// -*- verilog -*- // // USRP - Universal Software Radio Peripheral // // Copyright (C) 2003,2004,2005,2006 Matt Ettus // Copyright (C) 2006 Martin Dudok van Heel // // 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 2 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, write to the Free Software // Foundation, Inc., 51 Franklin Street, Boston, MA 02110-1301 USA // // Top level module for a full setup with DUCs and DDCs // Define DEBUG_OWNS_IO_PINS if we're using the daughterboard i/o pins // for debugging info. NB, This can kill the m'board and/or d'board if you // have anything except basic d'boards installed. // Uncomment the following to include optional circuitry `include "config.vh" `include "../../common/fpga_regs_common.v" `include "../../common/fpga_regs_standard.v" module usrp_multi (output MYSTERY_SIGNAL, input master_clk, input SCLK, input SDI, inout SDO, input SEN_FPGA, input FX2_1, output FX2_2, output FX2_3, input wire [11:0] rx_a_a, input wire [11:0] rx_b_a, input wire [11:0] rx_a_b, input wire [11:0] rx_b_b, output wire [13:0] tx_a, output wire [13:0] tx_b, output wire TXSYNC_A, output wire TXSYNC_B, // USB interface input usbclk, input wire [2:0] usbctl, output wire [1:0] usbrdy, inout [15:0] usbdata, // NB Careful, inout // These are the general purpose i/o's that go to the daughterboard slots inout wire [15:0] io_tx_a, inout wire [15:0] io_tx_b, inout wire [15:0] io_rx_a, inout wire [15:0] io_rx_b ); wire [15:0] debugdata,debugctrl; assign MYSTERY_SIGNAL = 1'b0; wire clk64,clk128; wire WR = usbctl[0]; wire RD = usbctl[1]; wire OE = usbctl[2]; wire have_space, have_pkt_rdy; assign usbrdy[0] = have_space; assign usbrdy[1] = have_pkt_rdy; wire tx_underrun, rx_overrun; wire clear_status = FX2_1; assign FX2_2 = rx_overrun; assign FX2_3 = tx_underrun; wire [15:0] usbdata_out; wire [3:0] dac0mux,dac1mux,dac2mux,dac3mux; wire tx_realsignals; wire [3:0] rx_numchan; wire [2:0] tx_numchan; wire [7:0] interp_rate, decim_rate; wire [15:0] tx_debugbus, rx_debugbus; wire enable_tx, enable_rx; wire reset_data; `ifdef MULTI_ON wire sync_rx; assign reset_data = sync_rx; `else assign reset_data = 1'b0; `endif // `ifdef MULTI_ON wire tx_dsp_reset, rx_dsp_reset, tx_bus_reset, rx_bus_reset; wire [7:0] settings; // Tri-state bus macro bustri bustri( .data(usbdata_out),.enabledt(OE),.tridata(usbdata) ); assign clk64 = master_clk; wire [15:0] ch0tx,ch1tx,ch2tx,ch3tx; //,ch4tx,ch5tx,ch6tx,ch7tx; wire [15:0] ch0rx,ch1rx,ch2rx,ch3rx,ch4rx,ch5rx,ch6rx,ch7rx; // TX wire [15:0] i_out_0,i_out_1,q_out_0,q_out_1; wire [15:0] bb_tx_i0,bb_tx_q0,bb_tx_i1,bb_tx_q1; // bb_tx_i2,bb_tx_q2,bb_tx_i3,bb_tx_q3; wire strobe_interp, tx_sample_strobe; wire tx_empty; wire serial_strobe; wire [6:0] serial_addr; wire [31:0] serial_data; reg [15:0] debug_counter; `ifdef COUNTER_32BIT_ON reg [31:0] sample_counter_32bit; `endif // `ifdef COUNTER_32BIT_ON reg [15:0] loopback_i_0,loopback_q_0; //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// // Transmit Side `ifdef TX_ON assign bb_tx_i0 = ch0tx; assign bb_tx_q0 = ch1tx; assign bb_tx_i1 = ch2tx; assign bb_tx_q1 = ch3tx; tx_buffer tx_buffer ( .usbclk(usbclk),.bus_reset(tx_bus_reset),.reset(tx_dsp_reset), .usbdata(usbdata),.WR(WR),.have_space(have_space),.tx_underrun(tx_underrun), .channels({tx_numchan,1'b0}), .tx_i_0(ch0tx),.tx_q_0(ch1tx), .tx_i_1(ch2tx),.tx_q_1(ch3tx), .tx_i_2(),.tx_q_2(), .tx_i_3(),.tx_q_3(), .txclk(clk64),.txstrobe(strobe_interp), .clear_status(clear_status), .tx_empty(tx_empty), .debugbus(tx_debugbus) ); tx_chain tx_chain_0 ( .clock(clk64),.reset(tx_dsp_reset),.enable(enable_tx), .interp_rate(interp_rate),.sample_strobe(tx_sample_strobe), .interpolator_strobe(strobe_interp),.freq(), .i_in(bb_tx_i0),.q_in(bb_tx_q0),.i_out(i_out_0),.q_out(q_out_0) ); tx_chain tx_chain_1 ( .clock(clk64),.reset(tx_dsp_reset),.enable(enable_tx), .interp_rate(interp_rate),.sample_strobe(tx_sample_strobe), .interpolator_strobe(strobe_interp),.freq(), .i_in(bb_tx_i1),.q_in(bb_tx_q1),.i_out(i_out_1),.q_out(q_out_1) ); setting_reg #(`FR_TX_MUX) sr_txmux(.clock(clk64),.reset(tx_dsp_reset),.strobe(serial_strobe),.addr(serial_addr),.in(serial_data), .out({dac3mux,dac2mux,dac1mux,dac0mux,tx_realsignals,tx_numchan})); wire [15:0] tx_a_a = dac0mux[3] ? (dac0mux[1] ? (dac0mux[0] ? q_out_1 : i_out_1) : (dac0mux[0] ? q_out_0 : i_out_0)) : 16'b0; wire [15:0] tx_b_a = dac1mux[3] ? (dac1mux[1] ? (dac1mux[0] ? q_out_1 : i_out_1) : (dac1mux[0] ? q_out_0 : i_out_0)) : 16'b0; wire [15:0] tx_a_b = dac2mux[3] ? (dac2mux[1] ? (dac2mux[0] ? q_out_1 : i_out_1) : (dac2mux[0] ? q_out_0 : i_out_0)) : 16'b0; wire [15:0] tx_b_b = dac3mux[3] ? (dac3mux[1] ? (dac3mux[0] ? q_out_1 : i_out_1) : (dac3mux[0] ? q_out_0 : i_out_0)) : 16'b0; wire txsync = tx_sample_strobe; assign TXSYNC_A = txsync; assign TXSYNC_B = txsync; assign tx_a = txsync ? tx_b_a[15:2] : tx_a_a[15:2]; assign tx_b = txsync ? tx_b_b[15:2] : tx_a_b[15:2]; `endif // `ifdef TX_ON ///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// // Receive Side `ifdef RX_ON wire rx_sample_strobe,strobe_decim,hb_strobe; wire [15:0] bb_rx_i0,bb_rx_q0,bb_rx_i1,bb_rx_q1, bb_rx_i2,bb_rx_q2,bb_rx_i3,bb_rx_q3; wire loopback = settings[0]; wire counter = settings[1]; `ifdef COUNTER_32BIT_ON wire counter_32bit = settings[2]; always @(posedge clk64) if(rx_dsp_reset) sample_counter_32bit <= #1 32'd0; else if(~enable_rx | reset_data) sample_counter_32bit <=#1 32'd0; else if(hb_strobe) sample_counter_32bit <=#1 sample_counter_32bit + 32'd1; `endif // `ifdef COUNTER_32BIT_ON always @(posedge clk64) if(rx_dsp_reset) debug_counter <= #1 16'd0; else if(~enable_rx) debug_counter <= #1 16'd0; else if(hb_strobe) debug_counter <=#1 debug_counter + 16'd2; always @(posedge clk64) if(strobe_interp) begin loopback_i_0 <= #1 ch0tx; loopback_q_0 <= #1 ch1tx; end `ifdef COUNTER_32BIT_ON assign ch0rx = counter_32bit?sample_counter_32bit[31:16]:counter ? debug_counter : loopback ? loopback_i_0 : bb_rx_i0; assign ch1rx = counter_32bit?sample_counter_32bit[15:0]:counter ? debug_counter + 16'd1 : loopback ? loopback_q_0 : bb_rx_q0; assign ch2rx = bb_rx_i1; assign ch3rx = bb_rx_q1; assign ch4rx = counter_32bit?bb_rx_i0:bb_rx_i2; assign ch5rx = counter_32bit?bb_rx_q0:bb_rx_q2;// If using counter replicate channels here to be able to get rx_i0 when using counter //This means if you use 4 channels that channel 3 will be replaced by channel 0 // and channel 0 will output the 32 bit counter. assign ch6rx = bb_rx_i3; assign ch7rx = bb_rx_q3; `else assign ch0rx = counter ? debug_counter : loopback ? loopback_i_0 : bb_rx_i0; assign ch1rx = counter ? debug_counter + 16'd1 : loopback ? loopback_q_0 : bb_rx_q0; assign ch2rx = bb_rx_i1; assign ch3rx = bb_rx_q1; assign ch4rx = bb_rx_i2; assign ch5rx = bb_rx_q2; assign ch6rx = bb_rx_i3; assign ch7rx = bb_rx_q3; `endif // `ifdef COUNTER_32BIT_ON wire [15:0] ddc0_in_i,ddc0_in_q,ddc1_in_i,ddc1_in_q,ddc2_in_i,ddc2_in_q,ddc3_in_i,ddc3_in_q; adc_interface adc_interface(.clock(clk64),.reset(rx_dsp_reset),.enable(1'b1), .serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe), .rx_a_a(rx_a_a),.rx_b_a(rx_b_a),.rx_a_b(rx_a_b),.rx_b_b(rx_b_b), .ddc0_in_i(ddc0_in_i),.ddc0_in_q(ddc0_in_q), .ddc1_in_i(ddc1_in_i),.ddc1_in_q(ddc1_in_q), .ddc2_in_i(ddc2_in_i),.ddc2_in_q(ddc2_in_q), .ddc3_in_i(ddc3_in_i),.ddc3_in_q(ddc3_in_q),.rx_numchan(rx_numchan) ); rx_buffer rx_buffer ( .usbclk(usbclk),.bus_reset(rx_bus_reset),.reset(rx_dsp_reset | reset_data), .reset_regs(rx_dsp_reset), .usbdata(usbdata_out),.RD(RD),.have_pkt_rdy(have_pkt_rdy),.rx_overrun(rx_overrun), .channels(rx_numchan), .ch_0(ch0rx),.ch_1(ch1rx), .ch_2(ch2rx),.ch_3(ch3rx), .ch_4(ch4rx),.ch_5(ch5rx), .ch_6(ch6rx),.ch_7(ch7rx), .rxclk(clk64),.rxstrobe(hb_strobe), .clear_status(clear_status), .serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe), .debugbus(rx_debugbus) ); `ifdef RX_EN_0 rx_chain #(`FR_RX_FREQ_0,`FR_RX_PHASE_0) rx_chain_0 ( .clock(clk64),.reset(reset_data),.enable(enable_rx), .decim_rate(decim_rate),.sample_strobe(rx_sample_strobe),.decimator_strobe(strobe_decim),.hb_strobe(hb_strobe), .serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe), .i_in(ddc0_in_i),.q_in(ddc0_in_q),.i_out(bb_rx_i0),.q_out(bb_rx_q0),.debugdata(debugdata),.debugctrl(debugctrl)); `else assign bb_rx_i0=16'd0; assign bb_rx_q0=16'd0; `endif `ifdef RX_EN_1 rx_chain #(`FR_RX_FREQ_1,`FR_RX_PHASE_1) rx_chain_1 ( .clock(clk64),.reset(reset_data),.enable(enable_rx), .decim_rate(decim_rate),.sample_strobe(rx_sample_strobe),.decimator_strobe(strobe_decim),.hb_strobe(), .serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe), .i_in(ddc1_in_i),.q_in(ddc1_in_q),.i_out(bb_rx_i1),.q_out(bb_rx_q1)); `else assign bb_rx_i1=16'd0; assign bb_rx_q1=16'd0; `endif `ifdef RX_EN_2 rx_chain #(`FR_RX_FREQ_2,`FR_RX_PHASE_2) rx_chain_2 ( .clock(clk64),.reset(reset_data),.enable(enable_rx), .decim_rate(decim_rate),.sample_strobe(rx_sample_strobe),.decimator_strobe(strobe_decim),.hb_strobe(), .serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe), .i_in(ddc2_in_i),.q_in(ddc2_in_q),.i_out(bb_rx_i2),.q_out(bb_rx_q2)); `else assign bb_rx_i2=16'd0; assign bb_rx_q2=16'd0; `endif `ifdef RX_EN_3 rx_chain #(`FR_RX_FREQ_3,`FR_RX_PHASE_3) rx_chain_3 ( .clock(clk64),.reset(reset_data),.enable(enable_rx), .decim_rate(decim_rate),.sample_strobe(rx_sample_strobe),.decimator_strobe(strobe_decim),.hb_strobe(), .serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe), .i_in(ddc3_in_i),.q_in(ddc3_in_q),.i_out(bb_rx_i3),.q_out(bb_rx_q3)); assign bb_rx_i3=16'd0; assign bb_rx_q3=16'd0; `endif `endif // `ifdef RX_ON /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// // Control Functions wire [31:0] capabilities; assign capabilities[7] = `TX_CAP_HB; assign capabilities[6:4] = `TX_CAP_NCHAN; assign capabilities[3] = `RX_CAP_HB; assign capabilities[2:0] = `RX_CAP_NCHAN; serial_io serial_io ( .master_clk(clk64),.serial_clock(SCLK),.serial_data_in(SDI), .enable(SEN_FPGA),.reset(1'b0),.serial_data_out(SDO), .serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe), .readback_0({io_rx_a,io_tx_a}),.readback_1({io_rx_b,io_tx_b}),.readback_2(capabilities),.readback_3(32'hf0f0931a) ); wire [15:0] reg_0,reg_1,reg_2,reg_3; `ifdef MULTI_ON master_control_multi master_control ( .master_clk(clk64),.usbclk(usbclk), .serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe), .rx_slave_sync(io_rx_a[`bitnoFR_RX_SYNC_INPUT_IOPIN]), .tx_bus_reset(tx_bus_reset),.rx_bus_reset(rx_bus_reset), .tx_dsp_reset(tx_dsp_reset),.rx_dsp_reset(rx_dsp_reset), .enable_tx(enable_tx),.enable_rx(enable_rx), .sync_rx(sync_rx), .interp_rate(interp_rate),.decim_rate(decim_rate), .tx_sample_strobe(tx_sample_strobe),.strobe_interp(strobe_interp), .rx_sample_strobe(rx_sample_strobe),.strobe_decim(strobe_decim), .tx_empty(tx_empty), //.debug_0(rx_a_a),.debug_1(ddc0_in_i), .debug_0(rx_debugbus),.debug_1(ddc0_in_i), .debug_2({rx_sample_strobe,strobe_decim,serial_strobe,serial_addr}),.debug_3({rx_dsp_reset,tx_dsp_reset,rx_bus_reset,tx_bus_reset,enable_rx,tx_underrun,rx_overrun,decim_rate}), .reg_0(reg_0),.reg_1(reg_1),.reg_2(reg_2),.reg_3(reg_3) ); `else //`ifdef MULTI_ON master_control master_control ( .master_clk(clk64),.usbclk(usbclk), .serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe), .tx_bus_reset(tx_bus_reset),.rx_bus_reset(rx_bus_reset), .tx_dsp_reset(tx_dsp_reset),.rx_dsp_reset(rx_dsp_reset), .enable_tx(enable_tx),.enable_rx(enable_rx), .interp_rate(interp_rate),.decim_rate(decim_rate), .tx_sample_strobe(tx_sample_strobe),.strobe_interp(strobe_interp), .rx_sample_strobe(rx_sample_strobe),.strobe_decim(strobe_decim), .tx_empty(tx_empty), //.debug_0(rx_a_a),.debug_1(ddc0_in_i), .debug_0(rx_debugbus),.debug_1(ddc0_in_i), .debug_2({rx_sample_strobe,strobe_decim,serial_strobe,serial_addr}),.debug_3({rx_dsp_reset,tx_dsp_reset,rx_bus_reset,tx_bus_reset,enable_rx,tx_underrun,rx_overrun,decim_rate}), .reg_0(reg_0),.reg_1(reg_1),.reg_2(reg_2),.reg_3(reg_3) ); `endif //`ifdef MULTI_ON io_pins io_pins (.io_0(io_tx_a),.io_1(io_rx_a),.io_2(io_tx_b),.io_3(io_rx_b), .reg_0(reg_0),.reg_1(reg_1),.reg_2(reg_2),.reg_3(reg_3), .clock(clk64),.rx_reset(rx_dsp_reset),.tx_reset(tx_dsp_reset), .serial_addr(serial_addr),.serial_data(serial_data),.serial_strobe(serial_strobe)); //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// // Misc Settings setting_reg #(`FR_MODE) sr_misc(.clock(clk64),.reset(rx_dsp_reset),.strobe(serial_strobe),.addr(serial_addr),.in(serial_data),.out(settings)); endmodule // usrp_multi