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[/] [core_arm/] [trunk/] [vhdl/] [sparc/] [cachemem.vhd] - Blame information for rev 4

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----------------------------------------------------------------------------
--  This file is a part of the LEON VHDL model
--  Copyright (C) 2003  Gaisler Research
--
--  This library is free software; you can redistribute it and/or
--  modify it under the terms of the GNU Lesser General Public
--  License as published by the Free Software Foundation; either
--  version 2 of the License, or (at your option) any later version.
--
--  See the file COPYING.LGPL for the full details of the license.
 
 
-----------------------------------------------------------------------------
-- Entity:      cachemem
-- File:        cachemem.vhd
-- Author:      Jiri Gaisler - Gaisler Research
-- Description: Contains ram cells for both instruction and data caches
------------------------------------------------------------------------------
 
library IEEE;
use IEEE.std_logic_1164.all;
use IEEE.std_logic_arith.all;
use work.leon_target.all;
use work.leon_config.all;
use work.mmuconfig.all;
use work.leon_iface.all;
use work.macro.all;
use work.tech_map.all;
 
entity cachemem is
  port (
        clk   : in  clk_type;
        crami : in  cram_in_type;
        cramo : out cram_out_type
  );
end;
 
architecture rtl of cachemem is
 
  constant ITDEPTH : natural := 2**IOFFSET_BITS;
  constant DTDEPTH : natural := 2**DOFFSET_BITS;
 
  -- i/d tag layout
  -- +-----+----------+--------+-----+-------+
  -- | LRR | LOCK_BIT | MMUCTX | TAG | VALID |
  -- +-----+----------+--------+-----+-------+
 
  constant ITWIDTH : natural := ITAG_BITS + ILRR_BIT + ICLOCK_BIT + MMUCTX_BITS;
  constant DTWIDTH : natural := DTAG_BITS + DLRR_BIT + DCLOCK_BIT + MMUCTX_BITS;
  constant IDWIDTH : natural := 32;
  constant DDWIDTH : natural := 32;
 
  subtype dtdatain_vector is std_logic_vector(DTWIDTH downto 0);
  type dtdatain_type is array (0 to MAXSETS-1) of dtdatain_vector;
  subtype itdatain_vector is std_logic_vector(ITWIDTH downto 0);
  type itdatain_type is array (0 to MAXSETS-1) of itdatain_vector;
 
  subtype itdataout_vector is std_logic_vector(ITWIDTH downto 0);
  type itdataout_type is array (0 to MAXSETS-1) of itdataout_vector;
  subtype iddataout_vector is std_logic_vector(IDWIDTH -1 downto 0);
  type iddataout_type is array (0 to MAXSETS-1) of iddataout_vector;
  subtype dtdataout_vector is std_logic_vector(DTWIDTH downto 0);
  type dtdataout_type is array (0 to MAXSETS-1) of dtdataout_vector;
  subtype dddataout_vector is std_logic_vector(DDWIDTH -1 downto 0);
  type dddataout_type is array (0 to MAXSETS-1) of dddataout_vector;
 
 
  signal itaddr    : std_logic_vector(IOFFSET_BITS + ILINE_BITS -1 downto ILINE_BITS);
  signal idaddr    : std_logic_vector(IOFFSET_BITS + ILINE_BITS -1 downto 0);
 
 
  --signal itdatain  : std_logic_vector(ITWIDTH -1 downto 0);
  signal itdatain  : itdatain_type;
  signal itdataout : itdataout_type;
  signal iddatain  : std_logic_vector(IDWIDTH -1 downto 0);
  signal iddataout : iddataout_type;
 
  signal itenable  : std_logic;
  signal idenable  : std_logic;
  signal itwrite   : std_logic_vector(0 to MAXSETS-1);
  signal idwrite   : std_logic_vector(0 to MAXSETS-1);
 
  signal dtaddr    : std_logic_vector(DOFFSET_BITS + DLINE_BITS -1 downto DLINE_BITS);
  signal dtaddr2   : std_logic_vector(DOFFSET_BITS + DLINE_BITS -1 downto DLINE_BITS);
  signal ddaddr    : std_logic_vector(DOFFSET_BITS + DLINE_BITS -1 downto 0);
 
  --signal dtdatain  : std_logic_vector(DTWIDTH -1 downto 0);
  signal dtdatain  : dtdatain_type;
--  signal dtdatain2 : std_logic_vector(DTWIDTH -1 downto 0);
  signal dtdatain2 : dtdatain_type;
  signal dtdataout : dtdataout_type;
  signal dtdataout2: dtdataout_type;
  signal dddatain  : std_logic_vector(DDWIDTH -1 downto 0);
  signal dddataout : dddataout_type;
  signal ldataout  : std_logic_vector(31 downto 0);
 
  signal dtenable  : std_logic;
  signal dtenable2 : std_logic;
  signal ddenable  : std_logic;
  signal dtwrite   : std_logic_vector(0 to MAXSETS-1);
  signal dtwrite2  : std_logic_vector(0 to MAXSETS-1);
  signal ddwrite   : std_logic_vector(0 to MAXSETS-1);
 
  signal vcc, gnd  : std_logic;
 
begin
 
  vcc <= '1'; gnd <= '0';
  itaddr <= crami.icramin.idramin.address(IOFFSET_BITS + ILINE_BITS -1 downto ILINE_BITS);
  idaddr <= crami.icramin.idramin.address;
 
 
  itinsel : process(crami, dtdataout2)
 
  variable viddatain  : std_logic_vector(IDWIDTH -1 downto 0);
  variable vdddatain  : std_logic_vector(DDWIDTH -1 downto 0);
  variable vitdatain : itdatain_type;
  variable vdtdatain : dtdatain_type;
  variable vdtdatain2 : dtdatain_type;
  begin
    viddatain := (others => '0');
    vdddatain := (others => '0');
 
    viddatain(31 downto 0) := crami.icramin.idramin.data;
 
    for i in 0 to DSETS-1 loop
      vdtdatain(i) := (others => '0');
      if M_EN then
        vdtdatain(i)((DTWIDTH - (DLRR_BIT+DCLOCK_BIT+1)) downto (DTWIDTH - (DLRR_BIT+DCLOCK_BIT+M_CTX_SZ))) := crami.dcramin.dtramin.ctx;
      end if;
      vdtdatain(i)(DTWIDTH-(DLRR_BIT + DCLOCK_BIT)) := crami.dcramin.dtramin.lrr(i);
      vdtdatain(i)(DTWIDTH-DCLOCK_BIT) := crami.dcramin.dtramin.lock(i);
      vdtdatain(i)(DTAG_BITS-1 downto 0) := crami.dcramin.dtramin.tag & crami.dcramin.dtramin.valid;
      if (DSETS > 1) and (crami.dcramin.dtramin.flush = '1') then
        vdtdatain(i)(DLINE_SIZE+1 downto DLINE_SIZE) :=  std_logic_vector(conv_unsigned(i,2));
      end if;
    end loop;
 
    vdtdatain2 := (others => (others => '0'));
    for i in 0 to DSETS-1 loop
 
      vdtdatain2(i)(DTWIDTH-(DLRR_BIT + DCLOCK_BIT)) := dtdataout2(i)(DTWIDTH-(DLRR_BIT+DCLOCK_BIT));
      vdtdatain2(i)(DTWIDTH-DCLOCK_BIT) := dtdataout2(i)(DTWIDTH-DCLOCK_BIT);
      vdtdatain2(i)(DTAG_BITS-1 downto DLINE_SIZE) := crami.dcramin.dtraminsn.tag;
    end loop;
    vdddatain(32 - 1 downto 0) := crami.dcramin.ddramin.data;
 
 
    for i in 0 to ISETS-1 loop
      vitdatain(i) := (others => '0');
      if M_EN then
        vitdatain(i)((ITWIDTH - (ILRR_BIT+ICLOCK_BIT+1)) downto (ITWIDTH - (ILRR_BIT+ICLOCK_BIT+M_CTX_SZ))) := crami.icramin.itramin.ctx;
      end if;
      vitdatain(i)(ITWIDTH-(ILRR_BIT + ICLOCK_BIT)) := crami.icramin.itramin.lrr;
      vitdatain(i)(ITWIDTH-ICLOCK_BIT) := crami.icramin.itramin.lock;
      vitdatain(i)(ITAG_BITS-1 downto 0) := crami.icramin.itramin.tag & crami.icramin.itramin.valid;
      if (ISETS > 1) and (crami.icramin.itramin.flush = '1') then
        vitdatain(i)(ILINE_SIZE+1 downto ILINE_SIZE) :=  std_logic_vector(conv_unsigned(i,2));
      end if;
    end loop;
 
    itdatain <= vitdatain; iddatain <= viddatain;
    dtdatain <= vdtdatain; dtdatain2 <= vdtdatain2; dddatain <= vdddatain;
 
  end process;
 
 
  itwrite   <= crami.icramin.itramin.write;
  idwrite   <= crami.icramin.idramin.write;
  itenable  <= crami.icramin.itramin.enable;
  idenable  <= crami.icramin.idramin.enable;
 
  dtaddr <= crami.dcramin.ddramin.address(DOFFSET_BITS + DLINE_BITS -1 downto DLINE_BITS);
  dtaddr2 <= crami.dcramin.dtraminsn.address;
  ddaddr <= crami.dcramin.ddramin.address;
  dtwrite   <= crami.dcramin.dtramin.write;
  dtwrite2  <= crami.dcramin.dtraminsn.write;
  ddwrite   <= crami.dcramin.ddramin.write;
  dtenable  <= crami.dcramin.dtramin.enable;
  dtenable2 <= crami.dcramin.dtraminsn.enable;
  ddenable  <= crami.dcramin.ddramin.enable;
 
 
  it0 : for i in 0 to ISETS-1 generate
    itags0 : syncram
      generic map ( dbits => ITWIDTH, abits => IOFFSET_BITS)
      port map ( itaddr, clk, itdatain(i)(ITWIDTH-1 downto 0), itdataout(i)(ITWIDTH-1 downto 0), itenable, itwrite(i));
  end generate;
 
  dtags0 : if not DSNOOP generate
    dt0 : for i in 0 to DSETS-1 generate
      dtags0 : syncram
      generic map ( dbits => DTWIDTH, abits => DOFFSET_BITS)
      port map ( dtaddr, clk, dtdatain(i)(DTWIDTH-1 downto 0), dtdataout(i)(DTWIDTH-1 downto 0), dtenable, dtwrite(i));
    end generate;
  end generate;
 
  dtags1 : if DSNOOP generate
    dt0 : for i in 0 to DSETS-1 generate
      dtags0 : dpsyncram
      generic map ( dbits => DTWIDTH, abits => DOFFSET_BITS)
      port map ( dtaddr, clk, dtdatain(i)(DTWIDTH-1 downto 0), dtdataout(i)(DTWIDTH-1 downto 0), dtenable, dtwrite(i),
                 dtaddr2, dtdatain2(i)(DTWIDTH-1 downto 0), dtdataout2(i)(DTWIDTH-1 downto 0), dtenable2, dtwrite2(i));
    end generate;
  end generate;
 
  id0 : for i in 0 to ISETS-1 generate
    idata0 : syncram
      generic map ( dbits => IDWIDTH, abits => IOFFSET_BITS+ILINE_BITS)
      port map ( idaddr, clk, iddatain, iddataout(i), idenable, idwrite(i));
  end generate;
 
  dd0 : for i in 0 to DSETS-1 generate
    ddata0 : syncram
     generic map ( dbits => DDWIDTH, abits => DOFFSET_BITS+DLINE_BITS)
      port map ( ddaddr, clk, dddatain, dddataout(i), ddenable, ddwrite(i));
  end generate;
 
  ld0 : if LOCAL_RAM generate
    ldata0 : syncram
     generic map ( dbits => 32, abits => LOCAL_RAM_BITS)
      port map ( crami.dcramin.ldramin.address, clk, dddatain, ldataout,
                crami.dcramin.ldramin.enable, crami.dcramin.ldramin.write);
  end generate;
 
  itx : for i in 0 to ISETS-1 generate
    itdataout(i)(ITWIDTH) <= '0';
    cramo.icramout.itramout(i).valid <= itdataout(i)(ILINE_SIZE -1 downto 0);
    cramo.icramout.itramout(i).tag <= itdataout(i)(ITAG_BITS-1 downto ILINE_SIZE);
    cramo.icramout.itramout(i).lrr <= itdataout(i)(ITWIDTH - (ILRR_BIT+ICLOCK_BIT));
    cramo.icramout.itramout(i).lock <= itdataout(i)(ITWIDTH-ICLOCK_BIT);
    cramo.icramout.itramout(i).ctx <= itdataout(i)((ITWIDTH - (ILRR_BIT+ICLOCK_BIT+1)) downto (ITWIDTH - (ILRR_BIT+ICLOCK_BIT+M_CTX_SZ)));
    cramo.icramout.idramout(i).data <= iddataout(i)(31 downto 0);
 
  end generate;
 
 
  itd : for i in 0 to DSETS-1 generate
    dtdataout(i)(DTWIDTH) <= '0';
    dtdataout2(i)(DTWIDTH) <= '0';
    cramo.dcramout.dtramout(i).valid <= dtdataout(i)(DLINE_SIZE -1 downto 0);
    cramo.dcramout.dtramout(i).tag <= dtdataout(i)(DTAG_BITS-1 downto DLINE_SIZE);
    cramo.dcramout.dtramout(i).lrr <= dtdataout(i)(DTWIDTH-(DLRR_BIT+DCLOCK_BIT));
    cramo.dcramout.dtramout(i).lock <= dtdataout(i)(DTWIDTH-DCLOCK_BIT);
    cramo.dcramout.dtramout(i).ctx <= dtdataout(i)((DTWIDTH - (DLRR_BIT+DCLOCK_BIT+1)) downto (DTWIDTH - (DLRR_BIT+DCLOCK_BIT+M_CTX_SZ)));
    cramo.dcramout.dtramoutsn(i).tag <= dtdataout2(i)(DTAG_BITS-1 downto DLINE_SIZE);
    cramo.dcramout.ddramout(i).data <= ldataout when LOCAL_RAM and (crami.dcramin.ldramin.read = '1')
    else dddataout(i)(31 downto 0);
 
  end generate;
 
end ;
 

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Subversion Repositories core_arm

[/] [core_arm/] [trunk/] [vhdl/] [sparc/] [cachemem.vhd] - Blame information for rev 4

Line No.	Rev	Author	Line
1	2	tarookumic
2
3
4
5			`----------------------------------------------------------------------------`
6			`-- This file is a part of the LEON VHDL model`
7			`-- Copyright (C) 2003 Gaisler Research`
8			`--`
9			`-- This library is free software; you can redistribute it and/or`
10			`-- modify it under the terms of the GNU Lesser General Public`
11			`-- License as published by the Free Software Foundation; either`
12			`-- version 2 of the License, or (at your option) any later version.`
13			`--`
14			`-- See the file COPYING.LGPL for the full details of the license.`
15
16
17			`-----------------------------------------------------------------------------`
18			`-- Entity: cachemem`
19			`-- File: cachemem.vhd`
20			`-- Author: Jiri Gaisler - Gaisler Research`
21			`-- Description: Contains ram cells for both instruction and data caches`
22			`------------------------------------------------------------------------------`
23
24			`library IEEE;`
25			`use IEEE.std_logic_1164.all;`
26			`use IEEE.std_logic_arith.all;`
27			`use work.leon_target.all;`
28			`use work.leon_config.all;`
29			`use work.mmuconfig.all;`
30			`use work.leon_iface.all;`
31			`use work.macro.all;`
32			`use work.tech_map.all;`
33
34			`entity cachemem is`
35			`port (`
36			`clk : in clk_type;`
37			`crami : in cram_in_type;`
38			`cramo : out cram_out_type`
39			`);`
40			`end;`
41
42			`architecture rtl of cachemem is`
43
44			`constant ITDEPTH : natural := 2**IOFFSET_BITS;`
45			`constant DTDEPTH : natural := 2**DOFFSET_BITS;`
46
47			`-- i/d tag layout`
48			`-- +-----+----------+--------+-----+-------+`
49			`-- \| LRR \| LOCK_BIT \| MMUCTX \| TAG \| VALID \|`
50			`-- +-----+----------+--------+-----+-------+`
51
52			`constant ITWIDTH : natural := ITAG_BITS + ILRR_BIT + ICLOCK_BIT + MMUCTX_BITS;`
53			`constant DTWIDTH : natural := DTAG_BITS + DLRR_BIT + DCLOCK_BIT + MMUCTX_BITS;`
54			`constant IDWIDTH : natural := 32;`
55			`constant DDWIDTH : natural := 32;`
56
57			`subtype dtdatain_vector is std_logic_vector(DTWIDTH downto 0);`
58			`type dtdatain_type is array (0 to MAXSETS-1) of dtdatain_vector;`
59			`subtype itdatain_vector is std_logic_vector(ITWIDTH downto 0);`
60			`type itdatain_type is array (0 to MAXSETS-1) of itdatain_vector;`
61
62			`subtype itdataout_vector is std_logic_vector(ITWIDTH downto 0);`
63			`type itdataout_type is array (0 to MAXSETS-1) of itdataout_vector;`
64			`subtype iddataout_vector is std_logic_vector(IDWIDTH -1 downto 0);`
65			`type iddataout_type is array (0 to MAXSETS-1) of iddataout_vector;`
66			`subtype dtdataout_vector is std_logic_vector(DTWIDTH downto 0);`
67			`type dtdataout_type is array (0 to MAXSETS-1) of dtdataout_vector;`
68			`subtype dddataout_vector is std_logic_vector(DDWIDTH -1 downto 0);`
69			`type dddataout_type is array (0 to MAXSETS-1) of dddataout_vector;`
70
71
72			`signal itaddr : std_logic_vector(IOFFSET_BITS + ILINE_BITS -1 downto ILINE_BITS);`
73			`signal idaddr : std_logic_vector(IOFFSET_BITS + ILINE_BITS -1 downto 0);`
74
75
76			`--signal itdatain : std_logic_vector(ITWIDTH -1 downto 0);`
77			`signal itdatain : itdatain_type;`
78			`signal itdataout : itdataout_type;`
79			`signal iddatain : std_logic_vector(IDWIDTH -1 downto 0);`
80			`signal iddataout : iddataout_type;`
81
82			`signal itenable : std_logic;`
83			`signal idenable : std_logic;`
84			`signal itwrite : std_logic_vector(0 to MAXSETS-1);`
85			`signal idwrite : std_logic_vector(0 to MAXSETS-1);`
86
87			`signal dtaddr : std_logic_vector(DOFFSET_BITS + DLINE_BITS -1 downto DLINE_BITS);`
88			`signal dtaddr2 : std_logic_vector(DOFFSET_BITS + DLINE_BITS -1 downto DLINE_BITS);`
89			`signal ddaddr : std_logic_vector(DOFFSET_BITS + DLINE_BITS -1 downto 0);`
90
91			`--signal dtdatain : std_logic_vector(DTWIDTH -1 downto 0);`
92			`signal dtdatain : dtdatain_type;`
93			`-- signal dtdatain2 : std_logic_vector(DTWIDTH -1 downto 0);`
94			`signal dtdatain2 : dtdatain_type;`
95			`signal dtdataout : dtdataout_type;`
96			`signal dtdataout2: dtdataout_type;`
97			`signal dddatain : std_logic_vector(DDWIDTH -1 downto 0);`
98			`signal dddataout : dddataout_type;`
99			`signal ldataout : std_logic_vector(31 downto 0);`
100
101			`signal dtenable : std_logic;`
102			`signal dtenable2 : std_logic;`
103			`signal ddenable : std_logic;`
104			`signal dtwrite : std_logic_vector(0 to MAXSETS-1);`
105			`signal dtwrite2 : std_logic_vector(0 to MAXSETS-1);`
106			`signal ddwrite : std_logic_vector(0 to MAXSETS-1);`
107
108			`signal vcc, gnd : std_logic;`
109
110			`begin`
111
112			`vcc <= '1'; gnd <= '0';`
113			`itaddr <= crami.icramin.idramin.address(IOFFSET_BITS + ILINE_BITS -1 downto ILINE_BITS);`
114			`idaddr <= crami.icramin.idramin.address;`
115
116
117			`itinsel : process(crami, dtdataout2)`
118
119			`variable viddatain : std_logic_vector(IDWIDTH -1 downto 0);`
120			`variable vdddatain : std_logic_vector(DDWIDTH -1 downto 0);`
121			`variable vitdatain : itdatain_type;`
122			`variable vdtdatain : dtdatain_type;`
123			`variable vdtdatain2 : dtdatain_type;`
124			`begin`
125			`viddatain := (others => '0');`
126			`vdddatain := (others => '0');`
127
128			`viddatain(31 downto 0) := crami.icramin.idramin.data;`
129
130			`for i in 0 to DSETS-1 loop`
131			`vdtdatain(i) := (others => '0');`
132			`if M_EN then`
133			`vdtdatain(i)((DTWIDTH - (DLRR_BIT+DCLOCK_BIT+1)) downto (DTWIDTH - (DLRR_BIT+DCLOCK_BIT+M_CTX_SZ))) := crami.dcramin.dtramin.ctx;`
134			`end if;`
135			`vdtdatain(i)(DTWIDTH-(DLRR_BIT + DCLOCK_BIT)) := crami.dcramin.dtramin.lrr(i);`
136			`vdtdatain(i)(DTWIDTH-DCLOCK_BIT) := crami.dcramin.dtramin.lock(i);`
137			`vdtdatain(i)(DTAG_BITS-1 downto 0) := crami.dcramin.dtramin.tag & crami.dcramin.dtramin.valid;`
138			`if (DSETS > 1) and (crami.dcramin.dtramin.flush = '1') then`
139			`vdtdatain(i)(DLINE_SIZE+1 downto DLINE_SIZE) := std_logic_vector(conv_unsigned(i,2));`
140			`end if;`
141			`end loop;`
142
143			`vdtdatain2 := (others => (others => '0'));`
144			`for i in 0 to DSETS-1 loop`
145
146			`vdtdatain2(i)(DTWIDTH-(DLRR_BIT + DCLOCK_BIT)) := dtdataout2(i)(DTWIDTH-(DLRR_BIT+DCLOCK_BIT));`
147			`vdtdatain2(i)(DTWIDTH-DCLOCK_BIT) := dtdataout2(i)(DTWIDTH-DCLOCK_BIT);`
148			`vdtdatain2(i)(DTAG_BITS-1 downto DLINE_SIZE) := crami.dcramin.dtraminsn.tag;`
149			`end loop;`
150			`vdddatain(32 - 1 downto 0) := crami.dcramin.ddramin.data;`
151
152
153			`for i in 0 to ISETS-1 loop`
154			`vitdatain(i) := (others => '0');`
155			`if M_EN then`
156			`vitdatain(i)((ITWIDTH - (ILRR_BIT+ICLOCK_BIT+1)) downto (ITWIDTH - (ILRR_BIT+ICLOCK_BIT+M_CTX_SZ))) := crami.icramin.itramin.ctx;`
157			`end if;`
158			`vitdatain(i)(ITWIDTH-(ILRR_BIT + ICLOCK_BIT)) := crami.icramin.itramin.lrr;`
159			`vitdatain(i)(ITWIDTH-ICLOCK_BIT) := crami.icramin.itramin.lock;`
160			`vitdatain(i)(ITAG_BITS-1 downto 0) := crami.icramin.itramin.tag & crami.icramin.itramin.valid;`
161			`if (ISETS > 1) and (crami.icramin.itramin.flush = '1') then`
162			`vitdatain(i)(ILINE_SIZE+1 downto ILINE_SIZE) := std_logic_vector(conv_unsigned(i,2));`
163			`end if;`
164			`end loop;`
165
166			`itdatain <= vitdatain; iddatain <= viddatain;`
167			`dtdatain <= vdtdatain; dtdatain2 <= vdtdatain2; dddatain <= vdddatain;`
168
169			`end process;`
170
171
172			`itwrite <= crami.icramin.itramin.write;`
173			`idwrite <= crami.icramin.idramin.write;`
174			`itenable <= crami.icramin.itramin.enable;`
175			`idenable <= crami.icramin.idramin.enable;`
176
177			`dtaddr <= crami.dcramin.ddramin.address(DOFFSET_BITS + DLINE_BITS -1 downto DLINE_BITS);`
178			`dtaddr2 <= crami.dcramin.dtraminsn.address;`
179			`ddaddr <= crami.dcramin.ddramin.address;`
180			`dtwrite <= crami.dcramin.dtramin.write;`
181			`dtwrite2 <= crami.dcramin.dtraminsn.write;`
182			`ddwrite <= crami.dcramin.ddramin.write;`
183			`dtenable <= crami.dcramin.dtramin.enable;`
184			`dtenable2 <= crami.dcramin.dtraminsn.enable;`
185			`ddenable <= crami.dcramin.ddramin.enable;`
186
187
188			`it0 : for i in 0 to ISETS-1 generate`
189			`itags0 : syncram`
190			`generic map ( dbits => ITWIDTH, abits => IOFFSET_BITS)`
191			`port map ( itaddr, clk, itdatain(i)(ITWIDTH-1 downto 0), itdataout(i)(ITWIDTH-1 downto 0), itenable, itwrite(i));`
192			`end generate;`
193
194			`dtags0 : if not DSNOOP generate`
195			`dt0 : for i in 0 to DSETS-1 generate`
196			`dtags0 : syncram`
197			`generic map ( dbits => DTWIDTH, abits => DOFFSET_BITS)`
198			`port map ( dtaddr, clk, dtdatain(i)(DTWIDTH-1 downto 0), dtdataout(i)(DTWIDTH-1 downto 0), dtenable, dtwrite(i));`
199			`end generate;`
200			`end generate;`
201
202			`dtags1 : if DSNOOP generate`
203			`dt0 : for i in 0 to DSETS-1 generate`
204			`dtags0 : dpsyncram`
205			`generic map ( dbits => DTWIDTH, abits => DOFFSET_BITS)`
206			`port map ( dtaddr, clk, dtdatain(i)(DTWIDTH-1 downto 0), dtdataout(i)(DTWIDTH-1 downto 0), dtenable, dtwrite(i),`
207			`dtaddr2, dtdatain2(i)(DTWIDTH-1 downto 0), dtdataout2(i)(DTWIDTH-1 downto 0), dtenable2, dtwrite2(i));`
208			`end generate;`
209			`end generate;`
210
211			`id0 : for i in 0 to ISETS-1 generate`
212			`idata0 : syncram`
213			`generic map ( dbits => IDWIDTH, abits => IOFFSET_BITS+ILINE_BITS)`
214			`port map ( idaddr, clk, iddatain, iddataout(i), idenable, idwrite(i));`
215			`end generate;`
216
217			`dd0 : for i in 0 to DSETS-1 generate`
218			`ddata0 : syncram`
219			`generic map ( dbits => DDWIDTH, abits => DOFFSET_BITS+DLINE_BITS)`
220			`port map ( ddaddr, clk, dddatain, dddataout(i), ddenable, ddwrite(i));`
221			`end generate;`
222
223			`ld0 : if LOCAL_RAM generate`
224			`ldata0 : syncram`
225			`generic map ( dbits => 32, abits => LOCAL_RAM_BITS)`
226			`port map ( crami.dcramin.ldramin.address, clk, dddatain, ldataout,`
227			`crami.dcramin.ldramin.enable, crami.dcramin.ldramin.write);`
228			`end generate;`
229
230			`itx : for i in 0 to ISETS-1 generate`
231			`itdataout(i)(ITWIDTH) <= '0';`
232			`cramo.icramout.itramout(i).valid <= itdataout(i)(ILINE_SIZE -1 downto 0);`
233			`cramo.icramout.itramout(i).tag <= itdataout(i)(ITAG_BITS-1 downto ILINE_SIZE);`
234			`cramo.icramout.itramout(i).lrr <= itdataout(i)(ITWIDTH - (ILRR_BIT+ICLOCK_BIT));`
235			`cramo.icramout.itramout(i).lock <= itdataout(i)(ITWIDTH-ICLOCK_BIT);`
236			`cramo.icramout.itramout(i).ctx <= itdataout(i)((ITWIDTH - (ILRR_BIT+ICLOCK_BIT+1)) downto (ITWIDTH - (ILRR_BIT+ICLOCK_BIT+M_CTX_SZ)));`
237			`cramo.icramout.idramout(i).data <= iddataout(i)(31 downto 0);`
238
239			`end generate;`
240
241
242			`itd : for i in 0 to DSETS-1 generate`
243			`dtdataout(i)(DTWIDTH) <= '0';`
244			`dtdataout2(i)(DTWIDTH) <= '0';`
245			`cramo.dcramout.dtramout(i).valid <= dtdataout(i)(DLINE_SIZE -1 downto 0);`
246			`cramo.dcramout.dtramout(i).tag <= dtdataout(i)(DTAG_BITS-1 downto DLINE_SIZE);`
247			`cramo.dcramout.dtramout(i).lrr <= dtdataout(i)(DTWIDTH-(DLRR_BIT+DCLOCK_BIT));`
248			`cramo.dcramout.dtramout(i).lock <= dtdataout(i)(DTWIDTH-DCLOCK_BIT);`
249			`cramo.dcramout.dtramout(i).ctx <= dtdataout(i)((DTWIDTH - (DLRR_BIT+DCLOCK_BIT+1)) downto (DTWIDTH - (DLRR_BIT+DCLOCK_BIT+M_CTX_SZ)));`
250			`cramo.dcramout.dtramoutsn(i).tag <= dtdataout2(i)(DTAG_BITS-1 downto DLINE_SIZE);`
251			`cramo.dcramout.ddramout(i).data <= ldataout when LOCAL_RAM and (crami.dcramin.ldramin.read = '1')`
252			`else dddataout(i)(31 downto 0);`
253
254			`end generate;`
255
256			`end ;`
257