/* Copyright (c) 2014-2020 Alex Forencich Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ // Language: Verilog 2001 `resetall `timescale 1ns / 1ps `default_nettype none /* * ARP ethernet frame transmitter (ARP frame in, Ethernet frame out) */ module arp_eth_tx # ( // Width of AXI stream interfaces in bits parameter DATA_WIDTH = 8, // Propagate tkeep signal // If disabled, tkeep assumed to be 1'b1 parameter KEEP_ENABLE = (DATA_WIDTH>8), // tkeep signal width (words per cycle) parameter KEEP_WIDTH = (DATA_WIDTH/8) ) ( input wire clk, input wire rst, /* * ARP frame input */ input wire s_frame_valid, output wire s_frame_ready, input wire [47:0] s_eth_dest_mac, input wire [47:0] s_eth_src_mac, input wire [15:0] s_eth_type, input wire [15:0] s_arp_htype, input wire [15:0] s_arp_ptype, input wire [15:0] s_arp_oper, input wire [47:0] s_arp_sha, input wire [31:0] s_arp_spa, input wire [47:0] s_arp_tha, input wire [31:0] s_arp_tpa, /* * Ethernet frame output */ output wire m_eth_hdr_valid, input wire m_eth_hdr_ready, output wire [47:0] m_eth_dest_mac, output wire [47:0] m_eth_src_mac, output wire [15:0] m_eth_type, output wire [DATA_WIDTH-1:0] m_eth_payload_axis_tdata, output wire [KEEP_WIDTH-1:0] m_eth_payload_axis_tkeep, output wire m_eth_payload_axis_tvalid, input wire m_eth_payload_axis_tready, output wire m_eth_payload_axis_tlast, output wire m_eth_payload_axis_tuser, /* * Status signals */ output wire busy ); parameter BYTE_LANES = KEEP_ENABLE ? KEEP_WIDTH : 1; parameter HDR_SIZE = 28; parameter CYCLE_COUNT = (HDR_SIZE+BYTE_LANES-1)/BYTE_LANES; parameter PTR_WIDTH = $clog2(CYCLE_COUNT); parameter OFFSET = HDR_SIZE % BYTE_LANES; // bus width assertions initial begin if (BYTE_LANES * 8 != DATA_WIDTH) begin $error("Error: AXI stream interface requires byte (8-bit) granularity (instance %m)"); $finish; end end /* ARP Frame Field Length Destination MAC address 6 octets Source MAC address 6 octets Ethertype (0x0806) 2 octets HTYPE (1) 2 octets PTYPE (0x0800) 2 octets HLEN (6) 1 octets PLEN (4) 1 octets OPER 2 octets SHA Sender MAC 6 octets SPA Sender IP 4 octets THA Target MAC 6 octets TPA Target IP 4 octets This module receives an ARP frame with header fields in parallel and transmits the complete Ethernet payload on an AXI interface. */ // datapath control signals reg store_frame; reg send_arp_header_reg = 1'b0, send_arp_header_next; reg [PTR_WIDTH-1:0] ptr_reg = 0, ptr_next; reg [15:0] arp_htype_reg = 16'd0; reg [15:0] arp_ptype_reg = 16'd0; reg [15:0] arp_oper_reg = 16'd0; reg [47:0] arp_sha_reg = 48'd0; reg [31:0] arp_spa_reg = 32'd0; reg [47:0] arp_tha_reg = 48'd0; reg [31:0] arp_tpa_reg = 32'd0; reg s_frame_ready_reg = 1'b0, s_frame_ready_next; reg m_eth_hdr_valid_reg = 1'b0, m_eth_hdr_valid_next; reg [47:0] m_eth_dest_mac_reg = 48'd0; reg [47:0] m_eth_src_mac_reg = 48'd0; reg [15:0] m_eth_type_reg = 16'd0; reg busy_reg = 1'b0; // internal datapath reg [DATA_WIDTH-1:0] m_eth_payload_axis_tdata_int; reg [KEEP_WIDTH-1:0] m_eth_payload_axis_tkeep_int; reg m_eth_payload_axis_tvalid_int; reg m_eth_payload_axis_tready_int_reg = 1'b0; reg m_eth_payload_axis_tlast_int; reg m_eth_payload_axis_tuser_int; wire m_eth_payload_axis_tready_int_early; assign s_frame_ready = s_frame_ready_reg; assign m_eth_hdr_valid = m_eth_hdr_valid_reg; assign m_eth_dest_mac = m_eth_dest_mac_reg; assign m_eth_src_mac = m_eth_src_mac_reg; assign m_eth_type = m_eth_type_reg; assign busy = busy_reg; always @* begin send_arp_header_next = send_arp_header_reg; ptr_next = ptr_reg; s_frame_ready_next = 1'b0; store_frame = 1'b0; m_eth_hdr_valid_next = m_eth_hdr_valid_reg && !m_eth_hdr_ready; m_eth_payload_axis_tdata_int = {DATA_WIDTH{1'b0}}; m_eth_payload_axis_tkeep_int = {KEEP_WIDTH{1'b0}}; m_eth_payload_axis_tvalid_int = 1'b0; m_eth_payload_axis_tlast_int = 1'b0; m_eth_payload_axis_tuser_int = 1'b0; if (s_frame_ready && s_frame_valid) begin store_frame = 1'b1; m_eth_hdr_valid_next = 1'b1; ptr_next = 0; send_arp_header_next = 1'b1; end if (m_eth_payload_axis_tready_int_reg) begin if (send_arp_header_reg) begin ptr_next = ptr_reg + 1; m_eth_payload_axis_tdata_int = {DATA_WIDTH{1'b0}}; m_eth_payload_axis_tkeep_int = {KEEP_WIDTH{1'b0}}; m_eth_payload_axis_tvalid_int = 1'b1; m_eth_payload_axis_tlast_int = 1'b0; m_eth_payload_axis_tuser_int = 1'b0; `define _HEADER_FIELD_(offset, field) \ if (ptr_reg == offset/BYTE_LANES) begin \ m_eth_payload_axis_tdata_int[(offset%BYTE_LANES)*8 +: 8] = field; \ m_eth_payload_axis_tkeep_int[offset%BYTE_LANES] = 1'b1; \ end `_HEADER_FIELD_(0, arp_htype_reg[1*8 +: 8]) `_HEADER_FIELD_(1, arp_htype_reg[0*8 +: 8]) `_HEADER_FIELD_(2, arp_ptype_reg[1*8 +: 8]) `_HEADER_FIELD_(3, arp_ptype_reg[0*8 +: 8]) `_HEADER_FIELD_(4, 8'd6) `_HEADER_FIELD_(5, 8'd4) `_HEADER_FIELD_(6, arp_oper_reg[1*8 +: 8]) `_HEADER_FIELD_(7, arp_oper_reg[0*8 +: 8]) `_HEADER_FIELD_(8, arp_sha_reg[5*8 +: 8]) `_HEADER_FIELD_(9, arp_sha_reg[4*8 +: 8]) `_HEADER_FIELD_(10, arp_sha_reg[3*8 +: 8]) `_HEADER_FIELD_(11, arp_sha_reg[2*8 +: 8]) `_HEADER_FIELD_(12, arp_sha_reg[1*8 +: 8]) `_HEADER_FIELD_(13, arp_sha_reg[0*8 +: 8]) `_HEADER_FIELD_(14, arp_spa_reg[3*8 +: 8]) `_HEADER_FIELD_(15, arp_spa_reg[2*8 +: 8]) `_HEADER_FIELD_(16, arp_spa_reg[1*8 +: 8]) `_HEADER_FIELD_(17, arp_spa_reg[0*8 +: 8]) `_HEADER_FIELD_(18, arp_tha_reg[5*8 +: 8]) `_HEADER_FIELD_(19, arp_tha_reg[4*8 +: 8]) `_HEADER_FIELD_(20, arp_tha_reg[3*8 +: 8]) `_HEADER_FIELD_(21, arp_tha_reg[2*8 +: 8]) `_HEADER_FIELD_(22, arp_tha_reg[1*8 +: 8]) `_HEADER_FIELD_(23, arp_tha_reg[0*8 +: 8]) `_HEADER_FIELD_(24, arp_tpa_reg[3*8 +: 8]) `_HEADER_FIELD_(25, arp_tpa_reg[2*8 +: 8]) `_HEADER_FIELD_(26, arp_tpa_reg[1*8 +: 8]) `_HEADER_FIELD_(27, arp_tpa_reg[0*8 +: 8]) if (ptr_reg == 27/BYTE_LANES) begin m_eth_payload_axis_tlast_int = 1'b1; send_arp_header_next = 1'b0; end `undef _HEADER_FIELD_ end end s_frame_ready_next = !m_eth_hdr_valid_next && !send_arp_header_next; end always @(posedge clk) begin send_arp_header_reg <= send_arp_header_next; ptr_reg <= ptr_next; s_frame_ready_reg <= s_frame_ready_next; m_eth_hdr_valid_reg <= m_eth_hdr_valid_next; busy_reg <= send_arp_header_next; if (store_frame) begin m_eth_dest_mac_reg <= s_eth_dest_mac; m_eth_src_mac_reg <= s_eth_src_mac; m_eth_type_reg <= s_eth_type; arp_htype_reg <= s_arp_htype; arp_ptype_reg <= s_arp_ptype; arp_oper_reg <= s_arp_oper; arp_sha_reg <= s_arp_sha; arp_spa_reg <= s_arp_spa; arp_tha_reg <= s_arp_tha; arp_tpa_reg <= s_arp_tpa; end if (rst) begin send_arp_header_reg <= 1'b0; ptr_reg <= 0; s_frame_ready_reg <= 1'b0; m_eth_hdr_valid_reg <= 1'b0; busy_reg <= 1'b0; end end // output datapath logic reg [DATA_WIDTH-1:0] m_eth_payload_axis_tdata_reg = {DATA_WIDTH{1'b0}}; reg [KEEP_WIDTH-1:0] m_eth_payload_axis_tkeep_reg = {KEEP_WIDTH{1'b0}}; reg m_eth_payload_axis_tvalid_reg = 1'b0, m_eth_payload_axis_tvalid_next; reg m_eth_payload_axis_tlast_reg = 1'b0; reg m_eth_payload_axis_tuser_reg = 1'b0; reg [DATA_WIDTH-1:0] temp_m_eth_payload_axis_tdata_reg = {DATA_WIDTH{1'b0}}; reg [KEEP_WIDTH-1:0] temp_m_eth_payload_axis_tkeep_reg = {KEEP_WIDTH{1'b0}}; reg temp_m_eth_payload_axis_tvalid_reg = 1'b0, temp_m_eth_payload_axis_tvalid_next; reg temp_m_eth_payload_axis_tlast_reg = 1'b0; reg temp_m_eth_payload_axis_tuser_reg = 1'b0; // datapath control reg store_eth_payload_int_to_output; reg store_eth_payload_int_to_temp; reg store_eth_payload_axis_temp_to_output; assign m_eth_payload_axis_tdata = m_eth_payload_axis_tdata_reg; assign m_eth_payload_axis_tkeep = KEEP_ENABLE ? m_eth_payload_axis_tkeep_reg : {KEEP_WIDTH{1'b1}}; assign m_eth_payload_axis_tvalid = m_eth_payload_axis_tvalid_reg; assign m_eth_payload_axis_tlast = m_eth_payload_axis_tlast_reg; assign m_eth_payload_axis_tuser = m_eth_payload_axis_tuser_reg; // enable ready input next cycle if output is ready or if both output registers are empty assign m_eth_payload_axis_tready_int_early = m_eth_payload_axis_tready || (!temp_m_eth_payload_axis_tvalid_reg && !m_eth_payload_axis_tvalid_reg); always @* begin // transfer sink ready state to source m_eth_payload_axis_tvalid_next = m_eth_payload_axis_tvalid_reg; temp_m_eth_payload_axis_tvalid_next = temp_m_eth_payload_axis_tvalid_reg; store_eth_payload_int_to_output = 1'b0; store_eth_payload_int_to_temp = 1'b0; store_eth_payload_axis_temp_to_output = 1'b0; if (m_eth_payload_axis_tready_int_reg) begin // input is ready if (m_eth_payload_axis_tready || !m_eth_payload_axis_tvalid_reg) begin // output is ready or currently not valid, transfer data to output m_eth_payload_axis_tvalid_next = m_eth_payload_axis_tvalid_int; store_eth_payload_int_to_output = 1'b1; end else begin // output is not ready, store input in temp temp_m_eth_payload_axis_tvalid_next = m_eth_payload_axis_tvalid_int; store_eth_payload_int_to_temp = 1'b1; end end else if (m_eth_payload_axis_tready) begin // input is not ready, but output is ready m_eth_payload_axis_tvalid_next = temp_m_eth_payload_axis_tvalid_reg; temp_m_eth_payload_axis_tvalid_next = 1'b0; store_eth_payload_axis_temp_to_output = 1'b1; end end always @(posedge clk) begin m_eth_payload_axis_tvalid_reg <= m_eth_payload_axis_tvalid_next; m_eth_payload_axis_tready_int_reg <= m_eth_payload_axis_tready_int_early; temp_m_eth_payload_axis_tvalid_reg <= temp_m_eth_payload_axis_tvalid_next; // datapath if (store_eth_payload_int_to_output) begin m_eth_payload_axis_tdata_reg <= m_eth_payload_axis_tdata_int; m_eth_payload_axis_tkeep_reg <= m_eth_payload_axis_tkeep_int; m_eth_payload_axis_tlast_reg <= m_eth_payload_axis_tlast_int; m_eth_payload_axis_tuser_reg <= m_eth_payload_axis_tuser_int; end else if (store_eth_payload_axis_temp_to_output) begin m_eth_payload_axis_tdata_reg <= temp_m_eth_payload_axis_tdata_reg; m_eth_payload_axis_tkeep_reg <= temp_m_eth_payload_axis_tkeep_reg; m_eth_payload_axis_tlast_reg <= temp_m_eth_payload_axis_tlast_reg; m_eth_payload_axis_tuser_reg <= temp_m_eth_payload_axis_tuser_reg; end if (store_eth_payload_int_to_temp) begin temp_m_eth_payload_axis_tdata_reg <= m_eth_payload_axis_tdata_int; temp_m_eth_payload_axis_tkeep_reg <= m_eth_payload_axis_tkeep_int; temp_m_eth_payload_axis_tlast_reg <= m_eth_payload_axis_tlast_int; temp_m_eth_payload_axis_tuser_reg <= m_eth_payload_axis_tuser_int; end if (rst) begin m_eth_payload_axis_tvalid_reg <= 1'b0; m_eth_payload_axis_tready_int_reg <= 1'b0; temp_m_eth_payload_axis_tvalid_reg <= 1'b0; end end endmodule `resetall