module_content stringlengths 18 1.05M |
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module sky130_fd_sc_hd__o32ai_1 (
Y ,
A1 ,
A2 ,
A3 ,
B1 ,
B2 ,
VPWR,
VGND,
VPB ,
VNB
);
output Y ;
input A1 ;
input A2 ;
input A3 ;
input B1 ;
input B2 ;
input VPWR;
input VGND;
input VPB ;
input VNB ;
sky130_fd_... |
module sky130_fd_sc_hd__o32ai_1 (
Y ,
A1,
A2,
A3,
B1,
B2
);
output Y ;
input A1;
input A2;
input A3;
input B1;
input B2;
// Voltage supply signals
supply1 VPWR;
supply0 VGND;
supply1 VPB ;
supply0 VNB ;
sky130_fd_sc_hd__o32ai base (
... |
module wasca_altpll_1_dffpipe_l2c
(
clock,
clrn,
d,
q) /* synthesis synthesis_clearbox=1 */;
input clock;
input clrn;
input [0:0] d;
output [0:0] q;
`ifndef ALTERA_RESERVED_QIS
// synopsys translate_off
`endif
tri0 clock;
tri1 clrn;
`ifndef ALTERA_RESERVED_QIS
// synopsys translate_on
`endif
... |
module wasca_altpll_1_stdsync_sv6
(
clk,
din,
dout,
reset_n) /* synthesis synthesis_clearbox=1 */;
input clk;
input din;
output dout;
input reset_n;
wire [0:0] wire_dffpipe3_q;
wasca_altpll_1_dffpipe_l2c dffpipe3
(
.clock(clk),
.clrn(reset_n),
.d(din),
.q(wire_dffpipe3_q));
assign
d... |
module wasca_altpll_1_altpll_8932
(
areset,
clk,
inclk,
locked) /* synthesis synthesis_clearbox=1 */;
input areset;
output [4:0] clk;
input [1:0] inclk;
output locked;
`ifndef ALTERA_RESERVED_QIS
// synopsys translate_off
`endif
tri0 areset;
tri0 [1:0] inclk;
`ifndef ALTERA_RESERVED_QIS
// s... |
module wasca_altpll_1
(
address,
areset,
c0,
clk,
locked,
phasedone,
read,
readdata,
reset,
write,
writedata) /* synthesis synthesis_clearbox=1 */;
input [1:0] address;
input areset;
output c0;
input clk;
output locked;
output phasedone;
input read;
output [31:0] readdata;
input... |
module pcie_7x_v1_11_0_pcie_top # (
// PCIE_2_1 params
parameter PIPE_PIPELINE_STAGES = 0, // 0 - 0 stages, 1 - 1 stage, 2 - 2 stages
parameter [11:0] AER_BASE_PTR = 12'h140,
parameter AER_CAP_ECRC_CHECK_CAPABLE = "FALSE",
parameter DEV_CAP_ROLE_BASED_ERROR = "TRUE",
para... |
module mac_tb;
parameter INTERMEDIATOR_DEPTH = 1024;
parameter LOG2_INTERMEDIATOR_DEPTH = log2(INTERMEDIATOR_DEPTH - 1);
parameter MATRIX_FILENAME = "../../src/tmp/cant/cant.mtx";
reg clk, rst, wr;
reg [LOG2_INTERMEDIATOR_DEPTH - 1:0] row;
reg [63:0] v0, v1;
wire push_out;
wire [63:0] v... |
module ColorImageProcess#
(
parameter[ 2 : 0 ]ReadState = 0, // read raw data operation
parameter[ 2 : 0 ]ALState = 1, // auto level
parameter[ 2 : 0 ]WBState = 2, // white balance
parameter[ 2 : 0 ]RemainderState = 3, // color correction
// forward space
// saturation enhancement
// backward ... |
module ColorImageProcess_testbench;
// Signal declaration
reg Clock;
reg Reset;
reg[ `size_char - 1 : 0 ]R;
reg[ `size_char - 1 : 0 ]G;
reg[ `size_char - 1 : 0 ]B;
wire[ `size_char - 1 : 0 ]R_out;
wire[ `size_char - 1 : 0 ]G_out;
wire[ `size_char - 1 : 0 ]B_out;
reg[ `size_char - 1 : 0 ]RBlock[ 0 : `S... |
module sky130_fd_sc_ls__nor2b_4 (
Y ,
A ,
B_N ,
VPWR,
VGND,
VPB ,
VNB
);
output Y ;
input A ;
input B_N ;
input VPWR;
input VGND;
input VPB ;
input VNB ;
sky130_fd_sc_ls__nor2b base (
.Y(Y),
.A(A),
.B_N(B_N),
.VPW... |
module sky130_fd_sc_ls__nor2b_4 (
Y ,
A ,
B_N
);
output Y ;
input A ;
input B_N;
// Voltage supply signals
supply1 VPWR;
supply0 VGND;
supply1 VPB ;
supply0 VNB ;
sky130_fd_sc_ls__nor2b base (
.Y(Y),
.A(A),
.B_N(B_N)
);
endmodule |
module sky130_fd_sc_hs__sdfbbn (
Q ,
Q_N ,
D ,
SCD ,
SCE ,
CLK_N ,
SET_B ,
RESET_B,
VPWR ,
VGND
);
// Module ports
output Q ;
output Q_N ;
input D ;
input SCD ;
input SCE ;
input CLK_N ;
input SET_B ... |
module sky130_fd_sc_hd__mux2i (
//# {{data|Data Signals}}
input A0,
input A1,
output Y ,
//# {{control|Control Signals}}
input S
);
// Voltage supply signals
supply1 VPWR;
supply0 VGND;
supply1 VPB ;
supply0 VNB ;
endmodule |
module sky130_fd_sc_hs__fill (
VPWR,
VGND,
VPB ,
VNB
);
input VPWR;
input VGND;
input VPB ;
input VNB ;
endmodule |
module
// 0x800 - 0x9ff Up to 512 bytes of Debug ROM.
//
//
wire i_icb_cmd_hsked = i_icb_cmd_valid & i_icb_cmd_ready;
wire icb_wr_ena = i_icb_cmd_hsked & (~i_icb_cmd_read);
wire icb_sel_cleardebint = (i_icb_cmd_addr == 12'h100);
wire icb_sel_sethaltnot = (i_icb_cmd_addr == 12'h10c);
wire icb_sel_... |
module FrequencyCounter(
input clk,
input freqin,
output [23:0] frequency
);
parameter SecondCount = 8001800; // Number of cycles of clk to 1 second
reg [23:0] counter = 0; // Counter for input freqin
reg [23:0] freq =... |
module ClkDiv_20Hz(
CLK, // 12MHz onbaord clock
RST, // Reset
CLKOUT, // New clock output
CLKOUTn
);
// ===========================================================================
// Port Declarations
// ==================================================... |
module clk_wiz_1(clk_txd, clk_rxd, resetn, locked, clk_in1)
/* synthesis syn_black_box black_box_pad_pin="clk_txd,clk_rxd,resetn,locked,clk_in1" */;
output clk_txd;
output clk_rxd;
input resetn;
output locked;
input clk_in1;
endmodule |
module n64_vdemux(
VCLK,
nDSYNC,
D_i,
demuxparams_i,
vdata_r_0,
vdata_r_1
);
`include "vh/n64rgb_params.vh"
input VCLK;
input nDSYNC;
input [color_width-1:0] D_i;
input [ 4:0] demuxparams_i;
output reg [`VDATA_FU_SLICE] vdata_r_0; // buffer for sync, red, green and blue
output reg [`VDATA... |
module testREG32;
// Inputs
reg [31:0] in;
reg clk;
reg R;
// Outputs
wire [31:0] out;
// Instantiate the DESIGN Under Test (DUT)
REG32 dut (
.in(in),
.clk(clk),
.R(R),
.out(out)
);
always begin
clk = 0;
#100;
clk = 1;
#100;
end
initial begin
// Initialize Inputs
in = 0;
R = ... |
module bcam_trs
#( parameter CAMD = 128 , // CAM depth
parameter CAMW = 9 , // CAM/pattern width
parameter BYPS = 1 , // Bypassed? (binary; 0 or 1)
parameter PIPE = 0 , // Pipelined? (binary; 0 or 1)
parameter ... |
module shift_reg(
input rx,
output reg[(reg_length-1):0] shifted_bus,
output reg finished_rx,
input rst,
input baud_clk
);
parameter reg_length = 150;
initial finished_rx = 0;
parameter idle = 2'b00, reading = 2'b01, finished = 2'b10, finished_and_waiting = 2'b11;
reg[1:0] current_state, nex... |
module sky130_fd_sc_hdll__sdfxtp (
Q ,
CLK ,
D ,
SCD ,
SCE ,
VPWR,
VGND,
VPB ,
VNB
);
// Module ports
output Q ;
input CLK ;
input D ;
input SCD ;
input SCE ;
input VPWR;
input VGND;
input VPB ;
input VNB ;
// Local signal... |
module axi_protocol_converter_v2_1_b2s_simple_fifo #
(
parameter C_WIDTH = 8,
parameter C_AWIDTH = 4,
parameter C_DEPTH = 16
)
(
input wire clk, // Main System Clock (Sync FIFO)
input wire rst, // FIFO Counter Reset (Clk
input wire wr_en, // FI... |
module axi_protocol_converter_v2_1_b2s_simple_fifo #
(
parameter C_WIDTH = 8,
parameter C_AWIDTH = 4,
parameter C_DEPTH = 16
)
(
input wire clk, // Main System Clock (Sync FIFO)
input wire rst, // FIFO Counter Reset (Clk
input wire wr_en, // FI... |
module axi_protocol_converter_v2_1_b2s_simple_fifo #
(
parameter C_WIDTH = 8,
parameter C_AWIDTH = 4,
parameter C_DEPTH = 16
)
(
input wire clk, // Main System Clock (Sync FIFO)
input wire rst, // FIFO Counter Reset (Clk
input wire wr_en, // FI... |
module sha256_transform #(
parameter LOOP = 7'd64 // For ltcminer
) (
input clk,
input feedback,
input [5:0] cnt,
input [255:0] rx_state,
input [511:0] rx_input,
output reg [255:0] tx_hash
);
// Constants defined by the SHA-2 standard.
localparam Ks = {
32'h428a2f98, 32'h71374491, 32'hb5c0fbcf, 32'he9b5dba... |
module sha256_digester (clk, k, rx_w, rx_state, tx_w, tx_state);
input clk;
input [31:0] k;
input [511:0] rx_w;
input [255:0] rx_state;
output reg [511:0] tx_w;
output reg [255:0] tx_state;
wire [31:0] e0_w, e1_w, ch_w, maj_w, s0_w, s1_w;
e0 e0_blk (rx_state[`IDX(0)], e0_w);
e1 e1_blk (rx_state[`IDX(4)],... |
module sha256_transform #(
parameter LOOP = 7'd64 // For ltcminer
) (
input clk,
input feedback,
input [5:0] cnt,
input [255:0] rx_state,
input [511:0] rx_input,
output reg [255:0] tx_hash
);
// Constants defined by the SHA-2 standard.
localparam Ks = {
32'h428a2f98, 32'h71374491, 32'hb5c0fbcf, 32'he9b5dba... |
module sha256_digester (clk, k, rx_w, rx_state, tx_w, tx_state);
input clk;
input [31:0] k;
input [511:0] rx_w;
input [255:0] rx_state;
output reg [511:0] tx_w;
output reg [255:0] tx_state;
wire [31:0] e0_w, e1_w, ch_w, maj_w, s0_w, s1_w;
e0 e0_blk (rx_state[`IDX(0)], e0_w);
e1 e1_blk (rx_state[`IDX(4)],... |
module sha256_transform #(
parameter LOOP = 7'd64 // For ltcminer
) (
input clk,
input feedback,
input [5:0] cnt,
input [255:0] rx_state,
input [511:0] rx_input,
output reg [255:0] tx_hash
);
// Constants defined by the SHA-2 standard.
localparam Ks = {
32'h428a2f98, 32'h71374491, 32'hb5c0fbcf, 32'he9b5dba... |
module sha256_digester (clk, k, rx_w, rx_state, tx_w, tx_state);
input clk;
input [31:0] k;
input [511:0] rx_w;
input [255:0] rx_state;
output reg [511:0] tx_w;
output reg [255:0] tx_state;
wire [31:0] e0_w, e1_w, ch_w, maj_w, s0_w, s1_w;
e0 e0_blk (rx_state[`IDX(0)], e0_w);
e1 e1_blk (rx_state[`IDX(4)],... |
module testbed_hi_simulate;
reg pck0;
reg [7:0] adc_d;
reg mod_type;
wire pwr_lo;
wire adc_clk;
reg ck_1356meg;
reg ck_1356megb;
wire ssp_frame;
wire ssp_din;
wire ssp_clk;
reg ssp_dout;
wire pwr_hi;
wire pwr_oe1;
wire pwr_oe2;
wire pwr_oe3;
wire pwr_oe4;
wire cross_lo;
wire cross_hi;
wire dbg;... |
module testbed_hi_simulate;
reg pck0;
reg [7:0] adc_d;
reg mod_type;
wire pwr_lo;
wire adc_clk;
reg ck_1356meg;
reg ck_1356megb;
wire ssp_frame;
wire ssp_din;
wire ssp_clk;
reg ssp_dout;
wire pwr_hi;
wire pwr_oe1;
wire pwr_oe2;
wire pwr_oe3;
wire pwr_oe4;
wire cross_lo;
wire cross_hi;
wire dbg;... |
module testbed_hi_simulate;
reg pck0;
reg [7:0] adc_d;
reg mod_type;
wire pwr_lo;
wire adc_clk;
reg ck_1356meg;
reg ck_1356megb;
wire ssp_frame;
wire ssp_din;
wire ssp_clk;
reg ssp_dout;
wire pwr_hi;
wire pwr_oe1;
wire pwr_oe2;
wire pwr_oe3;
wire pwr_oe4;
wire cross_lo;
wire cross_hi;
wire dbg;... |
module testbed_hi_simulate;
reg pck0;
reg [7:0] adc_d;
reg mod_type;
wire pwr_lo;
wire adc_clk;
reg ck_1356meg;
reg ck_1356megb;
wire ssp_frame;
wire ssp_din;
wire ssp_clk;
reg ssp_dout;
wire pwr_hi;
wire pwr_oe1;
wire pwr_oe2;
wire pwr_oe3;
wire pwr_oe4;
wire cross_lo;
wire cross_hi;
wire dbg;... |
module testbed_hi_simulate;
reg pck0;
reg [7:0] adc_d;
reg mod_type;
wire pwr_lo;
wire adc_clk;
reg ck_1356meg;
reg ck_1356megb;
wire ssp_frame;
wire ssp_din;
wire ssp_clk;
reg ssp_dout;
wire pwr_hi;
wire pwr_oe1;
wire pwr_oe2;
wire pwr_oe3;
wire pwr_oe4;
wire cross_lo;
wire cross_hi;
wire dbg;... |
module processing_system7_v5_5_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of ch... |
module processing_system7_v5_5_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of ch... |
module processing_system7_v5_5_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of ch... |
module processing_system7_v5_5_atc #
(
parameter C_FAMILY = "rtl",
// FPGA Family. Current version: virtex6, spartan6 or later.
parameter integer C_AXI_ID_WIDTH = 4,
// Width of all ID signals on SI and MI side of ch... |
module altera_avalon_sc_fifo
#(
// --------------------------------------------------
// Parameters
// --------------------------------------------------
parameter SYMBOLS_PER_BEAT = 1,
parameter BITS_PER_SYMBOL = 8,
parameter FIFO_DEPTH = 16,
parameter CHANNEL_WIDTH = 0,
p... |
module altera_avalon_sc_fifo
#(
// --------------------------------------------------
// Parameters
// --------------------------------------------------
parameter SYMBOLS_PER_BEAT = 1,
parameter BITS_PER_SYMBOL = 8,
parameter FIFO_DEPTH = 16,
parameter CHANNEL_WIDTH = 0,
p... |
module altera_avalon_sc_fifo
#(
// --------------------------------------------------
// Parameters
// --------------------------------------------------
parameter SYMBOLS_PER_BEAT = 1,
parameter BITS_PER_SYMBOL = 8,
parameter FIFO_DEPTH = 16,
parameter CHANNEL_WIDTH = 0,
p... |
module altera_avalon_sc_fifo
#(
// --------------------------------------------------
// Parameters
// --------------------------------------------------
parameter SYMBOLS_PER_BEAT = 1,
parameter BITS_PER_SYMBOL = 8,
parameter FIFO_DEPTH = 16,
parameter CHANNEL_WIDTH = 0,
p... |
module altera_avalon_sc_fifo
#(
// --------------------------------------------------
// Parameters
// --------------------------------------------------
parameter SYMBOLS_PER_BEAT = 1,
parameter BITS_PER_SYMBOL = 8,
parameter FIFO_DEPTH = 16,
parameter CHANNEL_WIDTH = 0,
p... |
module altera_avalon_sc_fifo
#(
// --------------------------------------------------
// Parameters
// --------------------------------------------------
parameter SYMBOLS_PER_BEAT = 1,
parameter BITS_PER_SYMBOL = 8,
parameter FIFO_DEPTH = 16,
parameter CHANNEL_WIDTH = 0,
p... |
module altera_avalon_sc_fifo
#(
// --------------------------------------------------
// Parameters
// --------------------------------------------------
parameter SYMBOLS_PER_BEAT = 1,
parameter BITS_PER_SYMBOL = 8,
parameter FIFO_DEPTH = 16,
parameter CHANNEL_WIDTH = 0,
p... |
module altera_avalon_sc_fifo
#(
// --------------------------------------------------
// Parameters
// --------------------------------------------------
parameter SYMBOLS_PER_BEAT = 1,
parameter BITS_PER_SYMBOL = 8,
parameter FIFO_DEPTH = 16,
parameter CHANNEL_WIDTH = 0,
p... |
module altera_avalon_sc_fifo
#(
// --------------------------------------------------
// Parameters
// --------------------------------------------------
parameter SYMBOLS_PER_BEAT = 1,
parameter BITS_PER_SYMBOL = 8,
parameter FIFO_DEPTH = 16,
parameter CHANNEL_WIDTH = 0,
p... |
module altera_avalon_sc_fifo
#(
// --------------------------------------------------
// Parameters
// --------------------------------------------------
parameter SYMBOLS_PER_BEAT = 1,
parameter BITS_PER_SYMBOL = 8,
parameter FIFO_DEPTH = 16,
parameter CHANNEL_WIDTH = 0,
p... |
module altera_avalon_sc_fifo
#(
// --------------------------------------------------
// Parameters
// --------------------------------------------------
parameter SYMBOLS_PER_BEAT = 1,
parameter BITS_PER_SYMBOL = 8,
parameter FIFO_DEPTH = 16,
parameter CHANNEL_WIDTH = 0,
p... |
module axi_protocol_converter_v2_1_r_axi3_conv #
(
parameter C_FAMILY = "none",
parameter integer C_AXI_ID_WIDTH = 1,
parameter integer C_AXI_ADDR_WIDTH = 32,
parameter integer C_AXI_DATA_WIDTH = 32,
parameter integer C_AXI_SUPPORTS_USER_SIG... |
module axi_protocol_converter_v2_1_r_axi3_conv #
(
parameter C_FAMILY = "none",
parameter integer C_AXI_ID_WIDTH = 1,
parameter integer C_AXI_ADDR_WIDTH = 32,
parameter integer C_AXI_DATA_WIDTH = 32,
parameter integer C_AXI_SUPPORTS_USER_SIG... |
module axi_protocol_converter_v2_1_r_axi3_conv #
(
parameter C_FAMILY = "none",
parameter integer C_AXI_ID_WIDTH = 1,
parameter integer C_AXI_ADDR_WIDTH = 32,
parameter integer C_AXI_DATA_WIDTH = 32,
parameter integer C_AXI_SUPPORTS_USER_SIG... |
module axi_protocol_converter_v2_1_r_axi3_conv #
(
parameter C_FAMILY = "none",
parameter integer C_AXI_ID_WIDTH = 1,
parameter integer C_AXI_ADDR_WIDTH = 32,
parameter integer C_AXI_DATA_WIDTH = 32,
parameter integer C_AXI_SUPPORTS_USER_SIG... |
module axi_protocol_converter_v2_1_r_axi3_conv #
(
parameter C_FAMILY = "none",
parameter integer C_AXI_ID_WIDTH = 1,
parameter integer C_AXI_ADDR_WIDTH = 32,
parameter integer C_AXI_DATA_WIDTH = 32,
parameter integer C_AXI_SUPPORTS_USER_SIG... |
module e0 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[1:0],x[31:2]} ^ {x[12:0],x[31:13]} ^ {x[21:0],x[31:22]};
endmodule |
module e1 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[5:0],x[31:6]} ^ {x[10:0],x[31:11]} ^ {x[24:0],x[31:25]};
endmodule |
module ch (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = z ^ (x & (y ^ z));
endmodule |
module maj (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = (x & y) | (z & (x | y));
endmodule |
module s0 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:29] = x[6:4] ^ x[17:15];
assign y[28:0] = {x[3:0], x[31:7]} ^ {x[14:0],x[31:18]} ^ x[31:3];
endmodule |
module s1 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:22] = x[16:7] ^ x[18:9];
assign y[21:0] = {x[6:0],x[31:17]} ^ {x[8:0],x[31:19]} ^ x[31:10];
endmodule |
module e0 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[1:0],x[31:2]} ^ {x[12:0],x[31:13]} ^ {x[21:0],x[31:22]};
endmodule |
module e1 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[5:0],x[31:6]} ^ {x[10:0],x[31:11]} ^ {x[24:0],x[31:25]};
endmodule |
module ch (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = z ^ (x & (y ^ z));
endmodule |
module maj (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = (x & y) | (z & (x | y));
endmodule |
module s0 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:29] = x[6:4] ^ x[17:15];
assign y[28:0] = {x[3:0], x[31:7]} ^ {x[14:0],x[31:18]} ^ x[31:3];
endmodule |
module s1 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:22] = x[16:7] ^ x[18:9];
assign y[21:0] = {x[6:0],x[31:17]} ^ {x[8:0],x[31:19]} ^ x[31:10];
endmodule |
module e0 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[1:0],x[31:2]} ^ {x[12:0],x[31:13]} ^ {x[21:0],x[31:22]};
endmodule |
module e1 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[5:0],x[31:6]} ^ {x[10:0],x[31:11]} ^ {x[24:0],x[31:25]};
endmodule |
module ch (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = z ^ (x & (y ^ z));
endmodule |
module maj (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = (x & y) | (z & (x | y));
endmodule |
module s0 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:29] = x[6:4] ^ x[17:15];
assign y[28:0] = {x[3:0], x[31:7]} ^ {x[14:0],x[31:18]} ^ x[31:3];
endmodule |
module s1 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:22] = x[16:7] ^ x[18:9];
assign y[21:0] = {x[6:0],x[31:17]} ^ {x[8:0],x[31:19]} ^ x[31:10];
endmodule |
module e0 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[1:0],x[31:2]} ^ {x[12:0],x[31:13]} ^ {x[21:0],x[31:22]};
endmodule |
module e1 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[5:0],x[31:6]} ^ {x[10:0],x[31:11]} ^ {x[24:0],x[31:25]};
endmodule |
module ch (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = z ^ (x & (y ^ z));
endmodule |
module maj (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = (x & y) | (z & (x | y));
endmodule |
module s0 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:29] = x[6:4] ^ x[17:15];
assign y[28:0] = {x[3:0], x[31:7]} ^ {x[14:0],x[31:18]} ^ x[31:3];
endmodule |
module s1 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:22] = x[16:7] ^ x[18:9];
assign y[21:0] = {x[6:0],x[31:17]} ^ {x[8:0],x[31:19]} ^ x[31:10];
endmodule |
module e0 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[1:0],x[31:2]} ^ {x[12:0],x[31:13]} ^ {x[21:0],x[31:22]};
endmodule |
module e1 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[5:0],x[31:6]} ^ {x[10:0],x[31:11]} ^ {x[24:0],x[31:25]};
endmodule |
module ch (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = z ^ (x & (y ^ z));
endmodule |
module maj (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = (x & y) | (z & (x | y));
endmodule |
module s0 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:29] = x[6:4] ^ x[17:15];
assign y[28:0] = {x[3:0], x[31:7]} ^ {x[14:0],x[31:18]} ^ x[31:3];
endmodule |
module s1 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:22] = x[16:7] ^ x[18:9];
assign y[21:0] = {x[6:0],x[31:17]} ^ {x[8:0],x[31:19]} ^ x[31:10];
endmodule |
module e0 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[1:0],x[31:2]} ^ {x[12:0],x[31:13]} ^ {x[21:0],x[31:22]};
endmodule |
module e1 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[5:0],x[31:6]} ^ {x[10:0],x[31:11]} ^ {x[24:0],x[31:25]};
endmodule |
module ch (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = z ^ (x & (y ^ z));
endmodule |
module maj (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = (x & y) | (z & (x | y));
endmodule |
module s0 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:29] = x[6:4] ^ x[17:15];
assign y[28:0] = {x[3:0], x[31:7]} ^ {x[14:0],x[31:18]} ^ x[31:3];
endmodule |
module s1 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:22] = x[16:7] ^ x[18:9];
assign y[21:0] = {x[6:0],x[31:17]} ^ {x[8:0],x[31:19]} ^ x[31:10];
endmodule |
module e0 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[1:0],x[31:2]} ^ {x[12:0],x[31:13]} ^ {x[21:0],x[31:22]};
endmodule |
module e1 (x, y);
input [31:0] x;
output [31:0] y;
assign y = {x[5:0],x[31:6]} ^ {x[10:0],x[31:11]} ^ {x[24:0],x[31:25]};
endmodule |
module ch (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = z ^ (x & (y ^ z));
endmodule |
module maj (x, y, z, o);
input [31:0] x, y, z;
output [31:0] o;
assign o = (x & y) | (z & (x | y));
endmodule |
module s0 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:29] = x[6:4] ^ x[17:15];
assign y[28:0] = {x[3:0], x[31:7]} ^ {x[14:0],x[31:18]} ^ x[31:3];
endmodule |
module s1 (x, y);
input [31:0] x;
output [31:0] y;
assign y[31:22] = x[16:7] ^ x[18:9];
assign y[21:0] = {x[6:0],x[31:17]} ^ {x[8:0],x[31:19]} ^ x[31:10];
endmodule |
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