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|
module packet_router
#(
parameter BUF_SIZE = 9,
parameter UDP_BASE = 0,
parameter STATUS_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 reg 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] dsp_inp_data, input dsp_inp_valid, output dsp_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,
// 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] 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
always @(posedge wb_clk_i)
wb_ack_o <= wb_stb_i & ~wb_ack_o;
//which buffer: 0 = CPU read buffer, 1 = CPU write buffer
wire which_buf = wb_adr_i[BUF_SIZE+2];
////////////////////////////////////////////////////////////////////
// CPU interface to this packet router
////////////////////////////////////////////////////////////////////
wire [35:0] cpu_inp_data;
wire cpu_inp_valid;
wire cpu_inp_ready;
wire [35:0] cpu_out_data;
wire cpu_out_valid;
wire cpu_out_ready;
////////////////////////////////////////////////////////////////////
// Communication interfaces
////////////////////////////////////////////////////////////////////
wire [35:0] com_inp_data;
wire com_inp_valid;
wire com_inp_ready;
wire [35:0] com_out_data;
wire com_out_valid;
wire com_out_ready;
wire [35:0] udp_out_data;
wire udp_out_valid;
wire udp_out_ready;
////////////////////////////////////////////////////////////////////
// status and control handshakes
////////////////////////////////////////////////////////////////////
reg cpu_out_hs_ctrl;
reg cpu_inp_hs_ctrl;
reg master_mode_flag;
reg [BUF_SIZE-1:0] cpu_inp_line_count;
reg [31:0] my_ip_addr;
wire [31:0] control;
wire control_changed;
setting_reg #(.my_addr(STATUS_BASE)) sreg(
.clk(stream_clk),.rst(stream_rst),
.strobe(set_stb),.addr(set_addr),.in(set_data),
.out(control),.changed(control_changed)
);
//grab the pertinent control settings
always @(posedge control_changed) begin
cpu_out_hs_ctrl <= control[0];
cpu_inp_hs_ctrl <= control[1];
master_mode_flag <= control[2];
cpu_inp_line_count <= control[BUF_SIZE-1+16:0+16];
case (control[5:4])
2'b01:
my_ip_addr[15:0] <= control[31:16];
2'b10:
my_ip_addr[31:16] <= control[31:16];
endcase
end
wire cpu_out_hs_stat;
assign status[0] = cpu_out_hs_stat;
wire [BUF_SIZE-1:0] cpu_out_line_count;
assign status[BUF_SIZE-1+16:0+16] = cpu_out_line_count;
wire cpu_inp_hs_stat;
assign status[1] = cpu_inp_hs_stat;
////////////////////////////////////////////////////////////////////
// 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] crs_inp_data;
wire crs_inp_valid;
wire crs_inp_ready;
//dummy signals for valve/xbar below
wire [35:0] _eth_inp_data;
wire _eth_inp_valid;
wire _eth_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(crs_inp_data), .src1_rdy_o(crs_inp_valid), .dst1_rdy_i(crs_inp_ready)
);
////////////////////////////////////////////////////////////////////
// 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] crs_out_data;
wire crs_out_valid;
wire crs_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(crs_out_data), .src1_rdy_i(crs_out_valid), .dst1_rdy_o(crs_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 framer
// - CPU input
// - Error input
// - Crossbar input
////////////////////////////////////////////////////////////////////
//streaming signals from the dsp framer to the combiner
wire [35:0] dsp_frm_data;
wire dsp_frm_valid;
wire dsp_frm_ready;
//dummy signals to join the the muxes below
wire [35:0] _combiner0_data, _combiner1_data;
wire _combiner0_valid, _combiner1_valid;
wire _combiner0_ready, _combiner1_ready;
fifo36_mux _com_output_combiner0(
.clk(stream_clk), .reset(stream_rst), .clear(stream_clr),
.data0_i(dsp_frm_data), .src0_rdy_i(dsp_frm_valid), .dst0_rdy_o(dsp_frm_ready),
.data1_i(err_inp_data), .src1_rdy_i(err_inp_valid), .dst1_rdy_o(err_inp_ready),
.data_o(_combiner0_data), .src_rdy_o(_combiner0_valid), .dst_rdy_i(_combiner0_ready)
);
fifo36_mux _com_output_combiner1(
.clk(stream_clk), .reset(stream_rst), .clear(stream_clr),
.data0_i(32'b0), .src0_rdy_i(1'b0), .dst0_rdy_o(), //mux out from dsp1 can go here
.data1_i(cpu_inp_data), .src1_rdy_i(cpu_inp_valid), .dst1_rdy_o(cpu_inp_ready),
.data_o(_combiner1_data), .src_rdy_o(_combiner1_valid), .dst_rdy_i(_combiner1_ready)
);
fifo36_mux com_output_source(
.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(_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 output to memory mapped wishbone
////////////////////////////////////////////////////////////////////
localparam CPU_OUT_STATE_WAIT_SOF = 0;
localparam CPU_OUT_STATE_WAIT_EOF = 1;
localparam CPU_OUT_STATE_WAIT_CTRL_HI = 2;
localparam CPU_OUT_STATE_WAIT_CTRL_LO = 3;
reg [1:0] cpu_out_state;
reg [BUF_SIZE-1:0] cpu_out_addr;
assign cpu_out_line_count = cpu_out_addr;
wire [BUF_SIZE-1:0] cpu_out_addr_next = cpu_out_addr + 1'b1;
wire cpu_out_reading = (
cpu_out_state == CPU_OUT_STATE_WAIT_SOF ||
cpu_out_state == CPU_OUT_STATE_WAIT_EOF
)? 1'b1 : 1'b0;
wire cpu_out_we = cpu_out_reading;
assign cpu_out_ready = cpu_out_reading;
assign cpu_out_hs_stat = (cpu_out_state == CPU_OUT_STATE_WAIT_CTRL_HI)? 1'b1 : 1'b0;
RAMB16_S36_S36 cpu_out_buff(
//port A = wishbone memory mapped address space (output only)
.DOA(wb_dat_o),.ADDRA(wb_adr_i[BUF_SIZE+1:2]),.CLKA(wb_clk_i),.DIA(36'b0),.DIPA(4'h0),
.ENA(wb_stb_i & (which_buf == 1'b0)),.SSRA(0),.WEA(wb_we_i),
//port B = packet router interface to CPU (input only)
.DOB(),.ADDRB(cpu_out_addr),.CLKB(stream_clk),.DIB(cpu_out_data),.DIPB(4'h0),
.ENB(cpu_out_we),.SSRB(0),.WEB(cpu_out_we)
);
always @(posedge stream_clk)
if(stream_rst | stream_clr) begin
cpu_out_state <= CPU_OUT_STATE_WAIT_SOF;
cpu_out_addr <= 0;
end
else begin
case(cpu_out_state)
CPU_OUT_STATE_WAIT_SOF: begin
if (cpu_out_ready & cpu_out_valid & cpu_out_data[32]) begin
cpu_out_state <= CPU_OUT_STATE_WAIT_EOF;
cpu_out_addr <= cpu_out_addr_next;
end
end
CPU_OUT_STATE_WAIT_EOF: begin
if (cpu_out_ready & cpu_out_valid & cpu_out_data[33]) begin
cpu_out_state <= CPU_OUT_STATE_WAIT_CTRL_HI;
end
if (cpu_out_ready & cpu_out_valid) begin
cpu_out_addr <= cpu_out_addr_next;
end
end
CPU_OUT_STATE_WAIT_CTRL_HI: begin
if (cpu_out_hs_ctrl == 1'b1) begin
cpu_out_state <= CPU_OUT_STATE_WAIT_CTRL_LO;
end
end
CPU_OUT_STATE_WAIT_CTRL_LO: begin
if (cpu_out_hs_ctrl == 1'b0) begin
cpu_out_state <= CPU_OUT_STATE_WAIT_SOF;
end
cpu_out_addr <= 0; //reset the address counter
end
endcase //cpu_out_state
end
////////////////////////////////////////////////////////////////////
// Interface CPU input to memory mapped wishbone
////////////////////////////////////////////////////////////////////
localparam CPU_INP_STATE_WAIT_CTRL_HI = 0;
localparam CPU_INP_STATE_WAIT_CTRL_LO = 1;
localparam CPU_INP_STATE_UNLOAD = 2;
reg [1:0] cpu_inp_state;
reg [BUF_SIZE-1:0] cpu_inp_addr;
wire [BUF_SIZE-1:0] cpu_inp_addr_next = cpu_inp_addr + 1'b1;
reg [BUF_SIZE-1:0] cpu_inp_line_count_reg;
assign cpu_inp_data[35:32] =
(cpu_inp_addr == 1 )? 4'b0001 : (
(cpu_inp_addr == cpu_inp_line_count_reg)? 4'b0010 : (
4'b0000));
assign cpu_inp_valid = (cpu_inp_state == CPU_INP_STATE_UNLOAD)? 1'b1 : 1'b0;
assign cpu_inp_hs_stat = (cpu_inp_state == CPU_INP_STATE_WAIT_CTRL_HI)? 1'b1 : 1'b0;
RAMB16_S36_S36 cpu_inp_buff(
//port A = wishbone memory mapped address space (input only)
.DOA(),.ADDRA(wb_adr_i[BUF_SIZE+1:2]),.CLKA(wb_clk_i),.DIA(wb_dat_i),.DIPA(4'h0),
.ENA(wb_stb_i & (which_buf == 1'b1)),.SSRA(0),.WEA(wb_we_i),
//port B = packet router interface from CPU (output only)
.DOB(cpu_inp_data[31:0]),.ADDRB(cpu_inp_addr),.CLKB(stream_clk),.DIB(36'b0),.DIPB(4'h0),
.ENB(cpu_inp_ready & cpu_inp_valid),.SSRB(0),.WEB(1'b0)
);
always @(posedge stream_clk)
if(stream_rst | stream_clr) begin
cpu_inp_state <= CPU_INP_STATE_WAIT_CTRL_HI;
cpu_inp_addr <= 0;
end
else begin
case(cpu_inp_state)
CPU_INP_STATE_WAIT_CTRL_HI: begin
if (cpu_inp_hs_ctrl == 1'b1) begin
cpu_inp_state <= CPU_INP_STATE_WAIT_CTRL_LO;
end
cpu_inp_line_count_reg <= cpu_inp_line_count;
end
CPU_INP_STATE_WAIT_CTRL_LO: begin
if (cpu_inp_hs_ctrl == 1'b0) begin
cpu_inp_state <= CPU_INP_STATE_UNLOAD;
cpu_inp_addr <= cpu_inp_addr_next;
end
end
CPU_INP_STATE_UNLOAD: begin
if (cpu_inp_ready & cpu_inp_valid) begin
if (cpu_inp_data[33]) begin
cpu_inp_addr <= 0;
cpu_inp_state <= CPU_INP_STATE_WAIT_CTRL_HI;
end
else begin
cpu_inp_addr <= cpu_inp_addr_next;
end
end
end
endcase //cpu_inp_state
end
////////////////////////////////////////////////////////////////////
// Communication input inspector
// - inspect com input and send it to CPU, DSP, or COM
////////////////////////////////////////////////////////////////////
localparam COM_INSP_STATE_READ_COM_PRE = 0;
localparam COM_INSP_STATE_READ_COM = 1;
localparam COM_INSP_STATE_WRITE_REGS = 2;
localparam COM_INSP_STATE_WRITE_LIVE = 3;
localparam COM_INSP_DEST_FP_THIS = 0;
localparam COM_INSP_DEST_FP_OTHER = 1;
localparam COM_INSP_DEST_SP_BOTH = 2;
localparam COM_INSP_MAX_NUM_DREGS = 12; //padded_eth + ip + udp + vrt_hdr
localparam COM_INSP_DREGS_DSP_OFFSET = 11; //offset to start dsp at
//output inspector interfaces
wire [35:0] com_insp_out_fp_this_data;
wire com_insp_out_fp_this_valid;
wire com_insp_out_fp_this_ready;
wire [35:0] com_insp_out_fp_other_data;
wire com_insp_out_fp_other_valid;
wire com_insp_out_fp_other_ready;
wire [35:0] com_insp_out_sp_both_data;
wire com_insp_out_sp_both_valid;
wire com_insp_out_sp_both_ready;
//connect this fast-path signals directly to the DSP out
assign dsp_out_data = com_insp_out_fp_this_data;
assign dsp_out_valid = com_insp_out_fp_this_valid;
assign com_insp_out_fp_this_ready = dsp_out_ready;
reg [1:0] com_insp_state;
reg [1:0] com_insp_dest;
reg [3:0] com_insp_dreg_count; //data registers to buffer headers
wire [3:0] com_insp_dreg_count_next = com_insp_dreg_count + 1'b1;
wire com_insp_dreg_counter_done = (com_insp_dreg_count_next == COM_INSP_MAX_NUM_DREGS)? 1'b1 : 1'b0;
reg [35:0] com_insp_dregs [COM_INSP_MAX_NUM_DREGS-1:0];
//Inspection logic:
wire com_inp_dregs_is_data = 1'b1
&& (com_insp_dregs[3][15:0] == 16'h800) //ethertype IPv4
&& (com_insp_dregs[6][23:16] == 8'h11) //protocol UDP
&& (com_insp_dregs[9][15:0] == 16'd49153) //UDP data port
&& (com_inp_data[31:0] != 32'h0) //VRT hdr non-zero
;
wire com_inp_dregs_my_ip_match = (my_ip_addr == com_insp_dregs[8][31:0])? 1'b1 : 1'b0;
wire com_inp_dregs_is_data_here = com_inp_dregs_is_data & com_inp_dregs_my_ip_match;
wire com_inp_dregs_is_data_there = com_inp_dregs_is_data & ~com_inp_dregs_my_ip_match;
//Inspector output flags special case:
//Inject SOF into flags at first DSP line.
wire [3:0] com_insp_out_flags = (
(com_insp_dreg_count == COM_INSP_DREGS_DSP_OFFSET) &&
(com_insp_dest == COM_INSP_DEST_FP_THIS)
)? 4'b0001 : com_insp_dregs[com_insp_dreg_count][35:32];
//The communication inspector ouput data and valid signals:
//Mux between com input and data registers based on the state.
wire [35:0] com_insp_out_data = (com_insp_state == COM_INSP_STATE_WRITE_REGS)?
{com_insp_out_flags, com_insp_dregs[com_insp_dreg_count][31:0]} : com_inp_data
;
wire com_insp_out_valid =
(com_insp_state == COM_INSP_STATE_WRITE_REGS)? 1'b1 : (
(com_insp_state == COM_INSP_STATE_WRITE_LIVE)? com_inp_valid : (
1'b0));
//The communication inspector ouput ready signal:
//Mux between the various destination ready signals.
wire com_insp_out_ready =
(com_insp_dest == COM_INSP_DEST_FP_THIS) ? com_insp_out_fp_this_ready : (
(com_insp_dest == COM_INSP_DEST_FP_OTHER)? com_insp_out_fp_other_ready : (
(com_insp_dest == COM_INSP_DEST_SP_BOTH) ? com_insp_out_sp_both_ready : (
1'b0)));
//Always connected output data lines.
assign com_insp_out_fp_this_data = com_insp_out_data;
assign com_insp_out_fp_other_data = com_insp_out_data;
assign com_insp_out_sp_both_data = com_insp_out_data;
//Destination output valid signals:
//Comes from inspector valid when destination is selected, and otherwise low.
assign com_insp_out_fp_this_valid = (com_insp_dest == COM_INSP_DEST_FP_THIS) ? com_insp_out_valid : 1'b0;
assign com_insp_out_fp_other_valid = (com_insp_dest == COM_INSP_DEST_FP_OTHER)? com_insp_out_valid : 1'b0;
assign com_insp_out_sp_both_valid = (com_insp_dest == COM_INSP_DEST_SP_BOTH) ? com_insp_out_valid : 1'b0;
//The communication inspector ouput ready signal:
//Always ready when storing to data registers,
//comes from inspector ready output when live,
//and otherwise low.
assign com_inp_ready =
(com_insp_state == COM_INSP_STATE_READ_COM_PRE) ? 1'b1 : (
(com_insp_state == COM_INSP_STATE_READ_COM) ? 1'b1 : (
(com_insp_state == COM_INSP_STATE_WRITE_LIVE) ? com_insp_out_ready : (
1'b0)));
always @(posedge stream_clk)
if(stream_rst | stream_clr) begin
com_insp_state <= COM_INSP_STATE_READ_COM_PRE;
com_insp_dreg_count <= 0;
end
else begin
case(com_insp_state)
COM_INSP_STATE_READ_COM_PRE: begin
if (com_inp_ready & com_inp_valid & com_inp_data[32]) begin
com_insp_state <= COM_INSP_STATE_READ_COM;
com_insp_dreg_count <= com_insp_dreg_count_next;
com_insp_dregs[com_insp_dreg_count] <= com_inp_data;
end
end
COM_INSP_STATE_READ_COM: begin
if (com_inp_ready & com_inp_valid) begin
com_insp_dregs[com_insp_dreg_count] <= com_inp_data;
if (com_inp_dregs_is_data_here & com_insp_dreg_counter_done) begin
com_insp_dest <= COM_INSP_DEST_FP_THIS;
com_insp_state <= COM_INSP_STATE_WRITE_REGS;
com_insp_dreg_count <= COM_INSP_DREGS_DSP_OFFSET;
end
else if (com_inp_dregs_is_data_there & com_insp_dreg_counter_done) begin
com_insp_dest <= COM_INSP_DEST_FP_OTHER;
com_insp_state <= COM_INSP_STATE_WRITE_REGS;
com_insp_dreg_count <= 0;
end
else if (com_inp_data[33] | com_insp_dreg_counter_done) begin
com_insp_dest <= COM_INSP_DEST_SP_BOTH;
com_insp_state <= COM_INSP_STATE_WRITE_REGS;
com_insp_dreg_count <= 0;
end
else begin
com_insp_dreg_count <= com_insp_dreg_count_next;
end
end
end
COM_INSP_STATE_WRITE_REGS: begin
if (com_insp_out_ready & com_insp_out_valid) begin
if (com_insp_out_data[33]) begin
com_insp_state <= COM_INSP_STATE_READ_COM_PRE;
com_insp_dreg_count <= 0;
end
else if (com_insp_dreg_counter_done) begin
com_insp_state <= COM_INSP_STATE_WRITE_LIVE;
com_insp_dreg_count <= 0;
end
else begin
com_insp_dreg_count <= com_insp_dreg_count_next;
end
end
end
COM_INSP_STATE_WRITE_LIVE: begin
if (com_insp_out_ready & com_insp_out_valid & com_insp_out_data[33]) begin
com_insp_state <= COM_INSP_STATE_READ_COM_PRE;
end
end
endcase //com_insp_state
end
////////////////////////////////////////////////////////////////////
// Serdes crossbar output source
// - combine slow-path data with fast-path other data
// - slow-path data is duplicated to this and CPU out
////////////////////////////////////////////////////////////////////
//dummy signals to join the the splitter and mux below
wire [35:0] _sp_split_to_mux_data;
wire _sp_split_to_mux_valid;
wire _sp_split_to_mux_ready;
splitter36 crs_out_src0(
.clk(stream_clk), .rst(stream_rst), .clr(stream_clr),
.inp_data(com_insp_out_sp_both_data), .inp_valid(com_insp_out_sp_both_valid), .inp_ready(com_insp_out_sp_both_ready),
.out0_data(_sp_split_to_mux_data), .out0_valid(_sp_split_to_mux_valid), .out0_ready(_sp_split_to_mux_ready),
.out1_data(cpu_out_data), .out1_valid(cpu_out_valid), .out1_ready(cpu_out_ready)
);
fifo36_mux crs_out_src1(
.clk(stream_clk), .reset(stream_rst), .clear(stream_clr),
.data0_i(com_insp_out_fp_other_data), .src0_rdy_i(com_insp_out_fp_other_valid), .dst0_rdy_o(com_insp_out_fp_other_ready),
.data1_i(_sp_split_to_mux_data), .src1_rdy_i(_sp_split_to_mux_valid), .dst1_rdy_o(_sp_split_to_mux_ready),
.data_o(crs_out_data), .src_rdy_o(crs_out_valid), .dst_rdy_i(crs_out_ready)
);
////////////////////////////////////////////////////////////////////
// DSP input framer
////////////////////////////////////////////////////////////////////
dsp_framer36 #(.BUF_SIZE(BUF_SIZE)) dsp0_framer36(
.clk(stream_clk), .rst(stream_rst), .clr(stream_clr),
.inp_data(dsp_inp_data), .inp_valid(dsp_inp_valid), .inp_ready(dsp_inp_ready),
.out_data(dsp_frm_data), .out_valid(dsp_frm_valid), .out_ready(dsp_frm_ready)
);
////////////////////////////////////////////////////////////////////
// UDP TX Protocol machine
////////////////////////////////////////////////////////////////////
//dummy signals to connect the components below
wire [18:0] _udp_r2s_data, _udp_s2p_data, _udp_p2s_data, _udp_s2r_data;
wire _udp_r2s_valid, _udp_s2p_valid, _udp_p2s_valid, _udp_s2r_valid;
wire _udp_r2s_ready, _udp_s2p_ready, _udp_p2s_ready, _udp_s2r_ready;
wire [35:0] _com_out_data;
wire _com_out_valid, _com_out_ready;
fifo36_to_fifo19 udp_fifo36_to_fifo19
(.clk(stream_clk), .reset(stream_rst), .clear(stream_clr),
.f36_datain(udp_out_data), .f36_src_rdy_i(udp_out_valid), .f36_dst_rdy_o(udp_out_ready),
.f19_dataout(_udp_r2s_data), .f19_src_rdy_o(_udp_r2s_valid), .f19_dst_rdy_i(_udp_r2s_ready) );
fifo_short #(.WIDTH(19)) udp_shortfifo19_inp
(.clk(stream_clk), .reset(stream_rst), .clear(stream_clr),
.datain(_udp_r2s_data), .src_rdy_i(_udp_r2s_valid), .dst_rdy_o(_udp_r2s_ready),
.dataout(_udp_s2p_data), .src_rdy_o(_udp_s2p_valid), .dst_rdy_i(_udp_s2p_ready),
.space(), .occupied() );
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_s2p_data), .src_rdy_i(_udp_s2p_valid), .dst_rdy_o(_udp_s2p_ready),
.dataout(_udp_p2s_data), .src_rdy_o(_udp_p2s_valid), .dst_rdy_i(_udp_p2s_ready) );
fifo_short #(.WIDTH(19)) udp_shortfifo19_out
(.clk(stream_clk), .reset(stream_rst), .clear(stream_clr),
.datain(_udp_p2s_data), .src_rdy_i(_udp_p2s_valid), .dst_rdy_o(_udp_p2s_ready),
.dataout(_udp_s2r_data), .src_rdy_o(_udp_s2r_valid), .dst_rdy_i(_udp_s2r_ready),
.space(), .occupied() );
fifo19_to_fifo36 udp_fifo19_to_fifo36
(.clk(stream_clk), .reset(stream_rst), .clear(stream_clr),
.f19_datain(_udp_s2r_data), .f19_src_rdy_i(_udp_s2r_valid), .f19_dst_rdy_o(_udp_s2r_ready),
.f36_dataout(_com_out_data), .f36_src_rdy_o(_com_out_valid), .f36_dst_rdy_i(_com_out_ready) );
fifo36_mux com_out_mux(
.clk(stream_clk), .reset(stream_rst), .clear(stream_clr),
.data0_i(crs_inp_data), .src0_rdy_i(crs_inp_valid), .dst0_rdy_o(crs_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 (8)
dsp_inp_ready, dsp_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,
//inspector interfaces (8)
com_inp_ready, com_inp_valid,
com_insp_out_fp_this_ready, com_insp_out_fp_this_valid,
com_insp_out_fp_other_ready, com_insp_out_fp_other_valid,
com_insp_out_sp_both_ready, com_insp_out_sp_both_valid,
//other interfaces (8)
crs_inp_ready, crs_inp_valid,
com_out_ready, com_out_valid,
crs_out_ready, crs_out_valid,
_sp_split_to_mux_ready, _sp_split_to_mux_valid
};
endmodule // packet_router
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