module_content stringlengths 18 1.05M |
|---|
module s526(GND,VDD,CK,G0,G1,G147,G148,G198,G199,G2,G213,G214);
input GND,VDD,CK,G0,G1,G2;
output G198,G213,G147,G199,G214,G148;
wire G10,G60,G11,G61,G12,G62,G13,G69,G14,G79,G15,G84,G16,G89,G17,G96,G18,
G101,G19,G106,G20,G115,G21,G127,G22,G137,G23,G167,G24,G173,G25,G179,G26,
G183,G27,G188,G28,G194,G29,G200,G... |
module memory(input clk, input [31:0] idata, output [47:0] odata, input [15:0] addr, input [1:0] rw);
reg [7:0] data [0:2**16-1];
initial $readmemb("mem_init.txt", data);
always @(clk) begin
case (rw)
2'b01 : begin
data[addr] <= idata;
end
2'b10 : begin
{data[addr], data[addr + 1] } <= idata;
... |
module memory_test;
reg clk;
reg [1:0] rw;
reg [15:0] addr;
wire line;
reg [31:0] wline;
wire [47:0] rline;
memory memory(clk, wline, rline, addr, rw);
initial begin
$monitor("%t: rw = %b, addr = %x, wline = %x, rline = %x", $time, rw, addr, wline, rline);
clk <= 0;
#10
rw <= 2'b11;
addr <= 0;
... |
module sky130_fd_sc_hdll__o31ai (
Y ,
A1 ,
A2 ,
A3 ,
B1 ,
VPWR,
VGND,
VPB ,
VNB
);
output Y ;
input A1 ;
input A2 ;
input A3 ;
input B1 ;
input VPWR;
input VGND;
input VPB ;
input VNB ;
endmodule |
module sky130_fd_sc_hd__dlrtp (
//# {{data|Data Signals}}
input D ,
output Q ,
//# {{control|Control Signals}}
input RESET_B,
//# {{clocks|Clocking}}
input GATE ,
//# {{power|Power}}
input VPB ,
input VPWR ,
input VGND ,
input VNB
);
endmodule |
module sky130_fd_sc_ls__a2111oi (
Y ,
A1,
A2,
B1,
C1,
D1
);
// Module ports
output Y ;
input A1;
input A2;
input B1;
input C1;
input D1;
// Local signals
wire and0_out ;
wire nor0_out_Y;
// Name Output Other arguments
and and0 (and0... |
module recorder(clock, reset, go, mode, keys, playback_keys);
input clock, reset, go;
input [3:0] keys;
output [1:0] mode;
output [3:0] playback_keys;
wire [1:0] mode_wire;
wire [4:0] cell_number;
wire [25:0] cyclecounter;
wire [25:0] countdown;
controlrecorder cr(
.clock(clock),
.reset(re... |
module controlrecorder(clock, reset, go, countdown, mode, num_keys, cyclecounter, cell_number);
input clock, reset, go;
input [25:0] countdown;
output reg [1:0] mode;
output reg [4:0] cell_number;
output reg [25:0] cyclecounter;
reg [3:0] prev_keys;
reg [2:0] current_state, next_state;
reg [25:0] count... |
module Small_Program_Top(
input clk,
input rst,
input left,
input right,
input up,
input down,
output hsync,
output vsync,
output [11:0]color_out,
output [7:0]seg_out,
output [3:0]sel
);
wire[7:0] direction;
wire[7:0] appleX;
wire[7:0] appleY;
wire[15:0] point;
wire[1:0] gam... |
module sky130_fd_sc_ls__udp_dff$PS_pp$PG$N (
//# {{data|Data Signals}}
input D ,
output Q ,
//# {{control|Control Signals}}
input SET ,
//# {{clocks|Clocking}}
input CLK ,
//# {{power|Power}}
input NOTIFIER,
input VPWR ,
input VGND
);
endmodule |
module read_master (
clk,
reset,
// descriptor commands sink port
snk_command_data,
snk_command_valid,
snk_command_ready,
// response source port
src_response_data,
src_response_valid,
src_response_ready,
// data path sink port
src_data,
src_valid,
src_ready,
src_sop,
src_eop,
src_e... |
module top ( n0 , n1 , n2 , n3 , n4 , n5 , n6 , n7 , n8 , n9 , n10 , n11 , n12 , n13 , n14 , n15 , n16 , n17 , n18 , n19 , n20 , n21 , n22 , n23 , n24 , n25 , n26 , n27 , n28 , n29 , n30 , n31 , n32 , n33 , n34 , n35 , n36 , n37 , n38 , n39 , n40 , n41 , n42 , n43 , n44 , n45 , n46 , n47 , n48 , n49 , n50 , n51 , n52 ,... |
module reg_8bit(
clk,
Load,
not_reset,
D,
Q
);
input wire clk;
input wire not_reset;
input wire Load;
input wire [7:0] D;
output wire [7:0] Q;
reg [7:0] Q_ALTERA_SYNTHESIZED;
always@(posedge clk or negedge not_reset)
begin
if (!not_reset)
begin
Q_ALTERA_SYNTHESIZED[7] <= 0;
end... |
module bsg_mux_one_hot #(parameter `BSG_INV_PARAM(width_p)
, els_p=1
, harden_p=1
)
(
input [els_p-1:0][width_p-1:0] data_i
,input [els_p-1:0] sel_one_hot_i
,output [width_p-1:0] data_o
);
wire [els_p-1:0][width_p-1:0] data_masked;
genva... |
module sky130_fd_sc_ls__xor3 (
//# {{data|Data Signals}}
input A,
input B,
input C,
output X
);
// Voltage supply signals
supply1 VPWR;
supply0 VGND;
supply1 VPB ;
supply0 VNB ;
endmodule |
module axi_traffic_gen_v2_0_streaming_top
#(
parameter C_FAMILY = "virtex7",
parameter C_S_AXI_ID_WIDTH = 1,
parameter C_S_AXI_DATA_WIDTH = 32,
parameter C_AXIS1_HAS_TKEEP = 1 ,
parameter C_AXIS1_HAS_TSTRB = 1 ,
parameter C_AXIS2_HAS_TKEEP ... |
module booth(.iClk(reset),.iReset_b(clock),.iGo(enable),.oDone(done),.iMer(a),.iMand(b),.oProduct(z));
//mult8 mult8(z,a,b);
always@(opc,a,b)
begin
case(opc)
8'b00000000:
//begin
z = a+b;
//booth kali(clock, reset, en, done, a, b, z);
//z = booth_m(clock, reset, en, done, a, b, z);
//end
... |
module uart
#( //Default setting:
// 9600 baud, 8 data bits, 1 stop bit, 2 2 FIFO
parameter DBIT = 8, //Num of data bits
SB_TICK = 16, //Num of ticks for stop bits
//DVSR=2,
DVSR = 163,//326, //Baud rate divisor
//DVSR = 100M/(16*baud_rate)
DVSR_BIT = 8, // Num bits of DVSR
... |
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 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 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 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 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 pipeline_registers
(
input clk,
input reset_n,
input [BIT_WIDTH-1:0] pipe_in,
output reg [BIT_WIDTH-1:0] pipe_out
);
// WARNING!!! THESE PARAMETERS ARE INTENDED TO BE MODIFIED IN A TOP
// LEVEL MODULE. LOCAL CHANGES HERE WILL, MOST LIK... |
module pipeline_registers
(
input clk,
input reset_n,
input [BIT_WIDTH-1:0] pipe_in,
output reg [BIT_WIDTH-1:0] pipe_out
);
// WARNING!!! THESE PARAMETERS ARE INTENDED TO BE MODIFIED IN A TOP
// LEVEL MODULE. LOCAL CHANGES HERE WILL, MOST LIK... |
module pipeline_registers
(
input clk,
input reset_n,
input [BIT_WIDTH-1:0] pipe_in,
output reg [BIT_WIDTH-1:0] pipe_out
);
// WARNING!!! THESE PARAMETERS ARE INTENDED TO BE MODIFIED IN A TOP
// LEVEL MODULE. LOCAL CHANGES HERE WILL, MOST LIK... |
module pipeline_registers
(
input clk,
input reset_n,
input [BIT_WIDTH-1:0] pipe_in,
output reg [BIT_WIDTH-1:0] pipe_out
);
// WARNING!!! THESE PARAMETERS ARE INTENDED TO BE MODIFIED IN A TOP
// LEVEL MODULE. LOCAL CHANGES HERE WILL, MOST LIK... |
module pipeline_registers
(
input clk,
input reset_n,
input [BIT_WIDTH-1:0] pipe_in,
output reg [BIT_WIDTH-1:0] pipe_out
);
// WARNING!!! THESE PARAMETERS ARE INTENDED TO BE MODIFIED IN A TOP
// LEVEL MODULE. LOCAL CHANGES HERE WILL, MOST LIK... |
module pipeline_registers
(
input clk,
input reset_n,
input [BIT_WIDTH-1:0] pipe_in,
output reg [BIT_WIDTH-1:0] pipe_out
);
// WARNING!!! THESE PARAMETERS ARE INTENDED TO BE MODIFIED IN A TOP
// LEVEL MODULE. LOCAL CHANGES HERE WILL, MOST LIK... |
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 |
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 |
Subsets and Splits
No community queries yet
The top public SQL queries from the community will appear here once available.