-- https://fpga4u.epfl.ch/wiki/FPGA4U_Description -- The SDRAM is an ISSI IS42S32800B. With 32 bits data bus, validated by SDRAM_DQM<3..0> signals, -- one for each Byte of data bus SDRAM_DQ<31..0>. -- This memory is a synchronous SDRAM, validating address and control signals with the rising edge of SDRAM_CLK, -- while SDRAM_CKE activated ('1'). The organisation is 4 banks selected by SDRAM_BA<1..0>. -- Each bank as 2^12 Row and 2^9 Column selected by SDRAM_AD<11.0>, with 32 bits words -- (SDRAM_DQ<31..0> (2^2 * 2^12 * 2^9 = 4 * 2M x 32 = 8Mx32 = 32MBytes). -- In SOPC Builder, with the SDRAM Controller, select: -- 4 Banks -- 12 Rows addresses lines -- 9 Columns addresses lines library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; entity fpga4u_sdram_controller is port( --Avalon slave interface (pipelined, variable latency) signal clk, reset : in std_logic; signal as_address : in std_logic_vector(22 downto 0); signal as_read, as_write : in std_logic; signal as_byteenable : in std_logic_vector(3 downto 0); signal as_readdata : out std_logic_vector(31 downto 0); signal as_writedata : in std_logic_vector(31 downto 0); signal as_waitrequest : out std_logic; signal as_readdatavalid : out std_logic; --SDRAM interface to FPGA4U SDRAM signal ram_addr : out std_logic_vector(11 downto 0); signal ram_ba : out std_logic_vector(1 downto 0); signal ram_cas_n : out std_logic; signal ram_cke : out std_logic; signal ram_cs_n : out std_logic; signal ram_dq : inout std_logic_vector(31 downto 0); signal ram_dqm : out std_logic_vector(3 downto 0); signal ram_ras_n : out std_logic; signal ram_we_n : out std_logic ); end entity; architecture arch of fpga4u_sdram_controller is --Initialisation signals type init_state_t is (init_reset, init_pre, init_wait_pre, init_ref, init_wait_ref, init_mode, init_wait_mode, init_done); signal init_state : init_state_t := init_reset; signal init_wait_counter : unsigned(15 downto 0); signal init_ref_counter : unsigned(3 downto 0); --Main state machine type state_t is (idle, ref, wait_ref, act, wait_act, read, spin_read, write, spin_write, precharge_all, wait_precharge); signal state : state_t := idle; signal ref_counter : unsigned(10 downto 0); signal ref_req : std_logic; signal wait_counter : unsigned(2 downto 0); --Active transaction signals signal int_address : std_logic_vector(22 downto 0); signal int_readdata : std_logic_vector(31 downto 0); signal int_writedata : std_logic_vector(31 downto 0); signal int_byteenable : std_logic_vector(3 downto 0); signal int_writeop : std_logic; --open bank and row signal open_bank : std_logic_vector(1 downto 0); signal open_row : std_logic_vector(11 downto 0); --readdata ready pipeline signal readdata_ready : std_logic_vector(4 downto 0); signal ram_cmd : std_logic_vector(3 downto 0); begin --State machine to handle SDRAM initialization INITSTATE : process(clk, reset) begin if reset = '1' then init_state <= init_reset; --power up delay init_wait_counter <= to_unsigned(24000,init_wait_counter'length); --number refresh cycles before mode register write init_ref_counter <= to_unsigned(2,init_ref_counter'length); elsif rising_edge(clk) then --count down when not 0 if init_wait_counter /= 0 then init_wait_counter <= init_wait_counter - 1; end if; case init_state is when init_reset => if init_wait_counter = 0 then init_state <= init_pre; end if; --do a precharge when init_pre => init_wait_counter <= to_unsigned(3,init_wait_counter'length); init_state <= init_wait_pre; when init_wait_pre => if init_wait_counter = 0 then init_state <= init_ref; end if; --do a refresh when init_ref => init_wait_counter <= to_unsigned(8,init_wait_counter'length); init_ref_counter <= init_ref_counter - 1; init_state <= init_wait_ref; when init_wait_ref => if init_wait_counter = 0 then if init_ref_counter = 0 then init_state <= init_mode; else init_state <= init_ref; end if; end if; --set the mode register when init_mode => init_wait_counter <= to_unsigned(2,init_wait_counter'length); init_state <= init_wait_mode; when init_wait_mode => if init_wait_counter = 0 then init_state <= init_done; end if; when others => null; end case; end if; end process; --Asynchronous waitrequest to allow one transfer per cycle (critical path) as_waitrequest <= '0' when (state = idle and ref_req = '0' and (as_read = '1' or as_write = '1')) or ((state = read or state = spin_read) and ref_req = '0' and as_read = '1' and as_address(22 downto 11) = open_row and as_address(10 downto 9) = open_bank) or ((state = write or state = spin_write) and ref_req = '0' and as_write = '1' and as_address(22 downto 11) = open_row and as_address(10 downto 9) = open_bank) else '1'; --Main state machine make_state : process(clk, reset) begin if reset = '1' then state <= idle; ref_counter <= (others=>'0'); ref_req <= '1'; --begin with a refresh wait_counter <= (others=>'0'); readdata_ready <= (others=>'0'); elsif rising_edge(clk) then --counters for delays and refresh generation if wait_counter /= 0 then wait_counter <= wait_counter - 1; end if; if ref_counter /= 0 then ref_counter <= ref_counter - 1; else ref_req <= '1'; ref_counter <= to_unsigned(1800,ref_counter'length); end if; --main state machine runs when the initialization is done if init_state = init_done then case state is when idle => if ref_req = '1' then --go do a refresh ref_req <= '0'; state <= ref; elsif as_write = '1' or as_read = '1' then --accept the request and go to open the row int_address <= as_address; int_writedata <= as_writedata; int_byteenable <= as_byteenable; int_writeop <= as_write; state <= act; end if; when ref => wait_counter <= to_unsigned(5,wait_counter'length); state <= wait_ref; when wait_ref => if wait_counter = 0 then state <= idle; end if; when act => --save the open bank and row open_bank <= int_address(10 downto 9); open_row <= int_address(22 downto 11); wait_counter <= to_unsigned(1,wait_counter'length); state <= wait_act; when wait_act => if wait_counter = 0 then if int_writeop = '0' then state <= read; else state <= write; end if; end if; when read => --issue a read command, feed a one in the readdata_ready pipeline, when it exits data is ready for the master as_readdata <= int_readdata; as_readdatavalid <= readdata_ready(4); readdata_ready <= readdata_ready(3 downto 0)&'1'; if ref_req = '0' and as_read = '1' and as_address(22 downto 11) = open_row and as_address(10 downto 9) = open_bank then int_address <= as_address; state <= read; else state <= spin_read; end if; when spin_read => --wait for reads to complete and eventually issue more compatible reads as_readdata <= int_readdata; as_readdatavalid <= readdata_ready(4); readdata_ready <= readdata_ready(3 downto 0)&'0'; if readdata_ready = "00000" and (ref_req = '1' or as_write = '1') then state <= precharge_all; elsif ref_req = '0' and as_read = '1' and as_address(22 downto 11) = open_row and as_address(10 downto 9) = open_bank then int_address <= as_address; state <= read; elsif readdata_ready = "00000" and as_read = '1' then state <= precharge_all; end if; when write => --the same as read, except there is no pipeline as data is presented to the SDRAM on the same cycle as the command wait_counter <= to_unsigned(1,wait_counter'length); if ref_req = '0' and as_write = '1' and as_address(22 downto 11) = open_row and as_address(10 downto 9) = open_bank then int_address <= as_address; int_writedata <= as_writedata; int_byteenable <= as_byteenable; state <= write; else state <= spin_write; end if; when spin_write => --same as for read if wait_counter = 0 and (ref_req = '1' or as_read = '1') then state <= precharge_all; elsif ref_req = '0' and as_write = '1' and as_address(22 downto 11) = open_row and as_address(10 downto 9) = open_bank then int_address <= as_address; int_writedata <= as_writedata; int_byteenable <= as_byteenable; state <= write; elsif wait_counter = 0 and as_write = '1' then state <= precharge_all; end if; when precharge_all => state <= wait_precharge; when wait_precharge => state <= idle; when others=> null; end case; end if; end if; end process; --data from the ram needs to be sampled on the falling edge of the controller clock for proper operation process(clk) begin if falling_edge(clk) then int_readdata <= ram_dq; end if; end process; --process generating the command sequence for the SDRAM ram_cke <= '1'; ram_cs_n <= ram_cmd(3); ram_ras_n <= ram_cmd(2); ram_cas_n <= ram_cmd(1); ram_we_n <= ram_cmd(0); OUTPUTS : process(clk, reset) begin if reset = '1' then ram_addr <= (others=>'0'); ram_cmd <= "1111"; ram_ba <= (others=>'0'); ram_dq <= (others=>'Z'); ram_dqm <= (others=>'1'); elsif rising_edge(clk) then if init_state = init_pre then ram_cmd <= "0010"; --precharge ram_addr <= (10=>'1', others=>'0'); elsif init_state = init_ref then ram_cmd <= "0001"; --refresh elsif init_state = init_mode then ram_cmd <= "0000"; --mode set ram_addr <= "000000110000"; --no burst, three cycles latency elsif init_state = init_done then if state = ref then ram_cmd <= "0001"; --refresh elsif state = act then ram_cmd <= "0011"; --activate ram_addr <= int_address(22 downto 11); ram_ba <= int_address(10 downto 9); elsif state = read then ram_cmd <= "0101"; --read ram_addr <= "000"&int_address(8 downto 0); ram_dqm <= "0000"; elsif state = write then ram_cmd <= "0100"; --write ram_addr <= "000"&int_address(8 downto 0); ram_dq <= int_writedata; ram_dqm <= not int_byteenable; elsif state = precharge_all then ram_cmd <= "0010"; --precharge ram_addr <= "010"&int_address(8 downto 0); ram_dqm <= "1111"; else ram_cmd <= "1111"; --nop ram_dq <= (others=>'Z'); end if; else ram_cmd <= "1111"; --nop end if; end if; end process; end arch;