//
// Copyright 2013 Ettus Research LLC
// Copyright 2018 Ettus Research, a National Instruments Company
//
// SPDX-License-Identifier: LGPL-3.0-or-later
//
// radio top level module for b200
// Contains all clock-rate DSP components, all radio and hardware controls and settings
module radio_legacy
#(
parameter RADIO_FIFO_SIZE = 13,
parameter SAMPLE_FIFO_SIZE = 11,
parameter FP_GPIO = 0,
parameter NEW_HB_INTERP = 0,
parameter NEW_HB_DECIM = 0,
parameter SOURCE_FLOW_CONTROL = 0,
parameter USER_SETTINGS = 0,
parameter DEVICE = "SPARTAN6"
)
(input radio_clk, input radio_rst,
input [31:0] rx, output reg [31:0] tx,
input [31:0] fe_gpio_in, output [31:0] fe_gpio_out, output [31:0] fe_gpio_ddr,
input [9:0] fp_gpio_in, output [9:0] fp_gpio_out, output [9:0] fp_gpio_ddr,
input pps, input time_sync,
input bus_clk, input bus_rst,
input [63:0] tx_tdata, input tx_tlast, input tx_tvalid, output tx_tready,
output [63:0] rx_tdata, output rx_tlast, output rx_tvalid, input rx_tready,
input [63:0] ctrl_tdata, input ctrl_tlast, input ctrl_tvalid, output ctrl_tready,
output [63:0] resp_tdata, output resp_tlast, output resp_tvalid, input resp_tready,
output reg [63:0] vita_time_b,
output [63:0] 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
wire [63:0] ctrl_tdata_r;
wire ctrl_tready_r, ctrl_tvalid_r;
wire ctrl_tlast_r;
wire [63:0] resp_tdata_r;
wire resp_tready_r, resp_tvalid_r;
wire resp_tlast_r;
wire [63:0] rx_tdata_r;
wire rx_tready_r, rx_tvalid_r;
wire rx_tlast_r;
wire [63:0] rx_err_tdata_r;
wire rx_err_tready_r, rx_err_tvalid_r;
wire rx_err_tlast_r;
wire [63:0] rx_prefc_tdata_r;
wire rx_prefc_tready_r, rx_prefc_tvalid_r;
wire rx_prefc_tlast_r;
wire [63:0] rx_postfc_tdata_r;
wire rx_postfc_tready_r, rx_postfc_tvalid_r;
wire rx_postfc_tlast_r;
wire [63:0] tx_tdata_r;
wire tx_tready_r, tx_tvalid_r;
wire tx_tlast_r;
wire [63:0] txresp_tdata, txresp_tdata_r;
wire txresp_tready, txresp_tready_r, txresp_tvalid, txresp_tvalid_r;
wire txresp_tlast, txresp_tlast_r;
wire [63:0] rmux_tdata_r;
wire rmux_tlast_r, rmux_tvalid_r, rmux_tready_r;
wire [31:0] tx_idle;
wire [3:0] ibs_state;
wire [63:0] rx_tdata_int;
wire rx_tready_int, rx_tvalid_int;
wire rx_tlast_int;
axi_fifo_2clk #(.WIDTH(65), .SIZE(0/*minimal*/)) ctrl_fifo
(.reset(bus_rst),
.i_aclk(bus_clk), .i_tvalid(ctrl_tvalid), .i_tready(ctrl_tready), .i_tdata({ctrl_tlast, ctrl_tdata}),
.o_aclk(radio_clk), .o_tvalid(ctrl_tvalid_r), .o_tready(ctrl_tready_r), .o_tdata({ctrl_tlast_r, ctrl_tdata_r}));
axi_fifo_2clk #(.WIDTH(65), .SIZE(RADIO_FIFO_SIZE)) tx_fifo
(.reset(bus_rst),
.i_aclk(bus_clk), .i_tvalid(tx_tvalid), .i_tready(tx_tready), .i_tdata({tx_tlast, tx_tdata}),
.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(0/*minimal*/)) resp_fifo
(.reset(radio_rst),
.i_aclk(radio_clk), .i_tvalid(rmux_tvalid_r), .i_tready(rmux_tready_r), .i_tdata({rmux_tlast_r, rmux_tdata_r}),
.o_aclk(bus_clk), .o_tvalid(resp_tvalid), .o_tready(resp_tready), .o_tdata({resp_tlast, resp_tdata}));
axi_fifo_2clk #(.WIDTH(65), .SIZE(RADIO_FIFO_SIZE)) rx_fifo
(.reset(radio_rst),
.i_aclk(radio_clk), .i_tvalid(rx_tvalid_r), .i_tready(rx_tready_r), .i_tdata({rx_tlast_r, rx_tdata_r}),
.o_aclk(bus_clk), .o_tvalid(rx_tvalid_int), .o_tready(rx_tready_int), .o_tdata({rx_tlast_int, rx_tdata_int}));
axi_packet_gate #(.WIDTH(64), .SIZE(SAMPLE_FIFO_SIZE), .USE_AS_BUFF(0)) buffer_whole_pkt
(
.clk(bus_clk), .reset(bus_rst), .clear(1'b0),
.i_tdata(rx_tdata_int), .i_tlast(rx_tlast_int), .i_terror(1'b0), .i_tvalid(rx_tvalid_int), .i_tready(rx_tready_int),
.o_tdata(rx_tdata), .o_tlast(rx_tlast), .o_tvalid(rx_tvalid), .o_tready(rx_tready));
///////////////////////////////////////////////////////////////////////////////////////
// Setting bus and controls
wire [63:0] ctrl_tdata_proc;
wire ctrl_tready_proc, ctrl_tvalid_proc;
wire ctrl_tlast_proc;
localparam SR_LOOPBACK = 8'd6;
localparam SR_SPI = 8'd8;
localparam SR_ATR = 8'd12; // thorugh 8'd18
localparam SR_TEST = 8'd21;
localparam SR_CODEC_IDLE = 8'd22;
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_FMT = 8'd136;
localparam SR_TX_FMT = 8'd138;
localparam SR_RX_DSP = 8'd144;
localparam SR_TX_DSP = 8'd184;
localparam SR_FP_GPIO = 8'd200; // thorugh 8'd206
localparam SR_USER_SR_BASE = 8'd253;
localparam SR_USER_RB_ADDR = 8'd255;
wire set_stb;
wire [7:0] set_addr;
wire [31:0] set_data;
wire [31:0] test_readback;
wire [9:0] fp_gpio_readback;
wire run_rx, run_tx;
wire rx_flow_ctrl_busy;
reg [63:0] rb_data;
wire [2:0] rb_addr;
wire [63:0] vita_time, vita_time_lastpps;
timekeeper #(.SR_TIME_HI(SR_TIME), .SR_TIME_LO(SR_TIME+1), .SR_TIME_CTRL(SR_TIME+2)) timekeeper
(.clk(radio_clk), .reset(radio_rst), .pps(pps), .sync_in(time_sync), .strobe(1'b1),
.set_stb(set_stb), .set_addr(set_addr), .set_data(set_data),
.vita_time(vita_time), .vita_time_lastpps(vita_time_lastpps),
.sync_out());
wire [31:0] debug_radio_ctrl_proc;
radio_ctrl_proc radio_ctrl_proc
(.clk(radio_clk), .reset(radio_rst), .clear(1'b0),
.ctrl_tdata(ctrl_tdata_proc), .ctrl_tlast(ctrl_tlast_proc), .ctrl_tvalid(ctrl_tvalid_proc), .ctrl_tready(ctrl_tready_proc),
.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(1'b1), .readback(rb_data),
.debug(debug_radio_ctrl_proc));
reg [63:0] rb_data_user;
generate
if (USER_SETTINGS == 1) begin
wire set_stb_user;
wire [7:0] set_addr_user;
wire [31:0] set_data_user;
wire [7:0] rb_addr_user;
user_settings #(.BASE(SR_USER_SR_BASE)) user_settings
(.clk(radio_clk), .rst(radio_rst),
.set_stb(set_stb), .set_addr(set_addr), .set_data(set_data),
.set_stb_user(set_stb_user), .set_addr_user(set_addr_user), .set_data_user(set_data_user));
setting_reg #(.my_addr(SR_USER_RB_ADDR), .awidth(8), .width(8)) user_rb_addr
(.clk(radio_clk), .rst(radio_rst), .strobe(set_stb), .addr(set_addr), .in(set_data),
.out(rb_addr_user), .changed());
// ----------------------------------
// Enter user settings registers here
// ----------------------------------
// Example code for 32-bit settings registers and 64-bit readback registers
//
// To test this, modify the *_core.v file for your specific USRP and set
// USER_SETTINGS=1 for the parameters for the radio_legacy instantiation.
//
// You can then use the get_user_settings_iface() like this:
//
// auto usrp = multi_usrp::make("type=b200,enable_user_regs");
// auto regs = usrp->get_user_settings_iface(0);
// regs->poke32(0, 0xCAFE);
// regs->poke32(4, 0xBEEF);
// std::cout << boost::format("0x%016X") % regs->peek64(0) << std::endl;
wire [31:0] user_reg_0_value, user_reg_1_value;
setting_reg #(.my_addr(8'd0), .awidth(8), .width(32)) user_reg_0
(.clk(radio_clk), .rst(radio_rst), .strobe(set_stb_user), .addr(set_addr_user), .in(set_data_user),
.out(user_reg_0_value), .changed());
setting_reg #(.my_addr(8'd1), .awidth(8), .width(32)) user_reg_1
(.clk(radio_clk), .rst(radio_rst), .strobe(set_stb_user), .addr(set_addr_user), .in(set_data_user),
.out(user_reg_1_value), .changed());
always @* begin
case(rb_addr_user)
8'd0 : rb_data_user <= {user_reg_1_value, user_reg_0_value};
default : rb_data_user <= 64'd0;
endcase
end
end else begin //for USER_SETTINGS == 1
always @* rb_data_user <= 64'd0;
end
endgenerate
always @*
case(rb_addr)
3'd0 : rb_data <= { 32'b0, test_readback };
3'd1 : rb_data <= vita_time;
3'd2 : rb_data <= vita_time_lastpps;
3'd3 : rb_data <= {tx, rx};
3'd4 : rb_data <= {54'h0,fp_gpio_readback};
3'd5 : rb_data <= {59'h0,rx_flow_ctrl_busy,ibs_state[3:0]}; // Monitor state of RX state machine.
// 3'd6 : rb_data <= <unused>;
3'd7 : rb_data <= rb_data_user;
default : rb_data <= 64'd0;
endcase // case (rb_addr)
//
// Sample VITA_TIME into the bus_clk domain for use by instrumentation.
//
wire [63:0] vita_time_b_int;
wire vita_time_b_valid;
axi_fifo_2clk #(.WIDTH(64), .SIZE(0)) vita_time_fifo
(.reset(radio_rst),
.i_aclk(radio_clk), .i_tvalid(1'b1), .i_tready(), .i_tdata(vita_time),
.o_aclk(bus_clk), .o_tvalid(vita_time_b_valid), .o_tready(1'b1), .o_tdata(vita_time_b_int));
always @(posedge bus_clk)
if (vita_time_b_valid)
vita_time_b <= vita_time_b_int;
// 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());
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_CODEC_IDLE), .awidth(8), .width(32)) sr_codec_idle
(.clk(radio_clk), .rst(radio_rst), .strobe(set_stb), .addr(set_addr), .in(set_data),
.out(tx_idle), .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());
//The fe_atr pins driven by this module are always configured as outputs so default
//the DDR (data direction register) to be all ones (outputs) so that the drive direction
//these lines does not change during/after resets.
gpio_atr #(.BASE(SR_ATR), .WIDTH(32), .FAB_CTRL_EN(0), .DEFAULT_DDR(32'hFFFFFFFF), .DEFAULT_IDLE(32'h00000000)) fe_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_in(fe_gpio_in), .gpio_out(fe_gpio_out), .gpio_ddr(fe_gpio_ddr),
.gpio_out_fab(32'h00000000 /* no fabric control */), .gpio_sw_rb() );
generate
if (FP_GPIO != 0) begin: add_fp_gpio
gpio_atr #(.BASE(SR_FP_GPIO), .WIDTH(10), .FAB_CTRL_EN(0)) 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_in(fp_gpio_in), .gpio_out(fp_gpio_out), .gpio_ddr(fp_gpio_ddr),
.gpio_out_fab(10'h000 /* no fabric control */), .gpio_sw_rb(fp_gpio_readback));
end
endgenerate
///////////////////////////////////////////////////////////////////////////////////////
// Source flow control
generate
if (SOURCE_FLOW_CONTROL == 1) begin
localparam SID_PREFIX_CTRL = 2'd0;
localparam SID_PREFIX_FC = 2'd1;
wire [63:0] ctrl_tdata_fc;
wire ctrl_tready_fc, ctrl_tvalid_fc;
wire ctrl_tlast_fc;
wire [63:0] ctrl_hdr;
wire [1:0] ctrl_dest;
assign ctrl_dest = (ctrl_hdr[1:0] == SID_PREFIX_FC) ? 2'd1 : 2'd0;
axi_demux4 #(.ACTIVE_CHAN(4'b0011), .WIDTH(64), .BUFFER(1)) demux_proc_fc
(.clk(radio_clk), .reset(radio_rst), .clear(1'b0),
.header(ctrl_hdr), .dest(ctrl_dest),
.i_tdata(ctrl_tdata_r), .i_tlast(ctrl_tlast_r), .i_tvalid(ctrl_tvalid_r), .i_tready(ctrl_tready_r), //Input
.o0_tdata(ctrl_tdata_proc), .o0_tlast(ctrl_tlast_proc), .o0_tvalid(ctrl_tvalid_proc), .o0_tready(ctrl_tready_proc), //Settings/Readback
.o1_tdata(ctrl_tdata_fc), .o1_tlast(ctrl_tlast_fc), .o1_tvalid(ctrl_tvalid_fc), .o1_tready(ctrl_tready_fc), //Flow control
.o2_tdata(), .o2_tlast(), .o2_tvalid(), .o2_tready(1'b0), //Unused
.o3_tdata(), .o3_tlast(), .o3_tvalid(), .o3_tready(1'b0)); //Unused
source_flow_control_legacy #(.BASE(SR_RX_CTRL+6)) rx_sfc
(.clk(radio_clk), .reset(radio_rst), .clear(1'b0),
.set_stb(set_stb), .set_addr(set_addr), .set_data(set_data),
.fc_tdata(ctrl_tdata_fc), .fc_tlast(ctrl_tlast_fc), .fc_tvalid(ctrl_tvalid_fc), .fc_tready(ctrl_tready_fc), //Flow control In
.in_tdata(rx_prefc_tdata_r), .in_tlast(rx_prefc_tlast_r), .in_tvalid(rx_prefc_tvalid_r), .in_tready(rx_prefc_tready_r), //RX Input
.out_tdata(rx_postfc_tdata_r), .out_tlast(rx_postfc_tlast_r), .out_tvalid(rx_postfc_tvalid_r), .out_tready(rx_postfc_tready_r), //RX Output
.busy(rx_flow_ctrl_busy));
end else begin //for SOURCE_FLOW_CONTROL == 1
assign ctrl_tdata_proc = ctrl_tdata_r;
assign ctrl_tlast_proc = ctrl_tlast_r;
assign ctrl_tvalid_proc = ctrl_tvalid_r;
assign ctrl_tready_r = ctrl_tready_proc;
assign rx_postfc_tdata_r = rx_prefc_tdata_r;
assign rx_postfc_tlast_r = rx_prefc_tlast_r;
assign rx_postfc_tvalid_r = rx_prefc_tvalid_r;
assign rx_prefc_tready_r = rx_postfc_tready_r;
assign rx_flow_ctrl_busy = 1'b0;
end
endgenerate
// /////////////////////////////////////////////////////////////////////////////////
// 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;
wire [31:0] debug_tx_control;
always @(posedge radio_clk) begin
tx[31:16] <= (run_tx) ? tx_fe_i[23:8] : tx_idle[31:16];
tx[15:0] <= (run_tx) ? tx_fe_q[23:8] : tx_idle[15:0];
end
wire [63:0] tx_tdata_i; wire tx_tlast_i, tx_tvalid_i, tx_tready_i;
new_tx_deframer tx_deframer
(.clk(radio_clk), .reset(radio_rst), .clear(1'b0),
.i_tdata(tx_tdata_i), .i_tlast(tx_tlast_i), .i_tvalid(tx_tvalid_i), .i_tready(tx_tready_i),
.sample_tdata(txsample_tdata), .sample_tvalid(txsample_tvalid), .sample_tready(txsample_tready),
.debug());
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(debug_tx_control));
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));
wire [31:0] debug_duc_chain;
duc_chain #(.BASE(SR_TX_DSP), .DSPNO(0), .WIDTH(24), .NEW_HB_INTERP(NEW_HB_INTERP),.DEVICE(DEVICE)) 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(debug_duc_chain) );
`ifdef DELETE_FORMAT_CONVERSION
assign tx_tdata_i = tx_tdata_r;
assign tx_tlast_i = tx_tlast_r;
assign tx_tvalid_i = tx_tvalid_r;
assign tx_tready_r = tx_tready_i;
`else
chdr_xxxx_to_16sc_chain #(.BASE(SR_TX_FMT)) convert_xxxx_to_16sc
(.clk(radio_clk), .reset(radio_rst),
.set_stb(set_stb),.set_addr(set_addr),.set_data(set_data),
.i_tdata(tx_tdata_r), .i_tlast(tx_tlast_r), .i_tvalid(tx_tvalid_r), .i_tready(tx_tready_r),
.o_tdata(tx_tdata_i), .o_tlast(tx_tlast_i), .o_tvalid(tx_tvalid_i), .o_tready(tx_tready_i),
.debug());
`endif // !`ifdef DELETE_FORMAT_CONVERSION
// /////////////////////////////////////////////////////////////////////////////////
// RX Chain
wire full, eob_rx;
wire strobe_rx;
wire [31:0] sample_rx;
wire [31:0] rx_sid;
wire [11:0] rx_seqnum;
wire [63:0] rx_tdata_i; wire rx_tlast_i, rx_tvalid_i, rx_tready_i;
wire [31:0] debug_rx_framer;
new_rx_framer #(.BASE(SR_RX_CTRL+4),.SAMPLE_FIFO_SIZE(SAMPLE_FIFO_SIZE)) 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_i), .o_tlast(rx_tlast_i), .o_tvalid(rx_tvalid_i), .o_tready(rx_tready_i),
.debug(debug_rx_framer));
wire [31:0] debug_rx_control;
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),
.ibs_state(ibs_state),
.debug(debug_rx_control));
wire [31:0] debug_ddc_chain;
// Digital Loopback TX -> RX (Pipeline immediately inside rx_frontend).
wire [31:0] rx_fe = loopback ? tx : rx;
ddc_chain #(.BASE(SR_RX_DSP), .DSPNO(0), .WIDTH(24), .NEW_HB_DECIM(NEW_HB_DECIM), .DEVICE(DEVICE)) 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_fe[31:16],8'd0}),.rx_fe_q({rx_fe[15:0],8'd0}),
.sample(sample_rx), .run(run_rx), .strobe(strobe_rx),
.debug(debug_ddc_chain) );
`ifdef DELETE_FORMAT_CONVERSION
assign rx_prefc_tdata_r = rx_tdata_i;
assign rx_prefc_tlast_r = rx_tlast_i;
assign rx_prefc_tvalid_r = rx_tvalid_i;
assign rx_tready_i = rx_prefc_tready_r;
`else
chdr_16sc_to_xxxx_chain #(.BASE(SR_RX_FMT)) convert_16sc_to_xxxx
(.clk(radio_clk), .reset(radio_rst),
.set_stb(set_stb),.set_addr(set_addr),.set_data(set_data),
.i_tdata(rx_tdata_i), .i_tlast(rx_tlast_i), .i_tvalid(rx_tvalid_i), .i_tready(rx_tready_i),
.o_tdata(rx_prefc_tdata_r), .o_tlast(rx_prefc_tlast_r), .o_tvalid(rx_prefc_tvalid_r), .o_tready(rx_prefc_tready_r),
.debug());
`endif
// /////////////////////////////////////////////////////////////////////////////////
// RX Channel Muxing
axi_mux4 #(.PRIO(1), .WIDTH(64), .BUFFER(1)) rx_mux
(.clk(radio_clk), .reset(radio_rst), .clear(1'b0),
.i0_tdata(rx_postfc_tdata_r), .i0_tlast(rx_postfc_tlast_r), .i0_tvalid(rx_postfc_tvalid_r), .i0_tready(rx_postfc_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(64'h0), .i2_tlast(1'b0), .i2_tvalid(1'b0), .i2_tready(),
.i3_tdata(64'h0), .i3_tlast(1'b0), .i3_tvalid(1'b0), .i3_tready(),
.o_tdata(rx_tdata_r), .o_tlast(rx_tlast_r), .o_tvalid(rx_tvalid_r), .o_tready(rx_tready_r));
// /////////////////////////////////////////////////////////////////////////////////
// Response Channel Muxing
axi_mux4 #(.PRIO(0), .WIDTH(64)) response_mux
(.clk(radio_clk), .reset(radio_rst), .clear(1'b0),
.i0_tdata(txresp_tdata_r), .i0_tlast(txresp_tlast_r), .i0_tvalid(txresp_tvalid_r), .i0_tready(txresp_tready_r),
.i1_tdata(resp_tdata_r), .i1_tlast(resp_tlast_r), .i1_tvalid(resp_tvalid_r), .i1_tready(resp_tready_r),
.i2_tdata(64'h0), .i2_tlast(1'b0), .i2_tvalid(1'b0), .i2_tready(),
.i3_tdata(64'h0), .i3_tlast(1'b0), .i3_tvalid(1'b0), .i3_tready(),
.o_tdata(rmux_tdata_r), .o_tlast(rmux_tlast_r), .o_tvalid(rmux_tvalid_r), .o_tready(rmux_tready_r));
/*******************************************************************
* Debug only logic below here.
******************************************************************/
assign debug = 0;
endmodule // radio_legacy