//////////////////////////////////////////////////////////////////////////////// // // Filename: ddr3_top.v // Project: UberDDR3 - An Open Source DDR3 Controller // // Purpose: Top module which instantiates the ddr3_controller and ddr3_phy modules // Use this as top module for instantiating UberDDR3 with Wishbone Interface. // // Engineer: Angelo C. Jacobo // //////////////////////////////////////////////////////////////////////////////// // // Copyright (C) 2023-2025 Angelo Jacobo // // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program. If not, see . // //////////////////////////////////////////////////////////////////////////////// `default_nettype none `timescale 1ps / 1ps module ddr3_top #( parameter CONTROLLER_CLK_PERIOD = 12_000, //ps, clock period of the controller interface DDR3_CLK_PERIOD = 3_000, //ps, clock period of the DDR3 RAM device (must be 1/4 of the CONTROLLER_CLK_PERIOD) ROW_BITS = 14, //width of row address COL_BITS = 10, //width of column address BA_BITS = 3, //width of bank address BYTE_LANES = 2, //number of byte lanes of DDR3 RAM AUX_WIDTH = 4, //width of aux line (must be >= 4) WB2_ADDR_BITS = 7, //width of 2nd wishbone address bus WB2_DATA_BITS = 32, //width of 2nd wishbone data bus DUAL_RANK_DIMM = 0, // enable dual rank DIMM (1 = enable, 0 = disable) // DDR3 timing parameter values parameter SPEED_BIN = 3, // 0 = Use top-level parameters , 1 = DDR3-1066 (7-7-7) , 2 = DR3-1333 (9-9-9) , 3 = DDR3-1600 (11-11-11) SDRAM_CAPACITY = 5, // 0 = 256Mb, 1 = 512Mb, 2 = 1Gb, 3 = 2Gb, 4 = 4Gb, 5 = 8Gb, 6 = 16Gb TRCD = 13_750, // ps Active to Read/Write command time (only used if SPEED_BIN = 0) TRP = 13_750, // ps Precharge command period (only used if SPEED_BIN = 0) TRAS = 35_000, // ps ACT to PRE command period (only used if SPEED_BIN = 0) parameter[0:0] MICRON_SIM = 0, //enable faster simulation for micron ddr3 model (shorten POWER_ON_RESET_HIGH and INITIAL_CKE_LOW) ODELAY_SUPPORTED = 0, //set to 1 when ODELAYE2 is supported SECOND_WISHBONE = 0, //set to 1 if 2nd wishbone for debugging is needed DLL_OFF = 0, // 1 = DLL off for low frequency ddr3 clock (< 125MHz) WB_ERROR = 0, // set to 1 to support Wishbone error (asserts at ECC double bit error) parameter[1:0] BIST_MODE = 1, // 0 = No BIST, 1 = run through all address space ONCE , 2 = run through all address space for every test (burst w/r, random w/r, alternating r/w) parameter[1:0] ECC_ENABLE = 0, // set to 1 or 2 to add ECC (1 = Side-band ECC per burst, 2 = Side-band ECC per 8 bursts , 3 = Inline ECC ) parameter[1:0] DIC = 2'b00, //Output Driver Impedance Control (2'b00 = RZQ/6, 2'b01 = RZQ/7, RZQ = 240ohms) (only change when you know what you are doing) parameter[2:0] RTT_NOM = 3'b011, //RTT Nominal (3'b000 = disabled, 3'b001 = RZQ/4, 3'b010 = RZQ/2 , 3'b011 = RZQ/6, RZQ = 240ohms) (only change when you know what you are doing) parameter[1:0] SELF_REFRESH = 2'b00, // 0 = use i_user_self_refresh input, 1 = Self-refresh mode is enabled after 64 controller clock cycles of no requests, 2 = 128 cycles, 3 = 256 cycles parameter // The next parameters act more like a localparam (since user does not have to set this manually) but was added here to simplify port declaration DQ_BITS = 8, //device width (fixed to 8, if DDR3 is x16 then BYTE_LANES will be 2 while ) serdes_ratio = 4, // this controller is fixed as a 4:1 memory controller (CONTROLLER_CLK_PERIOD/DDR3_CLK_PERIOD = 4) wb_addr_bits = ROW_BITS + COL_BITS + BA_BITS - $clog2(serdes_ratio*2) + DUAL_RANK_DIMM, wb_data_bits = DQ_BITS*BYTE_LANES*serdes_ratio*2, wb_sel_bits = wb_data_bits / 8, wb2_sel_bits = WB2_DATA_BITS / 8, //4 is the width of a single ddr3 command {cs_n, ras_n, cas_n, we_n} plus 3 (ck_en, odt, reset_n) plus bank bits plus row bits cmd_len = 4 + 3 + BA_BITS + ROW_BITS + 2*DUAL_RANK_DIMM ) ( input wire i_controller_clk, i_ddr3_clk, i_ref_clk, //i_controller_clk = CONTROLLER_CLK_PERIOD, i_ddr3_clk = DDR3_CLK_PERIOD, i_ref_clk = 200MHz input wire i_ddr3_clk_90, //required only when ODELAY_SUPPORTED is zero input wire i_rst_n, // // Wishbone inputs input wire i_wb_cyc, //bus cycle active (1 = normal operation, 0 = all ongoing transaction are to be cancelled) input wire i_wb_stb, //request a transfer input wire i_wb_we, //write-enable (1 = write, 0 = read) input wire[wb_addr_bits - 1:0] i_wb_addr, //burst-addressable {row,bank,col} input wire[wb_data_bits - 1:0] i_wb_data, //write data, for a 4:1 controller data width is 8 times the number of pins on the device input wire[wb_sel_bits - 1:0] i_wb_sel, //byte strobe for write (1 = write the byte) input wire[AUX_WIDTH - 1:0] i_aux, //for AXI-interface compatibility (given upon strobe) // Wishbone outputs output wire o_wb_stall, //1 = busy, cannot accept requests output wire o_wb_ack, //1 = read/write request has completed output wire o_wb_err, //1 = Error due to ECC double bit error (fixed to 0 if WB_ERROR = 0) output wire[wb_data_bits - 1:0] o_wb_data, //read data, for a 4:1 controller data width is 8 times the number of pins on the device output wire[AUX_WIDTH - 1:0] o_aux, //for AXI-interface compatibility (given upon strobe) // // Wishbone 2 (PHY) inputs input wire i_wb2_cyc, //bus cycle active (1 = normal operation, 0 = all ongoing transaction are to be cancelled) input wire i_wb2_stb, //request a transfer input wire i_wb2_we, //write-enable (1 = write, 0 = read) input wire[WB2_ADDR_BITS - 1:0] i_wb2_addr, // memory-mapped register to be accessed input wire[WB2_DATA_BITS - 1:0] i_wb2_data, //write data input wire[wb2_sel_bits - 1:0] i_wb2_sel, //byte strobe for write (1 = write the byte) // Wishbone 2 (Controller) outputs output wire o_wb2_stall, //1 = busy, cannot accept requests output wire o_wb2_ack, //1 = read/write request has completed output wire[WB2_DATA_BITS - 1:0] o_wb2_data, //read data // // DDR3 I/O Interface output wire[DUAL_RANK_DIMM:0] o_ddr3_clk_p, o_ddr3_clk_n, output wire o_ddr3_reset_n, output wire[DUAL_RANK_DIMM:0] o_ddr3_cke, // CKE output wire[DUAL_RANK_DIMM:0] o_ddr3_cs_n, // chip select signal output wire o_ddr3_ras_n, // RAS# output wire o_ddr3_cas_n, // CAS# output wire o_ddr3_we_n, // WE# output wire[ROW_BITS-1:0] o_ddr3_addr, output wire[BA_BITS-1:0] o_ddr3_ba_addr, inout wire[(DQ_BITS*BYTE_LANES)-1:0] io_ddr3_dq, inout wire[BYTE_LANES-1:0] io_ddr3_dqs, io_ddr3_dqs_n, output wire[BYTE_LANES-1:0] o_ddr3_dm, output wire[DUAL_RANK_DIMM:0] o_ddr3_odt, // on-die termination // // Done Calibration pin output wire o_calib_complete, // Debug outputs output wire[31:0] o_debug1, // output wire[31:0] o_debug2, // output wire[31:0] o_debug3, // output wire[(DQ_BITS*BYTE_LANES)/8-1:0] o_ddr3_debug_read_dqs_p, // output wire[(DQ_BITS*BYTE_LANES)/8-1:0] o_ddr3_debug_read_dqs_n // // User enabled self-refresh input wire i_user_self_refresh, output wire uart_tx ); // Instantiation Template (DEFAULT VALUE IS FOR ARTY S7) /* // DDR3 Controller ddr3_top #( .CONTROLLER_CLK_PERIOD(12_000), //ps, clock period of the controller interface .DDR3_CLK_PERIOD(3_000), //ps, clock period of the DDR3 RAM device (must be 1/4 of the CONTROLLER_CLK_PERIOD) .ROW_BITS(14), //width of row address .COL_BITS(10), //width of column address .BA_BITS(3), //width of bank address .BYTE_LANES(2), //number of byte lanes of DDR3 RAM .AUX_WIDTH(4), //width of aux line (must be >= 4) .MICRON_SIM(0), //enable faster simulation for micron ddr3 model (shorten POWER_ON_RESET_HIGH and INITIAL_CKE_LOW) .ODELAY_SUPPORTED(0), //set to 1 if ODELAYE2 is supported .SECOND_WISHBONE(0), //set to 1 if 2nd wishbone for debugging is needed .ECC_ENABLE(0), // set to 1 or 2 to add ECC (1 = Side-band ECC per burst, 2 = Side-band ECC per 8 bursts , 3 = Inline ECC ) .WB_ERROR(0), // set to 1 to support Wishbone error (asserts at ECC double bit error) ) ddr3_top ( //clock and reset .i_controller_clk(i_controller_clk), .i_ddr3_clk(i_ddr3_clk), //i_controller_clk has period of CONTROLLER_CLK_PERIOD, i_ddr3_clk has period of DDR3_CLK_PERIOD .i_ref_clk(i_ref_clk), // usually set to 200 MHz .i_ddr3_clk_90(i_ddr3_clk_90), //90 degree phase shifted version i_ddr3_clk (required only when ODELAY_SUPPORTED is zero) .i_rst_n(!i_rst && clk_locked), // // Wishbone inputs .i_wb_cyc(1), //bus cycle active (1 = normal operation, 0 = all ongoing transaction are to be cancelled) .i_wb_stb(i_wb_stb), //request a transfer .i_wb_we(i_wb_we), //write-enable (1 = write, 0 = read) .i_wb_addr(i_wb_addr), //burst-addressable {row,bank,col} .i_wb_data(i_wb_data), //write data, for a 4:1 controller data width is 8 times the number of pins on the device .i_wb_sel(16'hffff), //byte strobe for write (1 = write the byte) .i_aux(i_wb_we), //for AXI-interface compatibility (given upon strobe) // Wishbone outputs .o_wb_stall(o_wb_stall), //1 = busy, cannot accept requests .o_wb_ack(o_wb_ack), //1 = read/write request has completed .o_wb_err(o_wb_err), //1 = Error due to ECC double bit error (fixed to 0 if WB_ERROR = 0) .o_wb_data(o_wb_data), //read data, for a 4:1 controller data width is 8 times the number of pins on the device .o_aux(o_aux), // // Wishbone 2 (PHY) inputs .i_wb2_cyc(0), //bus cycle active (1 = normal operation, 0 = all ongoing transaction are to be cancelled) .i_wb2_stb(0), //request a transfer .i_wb2_we(0), //write-enable (1 = write, 0 = read) .i_wb2_addr(0), //burst-addressable {row,bank,col} .i_wb2_data(0), //write data, for a 4:1 controller data width is 8 times the number of pins on the device .i_wb2_sel(0), //byte strobe for write (1 = write the byte) // Wishbone 2 (Controller) outputs .o_wb2_stall(), //1 = busy, cannot accept requests .o_wb2_ack(), //1 = read/write request has completed .o_wb2_data(), //read data, for a 4:1 controller data width is 8 times the number of pins on the device // // DDR3 I/O Interface .o_ddr3_clk_p(ddr3_clk_p), .o_ddr3_clk_n(ddr3_clk_n), .o_ddr3_reset_n(ddr3_reset_n), .o_ddr3_cke(ddr3_cke), .o_ddr3_cs_n(ddr3_cs_n), // width = number of DDR3 ranks .o_ddr3_ras_n(ddr3_ras_n), .o_ddr3_cas_n(ddr3_cas_n), .o_ddr3_we_n(ddr3_we_n), .o_ddr3_addr(ddr3_addr), // width = ROW_BITS .o_ddr3_ba_addr(ddr3_ba), // width = BA_BITS .io_ddr3_dq(ddr3_dq), // width = BYTE_LANES*8 .io_ddr3_dqs(ddr3_dqs_p), // width = BYTE_LANES .io_ddr3_dqs_n(ddr3_dqs_n), // width = BYTE_LANES .o_ddr3_dm(ddr3_dm), // width = BYTE_LANES .o_ddr3_odt(ddr3_odt), // Debug outputs .o_debug1(), //////////////////////////////////// ); */ // Wire connections between controller and phy wire[cmd_len*serdes_ratio-1:0] cmd; wire dqs_tri_control, dq_tri_control; wire toggle_dqs; wire[wb_data_bits-1:0] data; wire[wb_sel_bits-1:0] dm; wire[BYTE_LANES-1:0] bitslip; wire[DQ_BITS*BYTE_LANES*8-1:0] iserdes_data; wire[BYTE_LANES*8-1:0] iserdes_dqs; wire[BYTE_LANES*8-1:0] iserdes_bitslip_reference; wire idelayctrl_rdy; wire[4:0] odelay_data_cntvaluein, odelay_dqs_cntvaluein; wire[4:0] idelay_data_cntvaluein, idelay_dqs_cntvaluein; wire[BYTE_LANES-1:0] odelay_data_ld, odelay_dqs_ld; wire[BYTE_LANES-1:0] idelay_data_ld, idelay_dqs_ld; wire write_leveling_calib; wire reset; // logic for self-refresh reg[8:0] refresh_counter = 0; reg user_self_refresh; // refresh counter always @(posedge i_controller_clk) begin if(i_wb_stb && i_wb_cyc) begin // if there is Wishbone request, then reset counter refresh_counter <= 0; end else if(!o_wb_stall || user_self_refresh) begin // if no request (but not stalled) OR already on self-refresh, then increment counter refresh_counter <= refresh_counter + 1; end end // choose self-refresh options always @* begin case(SELF_REFRESH) 2'b00: user_self_refresh = i_user_self_refresh; // use input i_user_self_refresh (high = enter self-refresh, low = exit self-refresh) 2'b01: user_self_refresh = refresh_counter[6]; // Self-refresh mode is enabled after 64 controller clock cycles of no requests, then exit Self-refresh after another 64 controller clk cycles 2'b10: user_self_refresh = refresh_counter[7]; // Self-refresh mode is enabled after 128 controller clock cycles of no requests, then exit Self-refresh after another 128 controller clk cycles 2'b11: user_self_refresh = refresh_counter[8]; // Self-refresh mode is enabled after 256 controller clock cycles of no requests, then exit Self-refresh after another 256 controller clk cycles endcase end //module instantiations ddr3_controller #( .CONTROLLER_CLK_PERIOD(CONTROLLER_CLK_PERIOD), //ps, clock period of the controller interface .DDR3_CLK_PERIOD(DDR3_CLK_PERIOD), //ps, clock period of the DDR3 RAM device (must be 1/4 of the CONTROLLER_CLK_PERIOD) .ROW_BITS(ROW_BITS), //width of row address .COL_BITS(COL_BITS), //width of column address .BA_BITS(BA_BITS), //width of bank address .DQ_BITS(DQ_BITS), //width of DQ .LANES(BYTE_LANES), // byte lanes .AUX_WIDTH(AUX_WIDTH), //width of aux line (must be >= 4) .WB2_ADDR_BITS(WB2_ADDR_BITS), //width of 2nd wishbone address bus .WB2_DATA_BITS(WB2_DATA_BITS), //width of 2nd wishbone data bus .MICRON_SIM(MICRON_SIM), //simulation for micron ddr3 model (shorten POWER_ON_RESET_HIGH and INITIAL_CKE_LOW) .ODELAY_SUPPORTED(ODELAY_SUPPORTED), //set to 1 when ODELAYE2 is supported .SECOND_WISHBONE(SECOND_WISHBONE), //set to 1 if 2nd wishbone is needed .ECC_ENABLE(ECC_ENABLE), // set to 1 or 2 to add ECC (1 = Side-band ECC per burst, 2 = Side-band ECC per 8 bursts , 3 = Inline ECC ) .DLL_OFF(DLL_OFF), // 1 = DLL off for low frequency ddr3 clock (< 125MHz) .WB_ERROR(WB_ERROR), // set to 1 to support Wishbone error (asserts at ECC double bit error) .BIST_MODE(BIST_MODE), // 0 = No BIST, 1 = run through all address space ONCE , 2 = run through all address space for every test (burst w/r, random w/r, alternating r/w) .DIC(DIC), //Output Driver Impedance Control (2'b00 = RZQ/6, 2'b01 = RZQ/7, RZQ = 240ohms) .RTT_NOM(RTT_NOM), //RTT Nominal (3'b000 = disabled, 3'b001 = RZQ/4, 3'b010 = RZQ/2 , 3'b011 = RZQ/6, RZQ = 240ohms) .DUAL_RANK_DIMM(DUAL_RANK_DIMM), // enable dual rank DIMM (1 = enable, 0 = disable) .SPEED_BIN(SPEED_BIN), // 0 = Use top-level parameters , 1 = DDR3-1066 (7-7-7) , 2 = DR3-1333 (9-9-9) , 3 = DDR3-1600 (11-11-11) .SDRAM_CAPACITY(SDRAM_CAPACITY), // 0 = 256Mb, 1 = 512Mb, 2 = 1Gb, 3 = 2Gb, 4 = 4Gb, 5 = 8Gb, 6 = 16Gb .TRCD(TRCD), // ps Active to Read/Write command time (only used if SPEED_BIN = 0) .TRP(TRP), // ps Precharge command period (only used if SPEED_BIN = 0) .TRAS(TRAS) // ps ACT to PRE command period (only used if SPEED_BIN = 0) ) ddr3_controller_inst ( .i_controller_clk(i_controller_clk), //i_controller_clk has period of CONTROLLER_CLK_PERIOD .i_rst_n(i_rst_n), //200MHz input clock // Wishbone inputs .i_wb_cyc(i_wb_cyc), //bus cycle active (1 = normal operation, 0 = all ongoing transaction are to be cancelled) .i_wb_stb(i_wb_stb), //request a transfer .i_wb_we(i_wb_we), //write-enable (1 = write, 0 = read) .i_wb_addr(i_wb_addr), //burst-addressable {row,bank,col} .i_wb_data(i_wb_data), //write data, for a 4:1 controller data width is 8 times the number of pins on the device .i_wb_sel(i_wb_sel), //byte strobe for write (1 = write the byte) .i_aux(i_aux), //for AXI-interface compatibility (given upon strobe) // Wishbone outputs .o_wb_stall(o_wb_stall), //1 = busy, cannot accept requests .o_wb_ack(o_wb_ack), //1 = read/write request has completed .o_wb_err(o_wb_err), //1 = Error due to ECC double bit error (fixed to 0 if WB_ERROR = 0) .o_wb_data(o_wb_data), //read data, for a 4:1 controller data width is 8 times the number of pins on the device .o_aux(o_aux), //for AXI-interface compatibility (returned upon ack) // Wishbone 2 (PHY) inputs .i_wb2_cyc(i_wb2_cyc), //bus cycle active (1 = normal operation, 0 = all ongoing transaction are to be cancelled) .i_wb2_stb(i_wb2_stb), //request a transfer .i_wb2_we(i_wb2_we), //write-enable (1 = write, 0 = read) .i_wb2_addr(i_wb2_addr), // memory-mapped register to be accessed .i_wb2_data(i_wb2_data), //write data .i_wb2_sel(i_wb2_sel), //byte strobe for write (1 = write the byte) // Wishbone 2 (Controller) outputs .o_wb2_stall(o_wb2_stall), //1 = busy, cannot accept requests .o_wb2_ack(o_wb2_ack), //1 = read/write request has completed .o_wb2_data(o_wb2_data), //read data // // PHY interface .i_phy_iserdes_data(iserdes_data), .i_phy_iserdes_dqs(iserdes_dqs), .i_phy_iserdes_bitslip_reference(iserdes_bitslip_reference), .i_phy_idelayctrl_rdy(idelayctrl_rdy), .o_phy_cmd(cmd), .o_phy_dqs_tri_control(dqs_tri_control), .o_phy_dq_tri_control(dq_tri_control), .o_phy_toggle_dqs(toggle_dqs), .o_phy_data(data), .o_phy_dm(dm), .o_phy_odelay_data_cntvaluein(odelay_data_cntvaluein), .o_phy_odelay_dqs_cntvaluein(odelay_dqs_cntvaluein), .o_phy_idelay_data_cntvaluein(idelay_data_cntvaluein), .o_phy_idelay_dqs_cntvaluein(idelay_dqs_cntvaluein), .o_phy_odelay_data_ld(odelay_data_ld), .o_phy_odelay_dqs_ld(odelay_dqs_ld), .o_phy_idelay_data_ld(idelay_data_ld), .o_phy_idelay_dqs_ld(idelay_dqs_ld), .o_phy_bitslip(bitslip), .o_phy_write_leveling_calib(write_leveling_calib), .o_phy_reset(reset), // Done Calibration pin .o_calib_complete(o_calib_complete), // Debug outputs .o_debug1(o_debug1), // .o_debug2(o_debug2), // .o_debug3(o_debug3) // User enabled self-refresh .i_user_self_refresh(user_self_refresh), .uart_tx(uart_tx) ); `ifndef LATTICE_ECP5_PHY // XILINX PHY ddr3_phy #( .ROW_BITS(ROW_BITS), //width of row address .BA_BITS(BA_BITS), //width of bank address .DQ_BITS(DQ_BITS), //width of DQ .LANES(BYTE_LANES), //8 lanes of DQ .CONTROLLER_CLK_PERIOD(CONTROLLER_CLK_PERIOD), //ps, period of clock input to this DDR3 controller module .DDR3_CLK_PERIOD(DDR3_CLK_PERIOD), //ps, period of clock input to DDR3 RAM device .ODELAY_SUPPORTED(ODELAY_SUPPORTED), //set to 1 when ODELAYE2 is supported .DUAL_RANK_DIMM(DUAL_RANK_DIMM) // enable dual rank DIMM (1 = enable, 0 = disable) ) ddr3_phy_inst ( .i_controller_clk(i_controller_clk), .i_ddr3_clk(i_ddr3_clk), .i_ref_clk(i_ref_clk), .i_ddr3_clk_90(i_ddr3_clk_90), .i_rst_n(i_rst_n), // Controller Interface .i_controller_reset(reset), .i_controller_cmd(cmd), .i_controller_dqs_tri_control(dqs_tri_control), .i_controller_dq_tri_control(dq_tri_control), .i_controller_toggle_dqs(toggle_dqs), .i_controller_data(data), .i_controller_dm(dm), .i_controller_odelay_data_cntvaluein(odelay_data_cntvaluein), .i_controller_odelay_dqs_cntvaluein(odelay_dqs_cntvaluein), .i_controller_idelay_data_cntvaluein(idelay_data_cntvaluein), .i_controller_idelay_dqs_cntvaluein(idelay_dqs_cntvaluein), .i_controller_odelay_data_ld(odelay_data_ld), .i_controller_odelay_dqs_ld(odelay_dqs_ld), .i_controller_idelay_data_ld(idelay_data_ld), .i_controller_idelay_dqs_ld(idelay_dqs_ld), .i_controller_bitslip(bitslip), .i_controller_write_leveling_calib(write_leveling_calib), .o_controller_iserdes_data(iserdes_data), .o_controller_iserdes_dqs(iserdes_dqs), .o_controller_iserdes_bitslip_reference(iserdes_bitslip_reference), .o_controller_idelayctrl_rdy(idelayctrl_rdy), // DDR3 I/O Interface .o_ddr3_clk_p(o_ddr3_clk_p), .o_ddr3_clk_n(o_ddr3_clk_n), .o_ddr3_reset_n(o_ddr3_reset_n), .o_ddr3_cke(o_ddr3_cke), // CKE .o_ddr3_cs_n(o_ddr3_cs_n), // chip select signal .o_ddr3_ras_n(o_ddr3_ras_n), // RAS# .o_ddr3_cas_n(o_ddr3_cas_n), // CAS# .o_ddr3_we_n(o_ddr3_we_n), // WE# .o_ddr3_addr(o_ddr3_addr), .o_ddr3_ba_addr(o_ddr3_ba_addr), .io_ddr3_dq(io_ddr3_dq), .io_ddr3_dqs(io_ddr3_dqs), .io_ddr3_dqs_n(io_ddr3_dqs_n), .o_ddr3_dm(o_ddr3_dm), .o_ddr3_odt(o_ddr3_odt), // on-die termination .o_ddr3_debug_read_dqs_p(/*o_ddr3_debug_read_dqs_p*/), .o_ddr3_debug_read_dqs_n(/*o_ddr3_debug_read_dqs_n*/) ); `else // LATTICE ECP5 PHY ddr3_phy_ecp5 #( .ROW_BITS(ROW_BITS), //width of row address .BA_BITS(BA_BITS), //width of bank address .DQ_BITS(DQ_BITS), //width of DQ .LANES(BYTE_LANES), //8 lanes of DQ .CONTROLLER_CLK_PERIOD(CONTROLLER_CLK_PERIOD) //ps, period of clock input to this DDR3 controller module ) ddr3_phy_inst ( .i_controller_clk(i_controller_clk), .i_ddr3_clk(i_ddr3_clk), .i_ref_clk(i_ref_clk), .i_ddr3_clk_90(i_ddr3_clk_90), .i_rst_n(i_rst_n), // Controller Interface .i_controller_reset(reset), .i_controller_cmd(cmd), .i_controller_dqs_tri_control(dqs_tri_control), .i_controller_dq_tri_control(dq_tri_control), .i_controller_toggle_dqs(toggle_dqs), .i_controller_data(data), .i_controller_dm(dm), .i_controller_odelay_data_cntvaluein(odelay_data_cntvaluein), .i_controller_odelay_dqs_cntvaluein(odelay_dqs_cntvaluein), .i_controller_idelay_data_cntvaluein(idelay_data_cntvaluein), .i_controller_idelay_dqs_cntvaluein(idelay_dqs_cntvaluein), .i_controller_odelay_data_ld(odelay_data_ld), .i_controller_odelay_dqs_ld(odelay_dqs_ld), .i_controller_idelay_data_ld(idelay_data_ld), .i_controller_idelay_dqs_ld(idelay_dqs_ld), .i_controller_bitslip(bitslip), .i_controller_write_leveling_calib(write_leveling_calib), .o_controller_iserdes_data(iserdes_data), .o_controller_iserdes_dqs(iserdes_dqs), .o_controller_iserdes_bitslip_reference(iserdes_bitslip_reference), .o_controller_idelayctrl_rdy(idelayctrl_rdy), // DDR3 I/O Interface .o_ddr3_clk_p(o_ddr3_clk_p), .o_ddr3_clk_n(o_ddr3_clk_n), .o_ddr3_reset_n(o_ddr3_reset_n), .o_ddr3_cke(o_ddr3_cke), // CKE .o_ddr3_cs_n(o_ddr3_cs_n), // chip select signal .o_ddr3_ras_n(o_ddr3_ras_n), // RAS# .o_ddr3_cas_n(o_ddr3_cas_n), // CAS# .o_ddr3_we_n(o_ddr3_we_n), // WE# .o_ddr3_addr(o_ddr3_addr), .o_ddr3_ba_addr(o_ddr3_ba_addr), .io_ddr3_dq(io_ddr3_dq), .io_ddr3_dqs(io_ddr3_dqs), .io_ddr3_dqs_n(io_ddr3_dqs_n), .o_ddr3_dm(o_ddr3_dm), .o_ddr3_odt(o_ddr3_odt), // on-die termination .o_ddr3_debug_read_dqs_p(/*o_ddr3_debug_read_dqs_p*/), .o_ddr3_debug_read_dqs_n(/*o_ddr3_debug_read_dqs_n*/) ); `endif // // display value of parameters for easy debugging // initial begin // $display("\nDDR3 TOP PARAMETERS:\n-----------------------------"); // $display("CONTROLLER_CLK_PERIOD = %0d", CONTROLLER_CLK_PERIOD); // $display("DDR3_CLK_PERIOD = %0d", DDR3_CLK_PERIOD); // $display("ROW_BITS = %0d", ROW_BITS); // $display("COL_BITS = %0d", COL_BITS); // $display("BA_BITS = %0d", BA_BITS); // $display("BYTE_LANES = %0d", BYTE_LANES); // $display("AUX_WIDTH = %0d", AUX_WIDTH); // $display("WB2_ADDR_BITS = %0d", WB2_ADDR_BITS); // $display("WB2_DATA_BITS = %0d", WB2_DATA_BITS); // $display("MICRON_SIM = %0d", MICRON_SIM); // $display("ODELAY_SUPPORTED = %0d", ODELAY_SUPPORTED); // $display("SECOND_WISHBONE = %0d", SECOND_WISHBONE); // $display("WB_ERROR = %0d", WB_ERROR); // $display("BIST_MODE = %0d", BIST_MODE); // $display("ECC_ENABLE = %0d", ECC_ENABLE); // $display("DIC = %0d", DIC); // $display("RTT_NOM = %0d", RTT_NOM); // $display("SELF_REFRESH = %0d", SELF_REFRESH); // $display("DUAL_RANK_DIMM = %0d", DUAL_RANK_DIMM); // $display("End of DDR3 TOP PARAMETERS\n-----------------------------"); // end endmodule