_free_en <= 0;
end
S_CPL_STATUS1: begin
r_hcmd_cq_rd_en <= 1;
r_tx_cq_mwr_req <= 0;
r_cq_update_entry <= 0;
r_hcmd_slot_free_en <= 0;
end
S_CPL_STATUS2: begin
r_hcmd_cq_rd_en <= 0;
r_tx_cq_mwr_req <= 0;
r_cq_update_entry <= 0;
r_hcmd_slot_free_en <= 0;
end
S_CPL_STATUS3: begin
r_hcmd_cq_rd_en <= 0;
r_tx_cq_mwr_req <= 0;
r_cq_update_entry <= 0;
r_hcmd_slot_free_en <= 0;
end
S_HEAD_PTR: begin
r_hcmd_cq_rd_en <= 0;
r_tx_cq_mwr_req <= 0;
r_cq_update_entry <= 0;
r_hcmd_slot_free_en <= 0;
end
S_PCIE_ADDR: begin
r_hcmd_cq_rd_en <= 0;
r_tx_cq_mwr_req <= 0;
r_cq_update_entry <= 0;
r_hcmd_slot_free_en <= 0;
end
S_PCIE_MWR_REQ: begin
r_hcmd_cq_rd_en <= 0;
r_tx_cq_mwr_req <= 1;
r_cq_update_entry <= 0;
r_hcmd_slot_free_en <= 0;
end
S_PCIE_MWR_DATA_LAST: begin
r_hcmd_cq_rd_en <= 0;
r_tx_cq_mwr_req <= 0;
r_cq_update_entry <= 0;
r_hcmd_slot_free_en <= 0;
end
S_PCIE_MWR_DONE: begin
r_hcmd_cq_rd_en <= 0;
r_tx_cq_mwr_req <= 0;
r_cq_update_entry <= r_cq_valid_entry;
r_hcmd_slot_free_en <= 0;
end
S_PCIE_SLOT_RELEASE: begin
r_hcmd_cq_rd_en <= 0;
r_tx_cq_mwr_req <= 0;
r_cq_update_entry <= 0;
r_hcmd_slot_free_en <= 1;
end
default: begin
r_hcmd_cq_rd_en <= 0;
r_tx_cq_mwr_req <= 0;
r_cq_update_entry <= 0;
r_hcmd_slot_free_en <= 0;
end
endcase
end
assign w_cq_rst_n[0] = pcie_user_rst_n & cq_rst_n[0];
assign w_cq_rst_n[1] = pcie_user_rst_n & cq_rst_n[1];
assign w_cq_rst_n[2] = pcie_user_rst_n & cq_rst_n[2];
assign w_cq_rst_n[3] = pcie_user_rst_n & cq_rst_n[3];
assign w_cq_rst_n[4] = pcie_user_rst_n & cq_rst_n[4];
assign w_cq_rst_n[5] = pcie_user_rst_n & cq_rst_n[5];
assign w_cq_rst_n[6] = pcie_user_rst_n & cq_rst_n[6];
assign w_cq_rst_n[7] = pcie_user_rst_n & cq_rst_n[7];
assign w_cq_rst_n[8] = pcie_user_rst_n & cq_rst_n[8];
always @ (posedge pcie_user_clk or negedge w_cq_rst_n[0])
begin
if(w_cq_rst_n[0] == 0) begin
r_admin_cq_tail_ptr <= 0;
r_cq_phase_tag[0] <= 1;
end
else begin
if(r_cq_update_entry[0] == 1) begin
if(r_admin_cq_tail_ptr == admin_cq_size) begin
r_admin_cq_tail_ptr <= 0;
r_cq_phase_tag[0] <= ~r_cq_phase_tag[0];
end
else begin
r_admin_cq_tail_ptr <= r_cq_tail_ptr;
end
end
end
end
always @ (posedge pcie_user_clk or negedge w_cq_rst_n[1])
begin
if(w_cq_rst_n[1] == 0) begin
r_io_cq1_tail_ptr <= 0;
r_cq_phase_tag[1] <= 1;
end
else begin
if(r_cq_update_entry[1] == 1) begin
if(r_io_cq1_tail_ptr == io_cq1_size) begin
r_io_cq1_tail_ptr <= 0;
r_cq_phase_tag[1] <= ~r_cq_phase_tag[1];
end
else begin
r_io_cq1_tail_ptr <= r_cq_tail_ptr;
end
end
end
end
always @ (posedge pcie_user_clk or negedge w_cq_rst_n[2])
begin
if(w_cq_rst_n[2] == 0) begin
r_io_cq2_tail_ptr <= 0;
r_cq_phase_tag[2] <= 1;
end
else begin
if(r_cq_update_entry[2] == 1) begin
if(r_io_cq2_tail_ptr == io_cq2_size) begin
r_io_cq2_tail_ptr <= 0;
r_cq_phase_tag[2] <= ~r_cq_phase_tag[2];
end
else begin
r_io_cq2_tail_ptr <= r_cq_tail_ptr;
end
end
end
end
always @ (posedge pcie_user_clk or negedge w_cq_rst_n[3])
begin
if(w_cq_rst_n[3] == 0) begin
r_io_cq3_tail_ptr <= 0;
r_cq_phase_tag[3] <= 1;
end
else begin
if(r_cq_update_entry[3] == 1) begin
if(r_io_cq3_tail_ptr == io_cq3_size) begin
r_io_cq3_tail_ptr <= 0;
r_cq_phase_tag[3] <= ~r_cq_phase_tag[3];
end
else begin
r_io_cq3_tail_ptr <= r_cq_tail_ptr;
end
end
end
end
always @ (posedge pcie_user_clk or negedge w_cq_rst_n[4])
begin
if(w_cq_rst_n[4] == 0) begin
r_io_cq4_tail_ptr <= 0;
r_cq_phase_tag[4] <= 1;
end
else begin
if(r_cq_update_entry[4] == 1) begin
if(r_io_cq4_tail_ptr == io_cq4_size) begin
r_io_cq4_tail_ptr <= 0;
r_cq_phase_tag[4] <= ~r_cq_phase_tag[4];
end
else begin
r_io_cq4_tail_ptr <= r_cq_tail_ptr;
end
end
end
end
always @ (posedge pcie_user_clk or negedge w_cq_rst_n[5])
begin
if(w_cq_rst_n[5] == 0) begin
r_io_cq5_tail_ptr <= 0;
r_cq_phase_tag[5] <= 1;
end
else begin
if(r_cq_update_entry[5] == 1) begin
if(r_io_cq5_tail_ptr == io_cq5_size) begin
r_io_cq5_tail_ptr <= 0;
r_cq_phase_tag[5] <= ~r_cq_phase_tag[5];
end
else begin
r_io_cq5_tail_ptr <= r_cq_tail_ptr;
end
end
end
end
always @ (posedge pcie_user_clk or negedge w_cq_rst_n[6])
begin
if(w_cq_rst_n[6] == 0) begin
r_io_cq6_tail_ptr <= 0;
r_cq_phase_tag[6] <= 1;
end
else begin
if(r_cq_update_entry[6] == 1) begin
if(r_io_cq6_tail_ptr == io_cq6_size) begin
r_io_cq6_tail_ptr <= 0;
r_cq_phase_tag[6] <= ~r_cq_phase_tag[6];
end
else begin
r_io_cq6_tail_ptr <= r_cq_tail_ptr;
end
end
end
end
always @ (posedge pcie_user_clk or negedge w_cq_rst_n[7])
begin
if(w_cq_rst_n[7] == 0) begin
r_io_cq7_tail_ptr <= 0;
r_cq_phase_tag[7] <= 1;
end
else begin
if(r_cq_update_entry[7] == 1) begin
if(r_io_cq7_tail_ptr == io_cq7_size) begin
r_io_cq7_tail_ptr <= 0;
r_cq_phase_tag[7] <= ~r_cq_phase_tag[7];
end
else begin
r_io_cq7_tail_ptr <= r_cq_tail_ptr;
end
end
end
end
always @ (posedge pcie_user_clk or negedge w_cq_rst_n[8])
begin
if(w_cq_rst_n[8] == 0) begin
r_io_cq8_tail_ptr <= 0;
r_cq_phase_tag[8] <= 1;
end
else begin
if(r_cq_update_entry[8] == 1) begin
if(r_io_cq8_tail_ptr == io_cq8_size) begin
r_io_cq8_tail_ptr <= 0;
r_cq_phase_tag[8] <= ~r_cq_phase_tag[8];
end
else begin
r_io_cq8_tail_ptr <= r_cq_tail_ptr;
end
end
end
end
endmodule
|
module chan_fifo_reader
(reset, tx_clock, tx_strobe, adc_time, samples_format,
fifodata, pkt_waiting, rdreq, skip, tx_q, tx_i,
underrun, tx_empty, debug, rssi, threshhold, rssi_wait) ;
input wire reset ;
input wire tx_clock ;
input wire tx_strobe ; //signal to output tx_i and tx_q
input wire [31:0] adc_time ; //current time
input wire [3:0] samples_format ;// not useful at this point
input wire [31:0] fifodata ; //the data input
input wire pkt_waiting ; //signal the next packet is ready
output reg rdreq ; //actually an ack to the current fifodata
output reg skip ; //finish reading current packet
output reg [15:0] tx_q ; //top 16 bit output of fifodata
output reg [15:0] tx_i ; //bottom 16 bit output of fifodata
output reg underrun ;
output reg tx_empty ; //cause 0 to be the output
input wire [31:0] rssi;
input wire [31:0] threshhold;
input wire [31:0] rssi_wait;
output wire [14:0] debug;
// Should not be needed if adc clock rate < tx clock rate
// Used only to debug
`define JITTER 5
//Samples format
// 16 bits interleaved complex samples
`define QI16 4'b0
// States
parameter IDLE = 3'd0;
parameter HEADER = 3'd1;
parameter TIMESTAMP = 3'd2;
parameter WAIT = 3'd3;
parameter WAITSTROBE = 3'd4;
parameter SEND = 3'd5;
// Header format
`define PAYLOAD 8:2
`define ENDOFBURST 27
`define STARTOFBURST 28
`define RSSI_FLAG 26
/* State registers */
reg [2:0] reader_state;
/* Local registers */
reg [6:0] payload_len;
reg [6:0] read_len;
reg [31:0] timestamp;
reg burst;
reg trash;
reg rssi_flag;
reg [31:0] time_wait;
assign debug = {7'd0, rdreq, skip, reader_state, pkt_waiting, tx_strobe, tx_clock};
always @(posedge tx_clock)
begin
if (reset)
begin
reader_state <= IDLE;
rdreq <= 0;
skip <= 0;
underrun <= 0;
burst <= 0;
tx_empty <= 1;
tx_q <= 0;
tx_i <= 0;
trash <= 0;
rssi_flag <= 0;
time_wait <= 0;
end
else
begin
case (reader_state)
IDLE:
begin
/*
* reset all the variables and wait for a tx_strobe
* it is assumed that the ram connected to this fifo_reader
* is a short hand fifo meaning that the header to the next packet
* is already available to this fifo_reader when pkt_waiting is on
*/
skip <=0;
time_wait <= 0;
if (pkt_waiting == 1)
begin
reader_state <= HEADER;
rdreq <= 1;
underrun <= 0;
end
if (burst == 1 && pkt_waiting == 0)
underrun <= 1;
if (tx_strobe == 1)
tx_empty <= 1 ;
end
/* Process header */
HEADER:
begin
if (tx_strobe == 1)
tx_empty <= 1 ;
rssi_flag <= fifodata[`RSSI_FLAG]&fifodata[`STARTOFBURST];
//Check Start/End burst flag
if (fifodata[`STARTOFBURST] == 1
&& fifodata[`ENDOFBURST] == 1)
burst <= 0;
else if (fifodata[`STARTOFBURST] == 1)
burst <= 1;
else if (fifodata[`ENDOFBURST] == 1)
burst <= 0;
if (trash == 1 && fifodata[`STARTOFBURST] == 0)
begin
skip <= 1;
reader_state <= IDLE;
rdreq <= 0;
end
else
begin
payload_len <= fifodata[`PAYLOAD] ;
read_len <= 0;
rdreq <= 1;
reader_state <= TIMESTAMP;
end
end
TIMESTAMP:
begin
timestamp <= fifodata;
reader_state <= WAIT;
if (tx_strobe == 1)
tx_empty <= 1 ;
rdreq <= 0;
end
// Decide if we wait, send or discard samples
WAIT:
begin
if (tx_strobe == 1)
tx_empty <= 1 ;
time_wait <= time_wait + 32'd1;
// Outdated
if ((timestamp < adc_time) ||
(time_wait >= rssi_wait && rssi_wait != 0 && rssi_flag))
begin
trash <= 1;
reader_state <= IDLE;
skip <= 1;
end
// Let's send it
else if ((timestamp <= adc_time + `JITTER
&& timestamp > adc_time)
|| timestamp == 32'hFFFFFFFF)
begin
if (rssi <= threshhold || rssi_flag == 0)
begin
trash <= 0;
reader_state <= WAITSTROBE;
end
else
reader_state <= WAIT;
end
else
reader_state <= WAIT;
end
// Wait for the transmit chain to be ready
WAITSTROBE:
begin
// If end of payload...
if (read_len == payload_len)
begin
reader_state <= IDLE;
skip <= 1;
if (tx_strobe == 1)
tx_empty <= 1 ;
end
else if (tx_strobe == 1)
begin
reader_state <= SEND;
rdreq <= 1;
end
end
// Send the samples to the tx_chain
SEND:
begin
reader_state <= WAITSTROBE;
read_len <= read_len + 7'd1;
tx_empty <= 0;
rdreq <= 0;
case(samples_format)
`QI16:
begin
tx_i <= fifodata[15:0];
tx_q <= fifodata[31:16];
end
// Assume 16 bits complex samples by default
default:
begin
tx_i <= fifodata[15:0];
tx_q <= fifodata[31:16];
end
endcase
end
default:
begin
//error handling
reader_state <= IDLE;
end
endcase
end
end
endmodule
|
module chan_fifo_reader
(reset, tx_clock, tx_strobe, adc_time, samples_format,
fifodata, pkt_waiting, rdreq, skip, tx_q, tx_i,
underrun, tx_empty, debug, rssi, threshhold, rssi_wait) ;
input wire reset ;
input wire tx_clock ;
input wire tx_strobe ; //signal to output tx_i and tx_q
input wire [31:0] adc_time ; //current time
input wire [3:0] samples_format ;// not useful at this point
input wire [31:0] fifodata ; //the data input
input wire pkt_waiting ; //signal the next packet is ready
output reg rdreq ; //actually an ack to the current fifodata
output reg skip ; //finish reading current packet
output reg [15:0] tx_q ; //top 16 bit output of fifodata
output reg [15:0] tx_i ; //bottom 16 bit output of fifodata
output reg underrun ;
output reg tx_empty ; //cause 0 to be the output
input wire [31:0] rssi;
input wire [31:0] threshhold;
input wire [31:0] rssi_wait;
output wire [14:0] debug;
// Should not be needed if adc clock rate < tx clock rate
// Used only to debug
`define JITTER 5
//Samples format
// 16 bits interleaved complex samples
`define QI16 4'b0
// States
parameter IDLE = 3'd0;
parameter HEADER = 3'd1;
parameter TIMESTAMP = 3'd2;
parameter WAIT = 3'd3;
parameter WAITSTROBE = 3'd4;
parameter SEND = 3'd5;
// Header format
`define PAYLOAD 8:2
`define ENDOFBURST 27
`define STARTOFBURST 28
`define RSSI_FLAG 26
/* State registers */
reg [2:0] reader_state;
/* Local registers */
reg [6:0] payload_len;
reg [6:0] read_len;
reg [31:0] timestamp;
reg burst;
reg trash;
reg rssi_flag;
reg [31:0] time_wait;
assign debug = {7'd0, rdreq, skip, reader_state, pkt_waiting, tx_strobe, tx_clock};
always @(posedge tx_clock)
begin
if (reset)
begin
reader_state <= IDLE;
rdreq <= 0;
skip <= 0;
underrun <= 0;
burst <= 0;
tx_empty <= 1;
tx_q <= 0;
tx_i <= 0;
trash <= 0;
rssi_flag <= 0;
time_wait <= 0;
end
else
begin
case (reader_state)
IDLE:
begin
/*
* reset all the variables and wait for a tx_strobe
* it is assumed that the ram connected to this fifo_reader
* is a short hand fifo meaning that the header to the next packet
* is already available to this fifo_reader when pkt_waiting is on
*/
skip <=0;
time_wait <= 0;
if (pkt_waiting == 1)
begin
reader_state <= HEADER;
rdreq <= 1;
underrun <= 0;
end
if (burst == 1 && pkt_waiting == 0)
underrun <= 1;
if (tx_strobe == 1)
tx_empty <= 1 ;
end
/* Process header */
HEADER:
begin
if (tx_strobe == 1)
tx_empty <= 1 ;
rssi_flag <= fifodata[`RSSI_FLAG]&fifodata[`STARTOFBURST];
//Check Start/End burst flag
if (fifodata[`STARTOFBURST] == 1
&& fifodata[`ENDOFBURST] == 1)
burst <= 0;
else if (fifodata[`STARTOFBURST] == 1)
burst <= 1;
else if (fifodata[`ENDOFBURST] == 1)
burst <= 0;
if (trash == 1 && fifodata[`STARTOFBURST] == 0)
begin
skip <= 1;
reader_state <= IDLE;
rdreq <= 0;
end
else
begin
payload_len <= fifodata[`PAYLOAD] ;
read_len <= 0;
rdreq <= 1;
reader_state <= TIMESTAMP;
end
end
TIMESTAMP:
begin
timestamp <= fifodata;
reader_state <= WAIT;
if (tx_strobe == 1)
tx_empty <= 1 ;
rdreq <= 0;
end
// Decide if we wait, send or discard samples
WAIT:
begin
if (tx_strobe == 1)
tx_empty <= 1 ;
time_wait <= time_wait + 32'd1;
// Outdated
if ((timestamp < adc_time) ||
(time_wait >= rssi_wait && rssi_wait != 0 && rssi_flag))
begin
trash <= 1;
reader_state <= IDLE;
skip <= 1;
end
// Let's send it
else if ((timestamp <= adc_time + `JITTER
&& timestamp > adc_time)
|| timestamp == 32'hFFFFFFFF)
begin
if (rssi <= threshhold || rssi_flag == 0)
begin
trash <= 0;
reader_state <= WAITSTROBE;
end
else
reader_state <= WAIT;
end
else
reader_state <= WAIT;
end
// Wait for the transmit chain to be ready
WAITSTROBE:
begin
// If end of payload...
if (read_len == payload_len)
begin
reader_state <= IDLE;
skip <= 1;
if (tx_strobe == 1)
tx_empty <= 1 ;
end
else if (tx_strobe == 1)
begin
reader_state <= SEND;
rdreq <= 1;
end
end
// Send the samples to the tx_chain
SEND:
begin
reader_state <= WAITSTROBE;
read_len <= read_len + 7'd1;
tx_empty <= 0;
rdreq <= 0;
case(samples_format)
`QI16:
begin
tx_i <= fifodata[15:0];
tx_q <= fifodata[31:16];
end
// Assume 16 bits complex samples by default
default:
begin
tx_i <= fifodata[15:0];
tx_q <= fifodata[31:16];
end
endcase
end
default:
begin
//error handling
reader_state <= IDLE;
end
endcase
end
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2007 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
integer cyc=0;
reg [63:0] crc;
reg [63:0] sum;
// Take CRC data and apply to testblock inputs
wire [33:0] in = crc[33:0];
/*AUTOWIRE*/
// Beginning of automatic wires (for undeclared instantiated-module outputs)
wire [31:0] code; // From test of Test.v
wire [4:0] len; // From test of Test.v
wire next; // From test of Test.v
// End of automatics
Test test (/*AUTOINST*/
// Outputs
.next (next),
.code (code[31:0]),
.len (len[4:0]),
// Inputs
.clk (clk),
.in (in[33:0]));
// Aggregate outputs into a single result vector
wire [63:0] result = {26'h0, next, len, code};
// What checksum will we end up with
`define EXPECTED_SUM 64'h5537fa30d49bf865
// Test loop
always @ (posedge clk) begin
`ifdef TEST_VERBOSE
$write("[%0t] cyc==%0d crc=%x result=%x\n",$time, cyc, crc, result);
`endif
cyc <= cyc + 1;
crc <= {crc[62:0], crc[63]^crc[2]^crc[0]};
sum <= result ^ {sum[62:0],sum[63]^sum[2]^sum[0]};
if (cyc==0) begin
// Setup
crc <= 64'h5aef0c8d_d70a4497;
end
else if (cyc<10) begin
sum <= 64'h0;
end
else if (cyc<90) begin
end
else if (cyc==99) begin
$write("[%0t] cyc==%0d crc=%x sum=%x\n",$time, cyc, crc, sum);
if (crc !== 64'hc77bb9b3784ea091) $stop;
if (sum !== `EXPECTED_SUM) $stop;
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
module Test (/*AUTOARG*/
// Outputs
next, code, len,
// Inputs
clk, in
);
input clk;
input [33:0] in;
output next;
output [31:0] code;
output [4:0] len;
/*AUTOREG*/
// Beginning of automatic regs (for this module's undeclared outputs)
reg [31:0] code;
reg [4:0] len;
reg next;
// End of automatics
/*
#!/usr/bin/perl -w
srand(5);
my @used;
pat:
for (my $pat=0; 1; ) {
last if $pat > 196;
my $len = int($pat / (6 + $pat/50)) + 4; $len=20 if $len>20;
my ($try, $val, $mask);
try:
for ($try=0; ; $try++) {
next pat if $try>50;
$val = 0;
for (my $bit=23; $bit>(23-$len); $bit--) {
my $b = int(rand()*2);
$val |= (1<<$bit) if $b;
}
$mask = (1<<(23-$len+1))-1;
for (my $testval = $val; $testval <= ($val + $mask); $testval ++) {
next try if $used[$testval];
}
last;
}
my $bits = "";
my $val2 = 0;
for (my $bit=23; $bit>(23-$len); $bit--) {
my $b = ($val & (1<<$bit));
$bits .= $b?'1':'0';
}
for (my $testval = $val; $testval <= ($val + $mask); $testval++) {
$used[$testval]= 1; #printf "U%08x\n", $testval;
}
if ($try<90) {
printf +(" 24'b%s: {next, len, code} = {in[%02d], 5'd%02d, 32'd%03d};\n"
,$bits.("?"x(24-$len)), 31-$len, $len, $pat);
$pat++;
}
}
*/
always @* begin
next = 1'b0;
code = 32'd0;
len = 5'b11111;
casez (in[31:8])
24'b1010????????????????????: {next, len, code} = {in[27], 5'd04, 32'd000};
24'b1100????????????????????: {next, len, code} = {in[27], 5'd04, 32'd001};
24'b0110????????????????????: {next, len, code} = {in[27], 5'd04, 32'd002};
24'b1001????????????????????: {next, len, code} = {in[27], 5'd04, 32'd003};
24'b1101????????????????????: {next, len, code} = {in[27], 5'd04, 32'd004};
24'b0011????????????????????: {next, len, code} = {in[27], 5'd04, 32'd005};
24'b0001????????????????????: {next, len, code} = {in[27], 5'd04, 32'd006};
24'b10001???????????????????: {next, len, code} = {in[26], 5'd05, 32'd007};
24'b01110???????????????????: {next, len, code} = {in[26], 5'd05, 32'd008};
24'b01000???????????????????: {next, len, code} = {in[26], 5'd05, 32'd009};
24'b00001???????????????????: {next, len, code} = {in[26], 5'd05, 32'd010};
24'b11100???????????????????: {next, len, code} = {in[26], 5'd05, 32'd011};
24'b01011???????????????????: {next, len, code} = {in[26], 5'd05, 32'd012};
24'b100001??????????????????: {next, len, code} = {in[25], 5'd06, 32'd013};
24'b111110??????????????????: {next, len, code} = {in[25], 5'd06, 32'd014};
24'b010010??????????????????: {next, len, code} = {in[25], 5'd06, 32'd015};
24'b001011??????????????????: {next, len, code} = {in[25], 5'd06, 32'd016};
24'b101110??????????????????: {next, len, code} = {in[25], 5'd06, 32'd017};
24'b111011??????????????????: {next, len, code} = {in[25], 5'd06, 32'd018};
24'b0111101?????????????????: {next, len, code} = {in[24], 5'd07, 32'd020};
24'b0010100?????????????????: {next, len, code} = {in[24], 5'd07, 32'd021};
24'b0111111?????????????????: {next, len, code} = {in[24], 5'd07, 32'd022};
24'b1011010?????????????????: {next, len, code} = {in[24], 5'd07, 32'd023};
24'b1000000?????????????????: {next, len, code} = {in[24], 5'd07, 32'd024};
24'b1011111?????????????????: {next, len, code} = {in[24], 5'd07, 32'd025};
24'b1110100?????????????????: {next, len, code} = {in[24], 5'd07, 32'd026};
24'b01111100????????????????: {next, len, code} = {in[23], 5'd08, 32'd027};
24'b00000110????????????????: {next, len, code} = {in[23], 5'd08, 32'd028};
24'b00000101????????????????: {next, len, code} = {in[23], 5'd08, 32'd029};
24'b01001100????????????????: {next, len, code} = {in[23], 5'd08, 32'd030};
24'b10110110????????????????: {next, len, code} = {in[23], 5'd08, 32'd031};
24'b00100110????????????????: {next, len, code} = {in[23], 5'd08, 32'd032};
24'b11110010????????????????: {next, len, code} = {in[23], 5'd08, 32'd033};
24'b010011101???????????????: {next, len, code} = {in[22], 5'd09, 32'd034};
24'b001000000???????????????: {next, len, code} = {in[22], 5'd09, 32'd035};
24'b010101111???????????????: {next, len, code} = {in[22], 5'd09, 32'd036};
24'b010101010???????????????: {next, len, code} = {in[22], 5'd09, 32'd037};
24'b010011011???????????????: {next, len, code} = {in[22], 5'd09, 32'd038};
24'b010100011???????????????: {next, len, code} = {in[22], 5'd09, 32'd039};
24'b010101000???????????????: {next, len, code} = {in[22], 5'd09, 32'd040};
24'b1111010101??????????????: {next, len, code} = {in[21], 5'd10, 32'd041};
24'b0010001000??????????????: {next, len, code} = {in[21], 5'd10, 32'd042};
24'b0101001101??????????????: {next, len, code} = {in[21], 5'd10, 32'd043};
24'b0010010100??????????????: {next, len, code} = {in[21], 5'd10, 32'd044};
24'b1011001110??????????????: {next, len, code} = {in[21], 5'd10, 32'd045};
24'b1111000011??????????????: {next, len, code} = {in[21], 5'd10, 32'd046};
24'b0101000000??????????????: {next, len, code} = {in[21], 5'd10, 32'd047};
24'b1111110000??????????????: {next, len, code} = {in[21], 5'd10, 32'd048};
24'b10110111010?????????????: {next, len, code} = {in[20], 5'd11, 32'd049};
24'b11110000011?????????????: {next, len, code} = {in[20], 5'd11, 32'd050};
24'b01001111011?????????????: {next, len, code} = {in[20], 5'd11, 32'd051};
24'b00101011011?????????????: {next, len, code} = {in[20], 5'd11, 32'd052};
24'b01010010100?????????????: {next, len, code} = {in[20], 5'd11, 32'd053};
24'b11110111100?????????????: {next, len, code} = {in[20], 5'd11, 32'd054};
24'b00100111001?????????????: {next, len, code} = {in[20], 5'd11, 32'd055};
24'b10110001010?????????????: {next, len, code} = {in[20], 5'd11, 32'd056};
24'b10000010000?????????????: {next, len, code} = {in[20], 5'd11, 32'd057};
24'b111111101100????????????: {next, len, code} = {in[19], 5'd12, 32'd058};
24'b100000111110????????????: {next, len, code} = {in[19], 5'd12, 32'd059};
24'b100000110010????????????: {next, len, code} = {in[19], 5'd12, 32'd060};
24'b100000111001????????????: {next, len, code} = {in[19], 5'd12, 32'd061};
24'b010100101111????????????: {next, len, code} = {in[19], 5'd12, 32'd062};
24'b001000001100????????????: {next, len, code} = {in[19], 5'd12, 32'd063};
24'b000001111111????????????: {next, len, code} = {in[19], 5'd12, 32'd064};
24'b011111010100????????????: {next, len, code} = {in[19], 5'd12, 32'd065};
24'b1110101111101???????????: {next, len, code} = {in[18], 5'd13, 32'd066};
24'b0100110101110???????????: {next, len, code} = {in[18], 5'd13, 32'd067};
24'b1111111011011???????????: {next, len, code} = {in[18], 5'd13, 32'd068};
24'b0101011011001???????????: {next, len, code} = {in[18], 5'd13, 32'd069};
24'b0010000101100???????????: {next, len, code} = {in[18], 5'd13, 32'd070};
24'b1111111101101???????????: {next, len, code} = {in[18], 5'd13, 32'd071};
24'b1011110010110???????????: {next, len, code} = {in[18], 5'd13, 32'd072};
24'b0101010111010???????????: {next, len, code} = {in[18], 5'd13, 32'd073};
24'b1111011010010???????????: {next, len, code} = {in[18], 5'd13, 32'd074};
24'b01010100100011??????????: {next, len, code} = {in[17], 5'd14, 32'd075};
24'b10110000110010??????????: {next, len, code} = {in[17], 5'd14, 32'd076};
24'b10111101001111??????????: {next, len, code} = {in[17], 5'd14, 32'd077};
24'b10110000010101??????????: {next, len, code} = {in[17], 5'd14, 32'd078};
24'b00101011001111??????????: {next, len, code} = {in[17], 5'd14, 32'd079};
24'b00100000101100??????????: {next, len, code} = {in[17], 5'd14, 32'd080};
24'b11111110010111??????????: {next, len, code} = {in[17], 5'd14, 32'd081};
24'b10110010100000??????????: {next, len, code} = {in[17], 5'd14, 32'd082};
24'b11101011101000??????????: {next, len, code} = {in[17], 5'd14, 32'd083};
24'b01010000011111??????????: {next, len, code} = {in[17], 5'd14, 32'd084};
24'b101111011001011?????????: {next, len, code} = {in[16], 5'd15, 32'd085};
24'b101111010001100?????????: {next, len, code} = {in[16], 5'd15, 32'd086};
24'b100000111100111?????????: {next, len, code} = {in[16], 5'd15, 32'd087};
24'b001010101011000?????????: {next, len, code} = {in[16], 5'd15, 32'd088};
24'b111111100100001?????????: {next, len, code} = {in[16], 5'd15, 32'd089};
24'b001001011000010?????????: {next, len, code} = {in[16], 5'd15, 32'd090};
24'b011110011001011?????????: {next, len, code} = {in[16], 5'd15, 32'd091};
24'b111111111111010?????????: {next, len, code} = {in[16], 5'd15, 32'd092};
24'b101111001010011?????????: {next, len, code} = {in[16], 5'd15, 32'd093};
24'b100000110000111?????????: {next, len, code} = {in[16], 5'd15, 32'd094};
24'b0010010000000101????????: {next, len, code} = {in[15], 5'd16, 32'd095};
24'b0010010010101001????????: {next, len, code} = {in[15], 5'd16, 32'd096};
24'b1111011010110010????????: {next, len, code} = {in[15], 5'd16, 32'd097};
24'b0010010001100100????????: {next, len, code} = {in[15], 5'd16, 32'd098};
24'b0101011101110100????????: {next, len, code} = {in[15], 5'd16, 32'd099};
24'b0101011010001111????????: {next, len, code} = {in[15], 5'd16, 32'd100};
24'b0010000110011111????????: {next, len, code} = {in[15], 5'd16, 32'd101};
24'b0101010010000101????????: {next, len, code} = {in[15], 5'd16, 32'd102};
24'b1110101011000000????????: {next, len, code} = {in[15], 5'd16, 32'd103};
24'b1111000000110010????????: {next, len, code} = {in[15], 5'd16, 32'd104};
24'b0111100010001101????????: {next, len, code} = {in[15], 5'd16, 32'd105};
24'b00100010110001100???????: {next, len, code} = {in[14], 5'd17, 32'd106};
24'b00100010101101010???????: {next, len, code} = {in[14], 5'd17, 32'd107};
24'b11111110111100000???????: {next, len, code} = {in[14], 5'd17, 32'd108};
24'b00100000111010000???????: {next, len, code} = {in[14], 5'd17, 32'd109};
24'b00100111011101001???????: {next, len, code} = {in[14], 5'd17, 32'd110};
24'b11111110111000011???????: {next, len, code} = {in[14], 5'd17, 32'd111};
24'b11110001101000100???????: {next, len, code} = {in[14], 5'd17, 32'd112};
24'b11101011101011101???????: {next, len, code} = {in[14], 5'd17, 32'd113};
24'b01010000100101011???????: {next, len, code} = {in[14], 5'd17, 32'd114};
24'b00100100110011001???????: {next, len, code} = {in[14], 5'd17, 32'd115};
24'b01001110010101000???????: {next, len, code} = {in[14], 5'd17, 32'd116};
24'b010011110101001000??????: {next, len, code} = {in[13], 5'd18, 32'd117};
24'b111010101110010010??????: {next, len, code} = {in[13], 5'd18, 32'd118};
24'b001001001001111000??????: {next, len, code} = {in[13], 5'd18, 32'd119};
24'b101111000110111101??????: {next, len, code} = {in[13], 5'd18, 32'd120};
24'b101101111010101001??????: {next, len, code} = {in[13], 5'd18, 32'd121};
24'b111101110010111110??????: {next, len, code} = {in[13], 5'd18, 32'd122};
24'b010100100011010000??????: {next, len, code} = {in[13], 5'd18, 32'd123};
24'b001001001111011001??????: {next, len, code} = {in[13], 5'd18, 32'd124};
24'b010100110010001001??????: {next, len, code} = {in[13], 5'd18, 32'd125};
24'b111010110000111000??????: {next, len, code} = {in[13], 5'd18, 32'd126};
24'b111010110011000101??????: {next, len, code} = {in[13], 5'd18, 32'd127};
24'b010100001000111001??????: {next, len, code} = {in[13], 5'd18, 32'd128};
24'b1000001011000110100?????: {next, len, code} = {in[12], 5'd19, 32'd129};
24'b0010010111001110110?????: {next, len, code} = {in[12], 5'd19, 32'd130};
24'b0101011001000001101?????: {next, len, code} = {in[12], 5'd19, 32'd131};
24'b0101000010010101011?????: {next, len, code} = {in[12], 5'd19, 32'd132};
24'b1111011111101001101?????: {next, len, code} = {in[12], 5'd19, 32'd133};
24'b1011001000101010110?????: {next, len, code} = {in[12], 5'd19, 32'd134};
24'b1011000001000100001?????: {next, len, code} = {in[12], 5'd19, 32'd135};
24'b1110101100010011001?????: {next, len, code} = {in[12], 5'd19, 32'd136};
24'b0010010111010111110?????: {next, len, code} = {in[12], 5'd19, 32'd137};
24'b0010010001100111100?????: {next, len, code} = {in[12], 5'd19, 32'd138};
24'b1011001011100000101?????: {next, len, code} = {in[12], 5'd19, 32'd139};
24'b1011000100010100101?????: {next, len, code} = {in[12], 5'd19, 32'd140};
24'b1111111001000111011?????: {next, len, code} = {in[12], 5'd19, 32'd141};
24'b00100010111101101101????: {next, len, code} = {in[11], 5'd20, 32'd142};
24'b10000010101010101101????: {next, len, code} = {in[11], 5'd20, 32'd143};
24'b10110010100101001101????: {next, len, code} = {in[11], 5'd20, 32'd144};
24'b01010110111100010000????: {next, len, code} = {in[11], 5'd20, 32'd145};
24'b10110111110011001001????: {next, len, code} = {in[11], 5'd20, 32'd146};
24'b11111101101100100101????: {next, len, code} = {in[11], 5'd20, 32'd147};
24'b10110000010100100001????: {next, len, code} = {in[11], 5'd20, 32'd148};
24'b10110010011010110110????: {next, len, code} = {in[11], 5'd20, 32'd149};
24'b01111001010000011000????: {next, len, code} = {in[11], 5'd20, 32'd150};
24'b11110110001011011011????: {next, len, code} = {in[11], 5'd20, 32'd151};
24'b01010000100100001011????: {next, len, code} = {in[11], 5'd20, 32'd152};
24'b10110001100101110111????: {next, len, code} = {in[11], 5'd20, 32'd153};
24'b10111100110111101000????: {next, len, code} = {in[11], 5'd20, 32'd154};
24'b01010001010111010000????: {next, len, code} = {in[11], 5'd20, 32'd155};
24'b01010100111110001110????: {next, len, code} = {in[11], 5'd20, 32'd156};
24'b11111110011001100111????: {next, len, code} = {in[11], 5'd20, 32'd157};
24'b11110111111101010001????: {next, len, code} = {in[11], 5'd20, 32'd158};
24'b10110000010111100000????: {next, len, code} = {in[11], 5'd20, 32'd159};
24'b01001111100001000101????: {next, len, code} = {in[11], 5'd20, 32'd160};
24'b01010010000111010110????: {next, len, code} = {in[11], 5'd20, 32'd161};
24'b11101010101011101111????: {next, len, code} = {in[11], 5'd20, 32'd162};
24'b11111110010011100011????: {next, len, code} = {in[11], 5'd20, 32'd163};
24'b01010111001111101111????: {next, len, code} = {in[11], 5'd20, 32'd164};
24'b10110001111111111101????: {next, len, code} = {in[11], 5'd20, 32'd165};
24'b10110001001100110000????: {next, len, code} = {in[11], 5'd20, 32'd166};
24'b11110100011000111101????: {next, len, code} = {in[11], 5'd20, 32'd167};
24'b00101011101110100011????: {next, len, code} = {in[11], 5'd20, 32'd168};
24'b01010000011011111110????: {next, len, code} = {in[11], 5'd20, 32'd169};
24'b00000111000010000010????: {next, len, code} = {in[11], 5'd20, 32'd170};
24'b00101010000011001000????: {next, len, code} = {in[11], 5'd20, 32'd171};
24'b01001110010100101110????: {next, len, code} = {in[11], 5'd20, 32'd172};
24'b11110000000010000000????: {next, len, code} = {in[11], 5'd20, 32'd173};
24'b01001101011001111001????: {next, len, code} = {in[11], 5'd20, 32'd174};
24'b11110111000111010101????: {next, len, code} = {in[11], 5'd20, 32'd175};
24'b01111001101001110110????: {next, len, code} = {in[11], 5'd20, 32'd176};
24'b11110000101011101111????: {next, len, code} = {in[11], 5'd20, 32'd177};
24'b00100100100110101010????: {next, len, code} = {in[11], 5'd20, 32'd178};
24'b11110001011011000011????: {next, len, code} = {in[11], 5'd20, 32'd179};
24'b01010111001000110011????: {next, len, code} = {in[11], 5'd20, 32'd180};
24'b01111000000100010101????: {next, len, code} = {in[11], 5'd20, 32'd181};
24'b00100101101011001101????: {next, len, code} = {in[11], 5'd20, 32'd182};
24'b10110010110000111001????: {next, len, code} = {in[11], 5'd20, 32'd183};
24'b10110000101010000011????: {next, len, code} = {in[11], 5'd20, 32'd184};
24'b00100100111110001101????: {next, len, code} = {in[11], 5'd20, 32'd185};
24'b01111001101001101011????: {next, len, code} = {in[11], 5'd20, 32'd186};
24'b01010001000000010001????: {next, len, code} = {in[11], 5'd20, 32'd187};
24'b11110101111111101110????: {next, len, code} = {in[11], 5'd20, 32'd188};
24'b10000010111110110011????: {next, len, code} = {in[11], 5'd20, 32'd189};
24'b00000100011110100111????: {next, len, code} = {in[11], 5'd20, 32'd190};
24'b11111101001111101100????: {next, len, code} = {in[11], 5'd20, 32'd191};
24'b00101011100011110000????: {next, len, code} = {in[11], 5'd20, 32'd192};
24'b00100100111001011001????: {next, len, code} = {in[11], 5'd20, 32'd193};
24'b10000010101000000100????: {next, len, code} = {in[11], 5'd20, 32'd194};
24'b11110001001000111100????: {next, len, code} = {in[11], 5'd20, 32'd195};
24'b10111100011010011001????: {next, len, code} = {in[11], 5'd20, 32'd196};
24'b000000??????????????????: begin
casez (in[33:32])
2'b1?: {next, len, code} = {1'b0, 5'd18, 32'd197};
2'b01: {next, len, code} = {1'b0, 5'd19, 32'd198};
2'b00: {next, len, code} = {1'b0, 5'd19, 32'd199};
default: ;
endcase
end
default: ;
endcase
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2003 by Wilson Snyder.
//
// This is a copy of t_param.v with the parentheses around the module parameters
// removed.
module t (/*AUTOARG*/
// Inputs
clk
);
parameter PAR = 3;
m1 #PAR m1();
m3 #PAR m3();
mnooverride #10 mno();
input clk;
integer cyc=1;
reg [4:0] bitsel;
always @ (posedge clk) begin
cyc <= cyc + 1;
if (cyc==0) begin
bitsel = 0;
if (PAR[bitsel]!==1'b1) $stop;
bitsel = 1;
if (PAR[bitsel]!==1'b1) $stop;
bitsel = 2;
if (PAR[bitsel]!==1'b0) $stop;
end
if (cyc==1) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
module m1;
localparam PAR1MINUS1 = PAR1DUP-2-1;
localparam PAR1DUP = PAR1+2; // Check we propagate parameters properly
parameter PAR1 = 0;
m2 #PAR1MINUS1 m2 ();
endmodule
module m2;
parameter PAR2 = 10;
initial begin
$display("%x",PAR2);
if (PAR2 !== 2) $stop;
end
endmodule
module m3;
localparam LOC = 13;
parameter PAR = 10;
initial begin
$display("%x %x",LOC,PAR);
if (LOC !== 13) $stop;
if (PAR !== 3) $stop;
end
endmodule
module mnooverride;
localparam LOC = 13;
parameter PAR = 10;
initial begin
$display("%x %x",LOC,PAR);
if (LOC !== 13) $stop;
if (PAR !== 10) $stop;
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2003 by Wilson Snyder.
//
// This is a copy of t_param.v with the parentheses around the module parameters
// removed.
module t (/*AUTOARG*/
// Inputs
clk
);
parameter PAR = 3;
m1 #PAR m1();
m3 #PAR m3();
mnooverride #10 mno();
input clk;
integer cyc=1;
reg [4:0] bitsel;
always @ (posedge clk) begin
cyc <= cyc + 1;
if (cyc==0) begin
bitsel = 0;
if (PAR[bitsel]!==1'b1) $stop;
bitsel = 1;
if (PAR[bitsel]!==1'b1) $stop;
bitsel = 2;
if (PAR[bitsel]!==1'b0) $stop;
end
if (cyc==1) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
module m1;
localparam PAR1MINUS1 = PAR1DUP-2-1;
localparam PAR1DUP = PAR1+2; // Check we propagate parameters properly
parameter PAR1 = 0;
m2 #PAR1MINUS1 m2 ();
endmodule
module m2;
parameter PAR2 = 10;
initial begin
$display("%x",PAR2);
if (PAR2 !== 2) $stop;
end
endmodule
module m3;
localparam LOC = 13;
parameter PAR = 10;
initial begin
$display("%x %x",LOC,PAR);
if (LOC !== 13) $stop;
if (PAR !== 3) $stop;
end
endmodule
module mnooverride;
localparam LOC = 13;
parameter PAR = 10;
initial begin
$display("%x %x",LOC,PAR);
if (LOC !== 13) $stop;
if (PAR !== 10) $stop;
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2003 by Wilson Snyder.
//
// This is a copy of t_param.v with the parentheses around the module parameters
// removed.
module t (/*AUTOARG*/
// Inputs
clk
);
parameter PAR = 3;
m1 #PAR m1();
m3 #PAR m3();
mnooverride #10 mno();
input clk;
integer cyc=1;
reg [4:0] bitsel;
always @ (posedge clk) begin
cyc <= cyc + 1;
if (cyc==0) begin
bitsel = 0;
if (PAR[bitsel]!==1'b1) $stop;
bitsel = 1;
if (PAR[bitsel]!==1'b1) $stop;
bitsel = 2;
if (PAR[bitsel]!==1'b0) $stop;
end
if (cyc==1) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
module m1;
localparam PAR1MINUS1 = PAR1DUP-2-1;
localparam PAR1DUP = PAR1+2; // Check we propagate parameters properly
parameter PAR1 = 0;
m2 #PAR1MINUS1 m2 ();
endmodule
module m2;
parameter PAR2 = 10;
initial begin
$display("%x",PAR2);
if (PAR2 !== 2) $stop;
end
endmodule
module m3;
localparam LOC = 13;
parameter PAR = 10;
initial begin
$display("%x %x",LOC,PAR);
if (LOC !== 13) $stop;
if (PAR !== 3) $stop;
end
endmodule
module mnooverride;
localparam LOC = 13;
parameter PAR = 10;
initial begin
$display("%x %x",LOC,PAR);
if (LOC !== 13) $stop;
if (PAR !== 10) $stop;
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2003 by Wilson Snyder.
//
// This is a copy of t_param.v with the parentheses around the module parameters
// removed.
module t (/*AUTOARG*/
// Inputs
clk
);
parameter PAR = 3;
m1 #PAR m1();
m3 #PAR m3();
mnooverride #10 mno();
input clk;
integer cyc=1;
reg [4:0] bitsel;
always @ (posedge clk) begin
cyc <= cyc + 1;
if (cyc==0) begin
bitsel = 0;
if (PAR[bitsel]!==1'b1) $stop;
bitsel = 1;
if (PAR[bitsel]!==1'b1) $stop;
bitsel = 2;
if (PAR[bitsel]!==1'b0) $stop;
end
if (cyc==1) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
module m1;
localparam PAR1MINUS1 = PAR1DUP-2-1;
localparam PAR1DUP = PAR1+2; // Check we propagate parameters properly
parameter PAR1 = 0;
m2 #PAR1MINUS1 m2 ();
endmodule
module m2;
parameter PAR2 = 10;
initial begin
$display("%x",PAR2);
if (PAR2 !== 2) $stop;
end
endmodule
module m3;
localparam LOC = 13;
parameter PAR = 10;
initial begin
$display("%x %x",LOC,PAR);
if (LOC !== 13) $stop;
if (PAR !== 3) $stop;
end
endmodule
module mnooverride;
localparam LOC = 13;
parameter PAR = 10;
initial begin
$display("%x %x",LOC,PAR);
if (LOC !== 13) $stop;
if (PAR !== 10) $stop;
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2004 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
integer cyc; initial cyc=1;
reg [31:0] a;
reg [31:0] b;
wire [2:0] bf; buf BF0 (bf[0], a[0]),
BF1 (bf[1], a[1]),
BF2 (bf[2], a[2]);
// verilator lint_off IMPLICIT
not #(0.108) NT0 (nt0, a[0]);
and #1 AN0 (an0, a[0], b[0]);
nand #(2,3) ND0 (nd0, a[0], b[0], b[1]);
or OR0 (or0, a[0], b[0]);
nor NR0 (nr0, a[0], b[0], b[2]);
xor (xo0, a[0], b[0]);
xnor (xn0, a[0], b[0], b[2]);
// verilator lint_on IMPLICIT
parameter BITS=32;
wire [BITS-1:0] ba;
buf BARRAY [BITS-1:0] (ba, a);
`ifdef verilator
specify
specparam CDS_LIBNAME = "foobar";
(nt0 *> nt0) = (0, 0);
endspecify
specify
// delay parameters
specparam
a$A1$Y = 1.0,
b$A0$Z = 1.0;
// path delays
(A1 *> Q) = (a$A1$Y, a$A1$Y);
(A0 *> Q) = (b$A0$Y, a$A0$Z);
endspecify
`endif
always @ (posedge clk) begin
if (cyc!=0) begin
cyc <= cyc + 1;
if (cyc==1) begin
a <= 32'h18f6b034;
b <= 32'h834bf892;
end
if (cyc==2) begin
a <= 32'h529ab56f;
b <= 32'h7835a237;
if (bf !== 3'b100) $stop;
if (nt0 !== 1'b1) $stop;
if (an0 !== 1'b0) $stop;
if (nd0 !== 1'b1) $stop;
if (or0 !== 1'b0) $stop;
if (nr0 !== 1'b1) $stop;
if (xo0 !== 1'b0) $stop;
if (xn0 !== 1'b1) $stop;
if (ba != 32'h18f6b034) $stop;
end
if (cyc==3) begin
if (bf !== 3'b111) $stop;
if (nt0 !== 1'b0) $stop;
if (an0 !== 1'b1) $stop;
if (nd0 !== 1'b0) $stop;
if (or0 !== 1'b1) $stop;
if (nr0 !== 1'b0) $stop;
if (xo0 !== 1'b0) $stop;
if (xn0 !== 1'b0) $stop;
end
if (cyc==4) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2004 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
integer cyc; initial cyc=1;
reg [31:0] a;
reg [31:0] b;
wire [2:0] bf; buf BF0 (bf[0], a[0]),
BF1 (bf[1], a[1]),
BF2 (bf[2], a[2]);
// verilator lint_off IMPLICIT
not #(0.108) NT0 (nt0, a[0]);
and #1 AN0 (an0, a[0], b[0]);
nand #(2,3) ND0 (nd0, a[0], b[0], b[1]);
or OR0 (or0, a[0], b[0]);
nor NR0 (nr0, a[0], b[0], b[2]);
xor (xo0, a[0], b[0]);
xnor (xn0, a[0], b[0], b[2]);
// verilator lint_on IMPLICIT
parameter BITS=32;
wire [BITS-1:0] ba;
buf BARRAY [BITS-1:0] (ba, a);
`ifdef verilator
specify
specparam CDS_LIBNAME = "foobar";
(nt0 *> nt0) = (0, 0);
endspecify
specify
// delay parameters
specparam
a$A1$Y = 1.0,
b$A0$Z = 1.0;
// path delays
(A1 *> Q) = (a$A1$Y, a$A1$Y);
(A0 *> Q) = (b$A0$Y, a$A0$Z);
endspecify
`endif
always @ (posedge clk) begin
if (cyc!=0) begin
cyc <= cyc + 1;
if (cyc==1) begin
a <= 32'h18f6b034;
b <= 32'h834bf892;
end
if (cyc==2) begin
a <= 32'h529ab56f;
b <= 32'h7835a237;
if (bf !== 3'b100) $stop;
if (nt0 !== 1'b1) $stop;
if (an0 !== 1'b0) $stop;
if (nd0 !== 1'b1) $stop;
if (or0 !== 1'b0) $stop;
if (nr0 !== 1'b1) $stop;
if (xo0 !== 1'b0) $stop;
if (xn0 !== 1'b1) $stop;
if (ba != 32'h18f6b034) $stop;
end
if (cyc==3) begin
if (bf !== 3'b111) $stop;
if (nt0 !== 1'b0) $stop;
if (an0 !== 1'b1) $stop;
if (nd0 !== 1'b0) $stop;
if (or0 !== 1'b1) $stop;
if (nr0 !== 1'b0) $stop;
if (xo0 !== 1'b0) $stop;
if (xn0 !== 1'b0) $stop;
end
if (cyc==4) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2004 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
integer cyc; initial cyc=1;
reg [31:0] a;
reg [31:0] b;
wire [2:0] bf; buf BF0 (bf[0], a[0]),
BF1 (bf[1], a[1]),
BF2 (bf[2], a[2]);
// verilator lint_off IMPLICIT
not #(0.108) NT0 (nt0, a[0]);
and #1 AN0 (an0, a[0], b[0]);
nand #(2,3) ND0 (nd0, a[0], b[0], b[1]);
or OR0 (or0, a[0], b[0]);
nor NR0 (nr0, a[0], b[0], b[2]);
xor (xo0, a[0], b[0]);
xnor (xn0, a[0], b[0], b[2]);
// verilator lint_on IMPLICIT
parameter BITS=32;
wire [BITS-1:0] ba;
buf BARRAY [BITS-1:0] (ba, a);
`ifdef verilator
specify
specparam CDS_LIBNAME = "foobar";
(nt0 *> nt0) = (0, 0);
endspecify
specify
// delay parameters
specparam
a$A1$Y = 1.0,
b$A0$Z = 1.0;
// path delays
(A1 *> Q) = (a$A1$Y, a$A1$Y);
(A0 *> Q) = (b$A0$Y, a$A0$Z);
endspecify
`endif
always @ (posedge clk) begin
if (cyc!=0) begin
cyc <= cyc + 1;
if (cyc==1) begin
a <= 32'h18f6b034;
b <= 32'h834bf892;
end
if (cyc==2) begin
a <= 32'h529ab56f;
b <= 32'h7835a237;
if (bf !== 3'b100) $stop;
if (nt0 !== 1'b1) $stop;
if (an0 !== 1'b0) $stop;
if (nd0 !== 1'b1) $stop;
if (or0 !== 1'b0) $stop;
if (nr0 !== 1'b1) $stop;
if (xo0 !== 1'b0) $stop;
if (xn0 !== 1'b1) $stop;
if (ba != 32'h18f6b034) $stop;
end
if (cyc==3) begin
if (bf !== 3'b111) $stop;
if (nt0 !== 1'b0) $stop;
if (an0 !== 1'b1) $stop;
if (nd0 !== 1'b0) $stop;
if (or0 !== 1'b1) $stop;
if (nr0 !== 1'b0) $stop;
if (xo0 !== 1'b0) $stop;
if (xn0 !== 1'b0) $stop;
end
if (cyc==4) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2004 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
integer cyc; initial cyc=1;
reg [31:0] a;
reg [31:0] b;
wire [2:0] bf; buf BF0 (bf[0], a[0]),
BF1 (bf[1], a[1]),
BF2 (bf[2], a[2]);
// verilator lint_off IMPLICIT
not #(0.108) NT0 (nt0, a[0]);
and #1 AN0 (an0, a[0], b[0]);
nand #(2,3) ND0 (nd0, a[0], b[0], b[1]);
or OR0 (or0, a[0], b[0]);
nor NR0 (nr0, a[0], b[0], b[2]);
xor (xo0, a[0], b[0]);
xnor (xn0, a[0], b[0], b[2]);
// verilator lint_on IMPLICIT
parameter BITS=32;
wire [BITS-1:0] ba;
buf BARRAY [BITS-1:0] (ba, a);
`ifdef verilator
specify
specparam CDS_LIBNAME = "foobar";
(nt0 *> nt0) = (0, 0);
endspecify
specify
// delay parameters
specparam
a$A1$Y = 1.0,
b$A0$Z = 1.0;
// path delays
(A1 *> Q) = (a$A1$Y, a$A1$Y);
(A0 *> Q) = (b$A0$Y, a$A0$Z);
endspecify
`endif
always @ (posedge clk) begin
if (cyc!=0) begin
cyc <= cyc + 1;
if (cyc==1) begin
a <= 32'h18f6b034;
b <= 32'h834bf892;
end
if (cyc==2) begin
a <= 32'h529ab56f;
b <= 32'h7835a237;
if (bf !== 3'b100) $stop;
if (nt0 !== 1'b1) $stop;
if (an0 !== 1'b0) $stop;
if (nd0 !== 1'b1) $stop;
if (or0 !== 1'b0) $stop;
if (nr0 !== 1'b1) $stop;
if (xo0 !== 1'b0) $stop;
if (xn0 !== 1'b1) $stop;
if (ba != 32'h18f6b034) $stop;
end
if (cyc==3) begin
if (bf !== 3'b111) $stop;
if (nt0 !== 1'b0) $stop;
if (an0 !== 1'b1) $stop;
if (nd0 !== 1'b0) $stop;
if (or0 !== 1'b1) $stop;
if (nr0 !== 1'b0) $stop;
if (xo0 !== 1'b0) $stop;
if (xn0 !== 1'b0) $stop;
end
if (cyc==4) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2003 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
reg [7:0] cyc; initial cyc=0;
reg [31:0] loops;
reg [31:0] loops2;
always @ (posedge clk) begin
cyc <= cyc+8'd1;
if (cyc == 8'd1) begin
$write("[%0t] t_loop: Running\n",$time);
// Unwind <
loops = 0;
loops2 = 0;
for (int i=0; i<16; i=i+1) begin
loops = loops + i; // surefire lint_off_line ASWEMB
loops2 = loops2 + i; // surefire lint_off_line ASWEMB
end
if (loops !== 120) $stop;
if (loops2 !== 120) $stop;
// Check we can declare the same signal twice
loops = 0;
for (int i=0; i<=16; i=i+1) begin
loops = loops + 1;
end
if (loops !== 17) $stop;
// Check type is correct
loops = 0;
for (byte unsigned i=5; i>4; i=i+1) begin
loops = loops + 1;
end
if (loops !== 251) $stop;
// Check large loops
loops = 0;
for (int i=0; i<100000; i=i+1) begin
loops = loops + 1;
end
if (loops !== 100000) $stop;
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2003 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
reg [7:0] cyc; initial cyc=0;
reg [31:0] loops;
reg [31:0] loops2;
always @ (posedge clk) begin
cyc <= cyc+8'd1;
if (cyc == 8'd1) begin
$write("[%0t] t_loop: Running\n",$time);
// Unwind <
loops = 0;
loops2 = 0;
for (int i=0; i<16; i=i+1) begin
loops = loops + i; // surefire lint_off_line ASWEMB
loops2 = loops2 + i; // surefire lint_off_line ASWEMB
end
if (loops !== 120) $stop;
if (loops2 !== 120) $stop;
// Check we can declare the same signal twice
loops = 0;
for (int i=0; i<=16; i=i+1) begin
loops = loops + 1;
end
if (loops !== 17) $stop;
// Check type is correct
loops = 0;
for (byte unsigned i=5; i>4; i=i+1) begin
loops = loops + 1;
end
if (loops !== 251) $stop;
// Check large loops
loops = 0;
for (int i=0; i<100000; i=i+1) begin
loops = loops + 1;
end
if (loops !== 100000) $stop;
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2004 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
integer cyc; initial cyc=1;
reg [255:0] a;
reg [255:0] q;
reg [63:0] qq;
integer i;
always @* begin
for (i=0; i<256; i=i+1) begin
q[255-i] = a[i];
end
q[27:16] = 12'hfed;
for (i=0; i<64; i=i+1) begin
qq[63-i] = a[i];
end
qq[27:16] = 12'hfed;
end
always @ (posedge clk) begin
if (cyc!=0) begin
cyc <= cyc + 1;
`ifdef TEST_VERBOSE
$write("%x/%x %x\n", q, qq, a);
`endif
if (cyc==1) begin
a = 256'hed388e646c843d35de489bab2413d77045e0eb7642b148537491f3da147e7f26;
end
if (cyc==2) begin
a = 256'h0e17c88f3d5fe51a982646c8e2bd68c3e236ddfddddbdad20a48e039c9f395b8;
if (q != 256'h64fe7e285bcf892eca128d426ed707a20eebc824d5d9127bacbc21362fed1cb7) $stop;
if (qq != 64'h64fe7e285fed892e) $stop;
end
if (cyc==3) begin
if (q != 256'h1da9cf939c0712504b5bdbbbbfbb6c47c316bd471362641958a7fabcffede870) $stop;
if (qq != 64'h1da9cf939fed1250) $stop;
end
if (cyc==4) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2004 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
integer cyc; initial cyc=1;
reg [255:0] a;
reg [255:0] q;
reg [63:0] qq;
integer i;
always @* begin
for (i=0; i<256; i=i+1) begin
q[255-i] = a[i];
end
q[27:16] = 12'hfed;
for (i=0; i<64; i=i+1) begin
qq[63-i] = a[i];
end
qq[27:16] = 12'hfed;
end
always @ (posedge clk) begin
if (cyc!=0) begin
cyc <= cyc + 1;
`ifdef TEST_VERBOSE
$write("%x/%x %x\n", q, qq, a);
`endif
if (cyc==1) begin
a = 256'hed388e646c843d35de489bab2413d77045e0eb7642b148537491f3da147e7f26;
end
if (cyc==2) begin
a = 256'h0e17c88f3d5fe51a982646c8e2bd68c3e236ddfddddbdad20a48e039c9f395b8;
if (q != 256'h64fe7e285bcf892eca128d426ed707a20eebc824d5d9127bacbc21362fed1cb7) $stop;
if (qq != 64'h64fe7e285fed892e) $stop;
end
if (cyc==3) begin
if (q != 256'h1da9cf939c0712504b5bdbbbbfbb6c47c316bd471362641958a7fabcffede870) $stop;
if (qq != 64'h1da9cf939fed1250) $stop;
end
if (cyc==4) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2005 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
reg [31:0] narrow;
reg [63:0] quad;
reg [127:0] wide;
integer cyc; initial cyc=0;
reg [7:0] crc;
reg [6:0] index;
always @ (posedge clk) begin
//$write("[%0t] cyc==%0d crc=%b n=%x\n",$time, cyc, crc, narrow);
cyc <= cyc + 1;
if (cyc==0) begin
// Setup
narrow <= 32'h0;
quad <= 64'h0;
wide <= 128'h0;
crc <= 8'hed;
index <= 7'h0;
end
else if (cyc<90) begin
index <= index + 7'h2;
crc <= {crc[6:0], ~^ {crc[7],crc[5],crc[4],crc[3]}};
// verilator lint_off WIDTH
if (index < 9'd20) narrow[index +: 3] <= crc[2:0];
if (index < 9'd60) quad [index +: 3] <= crc[2:0];
if (index < 9'd120) wide [index +: 3] <= crc[2:0];
//
narrow[index[3:0]] <= ~narrow[index[3:0]];
quad [~index[3:0]]<= ~quad [~index[3:0]];
wide [~index[3:0]] <= ~wide [~index[3:0]];
// verilator lint_on WIDTH
end
else if (cyc==90) begin
wide[12 +: 4] <=4'h6; quad[12 +: 4] <=4'h6; narrow[12 +: 4] <=4'h6;
wide[42 +: 4] <=4'h6; quad[42 +: 4] <=4'h6;
wide[82 +: 4] <=4'h6;
end
else if (cyc==91) begin
wide[0] <=1'b1; quad[0] <=1'b1; narrow[0] <=1'b1;
wide[41] <=1'b1; quad[41] <=1'b1;
wide[81] <=1'b1;
end
else if (cyc==99) begin
$write("[%0t] cyc==%0d crc=%b n=%x q=%x w=%x\n",$time, cyc, crc, narrow, quad, wide);
if (crc != 8'b01111001) $stop;
if (narrow != 32'h001661c7) $stop;
if (quad != 64'h16d49b6f64266039) $stop;
if (wide != 128'h012fd26d265b266ff6d49b6f64266039) $stop;
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2005 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
reg [31:0] narrow;
reg [63:0] quad;
reg [127:0] wide;
integer cyc; initial cyc=0;
reg [7:0] crc;
reg [6:0] index;
always @ (posedge clk) begin
//$write("[%0t] cyc==%0d crc=%b n=%x\n",$time, cyc, crc, narrow);
cyc <= cyc + 1;
if (cyc==0) begin
// Setup
narrow <= 32'h0;
quad <= 64'h0;
wide <= 128'h0;
crc <= 8'hed;
index <= 7'h0;
end
else if (cyc<90) begin
index <= index + 7'h2;
crc <= {crc[6:0], ~^ {crc[7],crc[5],crc[4],crc[3]}};
// verilator lint_off WIDTH
if (index < 9'd20) narrow[index +: 3] <= crc[2:0];
if (index < 9'd60) quad [index +: 3] <= crc[2:0];
if (index < 9'd120) wide [index +: 3] <= crc[2:0];
//
narrow[index[3:0]] <= ~narrow[index[3:0]];
quad [~index[3:0]]<= ~quad [~index[3:0]];
wide [~index[3:0]] <= ~wide [~index[3:0]];
// verilator lint_on WIDTH
end
else if (cyc==90) begin
wide[12 +: 4] <=4'h6; quad[12 +: 4] <=4'h6; narrow[12 +: 4] <=4'h6;
wide[42 +: 4] <=4'h6; quad[42 +: 4] <=4'h6;
wide[82 +: 4] <=4'h6;
end
else if (cyc==91) begin
wide[0] <=1'b1; quad[0] <=1'b1; narrow[0] <=1'b1;
wide[41] <=1'b1; quad[41] <=1'b1;
wide[81] <=1'b1;
end
else if (cyc==99) begin
$write("[%0t] cyc==%0d crc=%b n=%x q=%x w=%x\n",$time, cyc, crc, narrow, quad, wide);
if (crc != 8'b01111001) $stop;
if (narrow != 32'h001661c7) $stop;
if (quad != 64'h16d49b6f64266039) $stop;
if (wide != 128'h012fd26d265b266ff6d49b6f64266039) $stop;
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2005 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
parameter PAR = 3;
input clk;
m3 m3_inst (.clk(clk));
defparam m3_inst.FROMDEFP = 19;
defparam m3_inst.P2 = 2;
//defparam m3_inst.P3 = PAR;
defparam m3_inst.P3 = 3;
integer cyc=1;
always @ (posedge clk) begin
cyc <= cyc + 1;
if (cyc==1) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
module m3
(/*AUTOARG*/
// Inputs
clk
);
input clk;
localparam LOC = 13;
parameter UNCH = 99;
parameter P1 = 10;
parameter P2 = 20;
parameter P3 = 30;
parameter FROMDEFP = 11;
initial begin
$display("%x %x %x",P1,P2,P3);
end
always @ (posedge clk) begin
if (UNCH !== 99) $stop;
if (P1 !== 10) $stop;
if (P2 !== 2) $stop;
if (P3 !== 3) $stop;
if (FROMDEFP !== 19) $stop;
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2005 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
parameter PAR = 3;
input clk;
m3 m3_inst (.clk(clk));
defparam m3_inst.FROMDEFP = 19;
defparam m3_inst.P2 = 2;
//defparam m3_inst.P3 = PAR;
defparam m3_inst.P3 = 3;
integer cyc=1;
always @ (posedge clk) begin
cyc <= cyc + 1;
if (cyc==1) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
module m3
(/*AUTOARG*/
// Inputs
clk
);
input clk;
localparam LOC = 13;
parameter UNCH = 99;
parameter P1 = 10;
parameter P2 = 20;
parameter P3 = 30;
parameter FROMDEFP = 11;
initial begin
$display("%x %x %x",P1,P2,P3);
end
always @ (posedge clk) begin
if (UNCH !== 99) $stop;
if (P1 !== 10) $stop;
if (P2 !== 2) $stop;
if (P3 !== 3) $stop;
if (FROMDEFP !== 19) $stop;
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2005 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
parameter PAR = 3;
input clk;
m3 m3_inst (.clk(clk));
defparam m3_inst.FROMDEFP = 19;
defparam m3_inst.P2 = 2;
//defparam m3_inst.P3 = PAR;
defparam m3_inst.P3 = 3;
integer cyc=1;
always @ (posedge clk) begin
cyc <= cyc + 1;
if (cyc==1) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
module m3
(/*AUTOARG*/
// Inputs
clk
);
input clk;
localparam LOC = 13;
parameter UNCH = 99;
parameter P1 = 10;
parameter P2 = 20;
parameter P3 = 30;
parameter FROMDEFP = 11;
initial begin
$display("%x %x %x",P1,P2,P3);
end
always @ (posedge clk) begin
if (UNCH !== 99) $stop;
if (P1 !== 10) $stop;
if (P2 !== 2) $stop;
if (P3 !== 3) $stop;
if (FROMDEFP !== 19) $stop;
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2005 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
parameter PAR = 3;
input clk;
m3 m3_inst (.clk(clk));
defparam m3_inst.FROMDEFP = 19;
defparam m3_inst.P2 = 2;
//defparam m3_inst.P3 = PAR;
defparam m3_inst.P3 = 3;
integer cyc=1;
always @ (posedge clk) begin
cyc <= cyc + 1;
if (cyc==1) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
module m3
(/*AUTOARG*/
// Inputs
clk
);
input clk;
localparam LOC = 13;
parameter UNCH = 99;
parameter P1 = 10;
parameter P2 = 20;
parameter P3 = 30;
parameter FROMDEFP = 11;
initial begin
$display("%x %x %x",P1,P2,P3);
end
always @ (posedge clk) begin
if (UNCH !== 99) $stop;
if (P1 !== 10) $stop;
if (P2 !== 2) $stop;
if (P3 !== 3) $stop;
if (FROMDEFP !== 19) $stop;
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2005 by Wilson Snyder.
module t (/*AUTOARG*/
// Outputs
\escaped_normal , double__underscore, \9num , \bra[ket]slash/dash-colon:9backslash\done ,
// Inputs
clk
);
input clk;
integer cyc; initial cyc=1;
output \escaped_normal ;
wire \escaped_normal = cyc[0];
output double__underscore ;
wire double__underscore = cyc[0];
// C doesn't allow leading non-alpha, so must escape
output \9num ;
wire \9num = cyc[0];
output \bra[ket]slash/dash-colon:9backslash\done ;
wire \bra[ket]slash/dash-colon:9backslash\done = cyc[0];
wire \wire = cyc[0];
wire \check_alias = cyc[0];
wire \check:alias = cyc[0];
wire \check;alias = !cyc[0];
// These are *different entities*, bug83
wire [31:0] \a0.cyc = ~a0.cyc;
wire [31:0] \other.cyc = ~a0.cyc;
sub a0 (.cyc(cyc));
sub \mod.with_dot (.cyc(cyc));
always @ (posedge clk) begin
cyc <= cyc + 1;
if (escaped_normal != cyc[0]) $stop;
if (\escaped_normal != cyc[0]) $stop;
if (double__underscore != cyc[0]) $stop;
if (\9num != cyc[0]) $stop;
if (\bra[ket]slash/dash-colon:9backslash\done != cyc[0]) $stop;
if (\wire != cyc[0]) $stop;
if (\check_alias != cyc[0]) $stop;
if (\check:alias != cyc[0]) $stop;
if (\check;alias != !cyc[0]) $stop;
if (\a0.cyc != ~cyc) $stop;
if (\other.cyc != ~cyc) $stop;
if (cyc==10) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
module sub (
input [31:0] cyc
);
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2005 by Wilson Snyder.
module t (/*AUTOARG*/
// Outputs
\escaped_normal , double__underscore, \9num , \bra[ket]slash/dash-colon:9backslash\done ,
// Inputs
clk
);
input clk;
integer cyc; initial cyc=1;
output \escaped_normal ;
wire \escaped_normal = cyc[0];
output double__underscore ;
wire double__underscore = cyc[0];
// C doesn't allow leading non-alpha, so must escape
output \9num ;
wire \9num = cyc[0];
output \bra[ket]slash/dash-colon:9backslash\done ;
wire \bra[ket]slash/dash-colon:9backslash\done = cyc[0];
wire \wire = cyc[0];
wire \check_alias = cyc[0];
wire \check:alias = cyc[0];
wire \check;alias = !cyc[0];
// These are *different entities*, bug83
wire [31:0] \a0.cyc = ~a0.cyc;
wire [31:0] \other.cyc = ~a0.cyc;
sub a0 (.cyc(cyc));
sub \mod.with_dot (.cyc(cyc));
always @ (posedge clk) begin
cyc <= cyc + 1;
if (escaped_normal != cyc[0]) $stop;
if (\escaped_normal != cyc[0]) $stop;
if (double__underscore != cyc[0]) $stop;
if (\9num != cyc[0]) $stop;
if (\bra[ket]slash/dash-colon:9backslash\done != cyc[0]) $stop;
if (\wire != cyc[0]) $stop;
if (\check_alias != cyc[0]) $stop;
if (\check:alias != cyc[0]) $stop;
if (\check;alias != !cyc[0]) $stop;
if (\a0.cyc != ~cyc) $stop;
if (\other.cyc != ~cyc) $stop;
if (cyc==10) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
module sub (
input [31:0] cyc
);
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2005 by Wilson Snyder.
module t (/*AUTOARG*/
// Outputs
\escaped_normal , double__underscore, \9num , \bra[ket]slash/dash-colon:9backslash\done ,
// Inputs
clk
);
input clk;
integer cyc; initial cyc=1;
output \escaped_normal ;
wire \escaped_normal = cyc[0];
output double__underscore ;
wire double__underscore = cyc[0];
// C doesn't allow leading non-alpha, so must escape
output \9num ;
wire \9num = cyc[0];
output \bra[ket]slash/dash-colon:9backslash\done ;
wire \bra[ket]slash/dash-colon:9backslash\done = cyc[0];
wire \wire = cyc[0];
wire \check_alias = cyc[0];
wire \check:alias = cyc[0];
wire \check;alias = !cyc[0];
// These are *different entities*, bug83
wire [31:0] \a0.cyc = ~a0.cyc;
wire [31:0] \other.cyc = ~a0.cyc;
sub a0 (.cyc(cyc));
sub \mod.with_dot (.cyc(cyc));
always @ (posedge clk) begin
cyc <= cyc + 1;
if (escaped_normal != cyc[0]) $stop;
if (\escaped_normal != cyc[0]) $stop;
if (double__underscore != cyc[0]) $stop;
if (\9num != cyc[0]) $stop;
if (\bra[ket]slash/dash-colon:9backslash\done != cyc[0]) $stop;
if (\wire != cyc[0]) $stop;
if (\check_alias != cyc[0]) $stop;
if (\check:alias != cyc[0]) $stop;
if (\check;alias != !cyc[0]) $stop;
if (\a0.cyc != ~cyc) $stop;
if (\other.cyc != ~cyc) $stop;
if (cyc==10) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
module sub (
input [31:0] cyc
);
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2006 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
// verilator lint_off MULTIDRIVEN
ma ma0 ();
global_mod #(32'hf00d) global_cell ();
global_mod #(32'hf22d) global_cell2 ();
input clk;
integer cyc=1;
function [31:0] getName; input fake; getName = "t "; endfunction
always @ (posedge clk) begin
cyc <= cyc + 1;
if (cyc==2) begin
if (global_cell. getGlob(1'b0) !== 32'hf00d) $stop;
if (global_cell2.getGlob(1'b0) !== 32'hf22d) $stop;
end
if (cyc==3) begin
if (ma0. getName(1'b0) !== "ma ") $stop;
if (ma0.mb0. getName(1'b0) !== "mb ") $stop;
if (ma0.mb0.mc0.getName(1'b0) !== "mc ") $stop;
end
if (cyc==4) begin
if (ma0.mb0. getP2(1'b0) !== 32'h0) $stop;
if (ma0.mb0.mc0.getP3(1'b0) !== 32'h0) $stop;
if (ma0.mb0.mc1.getP3(1'b0) !== 32'h1) $stop;
end
if (cyc==5) begin
ma0. checkName(ma0. getName(1'b0));
ma0.mb0. checkName(ma0.mb0. getName(1'b0));
ma0.mb0.mc0.checkName(ma0.mb0.mc0.getName(1'b0));
end
if (cyc==9) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
`ifdef USE_INLINE_MID
`define INLINE_MODULE /*verilator inline_module*/
`define INLINE_MID_MODULE /*verilator no_inline_module*/
`else
`ifdef USE_INLINE
`define INLINE_MODULE /*verilator inline_module*/
`define INLINE_MID_MODULE /*verilator inline_module*/
`else
`define INLINE_MODULE /*verilator public_module*/
`define INLINE_MID_MODULE /*verilator public_module*/
`endif
`endif
module global_mod;
`INLINE_MODULE
parameter INITVAL = 0;
integer globali;
initial globali = INITVAL;
function [31:0] getName; input fake; getName = "gmod"; endfunction
function [31:0] getGlob; input fake; getGlob = globali; endfunction
endmodule
module ma ();
`INLINE_MODULE
mb #(0) mb0 ();
reg [31:0] gName; initial gName = "ma ";
function [31:0] getName; input fake; getName = "ma "; endfunction
task checkName; input [31:0] name; if (name !== "ma ") $stop; endtask
initial begin
if (ma.getName(1'b0) !== "ma ") $stop;
if (mb0.getName(1'b0) !== "mb ") $stop;
if (mb0.mc0.getName(1'b0) !== "mc ") $stop;
end
endmodule
module mb ();
`INLINE_MID_MODULE
parameter P2 = 0;
mc #(P2,0) mc0 ();
mc #(P2,1) mc1 ();
global_mod #(32'hf33d) global_cell2 ();
reg [31:0] gName; initial gName = "mb ";
function [31:0] getName; input fake; getName = "mb "; endfunction
function [31:0] getP2 ; input fake; getP2 = P2; endfunction
task checkName; input [31:0] name; if (name !== "mb ") $stop; endtask
initial begin
`ifndef verilator #1; `endif
if (ma. getName(1'b0) !== "ma ") $stop;
if ( getName(1'b0) !== "mb ") $stop;
if (mc1.getName(1'b0) !== "mc ") $stop;
ma. checkName (ma. gName);
/**/checkName ( gName);
mc1.checkName (mc1.gName);
ma. checkName (ma. getName(1'b0));
/**/checkName ( getName(1'b0));
mc1.checkName (mc1.getName(1'b0));
end
endmodule
module mc ();
`INLINE_MODULE
parameter P2 = 0;
parameter P3 = 0;
reg [31:0] gName; initial gName = "mc ";
function [31:0] getName; input fake; getName = "mc "; endfunction
function [31:0] getP3 ; input fake; getP3 = P3; endfunction
task checkName; input [31:0] name; if (name !== "mc ") $stop; endtask
initial begin
`ifndef verilator #1; `endif
if (ma.getName(1'b0) !== "ma ") $stop;
if (mb.getName(1'b0) !== "mb ") $stop;
if (mc.getName(1'b0) !== "mc ") $stop;
ma.checkName (ma.gName);
mb.checkName (mb.gName);
mc.checkName (mc.gName);
ma.checkName (ma.getName(1'b0));
mb.checkName (mb.getName(1'b0));
mc.checkName (mc.getName(1'b0));
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2006 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
// verilator lint_off MULTIDRIVEN
ma ma0 ();
global_mod #(32'hf00d) global_cell ();
global_mod #(32'hf22d) global_cell2 ();
input clk;
integer cyc=1;
function [31:0] getName; input fake; getName = "t "; endfunction
always @ (posedge clk) begin
cyc <= cyc + 1;
if (cyc==2) begin
if (global_cell. getGlob(1'b0) !== 32'hf00d) $stop;
if (global_cell2.getGlob(1'b0) !== 32'hf22d) $stop;
end
if (cyc==3) begin
if (ma0. getName(1'b0) !== "ma ") $stop;
if (ma0.mb0. getName(1'b0) !== "mb ") $stop;
if (ma0.mb0.mc0.getName(1'b0) !== "mc ") $stop;
end
if (cyc==4) begin
if (ma0.mb0. getP2(1'b0) !== 32'h0) $stop;
if (ma0.mb0.mc0.getP3(1'b0) !== 32'h0) $stop;
if (ma0.mb0.mc1.getP3(1'b0) !== 32'h1) $stop;
end
if (cyc==5) begin
ma0. checkName(ma0. getName(1'b0));
ma0.mb0. checkName(ma0.mb0. getName(1'b0));
ma0.mb0.mc0.checkName(ma0.mb0.mc0.getName(1'b0));
end
if (cyc==9) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
`ifdef USE_INLINE_MID
`define INLINE_MODULE /*verilator inline_module*/
`define INLINE_MID_MODULE /*verilator no_inline_module*/
`else
`ifdef USE_INLINE
`define INLINE_MODULE /*verilator inline_module*/
`define INLINE_MID_MODULE /*verilator inline_module*/
`else
`define INLINE_MODULE /*verilator public_module*/
`define INLINE_MID_MODULE /*verilator public_module*/
`endif
`endif
module global_mod;
`INLINE_MODULE
parameter INITVAL = 0;
integer globali;
initial globali = INITVAL;
function [31:0] getName; input fake; getName = "gmod"; endfunction
function [31:0] getGlob; input fake; getGlob = globali; endfunction
endmodule
module ma ();
`INLINE_MODULE
mb #(0) mb0 ();
reg [31:0] gName; initial gName = "ma ";
function [31:0] getName; input fake; getName = "ma "; endfunction
task checkName; input [31:0] name; if (name !== "ma ") $stop; endtask
initial begin
if (ma.getName(1'b0) !== "ma ") $stop;
if (mb0.getName(1'b0) !== "mb ") $stop;
if (mb0.mc0.getName(1'b0) !== "mc ") $stop;
end
endmodule
module mb ();
`INLINE_MID_MODULE
parameter P2 = 0;
mc #(P2,0) mc0 ();
mc #(P2,1) mc1 ();
global_mod #(32'hf33d) global_cell2 ();
reg [31:0] gName; initial gName = "mb ";
function [31:0] getName; input fake; getName = "mb "; endfunction
function [31:0] getP2 ; input fake; getP2 = P2; endfunction
task checkName; input [31:0] name; if (name !== "mb ") $stop; endtask
initial begin
`ifndef verilator #1; `endif
if (ma. getName(1'b0) !== "ma ") $stop;
if ( getName(1'b0) !== "mb ") $stop;
if (mc1.getName(1'b0) !== "mc ") $stop;
ma. checkName (ma. gName);
/**/checkName ( gName);
mc1.checkName (mc1.gName);
ma. checkName (ma. getName(1'b0));
/**/checkName ( getName(1'b0));
mc1.checkName (mc1.getName(1'b0));
end
endmodule
module mc ();
`INLINE_MODULE
parameter P2 = 0;
parameter P3 = 0;
reg [31:0] gName; initial gName = "mc ";
function [31:0] getName; input fake; getName = "mc "; endfunction
function [31:0] getP3 ; input fake; getP3 = P3; endfunction
task checkName; input [31:0] name; if (name !== "mc ") $stop; endtask
initial begin
`ifndef verilator #1; `endif
if (ma.getName(1'b0) !== "ma ") $stop;
if (mb.getName(1'b0) !== "mb ") $stop;
if (mc.getName(1'b0) !== "mc ") $stop;
ma.checkName (ma.gName);
mb.checkName (mb.gName);
mc.checkName (mc.gName);
ma.checkName (ma.getName(1'b0));
mb.checkName (mb.getName(1'b0));
mc.checkName (mc.getName(1'b0));
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2006 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
// verilator lint_off MULTIDRIVEN
ma ma0 ();
global_mod #(32'hf00d) global_cell ();
global_mod #(32'hf22d) global_cell2 ();
input clk;
integer cyc=1;
function [31:0] getName; input fake; getName = "t "; endfunction
always @ (posedge clk) begin
cyc <= cyc + 1;
if (cyc==2) begin
if (global_cell. getGlob(1'b0) !== 32'hf00d) $stop;
if (global_cell2.getGlob(1'b0) !== 32'hf22d) $stop;
end
if (cyc==3) begin
if (ma0. getName(1'b0) !== "ma ") $stop;
if (ma0.mb0. getName(1'b0) !== "mb ") $stop;
if (ma0.mb0.mc0.getName(1'b0) !== "mc ") $stop;
end
if (cyc==4) begin
if (ma0.mb0. getP2(1'b0) !== 32'h0) $stop;
if (ma0.mb0.mc0.getP3(1'b0) !== 32'h0) $stop;
if (ma0.mb0.mc1.getP3(1'b0) !== 32'h1) $stop;
end
if (cyc==5) begin
ma0. checkName(ma0. getName(1'b0));
ma0.mb0. checkName(ma0.mb0. getName(1'b0));
ma0.mb0.mc0.checkName(ma0.mb0.mc0.getName(1'b0));
end
if (cyc==9) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
`ifdef USE_INLINE_MID
`define INLINE_MODULE /*verilator inline_module*/
`define INLINE_MID_MODULE /*verilator no_inline_module*/
`else
`ifdef USE_INLINE
`define INLINE_MODULE /*verilator inline_module*/
`define INLINE_MID_MODULE /*verilator inline_module*/
`else
`define INLINE_MODULE /*verilator public_module*/
`define INLINE_MID_MODULE /*verilator public_module*/
`endif
`endif
module global_mod;
`INLINE_MODULE
parameter INITVAL = 0;
integer globali;
initial globali = INITVAL;
function [31:0] getName; input fake; getName = "gmod"; endfunction
function [31:0] getGlob; input fake; getGlob = globali; endfunction
endmodule
module ma ();
`INLINE_MODULE
mb #(0) mb0 ();
reg [31:0] gName; initial gName = "ma ";
function [31:0] getName; input fake; getName = "ma "; endfunction
task checkName; input [31:0] name; if (name !== "ma ") $stop; endtask
initial begin
if (ma.getName(1'b0) !== "ma ") $stop;
if (mb0.getName(1'b0) !== "mb ") $stop;
if (mb0.mc0.getName(1'b0) !== "mc ") $stop;
end
endmodule
module mb ();
`INLINE_MID_MODULE
parameter P2 = 0;
mc #(P2,0) mc0 ();
mc #(P2,1) mc1 ();
global_mod #(32'hf33d) global_cell2 ();
reg [31:0] gName; initial gName = "mb ";
function [31:0] getName; input fake; getName = "mb "; endfunction
function [31:0] getP2 ; input fake; getP2 = P2; endfunction
task checkName; input [31:0] name; if (name !== "mb ") $stop; endtask
initial begin
`ifndef verilator #1; `endif
if (ma. getName(1'b0) !== "ma ") $stop;
if ( getName(1'b0) !== "mb ") $stop;
if (mc1.getName(1'b0) !== "mc ") $stop;
ma. checkName (ma. gName);
/**/checkName ( gName);
mc1.checkName (mc1.gName);
ma. checkName (ma. getName(1'b0));
/**/checkName ( getName(1'b0));
mc1.checkName (mc1.getName(1'b0));
end
endmodule
module mc ();
`INLINE_MODULE
parameter P2 = 0;
parameter P3 = 0;
reg [31:0] gName; initial gName = "mc ";
function [31:0] getName; input fake; getName = "mc "; endfunction
function [31:0] getP3 ; input fake; getP3 = P3; endfunction
task checkName; input [31:0] name; if (name !== "mc ") $stop; endtask
initial begin
`ifndef verilator #1; `endif
if (ma.getName(1'b0) !== "ma ") $stop;
if (mb.getName(1'b0) !== "mb ") $stop;
if (mc.getName(1'b0) !== "mc ") $stop;
ma.checkName (ma.gName);
mb.checkName (mb.gName);
mc.checkName (mc.gName);
ma.checkName (ma.getName(1'b0));
mb.checkName (mb.getName(1'b0));
mc.checkName (mc.getName(1'b0));
end
endmodule
|
// -*- verilog -*-
//
// USRP - Universal Software Radio Peripheral
//
// Copyright (C) 2003 Matt Ettus
//
// This program 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 2 of the License, or
// (at your option) any later version.
//
// This program 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, write to the Free Software
// Foundation, Inc., 51 Franklin Street, Boston, MA 02110-1301 USA
//
module cic_interp(clock,reset,enable,rate,strobe_in,strobe_out,signal_in,signal_out);
parameter bw = 16;
parameter N = 4;
parameter log2_of_max_rate = 7;
parameter maxbitgain = (N-1)*log2_of_max_rate;
input clock;
input reset;
input enable;
input [7:0] rate;
input strobe_in,strobe_out;
input [bw-1:0] signal_in;
wire [bw-1:0] signal_in;
output [bw-1:0] signal_out;
wire [bw-1:0] signal_out;
wire [bw+maxbitgain-1:0] signal_in_ext;
reg [bw+maxbitgain-1:0] integrator [0:N-1];
reg [bw+maxbitgain-1:0] differentiator [0:N-1];
reg [bw+maxbitgain-1:0] pipeline [0:N-1];
integer i;
sign_extend #(bw,bw+maxbitgain)
ext_input (.in(signal_in),.out(signal_in_ext));
//FIXME Note that this section has pipe and diff reversed
// It still works, but is confusing
always @(posedge clock)
if(reset)
for(i=0;i<N;i=i+1)
integrator[i] <= #1 0;
else if (enable & strobe_out)
begin
if(strobe_in)
integrator[0] <= #1 integrator[0] + pipeline[N-1];
for(i=1;i<N;i=i+1)
integrator[i] <= #1 integrator[i] + integrator[i-1];
end
always @(posedge clock)
if(reset)
begin
for(i=0;i<N;i=i+1)
begin
differentiator[i] <= #1 0;
pipeline[i] <= #1 0;
end
end
else if (enable && strobe_in)
begin
differentiator[0] <= #1 signal_in_ext;
pipeline[0] <= #1 signal_in_ext - differentiator[0];
for(i=1;i<N;i=i+1)
begin
differentiator[i] <= #1 pipeline[i-1];
pipeline[i] <= #1 pipeline[i-1] - differentiator[i];
end
end
wire [bw+maxbitgain-1:0] signal_out_unnorm = integrator[N-1];
cic_int_shifter #(bw)
cic_int_shifter(rate,signal_out_unnorm,signal_out);
endmodule // cic_interp
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2008-2008 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
integer cyc=0;
reg [63:0] crc;
reg [63:0] sum;
wire [9:0] I1 = crc[9:0];
wire [9:0] I2 = crc[19:10];
/*AUTOWIRE*/
// Beginning of automatic wires (for undeclared instantiated-module outputs)
wire [9:0] S; // From test of Test.v
// End of automatics
Test test (/*AUTOINST*/
// Outputs
.S (S[9:0]),
// Inputs
.I1 (I1[9:0]),
.I2 (I2[9:0]));
wire [63:0] result = {32'h0, 22'h0, S};
`define EXPECTED_SUM 64'h24c38b77b0fcc2e7
// Test loop
always @ (posedge clk) begin
`ifdef TEST_VERBOSE
$write("[%0t] cyc==%0d crc=%x result=%x\n",$time, cyc, crc, result);
`endif
cyc <= cyc + 1;
crc <= {crc[62:0], crc[63]^crc[2]^crc[0]};
sum <= result ^ {sum[62:0],sum[63]^sum[2]^sum[0]};
if (cyc==0) begin
// Setup
crc <= 64'h5aef0c8d_d70a4497;
end
else if (cyc<10) begin
sum <= 64'h0;
end
else if (cyc<90) begin
end
else if (cyc==99) begin
$write("[%0t] cyc==%0d crc=%x sum=%x\n",$time, cyc, crc, sum);
if (crc !== 64'hc77bb9b3784ea091) $stop;
if (sum !== `EXPECTED_SUM) $stop;
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
module Test (/*AUTOARG*/
// Outputs
S,
// Inputs
I1, I2
);
input [9:0] I1/*verilator public*/;
input [9:0] I2/*verilator public*/;
output reg [9:0] S/*verilator public*/;
always @(I1 or I2)
t2(I1,I2,S);
task t1;
input In1,In2;
output Sum;
Sum = In1 ^ In2;
endtask
task t2;
input[9:0] In1,In2;
output [9:0] Sum;
integer I;
begin
for (I=0;I<10;I=I+1)
t1(In1[I],In2[I],Sum[I]);
end
endtask
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2008-2008 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
integer cyc=0;
reg [63:0] crc;
reg [63:0] sum;
wire [9:0] I1 = crc[9:0];
wire [9:0] I2 = crc[19:10];
/*AUTOWIRE*/
// Beginning of automatic wires (for undeclared instantiated-module outputs)
wire [9:0] S; // From test of Test.v
// End of automatics
Test test (/*AUTOINST*/
// Outputs
.S (S[9:0]),
// Inputs
.I1 (I1[9:0]),
.I2 (I2[9:0]));
wire [63:0] result = {32'h0, 22'h0, S};
`define EXPECTED_SUM 64'h24c38b77b0fcc2e7
// Test loop
always @ (posedge clk) begin
`ifdef TEST_VERBOSE
$write("[%0t] cyc==%0d crc=%x result=%x\n",$time, cyc, crc, result);
`endif
cyc <= cyc + 1;
crc <= {crc[62:0], crc[63]^crc[2]^crc[0]};
sum <= result ^ {sum[62:0],sum[63]^sum[2]^sum[0]};
if (cyc==0) begin
// Setup
crc <= 64'h5aef0c8d_d70a4497;
end
else if (cyc<10) begin
sum <= 64'h0;
end
else if (cyc<90) begin
end
else if (cyc==99) begin
$write("[%0t] cyc==%0d crc=%x sum=%x\n",$time, cyc, crc, sum);
if (crc !== 64'hc77bb9b3784ea091) $stop;
if (sum !== `EXPECTED_SUM) $stop;
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
module Test (/*AUTOARG*/
// Outputs
S,
// Inputs
I1, I2
);
input [9:0] I1/*verilator public*/;
input [9:0] I2/*verilator public*/;
output reg [9:0] S/*verilator public*/;
always @(I1 or I2)
t2(I1,I2,S);
task t1;
input In1,In2;
output Sum;
Sum = In1 ^ In2;
endtask
task t2;
input[9:0] In1,In2;
output [9:0] Sum;
integer I;
begin
for (I=0;I<10;I=I+1)
t1(In1[I],In2[I],Sum[I]);
end
endtask
endmodule
|
`timescale 1ns / 1ps
//////////////////////////////////////////////////////////////////////////////////
// Company:
// Engineer:
//
// Create Date: 18:20:57 09/06/2015
// Design Name:
// Module Name: FSM_Mult_Function
// Project Name:
// Target Devices:
// Tool versions:
// Description:
//
// Dependencies:
//
// Revision:
// Revision 0.01 - File Created
// Additional Comments:
//
//////////////////////////////////////////////////////////////////////////////////
module FSM_Mult_Function(
//INPUTS
input wire clk,
input wire rst,
input wire beg_FSM, //Be gin the multiply operation
input wire ack_FSM, //Is used in the last state, is an aknowledge signal
//ZERO PHASE EVALUATION SIGNALS
input wire zero_flag_i,
//Sgf_Operation *EVALUATION SIGNALS
input wire Mult_shift_i,
//round decoder EVALUATION SIGNALS
input wire round_flag_i,
//Adder round EV LUATION Signals
input wire Add_Overflow_i,
///////////////////////Load Signals/////////////////////////////////////7
//Oper Start_in load signal
output reg load_0_o,
/*Zero flag, Exp operation underflow, Sgf operation first reg, sign result reg*/
output reg load_1_o,
//Exp operation result,
output reg load_2_o,
//Exp operation Overflow, Sgf operation second reg
output reg load_3_o,
//Adder round register
output reg load_4_o,
//Final result registers
output reg load_5_o,
//Barrel shifter registers
output reg load_6_o,
/////////////////////Multiplexers selector control signals////////////
//Sixth Phase control signals
output reg ctrl_select_a_o,
output reg ctrl_select_b_o,
output reg [1:0] selector_b_o,
output reg ctrl_select_c_o,
//////////////////////Module's control signals/////////////////////////
//Exp operation control signals
output reg exp_op_o,
//Barrel shifter control signals
output reg shift_value_o,
//Internal reset signal
output reg rst_int,
//Ready Signal
output reg ready
);
////////States///////////
//Zero Phase
parameter [3:0] start = 4'd0,//A
load_operands = 4'd1, //B) loads both operands to registers
extra64_1 = 4'd2,
add_exp = 4'd3, //C) Add both operands, evaluate underflow
subt_bias = 4'd4, //D) Subtract bias to the result, evaluate overflow, evaluate zero
mult_overf= 4'd5, //E) Evaluate overflow in Sgf multiplication for normalization case
mult_norn = 4'd6, //F) Overflow normalization, right shift significant and increment exponent
mult_no_norn = 4'd7, //G)No_normalization sgf
round_case = 4'd8, //H) Rounding evaluation. Positive= adder rounding, Negative,=Final load
adder_round = 4'd9, //I) add a 1 to the significand in case of rounding
round_norm = 4'd10, //J) Evaluate overflow in adder for normalization, Positive = normalization, same that F
final_load = 4'd11, //K) Load output registers
ready_flag = 4'd12; //L) Ready flag, wait for ack signal
//State registers
reg [3:0] state_reg, state_next;
//State registers reset and standby logic
always @(posedge clk, posedge rst)
if(rst)
state_reg <= start;
else
state_reg <= state_next;
//Transition and Output Logic
always @*
begin
//STATE DEFAULT BEHAVIOR
state_next = state_reg; //If no changes, keep the value of the register unaltered
load_0_o=0;
/*Zero flag, Exp operation underflow, Sgf operation first reg, sign result reg*/
load_1_o=0;
//Exp operation result,
load_2_o=0;
//Exp operation Overflow, Sgf operation second reg
load_3_o=0;
//Adder round register
load_4_o=0;
//Final result registers
load_5_o=0;
load_6_o=0;
//////////////////////Multiplexers selector control signals////////////
//Sixth Phase control signals
ctrl_select_a_o=0;
ctrl_select_b_o=0;
selector_b_o=2'b0;
ctrl_select_c_o=0;
//////////////////////Module's control signals/////////////////////////
//Exp operation control signals
exp_op_o=0;
//Barrel shifter control signals
shift_value_o=0;
//Internal reset signal
rst_int=0;
//Ready Signal
ready=0;
case(state_reg)
start:
begin
rst_int = 1;
if(beg_FSM)
state_next = load_operands; //Jump to the first state of the machine
end
//First Phase
load_operands:
begin
load_0_o = 1;
state_next = extra64_1;
end
extra64_1:
begin
state_next = add_exp;
end
//Zero Check
add_exp:
begin
load_1_o = 1;
load_2_o = 1;
ctrl_select_a_o = 1;
ctrl_select_b_o = 1;
selector_b_o = 2'b01;
state_next = subt_bias;
end
subt_bias:
begin
load_2_o = 1;
load_3_o = 1;
exp_op_o = 1;
if(zero_flag_i)
state_next = ready_flag;
else
state_next = mult_overf;
end
mult_overf:
begin
if(Mult_shift_i) begin
ctrl_select_b_o =1;
selector_b_o =2'b10;
state_next = mult_norn;
end
else
state_next = mult_no_norn;
end
//Ninth Phase
mult_norn:
begin
shift_value_o =1;
load_6_o = 1;
load_2_o = 1;
load_3_o = 1;
//exp_op_o = 1;
state_next = round_case;
end
mult_no_norn:
begin
shift_value_o =0;
load_6_o = 1;
state_next = round_case;
end
round_case:
begin
if(round_flag_i) begin
ctrl_select_c_o =1;
state_next = adder_round;
end
else
state_next = final_load;
end
adder_round:
begin
load_4_o = 1;
ctrl_select_b_o = 1;
selector_b_o = 2'b01;
state_next = round_norm;
end
round_norm:
begin
load_6_o = 1;
if(Add_Overflow_i)begin
shift_value_o =1;
load_2_o = 1;
load_3_o = 1;
state_next = final_load;
end
else begin
shift_value_o =0;
state_next = final_load;
end
end
final_load:
begin
load_5_o =1;
state_next = ready_flag;
end
ready_flag:
begin
ready = 1;
if(ack_FSM) begin
state_next = start;end
end
default:
begin
state_next =start;end
endcase
end
endmodule
|
`timescale 1ns / 1ps
//////////////////////////////////////////////////////////////////////////////////
// Company:
// Engineer:
//
// Create Date: 18:20:57 09/06/2015
// Design Name:
// Module Name: FSM_Mult_Function
// Project Name:
// Target Devices:
// Tool versions:
// Description:
//
// Dependencies:
//
// Revision:
// Revision 0.01 - File Created
// Additional Comments:
//
//////////////////////////////////////////////////////////////////////////////////
module FSM_Mult_Function(
//INPUTS
input wire clk,
input wire rst,
input wire beg_FSM, //Be gin the multiply operation
input wire ack_FSM, //Is used in the last state, is an aknowledge signal
//ZERO PHASE EVALUATION SIGNALS
input wire zero_flag_i,
//Sgf_Operation *EVALUATION SIGNALS
input wire Mult_shift_i,
//round decoder EVALUATION SIGNALS
input wire round_flag_i,
//Adder round EV LUATION Signals
input wire Add_Overflow_i,
///////////////////////Load Signals/////////////////////////////////////7
//Oper Start_in load signal
output reg load_0_o,
/*Zero flag, Exp operation underflow, Sgf operation first reg, sign result reg*/
output reg load_1_o,
//Exp operation result,
output reg load_2_o,
//Exp operation Overflow, Sgf operation second reg
output reg load_3_o,
//Adder round register
output reg load_4_o,
//Final result registers
output reg load_5_o,
//Barrel shifter registers
output reg load_6_o,
/////////////////////Multiplexers selector control signals////////////
//Sixth Phase control signals
output reg ctrl_select_a_o,
output reg ctrl_select_b_o,
output reg [1:0] selector_b_o,
output reg ctrl_select_c_o,
//////////////////////Module's control signals/////////////////////////
//Exp operation control signals
output reg exp_op_o,
//Barrel shifter control signals
output reg shift_value_o,
//Internal reset signal
output reg rst_int,
//Ready Signal
output reg ready
);
////////States///////////
//Zero Phase
parameter [3:0] start = 4'd0,//A
load_operands = 4'd1, //B) loads both operands to registers
extra64_1 = 4'd2,
add_exp = 4'd3, //C) Add both operands, evaluate underflow
subt_bias = 4'd4, //D) Subtract bias to the result, evaluate overflow, evaluate zero
mult_overf= 4'd5, //E) Evaluate overflow in Sgf multiplication for normalization case
mult_norn = 4'd6, //F) Overflow normalization, right shift significant and increment exponent
mult_no_norn = 4'd7, //G)No_normalization sgf
round_case = 4'd8, //H) Rounding evaluation. Positive= adder rounding, Negative,=Final load
adder_round = 4'd9, //I) add a 1 to the significand in case of rounding
round_norm = 4'd10, //J) Evaluate overflow in adder for normalization, Positive = normalization, same that F
final_load = 4'd11, //K) Load output registers
ready_flag = 4'd12; //L) Ready flag, wait for ack signal
//State registers
reg [3:0] state_reg, state_next;
//State registers reset and standby logic
always @(posedge clk, posedge rst)
if(rst)
state_reg <= start;
else
state_reg <= state_next;
//Transition and Output Logic
always @*
begin
//STATE DEFAULT BEHAVIOR
state_next = state_reg; //If no changes, keep the value of the register unaltered
load_0_o=0;
/*Zero flag, Exp operation underflow, Sgf operation first reg, sign result reg*/
load_1_o=0;
//Exp operation result,
load_2_o=0;
//Exp operation Overflow, Sgf operation second reg
load_3_o=0;
//Adder round register
load_4_o=0;
//Final result registers
load_5_o=0;
load_6_o=0;
//////////////////////Multiplexers selector control signals////////////
//Sixth Phase control signals
ctrl_select_a_o=0;
ctrl_select_b_o=0;
selector_b_o=2'b0;
ctrl_select_c_o=0;
//////////////////////Module's control signals/////////////////////////
//Exp operation control signals
exp_op_o=0;
//Barrel shifter control signals
shift_value_o=0;
//Internal reset signal
rst_int=0;
//Ready Signal
ready=0;
case(state_reg)
start:
begin
rst_int = 1;
if(beg_FSM)
state_next = load_operands; //Jump to the first state of the machine
end
//First Phase
load_operands:
begin
load_0_o = 1;
state_next = extra64_1;
end
extra64_1:
begin
state_next = add_exp;
end
//Zero Check
add_exp:
begin
load_1_o = 1;
load_2_o = 1;
ctrl_select_a_o = 1;
ctrl_select_b_o = 1;
selector_b_o = 2'b01;
state_next = subt_bias;
end
subt_bias:
begin
load_2_o = 1;
load_3_o = 1;
exp_op_o = 1;
if(zero_flag_i)
state_next = ready_flag;
else
state_next = mult_overf;
end
mult_overf:
begin
if(Mult_shift_i) begin
ctrl_select_b_o =1;
selector_b_o =2'b10;
state_next = mult_norn;
end
else
state_next = mult_no_norn;
end
//Ninth Phase
mult_norn:
begin
shift_value_o =1;
load_6_o = 1;
load_2_o = 1;
load_3_o = 1;
//exp_op_o = 1;
state_next = round_case;
end
mult_no_norn:
begin
shift_value_o =0;
load_6_o = 1;
state_next = round_case;
end
round_case:
begin
if(round_flag_i) begin
ctrl_select_c_o =1;
state_next = adder_round;
end
else
state_next = final_load;
end
adder_round:
begin
load_4_o = 1;
ctrl_select_b_o = 1;
selector_b_o = 2'b01;
state_next = round_norm;
end
round_norm:
begin
load_6_o = 1;
if(Add_Overflow_i)begin
shift_value_o =1;
load_2_o = 1;
load_3_o = 1;
state_next = final_load;
end
else begin
shift_value_o =0;
state_next = final_load;
end
end
final_load:
begin
load_5_o =1;
state_next = ready_flag;
end
ready_flag:
begin
ready = 1;
if(ack_FSM) begin
state_next = start;end
end
default:
begin
state_next =start;end
endcase
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2003 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
// verilator lint_off GENCLK
reg [7:0] cyc; initial cyc=0;
reg genclk;
// verilator lint_off MULTIDRIVEN
reg [7:0] set_both;
// verilator lint_on MULTIDRIVEN
wire genthiscyc = ( (cyc % 2) == 1 );
always @ (posedge clk) begin
cyc <= cyc + 8'h1;
genclk <= genthiscyc;
set_both <= cyc;
$write ("SB set_both %x <= cyc %x\n", set_both, cyc);
if (genthiscyc) begin
if (cyc>1 && set_both != (cyc - 8'h1)) $stop;
end
else begin
if (cyc>1 && set_both != ~(cyc - 8'h1)) $stop;
end
if (cyc==10) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
always @ (posedge genclk) begin
set_both <= ~ set_both;
$write ("SB set_both %x <= cyc %x\n", set_both, ~cyc);
if (cyc>1 && set_both != (cyc - 8'h1)) $stop;
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2003 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
// verilator lint_off GENCLK
reg [7:0] cyc; initial cyc=0;
reg genclk;
// verilator lint_off MULTIDRIVEN
reg [7:0] set_both;
// verilator lint_on MULTIDRIVEN
wire genthiscyc = ( (cyc % 2) == 1 );
always @ (posedge clk) begin
cyc <= cyc + 8'h1;
genclk <= genthiscyc;
set_both <= cyc;
$write ("SB set_both %x <= cyc %x\n", set_both, cyc);
if (genthiscyc) begin
if (cyc>1 && set_both != (cyc - 8'h1)) $stop;
end
else begin
if (cyc>1 && set_both != ~(cyc - 8'h1)) $stop;
end
if (cyc==10) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
always @ (posedge genclk) begin
set_both <= ~ set_both;
$write ("SB set_both %x <= cyc %x\n", set_both, ~cyc);
if (cyc>1 && set_both != (cyc - 8'h1)) $stop;
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2005-2007 by Wilson Snyder.
module t (/*AUTOARG*/);
reg [3:0] value;
reg [3:0] valuex;
// verilator lint_off CASEOVERLAP
// verilator lint_off CASEWITHX
// verilator lint_off CASEX
// Note for Verilator Xs must become zeros, or the Xs may match.
initial begin
value = 4'b1001;
valuex = 4'b1xxx;
case (value)
4'b1xxx: $stop;
4'b1???: $stop;
4'b1001: ;
default: $stop;
endcase
case (valuex)
4'b1???: $stop;
4'b1xxx: ;
4'b1001: ;
4'b1000: ; // 1xxx is mapped to this by Verilator -x-assign 0
default: $stop;
endcase
//
casex (value)
4'b100x: ;
default: $stop;
endcase
casex (value)
4'b100?: ;
default: $stop;
endcase
casex (valuex)
4'b100x: ;
default: $stop;
endcase
casex (valuex)
4'b100?: ;
default: $stop;
endcase
//
casez (value)
4'bxxxx: $stop;
4'b100?: ;
default: $stop;
endcase
casez (valuex)
4'b1xx?: ;
4'b100?: ; // 1xxx is mapped to this by Verilator -x-assign 0
default: $stop;
endcase
$write("*-* All Finished *-*\n");
$finish;
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2004 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
integer cyc; initial cyc=1;
reg [125:0] a;
wire q;
sub sub (
.q (q),
.a (a),
.clk (clk));
always @ (posedge clk) begin
if (cyc!=0) begin
cyc <= cyc + 1;
if (cyc==1) begin
a <= 126'b1000;
end
if (cyc==2) begin
a <= 126'h1001;
end
if (cyc==3) begin
a <= 126'h1010;
end
if (cyc==4) begin
a <= 126'h1111;
if (q !== 1'b0) $stop;
end
if (cyc==5) begin
if (q !== 1'b1) $stop;
end
if (cyc==6) begin
if (q !== 1'b0) $stop;
end
if (cyc==7) begin
if (q !== 1'b0) $stop;
end
if (cyc==8) begin
if (q !== 1'b0) $stop;
$write("*-* All Finished *-*\n");
$finish;
end
end
end
endmodule
module sub (
input clk,
input [125:0] a,
output reg q
);
// verilator public_module
reg [125:0] g_r;
wire [127:0] g_extend = { g_r, 1'b1, 1'b0 };
reg [6:0] sel;
wire g_sel = g_extend[sel];
always @ (posedge clk) begin
g_r <= a;
sel <= a[6:0];
q <= g_sel;
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2004 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
integer cyc; initial cyc=1;
reg [125:0] a;
wire q;
sub sub (
.q (q),
.a (a),
.clk (clk));
always @ (posedge clk) begin
if (cyc!=0) begin
cyc <= cyc + 1;
if (cyc==1) begin
a <= 126'b1000;
end
if (cyc==2) begin
a <= 126'h1001;
end
if (cyc==3) begin
a <= 126'h1010;
end
if (cyc==4) begin
a <= 126'h1111;
if (q !== 1'b0) $stop;
end
if (cyc==5) begin
if (q !== 1'b1) $stop;
end
if (cyc==6) begin
if (q !== 1'b0) $stop;
end
if (cyc==7) begin
if (q !== 1'b0) $stop;
end
if (cyc==8) begin
if (q !== 1'b0) $stop;
$write("*-* All Finished *-*\n");
$finish;
end
end
end
endmodule
module sub (
input clk,
input [125:0] a,
output reg q
);
// verilator public_module
reg [125:0] g_r;
wire [127:0] g_extend = { g_r, 1'b1, 1'b0 };
reg [6:0] sel;
wire g_sel = g_extend[sel];
always @ (posedge clk) begin
g_r <= a;
sel <= a[6:0];
q <= g_sel;
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2003 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
integer cyc=0;
reg [7:0] crc;
genvar g;
wire [7:0] out_p1;
wire [15:0] out_p2;
wire [7:0] out_p3;
wire [7:0] out_p4;
paramed #(.WIDTH(8), .MODE(0)) p1 (.in(crc), .out(out_p1));
paramed #(.WIDTH(16), .MODE(1)) p2 (.in({crc,crc}), .out(out_p2));
paramed #(.WIDTH(8), .MODE(2)) p3 (.in(crc), .out(out_p3));
gencase #(.MODE(3)) p4 (.in(crc), .out(out_p4));
wire [7:0] out_ef;
enflop #(.WIDTH(8)) enf (.a(crc), .q(out_ef), .oe_e1(1'b1), .clk(clk));
always @ (posedge clk) begin
//$write("[%0t] cyc==%0d crc=%b %x %x %x %x %x\n",$time, cyc, crc, out_p1, out_p2, out_p3, out_p4, out_ef);
cyc <= cyc + 1;
crc <= {crc[6:0], ~^ {crc[7],crc[5],crc[4],crc[3]}};
if (cyc==0) begin
// Setup
crc <= 8'hed;
end
else if (cyc==1) begin
end
else if (cyc==3) begin
if (out_p1 !== 8'h2d) $stop;
if (out_p2 !== 16'h2d2d) $stop;
if (out_p3 !== 8'h78) $stop;
if (out_p4 !== 8'h44) $stop;
if (out_ef !== 8'hda) $stop;
end
else if (cyc==9) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
module gencase (/*AUTOARG*/
// Outputs
out,
// Inputs
in
);
parameter MODE = 0;
input [7:0] in;
output [7:0] out;
generate // : genblk1
begin
case (MODE)
2: mbuf mc [7:0] (.q(out[7:0]), .a({in[5:0],in[7:6]}));
default: mbuf mc [7:0] (.q(out[7:0]), .a({in[3:0],in[3:0]}));
endcase
end
endgenerate
endmodule
module paramed (/*AUTOARG*/
// Outputs
out,
// Inputs
in
);
parameter WIDTH = 1;
parameter MODE = 0;
input [WIDTH-1:0] in;
output [WIDTH-1:0] out;
generate
if (MODE==0) initial $write("Mode=0\n");
// No else
endgenerate
`ifndef NC // for(genvar) unsupported
`ifndef ATSIM // for(genvar) unsupported
generate
// Empty loop body, local genvar
for (genvar j=0; j<3; j=j+1) begin end
// Ditto to make sure j has new scope
for (genvar j=0; j<5; j=j+1) begin end
endgenerate
`endif
`endif
generate
endgenerate
genvar i;
generate
if (MODE==0) begin
// Flip bitorder, direct assign method
for (i=0; i<WIDTH; i=i+1) begin
assign out[i] = in[WIDTH-i-1];
end
end
else if (MODE==1) begin
// Flip using instantiation
for (i=0; i<WIDTH; i=i+1) begin
integer from = WIDTH-i-1;
if (i==0) begin // Test if's within a for
mbuf m0 (.q(out[i]), .a(in[from]));
end
else begin
mbuf ma (.q(out[i]), .a(in[from]));
end
end
end
else begin
for (i=0; i<WIDTH; i=i+1) begin
mbuf ma (.q(out[i]), .a(in[i^1]));
end
end
endgenerate
endmodule
module mbuf (
input a,
output q
);
assign q = a;
endmodule
module enflop (clk, oe_e1, a,q);
parameter WIDTH=1;
input clk;
input oe_e1;
input [WIDTH-1:0] a;
output [WIDTH-1:0] q;
reg [WIDTH-1:0] oe_r;
reg [WIDTH-1:0] q_r;
genvar i;
generate
for (i = 0; i < WIDTH; i = i + 1) begin : datapath_bits
enflop_one enflop_one
(.clk (clk),
.d (a[i]),
.q_r (q_r[i]));
always @(posedge clk) oe_r[i] <= oe_e1;
assign q[i] = oe_r[i] ? q_r[i] : 1'bx;
end
endgenerate
endmodule
module enflop_one (
input clk,
input d,
output reg q_r
);
always @(posedge clk) q_r <= d;
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2003 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
integer cyc=0;
reg [7:0] crc;
genvar g;
wire [7:0] out_p1;
wire [15:0] out_p2;
wire [7:0] out_p3;
wire [7:0] out_p4;
paramed #(.WIDTH(8), .MODE(0)) p1 (.in(crc), .out(out_p1));
paramed #(.WIDTH(16), .MODE(1)) p2 (.in({crc,crc}), .out(out_p2));
paramed #(.WIDTH(8), .MODE(2)) p3 (.in(crc), .out(out_p3));
gencase #(.MODE(3)) p4 (.in(crc), .out(out_p4));
wire [7:0] out_ef;
enflop #(.WIDTH(8)) enf (.a(crc), .q(out_ef), .oe_e1(1'b1), .clk(clk));
always @ (posedge clk) begin
//$write("[%0t] cyc==%0d crc=%b %x %x %x %x %x\n",$time, cyc, crc, out_p1, out_p2, out_p3, out_p4, out_ef);
cyc <= cyc + 1;
crc <= {crc[6:0], ~^ {crc[7],crc[5],crc[4],crc[3]}};
if (cyc==0) begin
// Setup
crc <= 8'hed;
end
else if (cyc==1) begin
end
else if (cyc==3) begin
if (out_p1 !== 8'h2d) $stop;
if (out_p2 !== 16'h2d2d) $stop;
if (out_p3 !== 8'h78) $stop;
if (out_p4 !== 8'h44) $stop;
if (out_ef !== 8'hda) $stop;
end
else if (cyc==9) begin
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
module gencase (/*AUTOARG*/
// Outputs
out,
// Inputs
in
);
parameter MODE = 0;
input [7:0] in;
output [7:0] out;
generate // : genblk1
begin
case (MODE)
2: mbuf mc [7:0] (.q(out[7:0]), .a({in[5:0],in[7:6]}));
default: mbuf mc [7:0] (.q(out[7:0]), .a({in[3:0],in[3:0]}));
endcase
end
endgenerate
endmodule
module paramed (/*AUTOARG*/
// Outputs
out,
// Inputs
in
);
parameter WIDTH = 1;
parameter MODE = 0;
input [WIDTH-1:0] in;
output [WIDTH-1:0] out;
generate
if (MODE==0) initial $write("Mode=0\n");
// No else
endgenerate
`ifndef NC // for(genvar) unsupported
`ifndef ATSIM // for(genvar) unsupported
generate
// Empty loop body, local genvar
for (genvar j=0; j<3; j=j+1) begin end
// Ditto to make sure j has new scope
for (genvar j=0; j<5; j=j+1) begin end
endgenerate
`endif
`endif
generate
endgenerate
genvar i;
generate
if (MODE==0) begin
// Flip bitorder, direct assign method
for (i=0; i<WIDTH; i=i+1) begin
assign out[i] = in[WIDTH-i-1];
end
end
else if (MODE==1) begin
// Flip using instantiation
for (i=0; i<WIDTH; i=i+1) begin
integer from = WIDTH-i-1;
if (i==0) begin // Test if's within a for
mbuf m0 (.q(out[i]), .a(in[from]));
end
else begin
mbuf ma (.q(out[i]), .a(in[from]));
end
end
end
else begin
for (i=0; i<WIDTH; i=i+1) begin
mbuf ma (.q(out[i]), .a(in[i^1]));
end
end
endgenerate
endmodule
module mbuf (
input a,
output q
);
assign q = a;
endmodule
module enflop (clk, oe_e1, a,q);
parameter WIDTH=1;
input clk;
input oe_e1;
input [WIDTH-1:0] a;
output [WIDTH-1:0] q;
reg [WIDTH-1:0] oe_r;
reg [WIDTH-1:0] q_r;
genvar i;
generate
for (i = 0; i < WIDTH; i = i + 1) begin : datapath_bits
enflop_one enflop_one
(.clk (clk),
.d (a[i]),
.q_r (q_r[i]));
always @(posedge clk) oe_r[i] <= oe_e1;
assign q[i] = oe_r[i] ? q_r[i] : 1'bx;
end
endgenerate
endmodule
module enflop_one (
input clk,
input d,
output reg q_r
);
always @(posedge clk) q_r <= d;
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2004 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
// Check empty blocks
task EmptyFor;
/* verilator public */
integer i;
begin
for (i = 0; i < 2; i = i+1)
begin
end
end
endtask
// Check look unroller
reg signed signed_tests_only = 1'sb1;
integer total;
integer i;
reg [31:0] iu;
reg [31:0] dly_to_insure_was_unrolled [1:0];
reg [2:0] i3;
integer cyc; initial cyc=0;
always @ (posedge clk) begin
cyc <= cyc + 1;
case (cyc)
1: begin
// >= signed
total = 0;
for (i=5; i>=0; i=i-1) begin
total = total - i -1;
dly_to_insure_was_unrolled[i] <= i;
end
if (total != -21) $stop;
end
2: begin
// > signed
total = 0;
for (i=5; i>0; i=i-1) begin
total = total - i -1;
dly_to_insure_was_unrolled[i] <= i;
end
if (total != -20) $stop;
end
3: begin
// < signed
total = 0;
for (i=1; i<5; i=i+1) begin
total = total - i -1;
dly_to_insure_was_unrolled[i] <= i;
end
if (total != -14) $stop;
end
4: begin
// <= signed
total = 0;
for (i=1; i<=5; i=i+1) begin
total = total - i -1;
dly_to_insure_was_unrolled[i] <= i;
end
if (total != -20) $stop;
end
// UNSIGNED
5: begin
// >= unsigned
total = 0;
for (iu=5; iu>=1; iu=iu-1) begin
total = total - iu -1;
dly_to_insure_was_unrolled[iu] <= iu;
end
if (total != -20) $stop;
end
6: begin
// > unsigned
total = 0;
for (iu=5; iu>1; iu=iu-1) begin
total = total - iu -1;
dly_to_insure_was_unrolled[iu] <= iu;
end
if (total != -18) $stop;
end
7: begin
// < unsigned
total = 0;
for (iu=1; iu<5; iu=iu+1) begin
total = total - iu -1;
dly_to_insure_was_unrolled[iu] <= iu;
end
if (total != -14) $stop;
end
8: begin
// <= unsigned
total = 0;
for (iu=1; iu<=5; iu=iu+1) begin
total = total - iu -1;
dly_to_insure_was_unrolled[iu] <= iu;
end
if (total != -20) $stop;
end
//===
9: begin
// mostly cover a small index
total = 0;
for (i3=3'd0; i3<3'd7; i3=i3+3'd1) begin
total = total - {29'd0,i3} -1;
dly_to_insure_was_unrolled[i3[0]] <= 0;
end
if (total != -28) $stop;
end
//===
10: begin
// mostly cover a small index
total = 0;
for (i3=0; i3<3'd7; i3=i3+3'd1) begin
total = total - {29'd0,i3} -1;
dly_to_insure_was_unrolled[i3[0]] <= 0;
end
if (total != -28) $stop;
end
//===
11: begin
// width violation on <, causes extend
total = 0;
for (i3=3'd0; i3<7; i3=i3+1) begin
total = total - {29'd0,i3} -1;
dly_to_insure_was_unrolled[i3[0]] <= 0;
end
if (total != -28) $stop;
end
//===
// width violation on <, causes extend signed
// Unsupported as yet
//===
19: begin
$write("*-* All Finished *-*\n");
$finish;
end
default: ;
endcase
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2004 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
// Check empty blocks
task EmptyFor;
/* verilator public */
integer i;
begin
for (i = 0; i < 2; i = i+1)
begin
end
end
endtask
// Check look unroller
reg signed signed_tests_only = 1'sb1;
integer total;
integer i;
reg [31:0] iu;
reg [31:0] dly_to_insure_was_unrolled [1:0];
reg [2:0] i3;
integer cyc; initial cyc=0;
always @ (posedge clk) begin
cyc <= cyc + 1;
case (cyc)
1: begin
// >= signed
total = 0;
for (i=5; i>=0; i=i-1) begin
total = total - i -1;
dly_to_insure_was_unrolled[i] <= i;
end
if (total != -21) $stop;
end
2: begin
// > signed
total = 0;
for (i=5; i>0; i=i-1) begin
total = total - i -1;
dly_to_insure_was_unrolled[i] <= i;
end
if (total != -20) $stop;
end
3: begin
// < signed
total = 0;
for (i=1; i<5; i=i+1) begin
total = total - i -1;
dly_to_insure_was_unrolled[i] <= i;
end
if (total != -14) $stop;
end
4: begin
// <= signed
total = 0;
for (i=1; i<=5; i=i+1) begin
total = total - i -1;
dly_to_insure_was_unrolled[i] <= i;
end
if (total != -20) $stop;
end
// UNSIGNED
5: begin
// >= unsigned
total = 0;
for (iu=5; iu>=1; iu=iu-1) begin
total = total - iu -1;
dly_to_insure_was_unrolled[iu] <= iu;
end
if (total != -20) $stop;
end
6: begin
// > unsigned
total = 0;
for (iu=5; iu>1; iu=iu-1) begin
total = total - iu -1;
dly_to_insure_was_unrolled[iu] <= iu;
end
if (total != -18) $stop;
end
7: begin
// < unsigned
total = 0;
for (iu=1; iu<5; iu=iu+1) begin
total = total - iu -1;
dly_to_insure_was_unrolled[iu] <= iu;
end
if (total != -14) $stop;
end
8: begin
// <= unsigned
total = 0;
for (iu=1; iu<=5; iu=iu+1) begin
total = total - iu -1;
dly_to_insure_was_unrolled[iu] <= iu;
end
if (total != -20) $stop;
end
//===
9: begin
// mostly cover a small index
total = 0;
for (i3=3'd0; i3<3'd7; i3=i3+3'd1) begin
total = total - {29'd0,i3} -1;
dly_to_insure_was_unrolled[i3[0]] <= 0;
end
if (total != -28) $stop;
end
//===
10: begin
// mostly cover a small index
total = 0;
for (i3=0; i3<3'd7; i3=i3+3'd1) begin
total = total - {29'd0,i3} -1;
dly_to_insure_was_unrolled[i3[0]] <= 0;
end
if (total != -28) $stop;
end
//===
11: begin
// width violation on <, causes extend
total = 0;
for (i3=3'd0; i3<7; i3=i3+1) begin
total = total - {29'd0,i3} -1;
dly_to_insure_was_unrolled[i3[0]] <= 0;
end
if (total != -28) $stop;
end
//===
// width violation on <, causes extend signed
// Unsupported as yet
//===
19: begin
$write("*-* All Finished *-*\n");
$finish;
end
default: ;
endcase
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2009 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
input clk;
logic use_AnB;
logic [1:0] active_command [8:0];
logic [1:0] command_A [8:0];
logic [1:0] command_B [8:0];
logic [1:0] active_command2 [8:0];
logic [1:0] command_A2 [7:0];
logic [1:0] command_B2 [8:0];
logic [1:0] active_command3 [1:0][2:0][3:0];
logic [1:0] command_A3 [1:0][2:0][3:0];
logic [1:0] command_B3 [1:0][2:0][3:0];
logic [1:0] active_command4 [8:0];
logic [1:0] command_A4 [7:0];
logic [1:0] active_command5 [8:0];
logic [1:0] command_A5 [7:0];
// Single dimension assign
assign active_command[3:0] = (use_AnB) ? command_A[7:0] : command_B[7:0];
// Assignment of entire arrays
assign active_command2 = (use_AnB) ? command_A2 : command_B2;
// Multi-dimension assign
assign active_command3[1:0][2:0][3:0] = (use_AnB) ? command_A3[1:0][2:0][3:0] : command_B3[1:0][1:0][3:0];
// Supported: Delayed assigment with RHS Var == LHS Var
logic [7:0] arrd [7:0];
always_ff @(posedge clk) arrd[7:4] <= arrd[3:0];
// Unsupported: Non-delayed assigment with RHS Var == LHS Var
logic [7:0] arr [7:0];
assign arr[7:4] = arr[3:0];
// Delayed assign
always @(posedge clk) begin
active_command4[7:0] <= command_A4[8:0];
end
// Combinational assign
always_comb begin
active_command5[8:0] = command_A5[7:0];
end
endmodule : t
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2003 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
// surefire lint_off ASWEBB
// surefire lint_off ASWEMB
// surefire lint_off STMINI
// surefire lint_off CSEBEQ
input clk;
reg [7:0] a_to_clk_levm3;
reg [7:0] b_to_clk_levm1;
reg [7:0] c_com_levs10;
reg [7:0] d_to_clk_levm2;
/*AUTOWIRE*/
// Beginning of automatic wires (for undeclared instantiated-module outputs)
wire [7:0] m_from_clk_lev1_r; // From a of t_order_a.v
wire [7:0] n_from_clk_lev2; // From a of t_order_a.v
wire [7:0] o_from_com_levs11; // From a of t_order_a.v
wire [7:0] o_from_comandclk_levs12;// From a of t_order_a.v
wire [7:0] o_subfrom_clk_lev2; // From b of t_order_b.v
// End of automatics
reg [7:0] cyc; initial cyc=0;
t_order_a a (
.one (8'h1),
/*AUTOINST*/
// Outputs
.m_from_clk_lev1_r (m_from_clk_lev1_r[7:0]),
.n_from_clk_lev2 (n_from_clk_lev2[7:0]),
.o_from_com_levs11 (o_from_com_levs11[7:0]),
.o_from_comandclk_levs12(o_from_comandclk_levs12[7:0]),
// Inputs
.clk (clk),
.a_to_clk_levm3 (a_to_clk_levm3[7:0]),
.b_to_clk_levm1 (b_to_clk_levm1[7:0]),
.c_com_levs10 (c_com_levs10[7:0]),
.d_to_clk_levm2 (d_to_clk_levm2[7:0]));
t_order_b b (
/*AUTOINST*/
// Outputs
.o_subfrom_clk_lev2 (o_subfrom_clk_lev2[7:0]),
// Inputs
.m_from_clk_lev1_r (m_from_clk_lev1_r[7:0]));
reg [7:0] o_from_com_levs12;
reg [7:0] o_from_com_levs13;
always @ (/*AS*/o_from_com_levs11) begin
o_from_com_levs12 = o_from_com_levs11 + 8'h1;
o_from_com_levs12 = o_from_com_levs12 + 8'h1; // Test we can add to self and optimize
o_from_com_levs13 = o_from_com_levs12;
end
reg sepassign_in;
// verilator lint_off UNOPTFLAT
wire [3:0] sepassign;
// verilator lint_on UNOPTFLAT
// verilator lint_off UNOPT
assign #0.1 sepassign[0] = 0,
sepassign[1] = sepassign[2],
sepassign[2] = sepassign[3],
sepassign[3] = sepassign_in;
wire [7:0] o_subfrom_clk_lev3 = o_subfrom_clk_lev2;
// verilator lint_on UNOPT
always @ (posedge clk) begin
cyc <= cyc+8'd1;
sepassign_in <= 0;
if (cyc == 8'd1) begin
a_to_clk_levm3 <= 0;
d_to_clk_levm2 <= 1;
b_to_clk_levm1 <= 1;
c_com_levs10 <= 2;
sepassign_in <= 1;
end
if (cyc == 8'd2) begin
if (sepassign !== 4'b1110) $stop;
end
if (cyc == 8'd3) begin
$display("%d %d %d %d",m_from_clk_lev1_r,
n_from_clk_lev2,
o_from_com_levs11,
o_from_comandclk_levs12);
if (m_from_clk_lev1_r !== 8'h2) $stop;
if (o_subfrom_clk_lev3 !== 8'h2) $stop;
if (n_from_clk_lev2 !== 8'h2) $stop;
if (o_from_com_levs11 !== 8'h3) $stop;
if (o_from_com_levs13 !== 8'h5) $stop;
if (o_from_comandclk_levs12 !== 8'h5) $stop;
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2003 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
// surefire lint_off ASWEBB
// surefire lint_off ASWEMB
// surefire lint_off STMINI
// surefire lint_off CSEBEQ
input clk;
reg [7:0] a_to_clk_levm3;
reg [7:0] b_to_clk_levm1;
reg [7:0] c_com_levs10;
reg [7:0] d_to_clk_levm2;
/*AUTOWIRE*/
// Beginning of automatic wires (for undeclared instantiated-module outputs)
wire [7:0] m_from_clk_lev1_r; // From a of t_order_a.v
wire [7:0] n_from_clk_lev2; // From a of t_order_a.v
wire [7:0] o_from_com_levs11; // From a of t_order_a.v
wire [7:0] o_from_comandclk_levs12;// From a of t_order_a.v
wire [7:0] o_subfrom_clk_lev2; // From b of t_order_b.v
// End of automatics
reg [7:0] cyc; initial cyc=0;
t_order_a a (
.one (8'h1),
/*AUTOINST*/
// Outputs
.m_from_clk_lev1_r (m_from_clk_lev1_r[7:0]),
.n_from_clk_lev2 (n_from_clk_lev2[7:0]),
.o_from_com_levs11 (o_from_com_levs11[7:0]),
.o_from_comandclk_levs12(o_from_comandclk_levs12[7:0]),
// Inputs
.clk (clk),
.a_to_clk_levm3 (a_to_clk_levm3[7:0]),
.b_to_clk_levm1 (b_to_clk_levm1[7:0]),
.c_com_levs10 (c_com_levs10[7:0]),
.d_to_clk_levm2 (d_to_clk_levm2[7:0]));
t_order_b b (
/*AUTOINST*/
// Outputs
.o_subfrom_clk_lev2 (o_subfrom_clk_lev2[7:0]),
// Inputs
.m_from_clk_lev1_r (m_from_clk_lev1_r[7:0]));
reg [7:0] o_from_com_levs12;
reg [7:0] o_from_com_levs13;
always @ (/*AS*/o_from_com_levs11) begin
o_from_com_levs12 = o_from_com_levs11 + 8'h1;
o_from_com_levs12 = o_from_com_levs12 + 8'h1; // Test we can add to self and optimize
o_from_com_levs13 = o_from_com_levs12;
end
reg sepassign_in;
// verilator lint_off UNOPTFLAT
wire [3:0] sepassign;
// verilator lint_on UNOPTFLAT
// verilator lint_off UNOPT
assign #0.1 sepassign[0] = 0,
sepassign[1] = sepassign[2],
sepassign[2] = sepassign[3],
sepassign[3] = sepassign_in;
wire [7:0] o_subfrom_clk_lev3 = o_subfrom_clk_lev2;
// verilator lint_on UNOPT
always @ (posedge clk) begin
cyc <= cyc+8'd1;
sepassign_in <= 0;
if (cyc == 8'd1) begin
a_to_clk_levm3 <= 0;
d_to_clk_levm2 <= 1;
b_to_clk_levm1 <= 1;
c_com_levs10 <= 2;
sepassign_in <= 1;
end
if (cyc == 8'd2) begin
if (sepassign !== 4'b1110) $stop;
end
if (cyc == 8'd3) begin
$display("%d %d %d %d",m_from_clk_lev1_r,
n_from_clk_lev2,
o_from_com_levs11,
o_from_comandclk_levs12);
if (m_from_clk_lev1_r !== 8'h2) $stop;
if (o_subfrom_clk_lev3 !== 8'h2) $stop;
if (n_from_clk_lev2 !== 8'h2) $stop;
if (o_from_com_levs11 !== 8'h3) $stop;
if (o_from_com_levs13 !== 8'h5) $stop;
if (o_from_comandclk_levs12 !== 8'h5) $stop;
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2003 by Wilson Snyder.
module t (/*AUTOARG*/
// Inputs
clk
);
// surefire lint_off ASWEBB
// surefire lint_off ASWEMB
// surefire lint_off STMINI
// surefire lint_off CSEBEQ
input clk;
reg [7:0] a_to_clk_levm3;
reg [7:0] b_to_clk_levm1;
reg [7:0] c_com_levs10;
reg [7:0] d_to_clk_levm2;
/*AUTOWIRE*/
// Beginning of automatic wires (for undeclared instantiated-module outputs)
wire [7:0] m_from_clk_lev1_r; // From a of t_order_a.v
wire [7:0] n_from_clk_lev2; // From a of t_order_a.v
wire [7:0] o_from_com_levs11; // From a of t_order_a.v
wire [7:0] o_from_comandclk_levs12;// From a of t_order_a.v
wire [7:0] o_subfrom_clk_lev2; // From b of t_order_b.v
// End of automatics
reg [7:0] cyc; initial cyc=0;
t_order_a a (
.one (8'h1),
/*AUTOINST*/
// Outputs
.m_from_clk_lev1_r (m_from_clk_lev1_r[7:0]),
.n_from_clk_lev2 (n_from_clk_lev2[7:0]),
.o_from_com_levs11 (o_from_com_levs11[7:0]),
.o_from_comandclk_levs12(o_from_comandclk_levs12[7:0]),
// Inputs
.clk (clk),
.a_to_clk_levm3 (a_to_clk_levm3[7:0]),
.b_to_clk_levm1 (b_to_clk_levm1[7:0]),
.c_com_levs10 (c_com_levs10[7:0]),
.d_to_clk_levm2 (d_to_clk_levm2[7:0]));
t_order_b b (
/*AUTOINST*/
// Outputs
.o_subfrom_clk_lev2 (o_subfrom_clk_lev2[7:0]),
// Inputs
.m_from_clk_lev1_r (m_from_clk_lev1_r[7:0]));
reg [7:0] o_from_com_levs12;
reg [7:0] o_from_com_levs13;
always @ (/*AS*/o_from_com_levs11) begin
o_from_com_levs12 = o_from_com_levs11 + 8'h1;
o_from_com_levs12 = o_from_com_levs12 + 8'h1; // Test we can add to self and optimize
o_from_com_levs13 = o_from_com_levs12;
end
reg sepassign_in;
// verilator lint_off UNOPTFLAT
wire [3:0] sepassign;
// verilator lint_on UNOPTFLAT
// verilator lint_off UNOPT
assign #0.1 sepassign[0] = 0,
sepassign[1] = sepassign[2],
sepassign[2] = sepassign[3],
sepassign[3] = sepassign_in;
wire [7:0] o_subfrom_clk_lev3 = o_subfrom_clk_lev2;
// verilator lint_on UNOPT
always @ (posedge clk) begin
cyc <= cyc+8'd1;
sepassign_in <= 0;
if (cyc == 8'd1) begin
a_to_clk_levm3 <= 0;
d_to_clk_levm2 <= 1;
b_to_clk_levm1 <= 1;
c_com_levs10 <= 2;
sepassign_in <= 1;
end
if (cyc == 8'd2) begin
if (sepassign !== 4'b1110) $stop;
end
if (cyc == 8'd3) begin
$display("%d %d %d %d",m_from_clk_lev1_r,
n_from_clk_lev2,
o_from_com_levs11,
o_from_comandclk_levs12);
if (m_from_clk_lev1_r !== 8'h2) $stop;
if (o_subfrom_clk_lev3 !== 8'h2) $stop;
if (n_from_clk_lev2 !== 8'h2) $stop;
if (o_from_com_levs11 !== 8'h3) $stop;
if (o_from_com_levs13 !== 8'h5) $stop;
if (o_from_comandclk_levs12 !== 8'h5) $stop;
$write("*-* All Finished *-*\n");
$finish;
end
end
endmodule
|
/****************************************************************************************
*
* File Name: ddr3.v
* Version: 1.61
* Model: BUS Functional
*
* Dependencies: ddr3_model_parameters.vh
*
* Description: Micron SDRAM DDR3 (Double Data Rate 3)
*
* Limitation: - doesn't check for average refresh timings
* - positive ck and ck_n edges are used to form internal clock
* - positive dqs and dqs_n edges are used to latch data
* - test mode is not modeled
* - Duty Cycle Corrector is not modeled
* - Temperature Compensated Self Refresh is not modeled
* - DLL off mode is not modeled.
*
* Note: - Set simulator resolution to "ps" accuracy
* - Set DEBUG = 0 to disable $display messages
*
* Disclaimer This software code and all associated documentation, comments or other
* of Warranty: information (collectively "Software") is provided "AS IS" without
* warranty of any kind. MICRON TECHNOLOGY, INC. ("MTI") EXPRESSLY
* DISCLAIMS ALL WARRANTIES EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED
* TO, NONINFRINGEMENT OF THIRD PARTY RIGHTS, AND ANY IMPLIED WARRANTIES
* OF MERCHANTABILITY OR FITNESS FOR ANY PARTICULAR PURPOSE. MTI DOES NOT
* WARRANT THAT THE SOFTWARE WILL MEET YOUR REQUIREMENTS, OR THAT THE
* OPERATION OF THE SOFTWARE WILL BE UNINTERRUPTED OR ERROR-FREE.
* FURTHERMORE, MTI DOES NOT MAKE ANY REPRESENTATIONS REGARDING THE USE OR
* THE RESULTS OF THE USE OF THE SOFTWARE IN TERMS OF ITS CORRECTNESS,
* ACCURACY, RELIABILITY, OR OTHERWISE. THE ENTIRE RISK ARISING OUT OF USE
* OR PERFORMANCE OF THE SOFTWARE REMAINS WITH YOU. IN NO EVENT SHALL MTI,
* ITS AFFILIATED COMPANIES OR THEIR SUPPLIERS BE LIABLE FOR ANY DIRECT,
* INDIRECT, CONSEQUENTIAL, INCIDENTAL, OR SPECIAL DAMAGES (INCLUDING,
* WITHOUT LIMITATION, DAMAGES FOR LOSS OF PROFITS, BUSINESS INTERRUPTION,
* OR LOSS OF INFORMATION) ARISING OUT OF YOUR USE OF OR INABILITY TO USE
* THE SOFTWARE, EVEN IF MTI HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH
* DAMAGES. Because some jurisdictions prohibit the exclusion or
* limitation of liability for consequential or incidental damages, the
* above limitation may not apply to you.
*
* Copyright 2003 Micron Technology, Inc. All rights reserved.
*
* Rev Author Date Changes
* ---------------------------------------------------------------------------------------
* 0.41 JMK 05/12/06 Removed auto-precharge to power down error check.
* 0.42 JMK 08/25/06 Created internal clock using ck and ck_n.
* TDQS can only be enabled in EMR for x8 configurations.
* CAS latency is checked vs frequency when DLL locks.
* Improved checking of DQS during writes.
* Added true BL4 operation.
* 0.43 JMK 08/14/06 Added checking for setting reserved bits in Mode Registers.
* Added ODTS Readout.
* Replaced tZQCL with tZQinit and tZQoper
* Fixed tWRPDEN and tWRAPDEN during BC4MRS and BL4MRS.
* Added tRFC checking for Refresh to Power-Down Re-Entry.
* Added tXPDLL checking for Power-Down Exit to Refresh to Power-Down Entry
* Added Clock Frequency Change during Precharge Power-Down.
* Added -125x speed grades.
* Fixed tRCD checking during Write.
* 1.00 JMK 05/11/07 Initial release
* 1.10 JMK 06/26/07 Fixed ODTH8 check during BLOTF
* Removed temp sensor readout from MPR
* Updated initialization sequence
* Updated timing parameters
* 1.20 JMK 09/05/07 Updated clock frequency change
* Added ddr3_dimm module
* 1.30 JMK 01/23/08 Updated timing parameters
* 1.40 JMK 12/02/08 Added support for DDR3-1866 and DDR3-2133
* renamed ddr3_dimm.v to ddr3_module.v and added SODIMM support.
* Added multi-chip package model support in ddr3_mcp.v
* 1.50 JMK 05/04/08 Added 1866 and 2133 speed grades.
* 1.60 MYY 07/10/09 Merging of 1.50 version and pre-1.0 version changes
* 1.61 SPH 12/10/09 Only check tIH for cmd_addr if CS# LOW
*****************************************************************************************/
// DO NOT CHANGE THE TIMESCALE
// MAKE SURE YOUR SIMULATOR USES "PS" RESOLUTION
`timescale 1ps / 1ps
// model flags
// `define MODEL_PASR
module ddr3_model (
rst_n,
ck,
ck_n,
cke,
cs_n,
ras_n,
cas_n,
we_n,
dm_tdqs,
ba,
addr,
dq,
dqs,
dqs_n,
tdqs_n,
odt
);
`include "ddr3_model_parameters.vh"
parameter check_strict_mrbits = 1;
parameter check_strict_timing = 1;
parameter feature_pasr = 1;
parameter feature_truebl4 = 0;
// text macros
`define DQ_PER_DQS DQ_BITS/DQS_BITS
`define BANKS (1<<BA_BITS)
`define MAX_BITS (BA_BITS+ROW_BITS+COL_BITS-BL_BITS)
`define MAX_SIZE (1<<(BA_BITS+ROW_BITS+COL_BITS-BL_BITS))
`define MEM_SIZE (1<<MEM_BITS)
`define MAX_PIPE 4*CL_MAX
// Declare Ports
input rst_n;
input ck;
input ck_n;
input cke;
input cs_n;
input ras_n;
input cas_n;
input we_n;
inout [DM_BITS-1:0] dm_tdqs;
input [BA_BITS-1:0] ba;
input [ADDR_BITS-1:0] addr;
inout [DQ_BITS-1:0] dq;
inout [DQS_BITS-1:0] dqs;
inout [DQS_BITS-1:0] dqs_n;
output [DQS_BITS-1:0] tdqs_n;
input odt;
// clock jitter
real tck_avg;
time tck_sample [TDLLK-1:0];
time tch_sample [TDLLK-1:0];
time tcl_sample [TDLLK-1:0];
time tck_i;
time tch_i;
time tcl_i;
real tch_avg;
real tcl_avg;
time tm_ck_pos;
time tm_ck_neg;
real tjit_per_rtime;
integer tjit_cc_time;
real terr_nper_rtime;
//DDR3 clock jitter variables
real tjit_ch_rtime;
real duty_cycle;
// clock skew
real out_delay;
integer dqsck [DQS_BITS-1:0];
integer dqsck_min;
integer dqsck_max;
integer dqsq_min;
integer dqsq_max;
integer seed;
// Mode Registers
reg [ADDR_BITS-1:0] mode_reg [`BANKS-1:0];
reg burst_order;
reg [BL_BITS:0] burst_length;
reg blotf;
reg truebl4;
integer cas_latency;
reg dll_reset;
reg dll_locked;
integer write_recovery;
reg low_power;
reg dll_en;
reg [2:0] odt_rtt_nom;
reg [1:0] odt_rtt_wr;
reg odt_en;
reg dyn_odt_en;
reg [1:0] al;
integer additive_latency;
reg write_levelization;
reg duty_cycle_corrector;
reg tdqs_en;
reg out_en;
reg [2:0] pasr;
integer cas_write_latency;
reg asr; // auto self refresh
reg srt; // self refresh temperature range
reg [1:0] mpr_select;
reg mpr_en;
reg odts_readout;
integer read_latency;
integer write_latency;
// cmd encoding
parameter // {cs, ras, cas, we}
LOAD_MODE = 4'b0000,
REFRESH = 4'b0001,
PRECHARGE = 4'b0010,
ACTIVATE = 4'b0011,
WRITE = 4'b0100,
READ = 4'b0101,
ZQ = 4'b0110,
NOP = 4'b0111,
// DESEL = 4'b1xxx,
PWR_DOWN = 4'b1000,
SELF_REF = 4'b1001
;
reg [8*9-1:0] cmd_string [9:0];
initial begin
cmd_string[LOAD_MODE] = "Load Mode";
cmd_string[REFRESH ] = "Refresh ";
cmd_string[PRECHARGE] = "Precharge";
cmd_string[ACTIVATE ] = "Activate ";
cmd_string[WRITE ] = "Write ";
cmd_string[READ ] = "Read ";
cmd_string[ZQ ] = "ZQ ";
cmd_string[NOP ] = "No Op ";
cmd_string[PWR_DOWN ] = "Pwr Down ";
cmd_string[SELF_REF ] = "Self Ref ";
end
// command state
reg [`BANKS-1:0] active_bank;
reg [`BANKS-1:0] auto_precharge_bank;
reg [`BANKS-1:0] write_precharge_bank;
reg [`BANKS-1:0] read_precharge_bank;
reg [ROW_BITS-1:0] active_row [`BANKS-1:0];
reg in_power_down;
reg in_self_refresh;
reg [3:0] init_mode_reg;
reg init_dll_reset;
reg init_done;
integer init_step;
reg zq_set;
reg er_trfc_max;
reg odt_state;
reg odt_state_dly;
reg dyn_odt_state;
reg dyn_odt_state_dly;
reg prev_odt;
wire [7:0] calibration_pattern = 8'b10101010; // value returned during mpr pre-defined pattern readout
wire [7:0] temp_sensor = 8'h01; // value returned during mpr temp sensor readout
reg [1:0] mr_chk;
reg rd_bc;
integer banki;
// cmd timers/counters
integer ref_cntr;
integer odt_cntr;
integer ck_cntr;
integer ck_txpr;
integer ck_load_mode;
integer ck_refresh;
integer ck_precharge;
integer ck_activate;
integer ck_write;
integer ck_read;
integer ck_zqinit;
integer ck_zqoper;
integer ck_zqcs;
integer ck_power_down;
integer ck_slow_exit_pd;
integer ck_self_refresh;
integer ck_freq_change;
integer ck_odt;
integer ck_odth8;
integer ck_dll_reset;
integer ck_cke_cmd;
integer ck_bank_write [`BANKS-1:0];
integer ck_bank_read [`BANKS-1:0];
integer ck_group_activate [1:0];
integer ck_group_write [1:0];
integer ck_group_read [1:0];
time tm_txpr;
time tm_load_mode;
time tm_refresh;
time tm_precharge;
time tm_activate;
time tm_write_end;
time tm_power_down;
time tm_slow_exit_pd;
time tm_self_refresh;
time tm_freq_change;
time tm_cke_cmd;
time tm_ttsinit;
time tm_bank_precharge [`BANKS-1:0];
time tm_bank_activate [`BANKS-1:0];
time tm_bank_write_end [`BANKS-1:0];
time tm_bank_read_end [`BANKS-1:0];
time tm_group_activate [1:0];
time tm_group_write_end [1:0];
// pipelines
reg [`MAX_PIPE:0] al_pipeline;
reg [`MAX_PIPE:0] wr_pipeline;
reg [`MAX_PIPE:0] rd_pipeline;
reg [`MAX_PIPE:0] odt_pipeline;
reg [`MAX_PIPE:0] dyn_odt_pipeline;
reg [BL_BITS:0] bl_pipeline [`MAX_PIPE:0];
reg [BA_BITS-1:0] ba_pipeline [`MAX_PIPE:0];
reg [ROW_BITS-1:0] row_pipeline [`MAX_PIPE:0];
reg [COL_BITS-1:0] col_pipeline [`MAX_PIPE:0];
reg prev_cke;
// data state
reg [BL_MAX*DQ_BITS-1:0] memory_data;
reg [BL_MAX*DQ_BITS-1:0] bit_mask;
reg [BL_BITS-1:0] burst_position;
reg [BL_BITS:0] burst_cntr;
reg [DQ_BITS-1:0] dq_temp;
reg [31:0] check_write_postamble;
reg [31:0] check_write_preamble;
reg [31:0] check_write_dqs_high;
reg [31:0] check_write_dqs_low;
reg [15:0] check_dm_tdipw;
reg [63:0] check_dq_tdipw;
// data timers/counters
time tm_rst_n;
time tm_cke;
time tm_odt;
time tm_tdqss;
time tm_dm [15:0];
time tm_dqs [15:0];
time tm_dqs_pos [31:0];
time tm_dqss_pos [31:0];
time tm_dqs_neg [31:0];
time tm_dq [63:0];
time tm_cmd_addr [22:0];
reg [8*7-1:0] cmd_addr_string [22:0];
initial begin
cmd_addr_string[ 0] = "CS_N ";
cmd_addr_string[ 1] = "RAS_N ";
cmd_addr_string[ 2] = "CAS_N ";
cmd_addr_string[ 3] = "WE_N ";
cmd_addr_string[ 4] = "BA 0 ";
cmd_addr_string[ 5] = "BA 1 ";
cmd_addr_string[ 6] = "BA 2 ";
cmd_addr_string[ 7] = "ADDR 0";
cmd_addr_string[ 8] = "ADDR 1";
cmd_addr_string[ 9] = "ADDR 2";
cmd_addr_string[10] = "ADDR 3";
cmd_addr_string[11] = "ADDR 4";
cmd_addr_string[12] = "ADDR 5";
cmd_addr_string[13] = "ADDR 6";
cmd_addr_string[14] = "ADDR 7";
cmd_addr_string[15] = "ADDR 8";
cmd_addr_string[16] = "ADDR 9";
cmd_addr_string[17] = "ADDR 10";
cmd_addr_string[18] = "ADDR 11";
cmd_addr_string[19] = "ADDR 12";
cmd_addr_string[20] = "ADDR 13";
cmd_addr_string[21] = "ADDR 14";
cmd_addr_string[22] = "ADDR 15";
end
reg [8*5-1:0] dqs_string [1:0];
initial begin
dqs_string[0] = "DQS ";
dqs_string[1] = "DQS_N";
end
// Memory Storage
`ifdef MAX_MEM
parameter RFF_BITS = DQ_BITS*BL_MAX;
// %z format uses 8 bytes for every 32 bits or less.
parameter RFF_CHUNK = 8 * (RFF_BITS/32 + (RFF_BITS%32 ? 1 : 0));
reg [1024:1] tmp_model_dir;
integer memfd[`BANKS-1:0];
initial
begin : file_io_open
integer bank;
if (!$value$plusargs("model_data+%s", tmp_model_dir))
begin
tmp_model_dir = "/tmp";
$display(
"%m: at time %t WARNING: no +model_data option specified, using /tmp.",
$time
);
end
for (bank = 0; bank < `BANKS; bank = bank + 1)
memfd[bank] = open_bank_file(bank);
end
`else
reg [BL_MAX*DQ_BITS-1:0] memory [0:`MEM_SIZE-1];
reg [`MAX_BITS-1:0] address [0:`MEM_SIZE-1];
reg [MEM_BITS:0] memory_index;
reg [MEM_BITS:0] memory_used = 0;
`endif
// receive
reg rst_n_in;
reg ck_in;
reg ck_n_in;
reg cke_in;
reg cs_n_in;
reg ras_n_in;
reg cas_n_in;
reg we_n_in;
reg [15:0] dm_in;
reg [2:0] ba_in;
reg [15:0] addr_in;
reg [63:0] dq_in;
reg [31:0] dqs_in;
reg odt_in;
reg [15:0] dm_in_pos;
reg [15:0] dm_in_neg;
reg [63:0] dq_in_pos;
reg [63:0] dq_in_neg;
reg dq_in_valid;
reg dqs_in_valid;
integer wdqs_cntr;
integer wdq_cntr;
integer wdqs_pos_cntr [31:0];
reg b2b_write;
reg [BL_BITS:0] wr_burst_length;
reg [31:0] prev_dqs_in;
reg diff_ck;
always @(rst_n ) rst_n_in <= #BUS_DELAY rst_n;
always @(ck ) ck_in <= #BUS_DELAY ck;
always @(ck_n ) ck_n_in <= #BUS_DELAY ck_n;
always @(cke ) cke_in <= #BUS_DELAY cke;
always @(cs_n ) cs_n_in <= #BUS_DELAY cs_n;
always @(ras_n ) ras_n_in <= #BUS_DELAY ras_n;
always @(cas_n ) cas_n_in <= #BUS_DELAY cas_n;
always @(we_n ) we_n_in <= #BUS_DELAY we_n;
always @(dm_tdqs) dm_in <= #BUS_DELAY dm_tdqs;
always @(ba ) ba_in <= #BUS_DELAY ba;
always @(addr ) addr_in <= #BUS_DELAY addr;
always @(dq ) dq_in <= #BUS_DELAY dq;
always @(dqs or dqs_n) dqs_in <= #BUS_DELAY (dqs_n<<16) | dqs;
always @(odt ) odt_in <= #BUS_DELAY odt;
// create internal clock
always @(posedge ck_in) diff_ck <= ck_in;
always @(posedge ck_n_in) diff_ck <= ~ck_n_in;
wire [15:0] dqs_even = dqs_in[15:0];
wire [15:0] dqs_odd = dqs_in[31:16];
wire [3:0] cmd_n_in = !cs_n_in ? {ras_n_in, cas_n_in, we_n_in} : NOP; //deselect = nop
// transmit
reg dqs_out_en;
reg [DQS_BITS-1:0] dqs_out_en_dly;
reg dqs_out;
reg [DQS_BITS-1:0] dqs_out_dly;
reg dq_out_en;
reg [DQ_BITS-1:0] dq_out_en_dly;
reg [DQ_BITS-1:0] dq_out;
reg [DQ_BITS-1:0] dq_out_dly;
integer rdqsen_cntr;
integer rdqs_cntr;
integer rdqen_cntr;
integer rdq_cntr;
bufif1 buf_dqs [DQS_BITS-1:0] (dqs, dqs_out_dly, dqs_out_en_dly & {DQS_BITS{out_en}});
bufif1 buf_dqs_n [DQS_BITS-1:0] (dqs_n, ~dqs_out_dly, dqs_out_en_dly & {DQS_BITS{out_en}});
bufif1 buf_dq [DQ_BITS-1:0] (dq, dq_out_dly, dq_out_en_dly & {DQ_BITS {out_en}});
assign tdqs_n = {DQS_BITS{1'bz}};
initial begin
if (BL_MAX < 2)
$display("%m ERROR: BL_MAX parameter must be >= 2. \nBL_MAX = %d", BL_MAX);
if ((1<<BO_BITS) > BL_MAX)
$display("%m ERROR: 2^BO_BITS cannot be greater than BL_MAX parameter.");
$timeformat (-12, 1, " ps", 1);
seed = RANDOM_SEED;
ck_cntr = 0;
end
function integer get_rtt_wr;
input [1:0] rtt;
begin
get_rtt_wr = RZQ/{rtt[0], rtt[1], 1'b0};
end
endfunction
function integer get_rtt_nom;
input [2:0] rtt;
begin
case (rtt)
1: get_rtt_nom = RZQ/4;
2: get_rtt_nom = RZQ/2;
3: get_rtt_nom = RZQ/6;
4: get_rtt_nom = RZQ/12;
5: get_rtt_nom = RZQ/8;
default : get_rtt_nom = 0;
endcase
end
endfunction
// calculate the absolute value of a real number
function real abs_value;
input arg;
real arg;
begin
if (arg < 0.0)
abs_value = -1.0 * arg;
else
abs_value = arg;
end
endfunction
function integer ceil;
input number;
real number;
// LMR 4.1.7
// When either operand of a relational expression is a real operand then the other operand shall be converted
// to an equivalent real value, and the expression shall be interpreted as a comparison between two real values.
if (number > $rtoi(number))
ceil = $rtoi(number) + 1;
else
ceil = number;
endfunction
function integer floor;
input number;
real number;
// LMR 4.1.7
// When either operand of a relational expression is a real operand then the other operand shall be converted
// to an equivalent real value, and the expression shall be interpreted as a comparison between two real values.
if (number < $rtoi(number))
floor = $rtoi(number) - 1;
else
floor = number;
endfunction
`ifdef MAX_MEM
function integer open_bank_file( input integer bank );
integer fd;
reg [2048:1] filename;
begin
$sformat( filename, "%0s/%m.%0d", tmp_model_dir, bank );
fd = $fopen(filename, "w+");
if (fd == 0)
begin
$display("%m: at time %0t ERROR: failed to open %0s.", $time, filename);
$finish;
end
else
begin
if (DEBUG) $display("%m: at time %0t INFO: opening %0s.", $time, filename);
open_bank_file = fd;
end
end
endfunction
function [RFF_BITS:1] read_from_file(
input integer fd,
input integer index
);
integer code;
integer offset;
reg [1024:1] msg;
reg [RFF_BITS:1] read_value;
begin
offset = index * RFF_CHUNK;
code = $fseek( fd, offset, 0 );
// $fseek returns 0 on success, -1 on failure
if (code != 0)
begin
$display("%m: at time %t ERROR: fseek to %d failed", $time, offset);
$finish;
end
code = $fscanf(fd, "%z", read_value);
// $fscanf returns number of items read
if (code != 1)
begin
if ($ferror(fd,msg) != 0)
begin
$display("%m: at time %t ERROR: fscanf failed at %d", $time, index);
$display(msg);
$finish;
end
else
read_value = 'hx;
end
/* when reading from unwritten portions of the file, 0 will be returned.
* Use 0 in bit 1 as indicator that invalid data has been read.
* A true 0 is encoded as Z.
*/
if (read_value[1] === 1'bz)
// true 0 encoded as Z, data is valid
read_value[1] = 1'b0;
else if (read_value[1] === 1'b0)
// read from file section that has not been written
read_value = 'hx;
read_from_file = read_value;
end
endfunction
task write_to_file(
input integer fd,
input integer index,
input [RFF_BITS:1] data
);
integer code;
integer offset;
begin
offset = index * RFF_CHUNK;
code = $fseek( fd, offset, 0 );
if (code != 0)
begin
$display("%m: at time %t ERROR: fseek to %d failed", $time, offset);
$finish;
end
// encode a valid data
if (data[1] === 1'bz)
data[1] = 1'bx;
else if (data[1] === 1'b0)
data[1] = 1'bz;
$fwrite( fd, "%z", data );
end
endtask
`else
function get_index;
input [`MAX_BITS-1:0] addr;
begin : index
get_index = 0;
for (memory_index=0; memory_index<memory_used; memory_index=memory_index+1) begin
if (address[memory_index] == addr) begin
get_index = 1;
disable index;
end
end
end
endfunction
`endif
task memory_write;
input [BA_BITS-1:0] bank;
input [ROW_BITS-1:0] row;
input [COL_BITS-1:0] col;
input [BL_MAX*DQ_BITS-1:0] data;
reg [`MAX_BITS-1:0] addr;
begin
`ifdef MAX_MEM
addr = {row, col}/BL_MAX;
write_to_file( memfd[bank], addr, data );
`else
// chop off the lowest address bits
addr = {bank, row, col}/BL_MAX;
if (get_index(addr)) begin
address[memory_index] = addr;
memory[memory_index] = data;
end else if (memory_used == `MEM_SIZE) begin
$display ("%m: at time %t ERROR: Memory overflow. Write to Address %h with Data %h will be lost.\nYou must increase the MEM_BITS parameter or define MAX_MEM.", $time, addr, data);
if (STOP_ON_ERROR) $stop(0);
end else begin
address[memory_used] = addr;
memory[memory_used] = data;
memory_used = memory_used + 1;
end
`endif
end
endtask
task memory_read;
input [BA_BITS-1:0] bank;
input [ROW_BITS-1:0] row;
input [COL_BITS-1:0] col;
output [BL_MAX*DQ_BITS-1:0] data;
reg [`MAX_BITS-1:0] addr;
begin
`ifdef MAX_MEM
addr = {row, col}/BL_MAX;
data = read_from_file( memfd[bank], addr );
`else
// chop off the lowest address bits
addr = {bank, row, col}/BL_MAX;
if (get_index(addr)) begin
data = memory[memory_index];
end else begin
data = {BL_MAX*DQ_BITS{1'bx}};
end
`endif
end
endtask
task set_latency;
begin
if (al == 0) begin
additive_latency = 0;
end else begin
additive_latency = cas_latency - al;
end
read_latency = cas_latency + additive_latency;
write_latency = cas_write_latency + additive_latency;
end
endtask
// this task will erase the contents of 0 or more banks
task erase_banks;
input [`BANKS-1:0] banks; //one select bit per bank
reg [BA_BITS-1:0] ba;
reg [`MAX_BITS-1:0] i;
integer bank;
begin
`ifdef MAX_MEM
for (bank = 0; bank < `BANKS; bank = bank + 1)
if (banks[bank] === 1'b1) begin
$fclose(memfd[bank]);
memfd[bank] = open_bank_file(bank);
end
`else
memory_index = 0;
i = 0;
// remove the selected banks
for (memory_index=0; memory_index<memory_used; memory_index=memory_index+1) begin
ba = (address[memory_index]>>(ROW_BITS+COL_BITS-BL_BITS));
if (!banks[ba]) begin //bank is selected to keep
address[i] = address[memory_index];
memory[i] = memory[memory_index];
i = i + 1;
end
end
// clean up the unused banks
for (memory_index=i; memory_index<memory_used; memory_index=memory_index+1) begin
address[memory_index] = 'bx;
memory[memory_index] = {8*DQ_BITS{1'bx}};
end
memory_used = i;
`endif
end
endtask
// Before this task runs, the model must be in a valid state for precharge power down and out of reset.
// After this task runs, NOP commands must be issued until TZQINIT has been met
task initialize;
input [ADDR_BITS-1:0] mode_reg0;
input [ADDR_BITS-1:0] mode_reg1;
input [ADDR_BITS-1:0] mode_reg2;
input [ADDR_BITS-1:0] mode_reg3;
begin
if (DEBUG) $display ("%m: at time %t INFO: Performing Initialization Sequence", $time);
cmd_task(1, NOP, 'bx, 'bx);
cmd_task(1, ZQ, 'bx, 'h400); //ZQCL
cmd_task(1, LOAD_MODE, 3, mode_reg3);
cmd_task(1, LOAD_MODE, 2, mode_reg2);
cmd_task(1, LOAD_MODE, 1, mode_reg1);
cmd_task(1, LOAD_MODE, 0, mode_reg0 | 'h100); // DLL Reset
cmd_task(0, NOP, 'bx, 'bx);
end
endtask
task reset_task;
integer i;
begin
// disable inputs
dq_in_valid = 0;
dqs_in_valid <= 0;
wdqs_cntr = 0;
wdq_cntr = 0;
for (i=0; i<31; i=i+1) begin
wdqs_pos_cntr[i] <= 0;
end
b2b_write <= 0;
// disable outputs
out_en = 0;
dq_out_en = 0;
rdq_cntr = 0;
dqs_out_en = 0;
rdqs_cntr = 0;
// disable ODT
odt_en = 0;
dyn_odt_en = 0;
odt_state = 0;
dyn_odt_state = 0;
// reset bank state
active_bank = 0;
auto_precharge_bank = 0;
read_precharge_bank = 0;
write_precharge_bank = 0;
// require initialization sequence
init_done = 0;
mpr_en = 0;
init_step = 0;
init_mode_reg = 0;
init_dll_reset = 0;
zq_set = 0;
// reset DLL
dll_en = 0;
dll_reset = 0;
dll_locked = 0;
// exit power down and self refresh
prev_cke = 1'bx;
in_power_down = 0;
in_self_refresh = 0;
// clear pipelines
al_pipeline = 0;
wr_pipeline = 0;
rd_pipeline = 0;
odt_pipeline = 0;
dyn_odt_pipeline = 0;
end
endtask
parameter SAME_BANK = 2'd0; // same bank, same group
parameter DIFF_BANK = 2'd1; // different bank, same group
parameter DIFF_GROUP = 2'd2; // different bank, different group
task chk_err;
input [1:0] relationship;
input [BA_BITS-1:0] bank;
input [3:0] fromcmd;
input [3:0] cmd;
reg err;
begin
// $display ("truebl4 = %d, relationship = %d, fromcmd = %h, cmd = %h", truebl4, relationship, fromcmd, cmd);
casex ({truebl4, relationship, fromcmd, cmd})
// load mode
{1'bx, DIFF_BANK , LOAD_MODE, LOAD_MODE} : begin if (ck_cntr - ck_load_mode < TMRD) $display ("%m: at time %t ERROR: tMRD violation during %s", $time, cmd_string[cmd]); end
{1'bx, DIFF_BANK , LOAD_MODE, READ } : begin if (($time - tm_load_mode < TMOD) || (ck_cntr - ck_load_mode < TMOD_TCK)) $display ("%m: at time %t ERROR: tMOD violation during %s", $time, cmd_string[cmd]); end
{1'bx, DIFF_BANK , LOAD_MODE, REFRESH } ,
{1'bx, DIFF_BANK , LOAD_MODE, PRECHARGE} ,
{1'bx, DIFF_BANK , LOAD_MODE, ACTIVATE } ,
{1'bx, DIFF_BANK , LOAD_MODE, ZQ } ,
{1'bx, DIFF_BANK , LOAD_MODE, PWR_DOWN } ,
{1'bx, DIFF_BANK , LOAD_MODE, SELF_REF } : begin if (($time - tm_load_mode < TMOD) || (ck_cntr - ck_load_mode < TMOD_TCK)) $display ("%m: at time %t ERROR: tMOD violation during %s", $time, cmd_string[cmd]); end
// refresh
{1'bx, DIFF_BANK , REFRESH , LOAD_MODE} ,
{1'bx, DIFF_BANK , REFRESH , REFRESH } ,
{1'bx, DIFF_BANK , REFRESH , PRECHARGE} ,
{1'bx, DIFF_BANK , REFRESH , ACTIVATE } ,
{1'bx, DIFF_BANK , REFRESH , ZQ } ,
{1'bx, DIFF_BANK , REFRESH , SELF_REF } : begin if ($time - tm_refresh < TRFC_MIN) $display ("%m: at time %t ERROR: tRFC violation during %s", $time, cmd_string[cmd]); end
{1'bx, DIFF_BANK , REFRESH , PWR_DOWN } : begin if (ck_cntr - ck_refresh < TREFPDEN) $display ("%m: at time %t ERROR: tREFPDEN violation during %s", $time, cmd_string[cmd]); end
// precharge
{1'bx, SAME_BANK , PRECHARGE, ACTIVATE } : begin if ($time - tm_bank_precharge[bank] < TRP) $display ("%m: at time %t ERROR: tRP violation during %s to bank %d", $time, cmd_string[cmd], bank); end
{1'bx, DIFF_BANK , PRECHARGE, LOAD_MODE} ,
{1'bx, DIFF_BANK , PRECHARGE, REFRESH } ,
{1'bx, DIFF_BANK , PRECHARGE, ZQ } ,
{1'bx, DIFF_BANK , PRECHARGE, SELF_REF } : begin if ($time - tm_precharge < TRP) $display ("%m: at time %t ERROR: tRP violation during %s", $time, cmd_string[cmd]); end
{1'bx, DIFF_BANK , PRECHARGE, PWR_DOWN } : ; //tPREPDEN = 1 tCK, can be concurrent with auto precharge
// activate
{1'bx, SAME_BANK , ACTIVATE , PRECHARGE} : begin if ($time - tm_bank_activate[bank] > TRAS_MAX) $display ("%m: at time %t ERROR: tRAS maximum violation during %s to bank %d", $time, cmd_string[cmd], bank);
if ($time - tm_bank_activate[bank] < TRAS_MIN) $display ("%m: at time %t ERROR: tRAS minimum violation during %s to bank %d", $time, cmd_string[cmd], bank);end
{1'bx, SAME_BANK , ACTIVATE , ACTIVATE } : begin if ($time - tm_bank_activate[bank] < TRC) $display ("%m: at time %t ERROR: tRC violation during %s to bank %d", $time, cmd_string[cmd], bank); end
{1'bx, SAME_BANK , ACTIVATE , WRITE } ,
{1'bx, SAME_BANK , ACTIVATE , READ } : ; // tRCD is checked outside this task
{1'b0, DIFF_BANK , ACTIVATE , ACTIVATE } : begin if (($time - tm_activate < TRRD) || (ck_cntr - ck_activate < TRRD_TCK)) $display ("%m: at time %t ERROR: tRRD violation during %s to bank %d", $time, cmd_string[cmd], bank); end
{1'b1, DIFF_BANK , ACTIVATE , ACTIVATE } : begin if (($time - tm_group_activate[bank[1]] < TRRD) || (ck_cntr - ck_group_activate[bank[1]] < TRRD_TCK)) $display ("%m: at time %t ERROR: tRRD violation during %s to bank %d", $time, cmd_string[cmd], bank); end
{1'b1, DIFF_GROUP, ACTIVATE , ACTIVATE } : begin if (($time - tm_activate < TRRD_DG) || (ck_cntr - ck_activate < TRRD_DG_TCK)) $display ("%m: at time %t ERROR: tRRD_DG violation during %s to bank %d", $time, cmd_string[cmd], bank); end
{1'bx, DIFF_BANK , ACTIVATE , REFRESH } : begin if ($time - tm_activate < TRC) $display ("%m: at time %t ERROR: tRC violation during %s", $time, cmd_string[cmd]); end
{1'bx, DIFF_BANK , ACTIVATE , PWR_DOWN } : begin if (ck_cntr - ck_activate < TACTPDEN) $display ("%m: at time %t ERROR: tACTPDEN violation during %s", $time, cmd_string[cmd]); end
// write
{1'bx, SAME_BANK , WRITE , PRECHARGE} : begin if (($time - tm_bank_write_end[bank] < TWR) || (ck_cntr - ck_bank_write[bank] <= write_latency + burst_length/2)) $display ("%m: at time %t ERROR: tWR violation during %s to bank %d", $time, cmd_string[cmd], bank); end
{1'b0, DIFF_BANK , WRITE , WRITE } : begin if (ck_cntr - ck_write < TCCD) $display ("%m: at time %t ERROR: tCCD violation during %s to bank %d", $time, cmd_string[cmd], bank); end
{1'b1, DIFF_BANK , WRITE , WRITE } : begin if (ck_cntr - ck_group_write[bank[1]] < TCCD) $display ("%m: at time %t ERROR: tCCD violation during %s to bank %d", $time, cmd_string[cmd], bank); end
{1'b0, DIFF_BANK , WRITE , READ } : begin if (ck_cntr - ck_write < write_latency + burst_length/2 + TWTR_TCK - additive_latency) $display ("%m: at time %t ERROR: tWTR violation during %s to bank %d", $time, cmd_string[cmd], bank); end
{1'b1, DIFF_BANK , WRITE , READ } : begin if (ck_cntr - ck_group_write[bank[1]] < write_latency + burst_length/2 + TWTR_TCK - additive_latency) $display ("%m: at time %t ERROR: tWTR violation during %s to bank %d", $time, cmd_string[cmd], bank); end
{1'b1, DIFF_GROUP, WRITE , WRITE } : begin if (ck_cntr - ck_write < TCCD_DG) $display ("%m: at time %t ERROR: tCCD_DG violation during %s to bank %d", $time, cmd_string[cmd], bank); end
{1'b1, DIFF_GROUP, WRITE , READ } : begin if (ck_cntr - ck_write < write_latency + burst_length/2 + TWTR_DG_TCK - additive_latency) $display ("%m: at time %t ERROR: tWTR_DG violation during %s to bank %d", $time, cmd_string[cmd], bank); end
{1'bx, DIFF_BANK , WRITE , PWR_DOWN } : begin if (($time - tm_write_end < TWR) || (ck_cntr - ck_write < write_latency + burst_length/2)) $display ("%m: at time %t ERROR: tWRPDEN violation during %s", $time, cmd_string[cmd]); end
// read
{1'bx, SAME_BANK , READ , PRECHARGE} : begin if (($time - tm_bank_read_end[bank] < TRTP) || (ck_cntr - ck_bank_read[bank] < additive_latency + TRTP_TCK)) $display ("%m: at time %t ERROR: tRTP violation during %s to bank %d", $time, cmd_string[cmd], bank); end
{1'b0, DIFF_BANK , READ , WRITE } : ; // tRTW is checked outside this task
{1'b1, DIFF_BANK , READ , WRITE } : ; // tRTW is checked outside this task
{1'b0, DIFF_BANK , READ , READ } : begin if (ck_cntr - ck_read < TCCD) $display ("%m: at time %t ERROR: tCCD violation during %s to bank %d", $time, cmd_string[cmd], bank); end
{1'b1, DIFF_BANK , READ , READ } : begin if (ck_cntr - ck_group_read[bank[1]] < TCCD) $display ("%m: at time %t ERROR: tCCD violation during %s to bank %d", $time, cmd_string[cmd], bank); end
{1'b1, DIFF_GROUP, READ , WRITE } : ; // tRTW is checked outside this task
{1'b1, DIFF_GROUP, READ , READ } : begin if (ck_cntr - ck_read < TCCD_DG) $display ("%m: at time %t ERROR: tCCD_DG violation during %s to bank %d", $time, cmd_string[cmd], bank); end
{1'bx, DIFF_BANK , READ , PWR_DOWN } : begin if (ck_cntr - ck_read < read_latency + 5) $display ("%m: at time %t ERROR: tRDPDEN violation during %s", $time, cmd_string[cmd]); end
// zq
{1'bx, DIFF_BANK , ZQ , LOAD_MODE} : ; // 1 tCK
{1'bx, DIFF_BANK , ZQ , REFRESH } ,
{1'bx, DIFF_BANK , ZQ , PRECHARGE} ,
{1'bx, DIFF_BANK , ZQ , ACTIVATE } ,
{1'bx, DIFF_BANK , ZQ , ZQ } ,
{1'bx, DIFF_BANK , ZQ , PWR_DOWN } ,
{1'bx, DIFF_BANK , ZQ , SELF_REF } : begin if (ck_cntr - ck_zqinit < TZQINIT) $display ("%m: at time %t ERROR: tZQinit violation during %s", $time, cmd_string[cmd]);
if (ck_cntr - ck_zqoper < TZQOPER) $display ("%m: at time %t ERROR: tZQoper violation during %s", $time, cmd_string[cmd]);
if (ck_cntr - ck_zqcs < TZQCS) $display ("%m: at time %t ERROR: tZQCS violation during %s", $time, cmd_string[cmd]); end
// power down
{1'bx, DIFF_BANK , PWR_DOWN , LOAD_MODE} ,
{1'bx, DIFF_BANK , PWR_DOWN , REFRESH } ,
{1'bx, DIFF_BANK , PWR_DOWN , PRECHARGE} ,
{1'bx, DIFF_BANK , PWR_DOWN , ACTIVATE } ,
{1'bx, DIFF_BANK , PWR_DOWN , WRITE } ,
{1'bx, DIFF_BANK , PWR_DOWN , ZQ } : begin if (($time - tm_power_down < TXP) || (ck_cntr - ck_power_down < TXP_TCK)) $display ("%m: at time %t ERROR: tXP violation during %s", $time, cmd_string[cmd]); end
{1'bx, DIFF_BANK , PWR_DOWN , READ } : begin if (($time - tm_power_down < TXP) || (ck_cntr - ck_power_down < TXP_TCK)) $display ("%m: at time %t ERROR: tXP violation during %s", $time, cmd_string[cmd]);
else if (($time - tm_slow_exit_pd < TXPDLL) || (ck_cntr - ck_slow_exit_pd < TXPDLL_TCK)) $display ("%m: at time %t ERROR: tXPDLL violation during %s", $time, cmd_string[cmd]); end
{1'bx, DIFF_BANK , PWR_DOWN , PWR_DOWN } ,
{1'bx, DIFF_BANK , PWR_DOWN , SELF_REF } : begin if (($time - tm_power_down < TXP) || (ck_cntr - ck_power_down < TXP_TCK)) $display ("%m: at time %t ERROR: tXP violation during %s", $time, cmd_string[cmd]);
if ((tm_power_down > tm_refresh) && ($time - tm_refresh < TRFC_MIN)) $display ("%m: at time %t ERROR: tRFC violation during %s", $time, cmd_string[cmd]);
if ((tm_refresh > tm_power_down) && (($time - tm_power_down < TXPDLL) || (ck_cntr - ck_power_down < TXPDLL_TCK))) $display ("%m: at time %t ERROR: tXPDLL violation during %s", $time, cmd_string[cmd]);
if (($time - tm_cke_cmd < TCKE) || (ck_cntr - ck_cke_cmd < TCKE_TCK)) $display ("%m: at time %t ERROR: tCKE violation on CKE", $time); end
// self refresh
{1'bx, DIFF_BANK , SELF_REF , LOAD_MODE} ,
{1'bx, DIFF_BANK , SELF_REF , REFRESH } ,
{1'bx, DIFF_BANK , SELF_REF , PRECHARGE} ,
{1'bx, DIFF_BANK , SELF_REF , ACTIVATE } ,
{1'bx, DIFF_BANK , SELF_REF , WRITE } ,
{1'bx, DIFF_BANK , SELF_REF , ZQ } : begin if (($time - tm_self_refresh < TXS) || (ck_cntr - ck_self_refresh < TXS_TCK)) $display ("%m: at time %t ERROR: tXS violation during %s", $time, cmd_string[cmd]); end
{1'bx, DIFF_BANK , SELF_REF , READ } : begin if (ck_cntr - ck_self_refresh < TXSDLL) $display ("%m: at time %t ERROR: tXSDLL violation during %s", $time, cmd_string[cmd]); end
{1'bx, DIFF_BANK , SELF_REF , PWR_DOWN } ,
{1'bx, DIFF_BANK , SELF_REF , SELF_REF } : begin if (($time - tm_self_refresh < TXS) || (ck_cntr - ck_self_refresh < TXS_TCK)) $display ("%m: at time %t ERROR: tXS violation during %s", $time, cmd_string[cmd]);
if (($time - tm_cke_cmd < TCKE) || (ck_cntr - ck_cke_cmd < TCKE_TCK)) $display ("%m: at time %t ERROR: tCKE violation on CKE", $time); end
endcase
end
endtask
task cmd_task;
input cke;
input [2:0] cmd;
input [BA_BITS-1:0] bank;
input [ADDR_BITS-1:0] addr;
reg [`BANKS:0] i;
integer j;
reg [`BANKS:0] tfaw_cntr;
reg [COL_BITS-1:0] col;
reg group;
begin
// tRFC max check
if (!er_trfc_max && !in_self_refresh) begin
if ($time - tm_refresh > TRFC_MAX && check_strict_timing) begin
$display ("%m: at time %t ERROR: tRFC maximum violation during %s", $time, cmd_string[cmd]);
er_trfc_max = 1;
end
end
if (cke) begin
if ((cmd < NOP) && (cmd != PRECHARGE)) begin
if (($time - tm_txpr < TXPR) || (ck_cntr - ck_txpr < TXPR_TCK))
$display ("%m: at time %t ERROR: tXPR violation during %s", $time, cmd_string[cmd]);
for (j=0; j<=SELF_REF; j=j+1) begin
chk_err(SAME_BANK , bank, j, cmd);
chk_err(DIFF_BANK , bank, j, cmd);
chk_err(DIFF_GROUP, bank, j, cmd);
end
end
case (cmd)
LOAD_MODE : begin
if (|odt_pipeline)
$display ("%m: at time %t ERROR: ODTL violation during %s", $time, cmd_string[cmd]);
if (odt_state)
$display ("%m: at time %t ERROR: ODT must be off prior to %s", $time, cmd_string[cmd]);
if (|active_bank) begin
$display ("%m: at time %t ERROR: %s Failure. All banks must be Precharged.", $time, cmd_string[cmd]);
if (STOP_ON_ERROR) $stop(0);
end else begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d", $time, cmd_string[cmd], bank);
if (bank>>2) begin
$display ("%m: at time %t ERROR: %s %d Illegal value. Reserved bank bits must be programmed to zero", $time, cmd_string[cmd], bank);
end
case (bank)
0 : begin
// Burst Length
if (addr[1:0] == 2'b00) begin
burst_length = 8;
blotf = 0;
truebl4 = 0;
if (DEBUG) $display ("%m: at time %t INFO: %s %d Burst Length = %d", $time, cmd_string[cmd], bank, burst_length);
end else if (addr[1:0] == 2'b01) begin
burst_length = 8;
blotf = 1;
truebl4 = 0;
if (DEBUG) $display ("%m: at time %t INFO: %s %d Burst Length = Select via A12", $time, cmd_string[cmd], bank);
end else if (addr[1:0] == 2'b10) begin
burst_length = 4;
blotf = 0;
truebl4 = 0;
if (DEBUG) $display ("%m: at time %t INFO: %s %d Burst Length = Fixed %d (chop)", $time, cmd_string[cmd], bank, burst_length);
end else if (feature_truebl4 && (addr[1:0] == 2'b11)) begin
burst_length = 4;
blotf = 0;
truebl4 = 1;
if (DEBUG) $display ("%m: at time %t INFO: %s %d Burst Length = True %d", $time, cmd_string[cmd], bank, burst_length);
end else begin
$display ("%m: at time %t ERROR: %s %d Illegal Burst Length = %d", $time, cmd_string[cmd], bank, addr[1:0]);
end
// Burst Order
burst_order = addr[3];
if (!burst_order) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Burst Order = Sequential", $time, cmd_string[cmd], bank);
end else if (burst_order) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Burst Order = Interleaved", $time, cmd_string[cmd], bank);
end else begin
$display ("%m: at time %t ERROR: %s %d Illegal Burst Order = %d", $time, cmd_string[cmd], bank, burst_order);
end
// CAS Latency
cas_latency = {addr[2],addr[6:4]} + 4;
set_latency;
if ((cas_latency >= CL_MIN) && (cas_latency <= CL_MAX)) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d CAS Latency = %d", $time, cmd_string[cmd], bank, cas_latency);
end else begin
$display ("%m: at time %t ERROR: %s %d Illegal CAS Latency = %d", $time, cmd_string[cmd], bank, cas_latency);
end
// Reserved
if (addr[7] !== 0 && check_strict_mrbits) begin
$display ("%m: at time %t ERROR: %s %d Illegal value. Reserved address bits must be programmed to zero", $time, cmd_string[cmd], bank);
end
// DLL Reset
dll_reset = addr[8];
if (!dll_reset) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d DLL Reset = Normal", $time, cmd_string[cmd], bank);
end else if (dll_reset) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d DLL Reset = Reset DLL", $time, cmd_string[cmd], bank);
dll_locked = 0;
init_dll_reset = 1;
ck_dll_reset <= ck_cntr;
end else begin
$display ("%m: at time %t ERROR: %s %d Illegal DLL Reset = %d", $time, cmd_string[cmd], bank, dll_reset);
end
// Write Recovery
if (addr[11:9] == 0) begin
write_recovery = 16;
end else if (addr[11:9] < 4) begin
write_recovery = addr[11:9] + 4;
end else begin
write_recovery = 2*addr[11:9];
end
if ((write_recovery >= WR_MIN) && (write_recovery <= WR_MAX)) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Write Recovery = %d", $time, cmd_string[cmd], bank, write_recovery);
end else begin
$display ("%m: at time %t ERROR: %s %d Illegal Write Recovery = %d", $time, cmd_string[cmd], bank, write_recovery);
end
// Power Down Mode
low_power = !addr[12];
if (!low_power) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Power Down Mode = DLL on", $time, cmd_string[cmd], bank);
end else if (low_power) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Power Down Mode = DLL off", $time, cmd_string[cmd], bank);
end else begin
$display ("%m: at time %t ERROR: %s %d Illegal Power Down Mode = %d", $time, cmd_string[cmd], bank, low_power);
end
// Reserved
if (ADDR_BITS>13 && addr[13] !== 0 && check_strict_mrbits) begin
$display ("%m: at time %t ERROR: %s %d Illegal value. Reserved address bits must be programmed to zero", $time, cmd_string[cmd], bank);
end
end
1 : begin
// DLL Enable
dll_en = !addr[0];
if (!dll_en) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d DLL Enable = Disabled", $time, cmd_string[cmd], bank);
if (check_strict_mrbits) $display ("%m: at time %t WARNING: %s %d DLL off mode is not modeled", $time, cmd_string[cmd], bank);
end else if (dll_en) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d DLL Enable = Enabled", $time, cmd_string[cmd], bank);
end else begin
$display ("%m: at time %t ERROR: %s %d Illegal DLL Enable = %d", $time, cmd_string[cmd], bank, dll_en);
end
// Output Drive Strength
if ({addr[5], addr[1]} == 2'b00) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Output Drive Strength = %d Ohm", $time, cmd_string[cmd], bank, RZQ/6);
end else if ({addr[5], addr[1]} == 2'b01) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Output Drive Strength = %d Ohm", $time, cmd_string[cmd], bank, RZQ/7);
end else if ({addr[5], addr[1]} == 2'b11) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Output Drive Strength = %d Ohm", $time, cmd_string[cmd], bank, RZQ/5);
end else begin
$display ("%m: at time %t ERROR: %s %d Illegal Output Drive Strength = %d", $time, cmd_string[cmd], bank, {addr[5], addr[1]});
end
// ODT Rtt (Rtt_NOM)
odt_rtt_nom = {addr[9], addr[6], addr[2]};
if (odt_rtt_nom == 3'b000) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d ODT Rtt = Disabled", $time, cmd_string[cmd], bank);
odt_en = 0;
end else if ((odt_rtt_nom < 4) || ((!addr[7] || (addr[7] && addr[12])) && (odt_rtt_nom < 6))) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d ODT Rtt = %d Ohm", $time, cmd_string[cmd], bank, get_rtt_nom(odt_rtt_nom));
odt_en = 1;
end else begin
$display ("%m: at time %t ERROR: %s %d Illegal ODT Rtt = %d", $time, cmd_string[cmd], bank, odt_rtt_nom);
odt_en = 0;
end
// Report the additive latency value
al = addr[4:3];
set_latency;
if (al == 0) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Additive Latency = %d", $time, cmd_string[cmd], bank, al);
end else if ((al >= AL_MIN) && (al <= AL_MAX)) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Additive Latency = CL - %d", $time, cmd_string[cmd], bank, al);
end else begin
$display ("%m: at time %t ERROR: %s %d Illegal Additive Latency = %d", $time, cmd_string[cmd], bank, al);
end
// Write Levelization
write_levelization = addr[7];
if (!write_levelization) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Write Levelization = Disabled", $time, cmd_string[cmd], bank);
end else if (write_levelization) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Write Levelization = Enabled", $time, cmd_string[cmd], bank);
end else begin
$display ("%m: at time %t ERROR: %s %d Illegal Write Levelization = %d", $time, cmd_string[cmd], bank, write_levelization);
end
// Reserved
if (addr[8] !== 0 && check_strict_mrbits) begin
$display ("%m: at time %t ERROR: %s %d Illegal value. Reserved address bits must be programmed to zero", $time, cmd_string[cmd], bank);
end
// Reserved
if (addr[10] !== 0 && check_strict_mrbits) begin
$display ("%m: at time %t ERROR: %s %d Illegal value. Reserved address bits must be programmed to zero", $time, cmd_string[cmd], bank);
end
// TDQS Enable
tdqs_en = addr[11];
if (!tdqs_en) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d TDQS Enable = Disabled", $time, cmd_string[cmd], bank);
end else if (tdqs_en) begin
if (8 == DQ_BITS) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d TDQS Enable = Enabled", $time, cmd_string[cmd], bank);
end
else begin
$display ("%m: at time %t WARNING: %s %d Illegal TDQS Enable. TDQS only exists on a x8 part", $time, cmd_string[cmd], bank);
tdqs_en = 0;
end
end else begin
$display ("%m: at time %t ERROR: %s %d Illegal TDQS Enable = %d", $time, cmd_string[cmd], bank, tdqs_en);
end
// Output Enable
out_en = !addr[12];
if (!out_en) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Qoff = Disabled", $time, cmd_string[cmd], bank);
end else if (out_en) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Qoff = Enabled", $time, cmd_string[cmd], bank);
end else begin
$display ("%m: at time %t ERROR: %s %d Illegal Qoff = %d", $time, cmd_string[cmd], bank, out_en);
end
// Reserved
if (ADDR_BITS>13 && addr[13] !== 0 && check_strict_mrbits) begin
$display ("%m: at time %t ERROR: %s %d Illegal value. Reserved address bits must be programmed to zero", $time, cmd_string[cmd], bank);
end
end
2 : begin
if (feature_pasr) begin
// Partial Array Self Refresh
pasr = addr[2:0];
case (pasr)
3'b000 : if (DEBUG) $display ("%m: at time %t INFO: %s %d Partial Array Self Refresh = Bank 0-7", $time, cmd_string[cmd], bank);
3'b001 : if (DEBUG) $display ("%m: at time %t INFO: %s %d Partial Array Self Refresh = Bank 0-3", $time, cmd_string[cmd], bank);
3'b010 : if (DEBUG) $display ("%m: at time %t INFO: %s %d Partial Array Self Refresh = Bank 0-1", $time, cmd_string[cmd], bank);
3'b011 : if (DEBUG) $display ("%m: at time %t INFO: %s %d Partial Array Self Refresh = Bank 0", $time, cmd_string[cmd], bank);
3'b100 : if (DEBUG) $display ("%m: at time %t INFO: %s %d Partial Array Self Refresh = Bank 2-7", $time, cmd_string[cmd], bank);
3'b101 : if (DEBUG) $display ("%m: at time %t INFO: %s %d Partial Array Self Refresh = Bank 4-7", $time, cmd_string[cmd], bank);
3'b110 : if (DEBUG) $display ("%m: at time %t INFO: %s %d Partial Array Self Refresh = Bank 6-7", $time, cmd_string[cmd], bank);
3'b111 : if (DEBUG) $display ("%m: at time %t INFO: %s %d Partial Array Self Refresh = Bank 7", $time, cmd_string[cmd], bank);
default : $display ("%m: at time %t ERROR: %s %d Illegal Partial Array Self Refresh = %d", $time, cmd_string[cmd], bank, pasr);
endcase
end
else
if (addr[2:0] !== 0 && check_strict_mrbits) begin
$display ("%m: at time %t ERROR: %s %d Illegal value. Reserved address bits must be programmed to zero", $time, cmd_string[cmd], bank);
end
// CAS Write Latency
cas_write_latency = addr[5:3]+5;
set_latency;
if ((cas_write_latency >= CWL_MIN) && (cas_write_latency <= CWL_MAX)) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d CAS Write Latency = %d", $time, cmd_string[cmd], bank, cas_write_latency);
end else begin
$display ("%m: at time %t ERROR: %s %d Illegal CAS Write Latency = %d", $time, cmd_string[cmd], bank, cas_write_latency);
end
// Auto Self Refresh Method
asr = addr[6];
if (!asr) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Auto Self Refresh = Disabled", $time, cmd_string[cmd], bank);
end else if (asr) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Auto Self Refresh = Enabled", $time, cmd_string[cmd], bank);
if (check_strict_mrbits) $display ("%m: at time %t WARNING: %s %d Auto Self Refresh is not modeled", $time, cmd_string[cmd], bank);
end else begin
$display ("%m: at time %t ERROR: %s %d Illegal Auto Self Refresh = %d", $time, cmd_string[cmd], bank, asr);
end
// Self Refresh Temperature
srt = addr[7];
if (!srt) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Self Refresh Temperature = Normal", $time, cmd_string[cmd], bank);
end else if (srt) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Self Refresh Temperature = Extended", $time, cmd_string[cmd], bank);
if (check_strict_mrbits) $display ("%m: at time %t WARNING: %s %d Self Refresh Temperature is not modeled", $time, cmd_string[cmd], bank);
end else begin
$display ("%m: at time %t ERROR: %s %d Illegal Self Refresh Temperature = %d", $time, cmd_string[cmd], bank, srt);
end
if (asr && srt)
$display ("%m: at time %t ERROR: %s %d SRT must be set to 0 when ASR is enabled.", $time, cmd_string[cmd], bank);
// Reserved
if (addr[8] !== 0 && check_strict_mrbits) begin
$display ("%m: at time %t ERROR: %s %d Illegal value. Reserved address bits must be programmed to zero", $time, cmd_string[cmd], bank);
end
// Dynamic ODT (Rtt_WR)
odt_rtt_wr = addr[10:9];
if (odt_rtt_wr == 2'b00) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Dynamic ODT = Disabled", $time, cmd_string[cmd], bank);
dyn_odt_en = 0;
end else if ((odt_rtt_wr > 0) && (odt_rtt_wr < 3)) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d Dynamic ODT Rtt = %d Ohm", $time, cmd_string[cmd], bank, get_rtt_wr(odt_rtt_wr));
dyn_odt_en = 1;
end else begin
$display ("%m: at time %t ERROR: %s %d Illegal Dynamic ODT = %d", $time, cmd_string[cmd], bank, odt_rtt_wr);
dyn_odt_en = 0;
end
// Reserved
if (ADDR_BITS>13 && addr[13:11] !== 0 && check_strict_mrbits) begin
$display ("%m: at time %t ERROR: %s %d Illegal value. Reserved address bits must be programmed to zero", $time, cmd_string[cmd], bank);
end
end
3 : begin
mpr_select = addr[1:0];
// MultiPurpose Register Select
if (mpr_select == 2'b00) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d MultiPurpose Register Select = Pre-defined pattern", $time, cmd_string[cmd], bank);
end else begin
if (check_strict_mrbits) $display ("%m: at time %t ERROR: %s %d Illegal MultiPurpose Register Select = %d", $time, cmd_string[cmd], bank, mpr_select);
end
// MultiPurpose Register Enable
mpr_en = addr[2];
if (!mpr_en) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d MultiPurpose Register Enable = Disabled", $time, cmd_string[cmd], bank);
end else if (mpr_en) begin
if (DEBUG) $display ("%m: at time %t INFO: %s %d MultiPurpose Register Enable = Enabled", $time, cmd_string[cmd], bank);
end else begin
$display ("%m: at time %t ERROR: %s %d Illegal MultiPurpose Register Enable = %d", $time, cmd_string[cmd], bank, mpr_en);
end
// Reserved
if (ADDR_BITS>13 && addr[13:3] !== 0 && check_strict_mrbits) begin
$display ("%m: at time %t ERROR: %s %d Illegal value. Reserved address bits must be programmed to zero", $time, cmd_string[cmd], bank);
end
end
endcase
if (dyn_odt_en && write_levelization)
$display ("%m: at time %t ERROR: Dynamic ODT is not available during Write Leveling mode.", $time);
init_mode_reg[bank] = 1;
mode_reg[bank] = addr;
tm_load_mode <= $time;
ck_load_mode <= ck_cntr;
end
end
REFRESH : begin
if (mpr_en) begin
$display ("%m: at time %t ERROR: %s Failure. Multipurpose Register must be disabled.", $time, cmd_string[cmd]);
if (STOP_ON_ERROR) $stop(0);
end else if (|active_bank) begin
$display ("%m: at time %t ERROR: %s Failure. All banks must be Precharged.", $time, cmd_string[cmd]);
if (STOP_ON_ERROR) $stop(0);
end else begin
if (DEBUG) $display ("%m: at time %t INFO: %s", $time, cmd_string[cmd]);
er_trfc_max = 0;
ref_cntr = ref_cntr + 1;
tm_refresh <= $time;
ck_refresh <= ck_cntr;
end
end
PRECHARGE : begin
if (addr[AP]) begin
if (DEBUG) $display ("%m: at time %t INFO: %s All", $time, cmd_string[cmd]);
end
// PRECHARGE command will be treated as a NOP if there is no open row in that bank (idle state),
// or if the previously open row is already in the process of precharging
if (|active_bank) begin
if (($time - tm_txpr < TXPR) || (ck_cntr - ck_txpr < TXPR_TCK))
$display ("%m: at time %t ERROR: tXPR violation during %s", $time, cmd_string[cmd]);
if (mpr_en) begin
$display ("%m: at time %t ERROR: %s Failure. Multipurpose Register must be disabled.", $time, cmd_string[cmd]);
if (STOP_ON_ERROR) $stop(0);
end else begin
for (i=0; i<`BANKS; i=i+1) begin
if (active_bank[i]) begin
if (addr[AP] || (i == bank)) begin
for (j=0; j<=SELF_REF; j=j+1) begin
chk_err(SAME_BANK, i, j, cmd);
chk_err(DIFF_BANK, i, j, cmd);
end
if (auto_precharge_bank[i]) begin
$display ("%m: at time %t ERROR: %s Failure. Auto Precharge is scheduled to bank %d.", $time, cmd_string[cmd], i);
if (STOP_ON_ERROR) $stop(0);
end else begin
if (DEBUG) $display ("%m: at time %t INFO: %s bank %d", $time, cmd_string[cmd], i);
active_bank[i] = 1'b0;
tm_bank_precharge[i] <= $time;
tm_precharge <= $time;
ck_precharge <= ck_cntr;
end
end
end
end
end
end
end
ACTIVATE : begin
tfaw_cntr = 0;
for (i=0; i<`BANKS; i=i+1) begin
if ($time - tm_bank_activate[i] < TFAW) begin
tfaw_cntr = tfaw_cntr + 1;
end
end
if (tfaw_cntr > 3) begin
$display ("%m: at time %t ERROR: tFAW violation during %s to bank %d", $time, cmd_string[cmd], bank);
end
if (mpr_en) begin
$display ("%m: at time %t ERROR: %s Failure. Multipurpose Register must be disabled.", $time, cmd_string[cmd]);
if (STOP_ON_ERROR) $stop(0);
end else if (!init_done) begin
$display ("%m: at time %t ERROR: %s Failure. Initialization sequence is not complete.", $time, cmd_string[cmd]);
if (STOP_ON_ERROR) $stop(0);
end else if (active_bank[bank]) begin
$display ("%m: at time %t ERROR: %s Failure. Bank %d must be Precharged.", $time, cmd_string[cmd], bank);
if (STOP_ON_ERROR) $stop(0);
end else begin
if (addr >= 1<<ROW_BITS) begin
$display ("%m: at time %t WARNING: row = %h does not exist. Maximum row = %h", $time, addr, (1<<ROW_BITS)-1);
end
if (DEBUG) $display ("%m: at time %t INFO: %s bank %d row %h", $time, cmd_string[cmd], bank, addr);
active_bank[bank] = 1'b1;
active_row[bank] = addr;
tm_group_activate[bank[1]] <= $time;
tm_activate <= $time;
tm_bank_activate[bank] <= $time;
ck_group_activate[bank[1]] <= ck_cntr;
ck_activate <= ck_cntr;
end
end
WRITE : begin
if ((!rd_bc && blotf) || (burst_length == 4)) begin // BL=4
if (truebl4) begin
if (ck_cntr - ck_group_read[bank[1]] < read_latency + TCCD/2 + 2 - write_latency)
$display ("%m: at time %t ERROR: tRTW violation during %s to bank %d", $time, cmd_string[cmd], bank);
if (ck_cntr - ck_read < read_latency + TCCD_DG/2 + 2 - write_latency)
$display ("%m: at time %t ERROR: tRTW_DG violation during %s to bank %d", $time, cmd_string[cmd], bank);
end else begin
if (ck_cntr - ck_read < read_latency + TCCD/2 + 2 - write_latency)
$display ("%m: at time %t ERROR: tRTW violation during %s to bank %d", $time, cmd_string[cmd], bank);
end
end else begin // BL=8
if (ck_cntr - ck_read < read_latency + TCCD + 2 - write_latency)
$display ("%m: at time %t ERROR: tRTW violation during %s to bank %d", $time, cmd_string[cmd], bank);
end
if (mpr_en) begin
$display ("%m: at time %t ERROR: %s Failure. Multipurpose Register must be disabled.", $time, cmd_string[cmd]);
if (STOP_ON_ERROR) $stop(0);
end else if (!init_done) begin
$display ("%m: at time %t ERROR: %s Failure. Initialization sequence is not complete.", $time, cmd_string[cmd]);
if (STOP_ON_ERROR) $stop(0);
end else if (!active_bank[bank]) begin
if (check_strict_timing) $display ("%m: at time %t ERROR: %s Failure. Bank %d must be Activated.", $time, cmd_string[cmd], bank);
if (STOP_ON_ERROR) $stop(0);
end else if (auto_precharge_bank[bank]) begin
$display ("%m: at time %t ERROR: %s Failure. Auto Precharge is scheduled to bank %d.", $time, cmd_string[cmd], bank);
if (STOP_ON_ERROR) $stop(0);
end else if (ck_cntr - ck_write < burst_length/2) begin
$display ("%m: at time %t ERROR: %s Failure. Illegal burst interruption.", $time, cmd_string[cmd]);
if (STOP_ON_ERROR) $stop(0);
end else begin
if (addr[AP]) begin
auto_precharge_bank[bank] = 1'b1;
write_precharge_bank[bank] = 1'b1;
end
col = {addr[BC-1:AP+1], addr[AP-1:0]}; // assume BC > AP
if (col >= 1<<COL_BITS) begin
$display ("%m: at time %t WARNING: col = %h does not exist. Maximum col = %h", $time, col, (1<<COL_BITS)-1);
end
if ((!addr[BC] && blotf) || (burst_length == 4)) begin // BL=4
col = col & -4;
end else begin // BL=8
col = col & -8;
end
if (DEBUG) $display ("%m: at time %t INFO: %s bank %d col %h, auto precharge %d", $time, cmd_string[cmd], bank, col, addr[AP]);
wr_pipeline[2*write_latency + 1] = 1;
ba_pipeline[2*write_latency + 1] = bank;
row_pipeline[2*write_latency + 1] = active_row[bank];
col_pipeline[2*write_latency + 1] = col;
if ((!addr[BC] && blotf) || (burst_length == 4)) begin // BL=4
bl_pipeline[2*write_latency + 1] = 4;
if (mpr_en && col%4) begin
$display ("%m: at time %t WARNING: col[1:0] must be set to 2'b00 during a BL4 Multipurpose Register read", $time);
end
end else begin // BL=8
bl_pipeline[2*write_latency + 1] = 8;
if (odt_in) begin
ck_odth8 <= ck_cntr;
end
end
for (j=0; j<(burst_length + 4); j=j+1) begin
dyn_odt_pipeline[2*(write_latency - 2) + j] = 1'b1; // ODTLcnw = WL - 2, ODTLcwn = BL/2 + 2
end
ck_bank_write[bank] <= ck_cntr;
ck_group_write[bank[1]] <= ck_cntr;
ck_write <= ck_cntr;
end
end
READ : begin
if (!dll_locked)
$display ("%m: at time %t WARNING: tDLLK violation during %s.", $time, cmd_string[cmd]);
if (mpr_en && (addr[1:0] != 2'b00)) begin
$display ("%m: at time %t ERROR: %s Failure. addr[1:0] must be zero during Multipurpose Register Read.", $time, cmd_string[cmd]);
if (STOP_ON_ERROR) $stop(0);
end else if (!init_done) begin
$display ("%m: at time %t ERROR: %s Failure. Initialization sequence is not complete.", $time, cmd_string[cmd]);
if (STOP_ON_ERROR) $stop(0);
end else if (!active_bank[bank] && !mpr_en) begin
if (check_strict_timing) $display ("%m: at time %t ERROR: %s Failure. Bank %d must be Activated.", $time, cmd_string[cmd], bank);
if (STOP_ON_ERROR) $stop(0);
end else if (auto_precharge_bank[bank]) begin
$display ("%m: at time %t ERROR: %s Failure. Auto Precharge is scheduled to bank %d.", $time, cmd_string[cmd], bank);
if (STOP_ON_ERROR) $stop(0);
end else if (ck_cntr - ck_read < burst_length/2) begin
$display ("%m: at time %t ERROR: %s Failure. Illegal burst interruption.", $time, cmd_string[cmd]);
if (STOP_ON_ERROR) $stop(0);
end else begin
if (addr[AP] && !mpr_en) begin
auto_precharge_bank[bank] = 1'b1;
read_precharge_bank[bank] = 1'b1;
end
col = {addr[BC-1:AP+1], addr[AP-1:0]}; // assume BC > AP
if (col >= 1<<COL_BITS) begin
$display ("%m: at time %t WARNING: col = %h does not exist. Maximum col = %h", $time, col, (1<<COL_BITS)-1);
end
if (DEBUG) $display ("%m: at time %t INFO: %s bank %d col %h, auto precharge %d", $time, cmd_string[cmd], bank, col, addr[AP]);
rd_pipeline[2*read_latency - 1] = 1;
ba_pipeline[2*read_latency - 1] = bank;
row_pipeline[2*read_latency - 1] = active_row[bank];
col_pipeline[2*read_latency - 1] = col;
if ((!addr[BC] && blotf) || (burst_length == 4)) begin // BL=4
bl_pipeline[2*read_latency - 1] = 4;
if (mpr_en && col%4) begin
$display ("%m: at time %t WARNING: col[1:0] must be set to 2'b00 during a BL4 Multipurpose Register read", $time);
end
end else begin // BL=8
bl_pipeline[2*read_latency - 1] = 8;
if (mpr_en && col%8) begin
$display ("%m: at time %t WARNING: col[2:0] must be set to 3'b000 during a BL8 Multipurpose Register read", $time);
end
end
rd_bc = addr[BC];
ck_bank_read[bank] <= ck_cntr;
ck_group_read[bank[1]] <= ck_cntr;
ck_read <= ck_cntr;
end
end
ZQ : begin
if (mpr_en) begin
$display ("%m: at time %t ERROR: %s Failure. Multipurpose Register must be disabled.", $time, cmd_string[cmd]);
if (STOP_ON_ERROR) $stop(0);
end else if (|active_bank) begin
$display ("%m: at time %t ERROR: %s Failure. All banks must be Precharged.", $time, cmd_string[cmd]);
if (STOP_ON_ERROR) $stop(0);
end else begin
if (DEBUG) $display ("%m: at time %t INFO: %s long = %d", $time, cmd_string[cmd], addr[AP]);
if (addr[AP]) begin
zq_set = 1;
if (init_done) begin
ck_zqoper <= ck_cntr;
end else begin
ck_zqinit <= ck_cntr;
end
end else begin
ck_zqcs <= ck_cntr;
end
end
end
NOP: begin
if (in_power_down) begin
if (($time - tm_freq_change < TCKSRX) || (ck_cntr - ck_freq_change < TCKSRX_TCK))
$display ("%m: at time %t ERROR: tCKSRX violation during Power Down Exit", $time);
if ($time - tm_cke_cmd > TPD_MAX)
$display ("%m: at time %t ERROR: tPD maximum violation during Power Down Exit", $time);
if (DEBUG) $display ("%m: at time %t INFO: Power Down Exit", $time);
in_power_down = 0;
if ((active_bank == 0) && low_power) begin // precharge power down with dll off
if (ck_cntr - ck_odt < write_latency - 1)
$display ("%m: at time %t WARNING: tANPD violation during Power Down Exit. Synchronous or asynchronous change in termination resistance is possible.", $time);
tm_slow_exit_pd <= $time;
ck_slow_exit_pd <= ck_cntr;
end
tm_power_down <= $time;
ck_power_down <= ck_cntr;
end
if (in_self_refresh) begin
if (($time - tm_freq_change < TCKSRX) || (ck_cntr - ck_freq_change < TCKSRX_TCK))
$display ("%m: at time %t ERROR: tCKSRX violation during Self Refresh Exit", $time);
if (ck_cntr - ck_cke_cmd < TCKESR_TCK)
$display ("%m: at time %t ERROR: tCKESR violation during Self Refresh Exit", $time);
if ($time - tm_cke < TISXR)
$display ("%m: at time %t ERROR: tISXR violation during Self Refresh Exit", $time);
if (DEBUG) $display ("%m: at time %t INFO: Self Refresh Exit", $time);
in_self_refresh = 0;
ck_dll_reset <= ck_cntr;
ck_self_refresh <= ck_cntr;
tm_self_refresh <= $time;
tm_refresh <= $time;
end
end
endcase
if ((prev_cke !== 1) && (cmd !== NOP)) begin
$display ("%m: at time %t ERROR: NOP or Deselect is required when CKE goes active.", $time);
end
if (!init_done) begin
case (init_step)
0 : begin
if ($time - tm_rst_n < 500000000 && check_strict_timing)
$display ("%m at time %t WARNING: 500 us is required after RST_N goes inactive before CKE goes active.", $time);
tm_txpr <= $time;
ck_txpr <= ck_cntr;
init_step = init_step + 1;
end
1 : if (dll_en) init_step = init_step + 1;
2 : begin
if (&init_mode_reg && init_dll_reset && zq_set) begin
if (DEBUG) $display ("%m: at time %t INFO: Initialization Sequence is complete", $time);
init_done = 1;
end
end
endcase
end
end else if (prev_cke) begin
if ((!init_done) && (init_step > 1)) begin
$display ("%m: at time %t ERROR: CKE must remain active until the initialization sequence is complete.", $time);
if (STOP_ON_ERROR) $stop(0);
end
case (cmd)
REFRESH : begin
if ($time - tm_txpr < TXPR)
$display ("%m: at time %t ERROR: tXPR violation during %s", $time, cmd_string[SELF_REF]);
for (j=0; j<=SELF_REF; j=j+1) begin
chk_err(DIFF_BANK, bank, j, SELF_REF);
end
if (mpr_en) begin
$display ("%m: at time %t ERROR: Self Refresh Failure. Multipurpose Register must be disabled.", $time);
if (STOP_ON_ERROR) $stop(0);
end else if (|active_bank) begin
$display ("%m: at time %t ERROR: Self Refresh Failure. All banks must be Precharged.", $time);
if (STOP_ON_ERROR) $stop(0);
end else if (odt_state) begin
$display ("%m: at time %t ERROR: Self Refresh Failure. ODT must be off prior to entering Self Refresh", $time);
if (STOP_ON_ERROR) $stop(0);
end else if (!init_done) begin
$display ("%m: at time %t ERROR: Self Refresh Failure. Initialization sequence is not complete.", $time);
if (STOP_ON_ERROR) $stop(0);
end else begin
if (DEBUG) $display ("%m: at time %t INFO: Self Refresh Enter", $time);
if (feature_pasr)
// Partial Array Self Refresh
case (pasr)
3'b000 : ;//keep Bank 0-7
3'b001 : begin if (DEBUG) $display("%m: at time %t INFO: Banks 4-7 will be lost due to Partial Array Self Refresh", $time); erase_banks(8'hF0); end
3'b010 : begin if (DEBUG) $display("%m: at time %t INFO: Banks 2-7 will be lost due to Partial Array Self Refresh", $time); erase_banks(8'hFC); end
3'b011 : begin if (DEBUG) $display("%m: at time %t INFO: Banks 1-7 will be lost due to Partial Array Self Refresh", $time); erase_banks(8'hFE); end
3'b100 : begin if (DEBUG) $display("%m: at time %t INFO: Banks 0-1 will be lost due to Partial Array Self Refresh", $time); erase_banks(8'h03); end
3'b101 : begin if (DEBUG) $display("%m: at time %t INFO: Banks 0-3 will be lost due to Partial Array Self Refresh", $time); erase_banks(8'h0F); end
3'b110 : begin if (DEBUG) $display("%m: at time %t INFO: Banks 0-5 will be lost due to Partial Array Self Refresh", $time); erase_banks(8'h3F); end
3'b111 : begin if (DEBUG) $display("%m: at time %t INFO: Banks 0-6 will be lost due to Partial Array Self Refresh", $time); erase_banks(8'h7F); end
endcase
in_self_refresh = 1;
dll_locked = 0;
end
end
NOP : begin
// entering precharge power down with dll off and tANPD has not been satisfied
if (low_power && (active_bank == 0) && |odt_pipeline)
$display ("%m: at time %t WARNING: tANPD violation during %s. Synchronous or asynchronous change in termination resistance is possible.", $time, cmd_string[PWR_DOWN]);
if ($time - tm_txpr < TXPR)
$display ("%m: at time %t ERROR: tXPR violation during %s", $time, cmd_string[PWR_DOWN]);
for (j=0; j<=SELF_REF; j=j+1) begin
chk_err(DIFF_BANK, bank, j, PWR_DOWN);
end
if (mpr_en) begin
$display ("%m: at time %t ERROR: Power Down Failure. Multipurpose Register must be disabled.", $time);
if (STOP_ON_ERROR) $stop(0);
end else if (!init_done) begin
$display ("%m: at time %t ERROR: Power Down Failure. Initialization sequence is not complete.", $time);
if (STOP_ON_ERROR) $stop(0);
end else begin
if (DEBUG) begin
if (|active_bank) begin
$display ("%m: at time %t INFO: Active Power Down Enter", $time);
end else begin
$display ("%m: at time %t INFO: Precharge Power Down Enter", $time);
end
end
in_power_down = 1;
end
end
default : begin
$display ("%m: at time %t ERROR: NOP, Deselect, or Refresh is required when CKE goes inactive.", $time);
end
endcase
end else if (in_self_refresh || in_power_down) begin
if ((ck_cntr - ck_cke_cmd <= TCPDED) && (cmd !== NOP))
$display ("%m: at time %t ERROR: tCPDED violation during Power Down or Self Refresh Entry. NOP or Deselect is required.", $time);
end
prev_cke = cke;
end
endtask
task data_task;
reg [BA_BITS-1:0] bank;
reg [ROW_BITS-1:0] row;
reg [COL_BITS-1:0] col;
integer i;
integer j;
begin
if (diff_ck) begin
for (i=0; i<32; i=i+1) begin
if (dq_in_valid && dll_locked && ($time - tm_dqs_neg[i] < $rtoi(TDSS*tck_avg)))
$display ("%m: at time %t ERROR: tDSS violation on %s bit %d", $time, dqs_string[i/16], i%16);
if (check_write_dqs_high[i])
$display ("%m: at time %t ERROR: %s bit %d latching edge required during the preceding clock period.", $time, dqs_string[i/16], i%16);
end
check_write_dqs_high <= 0;
end else begin
for (i=0; i<32; i=i+1) begin
if (dll_locked && dq_in_valid) begin
tm_tdqss = abs_value(1.0*tm_ck_pos - tm_dqss_pos[i]);
if ((tm_tdqss < tck_avg/2.0) && (tm_tdqss > TDQSS*tck_avg))
$display ("%m: at time %t ERROR: tDQSS violation on %s bit %d", $time, dqs_string[i/16], i%16);
end
if (check_write_dqs_low[i])
$display ("%m: at time %t ERROR: %s bit %d latching edge required during the preceding clock period", $time, dqs_string[i/16], i%16);
end
check_write_preamble <= 0;
check_write_postamble <= 0;
check_write_dqs_low <= 0;
end
if (wr_pipeline[0] || rd_pipeline[0]) begin
bank = ba_pipeline[0];
row = row_pipeline[0];
col = col_pipeline[0];
burst_cntr = 0;
memory_read(bank, row, col, memory_data);
end
// burst counter
if (burst_cntr < burst_length) begin
burst_position = col ^ burst_cntr;
if (!burst_order) begin
burst_position[BO_BITS-1:0] = col + burst_cntr;
end
burst_cntr = burst_cntr + 1;
end
// write dqs counter
if (wr_pipeline[WDQS_PRE + 1]) begin
wdqs_cntr = WDQS_PRE + bl_pipeline[WDQS_PRE + 1] + WDQS_PST - 1;
end
// write dqs
if ((wr_pipeline[2]) && (wdq_cntr == 0)) begin //write preamble
check_write_preamble <= ({DQS_BITS{1'b1}}<<16) | {DQS_BITS{1'b1}};
end
if (wdqs_cntr > 1) begin // write data
if ((wdqs_cntr - WDQS_PST)%2) begin
check_write_dqs_high <= ({DQS_BITS{1'b1}}<<16) | {DQS_BITS{1'b1}};
end else begin
check_write_dqs_low <= ({DQS_BITS{1'b1}}<<16) | {DQS_BITS{1'b1}};
end
end
if (wdqs_cntr == WDQS_PST) begin // write postamble
check_write_postamble <= ({DQS_BITS{1'b1}}<<16) | {DQS_BITS{1'b1}};
end
if (wdqs_cntr > 0) begin
wdqs_cntr = wdqs_cntr - 1;
end
// write dq
if (dq_in_valid) begin // write data
bit_mask = 0;
if (diff_ck) begin
for (i=0; i<DM_BITS; i=i+1) begin
bit_mask = bit_mask | ({`DQ_PER_DQS{~dm_in_neg[i]}}<<(burst_position*DQ_BITS + i*`DQ_PER_DQS));
end
memory_data = (dq_in_neg<<(burst_position*DQ_BITS) & bit_mask) | (memory_data & ~bit_mask);
end else begin
for (i=0; i<DM_BITS; i=i+1) begin
bit_mask = bit_mask | ({`DQ_PER_DQS{~dm_in_pos[i]}}<<(burst_position*DQ_BITS + i*`DQ_PER_DQS));
end
memory_data = (dq_in_pos<<(burst_position*DQ_BITS) & bit_mask) | (memory_data & ~bit_mask);
end
dq_temp = memory_data>>(burst_position*DQ_BITS);
if (DEBUG) $display ("%m: at time %t INFO: WRITE @ DQS= bank = %h row = %h col = %h data = %h",$time, bank, row, (-1*BL_MAX & col) + burst_position, dq_temp);
if (burst_cntr%BL_MIN == 0) begin
memory_write(bank, row, col, memory_data);
end
end
if (wr_pipeline[1]) begin
wdq_cntr = bl_pipeline[1];
end
if (wdq_cntr > 0) begin
wdq_cntr = wdq_cntr - 1;
dq_in_valid = 1'b1;
end else begin
dq_in_valid = 1'b0;
dqs_in_valid <= 1'b0;
for (i=0; i<31; i=i+1) begin
wdqs_pos_cntr[i] <= 0;
end
end
if (wr_pipeline[0]) begin
b2b_write <= 1'b0;
end
if (wr_pipeline[2]) begin
if (dqs_in_valid) begin
b2b_write <= 1'b1;
end
dqs_in_valid <= 1'b1;
wr_burst_length = bl_pipeline[2];
end
// read dqs enable counter
if (rd_pipeline[RDQSEN_PRE]) begin
rdqsen_cntr = RDQSEN_PRE + bl_pipeline[RDQSEN_PRE] + RDQSEN_PST - 1;
end
if (rdqsen_cntr > 0) begin
rdqsen_cntr = rdqsen_cntr - 1;
dqs_out_en = 1'b1;
end else begin
dqs_out_en = 1'b0;
end
// read dqs counter
if (rd_pipeline[RDQS_PRE]) begin
rdqs_cntr = RDQS_PRE + bl_pipeline[RDQS_PRE] + RDQS_PST - 1;
end
// read dqs
if (((rd_pipeline>>1 & {RDQS_PRE{1'b1}}) > 0) && (rdq_cntr == 0)) begin //read preamble
dqs_out = 1'b0;
end else if (rdqs_cntr > RDQS_PST) begin // read data
dqs_out = rdqs_cntr - RDQS_PST;
end else if (rdqs_cntr > 0) begin // read postamble
dqs_out = 1'b0;
end else begin
dqs_out = 1'b1;
end
if (rdqs_cntr > 0) begin
rdqs_cntr = rdqs_cntr - 1;
end
// read dq enable counter
if (rd_pipeline[RDQEN_PRE]) begin
rdqen_cntr = RDQEN_PRE + bl_pipeline[RDQEN_PRE] + RDQEN_PST;
end
if (rdqen_cntr > 0) begin
rdqen_cntr = rdqen_cntr - 1;
dq_out_en = 1'b1;
end else begin
dq_out_en = 1'b0;
end
// read dq
if (rd_pipeline[0]) begin
rdq_cntr = bl_pipeline[0];
end
if (rdq_cntr > 0) begin // read data
if (mpr_en) begin
`ifdef MPR_DQ0 // DQ0 output MPR data, other DQ low
if (mpr_select == 2'b00) begin // Calibration Pattern
dq_temp = {DQS_BITS{{`DQ_PER_DQS-1{1'b0}}, calibration_pattern[burst_position]}};
end else if (odts_readout && (mpr_select == 2'b11)) begin // Temp Sensor (ODTS)
dq_temp = {DQS_BITS{{`DQ_PER_DQS-1{1'b0}}, temp_sensor[burst_position]}};
end else begin // Reserved
dq_temp = {DQS_BITS{{`DQ_PER_DQS-1{1'b0}}, 1'bx}};
end
`else // all DQ output MPR data
if (mpr_select == 2'b00) begin // Calibration Pattern
dq_temp = {DQS_BITS{{`DQ_PER_DQS{calibration_pattern[burst_position]}}}};
end else if (odts_readout && (mpr_select == 2'b11)) begin // Temp Sensor (ODTS)
dq_temp = {DQS_BITS{{`DQ_PER_DQS{temp_sensor[burst_position]}}}};
end else begin // Reserved
dq_temp = {DQS_BITS{{`DQ_PER_DQS{1'bx}}}};
end
`endif
if (DEBUG) $display ("%m: at time %t READ @ DQS MultiPurpose Register %d, col = %d, data = %b", $time, mpr_select, burst_position, dq_temp[0]);
end else begin
dq_temp = memory_data>>(burst_position*DQ_BITS);
if (DEBUG) $display ("%m: at time %t INFO: READ @ DQS= bank = %h row = %h col = %h data = %h",$time, bank, row, (-1*BL_MAX & col) + burst_position, dq_temp);
end
dq_out = dq_temp;
rdq_cntr = rdq_cntr - 1;
end else begin
dq_out = {DQ_BITS{1'b1}};
end
// delay signals prior to output
if (RANDOM_OUT_DELAY && (dqs_out_en || (|dqs_out_en_dly) || dq_out_en || (|dq_out_en_dly))) begin
for (i=0; i<DQS_BITS; i=i+1) begin
// DQSCK requirements
// 1.) less than tDQSCK
// 2.) greater than -tDQSCK
// 3.) cannot change more than tQH + tDQSQ from previous DQS edge
dqsck_max = TDQSCK;
if (dqsck_max > dqsck[i] + TQH*tck_avg + TDQSQ) begin
dqsck_max = dqsck[i] + TQH*tck_avg + TDQSQ;
end
dqsck_min = -1*TDQSCK;
if (dqsck_min < dqsck[i] - TQH*tck_avg - TDQSQ) begin
dqsck_min = dqsck[i] - TQH*tck_avg - TDQSQ;
end
// DQSQ requirements
// 1.) less than tDQSQ
// 2.) greater than 0
// 3.) greater than tQH from the previous DQS edge
dqsq_min = 0;
if (dqsq_min < dqsck[i] - TQH*tck_avg) begin
dqsq_min = dqsck[i] - TQH*tck_avg;
end
if (dqsck_min == dqsck_max) begin
dqsck[i] = dqsck_min;
end else begin
dqsck[i] = $dist_uniform(seed, dqsck_min, dqsck_max);
end
dqsq_max = TDQSQ + dqsck[i];
dqs_out_en_dly[i] <= #(tck_avg/2) dqs_out_en;
dqs_out_dly[i] <= #(tck_avg/2 + dqsck[i]) dqs_out;
if (!write_levelization) begin
for (j=0; j<`DQ_PER_DQS; j=j+1) begin
dq_out_en_dly[i*`DQ_PER_DQS + j] <= #(tck_avg/2) dq_out_en;
if (dqsq_min == dqsq_max) begin
dq_out_dly [i*`DQ_PER_DQS + j] <= #(tck_avg/2 + dqsq_min) dq_out[i*`DQ_PER_DQS + j];
end else begin
dq_out_dly [i*`DQ_PER_DQS + j] <= #(tck_avg/2 + $dist_uniform(seed, dqsq_min, dqsq_max)) dq_out[i*`DQ_PER_DQS + j];
end
end
end
end
end else begin
out_delay = tck_avg/2;
dqs_out_en_dly <= #(out_delay) {DQS_BITS{dqs_out_en}};
dqs_out_dly <= #(out_delay) {DQS_BITS{dqs_out }};
if (write_levelization !== 1'b1) begin
dq_out_en_dly <= #(out_delay) {DQ_BITS {dq_out_en }};
dq_out_dly <= #(out_delay) {DQ_BITS {dq_out }};
end
end
end
endtask
always @ (posedge rst_n_in) begin : reset
integer i;
if (rst_n_in) begin
if ($time < 200000000 && check_strict_timing)
$display ("%m at time %t WARNING: 200 us is required before RST_N goes inactive.", $time);
if (cke_in !== 1'b0)
$display ("%m: at time %t ERROR: CKE must be inactive when RST_N goes inactive.", $time);
if ($time - tm_cke < 10000)
$display ("%m: at time %t ERROR: CKE must be maintained inactive for 10 ns before RST_N goes inactive.", $time);
// clear memory
`ifdef MAX_MEM
// verification group does not erase memory
// for (banki = 0; banki < `BANKS; banki = banki + 1) begin
// $fclose(memfd[banki]);
// memfd[banki] = open_bank_file(banki);
// end
`else
memory_used <= 0; //erase memory
`endif
end
end
always @(negedge rst_n_in or posedge diff_ck or negedge diff_ck) begin : main
integer i;
if (!rst_n_in) begin
reset_task;
end else begin
if (!in_self_refresh && (diff_ck !== 1'b0) && (diff_ck !== 1'b1))
$display ("%m: at time %t ERROR: CK and CK_N are not allowed to go to an unknown state.", $time);
data_task;
// Clock Frequency Change is legal:
// 1.) During Self Refresh
// 2.) During Precharge Power Down (DLL on or off)
if (in_self_refresh || (in_power_down && (active_bank == 0))) begin
if (diff_ck) begin
tjit_per_rtime = $time - tm_ck_pos - tck_avg;
end else begin
tjit_per_rtime = $time - tm_ck_neg - tck_avg;
end
if (dll_locked && (abs_value(tjit_per_rtime) > TJIT_PER)) begin
if ((tm_ck_pos - tm_cke_cmd < TCKSRE) || (ck_cntr - ck_cke_cmd < TCKSRE_TCK))
$display ("%m: at time %t ERROR: tCKSRE violation during Self Refresh or Precharge Power Down Entry", $time);
if (odt_state) begin
$display ("%m: at time %t ERROR: Clock Frequency Change Failure. ODT must be off prior to Clock Frequency Change.", $time);
if (STOP_ON_ERROR) $stop(0);
end else begin
if (DEBUG) $display ("%m: at time %t INFO: Clock Frequency Change detected. DLL Reset is Required.", $time);
tm_freq_change <= $time;
ck_freq_change <= ck_cntr;
dll_locked = 0;
end
end
end
if (diff_ck) begin
// check setup of command signals
if ($time > TIS) begin
if ($time - tm_cke < TIS)
$display ("%m: at time %t ERROR: tIS violation on CKE by %t", $time, tm_cke + TIS - $time);
if (cke_in) begin
for (i=0; i<22; i=i+1) begin
if ($time - tm_cmd_addr[i] < TIS)
$display ("%m: at time %t ERROR: tIS violation on %s by %t", $time, cmd_addr_string[i], tm_cmd_addr[i] + TIS - $time);
end
end
end
// update current state
if (dll_locked) begin
if (mr_chk == 0) begin
mr_chk = 1;
end else if (init_mode_reg[0] && (mr_chk == 1)) begin
// check CL value against the clock frequency
if (cas_latency*tck_avg < CL_TIME && check_strict_timing)
$display ("%m: at time %t ERROR: CAS Latency = %d is illegal @tCK(avg) = %f", $time, cas_latency, tck_avg);
// check WR value against the clock frequency
if (ceil(write_recovery*tck_avg) < TWR)
$display ("%m: at time %t ERROR: Write Recovery = %d is illegal @tCK(avg) = %f", $time, write_recovery, tck_avg);
// check the CWL value against the clock frequency
if (check_strict_timing) begin
case (cas_write_latency)
5 : if (tck_avg < 2500.0) $display ("%m: at time %t ERROR: CWL = %d is illegal @tCK(avg) = %f", $time, cas_write_latency, tck_avg);
6 : if ((tck_avg < 1875.0) || (tck_avg >= 2500.0)) $display ("%m: at time %t ERROR: CWL = %d is illegal @tCK(avg) = %f", $time, cas_write_latency, tck_avg);
7 : if ((tck_avg < 1500.0) || (tck_avg >= 1875.0)) $display ("%m: at time %t ERROR: CWL = %d is illegal @tCK(avg) = %f", $time, cas_write_latency, tck_avg);
8 : if ((tck_avg < 1250.0) || (tck_avg >= 1500.0)) $display ("%m: at time %t ERROR: CWL = %d is illegal @tCK(avg) = %f", $time, cas_write_latency, tck_avg);
9 : if ((tck_avg < 15e3/14) || (tck_avg >= 1250.0)) $display ("%m: at time %t ERROR: CWL = %d is illegal @tCK(avg) = %f", $time, cas_write_latency, tck_avg);
10: if ((tck_avg < 937.5) || (tck_avg >= 15e3/14)) $display ("%m: at time %t ERROR: CWL = %d is illegal @tCK(avg) = %f", $time, cas_write_latency, tck_avg);
default : $display ("%m: at time %t ERROR: CWL = %d is illegal @tCK(avg) = %f", $time, cas_write_latency, tck_avg);
endcase
// check the CL value against the clock frequency
if (!valid_cl(cas_latency, cas_write_latency))
$display ("%m: at time %t ERROR: CAS Latency = %d is not valid when CAS Write Latency = %d", $time, cas_latency, cas_write_latency);
end
mr_chk = 2;
end
end else if (!in_self_refresh) begin
mr_chk = 0;
if (ck_cntr - ck_dll_reset == TDLLK) begin
dll_locked = 1;
end
end
if (|auto_precharge_bank) begin
for (i=0; i<`BANKS; i=i+1) begin
// Write with Auto Precharge Calculation
// 1. Meet minimum tRAS requirement
// 2. Write Latency PLUS BL/2 cycles PLUS WR after Write command
if (write_precharge_bank[i]) begin
if ($time - tm_bank_activate[i] >= TRAS_MIN) begin
if (ck_cntr - ck_bank_write[i] >= write_latency + burst_length/2 + write_recovery) begin
if (DEBUG) $display ("%m: at time %t INFO: Auto Precharge bank %d", $time, i);
write_precharge_bank[i] = 0;
active_bank[i] = 0;
auto_precharge_bank[i] = 0;
tm_bank_precharge[i] = $time;
tm_precharge = $time;
ck_precharge = ck_cntr;
end
end
end
// Read with Auto Precharge Calculation
// 1. Meet minimum tRAS requirement
// 2. Additive Latency plus 4 cycles after Read command
// 3. tRTP after the last 8-bit prefetch
if (read_precharge_bank[i]) begin
if (($time - tm_bank_activate[i] >= TRAS_MIN) && (ck_cntr - ck_bank_read[i] >= additive_latency + TRTP_TCK)) begin
read_precharge_bank[i] = 0;
// In case the internal precharge is pushed out by tRTP, tRP starts at the point where
// the internal precharge happens (not at the next rising clock edge after this event).
if ($time - tm_bank_read_end[i] < TRTP) begin
if (DEBUG) $display ("%m: at time %t INFO: Auto Precharge bank %d", tm_bank_read_end[i] + TRTP, i);
active_bank[i] <= #(tm_bank_read_end[i] + TRTP - $time) 0;
auto_precharge_bank[i] <= #(tm_bank_read_end[i] + TRTP - $time) 0;
tm_bank_precharge[i] <= #(tm_bank_read_end[i] + TRTP - $time) tm_bank_read_end[i] + TRTP;
tm_precharge <= #(tm_bank_read_end[i] + TRTP - $time) tm_bank_read_end[i] + TRTP;
ck_precharge = ck_cntr;
end else begin
if (DEBUG) $display ("%m: at time %t INFO: Auto Precharge bank %d", $time, i);
active_bank[i] = 0;
auto_precharge_bank[i] = 0;
tm_bank_precharge[i] = $time;
tm_precharge = $time;
ck_precharge = ck_cntr;
end
end
end
end
end
// respond to incoming command
if (cke_in ^ prev_cke) begin
tm_cke_cmd <= $time;
ck_cke_cmd <= ck_cntr;
end
cmd_task(cke_in, cmd_n_in, ba_in, addr_in);
if ((cmd_n_in == WRITE) || (cmd_n_in == READ)) begin
al_pipeline[2*additive_latency] = 1'b1;
end
if (al_pipeline[0]) begin
// check tRCD after additive latency
if ((rd_pipeline[2*cas_latency - 1]) && ($time - tm_bank_activate[ba_pipeline[2*cas_latency - 1]] < TRCD))
$display ("%m: at time %t ERROR: tRCD violation during %s", $time, cmd_string[READ]);
if ((wr_pipeline[2*cas_write_latency + 1]) && ($time - tm_bank_activate[ba_pipeline[2*cas_write_latency + 1]] < TRCD))
$display ("%m: at time %t ERROR: tRCD violation during %s", $time, cmd_string[WRITE]);
// check tWTR after additive latency
if (rd_pipeline[2*cas_latency - 1]) begin //{
if (truebl4) begin //{
i = ba_pipeline[2*cas_latency - 1];
if ($time - tm_group_write_end[i[1]] < TWTR)
$display ("%m: at time %t ERROR: tWTR violation during %s", $time, cmd_string[READ]);
if ($time - tm_write_end < TWTR_DG)
$display ("%m: at time %t ERROR: tWTR_DG violation during %s", $time, cmd_string[READ]);
end else begin
if ($time - tm_write_end < TWTR)
$display ("%m: at time %t ERROR: tWTR violation during %s", $time, cmd_string[READ]);
end
end
end
if (rd_pipeline) begin
if (rd_pipeline[2*cas_latency - 1]) begin
tm_bank_read_end[ba_pipeline[2*cas_latency - 1]] <= $time;
end
end
for (i=0; i<`BANKS; i=i+1) begin
if ((ck_cntr - ck_bank_write[i] > write_latency) && (ck_cntr - ck_bank_write[i] <= write_latency + burst_length/2)) begin
tm_bank_write_end[i] <= $time;
tm_group_write_end[i[1]] <= $time;
tm_write_end <= $time;
end
end
// clk pin is disabled during self refresh
if (!in_self_refresh && tm_ck_pos ) begin
tjit_cc_time = $time - tm_ck_pos - tck_i;
tck_i = $time - tm_ck_pos;
tck_avg = tck_avg - tck_sample[ck_cntr%TDLLK]/$itor(TDLLK);
tck_avg = tck_avg + tck_i/$itor(TDLLK);
tck_sample[ck_cntr%TDLLK] = tck_i;
tjit_per_rtime = tck_i - tck_avg;
if (dll_locked && check_strict_timing) begin
// check accumulated error
terr_nper_rtime = 0;
for (i=0; i<12; i=i+1) begin
terr_nper_rtime = terr_nper_rtime + tck_sample[i] - tck_avg;
terr_nper_rtime = abs_value(terr_nper_rtime);
case (i)
0 :;
1 : if (terr_nper_rtime - TERR_2PER >= 1.0) $display ("%m: at time %t ERROR: tERR(2per) violation by %f ps.", $time, terr_nper_rtime - TERR_2PER);
2 : if (terr_nper_rtime - TERR_3PER >= 1.0) $display ("%m: at time %t ERROR: tERR(3per) violation by %f ps.", $time, terr_nper_rtime - TERR_3PER);
3 : if (terr_nper_rtime - TERR_4PER >= 1.0) $display ("%m: at time %t ERROR: tERR(4per) violation by %f ps.", $time, terr_nper_rtime - TERR_4PER);
4 : if (terr_nper_rtime - TERR_5PER >= 1.0) $display ("%m: at time %t ERROR: tERR(5per) violation by %f ps.", $time, terr_nper_rtime - TERR_5PER);
5 : if (terr_nper_rtime - TERR_6PER >= 1.0) $display ("%m: at time %t ERROR: tERR(6per) violation by %f ps.", $time, terr_nper_rtime - TERR_6PER);
6 : if (terr_nper_rtime - TERR_7PER >= 1.0) $display ("%m: at time %t ERROR: tERR(7per) violation by %f ps.", $time, terr_nper_rtime - TERR_7PER);
7 : if (terr_nper_rtime - TERR_8PER >= 1.0) $display ("%m: at time %t ERROR: tERR(8per) violation by %f ps.", $time, terr_nper_rtime - TERR_8PER);
8 : if (terr_nper_rtime - TERR_9PER >= 1.0) $display ("%m: at time %t ERROR: tERR(9per) violation by %f ps.", $time, terr_nper_rtime - TERR_9PER);
9 : if (terr_nper_rtime - TERR_10PER >= 1.0) $display ("%m: at time %t ERROR: tERR(10per) violation by %f ps.", $time, terr_nper_rtime - TERR_10PER);
10 : if (terr_nper_rtime - TERR_11PER >= 1.0) $display ("%m: at time %t ERROR: tERR(11per) violation by %f ps.", $time, terr_nper_rtime - TERR_11PER);
11 : if (terr_nper_rtime - TERR_12PER >= 1.0) $display ("%m: at time %t ERROR: tERR(12per) violation by %f ps.", $time, terr_nper_rtime - TERR_12PER);
endcase
end
// check tCK min/max/jitter
if (abs_value(tjit_per_rtime) - TJIT_PER >= 1.0)
$display ("%m: at time %t ERROR: tJIT(per) violation by %f ps.", $time, abs_value(tjit_per_rtime) - TJIT_PER);
if (abs_value(tjit_cc_time) - TJIT_CC >= 1.0)
$display ("%m: at time %t ERROR: tJIT(cc) violation by %f ps.", $time, abs_value(tjit_cc_time) - TJIT_CC);
if (TCK_MIN - tck_avg >= 1.0)
$display ("%m: at time %t ERROR: tCK(avg) minimum violation by %f ps.", $time, TCK_MIN - tck_avg);
if (tck_avg - TCK_MAX >= 1.0)
$display ("%m: at time %t ERROR: tCK(avg) maximum violation by %f ps.", $time, tck_avg - TCK_MAX);
// check tCL
if (tm_ck_neg - $time < TCL_ABS_MIN*tck_avg)
$display ("%m: at time %t ERROR: tCL(abs) minimum violation on CLK by %t", $time, TCL_ABS_MIN*tck_avg - tm_ck_neg + $time);
if (tcl_avg < TCL_AVG_MIN*tck_avg)
$display ("%m: at time %t ERROR: tCL(avg) minimum violation on CLK by %t", $time, TCL_AVG_MIN*tck_avg - tcl_avg);
if (tcl_avg > TCL_AVG_MAX*tck_avg)
$display ("%m: at time %t ERROR: tCL(avg) maximum violation on CLK by %t", $time, tcl_avg - TCL_AVG_MAX*tck_avg);
end
// calculate the tch avg jitter
tch_avg = tch_avg - tch_sample[ck_cntr%TDLLK]/$itor(TDLLK);
tch_avg = tch_avg + tch_i/$itor(TDLLK);
tch_sample[ck_cntr%TDLLK] = tch_i;
tjit_ch_rtime = tch_i - tch_avg;
duty_cycle = tch_avg/tck_avg;
// update timers/counters
tcl_i <= $time - tm_ck_neg;
end
prev_odt <= odt_in;
// update timers/counters
ck_cntr <= ck_cntr + 1;
tm_ck_pos = $time;
end else begin
// clk pin is disabled during self refresh
if (!in_self_refresh) begin
if (dll_locked && check_strict_timing) begin
if ($time - tm_ck_pos < TCH_ABS_MIN*tck_avg)
$display ("%m: at time %t ERROR: tCH(abs) minimum violation on CLK by %t", $time, TCH_ABS_MIN*tck_avg - $time + tm_ck_pos);
if (tch_avg < TCH_AVG_MIN*tck_avg)
$display ("%m: at time %t ERROR: tCH(avg) minimum violation on CLK by %t", $time, TCH_AVG_MIN*tck_avg - tch_avg);
if (tch_avg > TCH_AVG_MAX*tck_avg)
$display ("%m: at time %t ERROR: tCH(avg) maximum violation on CLK by %t", $time, tch_avg - TCH_AVG_MAX*tck_avg);
end
// calculate the tcl avg jitter
tcl_avg = tcl_avg - tcl_sample[ck_cntr%TDLLK]/$itor(TDLLK);
tcl_avg = tcl_avg + tcl_i/$itor(TDLLK);
tcl_sample[ck_cntr%TDLLK] = tcl_i;
// update timers/counters
tch_i <= $time - tm_ck_pos;
end
tm_ck_neg = $time;
end
// on die termination
if (odt_en || dyn_odt_en) begin
// odt pin is disabled during self refresh
if (!in_self_refresh && diff_ck) begin
if ($time - tm_odt < TIS)
$display ("%m: at time %t ERROR: tIS violation on ODT by %t", $time, tm_odt + TIS - $time);
if (prev_odt ^ odt_in) begin
if (!dll_locked)
$display ("%m: at time %t WARNING: tDLLK violation during ODT transition.", $time);
if (($time - tm_load_mode < TMOD) || (ck_cntr - ck_load_mode < TMOD_TCK))
$display ("%m: at time %t ERROR: tMOD violation during ODT transition", $time);
if (ck_cntr - ck_zqinit < TZQINIT)
$display ("%m: at time %t ERROR: TZQinit violation during ODT transition", $time);
if (ck_cntr - ck_zqoper < TZQOPER)
$display ("%m: at time %t ERROR: TZQoper violation during ODT transition", $time);
if (ck_cntr - ck_zqcs < TZQCS)
$display ("%m: at time %t ERROR: tZQcs violation during ODT transition", $time);
// if (($time - tm_slow_exit_pd < TXPDLL) || (ck_cntr - ck_slow_exit_pd < TXPDLL_TCK))
// $display ("%m: at time %t ERROR: tXPDLL violation during ODT transition", $time);
if (ck_cntr - ck_self_refresh < TXSDLL)
$display ("%m: at time %t ERROR: tXSDLL violation during ODT transition", $time);
if (in_self_refresh)
$display ("%m: at time %t ERROR: Illegal ODT transition during Self Refresh.", $time);
if (!odt_in && (ck_cntr - ck_odt < ODTH4))
$display ("%m: at time %t ERROR: ODTH4 violation during ODT transition", $time);
if (!odt_in && (ck_cntr - ck_odth8 < ODTH8))
$display ("%m: at time %t ERROR: ODTH8 violation during ODT transition", $time);
if (($time - tm_slow_exit_pd < TXPDLL) || (ck_cntr - ck_slow_exit_pd < TXPDLL_TCK))
$display ("%m: at time %t WARNING: tXPDLL during ODT transition. Synchronous or asynchronous change in termination resistance is possible.", $time);
// async ODT mode applies:
// 1.) during precharge power down with DLL off
// 2.) if tANPD has not been satisfied
// 3.) until tXPDLL has been satisfied
if ((in_power_down && low_power && (active_bank == 0)) || ($time - tm_slow_exit_pd < TXPDLL) || (ck_cntr - ck_slow_exit_pd < TXPDLL_TCK)) begin
odt_state = odt_in;
if (DEBUG && odt_en) $display ("%m: at time %t INFO: Async On Die Termination Rtt_NOM = %d Ohm", $time, {32{odt_state}} & get_rtt_nom(odt_rtt_nom));
if (odt_state) begin
odt_state_dly <= #(TAONPD) odt_state;
end else begin
odt_state_dly <= #(TAOFPD) odt_state;
end
// sync ODT mode applies:
// 1.) during normal operation
// 2.) during active power down
// 3.) during precharge power down with DLL on
end else begin
odt_pipeline[2*(write_latency - 2)] = 1'b1; // ODTLon, ODTLoff
end
ck_odt <= ck_cntr;
end
end
if (odt_pipeline[0]) begin
odt_state = ~odt_state;
if (DEBUG && odt_en) $display ("%m: at time %t INFO: Sync On Die Termination Rtt_NOM = %d Ohm", $time, {32{odt_state}} & get_rtt_nom(odt_rtt_nom));
if (odt_state) begin
odt_state_dly <= #(TAON) odt_state;
end else begin
odt_state_dly <= #(TAOF*tck_avg) odt_state;
end
end
if (rd_pipeline[RDQSEN_PRE]) begin
odt_cntr = 1 + RDQSEN_PRE + bl_pipeline[RDQSEN_PRE] + RDQSEN_PST - 1;
end
if (odt_cntr > 0) begin
if (odt_state) begin
$display ("%m: at time %t ERROR: On Die Termination must be OFF during Read data transfer.", $time);
end
odt_cntr = odt_cntr - 1;
end
if (dyn_odt_en && odt_state) begin
if (DEBUG && (dyn_odt_state ^ dyn_odt_pipeline[0]))
$display ("%m: at time %t INFO: Sync On Die Termination Rtt_WR = %d Ohm", $time, {32{dyn_odt_pipeline[0]}} & get_rtt_wr(odt_rtt_wr));
dyn_odt_state = dyn_odt_pipeline[0];
end
dyn_odt_state_dly <= #(TADC*tck_avg) dyn_odt_state;
end
if (cke_in && write_levelization) begin
for (i=0; i<DQS_BITS; i=i+1) begin
if ($time - tm_dqs_pos[i] < TWLH)
$display ("%m: at time %t WARNING: tWLH violation on DQS bit %d positive edge. Indeterminate CK capture is possible.", $time, i);
end
end
// shift pipelines
if (|wr_pipeline || |rd_pipeline || |al_pipeline) begin
al_pipeline = al_pipeline>>1;
wr_pipeline = wr_pipeline>>1;
rd_pipeline = rd_pipeline>>1;
for (i=0; i<`MAX_PIPE; i=i+1) begin
bl_pipeline[i] = bl_pipeline[i+1];
ba_pipeline[i] = ba_pipeline[i+1];
row_pipeline[i] = row_pipeline[i+1];
col_pipeline[i] = col_pipeline[i+1];
end
end
if (|odt_pipeline || |dyn_odt_pipeline) begin
odt_pipeline = odt_pipeline>>1;
dyn_odt_pipeline = dyn_odt_pipeline>>1;
end
end
end
// receiver(s)
task dqs_even_receiver;
input [3:0] i;
reg [63:0] bit_mask;
begin
bit_mask = {`DQ_PER_DQS{1'b1}}<<(i*`DQ_PER_DQS);
if (dqs_even[i]) begin
if (tdqs_en) begin // tdqs disables dm
dm_in_pos[i] = 1'b0;
end else begin
dm_in_pos[i] = dm_in[i];
end
dq_in_pos = (dq_in & bit_mask) | (dq_in_pos & ~bit_mask);
end
end
endtask
always @(posedge dqs_even[ 0]) dqs_even_receiver( 0);
always @(posedge dqs_even[ 1]) dqs_even_receiver( 1);
always @(posedge dqs_even[ 2]) dqs_even_receiver( 2);
always @(posedge dqs_even[ 3]) dqs_even_receiver( 3);
always @(posedge dqs_even[ 4]) dqs_even_receiver( 4);
always @(posedge dqs_even[ 5]) dqs_even_receiver( 5);
always @(posedge dqs_even[ 6]) dqs_even_receiver( 6);
always @(posedge dqs_even[ 7]) dqs_even_receiver( 7);
always @(posedge dqs_even[ 8]) dqs_even_receiver( 8);
always @(posedge dqs_even[ 9]) dqs_even_receiver( 9);
always @(posedge dqs_even[10]) dqs_even_receiver(10);
always @(posedge dqs_even[11]) dqs_even_receiver(11);
always @(posedge dqs_even[12]) dqs_even_receiver(12);
always @(posedge dqs_even[13]) dqs_even_receiver(13);
always @(posedge dqs_even[14]) dqs_even_receiver(14);
always @(posedge dqs_even[15]) dqs_even_receiver(15);
task dqs_odd_receiver;
input [3:0] i;
reg [63:0] bit_mask;
begin
bit_mask = {`DQ_PER_DQS{1'b1}}<<(i*`DQ_PER_DQS);
if (dqs_odd[i]) begin
if (tdqs_en) begin // tdqs disables dm
dm_in_neg[i] = 1'b0;
end else begin
dm_in_neg[i] = dm_in[i];
end
dq_in_neg = (dq_in & bit_mask) | (dq_in_neg & ~bit_mask);
end
end
endtask
always @(posedge dqs_odd[ 0]) dqs_odd_receiver( 0);
always @(posedge dqs_odd[ 1]) dqs_odd_receiver( 1);
always @(posedge dqs_odd[ 2]) dqs_odd_receiver( 2);
always @(posedge dqs_odd[ 3]) dqs_odd_receiver( 3);
always @(posedge dqs_odd[ 4]) dqs_odd_receiver( 4);
always @(posedge dqs_odd[ 5]) dqs_odd_receiver( 5);
always @(posedge dqs_odd[ 6]) dqs_odd_receiver( 6);
always @(posedge dqs_odd[ 7]) dqs_odd_receiver( 7);
always @(posedge dqs_odd[ 8]) dqs_odd_receiver( 8);
always @(posedge dqs_odd[ 9]) dqs_odd_receiver( 9);
always @(posedge dqs_odd[10]) dqs_odd_receiver(10);
always @(posedge dqs_odd[11]) dqs_odd_receiver(11);
always @(posedge dqs_odd[12]) dqs_odd_receiver(12);
always @(posedge dqs_odd[13]) dqs_odd_receiver(13);
always @(posedge dqs_odd[14]) dqs_odd_receiver(14);
always @(posedge dqs_odd[15]) dqs_odd_receiver(15);
// Processes to check hold and pulse width of control signals
always @(posedge rst_n_in) begin
if ($time > 100000) begin
if (tm_rst_n + 100000 > $time)
$display ("%m: at time %t ERROR: RST_N pulse width violation by %t", $time, tm_rst_n + 100000 - $time);
end
tm_rst_n = $time;
end
always @(cke_in) begin
if (rst_n_in) begin
if ($time > TIH) begin
if ($time - tm_ck_pos < TIH)
$display ("%m: at time %t ERROR: tIH violation on CKE by %t", $time, tm_ck_pos + TIH - $time);
end
if ($time - tm_cke < TIPW)
$display ("%m: at time %t ERROR: tIPW violation on CKE by %t", $time, tm_cke + TIPW - $time);
end
tm_cke = $time;
end
always @(odt_in) begin
if (rst_n_in && odt_en && !in_self_refresh) begin
if ($time - tm_ck_pos < TIH)
$display ("%m: at time %t ERROR: tIH violation on ODT by %t", $time, tm_ck_pos + TIH - $time);
if ($time - tm_odt < TIPW)
$display ("%m: at time %t ERROR: tIPW violation on ODT by %t", $time, tm_odt + TIPW - $time);
end
tm_odt = $time;
end
task cmd_addr_timing_check;
input i;
reg [4:0] i;
begin
if (rst_n_in && prev_cke) begin
if ((i == 0) && ($time - tm_ck_pos < TIH)) // always check tIH for CS#
$display ("%m: at time %t ERROR: tIH violation on %s by %t", $time, cmd_addr_string[i], tm_ck_pos + TIH - $time);
if ((i > 0) && (cs_n_in == 0) &&($time - tm_ck_pos < TIH)) // Only check tIH for cmd_addr if CS# is low
$display ("%m: at time %t ERROR: tIH violation on %s by %t", $time, cmd_addr_string[i], tm_ck_pos + TIH - $time);
if ($time - tm_cmd_addr[i] < TIPW)
$display ("%m: at time %t ERROR: tIPW violation on %s by %t", $time, cmd_addr_string[i], tm_cmd_addr[i] + TIPW - $time);
end
tm_cmd_addr[i] = $time;
end
endtask
always @(cs_n_in ) cmd_addr_timing_check( 0);
always @(ras_n_in ) cmd_addr_timing_check( 1);
always @(cas_n_in ) cmd_addr_timing_check( 2);
always @(we_n_in ) cmd_addr_timing_check( 3);
always @(ba_in [ 0]) cmd_addr_timing_check( 4);
always @(ba_in [ 1]) cmd_addr_timing_check( 5);
always @(ba_in [ 2]) cmd_addr_timing_check( 6);
always @(addr_in[ 0]) cmd_addr_timing_check( 7);
always @(addr_in[ 1]) cmd_addr_timing_check( 8);
always @(addr_in[ 2]) cmd_addr_timing_check( 9);
always @(addr_in[ 3]) cmd_addr_timing_check(10);
always @(addr_in[ 4]) cmd_addr_timing_check(11);
always @(addr_in[ 5]) cmd_addr_timing_check(12);
always @(addr_in[ 6]) cmd_addr_timing_check(13);
always @(addr_in[ 7]) cmd_addr_timing_check(14);
always @(addr_in[ 8]) cmd_addr_timing_check(15);
always @(addr_in[ 9]) cmd_addr_timing_check(16);
always @(addr_in[10]) cmd_addr_timing_check(17);
always @(addr_in[11]) cmd_addr_timing_check(18);
always @(addr_in[12]) cmd_addr_timing_check(19);
always @(addr_in[13]) cmd_addr_timing_check(20);
always @(addr_in[14]) cmd_addr_timing_check(21);
always @(addr_in[15]) cmd_addr_timing_check(22);
// Processes to check setup and hold of data signals
task dm_timing_check;
input i;
reg [3:0] i;
begin
if (dqs_in_valid) begin
if ($time - tm_dqs[i] < TDH)
$display ("%m: at time %t ERROR: tDH violation on DM bit %d by %t", $time, i, tm_dqs[i] + TDH - $time);
if (check_dm_tdipw[i]) begin
if ($time - tm_dm[i] < TDIPW)
$display ("%m: at time %t ERROR: tDIPW violation on DM bit %d by %t", $time, i, tm_dm[i] + TDIPW - $time);
end
end
check_dm_tdipw[i] <= 1'b0;
tm_dm[i] = $time;
end
endtask
always @(dm_in[ 0]) dm_timing_check( 0);
always @(dm_in[ 1]) dm_timing_check( 1);
always @(dm_in[ 2]) dm_timing_check( 2);
always @(dm_in[ 3]) dm_timing_check( 3);
always @(dm_in[ 4]) dm_timing_check( 4);
always @(dm_in[ 5]) dm_timing_check( 5);
always @(dm_in[ 6]) dm_timing_check( 6);
always @(dm_in[ 7]) dm_timing_check( 7);
always @(dm_in[ 8]) dm_timing_check( 8);
always @(dm_in[ 9]) dm_timing_check( 9);
always @(dm_in[10]) dm_timing_check(10);
always @(dm_in[11]) dm_timing_check(11);
always @(dm_in[12]) dm_timing_check(12);
always @(dm_in[13]) dm_timing_check(13);
always @(dm_in[14]) dm_timing_check(14);
always @(dm_in[15]) dm_timing_check(15);
task dq_timing_check;
input i;
reg [5:0] i;
begin
if (dqs_in_valid) begin
if ($time - tm_dqs[i/`DQ_PER_DQS] < TDH)
$display ("%m: at time %t ERROR: tDH violation on DQ bit %d by %t", $time, i, tm_dqs[i/`DQ_PER_DQS] + TDH - $time);
if (check_dq_tdipw[i]) begin
if ($time - tm_dq[i] < TDIPW)
$display ("%m: at time %t ERROR: tDIPW violation on DQ bit %d by %t", $time, i, tm_dq[i] + TDIPW - $time);
end
end
check_dq_tdipw[i] <= 1'b0;
tm_dq[i] = $time;
end
endtask
always @(dq_in[ 0]) dq_timing_check( 0);
always @(dq_in[ 1]) dq_timing_check( 1);
always @(dq_in[ 2]) dq_timing_check( 2);
always @(dq_in[ 3]) dq_timing_check( 3);
always @(dq_in[ 4]) dq_timing_check( 4);
always @(dq_in[ 5]) dq_timing_check( 5);
always @(dq_in[ 6]) dq_timing_check( 6);
always @(dq_in[ 7]) dq_timing_check( 7);
always @(dq_in[ 8]) dq_timing_check( 8);
always @(dq_in[ 9]) dq_timing_check( 9);
always @(dq_in[10]) dq_timing_check(10);
always @(dq_in[11]) dq_timing_check(11);
always @(dq_in[12]) dq_timing_check(12);
always @(dq_in[13]) dq_timing_check(13);
always @(dq_in[14]) dq_timing_check(14);
always @(dq_in[15]) dq_timing_check(15);
always @(dq_in[16]) dq_timing_check(16);
always @(dq_in[17]) dq_timing_check(17);
always @(dq_in[18]) dq_timing_check(18);
always @(dq_in[19]) dq_timing_check(19);
always @(dq_in[20]) dq_timing_check(20);
always @(dq_in[21]) dq_timing_check(21);
always @(dq_in[22]) dq_timing_check(22);
always @(dq_in[23]) dq_timing_check(23);
always @(dq_in[24]) dq_timing_check(24);
always @(dq_in[25]) dq_timing_check(25);
always @(dq_in[26]) dq_timing_check(26);
always @(dq_in[27]) dq_timing_check(27);
always @(dq_in[28]) dq_timing_check(28);
always @(dq_in[29]) dq_timing_check(29);
always @(dq_in[30]) dq_timing_check(30);
always @(dq_in[31]) dq_timing_check(31);
always @(dq_in[32]) dq_timing_check(32);
always @(dq_in[33]) dq_timing_check(33);
always @(dq_in[34]) dq_timing_check(34);
always @(dq_in[35]) dq_timing_check(35);
always @(dq_in[36]) dq_timing_check(36);
always @(dq_in[37]) dq_timing_check(37);
always @(dq_in[38]) dq_timing_check(38);
always @(dq_in[39]) dq_timing_check(39);
always @(dq_in[40]) dq_timing_check(40);
always @(dq_in[41]) dq_timing_check(41);
always @(dq_in[42]) dq_timing_check(42);
always @(dq_in[43]) dq_timing_check(43);
always @(dq_in[44]) dq_timing_check(44);
always @(dq_in[45]) dq_timing_check(45);
always @(dq_in[46]) dq_timing_check(46);
always @(dq_in[47]) dq_timing_check(47);
always @(dq_in[48]) dq_timing_check(48);
always @(dq_in[49]) dq_timing_check(49);
always @(dq_in[50]) dq_timing_check(50);
always @(dq_in[51]) dq_timing_check(51);
always @(dq_in[52]) dq_timing_check(52);
always @(dq_in[53]) dq_timing_check(53);
always @(dq_in[54]) dq_timing_check(54);
always @(dq_in[55]) dq_timing_check(55);
always @(dq_in[56]) dq_timing_check(56);
always @(dq_in[57]) dq_timing_check(57);
always @(dq_in[58]) dq_timing_check(58);
always @(dq_in[59]) dq_timing_check(59);
always @(dq_in[60]) dq_timing_check(60);
always @(dq_in[61]) dq_timing_check(61);
always @(dq_in[62]) dq_timing_check(62);
always @(dq_in[63]) dq_timing_check(63);
task dqs_pos_timing_check;
input i;
reg [4:0] i;
reg [3:0] j;
begin
if (write_levelization && i<16) begin
if (ck_cntr - ck_load_mode < TWLMRD)
$display ("%m: at time %t ERROR: tWLMRD violation on DQS bit %d positive edge.", $time, i);
if (($time - tm_ck_pos < TWLS) || ($time - tm_ck_neg < TWLS))
$display ("%m: at time %t WARNING: tWLS violation on DQS bit %d positive edge. Indeterminate CK capture is possible.", $time, i);
if (DEBUG)
$display ("%m: at time %t Write Leveling @ DQS ck = %b", $time, diff_ck);
dq_out_en_dly[i*`DQ_PER_DQS] <= #(TWLO) 1'b1;
dq_out_dly[i*`DQ_PER_DQS] <= #(TWLO) diff_ck;
for (j=1; j<`DQ_PER_DQS; j=j+1) begin
dq_out_en_dly[i*`DQ_PER_DQS+j] <= #(TWLO + TWLOE) 1'b1;
dq_out_dly[i*`DQ_PER_DQS+j] <= #(TWLO + TWLOE) 1'b0;
end
end
if (dqs_in_valid && ((wdqs_pos_cntr[i] < wr_burst_length/2) || b2b_write)) begin
if (dqs_in[i] ^ prev_dqs_in[i]) begin
if (dll_locked) begin
if (check_write_preamble[i]) begin
if ($time - tm_dqs_pos[i] < $rtoi(TWPRE*tck_avg))
$display ("%m: at time %t ERROR: tWPRE violation on &s bit %d", $time, dqs_string[i/16], i%16);
end else if (check_write_postamble[i]) begin
if ($time - tm_dqs_neg[i] < $rtoi(TWPST*tck_avg))
$display ("%m: at time %t ERROR: tWPST violation on %s bit %d", $time, dqs_string[i/16], i%16);
end else begin
if ($time - tm_dqs_neg[i] < $rtoi(TDQSL*tck_avg))
$display ("%m: at time %t ERROR: tDQSL violation on %s bit %d", $time, dqs_string[i/16], i%16);
end
end
if ($time - tm_dm[i%16] < TDS)
$display ("%m: at time %t ERROR: tDS violation on DM bit %d by %t", $time, i, tm_dm[i%16] + TDS - $time);
if (!dq_out_en) begin
for (j=0; j<`DQ_PER_DQS; j=j+1) begin
if ($time - tm_dq[(i%16)*`DQ_PER_DQS+j] < TDS)
$display ("%m: at time %t ERROR: tDS violation on DQ bit %d by %t", $time, i*`DQ_PER_DQS+j, tm_dq[(i%16)*`DQ_PER_DQS+j] + TDS - $time);
check_dq_tdipw[(i%16)*`DQ_PER_DQS+j] <= 1'b1;
end
end
if ((wdqs_pos_cntr[i] < wr_burst_length/2) && !b2b_write) begin
wdqs_pos_cntr[i] <= wdqs_pos_cntr[i] + 1;
end else begin
wdqs_pos_cntr[i] <= 1;
end
check_dm_tdipw[i%16] <= 1'b1;
check_write_preamble[i] <= 1'b0;
check_write_postamble[i] <= 1'b0;
check_write_dqs_low[i] <= 1'b0;
tm_dqs[i%16] <= $time;
end else begin
$display ("%m: at time %t ERROR: Invalid latching edge on %s bit %d", $time, dqs_string[i/16], i%16);
end
end
tm_dqss_pos[i] <= $time;
tm_dqs_pos[i] = $time;
prev_dqs_in[i] <= dqs_in[i];
end
endtask
always @(posedge dqs_in[ 0]) dqs_pos_timing_check( 0);
always @(posedge dqs_in[ 1]) dqs_pos_timing_check( 1);
always @(posedge dqs_in[ 2]) dqs_pos_timing_check( 2);
always @(posedge dqs_in[ 3]) dqs_pos_timing_check( 3);
always @(posedge dqs_in[ 4]) dqs_pos_timing_check( 4);
always @(posedge dqs_in[ 5]) dqs_pos_timing_check( 5);
always @(posedge dqs_in[ 6]) dqs_pos_timing_check( 6);
always @(posedge dqs_in[ 7]) dqs_pos_timing_check( 7);
always @(posedge dqs_in[ 8]) dqs_pos_timing_check( 8);
always @(posedge dqs_in[ 9]) dqs_pos_timing_check( 9);
always @(posedge dqs_in[10]) dqs_pos_timing_check(10);
always @(posedge dqs_in[11]) dqs_pos_timing_check(11);
always @(posedge dqs_in[12]) dqs_pos_timing_check(12);
always @(posedge dqs_in[13]) dqs_pos_timing_check(13);
always @(posedge dqs_in[14]) dqs_pos_timing_check(14);
always @(posedge dqs_in[15]) dqs_pos_timing_check(15);
always @(negedge dqs_in[16]) dqs_pos_timing_check(16);
always @(negedge dqs_in[17]) dqs_pos_timing_check(17);
always @(negedge dqs_in[18]) dqs_pos_timing_check(18);
always @(negedge dqs_in[19]) dqs_pos_timing_check(19);
always @(negedge dqs_in[20]) dqs_pos_timing_check(20);
always @(negedge dqs_in[21]) dqs_pos_timing_check(21);
always @(negedge dqs_in[22]) dqs_pos_timing_check(22);
always @(negedge dqs_in[23]) dqs_pos_timing_check(23);
always @(negedge dqs_in[24]) dqs_pos_timing_check(24);
always @(negedge dqs_in[25]) dqs_pos_timing_check(25);
always @(negedge dqs_in[26]) dqs_pos_timing_check(26);
always @(negedge dqs_in[27]) dqs_pos_timing_check(27);
always @(negedge dqs_in[28]) dqs_pos_timing_check(28);
always @(negedge dqs_in[29]) dqs_pos_timing_check(29);
always @(negedge dqs_in[30]) dqs_pos_timing_check(30);
always @(negedge dqs_in[31]) dqs_pos_timing_check(31);
task dqs_neg_timing_check;
input i;
reg [4:0] i;
reg [3:0] j;
begin
if (write_levelization && i<16) begin
if (ck_cntr - ck_load_mode < TWLDQSEN)
$display ("%m: at time %t ERROR: tWLDQSEN violation on DQS bit %d.", $time, i);
if ($time - tm_dqs_pos[i] < $rtoi(TDQSH*tck_avg))
$display ("%m: at time %t ERROR: tDQSH violation on DQS bit %d by %t", $time, i, tm_dqs_pos[i] + TDQSH*tck_avg - $time);
end
if (dqs_in_valid && (wdqs_pos_cntr[i] > 0) && check_write_dqs_high[i]) begin
if (dqs_in[i] ^ prev_dqs_in[i]) begin
if (dll_locked) begin
if ($time - tm_dqs_pos[i] < $rtoi(TDQSH*tck_avg))
$display ("%m: at time %t ERROR: tDQSH violation on %s bit %d", $time, dqs_string[i/16], i%16);
if ($time - tm_ck_pos < $rtoi(TDSH*tck_avg))
$display ("%m: at time %t ERROR: tDSH violation on %s bit %d", $time, dqs_string[i/16], i%16);
end
if ($time - tm_dm[i%16] < TDS)
$display ("%m: at time %t ERROR: tDS violation on DM bit %d by %t", $time, i, tm_dm[i%16] + TDS - $time);
if (!dq_out_en) begin
for (j=0; j<`DQ_PER_DQS; j=j+1) begin
if ($time - tm_dq[(i%16)*`DQ_PER_DQS+j] < TDS)
$display ("%m: at time %t ERROR: tDS violation on DQ bit %d by %t", $time, i*`DQ_PER_DQS+j, tm_dq[(i%16)*`DQ_PER_DQS+j] + TDS - $time);
check_dq_tdipw[(i%16)*`DQ_PER_DQS+j] <= 1'b1;
end
end
check_dm_tdipw[i%16] <= 1'b1;
tm_dqs[i%16] <= $time;
end else begin
$display ("%m: at time %t ERROR: Invalid latching edge on %s bit %d", $time, dqs_string[i/16], i%16);
end
end
check_write_dqs_high[i] <= 1'b0;
tm_dqs_neg[i] = $time;
prev_dqs_in[i] <= dqs_in[i];
end
endtask
always @(negedge dqs_in[ 0]) dqs_neg_timing_check( 0);
always @(negedge dqs_in[ 1]) dqs_neg_timing_check( 1);
always @(negedge dqs_in[ 2]) dqs_neg_timing_check( 2);
always @(negedge dqs_in[ 3]) dqs_neg_timing_check( 3);
always @(negedge dqs_in[ 4]) dqs_neg_timing_check( 4);
always @(negedge dqs_in[ 5]) dqs_neg_timing_check( 5);
always @(negedge dqs_in[ 6]) dqs_neg_timing_check( 6);
always @(negedge dqs_in[ 7]) dqs_neg_timing_check( 7);
always @(negedge dqs_in[ 8]) dqs_neg_timing_check( 8);
always @(negedge dqs_in[ 9]) dqs_neg_timing_check( 9);
always @(negedge dqs_in[10]) dqs_neg_timing_check(10);
always @(negedge dqs_in[11]) dqs_neg_timing_check(11);
always @(negedge dqs_in[12]) dqs_neg_timing_check(12);
always @(negedge dqs_in[13]) dqs_neg_timing_check(13);
always @(negedge dqs_in[14]) dqs_neg_timing_check(14);
always @(negedge dqs_in[15]) dqs_neg_timing_check(15);
always @(posedge dqs_in[16]) dqs_neg_timing_check(16);
always @(posedge dqs_in[17]) dqs_neg_timing_check(17);
always @(posedge dqs_in[18]) dqs_neg_timing_check(18);
always @(posedge dqs_in[19]) dqs_neg_timing_check(19);
always @(posedge dqs_in[20]) dqs_neg_timing_check(20);
always @(posedge dqs_in[21]) dqs_neg_timing_check(21);
always @(posedge dqs_in[22]) dqs_neg_timing_check(22);
always @(posedge dqs_in[23]) dqs_neg_timing_check(23);
always @(posedge dqs_in[24]) dqs_neg_timing_check(24);
always @(posedge dqs_in[25]) dqs_neg_timing_check(25);
always @(posedge dqs_in[26]) dqs_neg_timing_check(26);
always @(posedge dqs_in[27]) dqs_neg_timing_check(27);
always @(posedge dqs_in[28]) dqs_neg_timing_check(28);
always @(posedge dqs_in[29]) dqs_neg_timing_check(29);
always @(posedge dqs_in[30]) dqs_neg_timing_check(30);
always @(posedge dqs_in[31]) dqs_neg_timing_check(31);
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2003 by Wilson Snyder.
module t (clk);
input clk;
reg [31:0] r32;
wire [3:0] w4;
wire [4:0] w5;
assign w4 = NUMONES_8 ( r32[7:0] );
assign w5 = NUMONES_16( r32[15:0] );
function [3:0] NUMONES_8;
input [7:0] i8;
reg [7:0] i8;
begin
NUMONES_8 = 4'b1;
end
endfunction // NUMONES_8
function [4:0] NUMONES_16;
input [15:0] i16;
reg [15:0] i16;
begin
NUMONES_16 = ( NUMONES_8( i16[7:0] ) + NUMONES_8( i16[15:8] ));
end
endfunction
integer cyc; initial cyc=1;
always @ (posedge clk) begin
if (cyc!=0) begin
cyc <= cyc + 1;
if (cyc==1) begin
r32 <= 32'h12345678;
end
if (cyc==2) begin
if (w4 !== 1) $stop;
if (w5 !== 2) $stop;
$write("*-* All Finished *-*\n");
$finish;
end
end
end
endmodule
|
// DESCRIPTION: Verilator: Verilog Test module
//
// This file ONLY is placed into the Public Domain, for any use,
// without warranty, 2003 by Wilson Snyder.
module t (clk);
input clk;
reg [31:0] r32;
wire [3:0] w4;
wire [4:0] w5;
assign w4 = NUMONES_8 ( r32[7:0] );
assign w5 = NUMONES_16( r32[15:0] );
function [3:0] NUMONES_8;
input [7:0] i8;
reg [7:0] i8;
begin
NUMONES_8 = 4'b1;
end
endfunction // NUMONES_8
function [4:0] NUMONES_16;
input [15:0] i16;
reg [15:0] i16;
begin
NUMONES_16 = ( NUMONES_8( i16[7:0] ) + NUMONES_8( i16[15:8] ));
end
endfunction
integer cyc; initial cyc=1;
always @ (posedge clk) begin
if (cyc!=0) begin
cyc <= cyc + 1;
if (cyc==1) begin
r32 <= 32'h12345678;
end
if (cyc==2) begin
if (w4 !== 1) $stop;
if (w5 !== 2) $stop;
$write("*-* All Finished *-*\n");
$finish;
end
end
end
endmodule
|
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