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-- -- Small Synchronous FIFO -- library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_unsigned.all; use ieee.std_logic_arith.all; use ieee.std_logic_misc.all; library UNISIM; use UNISIM.vcomponents.all; entity wrapper_sync_fifo is generic ( width : natural := 32); port ( clk : in std_logic; rst : in std_logic; wadv : in std_logic; wdata : in std_logic_vector(width-1 downto 0); wnfull : out std_logic; wfull : out std_logic; radv : in std_logic; rdata : out std_logic_vector(width-1 downto 0); rdw_out : out std_logic_vector(width-1 downto 0); rempty : out std_logic; rnempty : out std_logic ); end wrapper_sync_fifo; architecture rtl of wrapper_sync_fifo is component RAM16X1D port ( DPO : out std_logic; SPO : out std_logic; A0 : in std_logic; A1 : in std_logic; A2 : in std_logic; A3 : in std_logic; D : in std_logic; DPRA0 : in std_logic; DPRA1 : in std_logic; DPRA2 : in std_logic; DPRA3 : in std_logic; WCLK : in std_logic; WE : in std_logic); end component; signal rdw, wdw : std_logic_vector(width-1 downto 0); signal radv_q, wadv_q, empty, lempty : std_logic; signal full_r, empty_x, nempty : std_logic; signal waddr, raddr, raddr_p1, count : std_logic_vector(3 downto 0); begin update_addr : process (clk, rst) begin if rst = '1' then waddr <= (others => '0'); raddr <= (others => '0'); raddr_p1 <= "0001"; count <= (others => '0'); elsif clk'event and clk = '1' then if radv_q = '1' then raddr <= raddr_p1; raddr_p1 <= raddr_p1+1; end if; if wadv_q = '1' then waddr <= waddr+1; end if; if radv_q = '1' and wadv_q = '0' then count <= count -1; else if wadv_q = '1' and radv_q = '0' then count <= count+1; end if; end if; end if; end process update_addr; empty <= '1' when count = "0000" else '0'; nempty <= '1' when count = "0001" else '0'; full_r <= '1' when count = "1111" else '0'; wnfull <= '1' when count(3 downto 2) = "11" else '0'; radv_q <= radv and not empty; wadv_q <= wadv and not full_r; wfull <= full_r; rempty <= empty; rnempty <= nempty; r_op : process (clk, rst) begin if rst = '1' then rdata <= (others => '0'); lempty <= '1'; empty_x <= '1'; elsif clk'event and clk = '1' then if radv = '1' then rdata <= rdw; end if; lempty <= empty; empty_x <= nempty and radv; end if; end process r_op; gen_DPRAM : for i in 0 to width-1 generate ram_i : RAM16X1D port map ( DPO => rdw(i), A0 => waddr(0), A1 => waddr(1), A2 => waddr(2), A3 => waddr(3), D => wdata(i), DPRA0 => raddr(0), DPRA1 => raddr(1), DPRA2 => raddr(2), DPRA3 => raddr(3), WCLK => clk, WE => wadv_q); end generate gen_DPRAM; rdw_out <= rdw; end rtl; -- -- plxdssm.vhd - PLX local bus direct slave state machine -- -- Modules defined: -- -- plxdssm PLX local bus direct slave state machine -- -- This state machine is designed to respond to direct slave transfers or -- programmed DMA transfers, NOT demand mode DMA transfers. -- -- One cycle of address decoding is permitted. -- library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_unsigned.all; use ieee.std_logic_arith.all; use ieee.std_logic_misc.all; entity plxdssm is port( clk : in std_logic; -- Local bus clock rst : in std_logic; -- Asynchronous reset, should reduce to FPGA global reset sr : in std_logic; -- Synchronous reset (should never be asserted mid-burst) qlads : in std_logic; -- LADS# signal qualified by address, FHOLDA and/or other decoding lblast : in std_logic; -- Local bus LBLAST# signal, active high lwrite : in std_logic; -- Local bus LWRITE signal, active high ld_oe : out std_logic; -- Output enable for local bus data pins lready : out std_logic; -- To local bus LREADY# signal, active high lready_oe : out std_logic; -- Enable for local bus LREADY# signal lbterm : out std_logic; -- To local bus LBTERM# signal, active high lbterm_oe : out std_logic; -- Enable for local bus LBTERM# signal, active high transfer : out std_logic; -- Data transfer on this clock edge decode : out std_logic; -- Application should do further address decoding write : out std_logic; -- 'lwrite' latched on 'qlads' ready : in std_logic; -- Apply pulse when ready stop : in std_logic); -- Pulse to terminate burst end plxdssm; architecture rtl of plxdssm is type state_type is (s_idle, s_decode, s_wait, s_xfer); signal state, n_state : state_type; signal i_transfer, n_transfer : std_logic; signal i_lready, n_lready : std_logic; signal i_lready_oe, n_lready_oe : std_logic; signal i_lbterm, n_lbterm : std_logic; signal i_decode, n_decode : std_logic; signal i_ld_oe, n_ld_oe : std_logic; signal i_write, n_write : std_logic; signal stopping, n_stopping : std_logic; begin transfer <= i_transfer; lready <= i_lready; lready_oe <= i_lready_oe; lbterm <= i_lbterm; lbterm_oe <= i_lready_oe; decode <= i_decode; ld_oe <= i_ld_oe; write <= i_write; state_transition : process(clk, rst) begin if rst = '1' then state <= s_idle; i_transfer <= '0'; i_lready <= '0'; i_lready_oe <= '0'; i_lbterm <= '0'; i_decode <= '0'; i_ld_oe <= '0'; i_write <= '0'; stopping <= '0'; elsif clk'event and clk = '1' then if sr = '1' then state <= s_idle; i_transfer <= '0'; i_lready <= '0'; i_lready_oe <= '0'; i_lbterm <= '0'; i_decode <= '0'; i_ld_oe <= '0'; i_write <= '0'; stopping <= '0'; else state <= n_state; i_transfer <= n_transfer; i_lready <= n_lready; i_lready_oe <= n_lready_oe; i_lbterm <= n_lbterm; i_decode <= n_decode; i_ld_oe <= n_ld_oe; i_write <= n_write; stopping <= n_stopping; end if; end if; end process state_transition; next_state : process( state, lblast, qlads, i_lbterm, lwrite, ready, stop, stopping, i_write) begin case state is when s_idle => n_transfer <= '0'; n_lready <= '0'; n_lready_oe <= '0'; n_lbterm <= '0'; n_ld_oe <= '0'; n_stopping <= '0'; if qlads = '1' then n_state <= s_decode; n_decode <= '1'; n_write <= lwrite; else n_state <= s_idle; n_decode <= '0'; n_write <= i_write; end if; when s_decode => n_decode <= '0'; n_ld_oe <= not i_write; n_lready_oe <= '1'; n_write <= i_write; if ready = '1' then n_state <= s_xfer; n_lready <= '1'; n_lbterm <= stop; n_transfer <= '1'; n_stopping <= '0'; else n_state <= s_wait; n_lready <= '0'; n_lbterm <= '0'; n_transfer <= '0'; n_stopping <= stop; end if; when s_wait => n_decode <= '0'; n_ld_oe <= not i_write; n_lready_oe <= '1'; n_write <= i_write; if ready = '1' then n_state <= s_xfer; n_lready <= '1'; n_lbterm <= stop or stopping; n_transfer <= '1'; n_stopping <= '0'; else n_state <= s_wait; n_lready <= '0'; n_lbterm <= '0'; n_transfer <= '0'; n_stopping <= stop or stopping; end if; when s_xfer => n_decode <= '0'; n_lready_oe <= '1'; n_stopping <= '0'; n_write <= i_write; if lblast = '1' or i_lbterm = '1' then n_state <= s_idle; n_lready <= '0'; n_lbterm <= '0'; n_transfer <= '0'; n_ld_oe <= '0'; else n_state <= s_xfer; n_lready <= '1'; n_lbterm <= stop; n_transfer <= '1'; n_ld_oe <= not i_write; end if; end case; end process next_state; end rtl; -- -- 4 bit gray counter -- library ieee; use ieee.std_logic_1164.all; entity gray4 is generic ( initial_state : std_logic_vector(4 downto 0) := "00000"); port ( clk : in std_logic; rst : in std_logic; adv : in std_logic; count : out std_logic_vector(3 downto 0)); end gray4; architecture rtl of gray4 is signal x, next_x : std_logic_vector(3 downto 0); signal dummy, next_dummy : std_logic; begin count <= x; clk_proc : process (clk, rst) begin if rst = '1' then x <= initial_state(4 downto 1); dummy <= initial_state(0); elsif clk'event and clk = '1' then x <= next_x; dummy <= next_dummy; end if; end process clk_proc; next_p : process (x, dummy, adv) begin if adv = '0' then next_x <= x; next_dummy <= dummy; else next_dummy <= not dummy; next_x(0) <= not dummy xor x(0); next_x(1) <= (dummy and x(0)) xor x(1); next_x(2) <= (dummy and x(1) and not x(0)) xor x(2); next_x(3) <= (dummy and not x(1) and not x(0)) xor x(3); end if; end process next_p; end rtl; -- -- Small Asynchronous FIFO -- library ieee; use ieee.std_logic_1164.all; -- synthesis translate_off library UNISIM; use UNISIM.all; -- synthesis translate_on entity async_fifo1 is generic ( width : natural := 32); port ( wclk : in std_logic; rst : in std_logic; wadv : in std_logic; wdata : in std_logic_vector(width-1 downto 0); wnfull : out std_logic; wfull : out std_logic; rclk : in std_logic; radv : in std_logic; rdata : out std_logic_vector(width-1 downto 0); rdw_out : out std_logic_vector(width-1 downto 0); rempty : out std_logic; rnempty : out std_logic ); end async_fifo1; architecture rtl of async_fifo1 is component async_bram_fifo port ( din : in std_logic_vector(31 downto 0); rd_clk : in std_logic; rd_en : in std_logic; rst : in std_logic; wr_clk : in std_logic; wr_en : in std_logic; dout : out std_logic_vector(31 downto 0); empty : out std_logic; full : out std_logic; prog_empty : out std_logic; prog_full : out std_logic); end component; component async_bram_fifo64 port ( din : in std_logic_vector(63 downto 0); rd_clk : in std_logic; rd_en : in std_logic; rst : in std_logic; wr_clk : in std_logic; wr_en : in std_logic; dout : out std_logic_vector(63 downto 0); empty : out std_logic; full : out std_logic; prog_empty : out std_logic; prog_full : out std_logic); end component; signal dinl, doutl : std_logic_vector(31 downto 0); signal dinw, doutw : std_logic_vector(63 downto 0); signal rdw_out_i : std_logic_vector(width-1 downto 0); signal remptyl, remptyh : std_logic; begin rdw_out <= rdw_out_i; reg_oip : process (rclk, rst) begin -- process reg_oip if rst = '1' then -- asynchronous reset (active low) rdata <= (others => '0'); elsif rclk'event and rclk = '1' then -- rising clock edge if radv = '1' then rdata <= rdw_out_i; end if; end if; end process reg_oip; gen_1bram : if width < 33 generate dinl(width-1 downto 0) <= wdata; rdw_out_i <= doutl(width-1 downto 0); abf0 : async_bram_fifo port map ( din => dinl, rd_clk => rclk, rd_en => radv, rst => rst, wr_clk => wclk, wr_en => wadv, dout => doutl, empty => rempty, full => wfull, prog_empty => rnempty, prog_full => wnfull); end generate gen_1bram; gen_2bram : if width > 32 generate dinw(width-1 downto 0) <= wdata; rdw_out_i <= doutw(width-1 downto 0); abf0 : async_bram_fifo64 port map ( din => dinw, rd_clk => rclk, rd_en => radv, rst => rst, wr_clk => wclk, wr_en => wadv, dout => doutw, empty => rempty, full => wfull, prog_empty => rnempty, prog_full => wnfull); end generate gen_2bram; end rtl; library IEEE; use IEEE.std_logic_1164.all; use IEEE.numeric_std.all; use ieee.std_logic_unsigned.all; use ieee.std_logic_arith.all; use ieee.std_logic_misc.all; entity xlreqgrantmanager_ad is port (hw_req : in std_logic; sw_req : out std_logic; hw_grant : out std_logic; sw_grant : in std_logic; ram_active : in std_logic; clk : in std_logic); end xlreqgrantmanager_ad; architecture structural of xlreqgrantmanager_ad is signal hw_req_int : std_logic; signal hr_reg1 : std_logic; signal hr_reg1_en : std_logic; signal hr_reg2 : std_logic; signal sw_req_int : std_logic; signal sw_grant_int : std_logic; signal hw_grant_int : std_logic; signal hwg_reg : std_logic_vector(31 downto 0); signal hw_grant_pipe : std_logic; begin sw_grant_int <= sw_grant; sw_req <= sw_req_int; hr_reg1_en <= not(hr_reg2); process (clk, hw_req) begin if (hw_req = '0') then hr_reg1 <= '0'; elsif (clk'event and clk = '1') then if (hr_reg1_en = '1') then hr_reg1 <= '1'; end if; end if; end process; process (clk) begin if (clk'event and clk = '1') then hr_reg2 <= hr_reg1; end if; end process; hw_req_int <= hw_req and hr_reg1; process (clk, hw_req_int) begin if (hw_req_int = '0') then sw_req_int <= '0'; elsif (rising_edge(clk)) then if (sw_grant_int = '0') then sw_req_int <= '1'; end if; end if; end process; process (clk, hw_req_int) begin if (hw_req_int = '0') then hw_grant_int <= '0'; elsif (rising_edge(clk)) then if (sw_req_int = '1' and sw_grant_int = '1') then hw_grant_int <= '1'; end if; end if; end process; process (clk) begin -- process if clk'event and clk = '1' then -- rising clock edge if ram_active = '0' then hw_grant <= hw_grant_int; end if; end if; end process; end architecture structural; library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_unsigned.all; use ieee.std_logic_arith.all; use ieee.std_logic_misc.all; library UNISIM; use UNISIM.vcomponents.all; library work; use work.common_interface.all; entity commonif is port( lclk : in std_logic; clk200_p : in std_logic; clk200_n : in std_logic; adcclk : in std_logic; lreseto_l : in std_logic; lwrite : in std_logic; lads_l : in std_logic; lblast_l : in std_logic; lbterm_o : out std_logic; lbterm_oe : out std_logic; lad_i : in std_logic_vector(63 downto 0); lad_o : out std_logic_vector(63 downto 0); lad_oe : out std_logic; lreadyi_o : out std_logic; lreadyi_oe : out std_logic; lbe_l : in std_logic_vector(7 downto 0); fholda : in std_logic; finti_l : out std_logic; -- DDRII Memory Banks DDR0_RAS_N : out std_logic; DDR0_CAS_N : out std_logic; DDR0_WE_N : out std_logic; DDR0_ODT : out std_logic; DDR0_CKE : out std_logic; DDR0_CS_N : out std_logic; DDR0_DQ : inout std_logic_vector(31 downto 0); DDR0_DQS : inout std_logic_vector(3 downto 0); DDR0_DQS_N : inout std_logic_vector(3 downto 0); DDR0_DM : out std_logic_vector(3 downto 0); DDR0_CK : out std_logic_vector(1 downto 0); DDR0_CK_N : out std_logic_vector(1 downto 0); DDR0_BA : out std_logic_vector(2 downto 0); DDR0_A : out std_logic_vector(12 downto 0); DDR1_RAS_N : out std_logic; DDR1_CAS_N : out std_logic; DDR1_WE_N : out std_logic; DDR1_ODT : out std_logic; DDR1_CKE : out std_logic; DDR1_CS_N : out std_logic; DDR1_DQ : inout std_logic_vector(31 downto 0); DDR1_DQS : inout std_logic_vector(3 downto 0); DDR1_DQS_N : inout std_logic_vector(3 downto 0); DDR1_DM : out std_logic_vector(3 downto 0); DDR1_CK : out std_logic_vector(1 downto 0); DDR1_CK_N : out std_logic_vector(1 downto 0); DDR1_BA : out std_logic_vector(2 downto 0); DDR1_A : out std_logic_vector(12 downto 0); DDR2_RAS_N : out std_logic; DDR2_CAS_N : out std_logic; DDR2_WE_N : out std_logic; DDR2_ODT : out std_logic; DDR2_CKE : out std_logic; DDR2_CS_N : out std_logic; DDR2_DQ : inout std_logic_vector(31 downto 0); DDR2_DQS : inout std_logic_vector(3 downto 0); DDR2_DQS_N : inout std_logic_vector(3 downto 0); DDR2_DM : out std_logic_vector(3 downto 0); DDR2_CK : out std_logic_vector(1 downto 0); DDR2_CK_N : out std_logic_vector(1 downto 0); DDR2_BA : out std_logic_vector(2 downto 0); DDR2_A : out std_logic_vector(12 downto 0); DDR3_RAS_N : out std_logic; DDR3_CAS_N : out std_logic; DDR3_WE_N : out std_logic; DDR3_ODT : out std_logic; DDR3_CKE : out std_logic; DDR3_CS_N : out std_logic; DDR3_DQ : inout std_logic_vector(31 downto 0); DDR3_DQS : inout std_logic_vector(3 downto 0); DDR3_DQS_N : inout std_logic_vector(3 downto 0); DDR3_DM : out std_logic_vector(3 downto 0); DDR3_CK : out std_logic_vector(1 downto 0); DDR3_CK_N : out std_logic_vector(1 downto 0); DDR3_BA : out std_logic_vector(2 downto 0); DDR3_A : out std_logic_vector(12 downto 0); debug : out std_Logic_vector(63 downto 0); -- Interface to Synth synth_cntrl : out std_logic_vector(15 downto 0); synth_strb : out std_logic_vector(3 downto 0); synth_status : in std_logic_vector(31 downto 0); synth_rst : out std_logic; -- Interface to User Top Level clk : out std_logic; rst : out std_logic; system_in : out std_logic_vector(system_width-1 downto 0); system_out : in std_logic_vector(system_width-1 downto 0)); end commonif; architecture mixed of commonif is constant number_of_aurorae : integer := 0; constant number_of_dram : integer := 4; signal rst_i : std_logic; signal rst_i_bg : std_logic; signal blast_i : std_logic; signal ads_i : std_logic; signal qlads : std_logic; signal write_i : std_logic; signal ds_xfer : std_logic; signal ds_decode : std_logic; signal ld_o : std_logic_vector(63 downto 0); signal ld_i : std_logic_vector(63 downto 0); signal ld_oe : std_logic; signal la_i : std_logic_vector(23 downto 2); signal be_i : std_logic_vector(7 downto 0); signal la_q : std_logic_vector(23 downto 2); signal write_q : std_logic; signal addr_reg : std_logic_vector(31 downto 0); signal oe_user : std_logic; signal oe_imem : std_logic; signal imem_reg : std_logic_vector(31 downto 0); signal bram_out, bram_out1 : std_logic_vector(bram_width-1 downto 0); signal zeros : std_logic_vector(3 downto 0); signal ds_write : std_logic; signal logic0 : std_logic; signal logic1 : std_logic; signal burst_active : std_logic; signal ds_ready : std_logic; signal ds_ready_rd : std_logic; signal ds_ready_wr : std_logic; signal ds_stop : std_logic; signal lclk0 : std_logic; signal clk0, mclk0 : std_logic; signal user_reg : std_logic_vector(31 downto 0); component plxdssm port( clk : in std_logic; rst : in std_logic; sr : in std_logic; qlads : in std_logic; lblast : in std_logic; lwrite : in std_logic; ld_oe : out std_logic; lready : out std_logic; lready_oe : out std_logic; lbterm : out std_logic; lbterm_oe : out std_logic; transfer : out std_logic; decode : out std_logic; write : out std_logic; ready : in std_logic; stop : in std_logic); end component; component dram2if generic ( chipscope : boolean := false); port ( lclk : in std_logic; rst : in std_logic; sysclk : in std_logic; -- SYSGEN Port Interface dram_out : in extmem_type; dram_in : out extmem_type; -- Local Bus Interface ld_i : in std_logic_vector(63 downto 0); ld_o : out std_logic_vector(63 downto 0); la_q : in std_logic_vector(27 downto 0); lwrite : in std_logic; lblast : in std_logic; lbterm : in std_logic; ds_xfer : in std_logic; lads : in std_logic; ready : out std_logic; stop : out std_logic; lb_request : out std_logic; lb_grant : in std_logic; lb_rskip : in std_logic_vector(4 downto 0); lb_roffset : in std_logic_vector(4 downto 0); status : out std_logic_vector(31 downto 0); debug : out std_Logic_vector(63 downto 0); -- Connections to DDRII Clocking and Infrastructure modules clk_0 : in std_logic; clk_90 : in std_logic; CNTL_CLK_ID1 : in std_logic; CNTL_CLK_ID2 : in std_logic; CNTL_CLK_ID3 : in std_logic; CNTL_CLK_ID4 : in std_logic; sys_rst : in std_logic; sys_rst90 : in std_logic; SYS_RST_ID : in std_logic; idelay_ctrl_rdy : in std_logic; online : out std_Logic; -- RAM Interface DDR2_RAS_N : out std_logic; DDR2_CAS_N : out std_logic; DDR2_WE_N : out std_logic; DDR2_ODT : out std_logic; DDR2_CKE : out std_logic; DDR2_CS_N : out std_logic; DDR2_DQ : inout std_logic_vector(31 downto 0); DDR2_DQS : inout std_logic_vector(3 downto 0); DDR2_DQS_N : inout std_logic_vector(3 downto 0); DDR2_DM : out std_logic_vector(3 downto 0); DDR2_CK : out std_logic_vector(1 downto 0); DDR2_CK_N : out std_logic_vector(1 downto 0); DDR2_BA : out std_logic_vector(2 downto 0); DDR2_A : out std_logic_vector(12 downto 0) ); end component; component mem_interface_infrastructure_DirectClk port ( SYS_CLK : in std_logic; CLK200 : in std_logic; SYS_RESET_INn : in std_logic; CLK : out std_logic; CLK90 : out std_logic; CLK_ID1 : out std_logic; CLK_ID2 : out std_logic; CLK_ID3 : out std_logic; CLK_ID4 : out std_logic; idelay_ctrl_rdy : out std_logic; LOCKED : out std_logic_vector(1 downto 0); sys_rst : out std_logic; sys_rst_90 : out std_logic; sys_rst_id : out std_logic ); end component; component ddrii_if_idelay_ctrl port ( CLK200 : in std_logic; RESET : in std_logic; RDY_STATUS : out std_logic ); end component; signal mem_reg : std_logic_vector(3 downto 0); signal mem_reg_decode : std_logic_vector(5 downto 0); signal mem_status : std_logic_vector(7 downto 0); signal ext_mem : std_logic; signal oe_mem : std_logic; signal qlads_mem, ds_xfer_mem : std_logic_vector(5 downto 0); signal mem_addr : std_logic_vector(21 downto 0); signal mem_addr_ddr : std_logic_vector(27 downto 0); signal mem_out, mem_out0, mem_out1, mem_out2, mem_out3, mem_out4, mem_out5 : std_logic_vector(63 downto 0); signal ds_ready_mem, ready0, ready1, ready2, ready3, ready4, ready5 : std_logic; signal mem_gnt, mem_gnt_trig, mem_gnt_auto : std_logic_vector(7 downto 0); signal clk180, mclk, mclkb : std_logic; signal refclk : std_logic; signal refclk_fb : std_logic; signal clk0b : std_logic; signal clk_i, lclk_i : std_logic; signal dram0_stop, dram1_stop, dram2_stop, dram3_stop : std_logic; signal locked : std_logic_vector(3 downto 0); signal ld_reg : std_logic_vector(31 downto 0); signal oe_reg : std_logic; signal interrupt : std_logic; signal dcm_rst1, dcm_rst2_1, dcm_rst2_2, dcm_rst2_3, dcm_rst2_0 : std_logic; signal dcm_rst_count1 : std_logic_vector(8 downto 0); signal dcm_rst_count2 : std_logic_vector(8 downto 0); signal ld_i_mem : std_logic_vector(31 downto 0); signal addr_i : std_logic_vector(24 downto 0); signal dram0_in, dram0_out : extmem_type; signal dram1_in, dram1_out : extmem_type; signal dram2_in, dram2_out : extmem_type; signal dram3_in, dram3_out : extmem_type; signal ctrl_bus_ivec : std_logic_vector(ctrl_bus_width-1 downto 0); signal status_bus_ivec : std_logic_vector(status_bus_width-1 downto 0); signal irq_bus_ivec : std_logic_vector(interrupt_bus_width-1 downto 0); signal bram_bus_ivec : std_logic_vector(bram_bus_width-1 downto 0); signal locallinks_ivec : std_logic_vector(4*locallink_type_width-1 downto 0); signal extrams_ivec : std_logic_vector(6*extmem_type_width-1 downto 0); signal ctrl_bus_ovec : std_logic_vector(ctrl_bus_width-1 downto 0); signal status_bus_ovec : std_logic_vector(status_bus_width-1 downto 0); signal irq_bus_ovec : std_logic_vector(interrupt_bus_width-1 downto 0); signal bram_bus_ovec : std_logic_vector(bram_bus_width-1 downto 0); signal locallinks_ovec : std_logic_vector(4*locallink_type_width-1 downto 0); signal extrams_ovec : std_logic_vector(6*extmem_type_width-1 downto 0); signal lclk_dummy : std_logic; signal ctrl_bus_in : ctrl_bus_type; signal status_bus_in, status_bus_out : status_bus_type; signal irq_bus_in, irq_bus_out : interrupt_bus_type; signal bram_bus_in, bram_bus_out : bram_bus_type; -- DDR2 Infrasturcture signal idelay_ctrl_rdy : std_logic; signal sys_rst0,sys_rst1,sys_rst2,sys_rst3 : std_logic; signal sys_rst90_0, sys_rst90_1, sys_rst90_2, sys_rst90_3 : std_logic; signal sys_rst_i : std_logic; signal sys_rst90_i : std_logic; signal sys_rst_ref_clk_1 : std_logic; signal clk_0, clk_90, clk_200 : std_logic; signal clkdiv_0, clkdiv_90, clkdiv_mux0, clkdiv_mux1 : std_logic; signal sys_clk,sys_clk_i,ref_clk200_in,clk200_bufg_out,ref_clk200 : std_logic; signal ddr2_CLK_ID1 : std_logic; signal ddr2_CLK_ID2 : std_logic; signal ddr2_CLK_ID3 : std_logic; signal ddr2_CLK_ID4 : std_logic; signal sys_rst_id : std_logic; signal usrclk_i, usrclk2, usrclk_2xi : std_logic; signal usrclk : std_logic; signal mem_rst : std_logic; signal mem_rst_n : std_logic; signal mem_rst_count : std_logic_vector(3 downto 0); signal lb_rskip_reg,lb_roffset_reg : std_logic_vector(4 downto 0); signal mem_online : std_logic_vector(5 downto 0); signal reset_reg : std_Logic_vector(31 downto 0); signal bram_bus_out_flush : std_logic; signal ds_xfer_reg : std_logic; signal bram_bus_qv_reg : std_logic; signal ld32_reg : std_logic_vector(31 downto 0); signal lbterm : std_logic; signal mem_overflow0 : std_logic_vector(31 downto 0); signal mem_overflow1 : std_logic_vector(31 downto 0); signal mem_overflow2 : std_logic_vector(31 downto 0); signal mem_overflow3 : std_logic_vector(31 downto 0); signal mem_overflow_reg0 : std_logic_vector(31 downto 0); signal mem_overflow_reg1 : std_logic_vector(31 downto 0); signal mem_overflow_reg2 : std_logic_vector(31 downto 0); signal mem_overflow_reg3 : std_logic_vector(31 downto 0); -- Force Register Duplication to be used for LA_Q attribute max_fanout : integer; attribute max_fanout of la_q : signal is 16; begin -- Split output system signals and convert data types split0 : split_system_signal( system => system_out, lclk => lclk_dummy, ctrl_bus => ctrl_bus_ovec, status_bus => status_bus_ovec, irq_bus => irq_bus_ovec, bram_bus => bram_bus_ovec, locallinks => locallinks_ovec, extrams => extrams_ovec); status_bus_out <= slv_to_status_bus(status_bus_ovec); irq_bus_out <= slv_to_irq_bus(irq_bus_ovec); bram_bus_out <= slv_to_bram_bus(bram_bus_ovec); dram0_out <= slv_to_extmem_type(extrams_ovec(extmem_type_width-1 downto 0)); dram1_out <= slv_to_extmem_type(extrams_ovec(2*extmem_type_width-1 downto extmem_type_width)); dram2_out <= slv_to_extmem_type(extrams_ovec(3*extmem_type_width-1 downto 2*extmem_type_width)); dram3_out <= slv_to_extmem_type(extrams_ovec(4*extmem_type_width-1 downto 3*extmem_type_width)); -- Merge signals into system inputs merge0 : build_system_signal ( system => system_in, lclk => lclk0, ctrl_bus => ctrl_bus_ivec, status_bus => status_bus_ivec, irq_bus => irq_bus_ivec, bram_bus => bram_bus_ivec, locallinks => locallinks_ivec, extrams => extrams_ivec); ctrl_bus_ivec <= ctrl_bus_to_slv(ctrl_bus_in); status_bus_ivec <= status_bus_to_slv(status_bus_in); irq_bus_ivec <= irq_bus_to_slv(irq_bus_in); bram_bus_ivec <= bram_bus_to_slv(bram_bus_in); extrams_ivec <= CONV_STD_LOGIC_VECTOR(0, extmem_type_width*2) & extmem_type_to_slv(dram3_in) & extmem_type_to_slv(dram2_in) & extmem_type_to_slv(dram1_in) & extmem_type_to_slv(dram0_in); locallinks_ivec <= (others => '0'); logic0 <= '0'; logic1 <= '1'; -- -- Convert the inputs to active high. -- rst_i <= not lreseto_l; rst <= rst_i; blast_i <= not lblast_l; ads_i <= not lads_l; write_i <= lwrite; la_i <= lad_i(23 downto 2); ld_i <= lad_i; lad_o <= ld_o; lad_oe <= ld_oe; be_i <= not lbe_l; clk <= SYS_CLK; lclk_bufg : BUFG port map ( I => lclk_i, O => lclk0); dcm0 : DCM generic map ( clkfx_multiply => 3, clkfx_divide => 1) port map ( clkin => lclk, clkfb => lclk0, dssen => '0', psincdec => '0', psen => '0', psclk => '0', rst => rst_i, locked => locked(0), clk0 => lclk_i, clkfx => mclk, clkfx180 => mclkb); mclk0_bufg : BUFG port map ( I => mclk, O => clk0); clk_i <= SYS_CLK; -- Generating Reset for DDR Memory Controllers -- DCM 2 now removed from design dcm_reset_block2 : process (lclk0, rst_i) begin -- process dcm_reset_block2 if rst_i = '1' then dcm_rst2_0 <= '1'; dcm_rst2_1 <= '1'; dcm_rst2_2 <= '1'; dcm_rst2_3 <= '1'; dcm_rst_count2 <= (others => '1'); mem_rst <= '0'; mem_rst_count <= (others => '1'); elsif lclk0'event and lclk0 = '1' then -- rising clock edge dcm_rst2_0 <= OR_reduce(dcm_rst_count2); dcm_rst2_1 <= OR_reduce(dcm_rst_count2); dcm_rst2_2 <= OR_reduce(dcm_rst_count2); dcm_rst2_3 <= OR_reduce(dcm_rst_count2); if locked(0) = '0' or reset_reg(0) = '1' then dcm_rst_count2 <= (others => '1'); elsif OR_reduce(dcm_rst_count2) = '1' then dcm_rst_count2 <= dcm_rst_count2-1; end if; mem_rst <= not OR_reduce(mem_rst_count); if locked(0) = '0' or reset_reg(1) = '1' then mem_rst_count <= (others => '1'); elsif OR_reduce(mem_rst_count) = '1' then mem_rst_count <= mem_rst_count-1; end if; end if; end process dcm_reset_block2; -- -- Decode the address of the FPGA which is the space when LA[23] is 0 -- qlads <= ads_i and not la_i(23) and not fholda; -- -- Latch the local bus address on the 'lads_l' pulse. -- latch_addr : process(rst_i, lclk0) begin if rst_i = '1' then la_q <= (others => '0'); burst_active <= '0'; ds_ready_rd <= '0'; bram_bus_qv_reg <= '0'; bram_bus_out_flush <= '0'; ds_xfer_reg <= '0'; elsif lclk0'event and lclk0 = '1' then if ads_i = '1' then la_q <= la_i; elsif ds_xfer = '1' or burst_active = '1' then --or (la_q(21) = '1' and ds_decode = '1' and lwrite = '0') la_q(20 downto 2) <= la_q(20 downto 2)+2; end if; if ds_decode = '1' and la_q(21) = '1' and lwrite = '0' then burst_active <= '1'; elsif blast_i = '1' or ds_stop = '1' or (la_q(21) = '0') then burst_active <= '0'; end if; ds_ready_rd <= (bram_bus_out.qv and not ext_mem and not bram_bus_out_flush) or (not la_q(21) and not burst_active and not ads_i); bram_bus_qv_reg <= bram_bus_out.qv; ds_xfer_reg <= ds_xfer; if ds_xfer = '0' and ds_xfer_reg = '1' and bram_bus_out.qv = '1' then bram_bus_out_flush <= '1'; elsif bram_bus_qv_reg = '1' and bram_bus_out.qv = '0' then bram_bus_out_flush <= '0'; end if; end if; end process; ds_ready_wr <= ds_write and ds_decode and (not (la_q(21) and ext_mem)); ds_ready <= ds_ready_rd or ds_ready_wr or ds_ready_mem; ds_stop <= dram0_stop or dram1_stop or dram2_stop or dram3_stop or not la_q(21); -- -- If the current cycle is a write, update the register -- update_reg : process(lclk0, rst_i) variable i : integer; begin if rst_i = '1' then addr_reg <= (others => '0'); irq_bus_in.ier <= (others => '0'); irq_bus_in.isr <= (others => '0'); mem_gnt_trig <= (others => '0'); mem_gnt_auto <= (others => '1'); mem_reg <= (others => '0'); imem_reg <= (others => '0'); mem_reg_decode <= (others => '0'); lb_rskip_reg <= "00001"; lb_roffset_reg <= (others => '0'); reset_reg <= (others => '0'); synth_cntrl <= (others => '0'); synth_strb <= (others => '0'); synth_rst <= '0'; elsif lclk0'event and lclk0 = '1' then reset_reg <= (others => '0'); if ds_xfer = '1' and ds_write = '1' then if la_q(11) = '0' and la_q(21) = '0' then if la_q(7 downto 3) = "00000" then imem_reg <= ld_i(31 downto 0); end if; if la_q(7 downto 3) = "00001" then reset_reg <= ld_i(31 downto 0); end if; if la_q(7 downto 3) = "00010" then addr_reg <= ld_i(31 downto 0); end if; if la_q(7 downto 3) = "00011" then mem_reg <= ld_i(3 downto 0); end if; if la_q(7 downto 3) = "00110" then lb_rskip_reg <= ld_i(4 downto 0); end if; if la_q(7 downto 3) = "00111" then lb_roffset_reg <= ld_i(4 downto 0); end if; if la_q(7 downto 3) = "00100" then irq_bus_in.ier <= ld_i(reg_width-1 downto 0); end if; if la_q(7 downto 3) = "00101" then irq_bus_in.isr <= ld_i(reg_width-1 downto 0); end if; if la_q(7 downto 3) = "01000" then mem_gnt_trig(0) <= ld_i(0); mem_gnt_auto(0) <= ld_i(1); end if; if la_q(7 downto 3) = "01001" then mem_gnt_trig(1) <= ld_i(0); mem_gnt_auto(1) <= ld_i(1); end if; if la_q(7 downto 3) = "01010" then mem_gnt_trig(2) <= ld_i(0); mem_gnt_auto(2) <= ld_i(1); end if; if la_q(7 downto 3) = "01011" then mem_gnt_trig(3) <= ld_i(0); mem_gnt_auto(3) <= ld_i(1); end if; if la_q(7 downto 3) = "01100" then mem_gnt_trig(4) <= ld_i(0); mem_gnt_auto(4) <= ld_i(1); end if; if la_q(7 downto 3) = "01101" then mem_gnt_trig(5) <= ld_i(0); mem_gnt_auto(5) <= ld_i(1); end if; if la_q(7 downto 3) = "10000" then synth_cntrl <= ld_i(15 downto 0); end if; if la_q(7 downto 3) = "10001" then synth_strb <= ld_i(3 downto 0); end if; if la_q(7 downto 3) = "10010" then synth_rst <= ld_i(0); end if; end if; end if; if mem_reg(3) = '1' then for i in 0 to 5 loop if mem_reg(2 downto 0) = CONV_STD_LOGIC_VECTOR(i, 3) then mem_reg_decode(i) <= '1'; else mem_reg_decode(i) <= '0'; end if; end loop; -- i else for i in 0 to 5 loop mem_reg_decode(i) <= '0'; end loop; end if; end if; end process update_reg; ext_mem <= mem_reg(3); -- -- Generate the 'oe_reg*' signals, for enabling registers onto -- the internal data bus. -- generate_oe_reg : process(rst_i, lclk0) begin if rst_i = '1' then oe_user <= '0'; oe_mem <= '0'; oe_imem <= '0'; oe_reg <= '0'; ld_reg <= (others => '0'); interrupt <= '0'; mem_overflow_reg0 <= (others => '0'); mem_overflow_reg1 <= (others => '0'); mem_overflow_reg2 <= (others => '0'); mem_overflow_reg3 <= (others => '0'); elsif lclk0'event and lclk0 = '1' then interrupt <= (OR_reduce(irq_bus_out.isr)); mem_overflow_reg0 <= mem_overflow0; mem_overflow_reg1 <= mem_overflow1; mem_overflow_reg2 <= mem_overflow2; mem_overflow_reg3 <= mem_overflow3; if ds_xfer = '1' and blast_i = '1' then oe_user <= '0'; oe_mem <= '0'; oe_imem <= '0'; oe_reg <= '0'; else if ds_decode = '1' and ds_write = '0' then if la_q(11) = '0' and la_q(21) = '0' then oe_reg <= '1'; if la_q(7 downto 3) = "00000" then ld_reg <= imem_reg; end if; if la_q(7 downto 3) = "00010" then ld_reg <= addr_reg; end if; if la_q(7 downto 3) = "00011" then ld_reg <= X"00" & mem_status & mem_gnt & "0000" & mem_reg; end if; if la_q(7 downto 3) = "00001" then ld_reg <= EXT(mem_online & locked, 32); end if; if la_q(7 downto 3) = "00100" then ld_reg <= irq_bus_in.ier; end if; if la_q(7 downto 3) = "00101" then ld_reg <= irq_bus_out.isr; end if; if la_q(7 downto 3) = "00110" then ld_reg <= EXT(lb_rskip_reg,32); end if; if la_q(7 downto 3) = "00111" then ld_reg <= EXT(lb_roffset_reg,32); end if; if la_q(7 downto 3) = "01000" then ld_reg <= mem_overflow_reg0; end if; if la_q(7 downto 3) = "01001" then ld_reg <= mem_overflow_reg1; end if; if la_q(7 downto 3) = "01010" then ld_reg <= mem_overflow_reg2; end if; if la_q(7 downto 3) = "01011" then ld_reg <= mem_overflow_reg3; end if; if la_q(7 downto 3) = "10000" then ld_reg <= synth_status; end if; else oe_reg <= '0'; end if; oe_user <= la_q(11) and not la_q(21); oe_imem <= la_q(21) and not ext_mem; oe_mem <= la_q(21) and ext_mem; end if; end if; user_reg <= status_bus_out.data; end if; end process generate_oe_reg; finti_l <= not interrupt; ld_o(63 downto 32) <= bram_out(63 downto 32) when oe_imem = '1' else mem_out(63 downto 32); ld_o(31 downto 0) <= ld_reg when oe_reg = '1' else user_reg when oe_user = '1' else bram_out(31 downto 0) when oe_imem = '1' else mem_out(31 downto 0); dssm : plxdssm port map( clk => lclk0, rst => rst_i, sr => logic0, qlads => qlads, lblast => blast_i, lwrite => lwrite, ld_oe => ld_oe, lready => lreadyi_o, lready_oe => lreadyi_oe, lbterm => lbterm, lbterm_oe => lbterm_oe, transfer => ds_xfer, decode => ds_decode, write => ds_write, ready => ds_ready, stop => ds_stop); lbterm_o <= lbterm; gen_addr : process (la_q, addr_reg) begin -- process gen_addr if la_q(21) = '0' then addr_i <= EXT(la_q(10 downto 2), 25); else addr_i <= addr_reg(24 downto 19) & la_q(20 downto 2); end if; end process gen_addr; -- User Application Control registers user_ctrl : process (lclk0, rst_i) begin -- process user_ctrl if rst_i = '1' then -- asynchronous reset (active low) ctrl_bus_in.data <= (others => '0'); ctrl_bus_in.addr <= (others => '0'); ctrl_bus_in.wstb <= '0'; elsif lclk0'event and lclk0 = '1' then -- rising clock edge ctrl_bus_in.data <= ld_i(reg_width-1 downto 0); ctrl_bus_in.addr <= la_q(reg_addr_width+2 downto 3); ctrl_bus_in.wstb <= ds_xfer and ds_write and la_q(11) and not la_q(21); end if; end process user_ctrl; -- User Application Status registers status_bus_in.addr <= la_q(reg_addr_width+2 downto 3); -- User Application BRAM bram_bus_in.data <= ld_i(bram_width-1 downto 0) when be_i(3) = '1' else ld_i(bram_width-1 downto 32) & ld32_reg; bram_bus_in.addr <= la_q(bram_addr_width+2 downto 3); bram_bus_in.id <= imem_reg(bram_id_width-1 downto 0); bram_bus_in.wstb <= ds_xfer and ds_write and la_q(21) and not ext_mem and be_i(7); bram_bus_in.rstb <= burst_active and la_q(21) and not ext_mem; bram_bus_in.qv <= '0'; process (lclk0) begin if lclk0'event and lclk0 = '1' then bram_out1 <= bram_bus_out.q; bram_out <= bram_out1; if ds_xfer = '1' and ds_write = '1' and be_i(3) = '1' then ld32_reg <= ld_i(31 downto 0); end if; end if; end process; mux_ram_banks : process (lclk0, rst_i) begin -- process mux_ram_banks if rst_i = '1' then mem_out <= (others => '0'); ds_ready_mem <= '0'; elsif lclk0'event and lclk0 = '1' then -- rising clock edge case mem_reg(2 downto 0) is when "000" => if (ready0 = '1' and ds_ready_mem = '0') or ds_xfer = '1' then mem_out <= mem_out0; end if; ds_ready_mem <= ready0; when "001" => if (ready1 = '1' and ds_ready_mem = '0') or ds_xfer = '1' then mem_out <= mem_out1; end if; ds_ready_mem <= ready1; when "010" => if (ready2 = '1' and ds_ready_mem = '0') or ds_xfer = '1' then mem_out <= mem_out2; end if; ds_ready_mem <= ready2; when "011" => if (ready3 = '1' and ds_ready_mem = '0') or ds_xfer = '1' then mem_out <= mem_out3; end if; ds_ready_mem <= ready3; when others => mem_out <= (others => '0'); ds_ready_mem <= '1'; end case; end if; end process mux_ram_banks; -- -- SRAM Interfaces -- gen_qlads_mem : for i in 0 to 5 generate ds_xfer_mem(i) <= ds_xfer and la_q(21) and mem_reg_decode(i); qlads_mem(i) <= qlads and la_i(21) and mem_reg_decode(i); end generate gen_qlads_mem; mem_addr <= addr_reg(22 downto 19) & la_i(20 downto 3); mem_addr_ddr <= addr_reg(28 downto 19) & la_i(20 downto 3); mem_gnt <= ((mem_gnt_auto and mem_status) or mem_gnt_trig) and not EXT(mem_reg_decode,8); -- -- DRAM Interface -- gen_dram0 : if number_of_dram > 0 generate dramif0 : dram2if -- generic map ( -- chipscope => true) port map ( lclk => lclk0, rst => dcm_rst2_0, sysclk => clk_i, dram_out => dram0_out, dram_in => dram0_in, ld_i => ld_i, ld_o => mem_out0, la_q => mem_addr_ddr, lwrite => lwrite, lblast => blast_i, lbterm => lbterm, ds_xfer => ds_xfer_mem(0), lads => qlads_mem(0), ready => ready0, stop => dram0_stop, lb_request => mem_status(0), lb_grant => mem_gnt(0), lb_rskip => lb_rskip_reg, lb_roffset => lb_roffset_reg, status => mem_overflow0, debug => debug, clk_0 => clk_0, clk_90 => clk_90, CNTL_CLK_ID1 => ddr2_CLK_ID1, CNTL_CLK_ID2 => ddr2_CLK_ID2, CNTL_CLK_ID3 => ddr2_CLK_ID3, CNTL_CLK_ID4 => ddr2_CLK_ID4, sys_rst => sys_rst0, sys_rst90 => sys_rst90_0, SYS_RST_ID => SYS_RST_ID, idelay_ctrl_rdy => idelay_ctrl_rdy, online => mem_online(0), DDR2_RAS_N => DDR0_RAS_N, DDR2_CAS_N => DDR0_CAS_N, DDR2_WE_N => DDR0_WE_N, DDR2_ODT => DDR0_ODT, DDR2_CKE => DDR0_CKE, DDR2_CS_N => DDR0_CS_N, DDR2_DQ => DDR0_DQ, DDR2_DQS => DDR0_DQS, DDR2_DQS_N => DDR0_DQS_N, DDR2_DM => DDR0_DM, DDR2_CK => DDR0_CK, DDR2_CK_N => DDR0_CK_N, DDR2_BA => DDR0_BA, DDR2_A => DDR0_A); end generate gen_dram0; gen_not_dram0 : if number_of_dram < 1 generate -- dram0_in <= slv_to_extmem_type(CONV_STD_LOGIC_VECTOR(0, extmem_type_width)); mem_out4 <= (others => '0'); ready4 <= '1'; dram1_stop <= '0'; mem_status(4) <= '0'; end generate gen_not_dram0; gen_dram1 : if number_of_dram > 1 generate dramif1 : dram2if -- generic map ( -- chipscope => true) port map ( lclk => lclk0, rst => dcm_rst2_1, sysclk => clk_i, dram_out => dram1_out, dram_in => dram1_in, ld_i => ld_i, ld_o => mem_out1, la_q => mem_addr_ddr, lwrite => lwrite, lblast => blast_i, lbterm => lbterm, ds_xfer => ds_xfer_mem(1), lads => qlads_mem(1), ready => ready1, stop => dram1_stop, lb_request => mem_status(1), lb_grant => mem_gnt(1), lb_rskip => lb_rskip_reg, lb_roffset => lb_roffset_reg, status => mem_overflow1, debug => open, clk_0 => clk_0, clk_90 => clk_90, CNTL_CLK_ID1 => ddr2_CLK_ID1, CNTL_CLK_ID2 => ddr2_CLK_ID2, CNTL_CLK_ID3 => ddr2_CLK_ID3, CNTL_CLK_ID4 => ddr2_CLK_ID4, sys_rst => sys_rst1, sys_rst90 => sys_rst90_1, SYS_RST_ID => SYS_RST_ID, idelay_ctrl_rdy => idelay_ctrl_rdy, online => mem_online(1), DDR2_RAS_N => DDR1_RAS_N, DDR2_CAS_N => DDR1_CAS_N, DDR2_WE_N => DDR1_WE_N, DDR2_ODT => DDR1_ODT, DDR2_CKE => DDR1_CKE, DDR2_CS_N => DDR1_CS_N, DDR2_DQ => DDR1_DQ, DDR2_DQS => DDR1_DQS, DDR2_DQS_N => DDR1_DQS_N, DDR2_DM => DDR1_DM, DDR2_CK => DDR1_CK, DDR2_CK_N => DDR1_CK_N, DDR2_BA => DDR1_BA, DDR2_A => DDR1_A); end generate gen_dram1; gen_not_dram1 : if number_of_dram < 2 generate -- dram1_in <= slv_to_extmem_type(CONV_STD_LOGIC_VECTOR(0, extmem_type_width)); mem_out1 <= (others => '0'); ready1 <= '1'; dram1_stop <= '0'; mem_status(1) <= '0'; end generate gen_not_dram1; gen_dram2 : if number_of_dram > 2 generate dramif2 : dram2if -- generic map ( -- chipscope => true) port map ( lclk => lclk0, rst => dcm_rst2_2, sysclk => clk_i, dram_out => dram2_out, dram_in => dram2_in, ld_i => ld_i, ld_o => mem_out2, la_q => mem_addr_ddr, lwrite => lwrite, lblast => blast_i, lbterm => lbterm, ds_xfer => ds_xfer_mem(2), lads => qlads_mem(2), ready => ready2, stop => dram2_stop, lb_request => mem_status(2), lb_grant => mem_gnt(2), lb_rskip => lb_rskip_reg, lb_roffset => lb_roffset_reg, status => mem_overflow2, debug => open, clk_0 => clk_0, clk_90 => clk_90, CNTL_CLK_ID1 => ddr2_CLK_ID1, CNTL_CLK_ID2 => ddr2_CLK_ID2, CNTL_CLK_ID3 => ddr2_CLK_ID3, CNTL_CLK_ID4 => ddr2_CLK_ID4, sys_rst => sys_rst2, sys_rst90 => sys_rst90_2, SYS_RST_ID => SYS_RST_ID, idelay_ctrl_rdy => idelay_ctrl_rdy, online => mem_online(2), DDR2_RAS_N => DDR2_RAS_N, DDR2_CAS_N => DDR2_CAS_N, DDR2_WE_N => DDR2_WE_N, DDR2_ODT => DDR2_ODT, DDR2_CKE => DDR2_CKE, DDR2_CS_N => DDR2_CS_N, DDR2_DQ => DDR2_DQ, DDR2_DQS => DDR2_DQS, DDR2_DQS_N => DDR2_DQS_N, DDR2_DM => DDR2_DM, DDR2_CK => DDR2_CK, DDR2_CK_N => DDR2_CK_N, DDR2_BA => DDR2_BA, DDR2_A => DDR2_A); end generate gen_dram2; gen_not_dram2 : if number_of_dram < 3 generate -- dram2_in <= slv_to_extmem_type(CONV_STD_LOGIC_VECTOR(0, extmem_type_width)); mem_out2 <= (others => '0'); ready2 <= '1'; dram2_stop <= '0'; mem_status(2) <= '0'; end generate gen_not_dram2; gen_dram3 : if number_of_dram > 3 generate dramif3 : dram2if -- generic map ( -- chipscope => true) port map ( lclk => lclk0, rst => dcm_rst2_3, sysclk => clk_i, dram_out => dram3_out, dram_in => dram3_in, ld_i => ld_i, ld_o => mem_out3, la_q => mem_addr_ddr, lwrite => lwrite, lblast => blast_i, lbterm => lbterm, ds_xfer => ds_xfer_mem(3), lads => qlads_mem(3), ready => ready3, stop => dram3_stop, lb_request => mem_status(3), lb_grant => mem_gnt(3), lb_rskip => lb_rskip_reg, lb_roffset => lb_roffset_reg, status => mem_overflow3, debug => open, clk_0 => clk_0, clk_90 => clk_90, CNTL_CLK_ID1 => ddr2_CLK_ID1, CNTL_CLK_ID2 => ddr2_CLK_ID2, CNTL_CLK_ID3 => ddr2_CLK_ID3, CNTL_CLK_ID4 => ddr2_CLK_ID4, sys_rst => sys_rst3, sys_rst90 => sys_rst90_3, SYS_RST_ID => SYS_RST_ID, idelay_ctrl_rdy => idelay_ctrl_rdy, online => mem_online(3), DDR2_RAS_N => DDR3_RAS_N, DDR2_CAS_N => DDR3_CAS_N, DDR2_WE_N => DDR3_WE_N, DDR2_ODT => DDR3_ODT, DDR2_CKE => DDR3_CKE, DDR2_CS_N => DDR3_CS_N, DDR2_DQ => DDR3_DQ, DDR2_DQS => DDR3_DQS, DDR2_DQS_N => DDR3_DQS_N, DDR2_DM => DDR3_DM, DDR2_CK => DDR3_CK, DDR2_CK_N => DDR3_CK_N, DDR2_BA => DDR3_BA, DDR2_A => DDR3_A); end generate gen_dram3; gen_not_dram3 : if number_of_dram < 4 generate -- dram3_in <= slv_to_extmem_type(CONV_STD_LOGIC_VECTOR(0, extmem_type_width)); mem_out3 <= (others => '0'); ready3 <= '1'; dram3_stop <= '0'; mem_status(3) <= '0'; end generate gen_not_dram3; -- -- Instantiate the module that generates the SDRAM clocks -- infrastructure: mem_interface_infrastructure_DirectClk PORT MAP( SYS_CLK => clk0, CLK200 => clk200_bufg_out, SYS_RESET_INn => mem_rst, CLK => clk_0, CLK90 => clk_90, CLK_ID1 => ddr2_CLK_ID1, CLK_ID2 => ddr2_CLK_ID2, CLK_ID3 => ddr2_CLK_ID3, CLK_ID4 => ddr2_CLK_ID4, idelay_ctrl_rdy => idelay_ctrl_rdy, LOCKED => locked(3 downto 2), sys_rst => sys_rst_i, sys_rst_90 => sys_rst90_i, SYS_RST_ID => SYS_RST_ID); sys_rst90_0 <= sys_rst90_i; sys_rst90_1 <= sys_rst90_i; sys_rst90_2 <= sys_rst90_i; sys_rst90_3 <= sys_rst90_i; sys_rst_bufg : BUFG port map ( I => sys_rst_i, O => sys_rst0); sys_rst1 <= sys_rst0; sys_rst2 <= sys_rst0; sys_rst3 <= sys_rst0; SYS_CLK <= adcclk; -- -- Input the 200MHz Reference Clock -- lvpecl_clk200_in : IBUFGDS_LVPECL_25 port map ( O => REF_CLK200_IN, I => clk200_p, IB => clk200_n ); clk_200bg : BUFG port map ( O => clk200_bufg_out, I => REF_CLK200_IN ); end mixed;