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[/] [layer2/] [trunk/] [vhdl/] [cpu/] [rtl/] [wbm.vhd] - Blame information for rev 4

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--------------------------------------------------------------------------------
-- MIPS� I CPU - Wishbone Master                                              --
--------------------------------------------------------------------------------
--                                                                            --
-- KNOWN BUGS:                                                                --
--                                                                            --
--  o The master cause some severe trouble when communicating with slave      --
--    interfaces that run on a different frequency than the master itself.    --
--       In order to get the DDR to work with a 50 MHz master, I added an     --
--    interface solely running at 50 MHz while the remaining DDR controller   --
--    runs at 25 MHz.                                                         --
--                                                                            --
--------------------------------------------------------------------------------
-- Copyright (C)2011  Mathias H�rtnagl <mathias.hoertnagl@gmail.comt>         --
--                                                                            --
-- This program 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 program 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 program.  If not, see <http://www.gnu.org/licenses/>.      --
--------------------------------------------------------------------------------
library ieee;
use ieee.std_logic_1164.all;
use ieee.numeric_std.all;
 
library work;
use work.iwb.all;
use work.icpu.all;
 
entity wbm is
   port(
      mi  : in  master_in_t;
      mo  : out master_out_t;
   -- Non Wishbone Signals
      ci  : out cpu_in_t;
      co  : in  cpu_out_t;
      irq : in  std_logic_vector(7 downto 0)
   );
end wbm;
 
architecture rtl of wbm is
 
   type state_t is (Init, I0, I1, I2, D0, D1, D2, Cpu);
 
   type regs_t is
   record
      s : state_t;
      i : std_logic_vector(31 downto 0);
      d : std_logic_vector(31 downto 0);
   end record;
 
   constant regs_d : regs_t :=
      regs_t'( Init, (others => '0'), (others => '0') );
 
   signal r, rin : regs_t := regs_d;
begin
 
   ci.clk <= mi.clk;
   ci.rst <= mi.rst;
 
   process(irq, r, co, mi.ack, mi.dat)
 
      variable t2 : std_logic_vector(31 downto 0);
   begin
 
      rin <= r;
 
      t2 := (others => '0');
 
      ci.hld <= '1';
      ci.ins <= (others => '0');       -- AREA: (others => '-');
      ci.dat <= (others => '0');       -- AREA: (others => '-');
      ci.irq <= irq;
 
      mo.adr <= (others => '0');       -- AREA: (others => '-');
      mo.dat <= (others => '0');       -- AREA: (others => '-');
      mo.we  <= '0';
      mo.sel <= (others => '0');
      mo.stb <= '0';
 
      case r.s is
 
         when Init =>
            rin.s <= I0;
 
         -----------------------------------------------------------------------
         -- Instruction                                                       --
         -----------------------------------------------------------------------        
         -- First stage of instruction fetch. Wait for memory device to be done
         -- loading desired data.
         when I0 =>
            mo.adr <= co.iadr;
            mo.sel <= "1111";
            mo.stb <= '1';
            if mi.ack = '1' then
               --rin.i <= mi.dat;
               rin.s <= I1;
            end if;
 
         -- Latch fetched instruction.
         -- If co.sel is not null, there is data to be processed from the memory
         -- stage. Else directly execute instruction.
         when I1 =>
            mo.adr <= co.iadr;
            mo.sel <= "1111";
            mo.stb <= '1';
            rin.i  <= mi.dat;
            rin.s  <= I2;
 
         when I2 =>
            if mi.ack = '0' then
               if co.sel = x"0" then
                  rin.s <= Cpu;
               else
                  rin.s <= D0;
               end if;
            end if;
 
         -----------------------------------------------------------------------
         -- Data                                                              --
         -----------------------------------------------------------------------            
         -- Set data to be written to propper location on the 32bit bus, 
         -- according to co.sel.
         -- Wait until I/O device is ready.
         when D0 =>
            mo.adr <= co.dadr;
            case co.sel is
               when "0001" => mo.dat(7 downto 0)   <= co.dat(7 downto 0);
               when "0010" => mo.dat(15 downto 8)  <= co.dat(7 downto 0);
               when "0100" => mo.dat(23 downto 16) <= co.dat(7 downto 0);
               when "1000" => mo.dat(31 downto 24) <= co.dat(7 downto 0);
               when "0011" => mo.dat(15 downto 0)  <= co.dat(15 downto 0);
               when "1100" => mo.dat(31 downto 16) <= co.dat(15 downto 0);
               when others => mo.dat               <= co.dat;
            end case;
            mo.we  <= co.we;
            mo.sel <= co.sel;
            mo.stb <= '1';
            if mi.ack = '1' then
               rin.s <= D1;
            end if;
 
         -- Finish write cycle or latch read data.
         when D1 =>
            mo.adr <= co.dadr;
 
            -- Read.
            case co.sel is
               when "0001" => t2(7 downto 0)  := mi.dat(7 downto 0);
               when "0010" => t2(7 downto 0)  := mi.dat(15 downto 8);
               when "0100" => t2(7 downto 0)  := mi.dat(23 downto 16);
               when "1000" => t2(7 downto 0)  := mi.dat(31 downto 24);
               when "0011" => t2(15 downto 0) := mi.dat(15 downto 0);
               when "1100" => t2(15 downto 0) := mi.dat(31 downto 16);
               when others => t2              := mi.dat;
            end case;
 
            -- Write.
            case co.sel is
               when "0001" => mo.dat(7 downto 0)   <= co.dat(7 downto 0);
               when "0010" => mo.dat(15 downto 8)  <= co.dat(7 downto 0);
               when "0100" => mo.dat(23 downto 16) <= co.dat(7 downto 0);
               when "1000" => mo.dat(31 downto 24) <= co.dat(7 downto 0);
               when "0011" => mo.dat(15 downto 0)  <= co.dat(15 downto 0);
               when "1100" => mo.dat(31 downto 16) <= co.dat(15 downto 0);
               when others => mo.dat               <= co.dat;
            end case;
 
            mo.we  <= co.we;
            mo.sel <= co.sel;
            mo.stb <= '1';
            rin.d  <= t2;
            rin.s  <= D2;
 
         when D2 =>
            if mi.ack = '0' then
               rin.s <= Cpu;
            end if;
 
         -----------------------------------------------------------------------
         -- Run CPU                                                           --
         -----------------------------------------------------------------------             
         -- Enable CPU and run it for one cycle, then at least fetch the next 
         -- instruction.
         when Cpu =>
            ci.hld <= '0';
            ci.ins <= r.i;
            ci.dat <= r.d;
            rin.s  <= I0;
      end case;
   end process;
 
   reg : process(mi.clk)
   begin
      if rising_edge(mi.clk) then
         if mi.rst = '1' then r <= regs_d; else r <= rin; end if;
      end if;
   end process;
end architecture;

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[/] [layer2/] [trunk/] [vhdl/] [cpu/] [rtl/] [wbm.vhd] - Blame information for rev 4

Line No.	Rev	Author	Line
1	2	idiolatrie	`--------------------------------------------------------------------------------`
2			`-- MIPS� I CPU - Wishbone Master --`
3			`--------------------------------------------------------------------------------`
4			`-- --`
5			`-- KNOWN BUGS: --`
6			`-- --`
7			`-- o The master cause some severe trouble when communicating with slave --`
8			`-- interfaces that run on a different frequency than the master itself. --`
9			`-- In order to get the DDR to work with a 50 MHz master, I added an --`
10			`-- interface solely running at 50 MHz while the remaining DDR controller --`
11			`-- runs at 25 MHz. --`
12			`-- --`
13			`--------------------------------------------------------------------------------`
14			`-- Copyright (C)2011 Mathias H�rtnagl <mathias.hoertnagl@gmail.comt> --`
15			`-- --`
16			`-- This program is free software: you can redistribute it and/or modify --`
17			`-- it under the terms of the GNU General Public License as published by --`
18			`-- the Free Software Foundation, either version 3 of the License, or --`
19			`-- (at your option) any later version. --`
20			`-- --`
21			`-- This program is distributed in the hope that it will be useful, --`
22			`-- but WITHOUT ANY WARRANTY; without even the implied warranty of --`
23			`-- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the --`
24			`-- GNU General Public License for more details. --`
25			`-- --`
26			`-- You should have received a copy of the GNU General Public License --`
27			`-- along with this program. If not, see <http://www.gnu.org/licenses/>. --`
28			`--------------------------------------------------------------------------------`
29			`library ieee;`
30			`use ieee.std_logic_1164.all;`
31			`use ieee.numeric_std.all;`
32
33			`library work;`
34			`use work.iwb.all;`
35			`use work.icpu.all;`
36
37			`entity wbm is`
38			`port(`
39			`mi : in master_in_t;`
40			`mo : out master_out_t;`
41			`-- Non Wishbone Signals`
42			`ci : out cpu_in_t;`
43			`co : in cpu_out_t;`
44			`irq : in std_logic_vector(7 downto 0)`
45			`);`
46			`end wbm;`
47
48			`architecture rtl of wbm is`
49
50			`type state_t is (Init, I0, I1, I2, D0, D1, D2, Cpu);`
51
52			`type regs_t is`
53			`record`
54			`s : state_t;`
55			`i : std_logic_vector(31 downto 0);`
56			`d : std_logic_vector(31 downto 0);`
57			`end record;`
58
59			`constant regs_d : regs_t :=`
60			`regs_t'( Init, (others => '0'), (others => '0') );`
61
62			`signal r, rin : regs_t := regs_d;`
63			`begin`
64
65			`ci.clk <= mi.clk;`
66			`ci.rst <= mi.rst;`
67
68			`process(irq, r, co, mi.ack, mi.dat)`
69
70			`variable t2 : std_logic_vector(31 downto 0);`
71			`begin`
72
73			`rin <= r;`
74
75			`t2 := (others => '0');`
76
77			`ci.hld <= '1';`
78			`ci.ins <= (others => '0'); -- AREA: (others => '-');`
79			`ci.dat <= (others => '0'); -- AREA: (others => '-');`
80			`ci.irq <= irq;`
81
82			`mo.adr <= (others => '0'); -- AREA: (others => '-');`
83			`mo.dat <= (others => '0'); -- AREA: (others => '-');`
84			`mo.we <= '0';`
85			`mo.sel <= (others => '0');`
86			`mo.stb <= '0';`
87
88			`case r.s is`
89
90			`when Init =>`
91			`rin.s <= I0;`
92
93			`-----------------------------------------------------------------------`
94			`-- Instruction --`
95			`-----------------------------------------------------------------------`
96			`-- First stage of instruction fetch. Wait for memory device to be done`
97			`-- loading desired data.`
98			`when I0 =>`
99			`mo.adr <= co.iadr;`
100			`mo.sel <= "1111";`
101			`mo.stb <= '1';`
102			`if mi.ack = '1' then`
103			`--rin.i <= mi.dat;`
104			`rin.s <= I1;`
105			`end if;`
106
107			`-- Latch fetched instruction.`
108			`-- If co.sel is not null, there is data to be processed from the memory`
109			`-- stage. Else directly execute instruction.`
110			`when I1 =>`
111			`mo.adr <= co.iadr;`
112			`mo.sel <= "1111";`
113			`mo.stb <= '1';`
114			`rin.i <= mi.dat;`
115			`rin.s <= I2;`
116
117			`when I2 =>`
118			`if mi.ack = '0' then`
119			`if co.sel = x"0" then`
120			`rin.s <= Cpu;`
121			`else`
122			`rin.s <= D0;`
123			`end if;`
124			`end if;`
125
126			`-----------------------------------------------------------------------`
127			`-- Data --`
128			`-----------------------------------------------------------------------`
129			`-- Set data to be written to propper location on the 32bit bus,`
130			`-- according to co.sel.`
131			`-- Wait until I/O device is ready.`
132			`when D0 =>`
133			`mo.adr <= co.dadr;`
134			`case co.sel is`
135			`when "0001" => mo.dat(7 downto 0) <= co.dat(7 downto 0);`
136			`when "0010" => mo.dat(15 downto 8) <= co.dat(7 downto 0);`
137			`when "0100" => mo.dat(23 downto 16) <= co.dat(7 downto 0);`
138			`when "1000" => mo.dat(31 downto 24) <= co.dat(7 downto 0);`
139			`when "0011" => mo.dat(15 downto 0) <= co.dat(15 downto 0);`
140			`when "1100" => mo.dat(31 downto 16) <= co.dat(15 downto 0);`
141			`when others => mo.dat <= co.dat;`
142			`end case;`
143			`mo.we <= co.we;`
144			`mo.sel <= co.sel;`
145			`mo.stb <= '1';`
146			`if mi.ack = '1' then`
147			`rin.s <= D1;`
148			`end if;`
149
150			`-- Finish write cycle or latch read data.`
151			`when D1 =>`
152			`mo.adr <= co.dadr;`
153
154			`-- Read.`
155			`case co.sel is`
156			`when "0001" => t2(7 downto 0) := mi.dat(7 downto 0);`
157			`when "0010" => t2(7 downto 0) := mi.dat(15 downto 8);`
158			`when "0100" => t2(7 downto 0) := mi.dat(23 downto 16);`
159			`when "1000" => t2(7 downto 0) := mi.dat(31 downto 24);`
160			`when "0011" => t2(15 downto 0) := mi.dat(15 downto 0);`
161			`when "1100" => t2(15 downto 0) := mi.dat(31 downto 16);`
162			`when others => t2 := mi.dat;`
163			`end case;`
164
165			`-- Write.`
166			`case co.sel is`
167			`when "0001" => mo.dat(7 downto 0) <= co.dat(7 downto 0);`
168			`when "0010" => mo.dat(15 downto 8) <= co.dat(7 downto 0);`
169			`when "0100" => mo.dat(23 downto 16) <= co.dat(7 downto 0);`
170			`when "1000" => mo.dat(31 downto 24) <= co.dat(7 downto 0);`
171			`when "0011" => mo.dat(15 downto 0) <= co.dat(15 downto 0);`
172			`when "1100" => mo.dat(31 downto 16) <= co.dat(15 downto 0);`
173			`when others => mo.dat <= co.dat;`
174			`end case;`
175
176			`mo.we <= co.we;`
177			`mo.sel <= co.sel;`
178			`mo.stb <= '1';`
179			`rin.d <= t2;`
180			`rin.s <= D2;`
181
182			`when D2 =>`
183			`if mi.ack = '0' then`
184			`rin.s <= Cpu;`
185			`end if;`
186
187			`-----------------------------------------------------------------------`
188			`-- Run CPU --`
189			`-----------------------------------------------------------------------`
190			`-- Enable CPU and run it for one cycle, then at least fetch the next`
191			`-- instruction.`
192			`when Cpu =>`
193			`ci.hld <= '0';`
194			`ci.ins <= r.i;`
195			`ci.dat <= r.d;`
196			`rin.s <= I0;`
197			`end case;`
198			`end process;`
199
200			`reg : process(mi.clk)`
201			`begin`
202			`if rising_edge(mi.clk) then`
203			`if mi.rst = '1' then r <= regs_d; else r <= rin; end if;`
204			`end if;`
205			`end process;`
206			`end architecture;`