给个参考给你,好像比你编的要好点
library IEEE;
use IEEE.Std_logic_1164.all;
entity FIFOMXN is
generic(m, n : Positive := 8); --m is fifo depth, n is fifo width
port(RESET, WRREQ, RDREQ, CLOCK : in Std_logic;
DATAIN : in Std_logic_vector((n-1) downto 0);
DATAOUT : out Std_logic_vector((n-1) downto 0);
FULL, EMPTY : inout Std_logic);
end FIFOMXN;
architecture V2 of FIFOMXN is
type Fifo_array is array(0 to (m-1)) of Bit_vector((n-1) downto 0);
signal Fifo_memory : Fifo_array;
signal Wraddr, Rdaddr, Offset : Natural range 0 to (m-1);
signal Rdpulse, Wrpulse, Q1, Q2, Q3, Q4 : Std_logic;
signal Databuffer : Bit_vector((n-1) downto 0);
begin
--pulse synchronisers for WRREQ and RDREQ
--modified for Synplify to a process
sync_ffs : process
begin
wait until rising_edge(CLOCK);
Q1 <= WRREQ;
Q2 <= Q1;
Q3 <= RDREQ;
Q4 <= Q3;
end process;
--concurrent logic to generate pulses
Wrpulse <= Q2 and not(Q1);
Rdpulse <= Q4 and not(Q3);
Fifo_read : process
begin
wait until rising_edge(CLOCK);
if RESET = '1' then
Rdaddr <= 0;
Databuffer <= (others => '0');
elsif (Rdpulse = '1' and EMPTY = '0') then
Databuffer <= Fifo_memory(Rdaddr);
Rdaddr <= (Rdaddr + 1) mod m;
end if;
end process;
Fifo_write : process
begin
wait until rising_edge(CLOCK);
if RESET = '1' then
Wraddr <= 0;
elsif (Wrpulse = '1' and FULL = '0') then
Fifo_memory(Wraddr) <= To_Bitvector(DATAIN);
Wraddr <= (Wraddr + 1) mod m;
end if;
end process;
Offset <= (Wraddr - Rdaddr) when (Wraddr > Rdaddr)
else (m - (Rdaddr - Wraddr)) when (Rdaddr > Wraddr)
else 0;
EMPTY <= '1' when (Offset = 0) else '0';
FULL <= '1' when (Offset = (m-1)) else '0';
DATAOUT <= To_Stdlogicvector(Databuffer) when RDREQ = '0'
else (others => 'Z');
end V2;
|
