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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:    prog_mem - Behavioral 
-- Create Date:    14:09:04 10/30/2009 
-- Description:    the program memory of a CPU.
--
----------------------------------------------------------------------------------
library IEEE;
use IEEE.STD_LOGIC_1164.ALL;
use IEEE.STD_LOGIC_ARITH.ALL;
use IEEE.STD_LOGIC_UNSIGNED.ALL;
 
-- the content of the program memory.
--
use work.prog_mem_content.all;
 
entity prog_mem is
    port (  I_CLK       : in  std_logic;
 
            I_WAIT      : in  std_logic;
            I_PC        : in  std_logic_vector(15 downto 0); -- word address
            I_PM_ADR    : in  std_logic_vector(11 downto 0); -- byte address
 
            Q_OPC       : out std_logic_vector(31 downto 0);
            Q_PC        : out std_logic_vector(15 downto 0);
            Q_PM_DOUT   : out std_logic_vector( 7 downto 0));
end prog_mem;
 
architecture Behavioral of prog_mem is
 
constant zero_256 : bit_vector := X"00000000000000000000000000000000"
                                & X"00000000000000000000000000000000";
 
component RAMB4_S4_S4
    generic(INIT_00 : bit_vector := zero_256;
            INIT_01 : bit_vector := zero_256;
            INIT_02 : bit_vector := zero_256;
            INIT_03 : bit_vector := zero_256;
            INIT_04 : bit_vector := zero_256;
            INIT_05 : bit_vector := zero_256;
            INIT_06 : bit_vector := zero_256;
            INIT_07 : bit_vector := zero_256;
            INIT_08 : bit_vector := zero_256;
            INIT_09 : bit_vector := zero_256;
            INIT_0A : bit_vector := zero_256;
            INIT_0B : bit_vector := zero_256;
            INIT_0C : bit_vector := zero_256;
            INIT_0D : bit_vector := zero_256;
            INIT_0E : bit_vector := zero_256;
            INIT_0F : bit_vector := zero_256);
 
    port(   ADDRA   : in  std_logic_vector(9 downto 0);
            ADDRB   : in  std_logic_vector(9 downto 0);
            CLKA    : in  std_ulogic;
            CLKB    : in  std_ulogic;
            DIA     : in  std_logic_vector(3 downto 0);
            DIB     : in  std_logic_vector(3 downto 0);
            ENA     : in  std_ulogic;
            ENB     : in  std_ulogic;
            RSTA    : in  std_ulogic;
            RSTB    : in  std_ulogic;
            WEA     : in  std_ulogic;
            WEB     : in  std_ulogic;
 
            DOA     : out std_logic_vector(3 downto 0);
            DOB     : out std_logic_vector(3 downto 0));
end component;
 
signal M_OPC_E      : std_logic_vector(15 downto 0);
signal M_OPC_O      : std_logic_vector(15 downto 0);
signal M_PMD_E      : std_logic_vector(15 downto 0);
signal M_PMD_O      : std_logic_vector(15 downto 0);
 
signal L_WAIT_N     : std_logic;
signal L_PC_0       : std_logic;
signal L_PC_E       : std_logic_vector(10 downto 1);
signal L_PC_O       : std_logic_vector(10 downto 1);
signal L_PMD        : std_logic_vector(15 downto 0);
signal L_PM_ADR_1_0 : std_logic_vector( 1 downto 0);
 
begin
 
    pe_0 : RAMB4_S4_S4 ---------------------------------------------------------
    generic map(INIT_00 => pe_0_00, INIT_01 => pe_0_01, INIT_02 => pe_0_02,
                INIT_03 => pe_0_03, INIT_04 => pe_0_04, INIT_05 => pe_0_05,
                INIT_06 => pe_0_06, INIT_07 => pe_0_07, INIT_08 => pe_0_08,
                INIT_09 => pe_0_09, INIT_0A => pe_0_0A, INIT_0B => pe_0_0B,
                INIT_0C => pe_0_0C, INIT_0D => pe_0_0D, INIT_0E => pe_0_0E,
                INIT_0F => pe_0_0F)
    port map(ADDRA => L_PC_E,                   ADDRB => I_PM_ADR(11 downto 2),
             CLKA  => I_CLK,                    CLKB  => I_CLK,
             DIA   => "0000",                   DIB   => "0000",
             ENA   => L_WAIT_N,                 ENB   => '1',
             RSTA  => '0',                      RSTB  => '0',
             WEA   => '0',                      WEB   => '0',
             DOA   => M_OPC_E(3 downto 0),      DOB   => M_PMD_E(3 downto 0));
 
    pe_1 : RAMB4_S4_S4 ---------------------------------------------------------
    generic map(INIT_00 => pe_1_00, INIT_01 => pe_1_01, INIT_02 => pe_1_02,
                INIT_03 => pe_1_03, INIT_04 => pe_1_04, INIT_05 => pe_1_05,
                INIT_06 => pe_1_06, INIT_07 => pe_1_07, INIT_08 => pe_1_08,
                INIT_09 => pe_1_09, INIT_0A => pe_1_0A, INIT_0B => pe_1_0B,
                INIT_0C => pe_1_0C, INIT_0D => pe_1_0D, INIT_0E => pe_1_0E,
                INIT_0F => pe_1_0F)
    port map(ADDRA => L_PC_E,                   ADDRB => I_PM_ADR(11 downto 2),
             CLKA  => I_CLK,                    CLKB  => I_CLK,
             DIA   => "0000",                   DIB   => "0000",
             ENA   => L_WAIT_N,                 ENB   => '1',
             RSTA  => '0',                      RSTB  => '0',
             WEA   => '0',                      WEB   => '0',
             DOA   => M_OPC_E(7 downto 4),      DOB   => M_PMD_E(7 downto 4));
 
    pe_2 : RAMB4_S4_S4 ---------------------------------------------------------
    generic map(INIT_00 => pe_2_00, INIT_01 => pe_2_01, INIT_02 => pe_2_02,
                INIT_03 => pe_2_03, INIT_04 => pe_2_04, INIT_05 => pe_2_05,
                INIT_06 => pe_2_06, INIT_07 => pe_2_07, INIT_08 => pe_2_08,
                INIT_09 => pe_2_09, INIT_0A => pe_2_0A, INIT_0B => pe_2_0B,
                INIT_0C => pe_2_0C, INIT_0D => pe_2_0D, INIT_0E => pe_2_0E,
                INIT_0F => pe_2_0F)
    port map(ADDRA => L_PC_E,                   ADDRB => I_PM_ADR(11 downto 2),
             CLKA  => I_CLK,                    CLKB  => I_CLK,
             DIA   => "0000",                   DIB   => "0000",
             ENA   => L_WAIT_N,                 ENB   => '1',
             RSTA  => '0',                      RSTB  => '0',
             WEA   => '0',                      WEB   => '0',
             DOA   => M_OPC_E(11 downto 8),     DOB   => M_PMD_E(11 downto 8));
 
    pe_3 : RAMB4_S4_S4 ---------------------------------------------------------
    generic map(INIT_00 => pe_3_00, INIT_01 => pe_3_01, INIT_02 => pe_3_02,
                INIT_03 => pe_3_03, INIT_04 => pe_3_04, INIT_05 => pe_3_05,
                INIT_06 => pe_3_06, INIT_07 => pe_3_07, INIT_08 => pe_3_08,
                INIT_09 => pe_3_09, INIT_0A => pe_3_0A, INIT_0B => pe_3_0B,
                INIT_0C => pe_3_0C, INIT_0D => pe_3_0D, INIT_0E => pe_3_0E,
                INIT_0F => pe_3_0F)
    port map(ADDRA => L_PC_E,                   ADDRB => I_PM_ADR(11 downto 2),
             CLKA  => I_CLK,                    CLKB  => I_CLK,
             DIA   => "0000",                   DIB   => "0000",
             ENA   => L_WAIT_N,                 ENB   => '1',
             RSTA  => '0',                      RSTB  => '0',
             WEA   => '0',                      WEB   => '0',
             DOA   => M_OPC_E(15 downto 12),    DOB   => M_PMD_E(15 downto 12));
 
    po_0 : RAMB4_S4_S4 ---------------------------------------------------------
    generic map(INIT_00 => po_0_00, INIT_01 => po_0_01, INIT_02 => po_0_02,
                INIT_03 => po_0_03, INIT_04 => po_0_04, INIT_05 => po_0_05,
                INIT_06 => po_0_06, INIT_07 => po_0_07, INIT_08 => po_0_08,
                INIT_09 => po_0_09, INIT_0A => po_0_0A, INIT_0B => po_0_0B,
                INIT_0C => po_0_0C, INIT_0D => po_0_0D, INIT_0E => po_0_0E,
                INIT_0F => po_0_0F)
    port map(ADDRA => L_PC_O,                   ADDRB => I_PM_ADR(11 downto 2),
             CLKA  => I_CLK,                    CLKB  => I_CLK,
             DIA   => "0000",                   DIB   => "0000",
             ENA   => L_WAIT_N,                 ENB   => '1',
             RSTA  => '0',                      RSTB  => '0',
             WEA   => '0',                      WEB   => '0',
             DOA   => M_OPC_O(3 downto 0),      DOB   => M_PMD_O(3 downto 0));
 
    po_1 : RAMB4_S4_S4 ---------------------------------------------------------
    generic map(INIT_00 => po_1_00, INIT_01 => po_1_01, INIT_02 => po_1_02,
                INIT_03 => po_1_03, INIT_04 => po_1_04, INIT_05 => po_1_05,
                INIT_06 => po_1_06, INIT_07 => po_1_07, INIT_08 => po_1_08,
                INIT_09 => po_1_09, INIT_0A => po_1_0A, INIT_0B => po_1_0B,
                INIT_0C => po_1_0C, INIT_0D => po_1_0D, INIT_0E => po_1_0E,
                INIT_0F => po_1_0F)
    port map(ADDRA => L_PC_O,                   ADDRB => I_PM_ADR(11 downto 2),
             CLKA  => I_CLK,                    CLKB  => I_CLK,
             DIA   => "0000",                   DIB   => "0000",
             ENA   => L_WAIT_N,                 ENB   => '1',
             RSTA  => '0',                      RSTB  => '0',
             WEA   => '0',                      WEB   => '0',
             DOA   => M_OPC_O(7 downto 4),      DOB   => M_PMD_O(7 downto 4));
 
    po_2 : RAMB4_S4_S4 ---------------------------------------------------------
    generic map(INIT_00 => po_2_00, INIT_01 => po_2_01, INIT_02 => po_2_02,
                INIT_03 => po_2_03, INIT_04 => po_2_04, INIT_05 => po_2_05,
                INIT_06 => po_2_06, INIT_07 => po_2_07, INIT_08 => po_2_08,
                INIT_09 => po_2_09, INIT_0A => po_2_0A, INIT_0B => po_2_0B,
                INIT_0C => po_2_0C, INIT_0D => po_2_0D, INIT_0E => po_2_0E,
                INIT_0F => po_2_0F)
    port map(ADDRA => L_PC_O,                   ADDRB => I_PM_ADR(11 downto 2),
             CLKA  => I_CLK,                    CLKB  => I_CLK,
             DIA   => "0000",                   DIB   => "0000",
             ENA   => L_WAIT_N,                 ENB   => '1',
             RSTA  => '0',                      RSTB  => '0',
             WEA   => '0',                      WEB   => '0',
             DOA   => M_OPC_O(11 downto 8),     DOB   => M_PMD_O(11 downto 8));
 
    po_3 : RAMB4_S4_S4 ---------------------------------------------------------
    generic map(INIT_00 => po_3_00, INIT_01 => po_3_01, INIT_02 => po_3_02,
                INIT_03 => po_3_03, INIT_04 => po_3_04, INIT_05 => po_3_05,
                INIT_06 => po_3_06, INIT_07 => po_3_07, INIT_08 => po_3_08,
                INIT_09 => po_3_09, INIT_0A => po_3_0A, INIT_0B => po_3_0B,
                INIT_0C => po_3_0C, INIT_0D => po_3_0D, INIT_0E => po_3_0E,
                INIT_0F => po_3_0F)
    port map(ADDRA => L_PC_O,                   ADDRB => I_PM_ADR(11 downto 2),
             CLKA  => I_CLK,                    CLKB  => I_CLK,
             DIA   => "0000",                   DIB   => "0000",
             ENA   => L_WAIT_N,                 ENB   => '1',
             RSTA  => '0',                      RSTB  => '0',
             WEA   => '0',                      WEB   => '0',
             DOA   => M_OPC_O(15 downto 12),    DOB   => M_PMD_O(15 downto 12));
 
    -- remember I_PC0 and I_PM_ADR for the output mux.
    --
    pc0: process(I_CLK)
    begin
        if (rising_edge(I_CLK)) then
            Q_PC <= I_PC;
            L_PM_ADR_1_0 <= I_PM_ADR(1 downto 0);
            if ((I_WAIT = '0')) then
                L_PC_0 <= I_PC(0);
            end if;
        end if;
    end process;
 
    L_WAIT_N <= not I_WAIT;
 
    -- we use two memory blocks _E and _O (even and odd).
    -- This gives us a quad-port memory so that we can access
    -- I_PC, I_PC + 1, and PM simultaneously.
    --
    -- I_PC and I_PC + 1 are handled by port A of the memory while PM
    -- is handled by port B.
    --
    -- Q_OPC(15 ... 0) shall contain the word addressed by I_PC, while
    -- Q_OPC(31 ... 16) shall contain the word addressed by I_PC + 1.
    --
    -- There are two cases:
    --
    -- case A: I_PC     is even, thus I_PC + 1 is odd
    -- case B: I_PC + 1 is odd , thus I_PC is even
    --
    L_PC_O <= I_PC(10 downto 1);
    L_PC_E <= I_PC(10 downto 1) + ("000000000" & I_PC(0));
    Q_OPC(15 downto  0) <= M_OPC_E when L_PC_0 = '0' else M_OPC_O;
    Q_OPC(31 downto 16) <= M_OPC_E when L_PC_0 = '1' else M_OPC_O;
 
    L_PMD <= M_PMD_E               when (L_PM_ADR_1_0(1) = '0') else M_PMD_O;
    Q_PM_DOUT <= L_PMD(7 downto 0) when (L_PM_ADR_1_0(0) = '0')
            else L_PMD(15 downto 8);
 
end Behavioral;
 

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[/] [cpu_lecture/] [trunk/] [src/] [prog_mem.vhd] - Blame information for rev 5

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: prog_mem - Behavioral`
23			`-- Create Date: 14:09:04 10/30/2009`
24			`-- Description: the program memory of a CPU.`
25			`--`
26			`----------------------------------------------------------------------------------`
27			`library IEEE;`
28			`use IEEE.STD_LOGIC_1164.ALL;`
29			`use IEEE.STD_LOGIC_ARITH.ALL;`
30			`use IEEE.STD_LOGIC_UNSIGNED.ALL;`
31
32			`-- the content of the program memory.`
33			`--`
34			`use work.prog_mem_content.all;`
35
36			`entity prog_mem is`
37			`port ( I_CLK : in std_logic;`
38
39			`I_WAIT : in std_logic;`
40			`I_PC : in std_logic_vector(15 downto 0); -- word address`
41			`I_PM_ADR : in std_logic_vector(11 downto 0); -- byte address`
42
43			`Q_OPC : out std_logic_vector(31 downto 0);`
44			`Q_PC : out std_logic_vector(15 downto 0);`
45			`Q_PM_DOUT : out std_logic_vector( 7 downto 0));`
46			`end prog_mem;`
47
48			`architecture Behavioral of prog_mem is`
49
50			`constant zero_256 : bit_vector := X"00000000000000000000000000000000"`
51			`& X"00000000000000000000000000000000";`
52
53			`component RAMB4_S4_S4`
54			`generic(INIT_00 : bit_vector := zero_256;`
55			`INIT_01 : bit_vector := zero_256;`
56			`INIT_02 : bit_vector := zero_256;`
57			`INIT_03 : bit_vector := zero_256;`
58			`INIT_04 : bit_vector := zero_256;`
59			`INIT_05 : bit_vector := zero_256;`
60			`INIT_06 : bit_vector := zero_256;`
61			`INIT_07 : bit_vector := zero_256;`
62			`INIT_08 : bit_vector := zero_256;`
63			`INIT_09 : bit_vector := zero_256;`
64			`INIT_0A : bit_vector := zero_256;`
65			`INIT_0B : bit_vector := zero_256;`
66			`INIT_0C : bit_vector := zero_256;`
67			`INIT_0D : bit_vector := zero_256;`
68			`INIT_0E : bit_vector := zero_256;`
69			`INIT_0F : bit_vector := zero_256);`
70
71			`port( ADDRA : in std_logic_vector(9 downto 0);`
72			`ADDRB : in std_logic_vector(9 downto 0);`
73			`CLKA : in std_ulogic;`
74			`CLKB : in std_ulogic;`
75			`DIA : in std_logic_vector(3 downto 0);`
76			`DIB : in std_logic_vector(3 downto 0);`
77			`ENA : in std_ulogic;`
78			`ENB : in std_ulogic;`
79			`RSTA : in std_ulogic;`
80			`RSTB : in std_ulogic;`
81			`WEA : in std_ulogic;`
82			`WEB : in std_ulogic;`
83
84			`DOA : out std_logic_vector(3 downto 0);`
85			`DOB : out std_logic_vector(3 downto 0));`
86			`end component;`
87
88			`signal M_OPC_E : std_logic_vector(15 downto 0);`
89			`signal M_OPC_O : std_logic_vector(15 downto 0);`
90			`signal M_PMD_E : std_logic_vector(15 downto 0);`
91			`signal M_PMD_O : std_logic_vector(15 downto 0);`
92
93			`signal L_WAIT_N : std_logic;`
94			`signal L_PC_0 : std_logic;`
95			`signal L_PC_E : std_logic_vector(10 downto 1);`
96			`signal L_PC_O : std_logic_vector(10 downto 1);`
97			`signal L_PMD : std_logic_vector(15 downto 0);`
98			`signal L_PM_ADR_1_0 : std_logic_vector( 1 downto 0);`
99
100			`begin`
101
102			`pe_0 : RAMB4_S4_S4 ---------------------------------------------------------`
103			`generic map(INIT_00 => pe_0_00, INIT_01 => pe_0_01, INIT_02 => pe_0_02,`
104			`INIT_03 => pe_0_03, INIT_04 => pe_0_04, INIT_05 => pe_0_05,`
105			`INIT_06 => pe_0_06, INIT_07 => pe_0_07, INIT_08 => pe_0_08,`
106			`INIT_09 => pe_0_09, INIT_0A => pe_0_0A, INIT_0B => pe_0_0B,`
107			`INIT_0C => pe_0_0C, INIT_0D => pe_0_0D, INIT_0E => pe_0_0E,`
108			`INIT_0F => pe_0_0F)`
109			`port map(ADDRA => L_PC_E, ADDRB => I_PM_ADR(11 downto 2),`
110			`CLKA => I_CLK, CLKB => I_CLK,`
111			`DIA => "0000", DIB => "0000",`
112			`ENA => L_WAIT_N, ENB => '1',`
113			`RSTA => '0', RSTB => '0',`
114			`WEA => '0', WEB => '0',`
115			`DOA => M_OPC_E(3 downto 0), DOB => M_PMD_E(3 downto 0));`
116
117			`pe_1 : RAMB4_S4_S4 ---------------------------------------------------------`
118			`generic map(INIT_00 => pe_1_00, INIT_01 => pe_1_01, INIT_02 => pe_1_02,`
119			`INIT_03 => pe_1_03, INIT_04 => pe_1_04, INIT_05 => pe_1_05,`
120			`INIT_06 => pe_1_06, INIT_07 => pe_1_07, INIT_08 => pe_1_08,`
121			`INIT_09 => pe_1_09, INIT_0A => pe_1_0A, INIT_0B => pe_1_0B,`
122			`INIT_0C => pe_1_0C, INIT_0D => pe_1_0D, INIT_0E => pe_1_0E,`
123			`INIT_0F => pe_1_0F)`
124			`port map(ADDRA => L_PC_E, ADDRB => I_PM_ADR(11 downto 2),`
125			`CLKA => I_CLK, CLKB => I_CLK,`
126			`DIA => "0000", DIB => "0000",`
127			`ENA => L_WAIT_N, ENB => '1',`
128			`RSTA => '0', RSTB => '0',`
129			`WEA => '0', WEB => '0',`
130			`DOA => M_OPC_E(7 downto 4), DOB => M_PMD_E(7 downto 4));`
131
132			`pe_2 : RAMB4_S4_S4 ---------------------------------------------------------`
133			`generic map(INIT_00 => pe_2_00, INIT_01 => pe_2_01, INIT_02 => pe_2_02,`
134			`INIT_03 => pe_2_03, INIT_04 => pe_2_04, INIT_05 => pe_2_05,`
135			`INIT_06 => pe_2_06, INIT_07 => pe_2_07, INIT_08 => pe_2_08,`
136			`INIT_09 => pe_2_09, INIT_0A => pe_2_0A, INIT_0B => pe_2_0B,`
137			`INIT_0C => pe_2_0C, INIT_0D => pe_2_0D, INIT_0E => pe_2_0E,`
138			`INIT_0F => pe_2_0F)`
139			`port map(ADDRA => L_PC_E, ADDRB => I_PM_ADR(11 downto 2),`
140			`CLKA => I_CLK, CLKB => I_CLK,`
141			`DIA => "0000", DIB => "0000",`
142			`ENA => L_WAIT_N, ENB => '1',`
143			`RSTA => '0', RSTB => '0',`
144			`WEA => '0', WEB => '0',`
145			`DOA => M_OPC_E(11 downto 8), DOB => M_PMD_E(11 downto 8));`
146
147			`pe_3 : RAMB4_S4_S4 ---------------------------------------------------------`
148			`generic map(INIT_00 => pe_3_00, INIT_01 => pe_3_01, INIT_02 => pe_3_02,`
149			`INIT_03 => pe_3_03, INIT_04 => pe_3_04, INIT_05 => pe_3_05,`
150			`INIT_06 => pe_3_06, INIT_07 => pe_3_07, INIT_08 => pe_3_08,`
151			`INIT_09 => pe_3_09, INIT_0A => pe_3_0A, INIT_0B => pe_3_0B,`
152			`INIT_0C => pe_3_0C, INIT_0D => pe_3_0D, INIT_0E => pe_3_0E,`
153			`INIT_0F => pe_3_0F)`
154			`port map(ADDRA => L_PC_E, ADDRB => I_PM_ADR(11 downto 2),`
155			`CLKA => I_CLK, CLKB => I_CLK,`
156			`DIA => "0000", DIB => "0000",`
157			`ENA => L_WAIT_N, ENB => '1',`
158			`RSTA => '0', RSTB => '0',`
159			`WEA => '0', WEB => '0',`
160			`DOA => M_OPC_E(15 downto 12), DOB => M_PMD_E(15 downto 12));`
161
162			`po_0 : RAMB4_S4_S4 ---------------------------------------------------------`
163			`generic map(INIT_00 => po_0_00, INIT_01 => po_0_01, INIT_02 => po_0_02,`
164			`INIT_03 => po_0_03, INIT_04 => po_0_04, INIT_05 => po_0_05,`
165			`INIT_06 => po_0_06, INIT_07 => po_0_07, INIT_08 => po_0_08,`
166			`INIT_09 => po_0_09, INIT_0A => po_0_0A, INIT_0B => po_0_0B,`
167			`INIT_0C => po_0_0C, INIT_0D => po_0_0D, INIT_0E => po_0_0E,`
168			`INIT_0F => po_0_0F)`
169			`port map(ADDRA => L_PC_O, ADDRB => I_PM_ADR(11 downto 2),`
170			`CLKA => I_CLK, CLKB => I_CLK,`
171			`DIA => "0000", DIB => "0000",`
172			`ENA => L_WAIT_N, ENB => '1',`
173			`RSTA => '0', RSTB => '0',`
174			`WEA => '0', WEB => '0',`
175			`DOA => M_OPC_O(3 downto 0), DOB => M_PMD_O(3 downto 0));`
176
177			`po_1 : RAMB4_S4_S4 ---------------------------------------------------------`
178			`generic map(INIT_00 => po_1_00, INIT_01 => po_1_01, INIT_02 => po_1_02,`
179			`INIT_03 => po_1_03, INIT_04 => po_1_04, INIT_05 => po_1_05,`
180			`INIT_06 => po_1_06, INIT_07 => po_1_07, INIT_08 => po_1_08,`
181			`INIT_09 => po_1_09, INIT_0A => po_1_0A, INIT_0B => po_1_0B,`
182			`INIT_0C => po_1_0C, INIT_0D => po_1_0D, INIT_0E => po_1_0E,`
183			`INIT_0F => po_1_0F)`
184			`port map(ADDRA => L_PC_O, ADDRB => I_PM_ADR(11 downto 2),`
185			`CLKA => I_CLK, CLKB => I_CLK,`
186			`DIA => "0000", DIB => "0000",`
187			`ENA => L_WAIT_N, ENB => '1',`
188			`RSTA => '0', RSTB => '0',`
189			`WEA => '0', WEB => '0',`
190			`DOA => M_OPC_O(7 downto 4), DOB => M_PMD_O(7 downto 4));`
191
192			`po_2 : RAMB4_S4_S4 ---------------------------------------------------------`
193			`generic map(INIT_00 => po_2_00, INIT_01 => po_2_01, INIT_02 => po_2_02,`
194			`INIT_03 => po_2_03, INIT_04 => po_2_04, INIT_05 => po_2_05,`
195			`INIT_06 => po_2_06, INIT_07 => po_2_07, INIT_08 => po_2_08,`
196			`INIT_09 => po_2_09, INIT_0A => po_2_0A, INIT_0B => po_2_0B,`
197			`INIT_0C => po_2_0C, INIT_0D => po_2_0D, INIT_0E => po_2_0E,`
198			`INIT_0F => po_2_0F)`
199			`port map(ADDRA => L_PC_O, ADDRB => I_PM_ADR(11 downto 2),`
200			`CLKA => I_CLK, CLKB => I_CLK,`
201			`DIA => "0000", DIB => "0000",`
202			`ENA => L_WAIT_N, ENB => '1',`
203			`RSTA => '0', RSTB => '0',`
204			`WEA => '0', WEB => '0',`
205			`DOA => M_OPC_O(11 downto 8), DOB => M_PMD_O(11 downto 8));`
206
207			`po_3 : RAMB4_S4_S4 ---------------------------------------------------------`
208			`generic map(INIT_00 => po_3_00, INIT_01 => po_3_01, INIT_02 => po_3_02,`
209			`INIT_03 => po_3_03, INIT_04 => po_3_04, INIT_05 => po_3_05,`
210			`INIT_06 => po_3_06, INIT_07 => po_3_07, INIT_08 => po_3_08,`
211			`INIT_09 => po_3_09, INIT_0A => po_3_0A, INIT_0B => po_3_0B,`
212			`INIT_0C => po_3_0C, INIT_0D => po_3_0D, INIT_0E => po_3_0E,`
213			`INIT_0F => po_3_0F)`
214			`port map(ADDRA => L_PC_O, ADDRB => I_PM_ADR(11 downto 2),`
215			`CLKA => I_CLK, CLKB => I_CLK,`
216			`DIA => "0000", DIB => "0000",`
217			`ENA => L_WAIT_N, ENB => '1',`
218			`RSTA => '0', RSTB => '0',`
219			`WEA => '0', WEB => '0',`
220			`DOA => M_OPC_O(15 downto 12), DOB => M_PMD_O(15 downto 12));`
221
222			`-- remember I_PC0 and I_PM_ADR for the output mux.`
223			`--`
224			`pc0: process(I_CLK)`
225			`begin`
226			`if (rising_edge(I_CLK)) then`
227			`Q_PC <= I_PC;`
228			`L_PM_ADR_1_0 <= I_PM_ADR(1 downto 0);`
229			`if ((I_WAIT = '0')) then`
230			`L_PC_0 <= I_PC(0);`
231			`end if;`
232			`end if;`
233			`end process;`
234
235			`L_WAIT_N <= not I_WAIT;`
236
237			`-- we use two memory blocks _E and _O (even and odd).`
238			`-- This gives us a quad-port memory so that we can access`
239			`-- I_PC, I_PC + 1, and PM simultaneously.`
240			`--`
241			`-- I_PC and I_PC + 1 are handled by port A of the memory while PM`
242			`-- is handled by port B.`
243			`--`
244			`-- Q_OPC(15 ... 0) shall contain the word addressed by I_PC, while`
245			`-- Q_OPC(31 ... 16) shall contain the word addressed by I_PC + 1.`
246			`--`
247			`-- There are two cases:`
248			`--`
249			`-- case A: I_PC is even, thus I_PC + 1 is odd`
250			`-- case B: I_PC + 1 is odd , thus I_PC is even`
251			`--`
252			`L_PC_O <= I_PC(10 downto 1);`
253			`L_PC_E <= I_PC(10 downto 1) + ("000000000" & I_PC(0));`
254			`Q_OPC(15 downto 0) <= M_OPC_E when L_PC_0 = '0' else M_OPC_O;`
255			`Q_OPC(31 downto 16) <= M_OPC_E when L_PC_0 = '1' else M_OPC_O;`
256
257			`L_PMD <= M_PMD_E when (L_PM_ADR_1_0(1) = '0') else M_PMD_O;`
258			`Q_PM_DOUT <= L_PMD(7 downto 0) when (L_PM_ADR_1_0(0) = '0')`
259			`else L_PMD(15 downto 8);`
260
261			`end Behavioral;`
262