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[/] [plasma/] [trunk/] [vhdl/] [cache.vhd] - Rev 408
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--------------------------------------------------------------------- -- TITLE: Cache Controller -- AUTHOR: Steve Rhoads (rhoadss@yahoo.com) -- DATE CREATED: 12/22/08 -- FILENAME: cache.vhd -- PROJECT: Plasma CPU core -- COPYRIGHT: Software placed into the public domain by the author. -- Software 'as is' without warranty. Author liable for nothing. -- DESCRIPTION: -- Control 4KB unified cache that uses the upper 4KB of the 8KB -- internal RAM. Only lowest 2MB of DDR is cached. -- Only include file for Xilinx FPGAs. --------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_unsigned.all; library UNISIM; use UNISIM.vcomponents.all; use work.mlite_pack.all; entity cache is generic(memory_type : string := "DEFAULT"); port(clk : in std_logic; reset : in std_logic; address_next : in std_logic_vector(31 downto 2); byte_we_next : in std_logic_vector(3 downto 0); cpu_address : in std_logic_vector(31 downto 2); mem_busy : in std_logic; cache_access : out std_logic; --access 4KB cache cache_checking : out std_logic; --checking if cache hit cache_miss : out std_logic); --cache miss end; --cache architecture logic of cache is subtype state_type is std_logic_vector(1 downto 0); constant STATE_IDLE : state_type := "00"; constant STATE_CHECKING : state_type := "01"; constant STATE_MISSED : state_type := "10"; constant STATE_WAITING : state_type := "11"; signal state_reg : state_type; signal state : state_type; signal state_next : state_type; signal cache_address : std_logic_vector(10 downto 0); signal cache_tag_in : std_logic_vector(8 downto 0); signal cache_tag_reg : std_logic_vector(8 downto 0); signal cache_tag_out : std_logic_vector(8 downto 0); signal cache_we : std_logic; begin cache_proc: process(clk, reset, mem_busy, cache_address, state_reg, state, state_next, address_next, byte_we_next, cache_tag_in, --Stage1 cache_tag_reg, cache_tag_out, --Stage2 cpu_address) --Stage3 begin case state_reg is when STATE_IDLE => --cache idle cache_checking <= '0'; cache_miss <= '0'; state <= STATE_IDLE; when STATE_CHECKING => --current read in cached range, check if match cache_checking <= '1'; if cache_tag_out /= cache_tag_reg or cache_tag_out = ONES(8 downto 0) then cache_miss <= '1'; state <= STATE_MISSED; else cache_miss <= '0'; state <= STATE_IDLE; end if; when STATE_MISSED => --current read cache miss cache_checking <= '0'; cache_miss <= '1'; if mem_busy = '1' then state <= STATE_MISSED; else state <= STATE_WAITING; end if; when STATE_WAITING => --waiting for memory access to complete cache_checking <= '0'; cache_miss <= '0'; if mem_busy = '1' then state <= STATE_WAITING; else state <= STATE_IDLE; end if; when others => cache_checking <= '0'; cache_miss <= '0'; state <= STATE_IDLE; end case; --state if state = STATE_IDLE then --check if next access in cached range cache_address <= '0' & address_next(11 downto 2); if address_next(30 downto 21) = "0010000000" then --first 2MB of DDR cache_access <= '1'; if byte_we_next = "0000" then --read cycle cache_we <= '0'; state_next <= STATE_CHECKING; --need to check if match else cache_we <= '1'; --update cache tag state_next <= STATE_WAITING; end if; else cache_access <= '0'; cache_we <= '0'; state_next <= STATE_IDLE; end if; else cache_address <= '0' & cpu_address(11 downto 2); cache_access <= '0'; if state = STATE_MISSED then cache_we <= '1'; --update cache tag else cache_we <= '0'; end if; state_next <= state; end if; if byte_we_next = "0000" or byte_we_next = "1111" then --read or 32-bit write cache_tag_in <= address_next(20 downto 12); else cache_tag_in <= ONES(8 downto 0); --invalid tag end if; if reset = '1' then state_reg <= STATE_IDLE; cache_tag_reg <= ZERO(8 downto 0); elsif rising_edge(clk) then state_reg <= state_next; if state = STATE_IDLE and state_reg /= STATE_MISSED then cache_tag_reg <= cache_tag_in; end if; end if; end process; cache_xilinx: if memory_type = "XILINX_16X" generate begin cache_tag: RAMB16_S9 --Xilinx specific port map ( DO => cache_tag_out(7 downto 0), DOP => cache_tag_out(8 downto 8), ADDR => cache_address, --registered CLK => clk, DI => cache_tag_in(7 downto 0), --registered DIP => cache_tag_in(8 downto 8), EN => '1', SSR => ZERO(0), WE => cache_we); end generate; --cache_xilinx cache_generic: if memory_type /= "XILINX_16X" generate begin cache_tag: process(clk, cache_address, cache_tag_in, cache_we) constant ADDRESS_WIDTH : natural := 10; type storage_array is array(natural range 0 to 2 ** ADDRESS_WIDTH - 1) of std_logic_vector(8 downto 0); variable storage : storage_array; variable index : natural := 0; begin if rising_edge(clk) then index := conv_integer(cache_address(ADDRESS_WIDTH-1 downto 0)); if cache_we = '1' then storage(index) := cache_tag_in; end if; cache_tag_out <= storage(index); end if; end process; --cache_tag end generate; --cache_generic end; --logic
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