path: root/fpga/usrp3/top/x300/radio.v

// radio top level module
//  Contains all clock-rate DSP components, all radio and hardware controls and settings
//  Communication with outside world is exclusively via a single in/out axi cvita port
//  Paths are separated by the lower 2 bits of stream ID, as follows:
//
//     SID[1:0]   IN                                 OUT
//       0        Transmit Data           (DATA)     Transmit Flow Control, ACK/Error  (CTXT)
//       1        Control (SPI, settings) (CTXT)     Response (readback)               (CTXT)
//       2        Receive Flow Control    (CTXT)     Receive Data                      (DATA)
//       3        Receive Commands        (CTXT)     Receive Command ACK/ERROR         (CTXT)

module radio
  #(
    parameter CHIPSCOPE = 0,
    parameter DELETE_DSP = 0
    )
  (input radio_clk, input radio_rst,
   input [31:0] rx, output [31:0] tx,
   inout [31:0] db_gpio,
   inout [31:0] fp_gpio,
   output [7:0] sen, output sclk, output mosi, input miso,
   output [7:0] misc_outs, output [2:0] leds,

   input bus_clk, input bus_rst,
   input [63:0] in_tdata, input in_tlast, input in_tvalid, output in_tready,
   output [63:0] out_tdata, output out_tlast, output out_tvalid, input out_tready,
   input [63:0] tx_tdata_bi, input tx_tlast_bi, input tx_tvalid_bi, output tx_tready_bi,
   output [63:0] tx_tdata_bo, output tx_tlast_bo, output tx_tvalid_bo, input tx_tready_bo,

   input pps,
   output sync_dacs,
   
   output [31:0] debug
   );

   // ///////////////////////////////////////////////////////////////////////////////
   // FIFO Interfacing to the bus clk domain
   // in_tdata splits to tx_tdata and ctrl_tdata
   // rx_tdata and resp_tdata get muxed to out_tdata
   // Everything except rx flow control must cross in to radio_clk domain before further use
   // _b signifies bus_clk domain, _r signifies radio_clk domain, _b_fc is bus_clk domain, post flow control

   wire [63:0] 	 ctrl_tdata_b, ctrl_tdata_r;
   wire 	 ctrl_tready_b, ctrl_tready_r, ctrl_tvalid_b, ctrl_tvalid_r;
   wire 	 ctrl_tlast_b, ctrl_tlast_r;
 
   wire [63:0] 	  ctrl_tdata_s_r;
   wire 	  ctrl_tready_s_r,  ctrl_tvalid_s_r;
   wire 	  ctrl_tlast_s_r;
   
   wire [63:0] 	 resp_tdata_b, resp_tdata_r;
   wire 	 resp_tready_b, resp_tready_r, resp_tvalid_b, resp_tvalid_r;
   wire 	 resp_tlast_b, resp_tlast_r;

   wire [63:0] 	 rx_tdata_b, rx_tdata_b_fc, rx_tdata_r;
   wire 	 rx_tready_b, rx_tready_b_fc, rx_tready_r, rx_tvalid_b, rx_tvalid_b_fc, rx_tvalid_r;
   wire 	 rx_tlast_b, rx_tlast_b_fc, rx_tlast_r;

   // IJB. _b signals now unused since adding DRAM FIFO.
   wire [63:0] 	 tx_tdata_b, tx_tdata_r;
   wire 	 tx_tready_b, tx_tready_r, tx_tvalid_b, tx_tvalid_r;
   wire 	 tx_tlast_b, tx_tlast_r;

   wire [63:0] 	 txresp_tdata_b, txresp_tdata_r;
   wire 	 txresp_tready_b, txresp_tready_r, txresp_tvalid_b, txresp_tvalid_r;
   wire 	 txresp_tlast_b, txresp_tlast_r;

   wire [63:0] 	 rxfc_tdata_b;
   wire 	 rxfc_tready_b, rxfc_tvalid_b, rxfc_tlast_b;

    wire [63:0] 	 rx_mux_tdata_r;
   wire 	 rx_mux_tready_r, rx_mux_tvalid_r;
   wire 	 rx_mux_tlast_r;

   wire [63:0] 	 rx_err_tdata_r;
   wire 	 rx_err_tready_r, rx_err_tvalid_r;
   wire 	 rx_err_tlast_r;
   //IJB debug
   wire [63:0] 	 tx_tdata_bo_debug;
   wire 	 tx_tlast_bo_debug, tx_tvalid_bo_debug, tx_tready_bo_debug;


   axi_mux4 #(.PRIO(0), .WIDTH(64), .BUFFER(1)) radio_mux
     (.clk(bus_clk), .reset(bus_rst), .clear(1'b0),
      .i0_tdata(txresp_tdata_b), .i0_tlast(txresp_tlast_b), .i0_tvalid(txresp_tvalid_b), .i0_tready(txresp_tready_b), // TX Flow Control/ACK
      .i1_tdata(resp_tdata_b), .i1_tlast(resp_tlast_b), .i1_tvalid(resp_tvalid_b), .i1_tready(resp_tready_b), // Control Response
      .i2_tdata(rx_tdata_b_fc), .i2_tlast(rx_tlast_b_fc), .i2_tvalid(rx_tvalid_b_fc), .i2_tready(rx_tready_b_fc), // RX Data
      .i3_tdata(), .i3_tlast(), .i3_tvalid(1'b0), .i3_tready(),   // RX Command ACK/ERR
      .o_tdata(out_tdata), .o_tlast(out_tlast), .o_tvalid(out_tvalid), .o_tready(out_tready));

   wire [63:0] 	 vheader;
   wire [1:0] 	 vdest = vheader[1:0];  // Switch by bottom 2 bits of SID

   axi_demux4 #(.ACTIVE_CHAN(4'b0111), .WIDTH(64)) radio_demux
     (.clk(bus_clk), .reset(bus_rst), .clear(1'b0),
      .header(vheader), .dest(vdest),
      .i_tdata(in_tdata), .i_tlast(in_tlast), .i_tvalid(in_tvalid), .i_tready(in_tready),
      .o0_tdata(tx_tdata_bo), .o0_tlast(tx_tlast_bo), .o0_tvalid(tx_tvalid_bo), .o0_tready(tx_tready_bo),  // TX Data
      .o1_tdata(ctrl_tdata_b), .o1_tlast(ctrl_tlast_b), .o1_tvalid(ctrl_tvalid_b), .o1_tready(ctrl_tready_b),  // Control
      .o2_tdata(rxfc_tdata_b), .o2_tlast(rxfc_tlast_b), .o2_tvalid(rxfc_tvalid_b), .o2_tready(rxfc_tready_b), // RX Flow Control
      .o3_tdata(), .o3_tlast(), .o3_tvalid(), .o3_tready(1'b1)); // RX Command

   axi_fifo_2clk #(.WIDTH(65), .SIZE(9)) ctrl_fifo
     (.reset(bus_rst),
      .i_aclk(bus_clk), .i_tvalid(ctrl_tvalid_b), .i_tready(ctrl_tready_b), .i_tdata({ctrl_tlast_b,ctrl_tdata_b}),
      .o_aclk(radio_clk), .o_tvalid(ctrl_tvalid_s_r), .o_tready(ctrl_tready_s_r), .o_tdata({ctrl_tlast_s_r,ctrl_tdata_s_r}));

   // For timing closure ..paths lead back from 64bit time comparison.
   axi_fifo_short #(.WIDTH(65)) ctrl_fifo_s
     (
      .clk(radio_clk), .reset(radio_rst), .clear(1'b0),
      .i_tdata({ctrl_tlast_s_r,ctrl_tdata_s_r}), .i_tvalid(ctrl_tvalid_s_r), .i_tready(ctrl_tready_s_r),
      .o_tdata({ctrl_tlast_r,ctrl_tdata_r}), .o_tvalid(ctrl_tvalid_r), .o_tready(ctrl_tready_r),
      .space(), .occupied()
      );

   axi_fifo_2clk #(.WIDTH(65), .SIZE(13)) tx_fifo
     (.reset(bus_rst),
      .i_aclk(bus_clk), .i_tvalid(tx_tvalid_bi), .i_tready(tx_tready_bi), .i_tdata({tx_tlast_bi,tx_tdata_bi}),
      .o_aclk(radio_clk), .o_tvalid(tx_tvalid_r), .o_tready(tx_tready_r), .o_tdata({tx_tlast_r,tx_tdata_r}));

   axi_fifo_2clk #(.WIDTH(65), .SIZE(9)) resp_fifo
     (.reset(radio_rst),
      .i_aclk(radio_clk), .i_tvalid(resp_tvalid_r), .i_tready(resp_tready_r), .i_tdata({resp_tlast_r,resp_tdata_r}),
      .o_aclk(bus_clk), .o_tvalid(resp_tvalid_b), .o_tready(resp_tready_b), .o_tdata({resp_tlast_b,resp_tdata_b}));

   axi_fifo_2clk #(.WIDTH(65), .SIZE(10)) rx_fifo
     (.reset(radio_rst),
      .i_aclk(radio_clk), .i_tvalid(rx_mux_tvalid_r), .i_tready(rx_mux_tready_r), .i_tdata({rx_mux_tlast_r,rx_mux_tdata_r}),
      .o_aclk(bus_clk), .o_tvalid(rx_tvalid_b), .o_tready(rx_tready_b), .o_tdata({rx_tlast_b,rx_tdata_b}));

   axi_fifo_2clk #(.WIDTH(65), .SIZE(9)) txresp_fifo
     (.reset(radio_rst),
      .i_aclk(radio_clk), .i_tvalid(txresp_tvalid_r), .i_tready(txresp_tready_r), .i_tdata({txresp_tlast_r,txresp_tdata_r}),
      .o_aclk(bus_clk), .o_tvalid(txresp_tvalid_b), .o_tready(txresp_tready_b), .o_tdata({txresp_tlast_b,txresp_tdata_b}));

   // /////////////////////////////////////////////////////////////////////////////////////
   // Setting bus and controls
   localparam SR_DACSYNC   = 8'd5;
   localparam SR_LOOPBACK  = 8'd6;
   localparam SR_TEST      = 8'd7;
   localparam SR_SPI       = 8'd8;
   localparam SR_GPIO      = 8'd16;
   localparam SR_MISC_OUTS = 8'd24;
   localparam SR_READBACK  = 8'd32;
   localparam SR_TX_CTRL   = 8'd64;
   localparam SR_RX_CTRL   = 8'd96;
   localparam SR_TIME      = 8'd128;
   localparam SR_RX_DSP    = 8'd144;
   localparam SR_TX_DSP    = 8'd184;
   localparam SR_LEDS      = 8'd196;
   localparam SR_FP_GPIO   = 8'd200;
   localparam SR_RX_FRONT  = 8'd208;
   localparam SR_TX_FRONT  = 8'd216;

   wire 	set_stb;
   wire [7:0] 	set_addr;
   wire [31:0] 	set_data;
   wire 	set_stb_b;
   wire [7:0] 	set_addr_b;
   wire [31:0] 	set_data_b;

   wire [31:0] 	fp_gpio_readback, gpio_readback, spi_readback;
   wire 	run_rx, run_tx;
   wire 	strobe_tx;

   wire 	spi_ready;

   reg [63:0] 	rb_data;
   wire [2:0] 	rb_addr;
   wire [63:0] 	vita_time, vita_time_lastpps;
   wire [31:0] test_readback;
   wire        loopback;
   


   radio_ctrl_proc radio_ctrl_proc
     (.clk(radio_clk), .reset(radio_rst), .clear(1'b0),
      .ctrl_tdata(ctrl_tdata_r), .ctrl_tlast(ctrl_tlast_r), .ctrl_tvalid(ctrl_tvalid_r), .ctrl_tready(ctrl_tready_r),
      .resp_tdata(resp_tdata_r), .resp_tlast(resp_tlast_r), .resp_tvalid(resp_tvalid_r), .resp_tready(resp_tready_r),
      .vita_time(vita_time),
      .set_stb(set_stb), .set_addr(set_addr), .set_data(set_data),
      .ready(spi_ready), .readback(rb_data),
      .debug());

   // Radio Readback Mux
   always @*
     case(rb_addr)
       3'd0 : rb_data <= { spi_readback, gpio_readback};
       3'd1 : rb_data <= vita_time;
       3'd2 : rb_data <= vita_time_lastpps;
       3'd3 : rb_data <= {rx, test_readback};
       3'd4 : rb_data <= {32'b0, fp_gpio_readback};
       default : rb_data <= 64'd0;
     endcase // case (rb_addr)

   settings_bus_crossclock
     #(.FLOW_CTRL(0))
       settings_bus_crossclock
       (.clk_i(radio_clk), .rst_i(radio_rst),
	.set_stb_i(set_stb), .set_addr_i(set_addr), .set_data_i(set_data),
	.clk_o(bus_clk), .rst_o(bus_rst),
	.set_stb_o(set_stb_b), .set_addr_o(set_addr_b), .set_data_o(set_data_b),
	.blocked(1'b0));

   // Write this register with any value to create DAC sync operation
   setting_reg #(.my_addr(SR_DACSYNC), .awidth(8), .width(1)) sr_dacsync
     (.clk(radio_clk), .rst(radio_rst), .strobe(set_stb), .addr(set_addr), .in(set_data),
      .out(), .changed(sync_dacs));

   // Set this register to loop TX data directly to RX data.
   setting_reg #(.my_addr(SR_LOOPBACK), .awidth(8), .width(1)) sr_loopback
     (.clk(radio_clk), .rst(radio_rst), .strobe(set_stb), .addr(set_addr), .in(set_data),
      .out(loopback), .changed());

   // Set this register to put a test value on the readback mux.
   setting_reg #(.my_addr(SR_TEST), .awidth(8), .width(32)) sr_test
     (.clk(radio_clk), .rst(radio_rst), .strobe(set_stb), .addr(set_addr), .in(set_data),
      .out(test_readback), .changed());

   setting_reg #(.my_addr(SR_READBACK), .awidth(8), .width(3)) sr_rdback
     (.clk(radio_clk), .rst(radio_rst), .strobe(set_stb), .addr(set_addr), .in(set_data),
      .out(rb_addr), .changed());

   setting_reg #(.my_addr(SR_MISC_OUTS), .awidth(8), .width(8), .at_reset(8'h0)) sr_misc
     (.clk(radio_clk), .rst(radio_rst), .strobe(set_stb), .addr(set_addr), .in(set_data),
      .out(misc_outs), .changed());

   simple_spi_core #(.BASE(SR_SPI), .WIDTH(8), .CLK_IDLE(0), .SEN_IDLE(8'hFF)) radio_spi
     (.clock(radio_clk), .reset(radio_rst),
      .set_stb(set_stb), .set_addr(set_addr), .set_data(set_data),
      .readback(spi_readback), .ready(spi_ready),
      .sen(sen), .sclk(sclk), .mosi(mosi), .miso(miso),
      .debug());

   gpio_atr #(.BASE(SR_GPIO), .WIDTH(32)) gpio_atr
     (.clk(radio_clk),.reset(radio_rst),
      .set_stb(set_stb),.set_addr(set_addr),.set_data(set_data),
      .rx(run_rx), .tx(run_tx),
      .gpio(db_gpio), .gpio_readback(gpio_readback) );

   gpio_atr #(.BASE(SR_FP_GPIO), .WIDTH(32)) fp_gpio_atr
     (.clk(radio_clk),.reset(radio_rst),
      .set_stb(set_stb),.set_addr(set_addr),.set_data(set_data),
      .rx(run_rx), .tx(run_tx),
      .gpio(fp_gpio), .gpio_readback(fp_gpio_readback) );

   gpio_atr #(.BASE(SR_LEDS), .WIDTH(3), .default_ddr(3'b111), .default_idle(3'b000)) gpio_leds
     (.clk(radio_clk),.reset(radio_rst),
      .set_stb(set_stb),.set_addr(set_addr),.set_data(set_data),
      .rx(run_rx), .tx(run_tx),
      .gpio(leds), .gpio_readback() );

   timekeeper #(.BASE(SR_TIME)) timekeeper
     (.clk(radio_clk), .reset(radio_rst), .pps(pps),
      .set_stb(set_stb),.set_addr(set_addr),.set_data(set_data),
      .vita_time(vita_time), .vita_time_lastpps(vita_time_lastpps));

   // /////////////////////////////////////////////////////////////////////////////////
   //  TX Chain

   wire [175:0] txsample_tdata;
   wire 	txsample_tvalid, txsample_tready;
   wire [31:0] 	sample_tx;
   wire 	ack_or_error, packet_consumed;
   wire [11:0] 	seqnum;
   wire [63:0] 	error_code;
   wire [31:0] 	sid;
   wire [23:0] 	tx_fe_i, tx_fe_q;

   new_tx_deframer tx_deframer
     (.clk(radio_clk), .reset(radio_rst), .clear(1'b0),
      .i_tdata(tx_tdata_r), .i_tlast(tx_tlast_r), .i_tvalid(tx_tvalid_r), .i_tready(tx_tready_r),
      .sample_tdata(txsample_tdata), .sample_tvalid(txsample_tvalid), .sample_tready(txsample_tready));

   new_tx_control #(.BASE(SR_TX_CTRL)) tx_control
     (.clk(radio_clk), .reset(radio_rst), .clear(1'b0),
      .set_stb(set_stb), .set_addr(set_addr), .set_data(set_data),
      .vita_time(vita_time),
      .ack_or_error(ack_or_error), .packet_consumed(packet_consumed),
      .seqnum(seqnum), .error_code(error_code), .sid(sid),
      .sample_tdata(txsample_tdata), .sample_tvalid(txsample_tvalid), .sample_tready(txsample_tready),
      .sample(sample_tx), .run(run_tx), .strobe(strobe_tx),
      .debug());

   tx_responder #(.BASE(SR_TX_CTRL+2)) tx_responder
     (.clk(radio_clk), .reset(radio_rst), .clear(1'b0),
      .set_stb(set_stb), .set_addr(set_addr), .set_data(set_data),
      .ack_or_error(ack_or_error), .packet_consumed(packet_consumed),
      .seqnum(seqnum), .error_code(error_code), .sid(sid),
      .vita_time(vita_time),
      .o_tdata(txresp_tdata_r), .o_tlast(txresp_tlast_r), .o_tvalid(txresp_tvalid_r), .o_tready(txresp_tready_r));

   generate
      if (DELETE_DSP==0) begin:	tx_dsp
	 duc_chain #(.BASE(SR_TX_DSP), .DSPNO(0), .WIDTH(24)) duc_chain
	   (.clk(radio_clk), .rst(radio_rst), .clr(1'b0),
	    .set_stb(set_stb),.set_addr(set_addr),.set_data(set_data),
	    .tx_fe_i(tx_fe_i),.tx_fe_q(tx_fe_q),
	    .sample(sample_tx), .run(run_tx), .strobe(strobe_tx),
	    .debug() );
	 tx_frontend #(.BASE(SR_TX_FRONT), .WIDTH_OUT(16), .IQCOMP_EN(1)) tx_frontend
	   (.clk(radio_clk), .rst(radio_rst),
	    .set_stb(set_stb), .set_addr(set_addr), .set_data(set_data),
	    .tx_i(tx_fe_i), .tx_q(tx_fe_q), .run(run_tx),
	    .dac_a(tx[31:16]), .dac_b(tx[15:0]));
      end
   endgenerate

   // /////////////////////////////////////////////////////////////////////////////////
   //  RX Chain

   wire 	full, eob_rx;
   wire 	strobe_rx;
   wire [31:0] 	sample_rx;
   wire [31:0] 	  rx_sid;
   wire [11:0] 	  rx_seqnum;

   source_flow_control #(.BASE(SR_RX_CTRL+6)) rx_sfc
     (.clk(bus_clk), .reset(bus_rst), .clear(1'b0),
      .set_stb(set_stb_b), .set_addr(set_addr_b), .set_data(set_data_b),
      .fc_tdata(rxfc_tdata_b), .fc_tlast(rxfc_tlast_b), .fc_tvalid(rxfc_tvalid_b), .fc_tready(rxfc_tready_b),
      .in_tdata(rx_tdata_b), .in_tlast(rx_tlast_b), .in_tvalid(rx_tvalid_b), .in_tready(rx_tready_b),
      .out_tdata(rx_tdata_b_fc), .out_tlast(rx_tlast_b_fc), .out_tvalid(rx_tvalid_b_fc), .out_tready(rx_tready_b_fc) );

   new_rx_framer #(.BASE(SR_RX_CTRL+4),.CHIPSCOPE(CHIPSCOPE)) new_rx_framer
     (.clk(radio_clk), .reset(radio_rst), .clear(1'b0),
      .set_stb(set_stb), .set_addr(set_addr), .set_data(set_data),
      .vita_time(vita_time),
      .strobe(strobe_rx), .sample(sample_rx), .run(run_rx), .eob(eob_rx), .full(full),
      .sid(rx_sid), .seqnum(rx_seqnum),
      .o_tdata(rx_tdata_r), .o_tlast(rx_tlast_r), .o_tvalid(rx_tvalid_r), .o_tready(rx_tready_r),
      .debug());

   new_rx_control #(.BASE(SR_RX_CTRL)) new_rx_control
     (.clk(radio_clk), .reset(radio_rst), .clear(1'b0),
      .set_stb(set_stb), .set_addr(set_addr), .set_data(set_data),
      .vita_time(vita_time),
      .strobe(strobe_rx), .run(run_rx), .eob(eob_rx), .full(full),
      .sid(rx_sid), .seqnum(rx_seqnum),
      .err_tdata(rx_err_tdata_r), .err_tlast(rx_err_tlast_r), .err_tvalid(rx_err_tvalid_r), .err_tready(rx_err_tready_r),
      .debug());

   wire [23:0] 	  rx_corr_i, rx_corr_q;

   // Digital Loopback TX -> RX (Pipeline immediately inside rx_frontend).
   wire [31:0] 	  rx_fe = loopback ? tx : rx;
   
   generate
      if (DELETE_DSP==0)
	begin:	rx_dsp
	   rx_frontend #(.BASE(SR_RX_FRONT)) rx_frontend
	     (.clk(radio_clk),.rst(radio_rst),
	      .set_stb(set_stb),.set_addr(set_addr),.set_data(set_data),
	      .adc_a(rx_fe[31:16]),.adc_ovf_a(1'b0),
	      .adc_b(rx_fe[15:0]),.adc_ovf_b(1'b0),
	      .i_out(rx_corr_i), .q_out(rx_corr_q),
	      .run(run_rx0_d1 | run_rx1_d1), .debug());

	   ddc_chain_x300 #(.BASE(SR_RX_DSP), .DSPNO(0), .WIDTH(24)) ddc_chain
	     (.clk(radio_clk), .rst(radio_rst), .clr(1'b0),
	      .set_stb(set_stb),.set_addr(set_addr),.set_data(set_data),
	      .rx_fe_i(rx_corr_i),.rx_fe_q(rx_corr_q),
	      .sample(sample_rx), .run(run_rx), .strobe(strobe_rx),
	      .debug() );
	end
   endgenerate

   // /////////////////////////////////////////////////////////////////////////////////
   //  RX Channel Muxing

   axi_mux4 #(.PRIO(1), .WIDTH(64)) rx_mux
     (.clk(radio_clk), .reset(radio_rst), .clear(1'b0),
      .i0_tdata(rx_tdata_r), .i0_tlast(rx_tlast_r), .i0_tvalid(rx_tvalid_r), .i0_tready(rx_tready_r),
      .i1_tdata(rx_err_tdata_r), .i1_tlast(rx_err_tlast_r), .i1_tvalid(rx_err_tvalid_r), .i1_tready(rx_err_tready_r),
      .i2_tdata(), .i2_tlast(), .i2_tvalid(1'b0), .i2_tready(),
      .i3_tdata(), .i3_tlast(), .i3_tvalid(1'b0), .i3_tready(),
      .o_tdata(rx_mux_tdata_r), .o_tlast(rx_mux_tlast_r), .o_tvalid(rx_mux_tvalid_r), .o_tready(rx_mux_tready_r));

   // /////////////////////////////////////////////////////////////////////////////////
   //  Debug
/* -----\/----- EXCLUDED -----\/-----
  generate
      if (CHIPSCOPE) begin: chipscope_gen
	 
   (* keep = "true", max_fanout = 10 *)   reg             debug_set_stb;
   (* keep = "true", max_fanout = 10 *)   reg [7:0]       debug_set_addr;
   (* keep = "true", max_fanout = 10 *)   reg [31:0]      debug_set_data;
   (* keep = "true", max_fanout = 10 *)   reg [63:0]      debug_ctrl_tdata_r;
   (* keep = "true", max_fanout = 10 *)   reg debug_ctrl_tlast_r;  
   (* keep = "true", max_fanout = 10 *)   reg debug_ctrl_tvalid_r;  
   (* keep = "true", max_fanout = 10 *)   reg debug_ctrl_tready_r;
   
   
    always @(posedge radio_clk) begin
       debug_set_stb <= set_stb;
       debug_set_addr <= set_addr[7:0];
       debug_set_data <= set_data[31:0];
       debug_ctrl_tdata_r <= ctrl_tdata_r;
       debug_ctrl_tlast_r <= ctrl_tlast_r;
       debug_ctrl_tvalid_r <= ctrl_tvalid_r;
       debug_ctrl_tready_r <= ctrl_tready_r;
    end
   
       
   wire [35:0] CONTROL0;
   wire [63:0] TRIG0;

   assign      TRIG0 = {
			sync_dacs,       // 109
			loopback,        // 108
			debug_ctrl_tready_r, // 107
			debug_ctrl_tvalid_r, // 106
			debug_ctrl_tlast_r, // 105
			debug_ctrl_tdata_r, // 104:41
			debug_set_stb,   // 40
			debug_set_addr,  // 39:32
			debug_set_data   // 31:0
			};
   

    chipscope_ila chipscope_ila_i0
     (
      .CONTROL(CONTROL0), // INOUT BUS [35:0]
      .CLK(radio_clk), // IN
      .TRIG0(TRIG0 ) // IN BUS [255:0]
      );
  
   chipscope_icon chipscope_icon_i0
     (
      .CONTROL0(CONTROL0) // INOUT BUS [35:0]
      );

      end // block: chipscope
   endgenerate
 -----/\----- EXCLUDED -----/\----- */
   
/* -----\/----- EXCLUDED -----\/-----

   generate
      if (CHIPSCOPE) begin: chipscope_gen
	 (* keep = "true", max_fanout = 10 *)   reg [5:0]	debug_error_code;        // 174:169
	 (* keep = "true", max_fanout = 10 *)   reg 		debug_ack_or_error;      // 168
	 (* keep = "true", max_fanout = 10 *)   reg 		debug_run_rx;            // 167
	 (* keep = "true", max_fanout = 10 *)   reg 		debug_strobe_rx;         // 166
	 (* keep = "true", max_fanout = 10 *)   reg 		debug_rx_err_tvalid_r;   // 165
	 (* keep = "true", max_fanout = 10 *)   reg 		debug_rx_err_tready_r;   // 164
	 (* keep = "true", max_fanout = 10 *)   reg 		debug_rx_err_tlast_r;    // 163
	 (* keep = "true", max_fanout = 10 *)   reg 		debug_rx_tvalid_r;   // 162
	 (* keep = "true", max_fanout = 10 *)   reg 		debug_rx_tready_r;   // 161
	 (* keep = "true", max_fanout = 10 *)   reg 		debug_rx_tlast_r;    // 160
	 (* keep = "true", max_fanout = 10 *)   reg [31:0] 	debug_sample_rx;         // 159:128
	 (* keep = "true", max_fanout = 10 *)   reg [63:0] 	debug_rx_err_tdata_r;    // 127:64
	 (* keep = "true", max_fanout = 10 *)   reg [63:0] 	debug_rx_tdata_r;    // 63:0
	 (* keep = "true", max_fanout = 10 *)   reg             debug_set_stb;
	 (* keep = "true", max_fanout = 10 *)   reg [7:0]       debug_set_addr;
	 (* keep = "true", max_fanout = 10 *)   reg [7:0]       debug_set_data;
	 (* keep = "true", max_fanout = 10 *)   reg [63:0]      debug_tx_tdata_r;
	 (* keep = "true", max_fanout = 10 *)   reg             debug_tx_tlast_r;
	 (* keep = "true", max_fanout = 10 *)   reg             debug_tx_tvalid_r;
	 (* keep = "true", max_fanout = 10 *)   reg             debug_tx_tready_r;
	 (* keep = "true", max_fanout = 10 *)   reg [11:0]      debug_seq_id;
 	 (* keep = "true", max_fanout = 10 *)   reg   	        debug_run_tx;
	 (* keep = "true", max_fanout = 10 *)   reg  	        debug_strobe_tx;
	 

	 always @(posedge radio_clk) begin
	    debug_set_stb <= set_stb;
	    debug_set_addr <= set_addr;
	    debug_set_data <= set_data[7:0];
	    debug_error_code <= error_code[37:32];
	    debug_ack_or_error <= ack_or_error;
	    debug_run_rx <=  run_rx ;
	    debug_strobe_rx <= strobe_rx;
	    debug_rx_err_tvalid_r <= rx_err_tvalid_r;
	    debug_rx_err_tready_r <= rx_err_tready_r;
	    debug_rx_err_tlast_r <=  rx_err_tlast_r;
	    debug_rx_tvalid_r <=  rx_tvalid_r ;
	    debug_rx_tready_r <=   rx_tready_r;
	    debug_rx_tlast_r <=  rx_tlast_r;
	    debug_sample_rx[31:0] <=  sample_rx[31:0];
	    debug_rx_err_tdata_r[63:0] <= rx_err_tdata_r[63:0];
	    debug_rx_tdata_r[63:0] <= rx_tdata_r[63:0];
	    debug_tx_tdata_r <= tx_tdata_r;
	    debug_tx_tlast_r <= tx_tlast_r;
	    debug_tx_tvalid_r <= tx_tvalid_r;
	    debug_tx_tready_r <= tx_tready_r;
	    debug_seq_id <= error_code[11:0];
	    debug_ack_or_error <= ack_or_error;
	    debug_run_tx <= run_tx;
	    debug_strobe_tx <= strobe_tx;
	    
	 end // always @ (posedge radio_clk)
   
   wire [35:0] CONTROL0;
   wire [255:0] TRIG0;

   assign TRIG0 = {
		   debug_strobe_tx,       // 87
		   debug_run_tx,          // 86
		   debug_ack_or_error,    // 85
		   debug_error_code[5:0], // 84:79
		   debug_seq_id[11:0],    // 78:67
 		   debug_tx_tready_r,     // 66
		   debug_tx_tvalid_r,     // 65
		   debug_tx_tlast_r,      // 64
		   debug_tx_tdata_r[63:0] // 63:0
		   };
   
   
   chipscope_ila chipscope_ila_i0
     (
      .CONTROL(CONTROL0), // INOUT BUS [35:0]
      .CLK(radio_clk), // IN
      .TRIG0(TRIG0 ) // IN BUS [255:0]
      );
  
   chipscope_icon chipscope_icon_i0
     (
      .CONTROL0(CONTROL0) // INOUT BUS [35:0]
      );

      end // block: chipscope
   endgenerate
 -----/\----- EXCLUDED -----/\----- */



endmodule // radio