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SEm-Labos/Libs/Memory/hdl/fifo_bram_rtl.vhd

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4.8 KiB
VHDL
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2024-02-23 13:01:05 +00:00
library Common;
use Common.CommonLib.all;
architecture RTL of FIFO_bram is
subtype register_type is std_ulogic_vector(dataIn'high downto 0);
type memory_type is array (0 to depth-1) of register_type;
signal writeCounter: unsigned(requiredBitNb(depth-1)-1 downto 0);
signal readCounter: unsigned(writeCounter'range);
signal memoryArray: memory_type;
type fifoStateType is (
sEmpty, sFull,
sRead, sWrite, sWriteFirst,
sReadWrite, sWait
);
signal fifoState: fifoStateType;
signal emptyCondition, fullCondition, empty_int: std_ulogic;
begin
------------------------------------------------------------------------------
-- read and write counters
updateWriteCounter: process(reset, clock)
begin
if reset = '1' then
writeCounter <= (others => '0');
elsif rising_edge(clock) then
if (write = '1') and (fullCondition = '0') then
writeCounter <= writeCounter + 1;
end if;
end if;
end process updateWriteCounter;
updateReadCounter: process(reset, clock)
begin
if reset = '1' then
readCounter <= (others => '0');
elsif rising_edge(clock) then
if (read = '1') and (empty_int = '0') then
readCounter <= readCounter + 1;
end if;
end if;
end process updateReadCounter;
------------------------------------------------------------------------------
-- memory access
writeMem: process(clock)
begin
if rising_edge(clock) then
if (write = '1') and (fullCondition = '0') then
memoryArray(to_integer(writeCounter)) <= dataIn;
end if;
end if;
end process writeMem;
readMem: process(reset, clock)
begin
if reset = '1' then
dataOut <= (others => '0');
elsif rising_edge(clock) then
if (read = '0') or (empty_int = '1') then
dataOut <= memoryArray(to_integer(readCounter));
else
dataOut <= memoryArray(to_integer(readCounter+1));
end if;
end if;
end process readMem;
------------------------------------------------------------------------------
-- controls
emptyCondition <= '1' when
( (fifoState = sRead) and (writeCounter = readCounter) ) or
(fifoState = sEmpty)
else '0';
fullCondition <= '1' when
( (fifoState = sWrite) and (writeCounter = readCounter) ) or
(fifoState = sFull)
else '0';
fifoControl: process(reset, clock)
begin
if reset = '1' then
fifoState <= sEmpty;
elsif rising_edge(clock) then
case fifoState is
when sEmpty =>
if write = '1' then
fifoState <= sWriteFirst;
end if;
when sFull =>
if (read = '1') then
fifoState <= sRead;
end if;
when sRead =>
if (read = '1') and (write = '1') then
fifoState <= sReadWrite;
elsif write = '1' then
fifoState <= sWrite;
elsif emptyCondition = '1' then
fifoState <= sEmpty;
elsif read = '1' then
fifoState <= sRead;
else
fifoState <= sWait;
end if;
when sWriteFirst =>
if (read = '1') and (write = '1') then
fifoState <= sReadWrite;
elsif write = '1' then
fifoState <= sWrite;
elsif read = '1' then
fifoState <= sRead;
else
fifoState <= sWait;
end if;
when sWrite =>
if (read = '1') and (write = '1') then
fifoState <= sReadWrite;
elsif read = '1' then
fifoState <= sRead;
elsif fullCondition = '1' then
fifoState <= sFull;
elsif write = '1' then
fifoState <= sWrite;
else
fifoState <= sWait;
end if;
when sReadWrite =>
if (read = '0') and (write = '0') then
fifoState <= sWait;
elsif (read = '1') and (write = '0') then
fifoState <= sRead;
elsif (write = '1') and (read = '0') then
fifoState <= sWrite;
end if;
when sWait =>
if (read = '1') and (write = '1') then
fifoState <= sReadWrite;
elsif read = '1' then
fifoState <= sRead;
elsif write = '1' then
fifoState <= sWrite;
end if;
when others => null;
end case;
end if;
end process fifoControl;
full <= '1' when
(fifoState = sFull) or
(fullCondition = '1')
else '0';
empty_int <= '1' when
(fifoState = sEmpty) or
(fifoState = sWriteFirst) or
( (emptyCondition = '1') and (fifoState = sRead) )
else '0';
empty <= empty_int;
end RTL;