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-------------------------------------------------------------------------------
-- 
-- Copyright (C) 2009, 2010 Dr. Juergen Sauermann
-- 
--  This code is free software: you can redistribute it and/or modify
--  it under the terms of the GNU General Public License as published by
--  the Free Software Foundation, either version 3 of the License, or
--  (at your option) any later version.
--
--  This code is distributed in the hope that it will be useful,
--  but WITHOUT ANY WARRANTY; without even the implied warranty of
--  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
--  GNU General Public License for more details.
--
--  You should have received a copy of the GNU General Public License
--  along with this code (see the file named COPYING).
--  If not, see http://www.gnu.org/licenses/.
--
-------------------------------------------------------------------------------
-------------------------------------------------------------------------------
--
-- Module Name:    RegisterFile - Behavioral 
-- Create Date:    12:43:34 10/28/2009 
-- Description:    a register file (16 register pairs) of a CPU.
--
-------------------------------------------------------------------------------
--
library IEEE;
use IEEE.STD_LOGIC_1164.ALL;
use IEEE.STD_LOGIC_ARITH.ALL;
use IEEE.STD_LOGIC_UNSIGNED.ALL;
 
use work.common.ALL;
 
entity register_file is
    port (  I_CLK       : in  std_logic;
 
            I_AMOD      : in  std_logic_vector( 5 downto 0);
            I_COND      : in  std_logic_vector( 3 downto 0);
            I_DDDDD     : in  std_logic_vector( 4 downto 0);
            I_DIN       : in  std_logic_vector(15 downto 0);
            I_FLAGS     : in  std_logic_vector( 7 downto 0);
            I_IMM       : in  std_logic_vector(15 downto 0);
            I_RRRR      : in  std_logic_vector( 4 downto 1);
            I_WE_01     : in  std_logic;
            I_WE_D      : in  std_logic_vector( 1 downto 0);
            I_WE_F      : in  std_logic;
            I_WE_M      : in  std_logic;
            I_WE_XYZS   : in  std_logic;
 
            Q_ADR       : out std_logic_vector(15 downto 0);
            Q_CC        : out std_logic;
            Q_D         : out std_logic_vector(15 downto 0);
            Q_FLAGS     : out std_logic_vector( 7 downto 0);
            Q_R         : out std_logic_vector(15 downto 0);
            Q_S         : out std_logic_vector( 7 downto 0);
            Q_Z         : out std_logic_vector(15 downto 0));
end register_file;
 
architecture Behavioral of register_file is
 
component reg_16
    port (  I_CLK       : in    std_logic;
 
            I_D         : in    std_logic_vector(15 downto 0);
            I_WE        : in    std_logic_vector( 1 downto 0);
 
            Q           : out   std_logic_vector(15 downto 0));
end component;
 
signal R_R00            : std_logic_vector(15 downto 0);
signal R_R02            : std_logic_vector(15 downto 0);
signal R_R04            : std_logic_vector(15 downto 0);
signal R_R06            : std_logic_vector(15 downto 0);
signal R_R08            : std_logic_vector(15 downto 0);
signal R_R10            : std_logic_vector(15 downto 0);
signal R_R12            : std_logic_vector(15 downto 0);
signal R_R14            : std_logic_vector(15 downto 0);
signal R_R16            : std_logic_vector(15 downto 0);
signal R_R18            : std_logic_vector(15 downto 0);
signal R_R20            : std_logic_vector(15 downto 0);
signal R_R22            : std_logic_vector(15 downto 0);
signal R_R24            : std_logic_vector(15 downto 0);
signal R_R26            : std_logic_vector(15 downto 0);
signal R_R28            : std_logic_vector(15 downto 0);
signal R_R30            : std_logic_vector(15 downto 0);
signal R_SP             : std_logic_vector(15 downto 0);    -- stack pointer
 
component status_reg is
    port (  I_CLK       : in  std_logic;
 
            I_COND      : in  std_logic_vector ( 3 downto 0);
            I_DIN       : in  std_logic_vector ( 7 downto 0);
            I_FLAGS     : in  std_logic_vector ( 7 downto 0);
            I_WE_F      : in  std_logic;
            I_WE_SR     : in  std_logic;
 
            Q           : out std_logic_vector ( 7 downto 0);
            Q_CC        : out std_logic);
end component;
 
signal S_FLAGS          : std_logic_vector( 7 downto 0);
 
signal L_ADR            : std_logic_vector(15 downto 0);
signal L_BASE           : std_logic_vector(15 downto 0);
signal L_DDDD           : std_logic_vector( 4 downto 1);
signal L_DSP            : std_logic_vector(15 downto 0);
signal L_DX             : std_logic_vector(15 downto 0);
signal L_DY             : std_logic_vector(15 downto 0);
signal L_DZ             : std_logic_vector(15 downto 0);
signal L_PRE            : std_logic_vector(15 downto 0);
signal L_POST           : std_logic_vector(15 downto 0);
signal L_S              : std_logic_vector(15 downto 0);
signal L_WE_SP_AMOD     : std_logic;
signal L_WE             : std_logic_vector(31 downto 0);
signal L_WE_A           : std_logic;
signal L_WE_D           : std_logic_vector(31 downto 0);
signal L_WE_D2          : std_logic_vector( 1 downto 0);
signal L_WE_DD          : std_logic_vector(31 downto 0);
signal L_WE_IO          : std_logic_vector(31 downto 0);
signal L_WE_MISC        : std_logic_vector(31 downto 0);
signal L_WE_X           : std_logic;
signal L_WE_Y           : std_logic;
signal L_WE_Z           : std_logic;
signal L_WE_SP          : std_logic_vector( 1 downto 0);
signal L_WE_SR          : std_logic;
signal L_XYZS           : std_logic_vector(15 downto 0);
 
begin
 
    r00: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE( 1 downto  0), I_D => I_DIN, Q => R_R00);
    r02: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE( 3 downto  2), I_D => I_DIN, Q => R_R02);
    r04: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE( 5 downto  4), I_D => I_DIN, Q => R_R04);
    r06: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE( 7 downto  6), I_D => I_DIN, Q => R_R06);
    r08: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE( 9 downto  8), I_D => I_DIN, Q => R_R08);
    r10: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(11 downto 10), I_D => I_DIN, Q => R_R10);
    r12: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(13 downto 12), I_D => I_DIN, Q => R_R12);
    r14: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(15 downto 14), I_D => I_DIN, Q => R_R14);
    r16: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(17 downto 16), I_D => I_DIN, Q => R_R16);
    r18: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(19 downto 18), I_D => I_DIN, Q => R_R18);
    r20: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(21 downto 20), I_D => I_DIN, Q => R_R20);
    r22: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(23 downto 22), I_D => I_DIN, Q => R_R22);
    r24: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(25 downto 24), I_D => I_DIN, Q => R_R24);
    r26: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(27 downto 26), I_D => L_DX,  Q => R_R26);
    r28: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(29 downto 28), I_D => L_DY,  Q => R_R28);
    r30: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(31 downto 30), I_D => L_DZ,  Q => R_R30);
    sp:  reg_16 port map(I_CLK => I_CLK, I_WE => L_WE_SP,            I_D => L_DSP, Q => R_SP);
 
    sr: status_reg
    port map(   I_CLK       => I_CLK,
                I_COND      => I_COND,
                I_DIN       => I_DIN(7 downto 0),
                I_FLAGS     => I_FLAGS,
                I_WE_F      => I_WE_F,
                I_WE_SR     => L_WE_SR,
                Q           => S_FLAGS,
                Q_CC        => Q_CC);
 
    -- The output of the register selected by L_ADR.
    --
    process(R_R00, R_R02, R_R04, R_R06, R_R08, R_R10, R_R12, R_R14,
            R_R16, R_R18, R_R20, R_R22, R_R24, R_R26, R_R28, R_R30,
            R_SP, S_FLAGS, L_ADR(6 downto 1))
    begin
        case L_ADR(6 downto 1) is
            when "000000" => L_S <= R_R00;
            when "000001" => L_S <= R_R02;
            when "000010" => L_S <= R_R04;
            when "000011" => L_S <= R_R06;
            when "000100" => L_S <= R_R08;
            when "000101" => L_S <= R_R10;
            when "000110" => L_S <= R_R12;
            when "000111" => L_S <= R_R14;
            when "001000" => L_S <= R_R16;
            when "001001" => L_S <= R_R18;
            when "001010" => L_S <= R_R20;
            when "001011" => L_S <= R_R22;
            when "001100" => L_S <= R_R24;
            when "001101" => L_S <= R_R26;
            when "001110" => L_S <= R_R28;
            when "001111" => L_S <= R_R30;
            when "101110" => L_S <= R_SP ( 7 downto 0) & X"00";     -- SPL
            when others   => L_S <= S_FLAGS & R_SP (15 downto 8);   -- SR/SPH
        end case;
    end process;
 
    -- The output of the register pair selected by I_DDDDD.
    --
    process(R_R00, R_R02, R_R04, R_R06, R_R08, R_R10, R_R12, R_R14,
            R_R16, R_R18, R_R20, R_R22, R_R24, R_R26, R_R28, R_R30,
            I_DDDDD(4 downto 1))
    begin
        case I_DDDDD(4 downto 1) is
            when "0000" => Q_D <= R_R00;
            when "0001" => Q_D <= R_R02;
            when "0010" => Q_D <= R_R04;
            when "0011" => Q_D <= R_R06;
            when "0100" => Q_D <= R_R08;
            when "0101" => Q_D <= R_R10;
            when "0110" => Q_D <= R_R12;
            when "0111" => Q_D <= R_R14;
            when "1000" => Q_D <= R_R16;
            when "1001" => Q_D <= R_R18;
            when "1010" => Q_D <= R_R20;
            when "1011" => Q_D <= R_R22;
            when "1100" => Q_D <= R_R24;
            when "1101" => Q_D <= R_R26;
            when "1110" => Q_D <= R_R28;
            when others => Q_D <= R_R30;
        end case;
    end process;
 
    -- The output of the register pair selected by I_RRRR.
    --
    process(R_R00, R_R02, R_R04,  R_R06, R_R08, R_R10, R_R12, R_R14,
            R_R16, R_R18, R_R20, R_R22, R_R24, R_R26, R_R28, R_R30, I_RRRR)
    begin
        case I_RRRR is
            when "0000" => Q_R <= R_R00;
            when "0001" => Q_R <= R_R02;
            when "0010" => Q_R <= R_R04;
            when "0011" => Q_R <= R_R06;
            when "0100" => Q_R <= R_R08;
            when "0101" => Q_R <= R_R10;
            when "0110" => Q_R <= R_R12;
            when "0111" => Q_R <= R_R14;
            when "1000" => Q_R <= R_R16;
            when "1001" => Q_R <= R_R18;
            when "1010" => Q_R <= R_R20;
            when "1011" => Q_R <= R_R22;
            when "1100" => Q_R <= R_R24;
            when "1101" => Q_R <= R_R26;
            when "1110" => Q_R <= R_R28;
            when others => Q_R <= R_R30;
        end case;
    end process;
 
    -- the base value of the X/Y/Z/SP register as per I_AMOD.
    --
    process(I_AMOD(2 downto 0), I_IMM, R_SP, R_R26, R_R28, R_R30)
    begin
        case I_AMOD(2 downto 0) is
            when AS_SP  => L_BASE <= R_SP;
            when AS_Z   => L_BASE <= R_R30;
            when AS_Y   => L_BASE <= R_R28;
            when AS_X   => L_BASE <= R_R26;
            when AS_IMM => L_BASE <= I_IMM;
            when others => L_BASE <= X"0000";
        end case;
    end process;
 
    -- the value of the X/Y/Z/SP register after a potential PRE-inc/decrement
    -- (by 1 or 2) and POST-inc/decrement (by 1 or 2).
    --
    process(I_AMOD, I_IMM)
    begin
        case I_AMOD is
            when AMOD_Xq | AMOD_Yq | AMOD_Zq  =>
                L_PRE <= I_IMM;      L_POST <= X"0000";
 
            when AMOD_Xi | AMOD_Yi | AMOD_Zi  =>
                L_PRE <= X"0000";    L_POST <= X"0001";
 
            when AMOD_dX  | AMOD_dY  | AMOD_dZ  =>
                L_PRE <= X"FFFF";    L_POST <= X"FFFF";
 
            when AMOD_iSP =>
                L_PRE <= X"0001";    L_POST <= X"0001";
 
            when AMOD_iiSP=>
                L_PRE <= X"0001";    L_POST <= X"0002";
 
            when AMOD_SPd =>
                L_PRE <= X"0000";    L_POST <= X"FFFF";
 
            when AMOD_SPdd=>
                L_PRE <= X"FFFF";    L_POST <= X"FFFE";
 
            when others =>
                L_PRE <= X"0000";    L_POST <= X"0000";
        end case;
    end process;
 
    L_XYZS <= L_BASE + L_POST;
    L_ADR  <= L_BASE + L_PRE;
 
    L_WE_A <= I_WE_M when (L_ADR(15 downto 5) = "00000000000") else '0';
    L_WE_SR    <= I_WE_M when (L_ADR = X"005F") else '0';
    L_WE_SP_AMOD <= I_WE_XYZS when (I_AMOD(2 downto 0) = AS_SP) else '0';
    L_WE_SP(1) <= I_WE_M when (L_ADR = X"005E") else L_WE_SP_AMOD;
    L_WE_SP(0) <= I_WE_M when (L_ADR = X"005D") else L_WE_SP_AMOD;
 
    L_DX  <= L_XYZS when (L_WE_MISC(26) = '1')        else I_DIN;
    L_DY  <= L_XYZS when (L_WE_MISC(28) = '1')        else I_DIN;
    L_DZ  <= L_XYZS when (L_WE_MISC(30) = '1')        else I_DIN;
    L_DSP <= L_XYZS when (I_AMOD(3 downto 0) = AM_WS) else I_DIN;
 
    -- the WE signals for the differen registers.
    --
    -- case 1: write to an 8-bit register addressed by DDDDD.
    --
    -- I_WE_D(0) = '1' and I_DDDDD matches,
    --
    L_WE_D( 0) <= I_WE_D(0) when (I_DDDDD = "00000") else '0';
    L_WE_D( 1) <= I_WE_D(0) when (I_DDDDD = "00001") else '0';
    L_WE_D( 2) <= I_WE_D(0) when (I_DDDDD = "00010") else '0';
    L_WE_D( 3) <= I_WE_D(0) when (I_DDDDD = "00011") else '0';
    L_WE_D( 4) <= I_WE_D(0) when (I_DDDDD = "00100") else '0';
    L_WE_D( 5) <= I_WE_D(0) when (I_DDDDD = "00101") else '0';
    L_WE_D( 6) <= I_WE_D(0) when (I_DDDDD = "00110") else '0';
    L_WE_D( 7) <= I_WE_D(0) when (I_DDDDD = "00111") else '0';
    L_WE_D( 8) <= I_WE_D(0) when (I_DDDDD = "01000") else '0';
    L_WE_D( 9) <= I_WE_D(0) when (I_DDDDD = "01001") else '0';
    L_WE_D(10) <= I_WE_D(0) when (I_DDDDD = "01010") else '0';
    L_WE_D(11) <= I_WE_D(0) when (I_DDDDD = "01011") else '0';
    L_WE_D(12) <= I_WE_D(0) when (I_DDDDD = "01100") else '0';
    L_WE_D(13) <= I_WE_D(0) when (I_DDDDD = "01101") else '0';
    L_WE_D(14) <= I_WE_D(0) when (I_DDDDD = "01110") else '0';
    L_WE_D(15) <= I_WE_D(0) when (I_DDDDD = "01111") else '0';
    L_WE_D(16) <= I_WE_D(0) when (I_DDDDD = "10000") else '0';
    L_WE_D(17) <= I_WE_D(0) when (I_DDDDD = "10001") else '0';
    L_WE_D(18) <= I_WE_D(0) when (I_DDDDD = "10010") else '0';
    L_WE_D(19) <= I_WE_D(0) when (I_DDDDD = "10011") else '0';
    L_WE_D(20) <= I_WE_D(0) when (I_DDDDD = "10100") else '0';
    L_WE_D(21) <= I_WE_D(0) when (I_DDDDD = "10101") else '0';
    L_WE_D(22) <= I_WE_D(0) when (I_DDDDD = "10110") else '0';
    L_WE_D(23) <= I_WE_D(0) when (I_DDDDD = "10111") else '0';
    L_WE_D(24) <= I_WE_D(0) when (I_DDDDD = "11000") else '0';
    L_WE_D(25) <= I_WE_D(0) when (I_DDDDD = "11001") else '0';
    L_WE_D(26) <= I_WE_D(0) when (I_DDDDD = "11010") else '0';
    L_WE_D(27) <= I_WE_D(0) when (I_DDDDD = "11011") else '0';
    L_WE_D(28) <= I_WE_D(0) when (I_DDDDD = "11100") else '0';
    L_WE_D(29) <= I_WE_D(0) when (I_DDDDD = "11101") else '0';
    L_WE_D(30) <= I_WE_D(0) when (I_DDDDD = "11110") else '0';
    L_WE_D(31) <= I_WE_D(0) when (I_DDDDD = "11111") else '0';
 
    --
    -- case 2: write to a 16-bit register pair addressed by DDDD.
    --
    -- I_WE_DD(1) = '1' and L_DDDD matches,
    --
    L_DDDD <= I_DDDDD(4 downto 1);
    L_WE_D2 <= I_WE_D(1) & I_WE_D(1);
    L_WE_DD( 1 downto  0) <= L_WE_D2 when (L_DDDD = "0000") else "00";
    L_WE_DD( 3 downto  2) <= L_WE_D2 when (L_DDDD = "0001") else "00";
    L_WE_DD( 5 downto  4) <= L_WE_D2 when (L_DDDD = "0010") else "00";
    L_WE_DD( 7 downto  6) <= L_WE_D2 when (L_DDDD = "0011") else "00";
    L_WE_DD( 9 downto  8) <= L_WE_D2 when (L_DDDD = "0100") else "00";
    L_WE_DD(11 downto 10) <= L_WE_D2 when (L_DDDD = "0101") else "00";
    L_WE_DD(13 downto 12) <= L_WE_D2 when (L_DDDD = "0110") else "00";
    L_WE_DD(15 downto 14) <= L_WE_D2 when (L_DDDD = "0111") else "00";
    L_WE_DD(17 downto 16) <= L_WE_D2 when (L_DDDD = "1000") else "00";
    L_WE_DD(19 downto 18) <= L_WE_D2 when (L_DDDD = "1001") else "00";
    L_WE_DD(21 downto 20) <= L_WE_D2 when (L_DDDD = "1010") else "00";
    L_WE_DD(23 downto 22) <= L_WE_D2 when (L_DDDD = "1011") else "00";
    L_WE_DD(25 downto 24) <= L_WE_D2 when (L_DDDD = "1100") else "00";
    L_WE_DD(27 downto 26) <= L_WE_D2 when (L_DDDD = "1101") else "00";
    L_WE_DD(29 downto 28) <= L_WE_D2 when (L_DDDD = "1110") else "00";
    L_WE_DD(31 downto 30) <= L_WE_D2 when (L_DDDD = "1111") else "00";
 
    --
    -- case 3: write to an 8-bit register pair addressed by an I/O address.
    --
    -- L_WE_A = '1' and L_ADR(4 downto 0) matches
    --
    L_WE_IO( 0) <= L_WE_A when (L_ADR(4 downto 0) = "00000") else '0';
    L_WE_IO( 1) <= L_WE_A when (L_ADR(4 downto 0) = "00001") else '0';
    L_WE_IO( 2) <= L_WE_A when (L_ADR(4 downto 0) = "00010") else '0';
    L_WE_IO( 3) <= L_WE_A when (L_ADR(4 downto 0) = "00011") else '0';
    L_WE_IO( 4) <= L_WE_A when (L_ADR(4 downto 0) = "00100") else '0';
    L_WE_IO( 5) <= L_WE_A when (L_ADR(4 downto 0) = "00101") else '0';
    L_WE_IO( 6) <= L_WE_A when (L_ADR(4 downto 0) = "00110") else '0';
    L_WE_IO( 7) <= L_WE_A when (L_ADR(4 downto 0) = "00111") else '0';
    L_WE_IO( 8) <= L_WE_A when (L_ADR(4 downto 0) = "01000") else '0';
    L_WE_IO( 9) <= L_WE_A when (L_ADR(4 downto 0) = "01001") else '0';
    L_WE_IO(10) <= L_WE_A when (L_ADR(4 downto 0) = "01010") else '0';
    L_WE_IO(11) <= L_WE_A when (L_ADR(4 downto 0) = "01011") else '0';
    L_WE_IO(12) <= L_WE_A when (L_ADR(4 downto 0) = "01100") else '0';
    L_WE_IO(13) <= L_WE_A when (L_ADR(4 downto 0) = "01101") else '0';
    L_WE_IO(14) <= L_WE_A when (L_ADR(4 downto 0) = "01110") else '0';
    L_WE_IO(15) <= L_WE_A when (L_ADR(4 downto 0) = "01111") else '0';
    L_WE_IO(16) <= L_WE_A when (L_ADR(4 downto 0) = "10000") else '0';
    L_WE_IO(17) <= L_WE_A when (L_ADR(4 downto 0) = "10001") else '0';
    L_WE_IO(18) <= L_WE_A when (L_ADR(4 downto 0) = "10010") else '0';
    L_WE_IO(19) <= L_WE_A when (L_ADR(4 downto 0) = "10011") else '0';
    L_WE_IO(20) <= L_WE_A when (L_ADR(4 downto 0) = "10100") else '0';
    L_WE_IO(21) <= L_WE_A when (L_ADR(4 downto 0) = "10101") else '0';
    L_WE_IO(22) <= L_WE_A when (L_ADR(4 downto 0) = "10110") else '0';
    L_WE_IO(23) <= L_WE_A when (L_ADR(4 downto 0) = "10111") else '0';
    L_WE_IO(24) <= L_WE_A when (L_ADR(4 downto 0) = "11000") else '0';
    L_WE_IO(25) <= L_WE_A when (L_ADR(4 downto 0) = "11001") else '0';
    L_WE_IO(26) <= L_WE_A when (L_ADR(4 downto 0) = "11010") else '0';
    L_WE_IO(27) <= L_WE_A when (L_ADR(4 downto 0) = "11011") else '0';
    L_WE_IO(28) <= L_WE_A when (L_ADR(4 downto 0) = "11100") else '0';
    L_WE_IO(29) <= L_WE_A when (L_ADR(4 downto 0) = "11101") else '0';
    L_WE_IO(30) <= L_WE_A when (L_ADR(4 downto 0) = "11110") else '0';
    L_WE_IO(31) <= L_WE_A when (L_ADR(4 downto 0) = "11111") else '0';
 
    -- case 4 special cases.
    -- 4a. WE_01 for register pair 0/1 (multiplication opcode).
    -- 4b. I_WE_XYZS for X (register pairs 26/27) and I_AMOD matches
    -- 4c. I_WE_XYZS for Y (register pairs 28/29) and I_AMOD matches
    -- 4d. I_WE_XYZS for Z (register pairs 30/31) and I_AMOD matches
    --
    L_WE_X <= I_WE_XYZS when (I_AMOD(3 downto 0) = AM_WX) else '0';
    L_WE_Y <= I_WE_XYZS when (I_AMOD(3 downto 0) = AM_WY) else '0';
    L_WE_Z <= I_WE_XYZS when (I_AMOD(3 downto 0) = AM_WZ) else '0';
    L_WE_MISC <= L_WE_Z & L_WE_Z &      -- -Z and Z+ address modes  r30
                 L_WE_Y & L_WE_Y &      -- -Y and Y+ address modes  r28
                 L_WE_X & L_WE_X &      -- -X and X+ address modes  r26
                 X"000000" &            -- never                    r24 - r02
                 I_WE_01 & I_WE_01;     -- multiplication result    r00
 
    L_WE <= L_WE_D or L_WE_DD or L_WE_IO or L_WE_MISC;
 
    Q_S <= L_S( 7 downto 0) when (L_ADR(0) = '0') else L_S(15 downto 8);
    Q_FLAGS <= S_FLAGS;
    Q_Z <= R_R30;
    Q_ADR <= L_ADR;
 
end Behavioral;
 

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[/] [cpu_lecture/] [trunk/] [src/] [register_file.vhd] - Blame information for rev 18

Line No.	Rev	Author	Line
1	2	jsauermann	`-------------------------------------------------------------------------------`
2			`--`
3			`-- Copyright (C) 2009, 2010 Dr. Juergen Sauermann`
4			`--`
5			`-- This code is free software: you can redistribute it and/or modify`
6			`-- it under the terms of the GNU General Public License as published by`
7			`-- the Free Software Foundation, either version 3 of the License, or`
8			`-- (at your option) any later version.`
9			`--`
10			`-- This code is distributed in the hope that it will be useful,`
11			`-- but WITHOUT ANY WARRANTY; without even the implied warranty of`
12			`-- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the`
13			`-- GNU General Public License for more details.`
14			`--`
15			`-- You should have received a copy of the GNU General Public License`
16			`-- along with this code (see the file named COPYING).`
17			`-- If not, see http://www.gnu.org/licenses/.`
18			`--`
19			`-------------------------------------------------------------------------------`
20			`-------------------------------------------------------------------------------`
21			`--`
22			`-- Module Name: RegisterFile - Behavioral`
23			`-- Create Date: 12:43:34 10/28/2009`
24			`-- Description: a register file (16 register pairs) of a CPU.`
25			`--`
26			`-------------------------------------------------------------------------------`
27			`--`
28			`library IEEE;`
29			`use IEEE.STD_LOGIC_1164.ALL;`
30			`use IEEE.STD_LOGIC_ARITH.ALL;`
31			`use IEEE.STD_LOGIC_UNSIGNED.ALL;`
32
33			`use work.common.ALL;`
34
35			`entity register_file is`
36			`port ( I_CLK : in std_logic;`
37
38			`I_AMOD : in std_logic_vector( 5 downto 0);`
39			`I_COND : in std_logic_vector( 3 downto 0);`
40			`I_DDDDD : in std_logic_vector( 4 downto 0);`
41			`I_DIN : in std_logic_vector(15 downto 0);`
42			`I_FLAGS : in std_logic_vector( 7 downto 0);`
43			`I_IMM : in std_logic_vector(15 downto 0);`
44			`I_RRRR : in std_logic_vector( 4 downto 1);`
45			`I_WE_01 : in std_logic;`
46			`I_WE_D : in std_logic_vector( 1 downto 0);`
47			`I_WE_F : in std_logic;`
48			`I_WE_M : in std_logic;`
49			`I_WE_XYZS : in std_logic;`
50
51			`Q_ADR : out std_logic_vector(15 downto 0);`
52			`Q_CC : out std_logic;`
53			`Q_D : out std_logic_vector(15 downto 0);`
54			`Q_FLAGS : out std_logic_vector( 7 downto 0);`
55			`Q_R : out std_logic_vector(15 downto 0);`
56			`Q_S : out std_logic_vector( 7 downto 0);`
57			`Q_Z : out std_logic_vector(15 downto 0));`
58			`end register_file;`
59
60			`architecture Behavioral of register_file is`
61
62			`component reg_16`
63			`port ( I_CLK : in std_logic;`
64
65			`I_D : in std_logic_vector(15 downto 0);`
66			`I_WE : in std_logic_vector( 1 downto 0);`
67
68			`Q : out std_logic_vector(15 downto 0));`
69			`end component;`
70
71			`signal R_R00 : std_logic_vector(15 downto 0);`
72			`signal R_R02 : std_logic_vector(15 downto 0);`
73			`signal R_R04 : std_logic_vector(15 downto 0);`
74			`signal R_R06 : std_logic_vector(15 downto 0);`
75			`signal R_R08 : std_logic_vector(15 downto 0);`
76			`signal R_R10 : std_logic_vector(15 downto 0);`
77			`signal R_R12 : std_logic_vector(15 downto 0);`
78			`signal R_R14 : std_logic_vector(15 downto 0);`
79			`signal R_R16 : std_logic_vector(15 downto 0);`
80			`signal R_R18 : std_logic_vector(15 downto 0);`
81			`signal R_R20 : std_logic_vector(15 downto 0);`
82			`signal R_R22 : std_logic_vector(15 downto 0);`
83			`signal R_R24 : std_logic_vector(15 downto 0);`
84			`signal R_R26 : std_logic_vector(15 downto 0);`
85			`signal R_R28 : std_logic_vector(15 downto 0);`
86			`signal R_R30 : std_logic_vector(15 downto 0);`
87			`signal R_SP : std_logic_vector(15 downto 0); -- stack pointer`
88
89			`component status_reg is`
90			`port ( I_CLK : in std_logic;`
91
92			`I_COND : in std_logic_vector ( 3 downto 0);`
93			`I_DIN : in std_logic_vector ( 7 downto 0);`
94			`I_FLAGS : in std_logic_vector ( 7 downto 0);`
95			`I_WE_F : in std_logic;`
96			`I_WE_SR : in std_logic;`
97
98			`Q : out std_logic_vector ( 7 downto 0);`
99			`Q_CC : out std_logic);`
100			`end component;`
101
102			`signal S_FLAGS : std_logic_vector( 7 downto 0);`
103
104			`signal L_ADR : std_logic_vector(15 downto 0);`
105			`signal L_BASE : std_logic_vector(15 downto 0);`
106			`signal L_DDDD : std_logic_vector( 4 downto 1);`
107			`signal L_DSP : std_logic_vector(15 downto 0);`
108			`signal L_DX : std_logic_vector(15 downto 0);`
109			`signal L_DY : std_logic_vector(15 downto 0);`
110			`signal L_DZ : std_logic_vector(15 downto 0);`
111			`signal L_PRE : std_logic_vector(15 downto 0);`
112			`signal L_POST : std_logic_vector(15 downto 0);`
113			`signal L_S : std_logic_vector(15 downto 0);`
114			`signal L_WE_SP_AMOD : std_logic;`
115			`signal L_WE : std_logic_vector(31 downto 0);`
116			`signal L_WE_A : std_logic;`
117			`signal L_WE_D : std_logic_vector(31 downto 0);`
118			`signal L_WE_D2 : std_logic_vector( 1 downto 0);`
119			`signal L_WE_DD : std_logic_vector(31 downto 0);`
120			`signal L_WE_IO : std_logic_vector(31 downto 0);`
121			`signal L_WE_MISC : std_logic_vector(31 downto 0);`
122			`signal L_WE_X : std_logic;`
123			`signal L_WE_Y : std_logic;`
124			`signal L_WE_Z : std_logic;`
125			`signal L_WE_SP : std_logic_vector( 1 downto 0);`
126			`signal L_WE_SR : std_logic;`
127			`signal L_XYZS : std_logic_vector(15 downto 0);`
128
129			`begin`
130
131			`r00: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE( 1 downto 0), I_D => I_DIN, Q => R_R00);`
132			`r02: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE( 3 downto 2), I_D => I_DIN, Q => R_R02);`
133			`r04: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE( 5 downto 4), I_D => I_DIN, Q => R_R04);`
134			`r06: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE( 7 downto 6), I_D => I_DIN, Q => R_R06);`
135			`r08: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE( 9 downto 8), I_D => I_DIN, Q => R_R08);`
136			`r10: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(11 downto 10), I_D => I_DIN, Q => R_R10);`
137			`r12: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(13 downto 12), I_D => I_DIN, Q => R_R12);`
138			`r14: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(15 downto 14), I_D => I_DIN, Q => R_R14);`
139			`r16: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(17 downto 16), I_D => I_DIN, Q => R_R16);`
140			`r18: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(19 downto 18), I_D => I_DIN, Q => R_R18);`
141			`r20: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(21 downto 20), I_D => I_DIN, Q => R_R20);`
142			`r22: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(23 downto 22), I_D => I_DIN, Q => R_R22);`
143			`r24: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(25 downto 24), I_D => I_DIN, Q => R_R24);`
144			`r26: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(27 downto 26), I_D => L_DX, Q => R_R26);`
145			`r28: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(29 downto 28), I_D => L_DY, Q => R_R28);`
146			`r30: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE(31 downto 30), I_D => L_DZ, Q => R_R30);`
147			`sp: reg_16 port map(I_CLK => I_CLK, I_WE => L_WE_SP, I_D => L_DSP, Q => R_SP);`
148
149			`sr: status_reg`
150			`port map( I_CLK => I_CLK,`
151			`I_COND => I_COND,`
152			`I_DIN => I_DIN(7 downto 0),`
153			`I_FLAGS => I_FLAGS,`
154			`I_WE_F => I_WE_F,`
155			`I_WE_SR => L_WE_SR,`
156			`Q => S_FLAGS,`
157			`Q_CC => Q_CC);`
158
159			`-- The output of the register selected by L_ADR.`
160			`--`
161			`process(R_R00, R_R02, R_R04, R_R06, R_R08, R_R10, R_R12, R_R14,`
162			`R_R16, R_R18, R_R20, R_R22, R_R24, R_R26, R_R28, R_R30,`
163			`R_SP, S_FLAGS, L_ADR(6 downto 1))`
164			`begin`
165			`case L_ADR(6 downto 1) is`
166			`when "000000" => L_S <= R_R00;`
167			`when "000001" => L_S <= R_R02;`
168			`when "000010" => L_S <= R_R04;`
169			`when "000011" => L_S <= R_R06;`
170			`when "000100" => L_S <= R_R08;`
171			`when "000101" => L_S <= R_R10;`
172			`when "000110" => L_S <= R_R12;`
173			`when "000111" => L_S <= R_R14;`
174			`when "001000" => L_S <= R_R16;`
175			`when "001001" => L_S <= R_R18;`
176			`when "001010" => L_S <= R_R20;`
177			`when "001011" => L_S <= R_R22;`
178			`when "001100" => L_S <= R_R24;`
179			`when "001101" => L_S <= R_R26;`
180			`when "001110" => L_S <= R_R28;`
181			`when "001111" => L_S <= R_R30;`
182	12	jsauermann	`when "101110" => L_S <= R_SP ( 7 downto 0) & X"00"; -- SPL`
183	2	jsauermann	`when others => L_S <= S_FLAGS & R_SP (15 downto 8); -- SR/SPH`
184			`end case;`
185			`end process;`
186
187			`-- The output of the register pair selected by I_DDDDD.`
188			`--`
189			`process(R_R00, R_R02, R_R04, R_R06, R_R08, R_R10, R_R12, R_R14,`
190			`R_R16, R_R18, R_R20, R_R22, R_R24, R_R26, R_R28, R_R30,`
191			`I_DDDDD(4 downto 1))`
192			`begin`
193			`case I_DDDDD(4 downto 1) is`
194			`when "0000" => Q_D <= R_R00;`
195			`when "0001" => Q_D <= R_R02;`
196			`when "0010" => Q_D <= R_R04;`
197			`when "0011" => Q_D <= R_R06;`
198			`when "0100" => Q_D <= R_R08;`
199			`when "0101" => Q_D <= R_R10;`
200			`when "0110" => Q_D <= R_R12;`
201			`when "0111" => Q_D <= R_R14;`
202			`when "1000" => Q_D <= R_R16;`
203			`when "1001" => Q_D <= R_R18;`
204			`when "1010" => Q_D <= R_R20;`
205			`when "1011" => Q_D <= R_R22;`
206			`when "1100" => Q_D <= R_R24;`
207			`when "1101" => Q_D <= R_R26;`
208			`when "1110" => Q_D <= R_R28;`
209			`when others => Q_D <= R_R30;`
210			`end case;`
211			`end process;`
212
213			`-- The output of the register pair selected by I_RRRR.`
214			`--`
215			`process(R_R00, R_R02, R_R04, R_R06, R_R08, R_R10, R_R12, R_R14,`
216			`R_R16, R_R18, R_R20, R_R22, R_R24, R_R26, R_R28, R_R30, I_RRRR)`
217			`begin`
218			`case I_RRRR is`
219			`when "0000" => Q_R <= R_R00;`
220			`when "0001" => Q_R <= R_R02;`
221			`when "0010" => Q_R <= R_R04;`
222			`when "0011" => Q_R <= R_R06;`
223			`when "0100" => Q_R <= R_R08;`
224			`when "0101" => Q_R <= R_R10;`
225			`when "0110" => Q_R <= R_R12;`
226			`when "0111" => Q_R <= R_R14;`
227			`when "1000" => Q_R <= R_R16;`
228			`when "1001" => Q_R <= R_R18;`
229			`when "1010" => Q_R <= R_R20;`
230			`when "1011" => Q_R <= R_R22;`
231			`when "1100" => Q_R <= R_R24;`
232			`when "1101" => Q_R <= R_R26;`
233			`when "1110" => Q_R <= R_R28;`
234			`when others => Q_R <= R_R30;`
235			`end case;`
236			`end process;`
237
238			`-- the base value of the X/Y/Z/SP register as per I_AMOD.`
239			`--`
240			`process(I_AMOD(2 downto 0), I_IMM, R_SP, R_R26, R_R28, R_R30)`
241			`begin`
242			`case I_AMOD(2 downto 0) is`
243			`when AS_SP => L_BASE <= R_SP;`
244			`when AS_Z => L_BASE <= R_R30;`
245			`when AS_Y => L_BASE <= R_R28;`
246			`when AS_X => L_BASE <= R_R26;`
247			`when AS_IMM => L_BASE <= I_IMM;`
248			`when others => L_BASE <= X"0000";`
249			`end case;`
250			`end process;`
251
252	15	jsauermann	`-- the value of the X/Y/Z/SP register after a potential PRE-inc/decrement`
253			`-- (by 1 or 2) and POST-inc/decrement (by 1 or 2).`
254	2	jsauermann	`--`
255	15	jsauermann	`process(I_AMOD, I_IMM)`
256	2	jsauermann	`begin`
257	15	jsauermann	`case I_AMOD is`
258			`when AMOD_Xq \| AMOD_Yq \| AMOD_Zq =>`
259			`L_PRE <= I_IMM; L_POST <= X"0000";`
260
261			`when AMOD_Xi \| AMOD_Yi \| AMOD_Zi =>`
262			`L_PRE <= X"0000"; L_POST <= X"0001";`
263
264			`when AMOD_dX \| AMOD_dY \| AMOD_dZ =>`
265			`L_PRE <= X"FFFF"; L_POST <= X"FFFF";`
266
267			`when AMOD_iSP =>`
268			`L_PRE <= X"0001"; L_POST <= X"0001";`
269
270			`when AMOD_iiSP=>`
271			`L_PRE <= X"0001"; L_POST <= X"0002";`
272
273			`when AMOD_SPd =>`
274			`L_PRE <= X"0000"; L_POST <= X"FFFF";`
275
276			`when AMOD_SPdd=>`
277			`L_PRE <= X"FFFF"; L_POST <= X"FFFE";`
278
279			`when others =>`
280			`L_PRE <= X"0000"; L_POST <= X"0000";`
281	2	jsauermann	`end case;`
282			`end process;`
283
284			`L_XYZS <= L_BASE + L_POST;`
285			`L_ADR <= L_BASE + L_PRE;`
286
287			`L_WE_A <= I_WE_M when (L_ADR(15 downto 5) = "00000000000") else '0';`
288			`L_WE_SR <= I_WE_M when (L_ADR = X"005F") else '0';`
289			`L_WE_SP_AMOD <= I_WE_XYZS when (I_AMOD(2 downto 0) = AS_SP) else '0';`
290			`L_WE_SP(1) <= I_WE_M when (L_ADR = X"005E") else L_WE_SP_AMOD;`
291			`L_WE_SP(0) <= I_WE_M when (L_ADR = X"005D") else L_WE_SP_AMOD;`
292
293			`L_DX <= L_XYZS when (L_WE_MISC(26) = '1') else I_DIN;`
294			`L_DY <= L_XYZS when (L_WE_MISC(28) = '1') else I_DIN;`
295			`L_DZ <= L_XYZS when (L_WE_MISC(30) = '1') else I_DIN;`
296			`L_DSP <= L_XYZS when (I_AMOD(3 downto 0) = AM_WS) else I_DIN;`
297
298			`-- the WE signals for the differen registers.`
299			`--`
300			`-- case 1: write to an 8-bit register addressed by DDDDD.`
301			`--`
302			`-- I_WE_D(0) = '1' and I_DDDDD matches,`
303			`--`
304			`L_WE_D( 0) <= I_WE_D(0) when (I_DDDDD = "00000") else '0';`
305			`L_WE_D( 1) <= I_WE_D(0) when (I_DDDDD = "00001") else '0';`
306			`L_WE_D( 2) <= I_WE_D(0) when (I_DDDDD = "00010") else '0';`
307			`L_WE_D( 3) <= I_WE_D(0) when (I_DDDDD = "00011") else '0';`
308			`L_WE_D( 4) <= I_WE_D(0) when (I_DDDDD = "00100") else '0';`
309			`L_WE_D( 5) <= I_WE_D(0) when (I_DDDDD = "00101") else '0';`
310			`L_WE_D( 6) <= I_WE_D(0) when (I_DDDDD = "00110") else '0';`
311			`L_WE_D( 7) <= I_WE_D(0) when (I_DDDDD = "00111") else '0';`
312			`L_WE_D( 8) <= I_WE_D(0) when (I_DDDDD = "01000") else '0';`
313			`L_WE_D( 9) <= I_WE_D(0) when (I_DDDDD = "01001") else '0';`
314			`L_WE_D(10) <= I_WE_D(0) when (I_DDDDD = "01010") else '0';`
315			`L_WE_D(11) <= I_WE_D(0) when (I_DDDDD = "01011") else '0';`
316			`L_WE_D(12) <= I_WE_D(0) when (I_DDDDD = "01100") else '0';`
317			`L_WE_D(13) <= I_WE_D(0) when (I_DDDDD = "01101") else '0';`
318			`L_WE_D(14) <= I_WE_D(0) when (I_DDDDD = "01110") else '0';`
319			`L_WE_D(15) <= I_WE_D(0) when (I_DDDDD = "01111") else '0';`
320			`L_WE_D(16) <= I_WE_D(0) when (I_DDDDD = "10000") else '0';`
321			`L_WE_D(17) <= I_WE_D(0) when (I_DDDDD = "10001") else '0';`
322			`L_WE_D(18) <= I_WE_D(0) when (I_DDDDD = "10010") else '0';`
323			`L_WE_D(19) <= I_WE_D(0) when (I_DDDDD = "10011") else '0';`
324			`L_WE_D(20) <= I_WE_D(0) when (I_DDDDD = "10100") else '0';`
325			`L_WE_D(21) <= I_WE_D(0) when (I_DDDDD = "10101") else '0';`
326			`L_WE_D(22) <= I_WE_D(0) when (I_DDDDD = "10110") else '0';`
327			`L_WE_D(23) <= I_WE_D(0) when (I_DDDDD = "10111") else '0';`
328			`L_WE_D(24) <= I_WE_D(0) when (I_DDDDD = "11000") else '0';`
329			`L_WE_D(25) <= I_WE_D(0) when (I_DDDDD = "11001") else '0';`
330			`L_WE_D(26) <= I_WE_D(0) when (I_DDDDD = "11010") else '0';`
331			`L_WE_D(27) <= I_WE_D(0) when (I_DDDDD = "11011") else '0';`
332			`L_WE_D(28) <= I_WE_D(0) when (I_DDDDD = "11100") else '0';`
333			`L_WE_D(29) <= I_WE_D(0) when (I_DDDDD = "11101") else '0';`
334			`L_WE_D(30) <= I_WE_D(0) when (I_DDDDD = "11110") else '0';`
335			`L_WE_D(31) <= I_WE_D(0) when (I_DDDDD = "11111") else '0';`
336
337			`--`
338			`-- case 2: write to a 16-bit register pair addressed by DDDD.`
339			`--`
340			`-- I_WE_DD(1) = '1' and L_DDDD matches,`
341			`--`
342			`L_DDDD <= I_DDDDD(4 downto 1);`
343			`L_WE_D2 <= I_WE_D(1) & I_WE_D(1);`
344			`L_WE_DD( 1 downto 0) <= L_WE_D2 when (L_DDDD = "0000") else "00";`
345			`L_WE_DD( 3 downto 2) <= L_WE_D2 when (L_DDDD = "0001") else "00";`
346			`L_WE_DD( 5 downto 4) <= L_WE_D2 when (L_DDDD = "0010") else "00";`
347			`L_WE_DD( 7 downto 6) <= L_WE_D2 when (L_DDDD = "0011") else "00";`
348			`L_WE_DD( 9 downto 8) <= L_WE_D2 when (L_DDDD = "0100") else "00";`
349			`L_WE_DD(11 downto 10) <= L_WE_D2 when (L_DDDD = "0101") else "00";`
350			`L_WE_DD(13 downto 12) <= L_WE_D2 when (L_DDDD = "0110") else "00";`
351			`L_WE_DD(15 downto 14) <= L_WE_D2 when (L_DDDD = "0111") else "00";`
352			`L_WE_DD(17 downto 16) <= L_WE_D2 when (L_DDDD = "1000") else "00";`
353			`L_WE_DD(19 downto 18) <= L_WE_D2 when (L_DDDD = "1001") else "00";`
354			`L_WE_DD(21 downto 20) <= L_WE_D2 when (L_DDDD = "1010") else "00";`
355			`L_WE_DD(23 downto 22) <= L_WE_D2 when (L_DDDD = "1011") else "00";`
356			`L_WE_DD(25 downto 24) <= L_WE_D2 when (L_DDDD = "1100") else "00";`
357			`L_WE_DD(27 downto 26) <= L_WE_D2 when (L_DDDD = "1101") else "00";`
358			`L_WE_DD(29 downto 28) <= L_WE_D2 when (L_DDDD = "1110") else "00";`
359			`L_WE_DD(31 downto 30) <= L_WE_D2 when (L_DDDD = "1111") else "00";`
360
361			`--`
362			`-- case 3: write to an 8-bit register pair addressed by an I/O address.`
363			`--`
364			`-- L_WE_A = '1' and L_ADR(4 downto 0) matches`
365			`--`
366			`L_WE_IO( 0) <= L_WE_A when (L_ADR(4 downto 0) = "00000") else '0';`
367			`L_WE_IO( 1) <= L_WE_A when (L_ADR(4 downto 0) = "00001") else '0';`
368			`L_WE_IO( 2) <= L_WE_A when (L_ADR(4 downto 0) = "00010") else '0';`
369			`L_WE_IO( 3) <= L_WE_A when (L_ADR(4 downto 0) = "00011") else '0';`
370			`L_WE_IO( 4) <= L_WE_A when (L_ADR(4 downto 0) = "00100") else '0';`
371			`L_WE_IO( 5) <= L_WE_A when (L_ADR(4 downto 0) = "00101") else '0';`
372			`L_WE_IO( 6) <= L_WE_A when (L_ADR(4 downto 0) = "00110") else '0';`
373			`L_WE_IO( 7) <= L_WE_A when (L_ADR(4 downto 0) = "00111") else '0';`
374			`L_WE_IO( 8) <= L_WE_A when (L_ADR(4 downto 0) = "01000") else '0';`
375			`L_WE_IO( 9) <= L_WE_A when (L_ADR(4 downto 0) = "01001") else '0';`
376			`L_WE_IO(10) <= L_WE_A when (L_ADR(4 downto 0) = "01010") else '0';`
377			`L_WE_IO(11) <= L_WE_A when (L_ADR(4 downto 0) = "01011") else '0';`
378			`L_WE_IO(12) <= L_WE_A when (L_ADR(4 downto 0) = "01100") else '0';`
379			`L_WE_IO(13) <= L_WE_A when (L_ADR(4 downto 0) = "01101") else '0';`
380			`L_WE_IO(14) <= L_WE_A when (L_ADR(4 downto 0) = "01110") else '0';`
381			`L_WE_IO(15) <= L_WE_A when (L_ADR(4 downto 0) = "01111") else '0';`
382			`L_WE_IO(16) <= L_WE_A when (L_ADR(4 downto 0) = "10000") else '0';`
383			`L_WE_IO(17) <= L_WE_A when (L_ADR(4 downto 0) = "10001") else '0';`
384			`L_WE_IO(18) <= L_WE_A when (L_ADR(4 downto 0) = "10010") else '0';`
385			`L_WE_IO(19) <= L_WE_A when (L_ADR(4 downto 0) = "10011") else '0';`
386			`L_WE_IO(20) <= L_WE_A when (L_ADR(4 downto 0) = "10100") else '0';`
387			`L_WE_IO(21) <= L_WE_A when (L_ADR(4 downto 0) = "10101") else '0';`
388			`L_WE_IO(22) <= L_WE_A when (L_ADR(4 downto 0) = "10110") else '0';`
389			`L_WE_IO(23) <= L_WE_A when (L_ADR(4 downto 0) = "10111") else '0';`
390			`L_WE_IO(24) <= L_WE_A when (L_ADR(4 downto 0) = "11000") else '0';`
391			`L_WE_IO(25) <= L_WE_A when (L_ADR(4 downto 0) = "11001") else '0';`
392			`L_WE_IO(26) <= L_WE_A when (L_ADR(4 downto 0) = "11010") else '0';`
393			`L_WE_IO(27) <= L_WE_A when (L_ADR(4 downto 0) = "11011") else '0';`
394			`L_WE_IO(28) <= L_WE_A when (L_ADR(4 downto 0) = "11100") else '0';`
395			`L_WE_IO(29) <= L_WE_A when (L_ADR(4 downto 0) = "11101") else '0';`
396			`L_WE_IO(30) <= L_WE_A when (L_ADR(4 downto 0) = "11110") else '0';`
397			`L_WE_IO(31) <= L_WE_A when (L_ADR(4 downto 0) = "11111") else '0';`
398
399			`-- case 4 special cases.`
400			`-- 4a. WE_01 for register pair 0/1 (multiplication opcode).`
401			`-- 4b. I_WE_XYZS for X (register pairs 26/27) and I_AMOD matches`
402			`-- 4c. I_WE_XYZS for Y (register pairs 28/29) and I_AMOD matches`
403			`-- 4d. I_WE_XYZS for Z (register pairs 30/31) and I_AMOD matches`
404			`--`
405			`L_WE_X <= I_WE_XYZS when (I_AMOD(3 downto 0) = AM_WX) else '0';`
406			`L_WE_Y <= I_WE_XYZS when (I_AMOD(3 downto 0) = AM_WY) else '0';`
407			`L_WE_Z <= I_WE_XYZS when (I_AMOD(3 downto 0) = AM_WZ) else '0';`
408			`L_WE_MISC <= L_WE_Z & L_WE_Z & -- -Z and Z+ address modes r30`
409			`L_WE_Y & L_WE_Y & -- -Y and Y+ address modes r28`
410			`L_WE_X & L_WE_X & -- -X and X+ address modes r26`
411			`X"000000" & -- never r24 - r02`
412			`I_WE_01 & I_WE_01; -- multiplication result r00`
413
414			`L_WE <= L_WE_D or L_WE_DD or L_WE_IO or L_WE_MISC;`
415
416			`Q_S <= L_S( 7 downto 0) when (L_ADR(0) = '0') else L_S(15 downto 8);`
417			`Q_FLAGS <= S_FLAGS;`
418			`Q_Z <= R_R30;`
419			`Q_ADR <= L_ADR;`
420
421			`end Behavioral;`
422