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------------------------------------------------------------------------------
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-- This file is a part of the LPP VHDL IP LIBRARY
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-- Copyright (C) 2009 - 2010, Laboratory of Plasmas Physic - CNRS
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--
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-- This program is free software; you can redistribute it and/or modify
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-- it under the terms of the GNU General Public License as published by
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-- the Free Software Foundation; either version 3 of the License, or
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-- (at your option) any later version.
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--
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-- This program is distributed in the hope that it will be useful,
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-- but WITHOUT ANY WARRANTY; without even the implied warranty of
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-- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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-- GNU General Public License for more details.
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--
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-- You should have received a copy of the GNU General Public License
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-- along with this program; if not, write to the Free Software
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-- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
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-------------------------------------------------------------------------------
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-- Author : Jean-christophe Pellion
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-- Mail : jean-christophe.pellion@lpp.polytechnique.fr
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-- jean-christophe.pellion@easii-ic.com
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----------------------------------------------------------------------------
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LIBRARY ieee;
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USE ieee.std_logic_1164.ALL;
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USE ieee.numeric_std.all;
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LIBRARY lpp;
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USE lpp.cic_pkg.ALL;
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USE lpp.data_type_pkg.ALL;
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USE lpp.iir_filter.ALL;
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LIBRARY techmap;
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USE techmap.gencomp.ALL;
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ENTITY cic_lfr_r2 IS
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GENERIC(
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tech : INTEGER := 0;
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use_RAM_nCEL : INTEGER := 0 -- 1 => RAM(tech) , 0 => RAM_CEL
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);
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PORT (
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clk : IN STD_LOGIC;
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rstn : IN STD_LOGIC;
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run : IN STD_LOGIC;
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param_r2 : IN STD_LOGIC;
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data_in : IN sample_vector(7 DOWNTO 0,15 DOWNTO 0);
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data_in_valid : IN STD_LOGIC;
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data_out_16 : OUT sample_vector(5 DOWNTO 0,15 DOWNTO 0);
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data_out_16_valid : OUT STD_LOGIC;
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data_out_256 : OUT sample_vector(5 DOWNTO 0,15 DOWNTO 0);
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data_out_256_valid : OUT STD_LOGIC
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);
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END cic_lfr_r2;
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ARCHITECTURE beh OF cic_lfr_r2 IS
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--
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SIGNAL sel_sample : STD_LOGIC_VECTOR(2 DOWNTO 0);
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SIGNAL sample_temp : sample_vector(5 DOWNTO 0,15 DOWNTO 0);
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SIGNAL sample : STD_LOGIC_VECTOR(15 DOWNTO 0);
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--
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SIGNAL sel_A : STD_LOGIC_VECTOR(1 DOWNTO 0);
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SIGNAL data_A_temp : sample_vector(2 DOWNTO 0,15 DOWNTO 0);
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SIGNAL data_A : STD_LOGIC_VECTOR(15 DOWNTO 0);
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--
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SIGNAL ALU_OP : STD_LOGIC_VECTOR(1 DOWNTO 0);
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SIGNAL data_B : STD_LOGIC_VECTOR(15 DOWNTO 0);
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SIGNAL data_B_reg : STD_LOGIC_VECTOR(15 DOWNTO 0);
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SIGNAL data_out : STD_LOGIC_VECTOR(15 DOWNTO 0);
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SIGNAL data_in_Carry : STD_LOGIC;
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SIGNAL data_out_Carry : STD_LOGIC;
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--
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CONSTANT S_parameter : INTEGER := 3;
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SIGNAL carry_reg : STD_LOGIC_VECTOR(S_parameter-1 DOWNTO 0);
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--
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SIGNAL OPERATION : STD_LOGIC_VECTOR(15 DOWNTO 0);
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SIGNAL OPERATION_reg: STD_LOGIC_VECTOR(15 DOWNTO 0);
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SIGNAL OPERATION_reg2: STD_LOGIC_VECTOR(15 DOWNTO 0);
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-----------------------------------------------------------------------------
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TYPE ARRAY_OF_ADDR IS ARRAY (7 DOWNTO 0) OF STD_LOGIC_VECTOR(8 DOWNTO 0);
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SIGNAL base_addr_INT : ARRAY_OF_ADDR;
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CONSTANT base_addr_delta : INTEGER := 40;
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SIGNAL addr_base_sel : STD_LOGIC_VECTOR(8 DOWNTO 0);
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SIGNAL addr_gen: STD_LOGIC_VECTOR(8 DOWNTO 0);
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SIGNAL addr_read: STD_LOGIC_VECTOR(8 DOWNTO 0);
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SIGNAL addr_write: STD_LOGIC_VECTOR(8 DOWNTO 0);
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SIGNAL addr_write_s: STD_LOGIC_VECTOR(8 DOWNTO 0);
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SIGNAL data_we: STD_LOGIC;
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SIGNAL data_we_s: STD_LOGIC;
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SIGNAL data_wen : STD_LOGIC;
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-----------------------------------------------------------------------------
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SIGNAL sample_out_reg16 : sample_vector(8*2-1 DOWNTO 0, 15 DOWNTO 0);
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SIGNAL sample_out_reg256 : sample_vector(6*3-1 DOWNTO 0, 15 DOWNTO 0);
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SIGNAL sample_valid_reg16 : STD_LOGIC_VECTOR(8*2 DOWNTO 0);
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SIGNAL sample_valid_reg256: STD_LOGIC_VECTOR(6*3 DOWNTO 0);
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SIGNAL data_out_16_valid_s : STD_LOGIC;
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SIGNAL data_out_256_valid_s : STD_LOGIC;
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SIGNAL data_out_16_valid_s1 : STD_LOGIC;
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SIGNAL data_out_256_valid_s1 : STD_LOGIC;
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SIGNAL data_out_16_valid_s2 : STD_LOGIC;
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SIGNAL data_out_256_valid_s2 : STD_LOGIC;
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-----------------------------------------------------------------------------
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SIGNAL sample_out_reg16_s : sample_vector(5 DOWNTO 0, 16*2-1 DOWNTO 0);
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SIGNAL sample_out_reg256_s : sample_vector(5 DOWNTO 0, 16*3-1 DOWNTO 0);
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-----------------------------------------------------------------------------
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BEGIN
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PROCESS (clk, rstn)
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BEGIN -- PROCESS
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IF rstn = '0' THEN -- asynchronous reset (active low)
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data_B_reg <= (OTHERS => '0');
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OPERATION_reg <= (OTHERS => '0');
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OPERATION_reg2 <= (OTHERS => '0');
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ELSIF clk'event AND clk = '1' THEN -- rising clock edge
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OPERATION_reg <= OPERATION;
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OPERATION_reg2 <= OPERATION_reg;
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data_B_reg <= data_B;
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END IF;
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END PROCESS;
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-----------------------------------------------------------------------------
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-- SEL_SAMPLE
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-----------------------------------------------------------------------------
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sel_sample <= OPERATION_reg(2 DOWNTO 0);
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all_bit: FOR I IN 15 DOWNTO 0 GENERATE
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sample_temp(0,I) <= data_in(0,I) WHEN sel_sample(0) = '0' ELSE data_in(1,I);
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sample_temp(1,I) <= data_in(2,I) WHEN sel_sample(0) = '0' ELSE data_in(3,I);
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sample_temp(2,I) <= data_in(4,I) WHEN sel_sample(0) = '0' ELSE data_in(5,I);
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sample_temp(3,I) <= data_in(6,I) WHEN sel_sample(0) = '0' ELSE data_in(7,I);
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sample_temp(4,I) <= sample_temp(0,I) WHEN sel_sample(1) = '0' ELSE sample_temp(1,I);
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sample_temp(5,I) <= sample_temp(2,I) WHEN sel_sample(1) = '0' ELSE sample_temp(3,I);
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sample(I) <= sample_temp(4,I) WHEN sel_sample(2) = '0' ELSE sample_temp(5,I);
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END GENERATE all_bit;
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-----------------------------------------------------------------------------
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-- SEL_DATA_IN_A
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-----------------------------------------------------------------------------
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sel_A <= OPERATION_reg(4 DOWNTO 3);
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all_data_mux_A: FOR I IN 15 DOWNTO 0 GENERATE
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data_A_temp(0,I) <= sample(I) WHEN sel_A(0) = '0' ELSE data_out(I);
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data_A_temp(1,I) <= '0' WHEN sel_A(0) = '0' ELSE sample(15);
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data_A_temp(2,I) <= data_A_temp(0,I) WHEN sel_A(1) = '0' ELSE data_A_temp(1,I);
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data_A(I) <= data_A_temp(2,I) WHEN OPERATION_reg(14) = '0' ELSE data_B_reg(I);
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END GENERATE all_data_mux_A;
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-----------------------------------------------------------------------------
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-- ALU
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-----------------------------------------------------------------------------
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ALU_OP <= OPERATION_reg(6 DOWNTO 5);
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ALU: cic_lfr_add_sub
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PORT MAP (
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clk => clk,
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rstn => rstn,
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run => run,
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OP => ALU_OP,
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data_in_A => data_A,
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data_in_B => data_B,
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data_in_Carry => data_in_Carry,
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data_out => data_out,
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data_out_Carry => data_out_Carry);
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-----------------------------------------------------------------------------
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-- CARRY_MANAGER
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-----------------------------------------------------------------------------
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data_in_Carry <= carry_reg(S_parameter-2) WHEN OPERATION_reg(7) = '0' ELSE carry_reg(S_parameter-1);
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-- CARRY_PUSH <= OPERATION_reg(7);
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-- CARRY_POP <= OPERATION_reg(6);
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PROCESS (clk, rstn)
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BEGIN -- PROCESS
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IF rstn = '0' THEN -- asynchronous reset (active low)
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carry_reg <= (OTHERS => '0');
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ELSIF clk'event AND clk = '1' THEN -- rising clock edge
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--IF CARRY_POP = '1' OR CARRY_PUSH = '1' THEN
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carry_reg(S_parameter-1 DOWNTO 1) <= carry_reg(S_parameter-2 DOWNTO 0);
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carry_reg(0) <= data_out_Carry;
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--END IF;
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END IF;
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END PROCESS;
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-----------------------------------------------------------------------------
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-- MEMORY
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-----------------------------------------------------------------------------
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all_bit_base_ADDR: FOR J IN 8 DOWNTO 0 GENERATE
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all_channel: FOR I IN 7 DOWNTO 0 GENERATE
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base_addr_INT(I)(J) <= '1' WHEN (base_addr_delta * I/(2**J)) MOD 2 = 1 ELSE '0';
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END GENERATE all_channel;
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END GENERATE all_bit_base_ADDR;
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addr_base_sel <= base_addr_INT(to_integer(UNSIGNED(OPERATION(2 DOWNTO 0))));
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cic_lfr_address_gen_1: cic_lfr_address_gen
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GENERIC MAP (
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ADDR_SIZE => 9)
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PORT MAP (
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clk => clk,
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rstn => rstn,
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run => run,
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addr_base => addr_base_sel,
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addr_init => OPERATION(8),
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addr_add_1 => OPERATION(9),
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addr => addr_gen);
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addr_read <= addr_gen WHEN OPERATION(12 DOWNTO 10) = "000" ELSE
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STD_LOGIC_VECTOR(to_unsigned(to_integer(UNSIGNED(addr_base_sel))+2,9)) WHEN OPERATION(12 DOWNTO 10) = "001" ELSE
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STD_LOGIC_VECTOR(to_unsigned(to_integer(UNSIGNED(addr_base_sel))+5,9)) WHEN OPERATION(12 DOWNTO 10) = "010" ELSE
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STD_LOGIC_VECTOR(to_unsigned(to_integer(UNSIGNED(addr_base_sel))+8,9)) WHEN OPERATION(12 DOWNTO 10) = "011" ELSE
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STD_LOGIC_VECTOR(to_unsigned(to_integer(UNSIGNED(addr_gen ))+6,9)) WHEN OPERATION(12 DOWNTO 10) = "100" ELSE
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STD_LOGIC_VECTOR(to_unsigned(to_integer(UNSIGNED(addr_gen ))+15,9));
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PROCESS (clk, rstn)
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BEGIN -- PROCESS
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IF rstn = '0' THEN -- asynchronous reset (active low)
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addr_write <= (OTHERS => '0');
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data_we <= '0';
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addr_write_s <= (OTHERS => '0');
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data_we_s <= '0';
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ELSIF clk'event AND clk = '1' THEN -- rising clock edge
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addr_write_s <= addr_read;
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data_we_s <= OPERATION(13);
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IF OPERATION_reg(15) = '0' THEN
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addr_write <= addr_write_s;
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ELSE
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addr_write <= addr_read;
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END IF;
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data_we <= data_we_s;
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END IF;
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END PROCESS;
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memCEL : IF use_RAM_nCEL = 0 GENERATE
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data_wen <= NOT data_we;
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RAMblk : RAM_CEL
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GENERIC MAP(16, 9)
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PORT MAP(
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WD => data_out,
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RD => data_B,
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WEN => data_wen,
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REN => '0',
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WADDR => addr_write,
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RADDR => addr_read,
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RWCLK => clk,
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RESET => rstn
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) ;
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END GENERATE;
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memRAM : IF use_RAM_nCEL = 1 GENERATE
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SRAM : syncram_2p
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GENERIC MAP(tech, 9, 16)
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PORT MAP(clk, '1', addr_read, data_B,
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clk, data_we, addr_write, data_out);
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END GENERATE;
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-----------------------------------------------------------------------------
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-- CONTROL
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-----------------------------------------------------------------------------
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cic_lfr_control_1: cic_lfr_control_r2
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PORT MAP (
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clk => clk,
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rstn => rstn,
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run => run,
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data_in_valid => data_in_valid,
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data_out_16_valid => data_out_16_valid_s,
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data_out_256_valid => data_out_256_valid_s,
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OPERATION => OPERATION);
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-----------------------------------------------------------------------------
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PROCESS (clk, rstn)
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BEGIN -- PROCESS
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IF rstn = '0' THEN -- asynchronous reset (active low)
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data_out_16_valid_s1 <= '0';
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data_out_256_valid_s1 <= '0';
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data_out_16_valid_s2 <= '0';
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data_out_256_valid_s2 <= '0';
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ELSIF clk'event AND clk = '1' THEN -- rising clock edge
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data_out_16_valid_s1 <= data_out_16_valid_s;
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data_out_256_valid_s1 <= data_out_256_valid_s;
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data_out_16_valid_s2 <= data_out_16_valid_s1;
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data_out_256_valid_s2 <= data_out_256_valid_s1;
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END IF;
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END PROCESS;
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PROCESS (clk, rstn)
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BEGIN -- PROCESS
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IF rstn = '0' THEN -- asynchronous reset (active low)
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sample_valid_reg16 <= "00000" & "000000" & "000001";
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sample_valid_reg256 <= '0' & "000000" & "000000" & "000001";
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ELSIF clk'event AND clk = '1' THEN -- rising clock edge
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IF run = '0' THEN
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sample_valid_reg16 <= "00000" & "000000" & "000001";
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sample_valid_reg256 <= '0' & "000000" & "000000" & "000001";
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ELSE
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IF data_out_16_valid_s2 = '1' OR sample_valid_reg16(8*2) = '1' THEN
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sample_valid_reg16 <= sample_valid_reg16(8*2-1 DOWNTO 0) & sample_valid_reg16(8*2);
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END IF;
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IF data_out_256_valid_s2 = '1' OR sample_valid_reg256(6*3) = '1' THEN
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sample_valid_reg256 <= sample_valid_reg256(6*3-1 DOWNTO 0) & sample_valid_reg256(6*3);
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END IF;
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END IF;
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END IF;
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END PROCESS;
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data_out_16_valid <= sample_valid_reg16(8*2);
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data_out_256_valid <= sample_valid_reg256(6*3);
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-----------------------------------------------------------------------------
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all_bits: FOR J IN 15 DOWNTO 0 GENERATE
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all_channel_out16: FOR I IN 8*2-1 DOWNTO 0 GENERATE
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PROCESS (clk, rstn)
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BEGIN -- PROCESS
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IF rstn = '0' THEN -- asynchronous reset (active low)
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sample_out_reg16(I,J) <= '0';
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ELSIF clk'event AND clk = '1' THEN -- rising clock edge
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IF run = '0' THEN
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sample_out_reg16(I,J) <= '0';
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ELSE
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IF sample_valid_reg16(I) = '1' AND data_out_16_valid_s2 = '1' THEN
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sample_out_reg16(I,J) <= data_out(J);
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END IF;
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END IF;
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END IF;
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END PROCESS;
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END GENERATE all_channel_out16;
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all_channel_out256: FOR I IN 6*3-1 DOWNTO 0 GENERATE
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PROCESS (clk, rstn)
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BEGIN -- PROCESS
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IF rstn = '0' THEN -- asynchronous reset (active low)
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sample_out_reg256(I,J) <= '0';
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ELSIF clk'event AND clk = '1' THEN -- rising clock edge
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IF run = '0' THEN
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sample_out_reg256(I,J) <= '0';
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ELSE
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IF sample_valid_reg256(I) = '1' AND data_out_256_valid_s2 = '1' THEN
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sample_out_reg256(I,J) <= data_out(J);
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END IF;
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END IF;
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END IF;
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END PROCESS;
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END GENERATE all_channel_out256;
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END GENERATE all_bits;
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all_bits_16: FOR J IN 15 DOWNTO 0 GENERATE
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all_reg_16: FOR K IN 1 DOWNTO 0 GENERATE
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sample_out_reg16_s(0,J+(K*16)) <= sample_out_reg16(2*0+K,J);
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sample_out_reg16_s(1,J+(K*16)) <= sample_out_reg16(2*1+K,J) WHEN param_r2 = '1' ELSE sample_out_reg16(2*6+K,J);
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sample_out_reg16_s(2,J+(K*16)) <= sample_out_reg16(2*2+K,J) WHEN param_r2 = '1' ELSE sample_out_reg16(2*7+K,J);
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sample_out_reg16_s(3,J+(K*16)) <= sample_out_reg16(2*3+K,J);
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sample_out_reg16_s(4,J+(K*16)) <= sample_out_reg16(2*4+K,J);
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sample_out_reg16_s(5,J+(K*16)) <= sample_out_reg16(2*5+K,J);
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END GENERATE all_reg_16;
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END GENERATE all_bits_16;
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all_channel_out_256: FOR I IN 5 DOWNTO 0 GENERATE
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all_bits_256: FOR J IN 15 DOWNTO 0 GENERATE
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all_reg_256: FOR K IN 2 DOWNTO 0 GENERATE
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sample_out_reg256_s(I,J+(K*16)) <= sample_out_reg256(3*I+K,J);
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END GENERATE all_reg_256;
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END GENERATE all_bits_256;
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END GENERATE all_channel_out_256;
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all_channel_out_v: FOR I IN 5 DOWNTO 0 GENERATE
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all_bits: FOR J IN 15 DOWNTO 0 GENERATE
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data_out_256(I,J) <= sample_out_reg256_s(I,J+16*2-32+27);
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data_out_16(I,J) <= sample_out_reg16_s (I,J+16 -16+15);
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END GENERATE all_bits;
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END GENERATE all_channel_out_v;
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END beh;
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