FireBee_SVN/vhdl/testbenches/ddr_ram_model.vhd

LIBRARY IEEE;
    USE IEEE.std_logic_1164.ALL;
    USE IEEE.numeric_std.ALL;

LIBRARY work;

PACKAGE ddr_ram_model_pkg IS        
    COMPONENT ddr_ram_model IS
        GENERIC
        (
            VERBOSE         : BOOLEAN := TRUE;          -- define if you want additional debug output

            CLOCK_TICK  : TIME := (1000000 / 132000) * 1 ps;     -- time for one clock tick

            NBANK           : INTEGER := 4;
            ADDRTOP         : INTEGER := 12;
            A10_LESS        : BOOLEAN := TRUE;          -- top column address is less than A10
            B               : INTEGER := 16;            -- number of bit (x16)
            NCOL            : INTEGER := 10;            -- top column address is CA9 (NCOL- 1)
            PAGEDEPTH       : INTEGER := 1024;
            NDM             : INTEGER := 2;
            NDQS            : INTEGER := 2
        );
        PORT
        (
            dqi             : INOUT std_logic_vector (B - 1 DOWNTO 0);
            ba              : IN unsigned (NBANK / 2 - 1 DOWNTO 0);
            ad              : IN std_logic_vector (ADDRTOP DOWNTO 0);
            rasb            : IN std_logic;
            casb            : IN std_logic;
            web             : IN std_logic;
            clk             : IN std_logic;
            clkb            : IN std_logic;
            cke             : IN std_logic;
            csb             : IN std_logic;
            dm              : IN unsigned (NDM - 1 DOWNTO 0);
            dqs             : INOUT std_logic_vector (NDQS - 1 DOWNTO 0);
            qfc             : OUT std_logic
        );
    END COMPONENT;
    
END PACKAGE;

PACKAGE BODY ddr_ram_model_pkg IS
    
END PACKAGE BODY ddr_ram_model_pkg;
---------------------------------------------------------------------------------------------------------------------------------------    

LIBRARY IEEE;
    USE IEEE.std_logic_1164.ALL;
    USE IEEE.numeric_std.ALL;

LIBRARY work;
    USE work.ddr_ram_model_pkg.ALL;
    
ENTITY ddr_ram_model IS
    GENERIC
    (
        VERBOSE         : BOOLEAN := TRUE;          -- define if you want additional debug output

        CLOCK_TICK  : TIME := (1000000 / 132000) * 1 ps;     -- time for one clock tick

        NBANK                   : INTEGER := 4;
        ADDRTOP                 : INTEGER := 12;
        A10_LESS                : BOOLEAN := TRUE;          -- top column address is less than A10
        B                       : INTEGER := 16;            -- number of bit (x16)
        NCOL                    : INTEGER := 10;            -- top column address is CA9 (NCOL - 1)
        PAGEDEPTH               : INTEGER := 1024;
        NDM                     : INTEGER := 2;
        NDQS                    : INTEGER := 2
    );
    PORT
    (
           dqi                  : INOUT std_logic_vector (B - 1 DOWNTO 0);
           ba                   : IN unsigned (NBANK / 2 - 1 DOWNTO 0);
           ad                   : IN std_logic_vector (ADDRTOP DOWNTO 0);
           rasb                 : IN std_logic;
           casb                 : IN std_logic;
           web                  : IN std_logic;
           clk                  : IN std_logic;
           clkb                 : IN std_logic;
           cke                  : IN std_logic;
           csb                  : IN std_logic;
           dm                   : IN unsigned (NDM - 1 DOWNTO 0);
           dqs                  : INOUT std_logic_vector (NDQS - 1 DOWNTO 0);
           qfc                  : OUT std_logic
     );
END ENTITY ddr_ram_model;

ARCHITECTURE rtl OF ddr_ram_model IS
    -- DDR RAM timing constants
    
    CONSTANT TRC                : TIME := 65 ps;            -- row cycle time (min)
    CONSTANT TRFC               : TIME := 115 ps;           -- Refresh Row cycle time (min)
    CONSTANT TRASMIN            : TIME := 45 ps;            -- Row active minimum time
    CONSTANT TRASMAX            : TIME := 120000 ps;        -- Row active maximum time
    CONSTANT TRCD               : TIME := 20 ps;            -- Ras to cas delay (min)
    CONSTANT TRP                : TIME := 20 ps;            -- Row precharge time (min)
    CONSTANT TRRD               : TIME := 15 ps;            -- Row to row delay (min)
    
    CONSTANT TCCD               : TIME := CLOCK_TICK;       -- Col. address to col. address delay: 1 clk
    
    CONSTANT TCKMIN             : TIME := 7.5 ps;           -- Clock minimum cycle time
    CONSTANT TCKMAX             : TIME := 12 ps;            -- Clock maximum cycle time
    CONSTANT TCK15              : TIME := 10 ps;            -- Clock minimum cycle time at cas latency=1.5
    CONSTANT TCK2               : TIME := 10 ps;            -- Clock minimum cycle time at cas latency=2
    CONSTANT TCK25              : TIME := 7.5 ps;           -- Clock minimum cycle time at cas latency=2.5
    CONSTANT TCK3               : TIME := 7.5 ps;           -- Clock minimum cycle time at cas latency=3
    CONSTANT TCHMIN             : TIME := 0.45 ps;          -- Clock high pulse width (min. 0.45 tCK, max: 0.55 tCK)
    CONSTANT TCHMAX             : TIME := 0.55 ps;
    CONSTANT TCLMIN             : TIME := 0.45 ps;          -- Clock low pulse width (min. 0.45 tCK, max: 0.55 tCK)
    CONSTANT TCLMAX             : TIME := 0.55 ps;
    CONSTANT TIS                : TIME := 0.9 ps;           -- input setup time (old Tss)
    CONSTANT TIH                : TIME := 0.9 ps;           -- input hold time (old Tsh)
    CONSTANT TWR                : TIME := 15 ps;            -- write recovery time
    CONSTANT TDS                : TIME := 0.5 ps;           -- Data in & DQM setup time
    CONSTANT TDH                : TIME := 0.5 ps;           -- Data in & DQM hold time
    CONSTANT TDQSH              : TIME := 0.6 ps;           -- DQS-in high level width (min. 0.4 tCK, max. 0.6 tCK)
    CONSTANT TDQSL              : TIME := 0.6 ps;           --
    CONSTANT TDSC               : TIME := 1 ps;             -- DQS-in cycle time tCIC changed following tDSC
    CONSTANT TPDEX              : TIME := 7.5 ps;           -- Power down exit time
    CONSTANT TSREX              : TIME := 200 ps;           -- Self refresh exit time : 200 clk
    CONSTANT THZQ               : TIME := 0.75 ps;          -- Data out active to High-Z (min:-0.75, max: +0.75)
    CONSTANT TDQSCK             : TIME := 0.75 ps;          -- DQS out edge to clock edge
    CONSTANT TAC                : TIME := 0.75 ps;          -- Output data access time from CK/CKB (min: -0.75, max: +0.75)
    CONSTANT TQCSW              : TIME := 3.5 ps;           -- Delay from the clock edge of write command to QFC out on writes (max: 4ns)
    CONSTANT TQCHW              : TIME := 0.5 ps;           -- QFC hold time on writes (min 1.25 ns, max: 0.5 tCK)
    CONSTANT TQCH               : TIME := 0.4 ps;           -- QFC hold time on reads (min 0.4 tCK, max 0.6 tCK)
    CONSTANT TQCS               : TIME := 0.9 ps;           -- QFC setup time on reads (min: 0.9 tCK, max 1.1 tCK)

    CONSTANT K1                 : INTEGER := 1024;
    CONSTANT M1                 : INTEGER := 1048576;
    CONSTANT BYTE               : INTEGER := 8;

    CONSTANT TBITS              : INTEGER := 512 * M1;

    --SIGNAL BITs                 : unsigned (B - 1 DOWNTO 0);
    CONSTANT BIT_C              : INTEGER := NCOL - 1;
    CONSTANT NWORD              : INTEGER := TBITS / B / NBANK;
    CONSTANT BIT_T              : INTEGER := NCOL + ADDRTOP;
    CONSTANT WORD               : INTEGER := NWORD - 1;

    CONSTANT HB                 : INTEGER := B / 2;
    
    CONSTANT PWRUP_TIME         : INTEGER := 0;
    CONSTANT PWUP_CHECK         : std_logic := '1';
    
    CONSTANT INITIAL            : INTEGER := 0;
    CONSTANT HIGH               : INTEGER := 1;
    CONSTANT LOW                : INTEGER := 0;
    
    SIGNAL addr                 : std_logic_vector (NBANK / 2 + ADDRTOP DOWNTO 0);
    
    TYPE mem_array_t IS ARRAY (NATURAL RANGE <>) OF std_logic_vector(B - 1 DOWNTO 0);
    SIGNAL mem_a                : mem_array_t (NWORD - 1 DOWNTO 0);                         -- memory cell array of a bank
    SIGNAL mem_b                : mem_array_t (NWORD - 1 DOWNTO 0);                         -- memory cell array of b bank
    SIGNAL mem_c                : mem_array_t (NWORD - 1 DOWNTO 0);                         -- memory cell array of c bank
    SIGNAL mem_d                : mem_array_t (NWORD - 1 DOWNTO 0);                         -- memory cell array of d bank
    
    SIGNAL t_dqi                : unsigned (B - 1 DOWNTO 0);
    SIGNAL dqsi                 : unsigned (NDQS - 1 DOWNTO 0);
    SIGNAL dqsi_n               : unsigned (NDQS - 1 DOWNTO 0);
    
    SIGNAL dqo                  : unsigned (B - 1 DOWNTO 0);        -- output temp register declaration
    SIGNAL t_tqo                : unsigned (B - 1 DOWNTO 0);
    
    TYPE r_addr_t IS ARRAY (NATURAL RANGE <>) OF unsigned (NBANK - 1 DOWNTO 0);
    SIGNAL r_addr_n             : r_addr_t (ADDRTOP DOWNTO 0);
    SIGNAL r_addr               : unsigned (ADDRTOP DOWNTO 0);
    SIGNAL c_addr               : unsigned (BIT_C DOWNTO 0);
    SIGNAL c_addr_delay         : unsigned (BIT_C DOWNTO 0);
    SIGNAL c_addr_delay_bf      : unsigned (BIT_C DOWNTO 0);
    SIGNAL m_addr               : unsigned (BIT_T DOWNTO 0);        -- merge row and column address
    SIGNAL m1_addr              : unsigned (BIT_T DOWNTO 0);        -- merge row and column address pseudo
    
    TYPE d_reg_t IS ARRAY (NATURAL RANGE <>) OF unsigned (PAGEDEPTH DOWNTO 0);
    SIGNAL dout_reg             : unsigned (B - 1 DOWNTO 0);
    SIGNAL din_reg              : unsigned (B - 1 DOWNTO 0);
    SIGNAL clk_dq               : unsigned (B - 1 DOWNTO 0);
    SIGNAL ptr                  : std_logic;
    SIGNAL zdata                : unsigned(B - 1 DOWNTO 0);
    SIGNAL zbyte                : unsigned(7 DOWNTO 0);
    
    -- we know the phase of external signal by examining the state of its flag
    SIGNAL r_bank_addr          : std_logic;
    SIGNAL c_bank_addr          : unsigned (NBANK / 2 - 1 DOWNTO 0);    -- column bank check flag
    SIGNAL c_bank_addr_delay    : unsigned (NBANK / 2 - 1 DOWNTO 0);    -- column bank check flag 
    SIGNAL c_bank_addr_delay_bf : unsigned (NBANK / 2 - 1 DOWNTO 0);    -- column bank check flag
    SIGNAL prech_reg            : unsigned (NBANK / 2 DOWNTO 0);        -- precharge mode (addr (13 DOWNTO 12) AND (addr(10))
    
    SIGNAL auto_flag            : BOOLEAN_VECTOR (NBANK - 1 DOWNTO 0);
    SIGNAL burst_type           : std_logic;                            -- burst type flag
    SIGNAL auto_flagx           : BOOLEAN;                              -- auto refresh flag
    SIGNAL self_flag            : BOOLEAN;                              -- self refresh flag
    SIGNAL kill_bank            : INTEGER;
    SIGNAL k                    : INTEGER;
    
    SIGNAL precharge_flag       : boolean_vector(NBANK - 1 DOWNTO 0);        -- precharge bank check flag
    SIGNAL autoprech_reg        : unsigned (1 DOWNTO 0);
    SIGNAL pwrup_done           : BOOLEAN;
    SIGNAL first_pre            : BOOLEAN_VECTOR (NBANK - 1 DOWNTO 0);
    
    SIGNAL auto_cnt             : INTEGER;
    SIGNAL i                    : INTEGER;
    
    SIGNAL rfu                  : unsigned (6 DOWNTO 0);
    
    SIGNAL mode                 : unsigned (NBANK - 1 DOWNTO 0);
    SIGNAL prdl                 : unsigned (NBANK - 1 DOWNTO 0);
    SIGNAL ignore_rdl           : unsigned (NBANK - 1 DOWNTO 0);
    
    SIGNAL bl                   : INTEGER;      -- burst_length
    SIGNAL wbl                  : INTEGER;
    
    SIGNAL cl                   : INTEGER;     -- CAS latency
    SIGNAL cl_tmp               : INTEGER;
    SIGNAL cl_org               : INTEGER;
    SIGNAL cl_tmp2              : INTEGER;
    
    SIGNAL write_event          : BOOLEAN;
    SIGNAL autoprecharge_WIRevent : BOOLEAN;
    SIGNAL write_mode_flag      : BOOLEAN;
    SIGNAL dqsi_flag            : BOOLEAN;
    SIGNAL dqsi_flag_u          : BOOLEAN;
    SIGNAL write_start          : BOOLEAN;
    
    SIGNAL tdss_min             : INTEGER;
    SIGNAL tdss_max             : INTEGER;
    
    SIGNAL tshz                 : INTEGER;          -- clk to output in hi-z
    SIGNAL tsac                 : INTEGER;          -- clk to valid output
    
    SIGNAL reautoprecharge      : BOOLEAN;
    
    TYPE event_record_t IS RECORD
        kkk_event                       : BOOLEAN;
        read_event                      : BOOLEAN;
        write_event                     : BOOLEAN;
        write_pre_event                 : BOOLEAN;
        write_mode_event                : BOOLEAN;
        write_mode_del_event            : BOOLEAN;
        write_task_event                : BOOLEAN;
        flush_write_event               : BOOLEAN;
        precharge_event                 : BOOLEAN;
        autoprecharge_event             : BOOLEAN;
        autoprecharge_a_event           : BOOLEAN;
        autoprecharge_b_event           : BOOLEAN;
        autoprecharge_c_event           : BOOLEAN;
        autoprecharge_d_event           : BOOLEAN;
        autoprecharge_write_event       : BOOLEAN;
        autoprecharge_write_a_event     : BOOLEAN;
        autoprecharge_write_b_event     : BOOLEAN;
        autoprecharge_write_c_event     : BOOLEAN;
        autoprecharge_write_d_event     : BOOLEAN;
        autoprecharge_write_int_event   : BOOLEAN;
        autoprecharge_write_int2_event  : BOOLEAN;
        precharge_start_event           : BOOLEAN;
        precharge_start_kill_event      : BOOLEAN;
        autorefresh_event               : BOOLEAN;
        autostart_event                 : BOOLEAN;
        selfrefresh_event               : BOOLEAN;
        selfexit_event                  : BOOLEAN;
        rdl_start_a_event               : BOOLEAN;
        rdl_start_b_event               : BOOLEAN;
        rdl_start_c_event               : BOOLEAN;
        rdl_start_d_event               : BOOLEAN;
    END RECORD;
    
    SIGNAL events                       : event_record_t;
BEGIN
    p_initial : PROCESS
    BEGIN
        FOR i IN 0 TO NDQS - 1 LOOP
            dqs(i) <= '1';
        END LOOP;
        
        FOR i IN 0 TO NBANK - 1 LOOP
            auto_flag(i) <= FALSE;
        END LOOP;
        
        auto_flagx <= FALSE;
        reautoprecharge <= FALSE;
        self_flag <= FALSE;
        events.write_event <= FALSE;
        autoprecharge_WIRevent <= FALSE;
        write_mode_flag <= FALSE;
        pwrup_done <= FALSE;
        dqsi_flag <= FALSE;
        dqsi_flag_u <= FALSE;
        mode <= TO_UNSIGNED(0, mode'LENGTH) OR TO_UNSIGNED(NBANK, 3)(0);
        prdl <= TO_UNSIGNED(0, mode'LENGTH) OR TO_UNSIGNED(NBANK, 3)(0);
        
        FOR i IN 0 TO NBANK - 1 LOOP
            first_pre(i) <= FALSE;
            precharge_flag(i) <= FALSE;
        END LOOP;
        zbyte <= (OTHERS => 'Z');
        
        FOR i IN 0 TO B - 1 LOOP
            zdata(i) <= '1';
        END LOOP;
        
        WAIT;
    END PROCESS p_initial;
    
    p_stupid_data_out : PROCESS
    BEGIN
        WAIT UNTIL rising_edge(clk);
        dqs <= (OTHERS => '1');
    END PROCESS p_stupid_data_out;
    
    p_stupid_data_out2 : PROCESS
    BEGIN
        WAIT UNTIL falling_edge(clkb);
        dqs <= (OTHERS => '0');
    END PROCESS p_stupid_data_out2;
    
    addr <= std_logic_vector(ba) & ad;
    rfu <= unsigned(addr(14 DOWNTO 9)) & unsigned(addr(7 DOWNTO 7)); 
END rtl;