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-- megafunction wizard: %LPM_MUX%
-- GENERATION: STANDARD
-- VERSION: WM1.0
-- MODULE: LPM_MUX
-- ============================================================
-- File Name: lpm_mux0.vhd
-- Megafunction Name(s):
-- LPM_MUX
--
-- Simulation Library Files(s):
-- lpm
-- ============================================================
-- ************************************************************
-- THIS IS A WIZARD-GENERATED FILE. DO NOT EDIT THIS FILE!
--
-- 13.0.1 Build 232 06/12/2013 SP 1 SJ Web Edition
-- ************************************************************
--Copyright (C) 1991-2013 Altera Corporation
--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 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 Altera Program License
--Subscription Agreement, Altera MegaCore Function License
--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.
LIBRARY ieee;
USE ieee.std_logic_1164.all;
LIBRARY lpm;
USE lpm.lpm_components.all;
ENTITY lpm_mux0 IS
PORT
(
data0x : IN STD_LOGIC_VECTOR (22 DOWNTO 0);
data1x : IN STD_LOGIC_VECTOR (22 DOWNTO 0);
data2x : IN STD_LOGIC_VECTOR (22 DOWNTO 0);
data3x : IN STD_LOGIC_VECTOR (22 DOWNTO 0);
sel : IN STD_LOGIC_VECTOR (1 DOWNTO 0);
result : OUT STD_LOGIC_VECTOR (22 DOWNTO 0)
);
END lpm_mux0;
ARCHITECTURE SYN OF lpm_mux0 IS
-- type STD_LOGIC_2D is array (NATURAL RANGE <>, NATURAL RANGE <>) of STD_LOGIC;
SIGNAL sub_wire0 : STD_LOGIC_VECTOR (22 DOWNTO 0);
SIGNAL sub_wire1 : STD_LOGIC_VECTOR (22 DOWNTO 0);
SIGNAL sub_wire2 : STD_LOGIC_2D (3 DOWNTO 0, 22 DOWNTO 0);
SIGNAL sub_wire3 : STD_LOGIC_VECTOR (22 DOWNTO 0);
SIGNAL sub_wire4 : STD_LOGIC_VECTOR (22 DOWNTO 0);
SIGNAL sub_wire5 : STD_LOGIC_VECTOR (22 DOWNTO 0);
BEGIN
sub_wire5 <= data0x(22 DOWNTO 0);
sub_wire4 <= data1x(22 DOWNTO 0);
sub_wire3 <= data2x(22 DOWNTO 0);
result <= sub_wire0(22 DOWNTO 0);
sub_wire1 <= data3x(22 DOWNTO 0);
sub_wire2(3, 0) <= sub_wire1(0);
sub_wire2(3, 1) <= sub_wire1(1);
sub_wire2(3, 2) <= sub_wire1(2);
sub_wire2(3, 3) <= sub_wire1(3);
sub_wire2(3, 4) <= sub_wire1(4);
sub_wire2(3, 5) <= sub_wire1(5);
sub_wire2(3, 6) <= sub_wire1(6);
sub_wire2(3, 7) <= sub_wire1(7);
sub_wire2(3, 8) <= sub_wire1(8);
sub_wire2(3, 9) <= sub_wire1(9);
sub_wire2(3, 10) <= sub_wire1(10);
sub_wire2(3, 11) <= sub_wire1(11);
sub_wire2(3, 12) <= sub_wire1(12);
sub_wire2(3, 13) <= sub_wire1(13);
sub_wire2(3, 14) <= sub_wire1(14);
sub_wire2(3, 15) <= sub_wire1(15);
sub_wire2(3, 16) <= sub_wire1(16);
sub_wire2(3, 17) <= sub_wire1(17);
sub_wire2(3, 18) <= sub_wire1(18);
sub_wire2(3, 19) <= sub_wire1(19);
sub_wire2(3, 20) <= sub_wire1(20);
sub_wire2(3, 21) <= sub_wire1(21);
sub_wire2(3, 22) <= sub_wire1(22);
sub_wire2(2, 0) <= sub_wire3(0);
sub_wire2(2, 1) <= sub_wire3(1);
sub_wire2(2, 2) <= sub_wire3(2);
sub_wire2(2, 3) <= sub_wire3(3);
sub_wire2(2, 4) <= sub_wire3(4);
sub_wire2(2, 5) <= sub_wire3(5);
sub_wire2(2, 6) <= sub_wire3(6);
sub_wire2(2, 7) <= sub_wire3(7);
sub_wire2(2, 8) <= sub_wire3(8);
sub_wire2(2, 9) <= sub_wire3(9);
sub_wire2(2, 10) <= sub_wire3(10);
sub_wire2(2, 11) <= sub_wire3(11);
sub_wire2(2, 12) <= sub_wire3(12);
sub_wire2(2, 13) <= sub_wire3(13);
sub_wire2(2, 14) <= sub_wire3(14);
sub_wire2(2, 15) <= sub_wire3(15);
sub_wire2(2, 16) <= sub_wire3(16);
sub_wire2(2, 17) <= sub_wire3(17);
sub_wire2(2, 18) <= sub_wire3(18);
sub_wire2(2, 19) <= sub_wire3(19);
sub_wire2(2, 20) <= sub_wire3(20);
sub_wire2(2, 21) <= sub_wire3(21);
sub_wire2(2, 22) <= sub_wire3(22);
sub_wire2(1, 0) <= sub_wire4(0);
sub_wire2(1, 1) <= sub_wire4(1);
sub_wire2(1, 2) <= sub_wire4(2);
sub_wire2(1, 3) <= sub_wire4(3);
sub_wire2(1, 4) <= sub_wire4(4);
sub_wire2(1, 5) <= sub_wire4(5);
sub_wire2(1, 6) <= sub_wire4(6);
sub_wire2(1, 7) <= sub_wire4(7);
sub_wire2(1, 8) <= sub_wire4(8);
sub_wire2(1, 9) <= sub_wire4(9);
sub_wire2(1, 10) <= sub_wire4(10);
sub_wire2(1, 11) <= sub_wire4(11);
sub_wire2(1, 12) <= sub_wire4(12);
sub_wire2(1, 13) <= sub_wire4(13);
sub_wire2(1, 14) <= sub_wire4(14);
sub_wire2(1, 15) <= sub_wire4(15);
sub_wire2(1, 16) <= sub_wire4(16);
sub_wire2(1, 17) <= sub_wire4(17);
sub_wire2(1, 18) <= sub_wire4(18);
sub_wire2(1, 19) <= sub_wire4(19);
sub_wire2(1, 20) <= sub_wire4(20);
sub_wire2(1, 21) <= sub_wire4(21);
sub_wire2(1, 22) <= sub_wire4(22);
sub_wire2(0, 0) <= sub_wire5(0);
sub_wire2(0, 1) <= sub_wire5(1);
sub_wire2(0, 2) <= sub_wire5(2);
sub_wire2(0, 3) <= sub_wire5(3);
sub_wire2(0, 4) <= sub_wire5(4);
sub_wire2(0, 5) <= sub_wire5(5);
sub_wire2(0, 6) <= sub_wire5(6);
sub_wire2(0, 7) <= sub_wire5(7);
sub_wire2(0, 8) <= sub_wire5(8);
sub_wire2(0, 9) <= sub_wire5(9);
sub_wire2(0, 10) <= sub_wire5(10);
sub_wire2(0, 11) <= sub_wire5(11);
sub_wire2(0, 12) <= sub_wire5(12);
sub_wire2(0, 13) <= sub_wire5(13);
sub_wire2(0, 14) <= sub_wire5(14);
sub_wire2(0, 15) <= sub_wire5(15);
sub_wire2(0, 16) <= sub_wire5(16);
sub_wire2(0, 17) <= sub_wire5(17);
sub_wire2(0, 18) <= sub_wire5(18);
sub_wire2(0, 19) <= sub_wire5(19);
sub_wire2(0, 20) <= sub_wire5(20);
sub_wire2(0, 21) <= sub_wire5(21);
sub_wire2(0, 22) <= sub_wire5(22);
LPM_MUX_component : LPM_MUX
GENERIC MAP (
lpm_size => 4,
lpm_type => "LPM_MUX",
lpm_width => 23,
lpm_widths => 2
)
PORT MAP (
data => sub_wire2,
sel => sel,
result => sub_wire0
);
END SYN;
-- ============================================================
-- CNX file retrieval info
-- ============================================================
-- Retrieval info: PRIVATE: INTENDED_DEVICE_FAMILY STRING "Cyclone II"
-- Retrieval info: PRIVATE: SYNTH_WRAPPER_GEN_POSTFIX STRING "0"
-- Retrieval info: PRIVATE: new_diagram STRING "1"
-- Retrieval info: LIBRARY: lpm lpm.lpm_components.all
-- Retrieval info: CONSTANT: LPM_SIZE NUMERIC "4"
-- Retrieval info: CONSTANT: LPM_TYPE STRING "LPM_MUX"
-- Retrieval info: CONSTANT: LPM_WIDTH NUMERIC "23"
-- Retrieval info: CONSTANT: LPM_WIDTHS NUMERIC "2"
-- Retrieval info: USED_PORT: data0x 0 0 23 0 INPUT NODEFVAL "data0x[22..0]"
-- Retrieval info: USED_PORT: data1x 0 0 23 0 INPUT NODEFVAL "data1x[22..0]"
-- Retrieval info: USED_PORT: data2x 0 0 23 0 INPUT NODEFVAL "data2x[22..0]"
-- Retrieval info: USED_PORT: data3x 0 0 23 0 INPUT NODEFVAL "data3x[22..0]"
-- Retrieval info: USED_PORT: result 0 0 23 0 OUTPUT NODEFVAL "result[22..0]"
-- Retrieval info: USED_PORT: sel 0 0 2 0 INPUT NODEFVAL "sel[1..0]"
-- Retrieval info: CONNECT: @data 1 0 23 0 data0x 0 0 23 0
-- Retrieval info: CONNECT: @data 1 1 23 0 data1x 0 0 23 0
-- Retrieval info: CONNECT: @data 1 2 23 0 data2x 0 0 23 0
-- Retrieval info: CONNECT: @data 1 3 23 0 data3x 0 0 23 0
-- Retrieval info: CONNECT: @sel 0 0 2 0 sel 0 0 2 0
-- Retrieval info: CONNECT: result 0 0 23 0 @result 0 0 23 0
-- Retrieval info: GEN_FILE: TYPE_NORMAL lpm_mux0.vhd TRUE
-- Retrieval info: GEN_FILE: TYPE_NORMAL lpm_mux0.inc FALSE
-- Retrieval info: GEN_FILE: TYPE_NORMAL lpm_mux0.cmp TRUE
-- Retrieval info: GEN_FILE: TYPE_NORMAL lpm_mux0.bsf TRUE
-- Retrieval info: GEN_FILE: TYPE_NORMAL lpm_mux0_inst.vhd FALSE
-- Retrieval info: LIB_FILE: lpm
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