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|
`timescale 1ns / 1ps
//////////////////////////////////////////////////////////////////////////////////
module u2_rev3
(
// Misc, debug
output [5:0] leds,
output [31:0] debug,
output [1:0] debug_clk,
output uart_tx_o,
input uart_rx_i,
// Expansion
input exp_time_in_p, // Diff
input exp_time_in_n, // Diff
output exp_time_out_p, // Diff
output exp_time_out_n, // Diff
// GMII
// GMII-CTRL
input GMII_COL,
input GMII_CRS,
// GMII-TX
output reg [7:0] GMII_TXD,
output reg GMII_TX_EN,
output reg GMII_TX_ER,
output GMII_GTX_CLK,
input GMII_TX_CLK, // 100mbps clk
// GMII-RX
input [7:0] GMII_RXD,
input GMII_RX_CLK,
input GMII_RX_DV,
input GMII_RX_ER,
// GMII-Management
inout MDIO,
output MDC,
input PHY_INTn, // open drain
output PHY_RESETn,
input PHY_CLK, // possibly use on-board osc
// RAM
inout [17:0] RAM_D,
output [18:0] RAM_A,
output RAM_CE1n,
output RAM_CENn,
output RAM_CLK,
output RAM_WEn,
output RAM_OEn,
output RAM_LDn,
// SERDES
output ser_enable,
output ser_prbsen,
output ser_loopen,
output ser_rx_en,
output ser_tx_clk,
output reg [15:0] ser_t,
output reg ser_tklsb,
output reg ser_tkmsb,
input ser_rx_clk,
input [15:0] ser_r,
input ser_rklsb,
input ser_rkmsb,
// CPLD interface
output cpld_start, // AA9
output cpld_mode, // U12
output cpld_done, // V12
input cpld_din, // AA14 Now shared with CFG_Din
input cpld_clk, // AB14 serial clock
input cpld_detached,// V11 unused
output cpld_init_b, // W12 unused dual purpose
output cpld_misc, // Y12
// Watchdog interface
input POR,
output WDI,
// ADC
input [13:0] adc_a,
input adc_ovf_a,
output adc_oen_a,
output adc_pdn_a,
input [13:0] adc_b,
input adc_ovf_b,
output adc_oen_b,
output adc_pdn_b,
// DAC
output reg [15:0] dac_a,
output reg [15:0] dac_b,
input dac_lock, // unused for now
// I2C
inout SCL,
inout SDA,
// Clock Gen Control
output [1:0] clk_en,
output [1:0] clk_sel,
input clk_func, // FIXME is an input to control the 9510
input clk_status,
// Clocks
input clk_fpga_p, // Diff
input clk_fpga_n, // Diff
input clk_to_mac,
input pps_in,
// Generic SPI
output sclk,
output sen_clk,
output sen_dac,
output sdi,
input sdo,
// TX DBoard
output sen_tx_db,
output sclk_tx_db,
input sdo_tx_db,
output sdi_tx_db,
output sen_tx_adc,
output sclk_tx_adc,
input sdo_tx_adc,
output sdi_tx_adc,
output sen_tx_dac,
output sclk_tx_dac,
output sdi_tx_dac,
inout [15:0] io_tx,
// RX DBoard
output sen_rx_db,
output sclk_rx_db,
input sdo_rx_db,
output sdi_rx_db,
output sen_rx_adc,
output sclk_rx_adc,
input sdo_rx_adc,
output sdi_rx_adc,
output sen_rx_dac,
output sclk_rx_dac,
output sdi_rx_dac,
inout [15:0] io_rx
);
assign cpld_init_b = 0;
// FPGA-specific pins connections
wire clk_fpga, dsp_clk, clk_div, dcm_out, wb_clk, clock_ready;
wire clk90, clk180, clk270;
// reset the watchdog continuously
reg [15:0] wd;
wire config_success;
always @(posedge wb_clk)
if(~config_success)
wd <= 0;
else
wd <= wd + 1;
assign WDI = wd[15];
wire clk_fpga_unbuf;
IBUFGDS clk_fpga_pin (.O(clk_fpga_unbuf),.I(clk_fpga_p),.IB(clk_fpga_n));
BUFG clk_fpga_BUF (.O(clk_fpga),.I(clk_fpga_unbuf));
defparam clk_fpga_pin.IOSTANDARD = "LVPECL_25";
wire cpld_clock_buf;
BUFG cpld_clock_BUF (.O(cpld_clock_buf),.I(cpld_clock));
wire exp_time_in;
IBUFDS exp_time_in_pin (.O(exp_time_in),.I(exp_time_in_p),.IB(exp_time_in_n));
defparam exp_time_in_pin.IOSTANDARD = "LVDS_25";
wire exp_time_out;
OBUFDS exp_time_out_pin (.O(exp_time_out_p),.OB(exp_time_out_n),.I(exp_time_out));
defparam exp_time_out_pin.IOSTANDARD = "LVDS_25";
reg [5:0] clock_ready_d;
always @(posedge clk_fpga)
clock_ready_d[5:0] <= {clock_ready_d[4:0],clock_ready};
wire dcm_rst = ~&clock_ready_d & |clock_ready_d;
wire adc_on_a, adc_on_b, adc_oe_a, adc_oe_b;
assign adc_oen_a = ~adc_oe_a;
assign adc_oen_b = ~adc_oe_b;
assign adc_pdn_a = ~adc_on_a;
assign adc_pdn_b = ~adc_on_b;
reg [13:0] adc_a_reg1, adc_b_reg1, adc_a_reg2, adc_b_reg2;
reg adc_ovf_a_reg1, adc_ovf_a_reg2, adc_ovf_b_reg1, adc_ovf_b_reg2;
// ADC A and B are swapped in schematic to facilitate clean layout
always @(posedge dsp_clk)
begin
adc_a_reg1 <= adc_b;
adc_b_reg1 <= adc_a;
adc_ovf_a_reg1 <= adc_ovf_b;
adc_ovf_b_reg1 <= adc_ovf_a;
end
always @(posedge dsp_clk)
begin
adc_a_reg2 <= adc_a_reg1;
adc_b_reg2 <= adc_b_reg1;
adc_ovf_a_reg2 <= adc_ovf_a_reg1;
adc_ovf_b_reg2 <= adc_ovf_b_reg1;
end // always @ (posedge dsp_clk)
// Handle Clocks
DCM DCM_INST (.CLKFB(dsp_clk),
.CLKIN(clk_fpga),
.DSSEN(0),
.PSCLK(0),
.PSEN(0),
.PSINCDEC(0),
.RST(dcm_rst),
.CLKDV(clk_div),
.CLKFX(),
.CLKFX180(),
.CLK0(dcm_out),
.CLK2X(),
.CLK2X180(),
.CLK90(clk90),
.CLK180(clk180),
.CLK270(clk270),
.LOCKED(LOCKED_OUT),
.PSDONE(),
.STATUS());
defparam DCM_INST.CLK_FEEDBACK = "1X";
defparam DCM_INST.CLKDV_DIVIDE = 2.0;
defparam DCM_INST.CLKFX_DIVIDE = 1;
defparam DCM_INST.CLKFX_MULTIPLY = 4;
defparam DCM_INST.CLKIN_DIVIDE_BY_2 = "FALSE";
defparam DCM_INST.CLKIN_PERIOD = 10.000;
defparam DCM_INST.CLKOUT_PHASE_SHIFT = "NONE";
defparam DCM_INST.DESKEW_ADJUST = "SYSTEM_SYNCHRONOUS";
defparam DCM_INST.DFS_FREQUENCY_MODE = "LOW";
defparam DCM_INST.DLL_FREQUENCY_MODE = "LOW";
defparam DCM_INST.DUTY_CYCLE_CORRECTION = "TRUE";
defparam DCM_INST.FACTORY_JF = 16'h8080;
defparam DCM_INST.PHASE_SHIFT = 0;
defparam DCM_INST.STARTUP_WAIT = "FALSE";
BUFG dspclk_BUFG (.I(dcm_out), .O(dsp_clk));
BUFG wbclk_BUFG (.I(clk_div), .O(wb_clk));
// I2C -- Don't use external transistors for open drain, the FPGA implements this
IOBUF scl_pin(.O(scl_pad_i), .IO(SCL), .I(scl_pad_o), .T(scl_pad_oen_o));
IOBUF sda_pin(.O(sda_pad_i), .IO(SDA), .I(sda_pad_o), .T(sda_pad_oen_o));
// LEDs are active low outputs
wire [5:0] leds_int;
assign leds = 6'b011111 ^ leds_int; // all except eth are active-low
// SPI
wire miso, mosi, sclk_int;
assign {sclk,sdi} = (~sen_clk | ~sen_dac) ? {sclk_int,mosi} : 2'b0;
assign {sclk_tx_db,sdi_tx_db} = ~sen_tx_db ? {sclk_int,mosi} : 2'b0;
assign {sclk_tx_dac,sdi_tx_dac} = ~sen_tx_dac ? {sclk_int,mosi} : 2'b0;
assign {sclk_tx_adc,sdi_tx_adc} = ~sen_tx_adc ? {sclk_int,mosi} : 2'b0;
assign {sclk_rx_db,sdi_rx_db} = ~sen_rx_db ? {sclk_int,mosi} : 2'b0;
assign {sclk_rx_dac,sdi_rx_dac} = ~sen_rx_dac ? {sclk_int,mosi} : 2'b0;
assign {sclk_rx_adc,sdi_rx_adc} = ~sen_rx_adc ? {sclk_int,mosi} : 2'b0;
assign miso = (~sen_clk & sdo) | (~sen_dac & sdo) |
(~sen_tx_db & sdo_tx_db) | (~sen_tx_adc & sdo_tx_adc) |
(~sen_rx_db & sdo_rx_db) | (~sen_rx_adc & sdo_rx_adc);
wire GMII_TX_EN_unreg, GMII_TX_ER_unreg;
wire [7:0] GMII_TXD_unreg;
wire GMII_GTX_CLK_int;
always @(posedge GMII_GTX_CLK_int)
begin
GMII_TX_EN <= GMII_TX_EN_unreg;
GMII_TX_ER <= GMII_TX_ER_unreg;
GMII_TXD <= GMII_TXD_unreg;
end
OFDDRRSE OFDDRRSE_gmii_inst
(.Q(GMII_GTX_CLK), // Data output (connect directly to top-level port)
.C0(GMII_GTX_CLK_int), // 0 degree clock input
.C1(~GMII_GTX_CLK_int), // 180 degree clock input
.CE(1), // Clock enable input
.D0(0), // Posedge data input
.D1(1), // Negedge data input
.R(0), // Synchronous reset input
.S(0) // Synchronous preset input
);
wire ser_tklsb_unreg, ser_tkmsb_unreg;
wire [15:0] ser_t_unreg;
wire ser_tx_clk_int;
always @(posedge ser_tx_clk_int)
begin
ser_tklsb <= ser_tklsb_unreg;
ser_tkmsb <= ser_tkmsb_unreg;
ser_t <= ser_t_unreg;
end
assign ser_tx_clk = clk_fpga;
reg [15:0] ser_r_int;
reg ser_rklsb_int, ser_rkmsb_int;
wire ser_rx_clk_buf;
BUFG ser_rx_clk_BUF (.O(ser_rx_clk_buf),.I(ser_rx_clk));
always @(posedge ser_rx_clk_buf)
begin
ser_r_int <= ser_r;
ser_rklsb_int <= ser_rklsb;
ser_rkmsb_int <= ser_rkmsb;
end
wire [15:0] dac_a_int, dac_b_int;
// DAC A and B are swapped in schematic to facilitate clean layout
// DAC A is also inverted in schematic to facilitate clean layout
always @(posedge dsp_clk) dac_a <= ~dac_b_int;
always @(posedge dsp_clk) dac_b <= dac_a_int;
/*
OFDDRRSE OFDDRRSE_serdes_inst
(.Q(ser_tx_clk), // Data output (connect directly to top-level port)
.C0(ser_tx_clk_int), // 0 degree clock input
.C1(~ser_tx_clk_int), // 180 degree clock input
.CE(1), // Clock enable input
.D0(0), // Posedge data input
.D1(1), // Negedge data input
.R(0), // Synchronous reset input
.S(0) // Synchronous preset input
);
*/
wire [17:0] RAM_D_pi;
wire [17:0] RAM_D_po;
wire RAM_D_poe;
genvar i;
//
// Instantiate IO for Bidirectional bus to SRAM
//
generate
for (i=0;i<18;i=i+1)
begin : gen_RAM_D_IO
IOBUF #(
.DRIVE(12),
.IOSTANDARD("LVCMOS25"),
.SLEW("FAST")
)
RAM_D_i (
.O(RAM_D_pi[i]),
.I(RAM_D_po[i]),
.IO(RAM_D[i]),
.T(RAM_D_poe)
);
end // block: gen_RAM_D_IO
endgenerate
//
// DCM edits start here
//
wire RAM_CLK_buf;
wire clk_to_mac_buf;
wire clk125_ext_clk0;
wire clk125_ext_clk180;
wire clk125_ext_clk0_buf;
wire clk125_ext_clk180_buf;
wire clk125_int_buf;
wire clk125_int;
IBUFG clk_to_mac_buf_i1 (.I(clk_to_mac),
.O(clk_to_mac_buf));
DCM DCM_INST1 (.CLKFB(RAM_CLK_buf),
.CLKIN(clk_to_mac_buf),
.DSSEN(1'b0),
.PSCLK(1'b0),
.PSEN(1'b0),
.PSINCDEC(1'b0),
.RST(1'b0),
.CLK0(clk125_ext_clk0),
.CLK180(clk125_ext_clk180) );
defparam DCM_INST1.CLK_FEEDBACK = "1X";
defparam DCM_INST1.CLKDV_DIVIDE = 2.0;
defparam DCM_INST1.CLKFX_DIVIDE = 1;
defparam DCM_INST1.CLKFX_MULTIPLY = 4;
defparam DCM_INST1.CLKIN_DIVIDE_BY_2 = "FALSE";
defparam DCM_INST1.CLKIN_PERIOD = 8.000;
defparam DCM_INST1.CLKOUT_PHASE_SHIFT = "FIXED";
defparam DCM_INST1.DESKEW_ADJUST = "SYSTEM_SYNCHRONOUS";
defparam DCM_INST1.DFS_FREQUENCY_MODE = "LOW";
defparam DCM_INST1.DLL_FREQUENCY_MODE = "LOW";
defparam DCM_INST1.DUTY_CYCLE_CORRECTION = "TRUE";
defparam DCM_INST1.FACTORY_JF = 16'h8080;
defparam DCM_INST1.PHASE_SHIFT = -64;
defparam DCM_INST1.STARTUP_WAIT = "FALSE";
IBUFG RAM_CLK_buf_i1 (.I(RAM_CLK),
.O(RAM_CLK_buf));
BUFG clk125_ext_clk0_buf_i1 (.I(clk125_ext_clk0),
.O(clk125_ext_clk0_buf));
BUFG clk125_ext_clk180_buf_i1 (.I(clk125_ext_clk180),
.O(clk125_ext_clk180_buf));
OFDDRRSE RAM_CLK_i1 (.Q(RAM_CLK),
.C0(clk125_ext_clk0_buf),
.C1(clk125_ext_clk180_buf),
.CE(1'b1),
.D0(1'b1),
.D1(1'b0),
.R(1'b0),
.S(1'b0));
// SRL16 dcm2_rst_i1 (.D(1'b0),
// .CLK(clk_to_mac_buf),
// .Q(dcm2_rst),
// .A0(1'b1),
// .A1(1'b1),
// .A2(1'b1),
// .A3(1'b1));
// synthesis attribute init of dcm2_rst_i1 is "000F";
DCM DCM_INST2 (.CLKFB(clk125_int_buf),
.CLKIN(clk_to_mac_buf),
.DSSEN(1'b0),
.PSCLK(1'b0),
.PSEN(1'b0),
.PSINCDEC(1'b0),
.RST(1'b0),
.CLK0(clk125_int));
defparam DCM_INST2.CLK_FEEDBACK = "1X";
defparam DCM_INST2.CLKDV_DIVIDE = 2.0;
defparam DCM_INST2.CLKFX_DIVIDE = 1;
defparam DCM_INST2.CLKFX_MULTIPLY = 4;
defparam DCM_INST2.CLKIN_DIVIDE_BY_2 = "FALSE";
defparam DCM_INST2.CLKIN_PERIOD = 8.000;
defparam DCM_INST2.CLKOUT_PHASE_SHIFT = "NONE";
defparam DCM_INST2.DESKEW_ADJUST = "SYSTEM_SYNCHRONOUS";
defparam DCM_INST2.DFS_FREQUENCY_MODE = "LOW";
defparam DCM_INST2.DLL_FREQUENCY_MODE = "LOW";
defparam DCM_INST2.DUTY_CYCLE_CORRECTION = "TRUE";
defparam DCM_INST2.FACTORY_JF = 16'h8080;
defparam DCM_INST2.PHASE_SHIFT = 0;
defparam DCM_INST2.STARTUP_WAIT = "FALSE";
BUFG clk125_int_buf_i1 (.I(clk125_int),
.O(clk125_int_buf));
//
// DCM edits end here
//
u2_core #(.RAM_SIZE(16384), .RAM_AW(14))
u2_core(.dsp_clk (dsp_clk),
.wb_clk (wb_clk),
.clock_ready (clock_ready),
.clk_to_mac (clk125_int_buf),
.pps_in (pps_in),
.leds (leds_int),
.debug (debug[31:0]),
.debug_clk (debug_clk[1:0]),
.exp_time_in (exp_time_in),
.exp_time_out (exp_time_out),
.GMII_COL (GMII_COL),
.GMII_CRS (GMII_CRS),
.GMII_TXD (GMII_TXD_unreg[7:0]),
.GMII_TX_EN (GMII_TX_EN_unreg),
.GMII_TX_ER (GMII_TX_ER_unreg),
.GMII_GTX_CLK (GMII_GTX_CLK_int),
.GMII_TX_CLK (GMII_TX_CLK),
.GMII_RXD (GMII_RXD[7:0]),
.GMII_RX_CLK (GMII_RX_CLK),
.GMII_RX_DV (GMII_RX_DV),
.GMII_RX_ER (GMII_RX_ER),
.MDIO (MDIO),
.MDC (MDC),
.PHY_INTn (PHY_INTn),
.PHY_RESETn (PHY_RESETn),
.ser_enable (ser_enable),
.ser_prbsen (ser_prbsen),
.ser_loopen (ser_loopen),
.ser_rx_en (ser_rx_en),
.ser_tx_clk (ser_tx_clk_int),
.ser_t (ser_t_unreg[15:0]),
.ser_tklsb (ser_tklsb_unreg),
.ser_tkmsb (ser_tkmsb_unreg),
.ser_rx_clk (ser_rx_clk_buf),
.ser_r (ser_r_int[15:0]),
.ser_rklsb (ser_rklsb_int),
.ser_rkmsb (ser_rkmsb_int),
.cpld_start (cpld_start),
.cpld_mode (cpld_mode),
.cpld_done (cpld_done),
.cpld_din (cpld_din),
.cpld_clk (cpld_clk),
.cpld_detached (cpld_detached),
.cpld_misc (cpld_misc),
.cpld_init_b (cpld_init_b),
.por (~POR),
.config_success (config_success),
.adc_a (adc_a_reg2),
.adc_ovf_a (adc_ovf_a_reg2),
.adc_on_a (adc_on_a),
.adc_oe_a (adc_oe_a),
.adc_b (adc_b_reg2),
.adc_ovf_b (adc_ovf_b_reg2),
.adc_on_b (adc_on_b),
.adc_oe_b (adc_oe_b),
.dac_a (dac_a_int),
.dac_b (dac_b_int),
.scl_pad_i (scl_pad_i),
.scl_pad_o (scl_pad_o),
.scl_pad_oen_o (scl_pad_oen_o),
.sda_pad_i (sda_pad_i),
.sda_pad_o (sda_pad_o),
.sda_pad_oen_o (sda_pad_oen_o),
.clk_en (clk_en[1:0]),
.clk_sel (clk_sel[1:0]),
.clk_func (clk_func),
.clk_status (clk_status),
.sclk (sclk_int),
.mosi (mosi),
.miso (miso),
.sen_clk (sen_clk),
.sen_dac (sen_dac),
.sen_tx_db (sen_tx_db),
.sen_tx_adc (sen_tx_adc),
.sen_tx_dac (sen_tx_dac),
.sen_rx_db (sen_rx_db),
.sen_rx_adc (sen_rx_adc),
.sen_rx_dac (sen_rx_dac),
.io_tx (io_tx[15:0]),
.io_rx (io_rx[15:0]),
.RAM_D_pi (RAM_D_pi),
.RAM_D_po (RAM_D_po),
.RAM_D_poe (RAM_D_poe),
.RAM_A (RAM_A),
.RAM_CE1n (RAM_CE1n),
.RAM_CENn (RAM_CENn),
// .RAM_CLK (RAM_CLK),
.RAM_WEn (RAM_WEn),
.RAM_OEn (RAM_OEn),
.RAM_LDn (RAM_LDn),
.uart_tx_o (uart_tx_o),
.uart_rx_i (uart_rx_i),
.uart_baud_o (),
.sim_mode (1'b0),
.clock_divider (2)
);
endmodule // u2_rev2
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