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--------------------------------------------------------------------------------
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-- light52_muldiv.vhdl -- Simple multiplier/divider module.
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--------------------------------------------------------------------------------
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-- The 8051 mul and div instructions are both unsigned and operands are 8 bit.
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--
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-- This module implements the division as a sequential state machine which takes
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-- 8 cycles to complete. 
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-- The multiplier can be implemented as sequential or as combinational, in which
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-- case it will use a DSP block in those architectures that support it.
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-- No attempt has been made to make this module generic or reusable.
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--
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-- If you want a combinational multiplier but don't want to waste a DSP block 
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-- in this module, you need to modify this file adding whatever synthesis 
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-- pragmas your tool of choice needs.
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--
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-- Note that unlike the division state machine, the combinational product logic
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-- is always operating: when SEQUENTIAL_MULTIPLIER=true, prod_out equals 
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-- data_a * data_b with a latency of 1 clock cycle, and mul_ready is hardwired
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-- to '1'.
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--
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-- FIXME explain division algorithm.
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--------------------------------------------------------------------------------
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-- GENERICS:
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-- 
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-- SEQUENTIAL_MULTIPLIER        -- Sequential vs. combinational multiplier.
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--  When true, a sequential implementation will be used for the multiplier, 
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--  which will usually save a lot of logic or a dedicated multiplier.
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--  When false, a combinational registered multiplier will be used.
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--
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--------------------------------------------------------------------------------
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-- INTERFACE SIGNALS:
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--
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-- clk :            Clock, active rising edge.
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-- reset :          Synchronous reset. Clears only the control registers not
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--                  visible to the programmer -- not the output registers.
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-- 
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-- data_a :         Numerator input, should be connected to the ACC register.
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-- data_b :         Denominator input, should be connected to the B register.
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-- start :          Assert for 1 cycle to start the division state machine
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--                  (and the product if SEQUENTIAL_MULTIPLIER=true);
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-- 
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-- prod_out :       Product output, valid only when mul_ready='1'.
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-- quot_out :       Quotient output, valid only when div_ready='1'.
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-- rem_out :        Remainder output, valid only when div_ready='1'.
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-- div_ov_out :     Division overflow flag, valid only when div_ready='1'.
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-- mul_ov_out :     Product overflow flag, valid only when mul_ready='1'.
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-- 
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-- mul_ready :      Asserted permanently if SEQUENTIAL_MULTIPLIER=false.
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-- div_ready :      Deasserted the cycle after start is asserted.
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--                  Asserted when the division has completed.
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--
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--------------------------------------------------------------------------------
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-- Copyright (C) 2012 Jose A. Ruiz
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--                                                              
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-- This source file may be used and distributed without         
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-- restriction provided that this copyright statement is not    
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-- removed from the file and that any derivative work contains  
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-- the original copyright notice and the associated disclaimer. 
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--                                                              
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-- This source file is free software; you can redistribute it   
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-- and/or modify it under the terms of the GNU Lesser General   
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-- Public License as published by the Free Software Foundation; 
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-- either version 2.1 of the License, or (at your option) any   
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-- later version.                                               
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--                                                              
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-- This source is distributed in the hope that it will be       
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-- useful, but WITHOUT ANY WARRANTY; without even the implied   
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-- warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR      
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-- PURPOSE.  See the GNU Lesser General Public License for more 
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-- details.                                                     
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--                                                              
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-- You should have received a copy of the GNU Lesser General    
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-- Public License along with this source; if not, download it   
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-- from http://www.opencores.org/lgpl.shtml
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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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use work.light52_pkg.all;
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use work.light52_ucode_pkg.all;
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entity light52_muldiv is
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    generic (
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        SEQUENTIAL_MULTIPLIER : boolean := false
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    );
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    port(
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        clk :                   in std_logic;
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        reset :                 in std_logic;
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        data_a :                in t_byte;
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        data_b :                in t_byte;
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        start :                 in std_logic;
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        prod_out :              out t_word;
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        quot_out :              out t_byte;
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        rem_out :               out t_byte;
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        div_ov_out :            out std_logic;
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        mul_ov_out :            out std_logic;
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        mul_ready :             out std_logic;
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        div_ready :             out std_logic
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    );
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end entity light52_muldiv;
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architecture sequential of light52_muldiv is
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signal bit_ctr :            integer range 0 to 8;
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signal b_shift_reg :        t_word;
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signal den_ge_256 :         std_logic;
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signal num_ge_den :         std_logic;
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signal sub_num :            std_logic;
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signal denominator :        t_byte;
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signal rem_reg :            t_byte;
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signal quot_reg :           t_byte;
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signal prod_reg :           t_word;
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signal ready :              std_logic;
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signal load_regs :          std_logic;
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begin
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-- Control logic ---------------------------------------------------------------
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control_counter:
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process(clk)
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begin
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    if clk'event and clk='1' then
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        if reset='1' then
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            bit_ctr <= 8;
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        else
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            if load_regs='1' then
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                bit_ctr <= 0;
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            elsif bit_ctr /= 8 then
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                bit_ctr <= bit_ctr + 1;
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            end if;
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        end if;
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    end if;
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end process control_counter;
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-- Internal signal ready is asserted after 8 cycles.
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-- The sequential multiplier will use this signal too, IF it takes 8 cycles.
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ready <= '1' when bit_ctr >= 8 else '0';
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---- Divider logic -------------------------------------------------------------
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-- What we do is a simple base-2 'shift-and-subtract' algorithm that takes
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-- 8 cycles to complete. We can get away with this because we deal with unsigned
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-- numbers only.
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divider_registers:
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process(clk)
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begin
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    if clk'event and clk='1' then
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        -- denominator shift register
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        if load_regs='1' then
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            b_shift_reg <= "0" & data_b & "0000000";
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            -- Division overflow can be determined upon loading B reg data.
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            -- OV will be raised only on div-by-zero.
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            if data_b=X"00" then
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                div_ov_out <= '1';
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            else
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                div_ov_out <= '0';
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            end if;
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        else
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            b_shift_reg <= "0" & b_shift_reg(b_shift_reg'high downto 1);
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        end if;
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        -- numerator register
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        if load_regs='1' then
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            rem_reg <= data_a;
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        elsif bit_ctr/=8 and sub_num='1' then
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            rem_reg <= rem_reg - denominator;
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        end if;
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        --- quotient register
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        if load_regs='1' then
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            quot_reg <= (others => '0');
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        elsif bit_ctr/=8 then
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            quot_reg <= quot_reg(quot_reg'high-1 downto 0) & sub_num;
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        end if;
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        load_regs <= start;
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    end if;
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end process divider_registers;
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denominator <= b_shift_reg(7 downto 0);
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-- The 16-bit comparison between b_shift_reg (denominator) and the zero-extended 
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-- rem_reg (numerator) can be simplified by splitting it in 2: 
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-- If the shifted denominator high byte is not zero, it is >=256...
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den_ge_256 <= '1' when b_shift_reg(15 downto 8) /= X"00" else '0';
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-- ...otherwise we need to compare the low bytes.
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num_ge_den <= '1' when rem_reg >= denominator else '0';
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sub_num <= '1' when den_ge_256='0' and num_ge_den='1' else '0';
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quot_out <= quot_reg;
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prod_out <= prod_reg;
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rem_out <= rem_reg;
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div_ready <= ready;
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---- Multiplier logic ----------------------------------------------------------
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---- Combinational multiplier -----------------------------
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multiplier_combinational:
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if not SEQUENTIAL_MULTIPLIER generate
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registered_combinational_multiplier:
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process(clk)
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begin
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    if clk'event and clk='1' then
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        prod_reg <= data_a * data_b; -- t_byte is unsigned
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    end if;
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end process registered_combinational_multiplier;
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-- The multiplier output is valid in the cycle after the operands are loaded,
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-- so by the time MUL is executed it's already done.
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mul_ready <= '1';
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mul_ov_out <= '1' when prod_reg(15 downto 8)/=X"00" else '0';
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prod_out <= prod_reg;
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end generate multiplier_combinational;
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---- Sequential multiplier --------------------------------
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multiplier_sequential:
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if SEQUENTIAL_MULTIPLIER generate
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assert false
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report "Sequential multiplier implementation not done yet."&
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       " Use combinational implementation."
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severity failure;
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end generate multiplier_sequential;
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end sequential;

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