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module processing_system7_v5_5_aw_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 ... |
module processing_system7_v5_5_aw_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 ... |
module processing_system7_v5_5_aw_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 ... |
module adc_interface
(input clock, input reset, input enable,
input wire [6:0] serial_addr, input wire [31:0] serial_data, input serial_strobe,
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 [31:0] rssi_0, output wire [31:0] rssi_1, output ... |
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red ... |
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red ... |
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red ... |
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red ... |
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red ... |
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red ... |
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red ... |
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red ... |
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red ... |
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red ... |
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red ... |
module traffic;
parameter on = 1, off = 0, red_tics = 35,
amber_tics = 3, green_tics = 20;
reg clock, red, amber, green;
// will stop the simulation after 1000 time units
initial begin: stop_at
#1000; $stop;
end
// initialize the lights and set up monitoring of registers
initial begin: Init
red ... |
module axi_protocol_converter_v2_1_decerr_slave #
(
parameter integer C_AXI_ID_WIDTH = 1,
parameter integer C_AXI_DATA_WIDTH = 32,
parameter integer C_AXI_BUSER_WIDTH = 1,
parameter integer C_AXI_RUSER_WIDTH = 1,
parameter integer C_AXI_PROTOCOL = 0,
paramet... |
module axi_protocol_converter_v2_1_decerr_slave #
(
parameter integer C_AXI_ID_WIDTH = 1,
parameter integer C_AXI_DATA_WIDTH = 32,
parameter integer C_AXI_BUSER_WIDTH = 1,
parameter integer C_AXI_RUSER_WIDTH = 1,
parameter integer C_AXI_PROTOCOL = 0,
paramet... |
module axi_protocol_converter_v2_1_decerr_slave #
(
parameter integer C_AXI_ID_WIDTH = 1,
parameter integer C_AXI_DATA_WIDTH = 32,
parameter integer C_AXI_BUSER_WIDTH = 1,
parameter integer C_AXI_RUSER_WIDTH = 1,
parameter integer C_AXI_PROTOCOL = 0,
paramet... |
module axi_protocol_converter_v2_1_decerr_slave #
(
parameter integer C_AXI_ID_WIDTH = 1,
parameter integer C_AXI_DATA_WIDTH = 32,
parameter integer C_AXI_BUSER_WIDTH = 1,
parameter integer C_AXI_RUSER_WIDTH = 1,
parameter integer C_AXI_PROTOCOL = 0,
paramet... |
module axi_protocol_converter_v2_1_w_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_w_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_w_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_w_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 debounce_switch #(
parameter WIDTH=1, // width of the input and output signals
parameter N=3, // length of shift register
parameter RATE=125000 // clock division factor
)(
input wire clk,
input wire rst,
input wire [WIDTH-1:0] in,
output wire [WIDTH-1:0] out
);
reg [23:0] cnt_reg = ... |
module debounce_switch #(
parameter WIDTH=1, // width of the input and output signals
parameter N=3, // length of shift register
parameter RATE=125000 // clock division factor
)(
input wire clk,
input wire rst,
input wire [WIDTH-1:0] in,
output wire [WIDTH-1:0] out
);
reg [23:0] cnt_reg = ... |
module shift_mux_array
#(parameter SWR=26, parameter LEVEL=5)
(
input wire [SWR-1:0] Data_i,
input wire select_i,
input wire bit_shift_i,
output wire [SWR-1:0] Data_o
);
genvar j;
generate for (j=0; j<=SWR-1 ; j=j+1) begin
localparam sh=(2**LEVEL)+j; //value for second mux input. It changes ... |
module shift_mux_array
#(parameter SWR=26, parameter LEVEL=5)
(
input wire [SWR-1:0] Data_i,
input wire select_i,
input wire bit_shift_i,
output wire [SWR-1:0] Data_o
);
genvar j;
generate for (j=0; j<=SWR-1 ; j=j+1) begin
localparam sh=(2**LEVEL)+j; //value for second mux input. It changes ... |
module pluto_servo(clk, led, nConfig, epp_nReset, pport_data, nWrite, nWait, nDataStr,
nAddrStr, dout, din, quadA, quadB, quadZ, up, down);
parameter QW=14;
input clk;
output led, nConfig;
inout [7:0] pport_data;
input nWrite;
output nWait;
input nDataStr, nAddrStr, epp_nReset;
wire do_tristate;
reg[9:0] real_dout; ou... |
module pluto_servo(clk, led, nConfig, epp_nReset, pport_data, nWrite, nWait, nDataStr,
nAddrStr, dout, din, quadA, quadB, quadZ, up, down);
parameter QW=14;
input clk;
output led, nConfig;
inout [7:0] pport_data;
input nWrite;
output nWait;
input nDataStr, nAddrStr, epp_nReset;
wire do_tristate;
reg[9:0] real_dout; ou... |
module pluto_servo(clk, led, nConfig, epp_nReset, pport_data, nWrite, nWait, nDataStr,
nAddrStr, dout, din, quadA, quadB, quadZ, up, down);
parameter QW=14;
input clk;
output led, nConfig;
inout [7:0] pport_data;
input nWrite;
output nWait;
input nDataStr, nAddrStr, epp_nReset;
wire do_tristate;
reg[9:0] real_dout; ou... |
module pluto_servo(clk, led, nConfig, epp_nReset, pport_data, nWrite, nWait, nDataStr,
nAddrStr, dout, din, quadA, quadB, quadZ, up, down);
parameter QW=14;
input clk;
output led, nConfig;
inout [7:0] pport_data;
input nWrite;
output nWait;
input nDataStr, nAddrStr, epp_nReset;
wire do_tristate;
reg[9:0] real_dout; ou... |
module test_stepgen();
reg clk;
reg [4:0] vel;
wire [19:0] pos;
wire step, dir;
stepgen #(16,4,16) s(clk, 1, pos, vel, 1, 0, step, dir, 3);
integer q;
reg ost;
initial begin
vel = 5'h8; // two useful test cases:
// vel=5'h8 (max step speed)
// vel=5'h2 (~1 step per repeat)
q =... |
module test_stepgen();
reg clk;
reg [4:0] vel;
wire [19:0] pos;
wire step, dir;
stepgen #(16,4,16) s(clk, 1, pos, vel, 1, 0, step, dir, 3);
integer q;
reg ost;
initial begin
vel = 5'h8; // two useful test cases:
// vel=5'h8 (max step speed)
// vel=5'h2 (~1 step per repeat)
q =... |
module test_stepgen();
reg clk;
reg [4:0] vel;
wire [19:0] pos;
wire step, dir;
stepgen #(16,4,16) s(clk, 1, pos, vel, 1, 0, step, dir, 3);
integer q;
reg ost;
initial begin
vel = 5'h8; // two useful test cases:
// vel=5'h8 (max step speed)
// vel=5'h2 (~1 step per repeat)
q =... |
module test_stepgen();
reg clk;
reg [4:0] vel;
wire [19:0] pos;
wire step, dir;
stepgen #(16,4,16) s(clk, 1, pos, vel, 1, 0, step, dir, 3);
integer q;
reg ost;
initial begin
vel = 5'h8; // two useful test cases:
// vel=5'h8 (max step speed)
// vel=5'h2 (~1 step per repeat)
q =... |
module fifo_generator_vlog_beh
#(
//-----------------------------------------------------------------------
// Generic Declarations
//-----------------------------------------------------------------------
parameter C_COMMON_CLOCK = 0,
parameter C_COUNT_TYPE = 0,
... |
module.
//***********************************************
assign RD_CLK_P0_IN = 0;
assign RST_P0_IN = 0;
assign RD_EN_P0_IN = 0;
assign RD_EN_FIFO_IN = rd_en_delayed;
assign DOUT = DOUT_FIFO_OUT;
assign DATA_P0_IN = 0;
assign VA... |
module fifo_generator_v13_1_3_sync_stage
#(
parameter C_WIDTH = 10
)
(
input RST,
input CLK,
input [C_WIDTH-1:0] DIN,
output reg [C_WIDTH-1:0] DOUT = 0
);
always @ (posedge RST or posedge CLK) begin
if (RST)
DOUT <= 0... |
module inputs and outputs to the internal signals of the
* behavioral model.
*************************************************************************/
//Inputs
/*
wire [C_DIN_WIDTH-1:0] DIN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wir... |
module fifo_generator_v13_1_3_beh_ver_ll_afifo
/***************************************************************************
* Declare user parameters and their defaults
***************************************************************************/
#(
parameter C_DIN_WIDTH = 8,
pa... |
module inputs and outputs to the internal signals of the
* behavioral model.
*************************************************************************/
//Inputs
/*
wire CLK;
wire [C_DIN_WIDTH-1:0] DIN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASS... |
module fifo_generator_v13_1_3_bhv_ver_preload0
#(
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_HAS_RST = 0,
parameter C_ENABLE_RST_SYNC = 0,
parameter C_HAS_SRST = 0,
parameter C_USE_EMBEDDED_REG ... |
module fifo_generator_v13_1_3_axic_reg_slice #
(
parameter C_FAMILY = "virtex7",
parameter C_DATA_WIDTH = 32,
parameter C_REG_CONFIG = 32'h00000000
)
(
// System Signals
input wire ACLK,
input wire ARESET,
// Slave side
input wire [C_DATA_... |
module fifo_generator_vlog_beh
#(
//-----------------------------------------------------------------------
// Generic Declarations
//-----------------------------------------------------------------------
parameter C_COMMON_CLOCK = 0,
parameter C_COUNT_TYPE = 0,
... |
module.
//***********************************************
assign RD_CLK_P0_IN = 0;
assign RST_P0_IN = 0;
assign RD_EN_P0_IN = 0;
assign RD_EN_FIFO_IN = rd_en_delayed;
assign DOUT = DOUT_FIFO_OUT;
assign DATA_P0_IN = 0;
assign VA... |
module fifo_generator_v13_1_3_sync_stage
#(
parameter C_WIDTH = 10
)
(
input RST,
input CLK,
input [C_WIDTH-1:0] DIN,
output reg [C_WIDTH-1:0] DOUT = 0
);
always @ (posedge RST or posedge CLK) begin
if (RST)
DOUT <= 0... |
module inputs and outputs to the internal signals of the
* behavioral model.
*************************************************************************/
//Inputs
/*
wire [C_DIN_WIDTH-1:0] DIN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASSERT;
wir... |
module fifo_generator_v13_1_3_beh_ver_ll_afifo
/***************************************************************************
* Declare user parameters and their defaults
***************************************************************************/
#(
parameter C_DIN_WIDTH = 8,
pa... |
module inputs and outputs to the internal signals of the
* behavioral model.
*************************************************************************/
//Inputs
/*
wire CLK;
wire [C_DIN_WIDTH-1:0] DIN;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH;
wire [C_RD_PNTR_WIDTH-1:0] PROG_EMPTY_THRESH_ASS... |
module fifo_generator_v13_1_3_bhv_ver_preload0
#(
parameter C_DOUT_RST_VAL = "",
parameter C_DOUT_WIDTH = 8,
parameter C_HAS_RST = 0,
parameter C_ENABLE_RST_SYNC = 0,
parameter C_HAS_SRST = 0,
parameter C_USE_EMBEDDED_REG ... |
module fifo_generator_v13_1_3_axic_reg_slice #
(
parameter C_FAMILY = "virtex7",
parameter C_DATA_WIDTH = 32,
parameter C_REG_CONFIG = 32'h00000000
)
(
// System Signals
input wire ACLK,
input wire ARESET,
// Slave side
input wire [C_DATA_... |
module duc(input clock,
input reset,
input enable,
input [3:0] rate1,
input [3:0] rate2,
output strobe,
input [31:0] freq,
input [15:0] i_in,
input [15:0] q_in,
output [15:0] i_out,
output [15:0] q_out
);
parameter bw = 16;
parameter zw = 16;
wire [15:0] i_interp_out, q_inter... |
module duc(input clock,
input reset,
input enable,
input [3:0] rate1,
input [3:0] rate2,
output strobe,
input [31:0] freq,
input [15:0] i_in,
input [15:0] q_in,
output [15:0] i_out,
output [15:0] q_out
);
parameter bw = 16;
parameter zw = 16;
wire [15:0] i_interp_out, q_inter... |
module duc(input clock,
input reset,
input enable,
input [3:0] rate1,
input [3:0] rate2,
output strobe,
input [31:0] freq,
input [15:0] i_in,
input [15:0] q_in,
output [15:0] i_out,
output [15:0] q_out
);
parameter bw = 16;
parameter zw = 16;
wire [15:0] i_interp_out, q_inter... |
module axi_crossbar_v2_1_addr_decoder #
(
parameter C_FAMILY = "none",
parameter integer C_NUM_TARGETS = 2, // Number of decode targets = [1:16]
parameter integer C_NUM_TARGETS_LOG = 1, // Log2(C_NUM_TARGETS)
parameter integer C_NUM_RANGES = 1, // Number of alternative ranges t... |
module axi_crossbar_v2_1_addr_decoder #
(
parameter C_FAMILY = "none",
parameter integer C_NUM_TARGETS = 2, // Number of decode targets = [1:16]
parameter integer C_NUM_TARGETS_LOG = 1, // Log2(C_NUM_TARGETS)
parameter integer C_NUM_RANGES = 1, // Number of alternative ranges t... |
module Tenth_Phase
//Module Parameters
/***SINGLE PRECISION***/
// W = 32
// EW = 8
// SW = 23
/***DOUBLE PRECISION***/
// W = 64
// EW = 11
// SW = 52
# (parameter W = 32, parameter EW = 8, parameter SW = 23)
// # (parameter W = 64, parameter EW = 11, parameter SW = 52)
(
//INPUTS
input wire clk, //Clock... |
module Tenth_Phase
//Module Parameters
/***SINGLE PRECISION***/
// W = 32
// EW = 8
// SW = 23
/***DOUBLE PRECISION***/
// W = 64
// EW = 11
// SW = 52
# (parameter W = 32, parameter EW = 8, parameter SW = 23)
// # (parameter W = 64, parameter EW = 11, parameter SW = 52)
(
//INPUTS
input wire clk, //Clock... |
module Tenth_Phase
//Module Parameters
/***SINGLE PRECISION***/
// W = 32
// EW = 8
// SW = 23
/***DOUBLE PRECISION***/
// W = 64
// EW = 11
// SW = 52
# (parameter W = 32, parameter EW = 8, parameter SW = 23)
// # (parameter W = 64, parameter EW = 11, parameter SW = 52)
(
//INPUTS
input wire clk, //Clock... |
module Tenth_Phase
//Module Parameters
/***SINGLE PRECISION***/
// W = 32
// EW = 8
// SW = 23
/***DOUBLE PRECISION***/
// W = 64
// EW = 11
// SW = 52
# (parameter W = 32, parameter EW = 8, parameter SW = 23)
// # (parameter W = 64, parameter EW = 11, parameter SW = 52)
(
//INPUTS
input wire clk, //Clock... |
module Tenth_Phase
//Module Parameters
/***SINGLE PRECISION***/
// W = 32
// EW = 8
// SW = 23
/***DOUBLE PRECISION***/
// W = 64
// EW = 11
// SW = 52
# (parameter W = 32, parameter EW = 8, parameter SW = 23)
// # (parameter W = 64, parameter EW = 11, parameter SW = 52)
(
//INPUTS
input wire clk, //Clock... |
module
// signal to increment to the next mc transaction
input wire next ,
// signal to the fsm there is another transaction required
output wire next_pending
);
/////////////////////////////////////////////////////////////////////////... |
module testbed_lo_read;
reg pck0;
reg [7:0] adc_d;
reg lo_is_125khz;
reg [15:0] divisor;
wire pwr_lo;
wire adc_clk;
wire ck_1356meg;
wire 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... |
module soc_design_niosII_core_cpu_debug_slave_tck (
// inputs:
MonDReg,
break_readreg,
dbrk_hit0_latch,
... |
module soc_design_niosII_core_cpu_debug_slave_sysclk (
// inputs:
clk,
ir_in,
sr,
... |
module soc_design_niosII_core_cpu_debug_slave_sysclk (
// inputs:
clk,
ir_in,
sr,
... |
module soc_design_niosII_core_cpu_debug_slave_sysclk (
// inputs:
clk,
ir_in,
sr,
... |
module processing_system7_v5_5_b_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 o... |
module processing_system7_v5_5_b_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 o... |
module processing_system7_v5_5_b_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 o... |
module processing_system7_v5_5_b_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 o... |
module processing_system7_v5_5_b_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 o... |
module processing_system7_v5_5_b_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 o... |
module Priority_Codec_32(
input wire [25:0] Data_Dec_i,
output reg [4:0] Data_Bin_o
);
always @(Data_Dec_i)
begin
if(~Data_Dec_i[25]) begin Data_Bin_o = 5'b00000;//0
end else if(~Data_Dec_i[24]) begin Data_Bin_o = 5'b00001;//1
end else if(~Data_Dec_i[23]) begin Data_Bin_o = 5'b00010;//2
end else ... |
module Priority_Codec_32(
input wire [25:0] Data_Dec_i,
output reg [4:0] Data_Bin_o
);
always @(Data_Dec_i)
begin
if(~Data_Dec_i[25]) begin Data_Bin_o = 5'b00000;//0
end else if(~Data_Dec_i[24]) begin Data_Bin_o = 5'b00001;//1
end else if(~Data_Dec_i[23]) begin Data_Bin_o = 5'b00010;//2
end else ... |
module clk_test(
input clk,
input sysclk,
output [31:0] snes_sysclk_freq
);
reg [31:0] snes_sysclk_freq_r;
assign snes_sysclk_freq = snes_sysclk_freq_r;
reg [31:0] sysclk_counter;
reg [31:0] sysclk_value;
initial snes_sysclk_freq_r = 32'hFFFFFFFF;
initial sysclk_counter = 0;
initial sysclk_value = 0;
reg [1:0... |
module axi_infrastructure_v1_1_vector2axi #
(
///////////////////////////////////////////////////////////////////////////////
// Parameter Definitions
///////////////////////////////////////////////////////////////////////////////
parameter integer C_AXI_PROTOCOL = 0,
parameter integer C_AXI_ID_WIDTH... |
module axi_infrastructure_v1_1_vector2axi #
(
///////////////////////////////////////////////////////////////////////////////
// Parameter Definitions
///////////////////////////////////////////////////////////////////////////////
parameter integer C_AXI_PROTOCOL = 0,
parameter integer C_AXI_ID_WIDTH... |
module sky130_fd_sc_ms__a311oi (
//# {{data|Data Signals}}
input A1 ,
input A2 ,
input A3 ,
input B1 ,
input C1 ,
output Y ,
//# {{power|Power}}
input VPB ,
input VPWR,
input VGND,
input VNB
);
endmodule |
module WireDelay # (
parameter Delay_g = 0,
parameter Delay_rd = 0,
parameter ERR_INSERT = "OFF"
)
(
inout A,
inout B,
input reset,
input phy_init_done
);
reg A_r;
reg B_r;
reg B_inv ;
reg line_en;
reg B_nonX;
assign A = A_r;
assign B = B_r;
always @ (*)
begin
if (B === 1'bx)
... |
module router_op_lut_regs_non_cntr
#( parameter NUM_QUEUES = 5,
parameter ARP_LUT_DEPTH_BITS = 4,
parameter LPM_LUT_DEPTH_BITS = 4,
parameter FILTER_DEPTH_BITS = 4,
parameter UDP_REG_SRC_WIDTH = 2
)
(
input reg_req_in,
input ... |
module sky130_fd_sc_hvl__a21oi (
Y ,
A1 ,
A2 ,
B1 ,
VPWR,
VGND,
VPB ,
VNB
);
// Module ports
output Y ;
input A1 ;
input A2 ;
input B1 ;
input VPWR;
input VGND;
input VPB ;
input VNB ;
// Local signals
wire and0_out ;... |
module ovl_no_underflow (clock, reset, enable, test_expr, fire);
parameter severity_level = `OVL_SEVERITY_DEFAULT;
parameter width = 1;
parameter min = 0;
parameter max = ((1<<width)-1);
parameter property_type = `OVL_PROPERTY_DEFAULT;
parameter msg = `OVL_MSG_DEF... |
module instantiated with wrong parameters");
$stop;
end
instantiated_with_wrong_parameters_error_see_comment_above
outreadylatency_check ( .error(1'b1) );
end
endgenerate
TimeHoldOver_Qsys_mm_interconnect_0_avalon_st_adapter_015_error_adapter_0 error_adapter_0 (
.clk (in_clk_0_clk), // ... |
module sky130_fd_sc_hs__fill (
VPWR,
VGND,
VPB ,
VNB
);
// Module ports
input VPWR;
input VGND;
input VPB ;
input VNB ;
// No contents.
endmodule |
module sky130_fd_sc_hs__udp_dlatch$PR_pp$sN (
Q ,
D ,
GATE ,
RESET ,
SLEEP_B ,
NOTIFIER
);
output Q ;
input D ;
input GATE ;
input RESET ;
input SLEEP_B ;
input NOTIFIER;
endmodule |
module sky130_fd_sc_hvl__sdfstp (
Q ,
CLK ,
D ,
SCD ,
SCE ,
SET_B,
VPWR ,
VGND ,
VPB ,
VNB
);
output Q ;
input CLK ;
input D ;
input SCD ;
input SCE ;
input SET_B;
input VPWR ;
input VGND ;
input VPB ;
input VN... |
module pll_sys (
inclk0,
c0,
c1,
c2,
locked);
input inclk0;
output c0;
output c1;
output c2;
output locked;
endmodule |
module upd77c25_datrom (
clock,
data,
rdaddress,
wraddress,
wren,
q);
input clock;
input [15:0] data;
input [10:0] rdaddress;
input [10:0] wraddress;
input wren;
output [15:0] q;
`ifndef ALTERA_RESERVED_QIS
// synopsys translate_off
`endif
tri1 clock;
tri0 wren;
`ifndef ALTERA_RESERVED_QIS
//... |
module sfifo_15x16 (
aclr,
clock,
data,
rdreq,
wrreq,
almost_full,
empty,
full,
q,
usedw);
input aclr;
input clock;
input [14:0] data;
input rdreq;
input wrreq;
output almost_full;
output empty;
output full;
output [14:0] q;
output [3:0] usedw;
wire [3:0] sub_wire0;
wire sub_wi... |
module axis2buffer #(
parameter DWIDTH = 32,
parameter WIDTH = 8
)(
// Control signals
clk,
rstn,
// Color conversion signals
alive_color,
dead_color,
// AXIS Connection
S_AXIS_TDATA,
S_AXIS_TVALID,
S_AXIS_TREADY,
S_AXIS_TLAST,
// Output to conware com... |
module Frequency(
input wire clk,
input wire rst,
input wire rand,
output reg pass
);
parameter N = 20000, U = 10182, L = 9818;
reg [14:0] count_bits0, count_bits1, count_ones;
always @(posedge clk)
if (rst) begin
count_bits0 <= 15'H7FFF;
count_bits1 <= 0;
count_ones <= 0;
pass <= 0;
en... |
module sky130_fd_sc_ls__einvp (
Z ,
A ,
TE
);
// Module ports
output Z ;
input A ;
input TE;
// Name Output Other arguments
notif1 notif10 (Z , A, TE );
endmodule |
module t;
integer file;
integer r_i;
byte r_upb[20:10];
byte r_dnb[20:10];
reg [13:0] r_ups[20:10];
reg [13:0] r_dns[10:20];
reg [30:0] r_upi[20:10];
reg [30:0] r_dni[10:20];
reg [61:0] r_upq[20:10];
reg [61:0] r_dnq[10:20];
reg [71:0] r_upw[20:10];
reg [71:0] r_dnw[10:20];
... |
module ff_40x32_fwft (
aclr,
clock,
data,
rdreq,
wrreq,
empty,
full,
q,
usedw);
input aclr;
input clock;
input [39:0] data;
input rdreq;
input wrreq;
output empty;
output full;
output [39:0] q;
output [4:0] usedw;
wire [4:0] sub_wire0;
wire sub_wire1;
wire sub_wire2;
wire [39:0]... |
module sky130_fd_sc_ms__o22a (
//# {{data|Data Signals}}
input A1 ,
input A2 ,
input B1 ,
input B2 ,
output X ,
//# {{power|Power}}
input VPB ,
input VPWR,
input VGND,
input VNB
);
endmodule |
module pcie3_7x_0_pcie_pipe_lane #
(
parameter TCQ = 100,
parameter PIPE_PIPELINE_STAGES = 0 // 0 - 0 stages, 1 - 1 stage, 2 - 2 stages
) (
output wire [ 1:0] pipe_rx_char_is_k_o ,// Pipelined PIPE Rx Char Is K
output wire [31:0] pipe_rx_data_o ,// Pipelined PIPE ... |
module usb_system (
input wire clk_clk, // clk.clk
output wire [7:0] keycode_export, // keycode.export
input wire reset_reset_n, // reset.reset_n
output wire sdram_out_clk_clk, // sdram_out_clk.clk
output wire [12:0] sdram_wire_addr, // sd... |
module sky130_fd_sc_hs__a211o (
VPWR,
VGND,
X ,
A1 ,
A2 ,
B1 ,
C1
);
// Module ports
input VPWR;
input VGND;
output X ;
input A1 ;
input A2 ;
input B1 ;
input C1 ;
// Local signals
wire C1 and0_out ;
wire or0_out_X ... |
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