// // Copyright 2011-2012 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 . // module packet_router #( parameter BUF_SIZE = 9, parameter UDP_BASE = 0, parameter CTRL_BASE = 0 ) ( //wishbone interface for memory mapped CPU frames input wb_clk_i, input wb_rst_i, input wb_we_i, input wb_stb_i, input [15:0] wb_adr_i, input [31:0] wb_dat_i, output [31:0] wb_dat_o, output wb_ack_o, output wb_err_o, output wb_rty_o, //setting register interface input set_stb, input [7:0] set_addr, input [31:0] set_data, input stream_clk, input stream_rst, input stream_clr, //output status register output [31:0] status, output sys_int_o, //want an interrupt? output [31:0] debug, // Input Interfaces (in to router) input [35:0] ser_inp_data, input ser_inp_valid, output ser_inp_ready, input [35:0] dsp0_inp_data, input dsp0_inp_valid, output dsp0_inp_ready, input [35:0] dsp1_inp_data, input dsp1_inp_valid, output dsp1_inp_ready, input [35:0] eth_inp_data, input eth_inp_valid, output eth_inp_ready, input [35:0] err_inp_data, input err_inp_valid, output err_inp_ready, input [35:0] ctl_inp_data, input ctl_inp_valid, output ctl_inp_ready, // Output Interfaces (out of router) output [35:0] ser_out_data, output ser_out_valid, input ser_out_ready, output [35:0] dsp_out_data, output dsp_out_valid, input dsp_out_ready, output [35:0] ctl_out_data, output ctl_out_valid, input ctl_out_ready, output [35:0] eth_out_data, output eth_out_valid, input eth_out_ready ); assign wb_err_o = 1'b0; // Unused for now assign wb_rty_o = 1'b0; // Unused for now //////////////////////////////////////////////////////////////////// // CPU interface to this packet router //////////////////////////////////////////////////////////////////// wire [35:0] cpu_inp_data, cpu_out_data; wire cpu_inp_valid, cpu_out_valid; wire cpu_inp_ready, cpu_out_ready; //////////////////////////////////////////////////////////////////// // Communication interfaces //////////////////////////////////////////////////////////////////// wire [35:0] com_inp_data, com_out_data, udp_out_data; wire com_inp_valid, com_out_valid, udp_out_valid; wire com_inp_ready, com_out_ready, udp_out_ready; //////////////////////////////////////////////////////////////////// // Control signals (setting registers and status signals) // - handshake lines for the CPU communication // - setting registers to program the inspector //////////////////////////////////////////////////////////////////// //setting register for mode control wire [31:0] _sreg_mode_ctrl; wire master_mode_flag; setting_reg #(.my_addr(CTRL_BASE+0), .width(1)) sreg_mode_ctrl( .clk(stream_clk),.rst(stream_rst), .strobe(set_stb),.addr(set_addr),.in(set_data), .out(master_mode_flag),.changed() ); //assign status output signals wire [31:0] cpu_iface_status; assign status = { cpu_iface_status[31:9], master_mode_flag, cpu_iface_status[7:0] }; //////////////////////////////////////////////////////////////////// // Communication input source crossbar // When in master mode: // - serdes input -> comm output combiner // - ethernet input -> comm input inspector // When in slave mode: // - serdes input -> comm input inspector // - ethernet input -> null sink //////////////////////////////////////////////////////////////////// //streaming signals from the crossbar to the combiner wire [35:0] ext_inp_data; wire ext_inp_valid; wire ext_inp_ready; //dummy signals for valve/xbar below wire [35:0] _eth_inp_data; wire _eth_inp_valid; wire _eth_inp_ready; // dummy signals to connect fifo_short wire [35:0] _com_inp_data; wire _com_inp_valid; wire _com_inp_ready; valve36 eth_inp_valve ( .clk(stream_clk), .reset(stream_rst), .clear(stream_clr), .shutoff(~master_mode_flag), .data_i(eth_inp_data), .src_rdy_i(eth_inp_valid), .dst_rdy_o(eth_inp_ready), .data_o(_eth_inp_data), .src_rdy_o(_eth_inp_valid), .dst_rdy_i(_eth_inp_ready) ); crossbar36 com_inp_xbar ( .clk(stream_clk), .reset(stream_rst), .clear(stream_clr), .cross(~master_mode_flag), .data0_i(_eth_inp_data), .src0_rdy_i(_eth_inp_valid), .dst0_rdy_o(_eth_inp_ready), .data1_i(ser_inp_data), .src1_rdy_i(ser_inp_valid), .dst1_rdy_o(ser_inp_ready), .data0_o(_com_inp_data), .src0_rdy_o(_com_inp_valid), .dst0_rdy_i(_com_inp_ready), .data1_o(ext_inp_data), .src1_rdy_o(ext_inp_valid), .dst1_rdy_i(ext_inp_ready) ); // short fifo in the packet inspection path to help timing fifo_short #(.WIDTH(36)) com_inp_fifo (.clk(stream_clk), .reset(stream_rst), .clear(stream_clr), .datain(_com_inp_data), .src_rdy_i(_com_inp_valid), .dst_rdy_o(_com_inp_ready), .dataout(com_inp_data), .src_rdy_o(com_inp_valid), .dst_rdy_i(com_inp_ready), .space(), .occupied() ); //////////////////////////////////////////////////////////////////// // Communication output sink crossbar // When in master mode: // - comm output -> ethernet output // - insp output -> serdes output // When in slave mode: // - com output -> serdes output // - insp output -> null sink //////////////////////////////////////////////////////////////////// //streaming signals from the inspector to the crossbar wire [35:0] ext_out_data; wire ext_out_valid; wire ext_out_ready; //dummy signals for valve/xbar below wire [35:0] _eth_out_data; wire _eth_out_valid; wire _eth_out_ready; crossbar36 com_out_xbar ( .clk(stream_clk), .reset(stream_rst), .clear(stream_clr), .cross(~master_mode_flag), .data0_i(com_out_data), .src0_rdy_i(com_out_valid), .dst0_rdy_o(com_out_ready), .data1_i(ext_out_data), .src1_rdy_i(ext_out_valid), .dst1_rdy_o(ext_out_ready), .data0_o(_eth_out_data), .src0_rdy_o(_eth_out_valid), .dst0_rdy_i(_eth_out_ready), .data1_o(ser_out_data), .src1_rdy_o(ser_out_valid), .dst1_rdy_i(ser_out_ready) ); valve36 eth_out_valve ( .clk(stream_clk), .reset(stream_rst), .clear(stream_clr), .shutoff(~master_mode_flag), .data_i(_eth_out_data), .src_rdy_i(_eth_out_valid), .dst_rdy_o(_eth_out_ready), .data_o(eth_out_data), .src_rdy_o(eth_out_valid), .dst_rdy_i(eth_out_ready) ); //////////////////////////////////////////////////////////////////// // Communication output source combiner (feeds UDP proto machine) // - DSP input // - CPU input // - ERR input //////////////////////////////////////////////////////////////////// //dummy signals to join the the muxes below wire [35:0] _combiner0_data, _combiner1_data, _combiner2_data; wire _combiner0_valid, _combiner1_valid, _combiner2_valid; wire _combiner0_ready, _combiner1_ready, _combiner2_ready; fifo36_mux #(.prio(0)) // No priority, fair sharing _com_output_combiner0( .clk(stream_clk), .reset(stream_rst), .clear(stream_clr), .data0_i(err_inp_data), .src0_rdy_i(err_inp_valid), .dst0_rdy_o(err_inp_ready), .data1_i(cpu_inp_data), .src1_rdy_i(cpu_inp_valid), .dst1_rdy_o(cpu_inp_ready), .data_o(_combiner0_data), .src_rdy_o(_combiner0_valid), .dst_rdy_i(_combiner0_ready) ); fifo36_mux #(.prio(0)) // No priority, fair sharing _com_output_combiner2( .clk(stream_clk), .reset(stream_rst), .clear(stream_clr), .data0_i(_combiner0_data), .src0_rdy_i(_combiner0_valid), .dst0_rdy_o(_combiner0_ready), .data1_i(ctl_inp_data), .src1_rdy_i(ctl_inp_valid), .dst1_rdy_o(ctl_inp_ready), .data_o(_combiner2_data), .src_rdy_o(_combiner2_valid), .dst_rdy_i(_combiner2_ready) ); fifo36_mux #(.prio(0)) // No priority, fair sharing _com_output_combiner1( .clk(stream_clk), .reset(stream_rst), .clear(stream_clr), .data0_i(dsp0_inp_data), .src0_rdy_i(dsp0_inp_valid), .dst0_rdy_o(dsp0_inp_ready), .data1_i(dsp1_inp_data), .src1_rdy_i(dsp1_inp_valid), .dst1_rdy_o(dsp1_inp_ready), .data_o(_combiner1_data), .src_rdy_o(_combiner1_valid), .dst_rdy_i(_combiner1_ready) ); fifo36_mux #(.prio(1)) // Give priority to err/cpu over dsp com_output_source( .clk(stream_clk), .reset(stream_rst), .clear(stream_clr), .data0_i(_combiner2_data), .src0_rdy_i(_combiner2_valid), .dst0_rdy_o(_combiner2_ready), .data1_i(_combiner1_data), .src1_rdy_i(_combiner1_valid), .dst1_rdy_o(_combiner1_ready), .data_o(udp_out_data), .src_rdy_o(udp_out_valid), .dst_rdy_i(udp_out_ready) ); //////////////////////////////////////////////////////////////////// // Interface CPU to memory mapped wishbone // - Uses 1 setting register //////////////////////////////////////////////////////////////////// buffer_int2 #(.BASE(CTRL_BASE+3), .BUF_SIZE(BUF_SIZE)) cpu_to_wb( .clk(stream_clk), .rst(stream_rst | stream_clr), .set_stb(set_stb), .set_addr(set_addr), .set_data(set_data), .status(cpu_iface_status), // Wishbone interface to RAM .wb_clk_i(wb_clk_i), .wb_rst_i(wb_rst_i), .wb_we_i(wb_we_i), .wb_stb_i(wb_stb_i), .wb_adr_i(wb_adr_i), .wb_dat_i(wb_dat_i), .wb_dat_o(wb_dat_o), .wb_ack_o(wb_ack_o), // Write FIFO Interface (from PR and into WB) .wr_data_i(cpu_out_data), .wr_ready_i(cpu_out_valid), .wr_ready_o(cpu_out_ready), // Read FIFO Interface (from WB and into PR) .rd_data_o(cpu_inp_data), .rd_ready_o(cpu_inp_valid), .rd_ready_i(cpu_inp_ready) ); //////////////////////////////////////////////////////////////////// // Packet Dispatcher // - Uses 2 setting registers // - provide buffering before cpu for random + small packet bursts //////////////////////////////////////////////////////////////////// wire [35:0] _cpu_out_data; wire _cpu_out_valid; wire _cpu_out_ready; packet_dispatcher36_x4 #(.BASE(CTRL_BASE+1)) packet_dispatcher( .clk(stream_clk), .rst(stream_rst), .clr(stream_clr), .set_stb(set_stb), .set_addr(set_addr), .set_data(set_data), .com_inp_data(com_inp_data), .com_inp_valid(com_inp_valid), .com_inp_ready(com_inp_ready), .ext_out_data(ext_out_data), .ext_out_valid(ext_out_valid), .ext_out_ready(ext_out_ready), .dsp_out_data(dsp_out_data), .dsp_out_valid(dsp_out_valid), .dsp_out_ready(dsp_out_ready), .ctl_out_data(ctl_out_data), .ctl_out_valid(ctl_out_valid), .ctl_out_ready(ctl_out_ready), .cpu_out_data(_cpu_out_data), .cpu_out_valid(_cpu_out_valid), .cpu_out_ready(_cpu_out_ready) ); fifo_cascade #(.WIDTH(36), .SIZE(9/*512 lines plenty for short pkts*/)) cpu_out_fifo ( .clk(stream_clk), .reset(stream_rst), .clear(stream_clr), .datain(_cpu_out_data), .src_rdy_i(_cpu_out_valid), .dst_rdy_o(_cpu_out_ready), .dataout(cpu_out_data), .src_rdy_o(cpu_out_valid), .dst_rdy_i(cpu_out_ready) ); //////////////////////////////////////////////////////////////////// // UDP TX Protocol machine //////////////////////////////////////////////////////////////////// //dummy signals to connect the components below wire [35:0] _com_out_data; wire _com_out_valid, _com_out_ready; prot_eng_tx #(.BASE(UDP_BASE)) udp_prot_eng_tx (.clk(stream_clk), .reset(stream_rst), .clear(stream_clr), .set_stb(set_stb), .set_addr(set_addr), .set_data(set_data), .datain(udp_out_data), .src_rdy_i(udp_out_valid), .dst_rdy_o(udp_out_ready), .dataout(_com_out_data), .src_rdy_o(_com_out_valid), .dst_rdy_i(_com_out_ready) ); fifo36_mux com_out_mux( .clk(stream_clk), .reset(stream_rst), .clear(stream_clr), .data0_i(ext_inp_data), .src0_rdy_i(ext_inp_valid), .dst0_rdy_o(ext_inp_ready), .data1_i(_com_out_data), .src1_rdy_i(_com_out_valid), .dst1_rdy_o(_com_out_ready), .data_o(com_out_data), .src_rdy_o(com_out_valid), .dst_rdy_i(com_out_ready) ); //////////////////////////////////////////////////////////////////// // Assign debugs //////////////////////////////////////////////////////////////////// assign debug = { //inputs to the router (12) dsp0_inp_ready, dsp0_inp_valid, dsp1_inp_ready, dsp1_inp_valid, err_inp_ready, err_inp_valid, ser_inp_ready, ser_inp_valid, eth_inp_ready, eth_inp_valid, cpu_inp_ready, cpu_inp_valid, //outputs from the router (8) dsp_out_ready, dsp_out_valid, ser_out_ready, ser_out_valid, eth_out_ready, eth_out_valid, cpu_out_ready, cpu_out_valid, //other interfaces (8) ext_inp_ready, ext_inp_valid, com_out_ready, com_out_valid, ext_out_ready, ext_out_valid, com_inp_ready, com_inp_valid, 4'b0 }; endmodule // packet_router