uaveiro-leci/1ano/isd/quartus-projects/DecoderDemo/simulation/qsim/DecoderDemo.vo

// Copyright (C) 2020  Intel Corporation. All rights reserved.
// Your use of Intel Corporation's design tools, logic functions 
// and other software and tools, and any partner logic 
// functions, and any output files from 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 Intel Program License 
// Subscription Agreement, the Intel Quartus Prime License Agreement,
// the Intel FPGA IP License Agreement, or other applicable license
// agreement, including, without limitation, that your use is for
// the sole purpose of programming logic devices manufactured by
// Intel and sold by Intel or its authorized distributors.  Please
// refer to the applicable agreement for further details, at
// https://fpgasoftware.intel.com/eula.

// VENDOR "Altera"
// PROGRAM "Quartus Prime"
// VERSION "Version 20.1.1 Build 720 11/11/2020 SJ Lite Edition"

// DATE "11/14/2022 21:42:11"

// 
// Device: Altera EP4CE6E22C6 Package TQFP144
// 

// 
// This Verilog file should be used for ModelSim-Altera (Verilog) only
// 

`timescale 1 ps/ 1 ps

module Dec2_4 (
	Y3,
	E0L,
	E1,
	X1,
	X0,
	Y2,
	Y1,
	Y0);
output 	Y3;
input 	E0L;
input 	E1;
input 	X1;
input 	X0;
output 	Y2;
output 	Y1;
output 	Y0;

// Design Ports Information
// Y3	=>  Location: PIN_33,	 I/O Standard: 2.5 V,	 Current Strength: Default
// Y2	=>  Location: PIN_32,	 I/O Standard: 2.5 V,	 Current Strength: Default
// Y1	=>  Location: PIN_28,	 I/O Standard: 2.5 V,	 Current Strength: Default
// Y0	=>  Location: PIN_34,	 I/O Standard: 2.5 V,	 Current Strength: Default
// E1	=>  Location: PIN_24,	 I/O Standard: 2.5 V,	 Current Strength: Default
// X0	=>  Location: PIN_25,	 I/O Standard: 2.5 V,	 Current Strength: Default
// X1	=>  Location: PIN_31,	 I/O Standard: 2.5 V,	 Current Strength: Default
// E0L	=>  Location: PIN_30,	 I/O Standard: 2.5 V,	 Current Strength: Default


wire gnd;
wire vcc;
wire unknown;

assign gnd = 1'b0;
assign vcc = 1'b1;
assign unknown = 1'bx;

tri1 devclrn;
tri1 devpor;
tri1 devoe;
wire \Y3~output_o ;
wire \Y2~output_o ;
wire \Y1~output_o ;
wire \Y0~output_o ;
wire \E1~input_o ;
wire \X1~input_o ;
wire \X0~input_o ;
wire \E0L~input_o ;
wire \inst~combout ;
wire \inst1~combout ;
wire \inst3~combout ;
wire \inst2~combout ;


hard_block auto_generated_inst(
	.devpor(devpor),
	.devclrn(devclrn),
	.devoe(devoe));

// Location: IOOBUF_X0_Y6_N23
cycloneive_io_obuf \Y3~output (
	.i(\inst~combout ),
	.oe(vcc),
	.seriesterminationcontrol(16'b0000000000000000),
	.devoe(devoe),
	.o(\Y3~output_o ),
	.obar());
// synopsys translate_off
defparam \Y3~output .bus_hold = "false";
defparam \Y3~output .open_drain_output = "false";
// synopsys translate_on

// Location: IOOBUF_X0_Y6_N16
cycloneive_io_obuf \Y2~output (
	.i(\inst1~combout ),
	.oe(vcc),
	.seriesterminationcontrol(16'b0000000000000000),
	.devoe(devoe),
	.o(\Y2~output_o ),
	.obar());
// synopsys translate_off
defparam \Y2~output .bus_hold = "false";
defparam \Y2~output .open_drain_output = "false";
// synopsys translate_on

// Location: IOOBUF_X0_Y9_N9
cycloneive_io_obuf \Y1~output (
	.i(\inst3~combout ),
	.oe(vcc),
	.seriesterminationcontrol(16'b0000000000000000),
	.devoe(devoe),
	.o(\Y1~output_o ),
	.obar());
// synopsys translate_off
defparam \Y1~output .bus_hold = "false";
defparam \Y1~output .open_drain_output = "false";
// synopsys translate_on

// Location: IOOBUF_X0_Y5_N16
cycloneive_io_obuf \Y0~output (
	.i(\inst2~combout ),
	.oe(vcc),
	.seriesterminationcontrol(16'b0000000000000000),
	.devoe(devoe),
	.o(\Y0~output_o ),
	.obar());
// synopsys translate_off
defparam \Y0~output .bus_hold = "false";
defparam \Y0~output .open_drain_output = "false";
// synopsys translate_on

// Location: IOIBUF_X0_Y11_N15
cycloneive_io_ibuf \E1~input (
	.i(E1),
	.ibar(gnd),
	.o(\E1~input_o ));
// synopsys translate_off
defparam \E1~input .bus_hold = "false";
defparam \E1~input .simulate_z_as = "z";
// synopsys translate_on

// Location: IOIBUF_X0_Y7_N1
cycloneive_io_ibuf \X1~input (
	.i(X1),
	.ibar(gnd),
	.o(\X1~input_o ));
// synopsys translate_off
defparam \X1~input .bus_hold = "false";
defparam \X1~input .simulate_z_as = "z";
// synopsys translate_on

// Location: IOIBUF_X0_Y11_N22
cycloneive_io_ibuf \X0~input (
	.i(X0),
	.ibar(gnd),
	.o(\X0~input_o ));
// synopsys translate_off
defparam \X0~input .bus_hold = "false";
defparam \X0~input .simulate_z_as = "z";
// synopsys translate_on

// Location: IOIBUF_X0_Y8_N15
cycloneive_io_ibuf \E0L~input (
	.i(E0L),
	.ibar(gnd),
	.o(\E0L~input_o ));
// synopsys translate_off
defparam \E0L~input .bus_hold = "false";
defparam \E0L~input .simulate_z_as = "z";
// synopsys translate_on

// Location: LCCOMB_X6_Y9_N8
cycloneive_lcell_comb inst(
// Equation(s):
// \inst~combout  = (\E1~input_o  & (!\X1~input_o  & (!\X0~input_o  & !\E0L~input_o )))

	.dataa(\E1~input_o ),
	.datab(\X1~input_o ),
	.datac(\X0~input_o ),
	.datad(\E0L~input_o ),
	.cin(gnd),
	.combout(\inst~combout ),
	.cout());
// synopsys translate_off
defparam inst.lut_mask = 16'h0002;
defparam inst.sum_lutc_input = "datac";
// synopsys translate_on

// Location: LCCOMB_X6_Y9_N2
cycloneive_lcell_comb inst1(
// Equation(s):
// \inst1~combout  = (\E1~input_o  & (!\X1~input_o  & (\X0~input_o  & !\E0L~input_o )))

	.dataa(\E1~input_o ),
	.datab(\X1~input_o ),
	.datac(\X0~input_o ),
	.datad(\E0L~input_o ),
	.cin(gnd),
	.combout(\inst1~combout ),
	.cout());
// synopsys translate_off
defparam inst1.lut_mask = 16'h0020;
defparam inst1.sum_lutc_input = "datac";
// synopsys translate_on

// Location: LCCOMB_X6_Y9_N28
cycloneive_lcell_comb inst3(
// Equation(s):
// \inst3~combout  = (\E1~input_o  & (\X1~input_o  & (\X0~input_o  & !\E0L~input_o )))

	.dataa(\E1~input_o ),
	.datab(\X1~input_o ),
	.datac(\X0~input_o ),
	.datad(\E0L~input_o ),
	.cin(gnd),
	.combout(\inst3~combout ),
	.cout());
// synopsys translate_off
defparam inst3.lut_mask = 16'h0080;
defparam inst3.sum_lutc_input = "datac";
// synopsys translate_on

// Location: LCCOMB_X6_Y9_N30
cycloneive_lcell_comb inst2(
// Equation(s):
// \inst2~combout  = (\E1~input_o  & (\X1~input_o  & (!\X0~input_o  & !\E0L~input_o )))

	.dataa(\E1~input_o ),
	.datab(\X1~input_o ),
	.datac(\X0~input_o ),
	.datad(\E0L~input_o ),
	.cin(gnd),
	.combout(\inst2~combout ),
	.cout());
// synopsys translate_off
defparam inst2.lut_mask = 16'h0008;
defparam inst2.sum_lutc_input = "datac";
// synopsys translate_on

assign Y3 = \Y3~output_o ;

assign Y2 = \Y2~output_o ;

assign Y1 = \Y1~output_o ;

assign Y0 = \Y0~output_o ;

endmodule

module hard_block (

	devpor,
	devclrn,
	devoe);

// Design Ports Information
// ~ALTERA_ASDO_DATA1~	=>  Location: PIN_6,	 I/O Standard: 2.5 V,	 Current Strength: Default
// ~ALTERA_FLASH_nCE_nCSO~	=>  Location: PIN_8,	 I/O Standard: 2.5 V,	 Current Strength: Default
// ~ALTERA_DCLK~	=>  Location: PIN_12,	 I/O Standard: 2.5 V,	 Current Strength: Default
// ~ALTERA_DATA0~	=>  Location: PIN_13,	 I/O Standard: 2.5 V,	 Current Strength: Default
// ~ALTERA_nCEO~	=>  Location: PIN_101,	 I/O Standard: 2.5 V,	 Current Strength: 8mA

input 	devpor;
input 	devclrn;
input 	devoe;

wire gnd;
wire vcc;
wire unknown;

assign gnd = 1'b0;
assign vcc = 1'b1;
assign unknown = 1'bx;

wire \~ALTERA_ASDO_DATA1~~padout ;
wire \~ALTERA_FLASH_nCE_nCSO~~padout ;
wire \~ALTERA_DATA0~~padout ;
wire \~ALTERA_ASDO_DATA1~~ibuf_o ;
wire \~ALTERA_FLASH_nCE_nCSO~~ibuf_o ;
wire \~ALTERA_DATA0~~ibuf_o ;


endmodule
Some quartus projects added 2023-01-11 18:07:46 +00:00			`// Copyright (C) 2020 Intel Corporation. All rights reserved.`
			`// Your use of Intel Corporation's design tools, logic functions`
			`// and other software and tools, and any partner logic`
			`// functions, and any output files from 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 Intel Program License`
			`// Subscription Agreement, the Intel Quartus Prime License Agreement,`
			`// the Intel FPGA IP License Agreement, or other applicable license`
			`// agreement, including, without limitation, that your use is for`
			`// the sole purpose of programming logic devices manufactured by`
			`// Intel and sold by Intel or its authorized distributors. Please`
			`// refer to the applicable agreement for further details, at`
			`// https://fpgasoftware.intel.com/eula.`

			`// VENDOR "Altera"`
			`// PROGRAM "Quartus Prime"`
			`// VERSION "Version 20.1.1 Build 720 11/11/2020 SJ Lite Edition"`

			`// DATE "11/14/2022 21:42:11"`

			`//`
			`// Device: Altera EP4CE6E22C6 Package TQFP144`
			`//`

			`//`
			`// This Verilog file should be used for ModelSim-Altera (Verilog) only`
			`//`

			`timescale 1 ps/ 1 ps

			`module Dec2_4 (`
			`Y3,`
			`E0L,`
			`E1,`
			`X1,`
			`X0,`
			`Y2,`
			`Y1,`
			`Y0);`
			`output Y3;`
			`input E0L;`
			`input E1;`
			`input X1;`
			`input X0;`
			`output Y2;`
			`output Y1;`
			`output Y0;`

			`// Design Ports Information`
			`// Y3 => Location: PIN_33, I/O Standard: 2.5 V, Current Strength: Default`
			`// Y2 => Location: PIN_32, I/O Standard: 2.5 V, Current Strength: Default`
			`// Y1 => Location: PIN_28, I/O Standard: 2.5 V, Current Strength: Default`
			`// Y0 => Location: PIN_34, I/O Standard: 2.5 V, Current Strength: Default`
			`// E1 => Location: PIN_24, I/O Standard: 2.5 V, Current Strength: Default`
			`// X0 => Location: PIN_25, I/O Standard: 2.5 V, Current Strength: Default`
			`// X1 => Location: PIN_31, I/O Standard: 2.5 V, Current Strength: Default`
			`// E0L => Location: PIN_30, I/O Standard: 2.5 V, Current Strength: Default`


			`wire gnd;`
			`wire vcc;`
			`wire unknown;`

			`assign gnd = 1'b0;`
			`assign vcc = 1'b1;`
			`assign unknown = 1'bx;`

			`tri1 devclrn;`
			`tri1 devpor;`
			`tri1 devoe;`
			`wire \Y3~output_o ;`
			`wire \Y2~output_o ;`
			`wire \Y1~output_o ;`
			`wire \Y0~output_o ;`
			`wire \E1~input_o ;`
			`wire \X1~input_o ;`
			`wire \X0~input_o ;`
			`wire \E0L~input_o ;`
			`wire \inst~combout ;`
			`wire \inst1~combout ;`
			`wire \inst3~combout ;`
			`wire \inst2~combout ;`


			`hard_block auto_generated_inst(`
			`.devpor(devpor),`
			`.devclrn(devclrn),`
			`.devoe(devoe));`

			`// Location: IOOBUF_X0_Y6_N23`
			`cycloneive_io_obuf \Y3~output (`
			`.i(\inst~combout ),`
			`.oe(vcc),`
			`.seriesterminationcontrol(16'b0000000000000000),`
			`.devoe(devoe),`
			`.o(\Y3~output_o ),`
			`.obar());`
			`// synopsys translate_off`
			`defparam \Y3~output .bus_hold = "false";`
			`defparam \Y3~output .open_drain_output = "false";`
			`// synopsys translate_on`

			`// Location: IOOBUF_X0_Y6_N16`
			`cycloneive_io_obuf \Y2~output (`
			`.i(\inst1~combout ),`
			`.oe(vcc),`
			`.seriesterminationcontrol(16'b0000000000000000),`
			`.devoe(devoe),`
			`.o(\Y2~output_o ),`
			`.obar());`
			`// synopsys translate_off`
			`defparam \Y2~output .bus_hold = "false";`
			`defparam \Y2~output .open_drain_output = "false";`
			`// synopsys translate_on`

			`// Location: IOOBUF_X0_Y9_N9`
			`cycloneive_io_obuf \Y1~output (`
			`.i(\inst3~combout ),`
			`.oe(vcc),`
			`.seriesterminationcontrol(16'b0000000000000000),`
			`.devoe(devoe),`
			`.o(\Y1~output_o ),`
			`.obar());`
			`// synopsys translate_off`
			`defparam \Y1~output .bus_hold = "false";`
			`defparam \Y1~output .open_drain_output = "false";`
			`// synopsys translate_on`

			`// Location: IOOBUF_X0_Y5_N16`
			`cycloneive_io_obuf \Y0~output (`
			`.i(\inst2~combout ),`
			`.oe(vcc),`
			`.seriesterminationcontrol(16'b0000000000000000),`
			`.devoe(devoe),`
			`.o(\Y0~output_o ),`
			`.obar());`
			`// synopsys translate_off`
			`defparam \Y0~output .bus_hold = "false";`
			`defparam \Y0~output .open_drain_output = "false";`
			`// synopsys translate_on`

			`// Location: IOIBUF_X0_Y11_N15`
			`cycloneive_io_ibuf \E1~input (`
			`.i(E1),`
			`.ibar(gnd),`
			`.o(\E1~input_o ));`
			`// synopsys translate_off`
			`defparam \E1~input .bus_hold = "false";`
			`defparam \E1~input .simulate_z_as = "z";`
			`// synopsys translate_on`

			`// Location: IOIBUF_X0_Y7_N1`
			`cycloneive_io_ibuf \X1~input (`
			`.i(X1),`
			`.ibar(gnd),`
			`.o(\X1~input_o ));`
			`// synopsys translate_off`
			`defparam \X1~input .bus_hold = "false";`
			`defparam \X1~input .simulate_z_as = "z";`
			`// synopsys translate_on`

			`// Location: IOIBUF_X0_Y11_N22`
			`cycloneive_io_ibuf \X0~input (`
			`.i(X0),`
			`.ibar(gnd),`
			`.o(\X0~input_o ));`
			`// synopsys translate_off`
			`defparam \X0~input .bus_hold = "false";`
			`defparam \X0~input .simulate_z_as = "z";`
			`// synopsys translate_on`

			`// Location: IOIBUF_X0_Y8_N15`
			`cycloneive_io_ibuf \E0L~input (`
			`.i(E0L),`
			`.ibar(gnd),`
			`.o(\E0L~input_o ));`
			`// synopsys translate_off`
			`defparam \E0L~input .bus_hold = "false";`
			`defparam \E0L~input .simulate_z_as = "z";`
			`// synopsys translate_on`

			`// Location: LCCOMB_X6_Y9_N8`
			`cycloneive_lcell_comb inst(`
			`// Equation(s):`
			`// \inst~combout = (\E1~input_o & (!\X1~input_o & (!\X0~input_o & !\E0L~input_o )))`

			`.dataa(\E1~input_o ),`
			`.datab(\X1~input_o ),`
			`.datac(\X0~input_o ),`
			`.datad(\E0L~input_o ),`
			`.cin(gnd),`
			`.combout(\inst~combout ),`
			`.cout());`
			`// synopsys translate_off`
			`defparam inst.lut_mask = 16'h0002;`
			`defparam inst.sum_lutc_input = "datac";`
			`// synopsys translate_on`

			`// Location: LCCOMB_X6_Y9_N2`
			`cycloneive_lcell_comb inst1(`
			`// Equation(s):`
			`// \inst1~combout = (\E1~input_o & (!\X1~input_o & (\X0~input_o & !\E0L~input_o )))`

			`.dataa(\E1~input_o ),`
			`.datab(\X1~input_o ),`
			`.datac(\X0~input_o ),`
			`.datad(\E0L~input_o ),`
			`.cin(gnd),`
			`.combout(\inst1~combout ),`
			`.cout());`
			`// synopsys translate_off`
			`defparam inst1.lut_mask = 16'h0020;`
			`defparam inst1.sum_lutc_input = "datac";`
			`// synopsys translate_on`

			`// Location: LCCOMB_X6_Y9_N28`
			`cycloneive_lcell_comb inst3(`
			`// Equation(s):`
			`// \inst3~combout = (\E1~input_o & (\X1~input_o & (\X0~input_o & !\E0L~input_o )))`

			`.dataa(\E1~input_o ),`
			`.datab(\X1~input_o ),`
			`.datac(\X0~input_o ),`
			`.datad(\E0L~input_o ),`
			`.cin(gnd),`
			`.combout(\inst3~combout ),`
			`.cout());`
			`// synopsys translate_off`
			`defparam inst3.lut_mask = 16'h0080;`
			`defparam inst3.sum_lutc_input = "datac";`
			`// synopsys translate_on`

			`// Location: LCCOMB_X6_Y9_N30`
			`cycloneive_lcell_comb inst2(`
			`// Equation(s):`
			`// \inst2~combout = (\E1~input_o & (\X1~input_o & (!\X0~input_o & !\E0L~input_o )))`

			`.dataa(\E1~input_o ),`
			`.datab(\X1~input_o ),`
			`.datac(\X0~input_o ),`
			`.datad(\E0L~input_o ),`
			`.cin(gnd),`
			`.combout(\inst2~combout ),`
			`.cout());`
			`// synopsys translate_off`
			`defparam inst2.lut_mask = 16'h0008;`
			`defparam inst2.sum_lutc_input = "datac";`
			`// synopsys translate_on`

			`assign Y3 = \Y3~output_o ;`

			`assign Y2 = \Y2~output_o ;`

			`assign Y1 = \Y1~output_o ;`

			`assign Y0 = \Y0~output_o ;`

			`endmodule`

			`module hard_block (`

			`devpor,`
			`devclrn,`
			`devoe);`

			`// Design Ports Information`
			`// ~ALTERA_ASDO_DATA1~ => Location: PIN_6, I/O Standard: 2.5 V, Current Strength: Default`
			`// ~ALTERA_FLASH_nCE_nCSO~ => Location: PIN_8, I/O Standard: 2.5 V, Current Strength: Default`
			`// ~ALTERA_DCLK~ => Location: PIN_12, I/O Standard: 2.5 V, Current Strength: Default`
			`// ~ALTERA_DATA0~ => Location: PIN_13, I/O Standard: 2.5 V, Current Strength: Default`
			`// ~ALTERA_nCEO~ => Location: PIN_101, I/O Standard: 2.5 V, Current Strength: 8mA`

			`input devpor;`
			`input devclrn;`
			`input devoe;`

			`wire gnd;`
			`wire vcc;`
			`wire unknown;`

			`assign gnd = 1'b0;`
			`assign vcc = 1'b1;`
			`assign unknown = 1'bx;`

			`wire \~ALTERA_ASDO_DATA1~~padout ;`
			`wire \~ALTERA_FLASH_nCE_nCSO~~padout ;`
			`wire \~ALTERA_DATA0~~padout ;`
			`wire \~ALTERA_ASDO_DATA1~~ibuf_o ;`
			`wire \~ALTERA_FLASH_nCE_nCSO~~ibuf_o ;`
			`wire \~ALTERA_DATA0~~ibuf_o ;`


			`endmodule`