fpga

//

// Copyright 2011 Ettus Research LLC

//

// 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 <http://www.gnu.org/licenses/>.

//

// ////////////////////////////////////////////////////////////////////////////////

// Module Name:    u2_core

// ////////////////////////////////////////////////////////////////////////////////

module u2plus_core

  (// Clocks

   input dsp_clk,

   input wb_clk,

   output clock_ready,

   input clk_to_mac,

   input pps_in,

   // Misc, debug

   output [7:0] leds,

   output [31:0] debug,

   output [1:0] debug_clk,

   // Expansion

   input exp_time_in,

   output exp_time_out,

   // GMII

   //   GMII-CTRL

   input GMII_COL,

   input GMII_CRS,

   //   GMII-TX

   output [7:0] GMII_TXD,

   output GMII_TX_EN,

   output 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,

   // SERDES

   output ser_enable,

   output ser_prbsen,

   output ser_loopen,

   output ser_rx_en,

   output ser_tx_clk,

   output [15:0] ser_t,

   output ser_tklsb,

   output ser_tkmsb,

   input ser_rx_clk,

   input [15:0] ser_r,

   input ser_rklsb,

   input ser_rkmsb,

   input por,

   output config_success,

   // ADC

   input [13:0] adc_a,

   input adc_ovf_a,

   output adc_on_a,

   output adc_oe_a,

   input [13:0] adc_b,

   input adc_ovf_b,

   output adc_on_b,

   output adc_oe_b,

   // DAC

   output [15:0] dac_a,

   output [15:0] dac_b,

   // I2C

   input scl_pad_i,

   output scl_pad_o,

   output scl_pad_oen_o,

   input sda_pad_i,

   output sda_pad_o,

   output sda_pad_oen_o,

   // 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,

   // Generic SPI

   output sclk,

   output mosi,

   input miso,

   output sen_clk,

   output sen_dac,

   output sen_adc,

   output sen_tx_db,

   output sen_tx_adc,

   output sen_tx_dac,

   output sen_rx_db,

   output sen_rx_adc,

   output sen_rx_dac,

   // GPIO to DBoards

   inout [15:0] io_tx,

   inout [15:0] io_rx,

   // External RAM

   input [35:0] RAM_D_pi,

   output [35:0] RAM_D_po,

   output RAM_D_poe,   

   output [20:0] RAM_A,

   output RAM_CE1n,

   output RAM_CENn,

   output RAM_WEn,

   output RAM_OEn,

   output RAM_LDn,

   // Debug stuff

   output [3:0] uart_tx_o, 

   input [3:0] uart_rx_i,

   output [3:0] uart_baud_o,

   input sim_mode,

   input [3:0] clock_divider,

   input button,

   output spiflash_cs, output spiflash_clk, input spiflash_miso, output spiflash_mosi

   );

   localparam SR_MISC     =   0;   // 7 regs

   localparam SR_SIMTIMER =   8;   // 2

   localparam SR_TIME64   =  10;   // 6

   localparam SR_BUF_POOL =  16;   // 4

   localparam SR_RX_FRONT =  24;   // 5

   localparam SR_RX_CTRL0 =  32;   // 9

   localparam SR_RX_DSP0  =  48;   // 7

   localparam SR_RX_CTRL1 =  80;   // 9

   localparam SR_RX_DSP1  =  96;   // 7

   localparam SR_TX_FRONT = 128;   // ?

   localparam SR_TX_CTRL  = 144;   // 6

   localparam SR_TX_DSP   = 160;   // 5

   localparam SR_UDP_SM   = 192;   // 64

   // FIFO Sizes, 9 = 512 lines, 10 = 1024, 11 = 2048

   // all (most?) are 36 bits wide, so 9 is 1 BRAM, 10 is 2, 11 is 4 BRAMs

   // localparam DSP_TX_FIFOSIZE = 9;  unused -- DSPTX uses extram fifo

   localparam DSP_RX_FIFOSIZE = 10;

   localparam ETH_TX_FIFOSIZE = 9;

   localparam ETH_RX_FIFOSIZE = 11;

   localparam SERDES_TX_FIFOSIZE = 9;

   localparam SERDES_RX_FIFOSIZE = 9;  // RX currently doesn't use a fifo?

   wire [7:0] 	set_addr, set_addr_dsp;

   wire [31:0] 	set_data, set_data_dsp;

   wire 	set_stb, set_stb_dsp;

   reg 		wb_rst; 

   wire 	dsp_rst = wb_rst;

   wire [31:0] 	status;

   wire 	bus_error, spi_int, i2c_int, pps_int, onetime_int, periodic_int, buffer_int;

   wire 	proc_int, overrun0, overrun1, underrun;

   wire [3:0] 	uart_tx_int, uart_rx_int;

   wire [31:0] 	debug_gpio_0, debug_gpio_1;

   wire [31:0] 	debug_rx, debug_mac, debug_mac0, debug_mac1, debug_tx_dsp, debug_txc,

		debug_serdes0, debug_serdes1, debug_serdes2, debug_rx_dsp, debug_udp, debug_extfifo, debug_extfifo2;

   wire [15:0] 	ser_rx_occ, ser_tx_occ, dsp_rx_occ, dsp_tx_occ, eth_rx_occ, eth_tx_occ, eth_rx_occ2;

   wire 	ser_rx_full, ser_tx_full, dsp_rx_full, dsp_tx_full, eth_rx_full, eth_tx_full, eth_rx_full2;

   wire 	ser_rx_empty, ser_tx_empty, dsp_rx_empty, dsp_tx_empty, eth_rx_empty, eth_tx_empty, eth_rx_empty2;

   wire 	serdes_link_up, good_sync;

   wire 	epoch;

   wire [31:0] 	irq;

   wire [63:0] 	vita_time, vita_time_pps;

   wire 	 run_rx0, run_rx1, run_tx;

   reg 		 run_rx0_d1, run_rx1_d1;

   // ///////////////////////////////////////////////////////////////////////////////////////////////

   // Wishbone Single Master INTERCON

   localparam 	dw = 32;  // Data bus width

   localparam 	aw = 16;  // Address bus width, for byte addressibility, 16 = 64K byte memory space

   localparam	sw = 4;   // Select width -- 32-bit data bus with 8-bit granularity.  

   wire [dw-1:0] m0_dat_o, m0_dat_i;

   wire [dw-1:0] s0_dat_o, s1_dat_o, s0_dat_i, s1_dat_i, s2_dat_o, s3_dat_o, s2_dat_i, s3_dat_i,

		 s4_dat_o, s5_dat_o, s4_dat_i, s5_dat_i, s6_dat_o, s7_dat_o, s6_dat_i, s7_dat_i,

		 s8_dat_o, s9_dat_o, s8_dat_i, s9_dat_i, sa_dat_o, sa_dat_i, sb_dat_i, sb_dat_o,

		 sc_dat_i, sc_dat_o, sd_dat_i, sd_dat_o, se_dat_i, se_dat_o, sf_dat_i, sf_dat_o;

   wire [aw-1:0] m0_adr,s0_adr,s1_adr,s2_adr,s3_adr,s4_adr,s5_adr,s6_adr,s7_adr,s8_adr,s9_adr,sa_adr,sb_adr,sc_adr, sd_adr, se_adr, sf_adr;

   wire [sw-1:0] m0_sel,s0_sel,s1_sel,s2_sel,s3_sel,s4_sel,s5_sel,s6_sel,s7_sel,s8_sel,s9_sel,sa_sel,sb_sel,sc_sel, sd_sel, se_sel, sf_sel;

   wire 	 m0_ack,s0_ack,s1_ack,s2_ack,s3_ack,s4_ack,s5_ack,s6_ack,s7_ack,s8_ack,s9_ack,sa_ack,sb_ack,sc_ack, sd_ack, se_ack, sf_ack;

   wire 	 m0_stb,s0_stb,s1_stb,s2_stb,s3_stb,s4_stb,s5_stb,s6_stb,s7_stb,s8_stb,s9_stb,sa_stb,sb_stb,sc_stb, sd_stb, se_stb, sf_stb;

   wire 	 m0_cyc,s0_cyc,s1_cyc,s2_cyc,s3_cyc,s4_cyc,s5_cyc,s6_cyc,s7_cyc,s8_cyc,s9_cyc,sa_cyc,sb_cyc,sc_cyc, sd_cyc, se_cyc, sf_cyc;

   wire 	 m0_err, m0_rty;

   wire 	 m0_we,s0_we,s1_we,s2_we,s3_we,s4_we,s5_we,s6_we,s7_we,s8_we,s9_we,sa_we,sb_we,sc_we,sd_we,se_we,sf_we;

   wb_1master #(.decode_w(8),

		.s0_addr(8'b0000_0000),.s0_mask(8'b1100_0000),  // Main RAM (0-16K)

		.s1_addr(8'b0100_0000),.s1_mask(8'b1111_0000),  // Packet Router (16-20K)

 		.s2_addr(8'b0101_0000),.s2_mask(8'b1111_1100),  // SPI

		.s3_addr(8'b0101_0100),.s3_mask(8'b1111_1100),  // I2C

		.s4_addr(8'b0101_1000),.s4_mask(8'b1111_1100),  // GPIO

		.s5_addr(8'b0101_1100),.s5_mask(8'b1111_1100),  // Readback

		.s6_addr(8'b0110_0000),.s6_mask(8'b1111_0000),  // Ethernet MAC

		.s7_addr(8'b0111_0000),.s7_mask(8'b1111_0000),  // 20K-24K, Settings Bus (only uses 1K)

		.s8_addr(8'b1000_0000),.s8_mask(8'b1111_1100),  // PIC

		.s9_addr(8'b1000_0100),.s9_mask(8'b1111_1100),  // Unused

		.sa_addr(8'b1000_1000),.sa_mask(8'b1111_1100),  // UART

		.sb_addr(8'b1000_1100),.sb_mask(8'b1111_1100),  // ATR

		.sc_addr(8'b1001_0000),.sc_mask(8'b1111_0000),  // Unused

		.sd_addr(8'b1010_0000),.sd_mask(8'b1111_0000),  // ICAP

		.se_addr(8'b1011_0000),.se_mask(8'b1111_0000),  // SPI Flash

		.sf_addr(8'b1100_0000),.sf_mask(8'b1100_0000),  // 48K-64K, Boot RAM

		.dw(dw),.aw(aw),.sw(sw)) wb_1master

     (.clk_i(wb_clk),.rst_i(wb_rst),       

      .m0_dat_o(m0_dat_o),.m0_ack_o(m0_ack),.m0_err_o(m0_err),.m0_rty_o(m0_rty),.m0_dat_i(m0_dat_i),

      .m0_adr_i(m0_adr),.m0_sel_i(m0_sel),.m0_we_i(m0_we),.m0_cyc_i(m0_cyc),.m0_stb_i(m0_stb),

      .s0_dat_o(s0_dat_o),.s0_adr_o(s0_adr),.s0_sel_o(s0_sel),.s0_we_o	(s0_we),.s0_cyc_o(s0_cyc),.s0_stb_o(s0_stb),

      .s0_dat_i(s0_dat_i),.s0_ack_i(s0_ack),.s0_err_i(0),.s0_rty_i(0),

      .s1_dat_o(s1_dat_o),.s1_adr_o(s1_adr),.s1_sel_o(s1_sel),.s1_we_o	(s1_we),.s1_cyc_o(s1_cyc),.s1_stb_o(s1_stb),

      .s1_dat_i(s1_dat_i),.s1_ack_i(s1_ack),.s1_err_i(0),.s1_rty_i(0),

      .s2_dat_o(s2_dat_o),.s2_adr_o(s2_adr),.s2_sel_o(s2_sel),.s2_we_o	(s2_we),.s2_cyc_o(s2_cyc),.s2_stb_o(s2_stb),

      .s2_dat_i(s2_dat_i),.s2_ack_i(s2_ack),.s2_err_i(0),.s2_rty_i(0),

      .s3_dat_o(s3_dat_o),.s3_adr_o(s3_adr),.s3_sel_o(s3_sel),.s3_we_o	(s3_we),.s3_cyc_o(s3_cyc),.s3_stb_o(s3_stb),

      .s3_dat_i(s3_dat_i),.s3_ack_i(s3_ack),.s3_err_i(0),.s3_rty_i(0),

      .s4_dat_o(s4_dat_o),.s4_adr_o(s4_adr),.s4_sel_o(s4_sel),.s4_we_o	(s4_we),.s4_cyc_o(s4_cyc),.s4_stb_o(s4_stb),

      .s4_dat_i(s4_dat_i),.s4_ack_i(s4_ack),.s4_err_i(0),.s4_rty_i(0),

      .s5_dat_o(s5_dat_o),.s5_adr_o(s5_adr),.s5_sel_o(s5_sel),.s5_we_o	(s5_we),.s5_cyc_o(s5_cyc),.s5_stb_o(s5_stb),

      .s5_dat_i(s5_dat_i),.s5_ack_i(s5_ack),.s5_err_i(0),.s5_rty_i(0),

      .s6_dat_o(s6_dat_o),.s6_adr_o(s6_adr),.s6_sel_o(s6_sel),.s6_we_o	(s6_we),.s6_cyc_o(s6_cyc),.s6_stb_o(s6_stb),

      .s6_dat_i(s6_dat_i),.s6_ack_i(s6_ack),.s6_err_i(0),.s6_rty_i(0),

      .s7_dat_o(s7_dat_o),.s7_adr_o(s7_adr),.s7_sel_o(s7_sel),.s7_we_o	(s7_we),.s7_cyc_o(s7_cyc),.s7_stb_o(s7_stb),

      .s7_dat_i(s7_dat_i),.s7_ack_i(s7_ack),.s7_err_i(0),.s7_rty_i(0),

      .s8_dat_o(s8_dat_o),.s8_adr_o(s8_adr),.s8_sel_o(s8_sel),.s8_we_o	(s8_we),.s8_cyc_o(s8_cyc),.s8_stb_o(s8_stb),

      .s8_dat_i(s8_dat_i),.s8_ack_i(s8_ack),.s8_err_i(0),.s8_rty_i(0),

      .s9_dat_o(s9_dat_o),.s9_adr_o(s9_adr),.s9_sel_o(s9_sel),.s9_we_o	(s9_we),.s9_cyc_o(s9_cyc),.s9_stb_o(s9_stb),

      .s9_dat_i(s9_dat_i),.s9_ack_i(s9_ack),.s9_err_i(0),.s9_rty_i(0),

      .sa_dat_o(sa_dat_o),.sa_adr_o(sa_adr),.sa_sel_o(sa_sel),.sa_we_o(sa_we),.sa_cyc_o(sa_cyc),.sa_stb_o(sa_stb),

      .sa_dat_i(sa_dat_i),.sa_ack_i(sa_ack),.sa_err_i(0),.sa_rty_i(0),

      .sb_dat_o(sb_dat_o),.sb_adr_o(sb_adr),.sb_sel_o(sb_sel),.sb_we_o(sb_we),.sb_cyc_o(sb_cyc),.sb_stb_o(sb_stb),

      .sb_dat_i(sb_dat_i),.sb_ack_i(sb_ack),.sb_err_i(0),.sb_rty_i(0),

      .sc_dat_o(sc_dat_o),.sc_adr_o(sc_adr),.sc_sel_o(sc_sel),.sc_we_o(sc_we),.sc_cyc_o(sc_cyc),.sc_stb_o(sc_stb),

      .sc_dat_i(sc_dat_i),.sc_ack_i(sc_ack),.sc_err_i(0),.sc_rty_i(0),

      .sd_dat_o(sd_dat_o),.sd_adr_o(sd_adr),.sd_sel_o(sd_sel),.sd_we_o(sd_we),.sd_cyc_o(sd_cyc),.sd_stb_o(sd_stb),

      .sd_dat_i(sd_dat_i),.sd_ack_i(sd_ack),.sd_err_i(0),.sd_rty_i(0),

      .se_dat_o(se_dat_o),.se_adr_o(se_adr),.se_sel_o(se_sel),.se_we_o(se_we),.se_cyc_o(se_cyc),.se_stb_o(se_stb),

      .se_dat_i(se_dat_i),.se_ack_i(se_ack),.se_err_i(0),.se_rty_i(0),

      .sf_dat_o(sf_dat_o),.sf_adr_o(sf_adr),.sf_sel_o(sf_sel),.sf_we_o(sf_we),.sf_cyc_o(sf_cyc),.sf_stb_o(sf_stb),

      .sf_dat_i(sf_dat_i),.sf_ack_i(sf_ack),.sf_err_i(0),.sf_rty_i(0));

   // ////////////////////////////////////////////////////////////////////////////////////////

   // Reset Controller

   reg 		 cpu_bldr_ctrl_state;

   localparam CPU_BLDR_CTRL_WAIT = 0;

   localparam CPU_BLDR_CTRL_DONE = 1;

   wire 	 bldr_done;

   wire 	 por_rst;

   wire [aw-1:0] cpu_adr;

   // Swap boot ram and main ram when in bootloader mode

   assign m0_adr = (^cpu_adr[15:14] | (cpu_bldr_ctrl_state == CPU_BLDR_CTRL_DONE)) ? cpu_adr :

		   cpu_adr ^ 16'hC000;

   system_control sysctrl 

     (.wb_clk_i(wb_clk), .wb_rst_o(por_rst), .ram_loader_done_i(1'b1) );

   always @(posedge wb_clk)

     if(por_rst) begin

        cpu_bldr_ctrl_state <= CPU_BLDR_CTRL_WAIT;

        wb_rst <= 1'b1;

     end

     else begin

        case(cpu_bldr_ctrl_state)

          CPU_BLDR_CTRL_WAIT: begin

             wb_rst <= 1'b0;

             if (bldr_done == 1'b1) begin //set by the bootloader

                cpu_bldr_ctrl_state <= CPU_BLDR_CTRL_DONE;

                wb_rst <= 1'b1;

             end

          end

          CPU_BLDR_CTRL_DONE: begin //stay here forever

             wb_rst <= 1'b0;

          end

        endcase //cpu_bldr_ctrl_state

     end

   // /////////////////////////////////////////////////////////////////////////

   // Processor

   assign 	 bus_error = m0_err | m0_rty;

   wire [63:0] zpu_status;

   zpu_wb_top #(.dat_w(dw), .adr_w(aw), .sel_w(sw))

     zpu_top0 (.clk(wb_clk), .rst(wb_rst), .enb(~wb_rst),

	   // Data Wishbone bus to system bus fabric

	   .we_o(m0_we),.stb_o(m0_stb),.dat_o(m0_dat_i),.adr_o(cpu_adr),

	   .dat_i(m0_dat_o),.ack_i(m0_ack),.sel_o(m0_sel),.cyc_o(m0_cyc),

	   // Interrupts and exceptions

	   .zpu_status(zpu_status), .interrupt(proc_int & 1'b0));

   // /////////////////////////////////////////////////////////////////////////

   // Dual Ported Boot RAM -- D-Port is Slave #0 on main Wishbone

   // Dual Ported Main RAM -- D-Port is Slave #F on main Wishbone

   // I-port connects directly to processor

   bootram bootram(.clk(wb_clk), .reset(wb_rst),

		   .if_adr(14'b0), .if_data(),

		   .dwb_adr_i(sf_adr[13:0]), .dwb_dat_i(sf_dat_o), .dwb_dat_o(sf_dat_i),

		   .dwb_we_i(sf_we), .dwb_ack_o(sf_ack), .dwb_stb_i(sf_stb), .dwb_sel_i(sf_sel));

////blinkenlights v0.1

//defparam bootram.RAM0.INIT_00=256'hbc32fff0_aa43502b_b00000fe_30630001_80000000_10600000_a48500ff_10a00000;

//defparam bootram.RAM0.INIT_01=256'ha48500ff_b810ffd0_f880200c_30a50001_10830000_308000ff_be23000c_a4640001;

`include "bootloader.rmi"

   ram_harvard2 #(.AWIDTH(14),.RAM_SIZE(16384))

   sys_ram(.wb_clk_i(wb_clk),.wb_rst_i(wb_rst),	     

	   .if_adr(14'b0), .if_data(),

	   .dwb_adr_i(s0_adr[13:0]), .dwb_dat_i(s0_dat_o), .dwb_dat_o(s0_dat_i),

	   .dwb_we_i(s0_we), .dwb_ack_o(s0_ack), .dwb_stb_i(s0_stb), .dwb_sel_i(s0_sel));

   // /////////////////////////////////////////////////////////////////////////

   // Buffer Pool, slave #1

   wire 	 rd0_ready_i, rd0_ready_o;

   wire 	 rd1_ready_i, rd1_ready_o;

   wire 	 rd2_ready_i, rd2_ready_o;

   wire 	 rd3_ready_i, rd3_ready_o;

   wire [35:0] 	 rd0_dat, rd1_dat, rd2_dat, rd3_dat;

   wire 	 wr0_ready_i, wr0_ready_o;

   wire 	 wr1_ready_i, wr1_ready_o;

   wire 	 wr2_ready_i, wr2_ready_o;

   wire 	 wr3_ready_i, wr3_ready_o;

   wire [35:0] 	 wr0_dat, wr1_dat, wr2_dat, wr3_dat;

   wire [35:0] 	 tx_err_data;

   wire 	 tx_err_src_rdy, tx_err_dst_rdy;

   wire [31:0] router_debug;

   packet_router #(.BUF_SIZE(9), .UDP_BASE(SR_UDP_SM), .CTRL_BASE(SR_BUF_POOL)) packet_router

     (.wb_clk_i(wb_clk),.wb_rst_i(wb_rst),

      .wb_we_i(s1_we),.wb_stb_i(s1_stb),.wb_adr_i(s1_adr),.wb_dat_i(s1_dat_o),

      .wb_dat_o(s1_dat_i),.wb_ack_o(s1_ack),.wb_err_o(),.wb_rty_o(),

      .set_stb(set_stb_dsp), .set_addr(set_addr_dsp), .set_data(set_data_dsp),

      .stream_clk(dsp_clk), .stream_rst(dsp_rst), .stream_clr(1'b0),

      .status(status), .sys_int_o(buffer_int), .debug(router_debug),

      .ser_inp_data(wr0_dat), .ser_inp_valid(wr0_ready_i), .ser_inp_ready(wr0_ready_o),

      .dsp0_inp_data(wr1_dat), .dsp0_inp_valid(wr1_ready_i), .dsp0_inp_ready(wr1_ready_o),

      .dsp1_inp_data(wr3_dat), .dsp1_inp_valid(wr3_ready_i), .dsp1_inp_ready(wr3_ready_o),

      .eth_inp_data(wr2_dat), .eth_inp_valid(wr2_ready_i), .eth_inp_ready(wr2_ready_o),

      .err_inp_data(tx_err_data), .err_inp_ready(tx_err_dst_rdy), .err_inp_valid(tx_err_src_rdy),

      .ser_out_data(rd0_dat), .ser_out_valid(rd0_ready_o), .ser_out_ready(rd0_ready_i),

      .dsp_out_data(rd1_dat), .dsp_out_valid(rd1_ready_o), .dsp_out_ready(rd1_ready_i),

      .eth_out_data(rd2_dat), .eth_out_valid(rd2_ready_o), .eth_out_ready(rd2_ready_i)

      );

   // /////////////////////////////////////////////////////////////////////////

   // SPI -- Slave #2

   spi_top shared_spi

     (.wb_clk_i(wb_clk),.wb_rst_i(wb_rst),.wb_adr_i(s2_adr[4:0]),.wb_dat_i(s2_dat_o),

      .wb_dat_o(s2_dat_i),.wb_sel_i(s2_sel),.wb_we_i(s2_we),.wb_stb_i(s2_stb),

      .wb_cyc_i(s2_cyc),.wb_ack_o(s2_ack),.wb_err_o(),.wb_int_o(spi_int),

      .ss_pad_o({sen_adc, sen_tx_db,sen_tx_adc,sen_tx_dac,sen_rx_db,sen_rx_adc,sen_rx_dac,sen_dac,sen_clk}),

      .sclk_pad_o(sclk),.mosi_pad_o(mosi),.miso_pad_i(miso) );

   // /////////////////////////////////////////////////////////////////////////

   // I2C -- Slave #3

   i2c_master_top #(.ARST_LVL(1)) 

     i2c (.wb_clk_i(wb_clk),.wb_rst_i(wb_rst),.arst_i(1'b0), 

	  .wb_adr_i(s3_adr[4:2]),.wb_dat_i(s3_dat_o[7:0]),.wb_dat_o(s3_dat_i[7:0]),

	  .wb_we_i(s3_we),.wb_stb_i(s3_stb),.wb_cyc_i(s3_cyc),

	  .wb_ack_o(s3_ack),.wb_inta_o(i2c_int),

	  .scl_pad_i(scl_pad_i),.scl_pad_o(scl_pad_o),.scl_padoen_o(scl_pad_oen_o),

	  .sda_pad_i(sda_pad_i),.sda_pad_o(sda_pad_o),.sda_padoen_o(sda_pad_oen_o) );

   assign 	 s3_dat_i[31:8] = 24'd0;

   // /////////////////////////////////////////////////////////////////////////

   // GPIOs -- Slave #4

   nsgpio nsgpio(.clk_i(wb_clk),.rst_i(wb_rst),

		 .cyc_i(s4_cyc),.stb_i(s4_stb),.adr_i(s4_adr[4:0]),.we_i(s4_we),

		 .dat_i(s4_dat_o),.dat_o(s4_dat_i),.ack_o(s4_ack),

		 .rx(run_rx0_d1 | rx_rx1_d1), .tx(run_tx), .gpio({io_tx,io_rx}) );

   // /////////////////////////////////////////////////////////////////////////

   // Buffer Pool Status -- Slave #5   

   //compatibility number -> increment when the fpga has been sufficiently altered

   localparam compat_num = {16'd7, 16'd1}; //major, minor

   wb_readback_mux buff_pool_status

     (.wb_clk_i(wb_clk), .wb_rst_i(wb_rst), .wb_stb_i(s5_stb),

      .wb_adr_i(s5_adr), .wb_dat_o(s5_dat_i), .wb_ack_o(s5_ack),

      .word00(32'b0),.word01(32'b0),.word02(32'b0),.word03(32'b0),

      .word04(32'b0),.word05(32'b0),.word06(32'b0),.word07(32'b0),

      .word08(status),.word09({sim_mode,27'b0,clock_divider[3:0]}),.word10(vita_time[63:32]),

      .word11(vita_time[31:0]),.word12(compat_num),.word13(irq),

      .word14(vita_time_pps[63:32]),.word15(vita_time_pps[31:0])

      );

   // /////////////////////////////////////////////////////////////////////////

   // Ethernet MAC  Slave #6

   simple_gemac_wrapper #(.RXFIFOSIZE(ETH_RX_FIFOSIZE), 

			  .TXFIFOSIZE(ETH_TX_FIFOSIZE)) simple_gemac_wrapper

     (.clk125(clk_to_mac),  .reset(wb_rst),

      .GMII_GTX_CLK(GMII_GTX_CLK), .GMII_TX_EN(GMII_TX_EN),  

      .GMII_TX_ER(GMII_TX_ER), .GMII_TXD(GMII_TXD),

      .GMII_RX_CLK(GMII_RX_CLK), .GMII_RX_DV(GMII_RX_DV),  

      .GMII_RX_ER(GMII_RX_ER), .GMII_RXD(GMII_RXD),

      .sys_clk(dsp_clk),

      .rx_f36_data(wr2_dat), .rx_f36_src_rdy(wr2_ready_i), .rx_f36_dst_rdy(wr2_ready_o),

      .tx_f36_data(rd2_dat), .tx_f36_src_rdy(rd2_ready_o), .tx_f36_dst_rdy(rd2_ready_i),

      .wb_clk(wb_clk), .wb_rst(wb_rst), .wb_stb(s6_stb), .wb_cyc(s6_cyc), .wb_ack(s6_ack),

      .wb_we(s6_we), .wb_adr(s6_adr), .wb_dat_i(s6_dat_o), .wb_dat_o(s6_dat_i),

      .mdio(MDIO), .mdc(MDC),

      .debug(debug_mac));

   // /////////////////////////////////////////////////////////////////////////

   // Settings Bus -- Slave #7

   settings_bus settings_bus

     (.wb_clk(wb_clk),.wb_rst(wb_rst),.wb_adr_i(s7_adr),.wb_dat_i(s7_dat_o),

      .wb_stb_i(s7_stb),.wb_we_i(s7_we),.wb_ack_o(s7_ack),

      .strobe(set_stb),.addr(set_addr),.data(set_data));

   assign 	 s7_dat_i = 32'd0;

   settings_bus_crossclock settings_bus_crossclock

     (.clk_i(wb_clk), .rst_i(wb_rst), .set_stb_i(set_stb), .set_addr_i(set_addr), .set_data_i(set_data),

      .clk_o(dsp_clk), .rst_o(dsp_rst), .set_stb_o(set_stb_dsp), .set_addr_o(set_addr_dsp), .set_data_o(set_data_dsp));

   // Output control lines

   wire [7:0] 	 clock_outs, serdes_outs, adc_outs;

   assign 	 {clock_ready, clk_en[1:0], clk_sel[1:0]} = clock_outs[4:0];

   assign 	 {ser_enable, ser_prbsen, ser_loopen, ser_rx_en} = serdes_outs[3:0];

   assign 	 {adc_oe_a, adc_on_a, adc_oe_b, adc_on_b } = adc_outs[3:0];

   wire 	 phy_reset;

   assign 	 PHY_RESETn = ~phy_reset;

   setting_reg #(.my_addr(SR_MISC+0),.width(8)) sr_clk (.clk(wb_clk),.rst(wb_rst),.strobe(s7_ack),.addr(set_addr),

				      .in(set_data),.out(clock_outs),.changed());

   setting_reg #(.my_addr(SR_MISC+1),.width(8)) sr_ser (.clk(wb_clk),.rst(wb_rst),.strobe(set_stb),.addr(set_addr),

				      .in(set_data),.out(serdes_outs),.changed());

   setting_reg #(.my_addr(SR_MISC+2),.width(8)) sr_adc (.clk(wb_clk),.rst(wb_rst),.strobe(set_stb),.addr(set_addr),

				      .in(set_data),.out(adc_outs),.changed());

   setting_reg #(.my_addr(SR_MISC+4),.width(1)) sr_phy (.clk(wb_clk),.rst(wb_rst),.strobe(set_stb),.addr(set_addr),

				      .in(set_data),.out(phy_reset),.changed());

   setting_reg #(.my_addr(SR_MISC+5),.width(1)) sr_bld (.clk(wb_clk),.rst(wb_rst),.strobe(set_stb),.addr(set_addr),

				      .in(set_data),.out(bldr_done),.changed());

   // /////////////////////////////////////////////////////////////////////////

   //  LEDS

   //    register 8 determines whether leds are controlled by SW or not

   //    1 = controlled by HW, 0 = by SW

   //    In Rev3 there are only 6 leds, and the highest one is on the ETH connector

   wire [7:0] 	 led_src, led_sw;

   wire [7:0] 	 led_hw = {run_tx, (run_rx0_d1 | run_rx1_d1), clk_status, serdes_link_up & good_sync, 1'b0};

   setting_reg #(.my_addr(SR_MISC+3),.width(8)) sr_led (.clk(wb_clk),.rst(wb_rst),.strobe(set_stb),.addr(set_addr),

				      .in(set_data),.out(led_sw),.changed());

   setting_reg #(.my_addr(SR_MISC+6),.width(8), .at_reset(8'b0001_1110)) 

   sr_led_src (.clk(wb_clk),.rst(wb_rst), .strobe(set_stb),.addr(set_addr), .in(set_data),.out(led_src),.changed());

   assign 	 leds = (led_src & led_hw) | (~led_src & led_sw);

   // /////////////////////////////////////////////////////////////////////////

   // Interrupt Controller, Slave #8

   // Pass interrupts on dsp_clk to wb_clk.  These need edge triggering in the pic

   wire 	 underrun_wb, overrun_wb, pps_wb;

   oneshot_2clk underrun_1s (.clk_in(dsp_clk), .in(underrun), .clk_out(wb_clk), .out(underrun_wb));

   oneshot_2clk overrun_1s (.clk_in(dsp_clk), .in(overrun0 | overrun1), .clk_out(wb_clk), .out(overrun_wb));

   oneshot_2clk pps_1s (.clk_in(dsp_clk), .in(pps_int), .clk_out(wb_clk), .out(pps_wb));

   assign irq= {{8'b0},

		{uart_tx_int[3:0], uart_rx_int[3:0]},

		{2'b0, button, periodic_int, clk_status, serdes_link_up, 2'b00},

		{pps_wb,overrun_wb,underrun_wb,PHY_INTn,i2c_int,spi_int,onetime_int,buffer_int}};

   pic pic(.clk_i(wb_clk),.rst_i(wb_rst),.cyc_i(s8_cyc),.stb_i(s8_stb),.adr_i(s8_adr[4:2]),

	   .we_i(s8_we),.dat_i(s8_dat_o),.dat_o(s8_dat_i),.ack_o(s8_ack),.int_o(proc_int),

	   .irq(irq) );

   // /////////////////////////////////////////////////////////////////////////

   // Master Timer, Slave #9

   // No longer used, replaced with simple_timer below

   assign s9_ack = 0;

   // /////////////////////////////////////////////////////////////////////////

   //  Simple Timer interrupts

   /*

   simple_timer #(.BASE(SR_SIMTIMER)) simple_timer

     (.clk(wb_clk), .reset(wb_rst),

      .set_stb(set_stb), .set_addr(set_addr), .set_data(set_data),

      .onetime_int(onetime_int), .periodic_int(periodic_int));

   */

   // /////////////////////////////////////////////////////////////////////////

   // UART, Slave #10

   quad_uart #(.TXDEPTH(3),.RXDEPTH(3)) uart  // depth of 3 is 128 entries

     (.clk_i(wb_clk),.rst_i(wb_rst),

      .we_i(sa_we),.stb_i(sa_stb),.cyc_i(sa_cyc),.ack_o(sa_ack),

      .adr_i(sa_adr[6:2]),.dat_i(sa_dat_o),.dat_o(sa_dat_i),

      .rx_int_o(uart_rx_int),.tx_int_o(uart_tx_int),

      .tx_o(uart_tx_o),.rx_i(uart_rx_i),.baud_o(uart_baud_o));

   // /////////////////////////////////////////////////////////////////////////

   // ATR Controller, Slave #11

   /*

   atr_controller atr_controller

     (.clk_i(wb_clk),.rst_i(wb_rst),

      .adr_i(sb_adr[5:0]),.sel_i(sb_sel),.dat_i(sb_dat_o),.dat_o(sb_dat_i),

      .we_i(sb_we),.stb_i(sb_stb),.cyc_i(sb_cyc),.ack_o(sb_ack),

      .run_rx(run_rx0_d1 | run_rx1_d1),.run_tx(run_tx),.ctrl_lines(atr_lines) );

   */

   // //////////////////////////////////////////////////////////////////////////

   // Time Sync, Slave #12 

   // No longer used, see time_64bit.  Still need to handle mimo time, though

   assign sc_ack = 0;

   // /////////////////////////////////////////////////////////////////////////

   // ICAP for reprogramming the FPGA, Slave #13 (D)

   s3a_icap_wb s3a_icap_wb

     (.clk(wb_clk), .reset(wb_rst), .cyc_i(sd_cyc), .stb_i(sd_stb),

      .we_i(sd_we), .ack_o(sd_ack), .dat_i(sd_dat_o), .dat_o(sd_dat_i));

   // /////////////////////////////////////////////////////////////////////////

   // SPI for Flash -- Slave #14 (E)

   spi_top flash_spi

     (.wb_clk_i(wb_clk),.wb_rst_i(wb_rst),.wb_adr_i(se_adr[4:0]),.wb_dat_i(se_dat_o),

      .wb_dat_o(se_dat_i),.wb_sel_i(se_sel),.wb_we_i(se_we),.wb_stb_i(se_stb),

      .wb_cyc_i(se_cyc),.wb_ack_o(se_ack),.wb_err_o(se_err),.wb_int_o(spiflash_int),

      .ss_pad_o(spiflash_cs),

      .sclk_pad_o(spiflash_clk),.mosi_pad_o(spiflash_mosi),.miso_pad_i(spiflash_miso) );

   // /////////////////////////////////////////////////////////////////////////

   // ADC Frontend

   wire [23:0] 	 adc_i, adc_q;

   rx_frontend #(.BASE(SR_RX_FRONT)) rx_frontend

     (.clk(dsp_clk),.rst(dsp_rst),

      .set_stb(set_stb_dsp),.set_addr(set_addr_dsp),.set_data(set_data_dsp),

      .adc_a({adc_a,2'b00}),.adc_ovf_a(adc_ovf_a),

      .adc_b({adc_b,2'b00}),.adc_ovf_b(adc_ovf_b),

      .i_out(adc_i), .q_out(adc_q), .run(run_rx0_d1 | run_rx1_d1), .debug());

   // /////////////////////////////////////////////////////////////////////////

   // DSP RX 0

   wire [31:0] 	 sample_rx0;

   wire 	 clear_rx0, strobe_rx0;

   always @(posedge dsp_clk)

     run_rx0_d1 <= run_rx0;

   dsp_core_rx #(.BASE(SR_RX_DSP0)) dsp_core_rx0

     (.clk(dsp_clk),.rst(dsp_rst),

      .set_stb(set_stb_dsp),.set_addr(set_addr_dsp),.set_data(set_data_dsp),

      .adc_i(adc_i),.adc_ovf_i(adc_ovf_a),.adc_q(adc_q),.adc_ovf_q(adc_ovf_b),

      .sample(sample_rx0), .run(run_rx0_d1), .strobe(strobe_rx0),

      .debug() );

   setting_reg #(.my_addr(SR_RX_CTRL0+3)) sr_clear_rx0

     (.clk(dsp_clk),.rst(dsp_rst),

      .strobe(set_stb_dsp),.addr(set_addr_dsp),.in(set_data_dsp),

      .out(),.changed(clear_rx0));

   vita_rx_chain #(.BASE(SR_RX_CTRL0),.UNIT(0),.FIFOSIZE(DSP_RX_FIFOSIZE)) vita_rx_chain0

     (.clk(dsp_clk), .reset(dsp_rst), .clear(clear_rx0),

      .set_stb(set_stb_dsp),.set_addr(set_addr_dsp),.set_data(set_data_dsp),

      .vita_time(vita_time), .overrun(overrun0),

      .sample(sample_rx0), .run(run_rx0), .strobe(strobe_rx0),

      .rx_data_o(wr1_dat), .rx_src_rdy_o(wr1_ready_i), .rx_dst_rdy_i(wr1_ready_o),

      .debug() );

   // /////////////////////////////////////////////////////////////////////////

   // DSP RX 1

   wire [31:0] 	 sample_rx1;

   wire 	 clear_rx1, strobe_rx1;

   always @(posedge dsp_clk)

     run_rx1_d1 <= run_rx1;

   dsp_core_rx #(.BASE(SR_RX_DSP1)) dsp_core_rx1

     (.clk(dsp_clk),.rst(dsp_rst),

      .set_stb(set_stb_dsp),.set_addr(set_addr_dsp),.set_data(set_data_dsp),

      .adc_i(adc_i),.adc_ovf_i(adc_ovf_a),.adc_q(adc_q),.adc_ovf_q(adc_ovf_b),

      .sample(sample_rx1), .run(run_rx1_d1), .strobe(strobe_rx1),

      .debug() );

   setting_reg #(.my_addr(SR_RX_CTRL1+3)) sr_clear_rx1

     (.clk(dsp_clk),.rst(dsp_rst),

      .strobe(set_stb_dsp),.addr(set_addr_dsp),.in(set_data_dsp),

      .out(),.changed(clear_rx1));

   vita_rx_chain #(.BASE(SR_RX_CTRL1),.UNIT(2),.FIFOSIZE(DSP_RX_FIFOSIZE)) vita_rx_chain1

     (.clk(dsp_clk), .reset(dsp_rst), .clear(clear_rx1),

      .set_stb(set_stb_dsp),.set_addr(set_addr_dsp),.set_data(set_data_dsp),

      .vita_time(vita_time), .overrun(overrun1),

      .sample(sample_rx1), .run(run_rx1), .strobe(strobe_rx1),

      .rx_data_o(wr3_dat), .rx_src_rdy_o(wr3_ready_i), .rx_dst_rdy_i(wr3_ready_o),

      .debug() );

   // ///////////////////////////////////////////////////////////////////////////////////

   // DSP TX

   wire [35:0] 	 tx_data;

   wire 	 tx_src_rdy, tx_dst_rdy;

   wire [31:0] 	 debug_vt;

   wire 	 clear_tx;

   setting_reg #(.my_addr(SR_TX_CTRL+1)) sr_clear_tx

     (.clk(clk),.rst(rst),.strobe(set_stb),.addr(set_addr),

      .in(set_data),.out(),.changed(clear_tx));

   assign 	 RAM_A[20:18] = 3'b0;

   ext_fifo #(.EXT_WIDTH(36),.INT_WIDTH(36),.RAM_DEPTH(18),.FIFO_DEPTH(18)) 

     ext_fifo_i1

       (.int_clk(dsp_clk),

	.ext_clk(dsp_clk),

	.rst(dsp_rst | clear_tx),

	.RAM_D_pi(RAM_D_pi),

	.RAM_D_po(RAM_D_po),

	.RAM_D_poe(RAM_D_poe),

	.RAM_A(RAM_A[17:0]),

	.RAM_WEn(RAM_WEn),

	.RAM_CENn(RAM_CENn),

	.RAM_LDn(RAM_LDn),

	.RAM_OEn(RAM_OEn),

	.RAM_CE1n(RAM_CE1n),

	.datain(rd1_dat),

	.src_rdy_i(rd1_ready_o),

	.dst_rdy_o(rd1_ready_i),

	.dataout(tx_data),

	.src_rdy_o(tx_src_rdy),

	.dst_rdy_i(tx_dst_rdy),

	.debug(debug_extfifo),

	.debug2(debug_extfifo2) );

   wire [23:0] 	 tx_i, tx_q;

   vita_tx_chain #(.BASE_CTRL(SR_TX_CTRL), .BASE_DSP(SR_TX_DSP), 

		   .REPORT_ERROR(1), .DO_FLOW_CONTROL(1),

		   .PROT_ENG_FLAGS(1), .USE_TRANS_HEADER(1),

		   .DSP_NUMBER(0))

   vita_tx_chain

     (.clk(dsp_clk), .reset(dsp_rst),

      .set_stb(set_stb_dsp),.set_addr(set_addr_dsp),.set_data(set_data_dsp),

      .vita_time(vita_time),

      .tx_data_i(tx_data), .tx_src_rdy_i(tx_src_rdy), .tx_dst_rdy_o(tx_dst_rdy),

      .err_data_o(tx_err_data), .err_src_rdy_o(tx_err_src_rdy), .err_dst_rdy_i(tx_err_dst_rdy),

      .tx_i(tx_i),.tx_q(tx_q),

      .underrun(underrun), .run(run_tx),

      .debug(debug_vt));

   tx_frontend #(.BASE(SR_TX_FRONT)) tx_frontend

     (.clk(dsp_clk), .rst(dsp_rst),

      .set_stb(set_stb_dsp),.set_addr(set_addr_dsp),.set_data(set_data_dsp),

      .tx_i(tx_i), .tx_q(tx_q), .run(1'b1),

      .dac_a(dac_a), .dac_b(dac_b));

   // ///////////////////////////////////////////////////////////////////////////////////

   // SERDES

   serdes #(.TXFIFOSIZE(SERDES_TX_FIFOSIZE),.RXFIFOSIZE(SERDES_RX_FIFOSIZE)) serdes

     (.clk(dsp_clk),.rst(dsp_rst),

      .ser_tx_clk(ser_tx_clk),.ser_t(ser_t),.ser_tklsb(ser_tklsb),.ser_tkmsb(ser_tkmsb),

      .rd_dat_i(rd0_dat[31:0]),.rd_flags_i(rd0_dat[35:32]),.rd_ready_o(rd0_ready_i),.rd_ready_i(rd0_ready_o),

      .ser_rx_clk(ser_rx_clk),.ser_r(ser_r),.ser_rklsb(ser_rklsb),.ser_rkmsb(ser_rkmsb),

      .wr_dat_o(wr0_dat[31:0]),.wr_flags_o(wr0_dat[35:32]),.wr_ready_o(wr0_ready_i),.wr_ready_i(wr0_ready_o),

      .tx_occupied(ser_tx_occ),.tx_full(ser_tx_full),.tx_empty(ser_tx_empty),

      .rx_occupied(ser_rx_occ),.rx_full(ser_rx_full),.rx_empty(ser_rx_empty),

      .serdes_link_up(serdes_link_up),.debug0(debug_serdes0), .debug1(debug_serdes1) );

   // /////////////////////////////////////////////////////////////////////////

   // VITA Timing

   wire [31:0] 	 debug_sync;

   time_64bit #(.TICKS_PER_SEC(32'd100000000),.BASE(SR_TIME64)) time_64bit

     (.clk(dsp_clk), .rst(dsp_rst), .set_stb(set_stb_dsp), .set_addr(set_addr_dsp), .set_data(set_data_dsp),

      .pps(pps_in), .vita_time(vita_time), .vita_time_pps(vita_time_pps), .pps_int(pps_int),

      .exp_time_in(exp_time_in), .exp_time_out(exp_time_out), .good_sync(good_sync), .debug(debug_sync));

   // /////////////////////////////////////////////////////////////////////////////////////////

   // Debug Pins

   assign debug_clk = 2'b00; // {dsp_clk, clk_to_mac};

   assign debug = 32'd0;

   assign debug_gpio_0 = 32'd0;

   assign debug_gpio_1 = 32'd0;

endmodule // u2_core