FPGA——三速自适应以太网设计(1)基本模块

FPGA——以太网设计(1)基本模块

  • 1. 协议解析
    • (1)MAC层
    • (2)IP层 和 ARP层
    • (3)UDP层 和 ICMP层
  • 2.1 MAC接收模块
  • 2.2 MAC发送模块
  • 3.1 IP接收模块
  • 3.2 IP发送模块
  • 4.1 UDP接收模块
  • 4.2 UDP发送模块
  • 5.1 ICMP接收模块
  • 5.2 ICMP发送模块
  • 6.1 ARP接收模块
  • 6.2 ARP发送模块
  • 6.3 ARP表模块
  • 7 CRC数据对比模块
  • 8 MAC下ARP和IP数据分流模块
  • 9 数据流仲裁模块
  • 模块收发组合
    • 1 MAC层收发
      • 2 ARP层收发
      • 2 IP层收发
        • 3 ICMP层收发
        • 3 UDP层收发
  • UDP协议栈

1. 协议解析

每层都嵌套在上层的数据字段
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(1)MAC层

以太网帧长: 64B~1518B
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(2)IP层 和 ARP层

IP层
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ARP层
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(3)UDP层 和 ICMP层

UDP层
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ICMP层
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2.1 MAC接收模块

module MAC_rx#(parameter       P_TARTGET_MAC   =   {8'h00,8'h00,8'h00,8'h00,8'h00,8'h00},P_SOURCE_MAC    =   {8'h00,8'h00,8'h00,8'h00,8'h00,8'h00},P_CRC_CHECK     =   1
)(input           i_clk               ,input           i_rst               ,/*--------info port--------*/   input  [47:0]   i_target_mac        ,input           i_target_mac_valid  ,input  [47:0]   i_source_mac        ,input           i_source_mac_valid  ,/*--------data port--------*/output [15:0]   o_post_type         ,output [7 :0]   o_post_data         ,output          o_post_last         ,output          o_post_valid        ,output [47:0]   o_rec_src_mac       ,output          o_rec_src_valid     ,output          o_crc_error         ,   output          o_crc_valid         ,    /*--------GMII port--------*/input  [7 :0]   i_GMII_data         ,input           i_GMII_valid        
);
/***************function**************//***************parameter*************//***************port******************/             /***************mechine***************//***************reg*******************/
reg                 ro_post_last          ;
reg                 ro_post_valid         ;
reg  [47:0]         ro_rec_src_mac      ;
reg                 ro_rec_src_valid    ;
reg                 ro_crc_error        ;
reg  [7 :0]         ri_GMII_data        ;
reg                 ri_GMII_valid       ;
reg  [7 :0]         ri_GMII_data_1d     ;
reg                 ri_GMII_valid_1d    ;
reg  [7 :0]         ri_GMII_data_2d     ;
reg                 ri_GMII_valid_2d    ;
reg  [7 :0]         ri_GMII_data_3d     ;
reg                 ri_GMII_valid_3d    ;
reg  [7 :0]         ri_GMII_data_4d     ;
reg                 ri_GMII_valid_4d    ;
reg  [7 :0]         ri_GMII_data_5d     ;
reg                 ri_GMII_valid_5d    ;
reg  [47:0]         r_target_mac        ;
reg  [47:0]         r_source_mac        ;
reg  [47:0]         r_rec_mac           ;
reg                 r_rec_mac_access    ;
reg  [15:0]         r_rec_cnt           ;
reg                 r_headr_check       ;
reg                 r_header_access     ;
reg  [15:0]         r_rec_type          ;//0x0800-IP 0X0806-ARP
reg                 r_crc_rst           ;
reg                 r_crc_en            ;
reg                 r_crc_en_1d         ;
reg  [15:0]         r_rec_5d_cnt        ;
reg  [31:0]         r_crc_result        ;
reg                 ro_crc_valid        ;/***************wire******************/
wire [31:0]         w_crc_result        ;/***************component*************/
CRC32_D8 CRC32_D8_u0(.i_clk            (i_clk              ),.i_rst            (r_crc_rst          ),.i_en             (r_crc_en           ),.i_data           (ri_GMII_data_5d       ),.o_crc            (w_crc_result       )   
);
/***************assign****************/
assign o_post_type     = r_rec_type             ;
assign o_post_data     = ri_GMII_data_5d        ;
assign o_post_last     = ro_post_last             ;
assign o_post_valid    = ro_post_valid            ;
assign o_rec_src_mac   = ro_rec_src_mac         ;
assign o_rec_src_valid = ro_rec_src_valid       ;
assign o_crc_error     = ro_crc_error           ;
assign o_crc_valid     = ro_crc_valid           ;
/***************always****************///数据打5拍,为了对齐信号
always@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginri_GMII_data        <= 'd0;ri_GMII_valid       <= 'd0;ri_GMII_data_1d     <= 'd0;ri_GMII_valid_1d    <= 'd0;ri_GMII_data_2d     <= 'd0;ri_GMII_valid_2d    <= 'd0;ri_GMII_data_3d     <= 'd0;ri_GMII_valid_3d    <= 'd0;ri_GMII_data_4d     <= 'd0;ri_GMII_valid_4d    <= 'd0;end else beginri_GMII_data        <= i_GMII_data ;ri_GMII_valid       <= i_GMII_valid;ri_GMII_data_1d     <= ri_GMII_data ;ri_GMII_valid_1d    <= ri_GMII_valid;ri_GMII_data_2d     <= ri_GMII_data_1d ;ri_GMII_valid_2d    <= ri_GMII_valid_1d;ri_GMII_data_3d     <= ri_GMII_data_2d ;ri_GMII_valid_3d    <= ri_GMII_valid_2d;ri_GMII_data_4d     <= ri_GMII_data_3d ;ri_GMII_valid_4d    <= ri_GMII_valid_3d;ri_GMII_data_5d     <= ri_GMII_data_4d ;ri_GMII_valid_5d    <= ri_GMII_valid_4d;end     
end
//valid后,输入目标mac地址锁存
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_target_mac <= P_TARTGET_MAC;else if(i_target_mac_valid)r_target_mac <= i_target_mac;elser_target_mac <= r_target_mac;
end//valid后,输入源mac地址锁存
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_source_mac <= P_SOURCE_MAC ;else if(i_source_mac_valid)r_source_mac <= i_source_mac;elser_source_mac <= r_source_mac;
end//GMII接口输入有效 
// r_rec_cnt  为 6  停一个周期 接收SFD
// 继续 + 1
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_rec_cnt <= 'd0;else if(ri_GMII_valid && r_rec_cnt == 6 && ri_GMII_data == 8'h55)r_rec_cnt <= r_rec_cnt;else if(ri_GMII_valid)r_rec_cnt <= r_rec_cnt + 1;else r_rec_cnt <= 'd0;
end// r_rec_cnt  7 ~ 12 存好收到目的的MAC地址
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_rec_mac <= 'd0;else if(ri_GMII_valid && r_rec_cnt >= 7 && r_rec_cnt <= 12)r_rec_mac <= {r_rec_mac[39:0],ri_GMII_data};else r_rec_mac <= r_rec_mac;
end// r_rec_cnt  13 检测收到目的mac与自身mac是否相等
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_rec_mac_access <= 'd0;else if(r_rec_cnt == 13 && r_rec_mac != r_source_mac)r_rec_mac_access <= 'd0;else if(r_rec_cnt == 13 && (r_rec_mac == r_source_mac || &r_rec_mac))r_rec_mac_access <= 'd1;else r_rec_mac_access <= r_rec_mac_access;
end
//r_rec_cnt   0~6  检验前导码 是否为55     再6 检测SFD 是否为D5
always@(*)
begincase(r_rec_cnt)0,1,2,3,4,5 :r_headr_check <= ri_GMII_data == 8'h55 ? 'd1 : 'd0;6           :r_headr_check <= ri_GMII_data == 8'hD5 || ri_GMII_data == 8'h55 ? 'd1 : 'd0;default     :r_headr_check <= 'd1;endcase
end//头没有问题,就通过信号不拉低
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_header_access <= 'd1;else if(!ri_GMII_valid)r_header_access <= 'd1;else if(ri_GMII_valid && r_rec_cnt >= 0 && r_rec_cnt <= 6 && !r_headr_check)r_header_access <= 'd0;else r_header_access <= r_header_access;
end// r_rec_cnt 13~ 18 源MAC地址接收
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_rec_src_mac <= 'd0;else if(ri_GMII_valid && r_rec_cnt >= 13 && r_rec_cnt <= 18)ro_rec_src_mac <= {ro_rec_src_mac[39:0],ri_GMII_data};else ro_rec_src_mac <= ro_rec_src_mac;
end// r_rec_cnt 19 源MAC地址接收有效
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_rec_src_valid <= 'd0;else if(r_rec_cnt == 19)ro_rec_src_valid <= 'd1;else ro_rec_src_valid <= ro_rec_src_valid;
end//r_rec_cnt 19 ~ 20 接收类型
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_rec_type <= 'd0;else if(ri_GMII_valid && r_rec_cnt >= 19 && r_rec_cnt <= 20)r_rec_type <= {r_rec_type[7:0],ri_GMII_data};else r_rec_type <= r_rec_type;
end //延迟5个周期的 GMII 有效    r_rec_5d_cnt + 1
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_rec_5d_cnt <= 'd0; else if(ri_GMII_valid_5d)r_rec_5d_cnt <= r_rec_5d_cnt + 1;elser_rec_5d_cnt <= 'd0; 
end 
//正常信号的下降沿 有效为0
//延迟5个周期 计数为 21 有效为1
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_post_valid <= 'd0;else if(ro_post_last)ro_post_valid <= 'd0;else if(r_rec_5d_cnt == 21)ro_post_valid <= 'd1;else ro_post_valid <= ro_post_valid;
end//GMII有效信号下降沿  输出 ro_post_last
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_post_last <= 'd0;else if(!i_GMII_valid && ri_GMII_valid)ro_post_last <= 'd1;else ro_post_last <= 'd0;
end// always@(posedge i_clk,posedge i_rst)
// begin
//     if(i_rst)
//         ro_arp_valid <= 'd0;
//     else if(!ri_GMII_valid && ri_GMII_data_1d)
//         ro_arp_valid <= 'd0;
//     else if(r_rec_type == 16'h0806 && r_rec_5d_cnt == 20)
//         ro_arp_valid <= 'd1;
//     else 
//         ro_arp_valid <= ro_ip_valid;
// end// always@(posedge i_clk,posedge i_rst)
// begin
//     if(i_rst)
//         ro_arp_last <= 'd0;
//     else if(!i_GMII_valid && ri_GMII_valid && r_rec_type == 16'h0806)
//         ro_arp_last <= 'd1;
//     else 
//         ro_arp_last <= 'd0;
// end//CRC使能信号 来 CRC模块数据复位信号
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_crc_rst <= 'd1;else if(r_rec_5d_cnt == 7)r_crc_rst <= 'd0;else if(!r_crc_en && r_crc_en_1d)r_crc_rst <= 'd1;else r_crc_rst <= r_crc_rst;
end// GMII有效的下降沿 关闭crc校验使能
//
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_crc_en <= 'd0;else if(!ri_GMII_valid && ri_GMII_data_1d)r_crc_en <= 'd0;else if(r_rec_5d_cnt == 7)r_crc_en <= 'd1;else r_crc_en <= r_crc_en;
end//CRC使能信号打拍
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_crc_en_1d <= 'd0;else r_crc_en_1d <= r_crc_en;
end//获取外部输入的CRC结果
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_crc_result <= 'd0;else if(ri_GMII_valid)r_crc_result <= {ri_GMII_data,r_crc_result[31:8]};elser_crc_result <= r_crc_result;
end//CRC使能下降沿 CRC有效
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_crc_valid <= 'd0;else if(!r_crc_en && r_crc_en_1d)ro_crc_valid <= 'd1;else ro_crc_valid <= 'd0;
end//CRC校验 error
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_crc_error <= 'd0;else if(!P_CRC_CHECK)ro_crc_error <= 'd0;else if(!r_crc_en && r_crc_en_1d && r_crc_result != w_crc_result)ro_crc_error <= 'd1;else ro_crc_error <= 'd0;
endendmodule

2.2 MAC发送模块

module MAC_tx#(parameter       P_TARTGET_MAC   =   {8'h00,8'h00,8'h00,8'h00,8'h00,8'h00},P_SOURCE_MAC    =   {8'h00,8'h00,8'h00,8'h00,8'h00,8'h00},P_CRC_CHECK     =   1
)(input           i_clk       ,input           i_rst       ,/*--------info port--------*/   input  [47:0]   i_target_mac        ,input           i_target_mac_valid  ,input  [47:0]   i_source_mac        ,input           i_source_mac_valid  ,/*--------data port--------*/input           i_udp_valid         ,output          o_udp_ready         ,input  [15:0]   i_send_type         ,input  [15:0]   i_send_len          ,input  [7 :0]   i_send_data         ,input           i_send_last         ,input           i_send_valid        ,/*--------GMII port--------*/output [7 :0]   o_GMII_data         ,output          o_GMII_valid        
);/***************function**************//***************parameter*************//***************port******************/             /***************mechine***************//***************reg*******************/
reg  [15:0]         ri_send_type        ;
reg  [15:0]         ri_send_len         ;
reg  [7 :0]         ri_send_data        ;
reg                 ri_send_valid       ;
reg                 ri_send_valid_1d    ;
reg  [7 :0]         ro_GMII_data        ;
reg                 ro_GMII_valid       ;
reg                 ro_GMII_valid_1d    ;
reg  [47:0]         r_target_mac        ;
reg  [47:0]         r_source_mac        ;
reg                 r_fifo_mac_rd_en    ;
reg  [15:0]         r_mac_pkg_cnt       ;
reg  [7 :0]         r_mac_data          ;
reg                 r_mac_data_valid    ;
reg                 r_mac_data_valid_1d ;
reg  [15:0]         r_mac_data_cnt      ;
reg                 r_crc_rst           ;          
reg                 r_crc_en            ;
reg  [1 :0]         r_crc_out_cnt       ;  
reg                 r_crc_out_cnt_1d    ;
reg  [15:0]         r_gap_lat           ;
reg                 r_gap_lock          ;
reg  [15:0]         r_gap_cnt           ;
reg                 ri_udp_valid        ;
reg                 ro_udp_ready        ;/***************wire******************/
wire [7 :0]         w_fifo_mac_dout     ;
wire                w_fifo_mac_full     ;
wire                w_fifo_mac_empty    ;
wire                w_send_valid_pos    ;
wire                w_send_valid_neg    ;
wire [31:0]         w_crc_result        ;/***************component*************/
FIFO_MAC_8X64 FIFO_MAC_8X64_U0 (.clk              (i_clk              ),      // input wire clk.din              (ri_send_data       ),      // input wire [7 : 0] din.wr_en            (ri_send_valid      ),  // input wire wr_en.rd_en            (r_fifo_mac_rd_en   ),  // input wire rd_en.dout             (w_fifo_mac_dout    ),    // output wire [7 : 0] dout.full             (w_fifo_mac_full    ),    // output wire full.empty            (w_fifo_mac_empty   )  // output wire empty
);CRC32_D8 CRC32_D8_u0(.i_clk            (i_clk              ),.i_rst            (r_crc_rst          ),.i_en             (r_crc_en           ),.i_data           (r_mac_data         ),.o_crc            (w_crc_result       )   
);/***************assign****************/
assign o_GMII_data      = ro_GMII_data      ;
assign o_GMII_valid     = ro_GMII_valid     ;
assign w_send_valid_pos = ri_send_valid & !ri_send_valid_1d;
assign w_send_valid_neg = !ri_send_valid & ri_send_valid_1d;
assign o_udp_ready      = ro_udp_ready      ;/***************always****************/
//锁存 目的mac
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_target_mac <= P_TARTGET_MAC;else if(i_target_mac_valid)r_target_mac <= i_target_mac;elser_target_mac <= r_target_mac;
end
//锁存 源mac
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_source_mac <= P_SOURCE_MAC ;else if(i_source_mac_valid)r_source_mac <= i_source_mac;elser_source_mac <= r_source_mac;
end//锁存输入的 发送mac帧信息
always@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginri_send_type  <= 'd0;ri_send_len   <= 'd0;ri_send_data  <= 'd0;ri_send_valid <= 'd0;end else if(i_send_valid) beginri_send_type  <= i_send_type ;ri_send_len   <= i_send_len  ;ri_send_data  <= i_send_data ;ri_send_valid <= i_send_valid;end else beginri_send_type  <= ri_send_type ;ri_send_len   <= ri_send_len  ;ri_send_data  <= 'd0 ;ri_send_valid <= 'd0;end
end//mac帧的计数器 
//CRC校验输出完成 停止
//输入信号有效上升沿开始 计数
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_mac_pkg_cnt <= 'd0;else if(r_crc_out_cnt == 3)r_mac_pkg_cnt <= 'd0;else if(w_send_valid_pos || r_mac_pkg_cnt)r_mac_pkg_cnt <= r_mac_pkg_cnt + 1;else r_mac_pkg_cnt <= r_mac_pkg_cnt;
end//组mac帧 :  前导码 + SFD + 目的mac + 源mac
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_mac_data <= 'd0;else case(r_mac_pkg_cnt)0,1,2,3,4,5,6   :r_mac_data <= 8'h55;7               :r_mac_data <= 8'hd5;8               :r_mac_data <= ri_send_type == 16'h0806 ? 8'hff : r_target_mac[47:40];9               :r_mac_data <= ri_send_type == 16'h0806 ? 8'hff : r_target_mac[39:32];10              :r_mac_data <= ri_send_type == 16'h0806 ? 8'hff : r_target_mac[31:24];11              :r_mac_data <= ri_send_type == 16'h0806 ? 8'hff : r_target_mac[23:16];12              :r_mac_data <= ri_send_type == 16'h0806 ? 8'hff : r_target_mac[15: 8];13              :r_mac_data <= ri_send_type == 16'h0806 ? 8'hff : r_target_mac[7 : 0];14              :r_mac_data <= r_source_mac[47:40];15              :r_mac_data <= r_source_mac[39:32];16              :r_mac_data <= r_source_mac[31:24];17              :r_mac_data <= r_source_mac[23:16];18              :r_mac_data <= r_source_mac[15: 8];19              :r_mac_data <= r_source_mac[7 : 0];20              :r_mac_data <= ri_send_type[15: 8];21              :r_mac_data <= ri_send_type[7 : 0];default         :r_mac_data <= w_fifo_mac_dout;endcase
end//mac有效信号
// mac数据计数到值 关闭
//发送有效上升沿 开启
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_mac_data_valid <= 'd0;else if(r_mac_data_cnt == ri_send_len + 1)r_mac_data_valid <= 'd0;else if(w_send_valid_pos)r_mac_data_valid <= 'd1;else r_mac_data_valid <= r_mac_data_valid;
end//mac总数计数器
//到设置长度清零
//fifo读使能 开启计数
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_mac_data_cnt <= 'd0;else if(r_mac_data_cnt == ri_send_len + 1)r_mac_data_cnt <= 'd0;else if(r_fifo_mac_rd_en | r_mac_data_cnt)r_mac_data_cnt <= r_mac_data_cnt + 1;else r_mac_data_cnt <= r_mac_data_cnt;
end//mac帧的计数器 到20 开启读fifo使能
//到mac总数关闭
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_fifo_mac_rd_en <= 'd0;else if(r_mac_data_cnt == ri_send_len - 1)r_fifo_mac_rd_en <= 'd0;else if(r_mac_pkg_cnt == 20)r_fifo_mac_rd_en <= 'd1;else r_fifo_mac_rd_en <= r_fifo_mac_rd_en;
end//CRC校验复位
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_crc_rst <= 'd1;else if(r_mac_pkg_cnt == 8 )r_crc_rst <= 'd0;else if(r_crc_out_cnt == 3)r_crc_rst <= 'd1;else r_crc_rst <= r_crc_rst;
end//CRC校验使能,mac帧计时器为 8时  开启
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_crc_en <= 'd0;else if(r_mac_data_cnt == ri_send_len + 1)r_crc_en <= 'd0;else if(r_mac_pkg_cnt == 8 )r_crc_en <= 'd1;else r_crc_en <= r_crc_en;
end// r_crc_out_cnt 数据有效下降沿开启计数   等于3清零
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_crc_out_cnt <= 'd0;else if(r_crc_out_cnt == 3)   r_crc_out_cnt <= 'd0;else if((!r_mac_data_valid && r_mac_data_valid_1d) || r_crc_out_cnt)r_crc_out_cnt <= r_crc_out_cnt + 1;else r_crc_out_cnt <= r_crc_out_cnt;
end//输出mac帧数据
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_GMII_data <= 'd0;else if(r_mac_data_valid)ro_GMII_data <= r_mac_data;else case(r_crc_out_cnt)0       :ro_GMII_data <= w_crc_result[7 : 0];1       :ro_GMII_data <= w_crc_result[15: 8];2       :ro_GMII_data <= w_crc_result[23:16];3       :ro_GMII_data <= w_crc_result[31:24];default :ro_GMII_data <= 'd0;endcase   
end // r_crc_out_cnt_1d 
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_crc_out_cnt_1d <= 'd0;else if(r_crc_out_cnt == 3)r_crc_out_cnt_1d <= 'd1;else r_crc_out_cnt_1d <= 'd0;
end//数据有效的时候 GMII输出有效
//只有在CRC结束,r_crc_out_cnt_1d 拉高的时候,GMII输出无效
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_GMII_valid <= 'd0;else if(r_crc_out_cnt_1d)ro_GMII_valid <= 'd0;else if(r_mac_data_valid)ro_GMII_valid <= 'd1;else    ro_GMII_valid <= ro_GMII_valid;
end 
//信号打拍 获得上升沿
always@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginri_send_valid_1d    <= 'd0;r_mac_data_valid_1d <= 'd0;end else beginri_send_valid_1d    <= ri_send_valid   ;r_mac_data_valid_1d <= r_mac_data_valid;end
end
/*-------------------UDP------------------------*/
always@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginri_udp_valid <= 'd0 ;ro_GMII_valid_1d <= 'd0;end else beginri_udp_valid <= i_udp_valid;ro_GMII_valid_1d <= ro_GMII_valid;end
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_udp_ready <= 'd1;else if(i_udp_valid)ro_udp_ready <= 'd0;else if( r_mac_data_cnt == ri_send_len  - 1)ro_udp_ready <= 'd1;else ro_udp_ready <= ro_udp_ready;
endendmodule

3.1 IP接收模块

module IP_rx#(parameter       P_ST_TARGET_IP = {8'd192,8'd168,8'd1,8'd0},parameter       P_ST_SOURCE_IP = {8'd192,8'd168,8'd1,8'd1}
)(input           i_clk               ,input           i_rst               ,/*--------info port --------*/input  [31:0]   i_target_ip         ,input           i_target_valid      ,input  [31:0]   i_source_ip         ,input           i_source_valid      ,/*--------data port--------*/output [15:0]   o_udp_len           ,output [7 :0]   o_udp_data          ,output          o_udp_last          ,output          o_udp_valid         ,output [15:0]   o_icmp_len          ,output [7 :0]   o_icmp_data         ,output          o_icmp_last         ,output          o_icmp_valid        ,output [31:0]   o_source_ip         ,output          o_source_ip_valid   ,/*--------mac port--------*/input  [7 :0]   i_mac_data          ,input           i_mac_last          ,input           i_mac_valid);/***************function**************//***************parameter*************//***************port******************/             /***************mechine***************//***************reg*******************/
reg  [31:0]         r_target_ip         ;
reg  [31:0]         r_source_ip         ;
reg  [7 :0]         ri_mac_data         ;
reg  [7 :0]         ri_mac_data_1d      ;
reg                 ri_mac_last         ;
reg                 ri_mac_valid        ;
reg                 ri_mac_valid_1d     ;
reg  [15:0]         ro_udp_len          ;
reg                 ro_udp_last         ;
reg                 ro_udp_valid        ;
reg  [15:0]         ro_icmp_len         ;
reg                 ro_icmp_last        ;
reg                 ro_icmp_valid       ;
reg  [15:0]         r_ip_len            ;
reg  [7 :0]         r_ip_type           ;
reg  [31:0]         r_ip_source         ;
reg  [31:0]         r_ip_target         ;
reg  [15:0]         r_ip_cnt            ;
reg                 ro_source_ip_valid  ;/***************wire******************//***************component*************//***************assign****************/
assign o_udp_data   = ri_mac_data_1d    ;
assign o_icmp_data  = ri_mac_data_1d    ;
assign o_udp_len    = ro_udp_len        ;
assign o_udp_last   = ro_udp_last       ;
assign o_udp_valid  = ro_udp_valid      ;
assign o_icmp_len   = ro_icmp_len       ;
assign o_icmp_last  = ro_icmp_last      ;
assign o_icmp_valid = ro_icmp_valid     ;
assign o_source_ip       = r_ip_source  ;
assign o_source_ip_valid = ro_source_ip_valid;
/***************always****************/
//目的ip有效信号 锁存 目的ip
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_target_ip <= P_ST_TARGET_IP;else if(i_target_valid)r_target_ip <= i_target_ip;else r_target_ip <= r_target_ip;
end//源ip效信号 锁存 源ip
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_source_ip <= P_ST_SOURCE_IP;else if(i_source_valid)r_source_ip <= i_source_ip;else r_source_ip <= r_source_ip;
end//信号和数据打拍
always@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginri_mac_data  <= 'd0;ri_mac_last  <= 'd0;ri_mac_valid <= 'd0;ri_mac_data_1d <= 'd0;ri_mac_valid_1d <= 'd0;end else beginri_mac_data  <= i_mac_data ;ri_mac_last  <= i_mac_last ;ri_mac_valid <= i_mac_valid;ri_mac_data_1d <= ri_mac_data;ri_mac_valid_1d <= ri_mac_valid;end
end//mac端口有效  ip计数器+1
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_ip_cnt <= 'd0;else if(ri_mac_valid)r_ip_cnt <= r_ip_cnt + 1;else r_ip_cnt <= 'd0;
end// 2 3 字节数据为ip报文总长度
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_ip_len <= 'd0;else if(r_ip_cnt >= 2 && r_ip_cnt <= 3)r_ip_len <= {r_ip_len[7:0],ri_mac_data};else r_ip_len <= r_ip_len;
end//第9字节 ip 协议类型 
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_ip_type <= 'd0;else if(r_ip_cnt == 9)r_ip_type <= ri_mac_data;else r_ip_type <= r_ip_type;
end//第12 13 14 15字节  ip源地址
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_ip_source <= 'd0;else if(r_ip_cnt >= 12 && r_ip_cnt <= 15)r_ip_source <= {r_ip_source[23:0],ri_mac_data};else    r_ip_source <= r_ip_source;
end     
//输出ip源地址有效
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_source_ip_valid <= 'd0;else if(r_ip_cnt == 15)ro_source_ip_valid <= 'd1;else ro_source_ip_valid <= 'd0;
end//第16 17 18 19字节  ip目的地址
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_ip_target <= 'd0;else if(r_ip_cnt >= 16 && r_ip_cnt <= 19)r_ip_target <= {r_ip_target[23:0],ri_mac_data};else r_ip_target <= r_ip_target;
end//计算UDP 或者 ICMP 的数据长度
always@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginro_udp_len  <= 'd0;ro_icmp_len <= 'd0;end else beginro_udp_len  <= r_ip_len - 20;ro_icmp_len <= r_ip_len - 20;end 
end// 第20字节  检测是目的和源IP是否正确
//检测协议类型  UDP还是ICMP
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_udp_valid <= 'd0;else if(!ri_mac_valid && ri_mac_valid_1d)ro_udp_valid <= 'd0;else if(r_ip_cnt == 20 && r_ip_target == r_source_ip && r_ip_type == 17)ro_udp_valid <= 'd1;else ro_udp_valid <= ro_udp_valid;
end
//ICMP  同上
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_icmp_valid <= 'd0;else if(!ri_mac_valid && ri_mac_valid_1d)ro_icmp_valid <= 'd0;else if(r_ip_cnt == 20 && r_ip_target == r_source_ip && r_ip_type == 1)ro_icmp_valid <= 'd1;else ro_icmp_valid <= ro_icmp_valid;
end//i_mac_valid 信号的下降沿 拉高 last信号
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_udp_last <= 'd0;else if(!i_mac_valid && ri_mac_valid && r_ip_type == 17)ro_udp_last <= 'd1;else ro_udp_last <= 'd0;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_icmp_last <= 'd0;else if(!i_mac_valid && ri_mac_valid && r_ip_type == 1)ro_icmp_last <= 'd1;else ro_icmp_last <= 'd0;
endendmodule

3.2 IP发送模块

module IP_tx#(parameter       P_ST_TARGET_IP = {8'd192,8'd168,8'd1,8'd0},parameter       P_ST_SOURCE_IP = {8'd192,8'd168,8'd1,8'd1}
)(input               i_clk       ,input               i_rst       ,/*--------info port --------*/input  [31:0]   i_target_ip         ,input           i_target_valid      ,input  [31:0]   i_source_ip         ,input           i_source_valid      ,/*--------data port--------*/input  [7 :0]   i_send_type         ,input  [15:0]   i_send_len          ,input  [7 :0]   i_send_data         ,input           i_send_last         ,input           i_send_valid        ,output [31:0]   o_arp_seek_ip       ,output          o_arp_seek_valid    ,/*--------mac port--------*/output [15:0]   o_mac_type          ,output [15:0]   o_mac_len           ,output [7 :0]   o_mac_data          ,output          o_mac_last          ,output          o_mac_valid         );/***************function**************//***************parameter*************//***************port******************/             /***************mechine***************//***************reg*******************/
reg  [31:0]         r_target_ip         ;
reg  [31:0]         r_source_ip         ;
reg  [7 :0]         ri_send_type        ;
reg  [15:0]         ri_send_len         ;
reg  [7 :0]         ri_send_data        ;
reg                 ri_send_last        ;
reg                 ri_send_valid       ;
reg                 ri_send_valid_1d    ;
reg                 r_fifo_ip_rd_en     ;
reg  [7 :0]         r_ip_data           ;
reg  [7 :0]         r_ip_valid          ;
reg  [15:0]         r_ip_data_cnt       ;
reg  [15:0]         r_ip_message        ;
reg  [31:0]         r_ip_check          ;
reg  [15:0]         ro_mac_type         ;  
reg                 ro_mac_last         ; 
reg  [31:0]         ro_arp_seek_ip      ;
reg                 ro_arp_seek_valid   ;/***************wire******************/
wire [31:0]         w_fifo_ip_dout      ;
wire                w_fifo_ip_full      ;
wire                w_fifo_ip_empty     ;/***************component*************/
//把要发送的数据存进FIFO,要发送时读出来
FIFO_MAC_8X64 FIFO_IP_8X64_U0 (.clk          (i_clk              ),      // input wire clk.din          (ri_send_data       ),      // input wire [7 : 0] din.wr_en        (ri_send_valid      ),  // input wire wr_en.rd_en        (r_fifo_ip_rd_en    ),  // input wire rd_en.dout         (w_fifo_ip_dout     ),    // output wire [7 : 0] dout.full         (w_fifo_ip_full     ),    // output wire full.empty        (w_fifo_ip_empty    )  // output wire empty
);/***************assign****************/
assign o_mac_data  = r_ip_data  ;
assign o_mac_valid = r_ip_valid ;
assign o_mac_len   = ri_send_len; 
assign o_mac_type  = ro_mac_type;
assign o_mac_last  = ro_mac_last;
assign o_arp_seek_ip    = ro_arp_seek_ip   ;
assign o_arp_seek_valid = ro_arp_seek_valid;
/***************always****************/
//目的地址有效  锁存
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_target_ip <= P_ST_TARGET_IP;else if(i_target_valid)r_target_ip <= i_target_ip;else r_target_ip <= r_target_ip;
end//源地址有效  锁存
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_source_ip <= P_ST_SOURCE_IP;else if(i_source_valid)r_source_ip <= i_source_ip;else r_source_ip <= r_source_ip;
end//锁存 类型和数据等信息   ip报文长度 为 UDP报文 + 20
always@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginri_send_type  <= 'd0;ri_send_len   <= 'd0;ri_send_data  <= 'd0;ri_send_last  <= 'd0;ri_send_valid <= 'd0;end else if(i_send_valid) beginri_send_type  <= i_send_type    ;ri_send_len   <= i_send_len + 20;ri_send_data  <= i_send_data    ;ri_send_last  <= i_send_last    ;ri_send_valid <= i_send_valid   ;end else beginri_send_type  <= ri_send_type   ;ri_send_len   <= ri_send_len    ;ri_send_data  <= ri_send_data   ;ri_send_last  <= 'd0;ri_send_valid <= 'd0;end
end   // r_ip_data_cnt 计数
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_ip_data_cnt <= 'd0;else if(r_ip_data_cnt == ri_send_len - 1)r_ip_data_cnt <= 'd0;else if(ri_send_valid || r_ip_data_cnt)r_ip_data_cnt <= r_ip_data_cnt + 1;else r_ip_data_cnt <= r_ip_data_cnt;
end// ip报文的个数  计数
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_ip_message <= 'd0;else if(o_mac_last)r_ip_message <= r_ip_message + 1;else r_ip_message <= r_ip_message;
end//进行首部校验和
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_ip_check <= 'd0;else if(ri_send_valid && r_ip_data_cnt == 0)r_ip_check <= 16'h4500 + ri_send_len + r_ip_message + 16'h4000 + {8'd64,ri_send_type} + r_source_ip[31:16] +r_source_ip[15:0] + r_target_ip[31:16] + r_target_ip[15:0];else if(r_ip_data_cnt == 1)r_ip_check <= r_ip_check[31:16] + r_ip_check[15:0];else if(r_ip_data_cnt == 2)r_ip_check <= r_ip_check[31:16] + r_ip_check[15:0];else if(r_ip_data_cnt == 3)r_ip_check <= ~r_ip_check;else r_ip_check <= r_ip_check;
end//打拍生成边沿
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ri_send_valid_1d <= 'd0;else    ri_send_valid_1d <= ri_send_valid;
end//发送有效信号上升沿 ip帧有效拉高
// mac帧结束信号拉高,ip帧有效拉低
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_ip_valid <= 'd0;else if(ro_mac_last)r_ip_valid <= 'd0;else if(ri_send_valid && !ri_send_valid_1d)r_ip_valid <= 'd1;else r_ip_valid <= r_ip_valid;
end
//组帧输出
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_ip_data <= 'd0;else case(r_ip_data_cnt)0           : r_ip_data <= {4'b0100,4'b0101};           //版本+首部长度1           : r_ip_data <= 'd0;                         //服务类型2           : r_ip_data <= ri_send_len[15:8];           //总长度的高8位3           : r_ip_data <= ri_send_len[7 :0];           //总长度的低8位4           : r_ip_data <= r_ip_message[15:8];          //报文标识的高8位5           : r_ip_data <= r_ip_message[7 :0];          //报文标识的低8位6           : r_ip_data <= {3'b010,5'b00000};           //标志+片偏移7           : r_ip_data <= 'd0;                         //片偏移8           : r_ip_data <= 'd64;                        //生存时间9           : r_ip_data <= ri_send_type;                //协议类型10          : r_ip_data <= r_ip_check[15:8];11          : r_ip_data <= r_ip_check[7 :0];12          : r_ip_data <= r_source_ip[31:24];13          : r_ip_data <= r_source_ip[23:16];14          : r_ip_data <= r_source_ip[15:8];15          : r_ip_data <= r_source_ip[7 :0];16          : r_ip_data <= r_target_ip[31:24];17          : r_ip_data <= r_target_ip[23:16];18          : r_ip_data <= r_target_ip[15:8];19          : r_ip_data <= r_target_ip[7 :0];default     : r_ip_data <= w_fifo_ip_dout;endcase
end// ip帧 计数到18  从FIFO中读取数据
// mac帧结束信号拉高,不读了
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_fifo_ip_rd_en <= 'd0;else if(ro_mac_last)r_fifo_ip_rd_en <= 'd0;else if(r_ip_data_cnt == 18)r_fifo_ip_rd_en <= 'd1;else r_fifo_ip_rd_en <= r_fifo_ip_rd_en;
end//ip帧计数器计到最大   mac 帧结束了
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_mac_last <= 'd0;else if(r_ip_data_cnt == ri_send_len - 1)ro_mac_last <= 'd1;else ro_mac_last <= 'd0;
end//输出mac层的报文类型
always@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginro_mac_type <= 'd0;end else beginro_mac_type <= 16'h0800;end
end //ARP
always@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginro_arp_seek_ip    <= P_ST_TARGET_IP;ro_arp_seek_valid <= 'd0;end else if(ri_send_valid && !ri_send_valid_1d) beginro_arp_seek_ip    <= r_target_ip;ro_arp_seek_valid <= 'd1;end else beginro_arp_seek_ip    <= ro_arp_seek_ip;ro_arp_seek_valid <= 'd0;end
end 
endmodule

4.1 UDP接收模块

module UDP_rx#(parameter           P_TARGET_PORT   =  16'h8080 ,P_SOURCE_PORT   =  16'h8080
)(input               i_clk           ,input               i_rst           ,/*--------info port-------*/input  [15:0]       i_target_port   ,input               i_target_valid  ,input  [15:0]       i_source_port   ,input               i_source_valid  ,/*--------data port--------*/output [15:0]       o_udp_len       ,output [7 :0]       o_udp_data      ,output              o_udp_last      ,output              o_udp_valid     ,/*--------ip port--------*/input  [15:0]       i_ip_len        ,input  [7 :0]       i_ip_data       ,input               i_ip_last       ,input               i_ip_valid      
);/***************function**************//***************parameter*************//***************port******************/             /***************mechine***************//***************reg*******************/
reg  [15:0]             r_target_port   ;
reg  [15:0]             r_source_port   ;
reg  [15:0]             ri_ip_len       ;
reg  [7 :0]             ri_ip_data      ;
reg                     ri_ip_last      ;
reg                     ri_ip_valid     ;
reg  [15:0]             ro_udp_len      ;
reg                     ro_udp_last     ;
reg                     ro_udp_valid    ;
reg  [15:0]             r_udp_cnt       ;/***************wire******************//***************component*************//***************assign****************/
assign o_udp_len   = ro_udp_len         ;
assign o_udp_data  = ri_ip_data         ;
assign o_udp_last  = ro_udp_last        ;
assign o_udp_valid = ro_udp_valid       ;
/***************always****************/
//锁存 目标端口
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_target_port <= 'd0;else if(i_target_valid)       r_target_port <= i_target_port;else r_target_port <= r_target_port;
end//锁存 源端口
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_source_port <= 'd0;else if(i_source_valid)       r_source_port <= i_source_port;else r_source_port <= r_source_port;
end//ip有效信号 锁存ip的信息 
always@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginri_ip_len   <= 0;ri_ip_data  <= 0;ri_ip_last  <= 0;ri_ip_valid <= 0;end else if(i_ip_valid) beginri_ip_len   <= i_ip_len  ;ri_ip_data  <= i_ip_data ;ri_ip_last  <= i_ip_last ;ri_ip_valid <= i_ip_valid;end else beginri_ip_len   <= ri_ip_len  ;ri_ip_data  <= 'd0 ;ri_ip_last  <= 'd0 ;ri_ip_valid <= 'd0;end 
end//ip有效信号,r_udp_cnt + 1
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_udp_cnt <= 'd0;else if(ri_ip_valid)r_udp_cnt <= r_udp_cnt + 1;else r_udp_cnt <= 'd0;
end 
//UDP帧的长度 为 IP帧长度 - 8
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_udp_len <= 'd0;else ro_udp_len <= ri_ip_len - 8;
end//UDP接收到第7位 拉高UDP有效,跟数据一起出来
//UDP发送到长度-1 时,拉低有效信号
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_udp_valid <= 'd0;else if(r_udp_cnt == ri_ip_len - 1)ro_udp_valid <= 'd0;else if(r_udp_cnt == 7)ro_udp_valid <= 'd1;else ro_udp_valid <= ro_udp_valid;
end
//拉高last结束信号
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)   ro_udp_last <= 'd0;else if(r_udp_cnt == ri_ip_len - 2)ro_udp_last <= 'd1;else ro_udp_last <= 'd0;
endendmodule

4.2 UDP发送模块

module UDP_tx#(parameter           P_TARGET_PORT   =  16'h8080 ,P_SOURCE_PORT   =  16'h8080
)(input               i_clk           ,input               i_rst           ,/*--------info port-------*/input  [15:0]       i_target_port   ,input               i_target_valid  ,input  [15:0]       i_source_port   ,input               i_source_valid  ,/*--------data port--------*/input  [15:0]       i_send_len      ,input  [7 :0]       i_send_data     ,input               i_send_last     ,input               i_send_valid    ,/*--------ip port--------*/output [15:0]       o_ip_len        ,output [7 :0]       o_ip_data       ,output              o_ip_last       ,output              o_ip_valid      
);/***************function**************//***************parameter*************/
localparam              P_ST_MIN_LEN = 18 + 8;/***************port******************/             /***************mechine***************//***************reg*******************/
reg  [15:0]             r_target_port   ;
reg  [15:0]             r_source_port   ;
reg  [15:0]             ri_send_len     ;
reg  [7 :0]             ri_send_data    ;
reg                     ri_send_last    ;
reg                     ri_send_valid   ;
reg  [15:0]             ro_ip_len       ;
reg  [7 :0]             ro_ip_data      ;
reg                     ro_ip_last      ;
reg                     ro_ip_valid     ;
reg                     r_fifo_udp_rd_en; 
reg  [15:0]             r_udp_cnt       ;
reg                     r_fifo_udp_empty;/***************wire******************/
wire [7:0]              w_fifo_udp_dout ;   
wire                    w_fifo_udp_full ;   
wire                    w_fifo_udp_empty;   /***************component*************/
//要写的数据存进FIFO
FIFO_MAC_8X64 FIFO_UDP_8X64_U0 (.clk          (i_clk              ),      // input wire clk.din          (ri_send_data       ),      // input wire [7 : 0] din.wr_en        (ri_send_valid      ),  // input wire wr_en.rd_en        (r_fifo_udp_rd_en   ),  // input wire rd_en.dout         (w_fifo_udp_dout    ),    // output wire [7 : 0] dout.full         (w_fifo_udp_full    ),    // output wire full.empty        (w_fifo_udp_empty   )  // output wire empty
);/***************assign****************/
assign o_ip_len   = ro_ip_len           ;
assign o_ip_data  = ro_ip_data          ;
assign o_ip_last  = ro_ip_last          ;
assign o_ip_valid = ro_ip_valid         ;/***************always****************/
//锁存 目的端口
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_target_port <= P_TARGET_PORT;else if(i_target_valid)       r_target_port <= i_target_port;else r_target_port <= r_target_port;
end//锁存 源端口
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_source_port <= P_SOURCE_PORT;else if(i_source_valid)       r_source_port <= i_source_port;else r_source_port <= r_source_port;
end//锁存输入的IP数据
always@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginri_send_data  <= 'd0;ri_send_last  <= 'd0;ri_send_valid <= 'd0;end else beginri_send_data  <= i_send_data ;ri_send_last  <= i_send_last ;ri_send_valid <= i_send_valid;end
end//锁存输入的数据长度
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ri_send_len     <= 'd0;else if(i_send_valid)   ri_send_len     <= i_send_len  ;else ri_send_len     <= ri_send_len;
end//发送UDP数据长度小于18 并且已经完成18+8 的UDP帧 ,后计数器清空
//大于18 ,正常发完
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)    r_udp_cnt <= 'd0;else if(ri_send_len < 18 && r_udp_cnt == P_ST_MIN_LEN - 1)r_udp_cnt <= 'd0;else if(ri_send_len >= 18 && r_udp_cnt == (ri_send_len + 8) - 1)r_udp_cnt <= 'd0;else if(ri_send_valid || r_udp_cnt)r_udp_cnt <= r_udp_cnt + 1;else r_udp_cnt <= r_udp_cnt;
end//如果数据长度小于18 就默认18
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_ip_len <= 'd0;else if(ri_send_len < 18)ro_ip_len <= 18;else ro_ip_len <= ri_send_len + 8;
end//如果收到ip_last信号,ip有效拉低
//收到输入有效信号,ip有效拉高
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_ip_valid <= 'd0;else if(ro_ip_last)ro_ip_valid <= 'd0;else if(ri_send_valid)ro_ip_valid <= 'd1;else ro_ip_valid <= ro_ip_valid;
end
//UDP发完后,拉高ip_last信号
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_ip_last <= 'd0;else if(ri_send_len < 18 && r_udp_cnt == P_ST_MIN_LEN - 1)ro_ip_last <= 'd1;else if(ri_send_len >= 18 && r_udp_cnt == (ri_send_len + 8) - 1)ro_ip_last <= 'd1;else ro_ip_last <= 'd0;
end//输出完8字节 UDP帧的头 FIFO读使能打开
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_fifo_udp_rd_en <= 'd0;else if(r_udp_cnt == (ri_send_len + 8) - 1)r_fifo_udp_rd_en <= 'd0;else if(r_udp_cnt == 6)r_fifo_udp_rd_en <= 'd1;else r_fifo_udp_rd_en <= r_fifo_udp_rd_en;
end//空信号打拍
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_fifo_udp_empty <= 'd0;else r_fifo_udp_empty <= w_fifo_udp_empty;
end//组帧输出
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_ip_data <= 'd0;else case(r_udp_cnt)0           : ro_ip_data <= r_source_port[15:8];1           : ro_ip_data <= r_source_port[7 :0];2           : ro_ip_data <= r_target_port[15:8];3           : ro_ip_data <= r_target_port[7 :0];4           : ro_ip_data <= ro_ip_len[15:8];5           : ro_ip_data <= ro_ip_len[7 :0];6           : ro_ip_data <= 'd0;7           : ro_ip_data <= 'd0;default     : ro_ip_data <= !r_fifo_udp_empty ? w_fifo_udp_dout : 'd0;endcase         
endendmodule

5.1 ICMP接收模块

module ICMP_rx(input           i_clk       ,input           i_rst       ,/*--------rec port--------*/input  [15:0]   i_icmp_len          ,input  [7 :0]   i_icmp_data         ,input           i_icmp_last         ,input           i_icmp_valid        ,           /*--------send port--------*/output          o_trig_reply        ,output  [15:0]  o_trig_seq          
);/***************function**************//***************parameter*************//***************port******************/             /***************mechine***************//***************reg*******************/
reg  [15:0]         ri_icmp_len         ;
reg  [7 :0]         ri_icmp_data        ;
reg                 ri_icmp_last        ;
reg                 ri_icmp_valid       ;
reg                 ro_trig_reply       ;
reg  [15:0]         r_icmp_cnt          ;
reg  [7 :0]         r_type              ;
reg  [15:0]         ro_trig_seq         ;/***************wire******************//***************component*************//***************assign****************/
assign o_trig_reply = ro_trig_reply     ;
assign o_trig_seq   = ro_trig_seq       ;/***************always****************/
//输入信号打拍
always@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginri_icmp_len   <= 'd0;ri_icmp_data  <= 'd0;ri_icmp_last  <= 'd0;ri_icmp_valid <= 'd0;end else beginri_icmp_len   <= i_icmp_len  ;ri_icmp_data  <= i_icmp_data ;ri_icmp_last  <= i_icmp_last ;ri_icmp_valid <= i_icmp_valid;end
end//开始计数
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_icmp_cnt <= 'd0;else if(ri_icmp_valid)r_icmp_cnt <= r_icmp_cnt + 1;else r_icmp_cnt <= 'd0;
end//存下icmp类型
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_type <= 'd0;else if(ri_icmp_valid && r_icmp_cnt == 0)r_type <= ri_icmp_data;else r_type <= r_type;
end//ICMP帧的 序号 
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_trig_seq <= 'd0;else if(r_icmp_cnt >=6 && r_icmp_cnt <= 7)ro_trig_seq <= {ro_trig_seq[7 :0],ri_icmp_data};else ro_trig_seq <= ro_trig_seq;
end//类型为8  计数8个 拉高序号的回复信号
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_trig_reply <= 'd0;else if(r_icmp_cnt == 7 && r_type == 8)ro_trig_reply <= 'd1;else ro_trig_reply <= 'd0;
endendmodule

5.2 ICMP发送模块

module ICMP_tx(input           i_clk           ,input           i_rst           ,input           i_trig_reply    ,input  [15:0]   i_trig_seq      ,output [15:0]   o_icmp_len      ,output [7 :0]   o_icmp_data     ,output          o_icmp_last     ,output          o_icmp_valid    
);/***************function**************//***************parameter*************/
localparam          P_LEN  = 40     ;
/***************port******************/             /***************mechine***************//***************reg*******************/
reg                 ri_trig_reply   ;
reg  [15:0]         ri_trig_seq     ;
reg  [15:0]         ro_icmp_len     ;
reg  [7 :0]         ro_icmp_data    ;
reg                 ro_icmp_last    ;
reg                 ro_icmp_valid   ;
reg  [15:0]         r_icmp_cnt      ;
reg  [31:0]         r_icmp_check    ;
reg  [7 :0]         r_check_cnt     ;/***************wire******************//***************component*************//***************assign****************/
assign o_icmp_len   = ro_icmp_len  ;
assign o_icmp_data  = ro_icmp_data ;
assign o_icmp_last  = ro_icmp_last ;
assign o_icmp_valid = ro_icmp_valid;
/***************always****************/
//序号值 和 信号 打一拍
always@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginri_trig_reply <= 'd0;ri_trig_seq   <= 'd0;end else beginri_trig_reply <= i_trig_reply;ri_trig_seq   <= i_trig_seq;end
end//r_check_cnt 在 ri_trig_reply拉高后 +1
//r_icmp_cnt 计数完,r_check_cnt清空
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_check_cnt <= 'd0;else if(r_icmp_cnt == P_LEN - 1)r_check_cnt <= 'd0;else if(r_check_cnt == 3)r_check_cnt <= r_check_cnt + 1;else if(ri_trig_reply | r_check_cnt)r_check_cnt <= r_check_cnt + 1;else r_check_cnt <= r_check_cnt;
end//ICMP的校验和  和IP层的首部校验和一样
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_icmp_check <= 'd0;else if(r_check_cnt == 0)r_icmp_check <= 16'h0001 + ri_trig_seq;else if(r_check_cnt == 1)r_icmp_check <= r_icmp_check[31:16] + r_icmp_check[15:0];else if(r_check_cnt == 2)r_icmp_check <= r_icmp_check[31:16] + r_icmp_check[15:0];else if(r_check_cnt == 3)r_icmp_check <= ~r_icmp_check;else r_icmp_check <= r_icmp_check;
end//校验完成后 开始组帧计数
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_icmp_cnt <= 'd0;else if(r_icmp_cnt == P_LEN - 1)r_icmp_cnt <= 'd0;else if(r_check_cnt == 3 || r_icmp_cnt)r_icmp_cnt <= r_icmp_cnt + 1;else r_icmp_cnt <= r_icmp_cnt;
end
//ICMP的长度 输出
always@(posedge i_clk,posedge i_rst)
begin   if(i_rst)ro_icmp_len <= 'd0;else ro_icmp_len <= P_LEN;
end
//校验完成输出 ICMP帧,使能拉高
always@(posedge i_clk,posedge i_rst)
begin   if(i_rst)ro_icmp_valid <= 'd0;else if(r_icmp_cnt == P_LEN - 1)ro_icmp_valid <= 'd0;else if(r_check_cnt == 3)ro_icmp_valid <= 'd1;else ro_icmp_valid <= ro_icmp_valid;
end//输出结束信号
always@(posedge i_clk,posedge i_rst)
begin   if(i_rst)ro_icmp_last <= 'd0;else if(r_icmp_cnt == P_LEN - 2)ro_icmp_last <= 'd1;else ro_icmp_last <= 'd0;
end//组帧
always@(posedge i_clk,posedge i_rst)
begin   if(i_rst)ro_icmp_data <= 'd0;else case(r_icmp_cnt)0           :ro_icmp_data <= 'd0;1           :ro_icmp_data <= 'd0;2           :ro_icmp_data <= r_icmp_check[15:8];3           :ro_icmp_data <= r_icmp_check[7 :0];4           :ro_icmp_data <= 8'h00;5           :ro_icmp_data <= 8'h01;6           :ro_icmp_data <= ri_trig_seq[15:8];7           :ro_icmp_data <= ri_trig_seq[7 :0];default     :ro_icmp_data <= 'd0;endcase
endendmodule

6.1 ARP接收模块

module ARP_rx#(parameter       P_TARGET_IP = {8'd192,8'd168,8'd1,8'd1},parameter       P_SOURCE_MAC = {8'h00,8'h00,8'h00,8'h00,8'h00,8'h00},parameter       P_SOURCE_IP  = {8'd192,8'd168,8'd1,8'd2}
)(input           i_clk           ,input           i_rst           ,input   [31:0]  i_source_ip     ,input           i_s_ip_valid    ,/*--------info port--------*/output  [47:0]  o_target_mac    ,output  [31:0]  o_target_ip     ,output          o_target_valid  ,output          o_tirg_reply    ,/*--------MAC port--------*/input   [7 :0]  i_mac_data      ,input           i_mac_last      ,input           i_mac_valid     
);/***************function**************//***************parameter*************//***************port******************/             /***************mechine***************//***************reg*******************/
reg  [47:0]         ro_target_mac   ;
reg  [31:0]         ro_target_ip    ;
reg                 ro_target_valid ;
reg  [7 :0]         ri_mac_data     ;
reg  [7 :0]         ri_mac_data_1d  ;
reg                 ri_mac_last     ;
reg                 ri_mac_valid    ;
reg  [15:0]         r_mac_cnt       ;
reg  [15:0]         r_arp_op        ;
reg                 ro_tirg_reply   ;
reg  [31:0]         ri_source_ip    ; /***************wire******************//***************component*************//***************assign****************/
assign o_target_mac = ro_target_mac ;
assign o_target_ip  = ro_target_ip  ;
assign o_tirg_reply = ro_tirg_reply ;
assign o_target_valid = ro_target_valid;/***************always****************/
//打拍
always@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginri_mac_data  <= 'd0;ri_mac_last  <= 'd0;ri_mac_valid <= 'd0;ri_mac_data_1d <= 'd0;end else begin   ri_mac_data  <= i_mac_data ;ri_mac_last  <= i_mac_last ;ri_mac_valid <= i_mac_valid;ri_mac_data_1d <= ri_mac_data;end
end//源ip 锁存
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ri_source_ip <= P_SOURCE_IP;else if(i_s_ip_valid)ri_source_ip <= i_source_ip;else ri_source_ip <= ri_source_ip;
end//mac计数器
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_mac_cnt <= 'd0;else if(ri_mac_valid)   r_mac_cnt <= r_mac_cnt + 1;else     r_mac_cnt <= 'd0;
end//获得ARP的操作类型
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_arp_op <= 'd0;else if(r_mac_cnt >= 6 && r_mac_cnt <= 7)r_arp_op <= {r_arp_op[7 :0],ri_mac_data};else     r_arp_op <= r_arp_op;
end//获得目的mac
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_target_mac <= 'd0;else if(r_mac_cnt >= 8 && r_mac_cnt <= 13 && (r_arp_op == 1 || r_arp_op == 2))ro_target_mac <= {ro_target_mac[39:0],ri_mac_data};else        ro_target_mac <= ro_target_mac;
end//获得目的ip
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_target_ip <= 'd0;else if(r_mac_cnt >= 14 && r_mac_cnt <= 17 && (r_arp_op == 1 || r_arp_op == 2))ro_target_ip <= {ro_target_ip[23:0],ri_mac_data};else     ro_target_ip <= ro_target_ip;
end//计数到17 拉高有效信号
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)    ro_target_valid <= 'd0;else if(r_mac_cnt == 17)   ro_target_valid <= 'd1;else        ro_target_valid <= 'd0;
end//计数到18 类型为1 请求   
//回复信号触发信号 拉高
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_tirg_reply <= 'd0;else if(r_mac_cnt == 18 && r_arp_op == 1)ro_tirg_reply <= 'd1;else ro_tirg_reply <= 'd0;
endendmodule

6.2 ARP发送模块

module ARP_tx#(parameter       P_TARGET_IP = {8'd192,8'd168,8'd1,8'd1},parameter       P_SOURCE_MAC = {8'h00,8'h00,8'h00,8'h00,8'h00,8'h00},parameter       P_SOURCE_IP  = {8'd192,8'd168,8'd1,8'd2}
)(input           i_clk           ,input           i_rst           ,input   [31:0]  i_target_ip     ,input           i_target_valid  ,input   [47:0]  i_source_mac    ,input           i_s_mac_valid   ,input   [31:0]  i_source_ip     ,input           i_s_ip_valid    ,input   [47:0]  i_reply_mac     ,output  [31:0]  o_seek_ip       ,output          o_seek_valid    ,input           i_trig_reply    ,input           i_active_send   ,output  [7 :0]  o_mac_data      ,output          o_mac_last      ,output          o_mac_valid     
);/***************function**************//***************parameter*************/
localparam          P_LEN    = 46   ;/***************port******************/             /***************mechine***************//***************reg*******************/
reg  [31:0]         r_target_ip     ;
reg                 ri_trig_reply   ;
reg                 ri_active_send  ;
reg  [7 :0]         ro_mac_data     ;
reg                 ro_mac_last     ;
reg                 ro_mac_valid    ;
reg  [15:0]         r_mac_cnt       ;
reg  [15:0]         r_arp_op        ;
reg  [47:0]         ri_source_mac   ; 
reg  [31:0]         ri_source_ip    ; 
reg  [31:0]         ro_seek_ip      ;
reg                 ro_seek_valid   ;
reg  [47:0]         ri_reply_mac    ;
reg  [15:0]         r_arp_cnt       ;/***************wire******************/
wire                w_act           ;/***************component*************//***************assign****************/
assign o_mac_data  = ro_mac_data    ;
assign o_mac_last  = ro_mac_last    ;
assign o_mac_valid = ro_mac_valid   ;
assign o_seek_ip    = ro_seek_ip    ;
assign o_seek_valid = ro_seek_valid ;
assign w_act       = r_arp_cnt == 10;/***************always****************///主动ARP和被动ARP 触发有效
always@(posedge i_clk,posedge i_rst)
beginif(i_rst) ro_seek_valid <= 'd0;else if(i_trig_reply | i_active_send)ro_seek_valid <= 'd1;else            ro_seek_valid <= 'd0;
end//输出 源ip
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_seek_ip <= 'd0;else ro_seek_ip <= ri_source_ip;
end//输入目的有效 获得目的ip
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_target_ip <= P_TARGET_IP;else if(i_target_valid)r_target_ip <= i_target_ip;else r_target_ip <= r_target_ip;
end//输入mac有效,获得源mac
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ri_source_mac <= P_SOURCE_MAC;else if(i_s_mac_valid)ri_source_mac <= i_source_mac;else ri_source_mac <= ri_source_mac;
end//输入ip有效,获得源ip 
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ri_source_ip <= P_SOURCE_IP;else if(i_s_ip_valid)ri_source_ip <= i_source_ip;else ri_source_ip <= ri_source_ip;
end// 被动触发 和主动触发信号打拍
always@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginri_trig_reply  <= 'd0;ri_active_send <= 'd0;end else beginri_trig_reply  <= i_trig_reply ;ri_active_send <= i_active_send | w_act;end 
end//r_arp_cnt计数器  0 到 11 
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_arp_cnt <= 'd0;else if(r_arp_cnt < 11)r_arp_cnt <= r_arp_cnt + 1;else r_arp_cnt <= r_arp_cnt;
end//打拍后的触发信号,控制开始mac帧计数
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_mac_cnt <= 'd0;else if(r_mac_cnt == P_LEN - 1)r_mac_cnt <= 'd0;else if(ri_trig_reply || ri_active_send  || r_mac_cnt)   r_mac_cnt <= r_mac_cnt + 1;else r_mac_cnt <= r_mac_cnt;
end//打拍后的触发信号,控制回复类型值
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_arp_op <= 'd0;else if(ri_trig_reply)r_arp_op <= 'd2;else if(ri_active_send)r_arp_op <= 'd1;else r_arp_op <= r_arp_op;
end//得到mac帧 用于回复
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ri_reply_mac <= 'd0;else ri_reply_mac <= i_reply_mac;
end     //组帧输出
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_mac_data <= 'd0;else case(r_mac_cnt)0           :ro_mac_data <= 'd0;1           :ro_mac_data <= 'd1;2           :ro_mac_data <= 8'h08;3           :ro_mac_data <= 8'h00;4           :ro_mac_data <= 'd6;5           :ro_mac_data <= 'd4;6           :ro_mac_data <= r_arp_op[15:8];7           :ro_mac_data <= r_arp_op[7 :0];8           :ro_mac_data <= ri_source_mac[47:40];9           :ro_mac_data <= ri_source_mac[39:32];10          :ro_mac_data <= ri_source_mac[31:24];11          :ro_mac_data <= ri_source_mac[23:16];12          :ro_mac_data <= ri_source_mac[15: 8];13          :ro_mac_data <= ri_source_mac[7 : 0];14          :ro_mac_data <= ri_source_ip[31:24];15          :ro_mac_data <= ri_source_ip[23:16];16          :ro_mac_data <= ri_source_ip[15: 8];17          :ro_mac_data <= ri_source_ip[7 : 0];18          :ro_mac_data <= r_arp_op == 2 ? ri_reply_mac[47:40] : 8'h00;19          :ro_mac_data <= r_arp_op == 2 ? ri_reply_mac[39:32] : 8'h00;20          :ro_mac_data <= r_arp_op == 2 ? ri_reply_mac[31:24] : 8'h00; 21          :ro_mac_data <= r_arp_op == 2 ? ri_reply_mac[23:16] : 8'h00;22          :ro_mac_data <= r_arp_op == 2 ? ri_reply_mac[15: 8] : 8'h00;23          :ro_mac_data <= r_arp_op == 2 ? ri_reply_mac[7 : 0] : 8'h00;24          :ro_mac_data <= r_target_ip[31:24];25          :ro_mac_data <= r_target_ip[23:16];26          :ro_mac_data <= r_target_ip[15: 8];27          :ro_mac_data <= r_target_ip[7 : 0];default     :ro_mac_data <= 'd0;endcase
end//到长度就拉低有效信号
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_mac_valid <= 'd0;else if(r_mac_cnt == P_LEN - 1)ro_mac_valid <= 'd0;else if(ri_trig_reply || ri_active_send )ro_mac_valid <= 'd1;else ro_mac_valid <= ro_mac_valid;
end //产生last信号
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_mac_last <= 'd0;else if(r_mac_cnt == P_LEN - 2)ro_mac_last <= 'd1;else ro_mac_last <= 'd0;
endendmodule

6.3 ARP表模块

module ARP_Table(input               i_clk           ,input               i_rst           ,input  [31:0]       i_seek_ip       ,input               i_seek_valid    ,input  [31:0]       i_updata_ip     ,input  [47:0]       i_updata_mac    ,input               i_updata_valid  ,output [47:0]       o_active_mac    ,output              o_active_valid  
);  /***************function**************//***************parameter*************/
localparam              P_ST_IDLE       =   0   ,P_ST_SEEK       =   1   ,P_ST_UPDATA_S   =   2   ,P_ST_UPDATA     =   3   ,P_ST_MAC        =   4   ;/***************port******************/             /***************mechine***************/
reg  [7 :0]             r_st_current    ;
reg  [7 :0]             r_st_next       ;/***************reg*******************/
reg  [31:0]             r_seek_ip       ;
reg  [31:0]             r_updata_ip     ;
reg  [47:0]             r_updata_mac    ;
reg  [47:0]             ro_active_mac   ;
reg                     ro_active_valid ;
reg                     ri_seek_valid   ;
reg                     ri_updata_valid ;
reg                     r_ram_ip_en     ;
reg                     r_ram_ip_we     ;
reg  [2 :0]             r_ram_ip_addr   ;
reg                     r_ram_ip_dv     ;
reg                     r_ram_mac_en    ;
reg                     r_ram_mac_we    ;
reg  [2 :0]             r_ram_mac_addr  ;
reg                     r_ram_mac_dv    ;
reg                     r_ip_access     ;
reg  [2 :0]             r_access_addr   ;
reg                     r_ram_ip_end    ;
reg                     r_ram_ip_end_1d ;
reg                     r_updata_acc    ;
reg  [2 :0]             r_up_data_addr  ;/***************wire******************/
wire [31:0]             w_ram_ip_dout   ;
wire [47:0]             w_ram_mac_dout  ;
wire                    w_seek_v_pos    ;
wire                    w_seek_v_neg    ;
wire                    w_updata_v_pos  ;
wire                    w_updata_v_neg  ;
wire                    r_ram_ip_end_neg;/***************component*************/
RAM_IP RAM_IP_U0 (.clka     (i_clk          ),.ena      (r_ram_ip_en    ),.wea      (r_ram_ip_we    ),.addra    (r_ram_ip_addr  ),.dina     (r_updata_ip    ),.douta    (w_ram_ip_dout  ) 
);RAM_MAC RAM_MAC_U0 (.clka     (i_clk          ), .ena      (r_ram_mac_en   ), .wea      (r_ram_mac_we   ), .addra    (r_ram_mac_addr ), .dina     (r_updata_mac   ), .douta    (w_ram_mac_dout )  
);
/***************assign****************/
assign o_active_mac   = ro_active_mac   ;
assign o_active_valid = ro_active_valid ;
assign w_seek_v_pos   = i_seek_valid & !ri_seek_valid;
assign w_seek_v_neg   = !i_seek_valid & ri_seek_valid;
assign w_updata_v_pos = i_updata_valid & !ri_updata_valid;
assign w_updata_v_neg = !i_updata_valid & ri_updata_valid;
assign r_ram_ip_end_neg = r_ram_ip_end & !r_ram_ip_end_1d;/***************always****************/
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_st_current <= P_ST_IDLE;else r_st_current <= r_st_next;
endalways@(*)
begincase(r_st_current)P_ST_IDLE       :r_st_next = w_seek_v_pos   ? P_ST_SEEK     : i_updata_valid ? P_ST_UPDATA_S : P_ST_IDLE;P_ST_SEEK       :r_st_next = r_ip_access || (r_ram_ip_end_neg && !r_ip_access)? P_ST_MAC    : P_ST_SEEK;P_ST_UPDATA_S   :r_st_next = r_updata_acc ? P_ST_IDLE : (r_ram_ip_end_neg && !r_updata_acc) ? P_ST_UPDATA : P_ST_UPDATA_S;P_ST_UPDATA     :r_st_next = P_ST_IDLE;P_ST_MAC        :r_st_next = P_ST_IDLE;default         :r_st_next = P_ST_IDLE;endcase 
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_seek_ip <= 'd0;else if(i_seek_valid)r_seek_ip <= i_seek_ip;else r_seek_ip <= r_seek_ip;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginr_updata_ip  <= 'd0;r_updata_mac <= 'd0;end else if(i_updata_valid) begin     r_updata_ip  <= i_updata_ip ;r_updata_mac <= i_updata_mac;end else beginr_updata_ip  <= r_updata_ip ;r_updata_mac <= r_updata_mac;end 
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginri_seek_valid   <= 'd0;ri_updata_valid <= 'd0;end else beginri_seek_valid   <= i_seek_valid  ;ri_updata_valid <= i_updata_valid;end 
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst) begin  r_ram_ip_en   <= 'd0;r_ram_ip_we   <= 'd0;r_ram_ip_addr <= 'd0;   end else if(r_st_current == P_ST_SEEK && !r_ram_ip_end) beginr_ram_ip_en   <= 'd1;r_ram_ip_we   <= 'd0;if(r_ram_ip_en) r_ram_ip_addr <= r_ram_ip_addr + 1;else r_ram_ip_addr <= 'd0;end else if(r_st_current == P_ST_UPDATA_S && !r_ram_ip_end) beginr_ram_ip_en   <= 'd1;r_ram_ip_we   <= 'd0;if(r_ram_ip_en) r_ram_ip_addr <= r_ram_ip_addr + 1;else r_ram_ip_addr <= 'd0;end else if(r_st_current == P_ST_UPDATA) beginr_ram_ip_en   <= 'd1;r_ram_ip_we   <= 'd1;r_ram_ip_addr <= r_up_data_addr;end else beginr_ram_ip_en   <= 'd0;r_ram_ip_we   <= 'd0;r_ram_ip_addr <= 'd0;end 
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst) begin  r_ram_mac_en   <= 'd0;r_ram_mac_we   <= 'd0;r_ram_mac_addr <= 'd0;   end else if(r_st_current == P_ST_UPDATA_S && !r_ram_ip_end) beginr_ram_mac_en   <= 'd1;r_ram_mac_we   <= 'd0;r_ram_mac_addr <= r_ram_mac_addr + 1;end else if(r_st_current == P_ST_UPDATA) beginr_ram_mac_en   <= 'd1;r_ram_mac_we   <= 'd1;r_ram_mac_addr <= r_up_data_addr;end else if(r_ram_ip_dv && w_ram_ip_dout == r_seek_ip) beginr_ram_mac_en   <= 'd1;r_ram_mac_we   <= 'd0;r_ram_mac_addr <= r_access_addr;end else beginr_ram_mac_en   <= 'd0;r_ram_mac_we   <= 'd0;r_ram_mac_addr <= 'd0;end 
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_ram_ip_end <= 'd0;else if(r_st_current == P_ST_IDLE)r_ram_ip_end <= 'd0;else if(r_st_current == P_ST_SEEK && r_ram_ip_addr == 7)r_ram_ip_end <= 'd1;else if(r_st_current == P_ST_UPDATA_S && r_ram_ip_addr == 7)r_ram_ip_end <= 'd1;else r_ram_ip_end <= r_ram_ip_end;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_ram_ip_end_1d <= 'd0;elser_ram_ip_end_1d <= r_ram_ip_end;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_ram_ip_dv <= 'd0;else if(r_ram_ip_en && !r_ram_ip_we && !r_ip_access)r_ram_ip_dv <= 'd1;else r_ram_ip_dv <= 'd0;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_ip_access <= 'd0;else if(r_st_current == P_ST_IDLE)r_ip_access <= 'd0;else if(r_ram_ip_dv && w_ram_ip_dout == r_seek_ip)r_ip_access <= 'd1;else r_ip_access <= r_ip_access;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_access_addr <= 'd0;else if(r_st_current == P_ST_IDLE)r_access_addr <= 'd0;else if(r_ram_ip_dv && !r_ip_access)r_access_addr <= r_access_addr + 1;else r_access_addr <= r_access_addr;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_updata_acc <= 'd0;else if(r_ram_ip_dv && w_ram_ip_dout == r_updata_ip && w_ram_mac_dout == r_updata_mac)r_updata_acc <= 'd1;else r_updata_acc <= 'd0;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_up_data_addr <= 'd0;else if(r_st_current == P_ST_UPDATA)r_up_data_addr <= r_up_data_addr + 1;else r_up_data_addr <= r_up_data_addr;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_active_mac <= 48'd0;else if(r_st_current == P_ST_MAC && r_ip_access)ro_active_mac <= w_ram_mac_dout;else        ro_active_mac <= 48'hffffffffffff;
end always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_active_valid <= 'd0;else if(r_st_current == P_ST_MAC)ro_active_valid <= 'd1;else ro_active_valid <= 'd0;
end
endmodule

7 CRC数据对比模块

要双端口ram读写缓存帧的数据和FIFO配合存储帧长度和类型

module CRC_Data_Pro(input               i_clk           ,input               i_rst           ,input  [15:0]       i_per_type      ,input  [7 :0]       i_per_data      ,input               i_per_last      ,input               i_per_valid     ,input               i_per_crc_error ,input               i_per_crc_valid ,output [15:0]       o_post_type     ,output [7 :0]       o_post_data     ,output              o_post_last     ,output              o_post_valid 
);/***************function**************//***************parameter*************/
localparam              P_FRAME_GAP =   12  ;/***************port******************/             /***************mechine***************//***************reg*******************/
reg  [15:0]             ri_per_type         ;
reg  [7 :0]             ri_per_data         ;
reg                     ri_per_last         ;
reg                     ri_per_valid        ;
reg                     ri_per_valid_1d     ;
reg                     ri_per_crc_error    ;
reg                     ri_per_crc_valid    ;
reg  [7 :0]             ro_post_data        ;
reg                     ro_post_last        ;
reg                     ro_post_valid       ;
reg                     r_ram_en_A          ;
reg                     r_ram_we_A          ;
reg  [11:0]             r_ram_addr_A        ;
reg  [7 :0]             r_ram_din_A         ;
reg                     r_ram_en_B          ;
reg                     r_ram_en_B_1d       ;
reg                     r_ram_we_B          ;
reg  [11:0]             r_ram_addr_B        ;
reg  [10:0]             r_data_len          ;
reg  [10:0]             r_data_len_o        ;
reg                     r_fifo_rd_en        ;
reg                     r_fifo_rd_en_1d     ;
reg                     r_fifo_wr_en        ;
reg                     r_out_run           ;
reg                     r_out_run_1d        ;
reg  [10:0]             r_fifo_dout         ;
reg  [15:0]             r_gap_cnt           ;
reg  [15:0]             ro_post_type        ;
reg                     ri_per_last_1d      ;/***************wire******************/
wire [7 :0]             w_ram_dout_B        ;
wire [10:0]             w_fifo_dout         ;
wire                    w_fifo_empty        ;
wire                    w_fifo_full         ;
wire [15:0]             w_fifo_type         ;/***************component*************/
RAM_8x1500_TrueDual RAM_8x1500_TrueDual_u0 (//修改为8X3000 .clka                 (i_clk          ),.ena                  (r_ram_en_A     ),.wea                  (r_ram_we_A     ),.addra                (r_ram_addr_A   ),.dina                 (r_ram_din_A    ),.douta                (),.clkb                 (i_clk          ),.enb                  (r_ram_en_B     ),.web                  (r_ram_we_B     ),.addrb                (r_ram_addr_B   ),.dinb                 (0              ),.doutb                (w_ram_dout_B   ) 
);FIFO_11X64 FIFO_11X64_U0 (.clk                  (i_clk          ),.din                  (r_data_len     ),.wr_en                (r_fifo_wr_en   ),.rd_en                (r_fifo_rd_en   ),.dout                 (w_fifo_dout    ),.full                 (w_fifo_full    ),.empty                (w_fifo_empty   ) 
);FIFO_16X64 FIFO_16X64_U1 (.clk                  (i_clk          ),.din                  (ri_per_type     ),.wr_en                (r_fifo_wr_en   ),.rd_en                (r_fifo_rd_en   ),.dout                 (w_fifo_type    ),.full                 (),.empty                () 
);/***************assign****************/
assign o_post_data  = ro_post_data ;
assign o_post_last  = ro_post_last ;
assign o_post_valid = ro_post_valid;
assign o_post_type  = ro_post_type;/***************always****************/
always@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginri_per_data      <= 'd0;ri_per_last      <= 'd0;ri_per_valid     <= 'd0;ri_per_type      <= 'd0;ri_per_crc_error <= 'd0;ri_per_crc_valid <= 'd0;end else beginri_per_data      <= i_per_data     ;ri_per_last      <= i_per_last     ;ri_per_valid     <= i_per_valid    ;ri_per_type      <= i_per_type     ;ri_per_crc_error <= i_per_crc_error;ri_per_crc_valid <= i_per_crc_valid;end 
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginr_ram_en_A   <= 'd0;   r_ram_we_A   <= 'd0;   r_ram_din_A  <= 'd0;end else if(ri_per_valid) beginr_ram_en_A   <= 'd1;r_ram_we_A   <= 'd1;r_ram_din_A  <= ri_per_data;end else beginr_ram_en_A   <= 'd0;r_ram_we_A   <= 'd0;r_ram_din_A  <= 'd0;end
end always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ri_per_valid_1d <= 'd0;elseri_per_valid_1d <= ri_per_valid;
end always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_ram_addr_A <= 'd0;else if(ri_per_crc_valid && ri_per_crc_error)r_ram_addr_A <= r_ram_addr_A - r_data_len;else if(r_ram_addr_A == 2999)r_ram_addr_A <= 'd0;else if(ri_per_valid && !ri_per_valid_1d)r_ram_addr_A <= r_ram_addr_A;else if(ri_per_valid | ri_per_valid_1d)r_ram_addr_A <= r_ram_addr_A + 1;else r_ram_addr_A <= r_ram_addr_A;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)ri_per_last_1d <= 'd0;else ri_per_last_1d <= ri_per_last;
end// always@(posedge i_clk,posedge i_rst)
// begin
//     if(i_rst)
//         r_data_len <= 'd0;
//     else if(ri_per_last_1d)
//         r_data_len <= r_ram_addr_A;
//     else 
//         r_data_len <= r_data_len;
// endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_data_len <= 'd0;else if(r_fifo_wr_en)r_data_len <= 'd0;else if(ri_per_valid)r_data_len <= r_data_len + 1;elser_data_len <= r_data_len;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_fifo_wr_en <= 'd0;else if(ri_per_crc_valid && !ri_per_crc_error && !r_fifo_wr_en)r_fifo_wr_en <= 'd1;else r_fifo_wr_en <= 'd0;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_fifo_rd_en <= 'd0;else if(!w_fifo_empty && !r_out_run && !r_fifo_rd_en && r_gap_cnt == P_FRAME_GAP - 4)r_fifo_rd_en <= 'd1;elser_fifo_rd_en <= 'd0; 
end always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_fifo_rd_en_1d <= 'd0;else r_fifo_rd_en_1d <= r_fifo_rd_en;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_fifo_dout <= 'd0;else if(r_fifo_rd_en_1d)   r_fifo_dout <= w_fifo_dout;else r_fifo_dout <= r_fifo_dout;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_out_run <= 'd0;else if(r_data_len_o == r_fifo_dout - 1)r_out_run <= 'd0;else if(!r_fifo_rd_en && r_fifo_rd_en_1d)r_out_run <= 'd1;else r_out_run <= r_out_run;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_data_len_o <= 'd0;else if(r_data_len_o == r_fifo_dout - 1)r_data_len_o <= 'd0;else  if(r_out_run)r_data_len_o <= r_data_len_o + 1;else  r_data_len_o <= r_data_len_o;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_out_run_1d <= 'd0;elser_out_run_1d <= r_out_run;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginr_ram_en_B   <= 'd0;   r_ram_we_B   <= 'd0;   end else if(r_out_run && !r_out_run_1d) beginr_ram_en_B   <= 'd1;   r_ram_we_B   <= 'd0;   end else if(r_out_run) beginr_ram_en_B   <= 'd1;   r_ram_we_B   <= 'd0;   end else beginr_ram_en_B   <= 'd0;   r_ram_we_B   <= 'd0;   end 
end always@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_ram_addr_B <= 'd0;else if(r_ram_addr_B == 2999)   r_ram_addr_B <= 'd0;else if(r_out_run && !r_out_run_1d)r_ram_addr_B <= r_ram_addr_B;else if(r_out_run | r_out_run_1d)r_ram_addr_B <= r_ram_addr_B + 1;else r_ram_addr_B <= r_ram_addr_B;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_post_data <= 'd0;else if(r_ram_en_B_1d)ro_post_data <= w_ram_dout_B;else ro_post_data <= 'd0;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_post_type <= 'd0;else if(r_fifo_rd_en_1d)ro_post_type <= w_fifo_type;else ro_post_type <= ro_post_type;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_ram_en_B_1d <= 'd0;else r_ram_en_B_1d <= r_ram_en_B;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_post_valid <= 'd0;else ro_post_valid <= r_ram_en_B_1d;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_post_last <= 'd0;else if(!r_ram_en_B && r_ram_en_B_1d)ro_post_last <= 'd1;else    ro_post_last <= 'd0;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_gap_cnt <= 'd1;else if(r_fifo_rd_en)r_gap_cnt <= 'd0;else if(r_gap_cnt == P_FRAME_GAP - 4)r_gap_cnt <= r_gap_cnt;else if(ro_post_last | r_gap_cnt)r_gap_cnt <= r_gap_cnt + 1;else r_gap_cnt <= r_gap_cnt;
endendmodule

8 MAC下ARP和IP数据分流模块

类型是0800就是IP 0806就是ARP,进行分流操作

module mac_arp_ip_mux(input               i_clk           ,input               i_rst           ,input  [15:0]       i_type          ,input  [7 :0]       i_data          ,input               i_last          ,input               i_valid         ,output [7 :0]       o_ip_data       ,output              o_ip_last       ,output              o_ip_valid      ,output [7 :0]       o_arp_data      ,output              o_arp_last      ,output              o_arp_valid     
);reg  [7 :0]             ro_ip_data      ;
reg                     ro_ip_last      ;
reg                     ro_ip_valid     ;
reg  [7 :0]             ro_arp_data     ;
reg                     ro_arp_last     ;
reg                     ro_arp_valid    ;assign o_ip_data   = ro_ip_data          ;
assign o_ip_last   = ro_ip_last          ;
assign o_ip_valid  = ro_ip_valid         ;
assign o_arp_data  = ro_arp_data         ;
assign o_arp_last  = ro_arp_last         ;
assign o_arp_valid = ro_arp_valid        ;always@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginro_ip_data  <= 'd0;ro_ip_last  <= 'd0;ro_ip_valid <= 'd0;end else if(i_type == 16'h0800) beginro_ip_data  <= i_data ;ro_ip_last  <= i_last ;ro_ip_valid <= i_valid;end else beginro_ip_data  <= 'd0;ro_ip_last  <= 'd0;ro_ip_valid <= 'd0;end 
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginro_arp_data  <= 'd0;ro_arp_last  <= 'd0;ro_arp_valid <= 'd0;end else if(i_type == 16'h0806) beginro_arp_data   <= i_data ;ro_arp_last   <= i_last ;ro_arp_valid <= i_valid;end else beginro_arp_data  <= 'd0;ro_arp_last  <= 'd0;ro_arp_valid <= 'd0;end 
endendmodule

9 数据流仲裁模块

两个数据流都加个FIFO,以帧为单位,先输出A,A输出完成后再输出B。还要进行流控:要切换通道输出时,要先把现在这个通道的FIFO数据输出完,才能来新通道的输入,保证多次操作之后FIFO不会溢出。

module Data_2to1(input               i_clk               ,input               i_rst               ,input  [15:0]       i_type_A            ,input  [15:0]       i_len_A             ,input  [7 :0]       i_data_A            ,input               i_last_A            ,input               i_valid_A           ,output              o_next_frame_stop   ,input  [15:0]       i_type_B            ,input  [15:0]       i_len_B             ,input  [7 :0]       i_data_B            ,input               i_last_B            ,input               i_valid_B           ,output [15:0]       o_type              ,output [15:0]       o_len               ,output [7 :0]       o_data              ,output              o_last              ,output              o_valid         
);/***************function**************//***************parameter*************//***************port******************/             /***************mechine***************//***************reg*******************/
reg [15:0]              ri_type_A       ;
reg [15:0]              ri_len_A        ;
reg [7 :0]              ri_data_A       ;
reg                     ri_last_A       ;
reg                     ri_valid_A      ;
reg                     ri_valid_A_1d   ;
reg [15:0]              ri_type_B       ;
reg [15:0]              ri_len_B        ;
reg [7 :0]              ri_data_B       ;
reg                     ri_last_B       ;
reg                     ri_valid_B      ;
reg                     ri_valid_B_1d   ;
reg  [7 :0]             ro_data         ;
reg                     ro_last         ;
reg                     ro_valid        ;
reg                     r_fifo_A_rden   ;
reg                     r_fifo_B_rden   ;
reg                     r_fifo_A_rden_1d;
reg                     r_fifo_B_rden_1d;
reg  [1 :0]             r_fifo_rd       ;
reg  [1:0]              r_arbiter       ;
reg  [15:0]             r_rd_cnt        ; 
reg                     r_rd_en         ;
reg                     ro_next_frame_stop  ;
reg  [15:0]             ro_type         ;
reg  [15:0]             ro_len          ;
reg                     r_rden_A_pos    ;
reg                     r_rden_B_pos    ;
reg  [7 :0]             r_cnt           ;/***************wire******************/
wire [7 :0]             w_fifo_A_dout   ;
wire                    w_fifo_A_full   ;
wire                    w_fifo_A_empty  ;
wire [7 :0]             w_fifo_B_dout   ;
wire                    w_fifo_B_full   ;
wire                    w_fifo_B_empty  ;
wire                    w_rd_en         ;
wire                    w_valid_A_pos   ;
wire                    w_valid_B_pos   ;
wire                    w_rden_A_pos    ;
wire                    w_rden_B_pos    ;
wire [31:0]             w_A_type_len    ;
wire [31:0]             w_B_type_len    ;/***************component*************/
FIFO_8X256 FIFO_8X256_U0_A (.clk              (i_clk          ),   .din              (ri_data_A      ),   .wr_en            (ri_valid_A     ), .rd_en            (r_fifo_A_rden  ), .dout             (w_fifo_A_dout  ),  .full             (w_fifo_A_full  ),  .empty            (w_fifo_A_empty )  
);FIFO_32X16 FIFO_32X16_A (.clk              (i_clk                  ),  .din              ({ri_type_A,ri_len_A}   ),  .wr_en            (w_valid_A_pos          ),  .rd_en            (w_rden_A_pos           ),  .dout             (w_A_type_len           ),  .full             (),.empty            () 
);FIFO_8X256 FIFO_8X256_U0_B (.clk              (i_clk          ),   .din              (ri_data_B      ),   .wr_en            (ri_valid_B     ), .rd_en            (r_fifo_B_rden  ), .dout             (w_fifo_B_dout  ),  .full             (w_fifo_B_full  ),  .empty            (w_fifo_B_empty )  
);FIFO_32X16 FIFO_32X16_B (.clk              (i_clk                  ),.din              ({ri_type_B,ri_len_B}   ),.wr_en            (w_valid_B_pos          ),.rd_en            (w_rden_B_pos           ),.dout             (w_B_type_len           ),.full             (), .empty            ()  
);/***************assign****************/
assign o_data  = ro_data    ;
assign o_last  = ro_last    ;
assign o_valid = ro_valid   ;
assign w_rd_en = r_fifo_A_rden | r_fifo_B_rden;
assign o_next_frame_stop = ro_next_frame_stop;
assign w_valid_A_pos = ri_valid_A & !ri_valid_A_1d;
assign w_valid_B_pos = ri_valid_B & !ri_valid_B_1d;
assign w_rden_A_pos = r_fifo_A_rden & !r_fifo_A_rden_1d;
assign w_rden_B_pos = r_fifo_B_rden & !r_fifo_B_rden_1d;
assign o_type       = ro_type;
assign o_len        = ro_len ;/***************always****************/
always@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginri_type_A  <= 'd0;ri_len_A   <= 'd0;ri_data_A  <= 'd0;ri_last_A  <= 'd0;ri_valid_A <= 'd0;ri_type_B  <= 'd0;ri_len_B   <= 'd0;ri_data_B  <= 'd0;ri_last_B  <= 'd0;ri_valid_B <= 'd0;ri_valid_A_1d <= 'd0;ri_valid_B_1d <= 'd0;end else beginri_type_A  <= i_type_A  ;ri_len_A   <= i_len_A   ;ri_data_A  <= i_data_A  ;ri_last_A  <= i_last_A  ;ri_valid_A <= i_valid_A ;ri_type_B  <= i_type_B  ;ri_len_B   <= i_len_B   ;ri_data_B  <= i_data_B  ;ri_last_B  <= i_last_B  ;ri_valid_B <= i_valid_B ;ri_valid_A_1d <= ri_valid_A;ri_valid_B_1d <= ri_valid_B;end
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginr_fifo_A_rden_1d <= 'd0 ;r_fifo_B_rden_1d <= 'd0 ;end else beginr_fifo_A_rden_1d <= r_fifo_A_rden;r_fifo_B_rden_1d <= r_fifo_B_rden;end
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_cnt <= 'd0;else if(r_arbiter)r_cnt <= 'd0;else if(r_cnt == 8)r_cnt <= r_cnt;else if(r_arbiter == 0)r_cnt <= r_cnt + 1;else r_cnt <= 'd0;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_arbiter <= 'd0;else if(ro_last)r_arbiter <= 'd0;else if(!w_fifo_A_empty && r_arbiter == 0 && r_cnt == 8)r_arbiter <= 'd1;else if(!w_fifo_B_empty && r_arbiter == 0 && r_cnt == 8)r_arbiter <= 'd2;else r_arbiter <= r_arbiter;
end always@(posedge i_clk,posedge i_rst)
beginif(i_rst) ro_data  <= 'd0;else if(r_arbiter == 1)  ro_data  <= w_fifo_A_dout;else if(r_arbiter == 2)   ro_data  <= w_fifo_B_dout;else  ro_data  <= 'd0;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_valid <= 'd0;else ro_valid <= r_fifo_rd[0];
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_last <= 'd0;else if(!w_rd_en & r_rd_en)ro_last <= 'd1;else ro_last <= 'd0;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_fifo_A_rden <= 'd0;else if(r_arbiter == 1 && r_rd_cnt == ri_len_A - 1)r_fifo_A_rden <= 'd0;else if(r_arbiter == 1 && !w_fifo_A_empty && !ro_valid)r_fifo_A_rden <= 'd1;else r_fifo_A_rden <= r_fifo_A_rden;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_fifo_B_rden <= 'd0;else if(r_arbiter == 2 && r_rd_cnt == ri_len_B - 1)r_fifo_B_rden <= 'd0;else if(r_arbiter == 2 && !w_fifo_B_empty && !ro_valid)r_fifo_B_rden <= 'd1;else r_fifo_B_rden <= r_fifo_B_rden;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_rd_cnt <= 'd0;else if(r_arbiter == 1 && r_rd_cnt == ri_len_A - 1)r_rd_cnt <= 'd0;else if(r_arbiter == 2 && r_rd_cnt == ri_len_B - 1)r_rd_cnt <= 'd0;else if(r_fifo_A_rden | r_fifo_B_rden)r_rd_cnt <= r_rd_cnt + 1;else r_rd_cnt <= r_rd_cnt;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_fifo_rd <= 'd0;else r_fifo_rd <= {r_fifo_rd[0],(r_fifo_A_rden | r_fifo_B_rden)};
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst)r_rd_en <= 'd0;else r_rd_en <= w_rd_en;
end//流控的过程
//1. A的数据来了,但是B还有帧还没发完,先输出stop信号。
//2. stop时,会A先发打断,完成然后把B的帧发了。
//3. A是空的,B也是空的,并且还在stop状态,此时拉低stop信号,正常输出
always@(posedge i_clk,posedge i_rst)
beginif(i_rst)ro_next_frame_stop <= 'd0;else if(ro_next_frame_stop && r_arbiter == 2 && w_fifo_B_empty)ro_next_frame_stop <= 'd0;else if(r_arbiter == 1 && !w_fifo_B_empty)ro_next_frame_stop <= 'd1;else ro_next_frame_stop <= ro_next_frame_stop;
endalways@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginr_rden_A_pos <= 'd0;r_rden_B_pos <= 'd0;end else beginr_rden_A_pos <= w_rden_A_pos ;r_rden_B_pos <= w_rden_B_pos ;end 
end
always@(posedge i_clk,posedge i_rst)
beginif(i_rst) beginro_type <= 'd0;ro_len  <= 'd0;end else if(r_arbiter == 1 && r_rden_A_pos) beginro_type <= w_A_type_len[31:16];ro_len  <= w_A_type_len[15:0];end else if(r_arbiter == 2 && r_rden_B_pos) beginro_type <= w_B_type_len[31:16];ro_len  <= w_B_type_len[15:0];end else beginro_type <= ro_type;ro_len  <= ro_len ;end
endendmodule

模块收发组合

1 MAC层收发

module Ethernet_MAC#(parameter       P_TARTGET_MAC   =   {8'h00,8'h00,8'h00,8'h00,8'h00,8'h00},P_SOURCE_MAC    =   {8'h00,8'h00,8'h00,8'h00,8'h00,8'h00},P_CRC_CHECK     =   1
)(input           i_clk       ,input           i_rst       ,/*--------info port--------*/   input  [47:0]   i_target_mac        ,input           i_target_mac_valid  ,input  [47:0]   i_source_mac        ,input           i_source_mac_valid  ,/*--------data port--------*/input           i_udp_valid         ,output          o_udp_ready         ,input  [15:0]   i_send_type         ,input  [15:0]   i_send_len          ,input  [7 :0]   i_send_data         ,input           i_send_last         ,input           i_send_valid        ,output [7 :0]   o_ip_data           ,output          o_ip_last           ,output          o_ip_valid          ,output [7 :0]   o_arp_data          ,output          o_arp_last          ,output          o_arp_valid         ,output [47:0]   o_rec_src_mac       ,output          o_rec_src_valid     ,output          o_crc_error         ,   output          o_crc_valid         , /*--------GMII port--------*/output [7 :0]   o_GMII_data         ,output          o_GMII_valid        ,input  [7 :0]   i_GMII_data         ,input           i_GMII_valid
);(* mark_debug = "true" *)wire  [15:0]        w_post_type             ;
(* mark_debug = "true" *)wire  [7 :0]        w_post_data             ;
(* mark_debug = "true" *)wire                w_post_last             ;
(* mark_debug = "true" *)wire                w_post_valid            ;
(* mark_debug = "true" *)wire  [15:0]        w_crc_post_type         ;
(* mark_debug = "true" *)wire  [7 :0]        w_crc_post_data         ;
(* mark_debug = "true" *)wire                w_crc_post_last         ;
(* mark_debug = "true" *)wire                w_crc_post_valid        ;
(* mark_debug = "true" *)wire                w_crc_error             ;       
(* mark_debug = "true" *)wire                w_crc_valid             ;       assign o_crc_error = w_crc_error            ;    
assign o_crc_valid = w_crc_valid            ;    MAC_tx#(.P_TARTGET_MAC          (P_TARTGET_MAC),.P_SOURCE_MAC           (P_SOURCE_MAC ),.P_CRC_CHECK            (P_CRC_CHECK  )  
)
MAC_tx_u0
(.i_clk                  (i_clk             ),.i_rst                  (i_rst             ),.i_target_mac           (i_target_mac      ),.i_target_mac_valid     (i_target_mac_valid),.i_source_mac           (i_source_mac      ),.i_source_mac_valid     (i_source_mac_valid),.i_udp_valid            (i_udp_valid       ),.o_udp_ready            (o_udp_ready       ),.i_send_type            (i_send_type       ),.i_send_len             (i_send_len        ),.i_send_data            (i_send_data       ),.i_send_last            (i_send_last       ),.i_send_valid           (i_send_valid      ),.o_GMII_data            (o_GMII_data       ),.o_GMII_valid           (o_GMII_valid      )
);mac_arp_ip_mux mac_arp_ip_mux_u0(.i_clk                  (i_clk              ),.i_rst                  (i_rst              ),.i_type                 (w_crc_post_type    ),.i_data                 (w_crc_post_data    ),.i_last                 (w_crc_post_last    ),.i_valid                (w_crc_post_valid   ),.o_ip_data              (o_ip_data          ),.o_ip_last              (o_ip_last          ),.o_ip_valid             (o_ip_valid         ),.o_arp_data             (o_arp_data         ),.o_arp_last             (o_arp_last         ),.o_arp_valid            (o_arp_valid        )
);CRC_Data_Pro CRC_Data_Pro_u0(.i_clk                  (i_clk              ),.i_rst                  (i_rst              ),.i_per_type             (w_post_type        ),.i_per_data             (w_post_data        ),.i_per_last             (w_post_last        ),.i_per_valid            (w_post_valid       ),.i_per_crc_error        (w_crc_error        ),.i_per_crc_valid        (w_crc_valid        ),.o_post_type            (w_crc_post_type    ),.o_post_data            (w_crc_post_data    ),.o_post_last            (w_crc_post_last    ),.o_post_valid           (w_crc_post_valid   )   
);MAC_rx#(.P_TARTGET_MAC          (P_TARTGET_MAC      ),.P_SOURCE_MAC           (P_SOURCE_MAC       ),.P_CRC_CHECK            (P_CRC_CHECK        )  
)
MAC_rx_u0
(.i_clk                  (i_clk             ),.i_rst                  (i_rst             ),.i_target_mac           (i_target_mac      ),.i_target_mac_valid     (i_target_mac_valid),.i_source_mac           (i_source_mac      ),.i_source_mac_valid     (i_source_mac_valid),.o_post_type            (w_post_type        ),.o_post_data            (w_post_data        ),.o_post_last            (w_post_last        ),.o_post_valid           (w_post_valid       ),.o_rec_src_mac          (o_rec_src_mac     ),.o_rec_src_valid        (o_rec_src_valid   ),.o_crc_error            (w_crc_error       ),   .o_crc_valid            (w_crc_valid       ),    .i_GMII_data            (i_GMII_data       ),.i_GMII_valid           (i_GMII_valid      )
);endmodule

2 ARP层收发

module Ethernet_ARP#(parameter       P_TARGET_IP = {8'd192,8'd168,8'd1,8'd1},parameter       P_SOURCE_MAC = {8'h00,8'h00,8'h00,8'h00,8'h00,8'h00},parameter       P_SOURCE_IP  = {8'd192,8'd168,8'd1,8'd2}
)(input           i_clk           ,input           i_rst           ,input   [31:0]  i_source_ip     ,input           i_s_ip_valid    ,input   [47:0]  i_source_mac    ,input           i_s_mac_valid   ,input   [31:0]  i_target_ip     ,input           i_target_valid  , input  [31:0]   i_seek_ip           ,input           i_seek_valid        ,output  [47:0]  o_rec_target_mac    ,output          o_rec_target_valid  ,output  [7 :0]  o_mac_data      ,output          o_mac_last      ,output          o_mac_valid     ,input   [7 :0]  i_mac_data      ,input           i_mac_last      ,input           i_mac_valid     
);wire                w_trig_reply    ;
wire [47:0]         w_rec_target_mac    ;   
wire [31:0]         w_target_ip         ;   
wire                w_rec_target_valid  ;
wire [31:0]         w_arp_seek_ip     ;   
wire                w_arp_seek_valid  ;ARP_tx#(.P_TARGET_IP     (P_TARGET_IP                           ),.P_SOURCE_MAC    (P_SOURCE_MAC                          ),.P_SOURCE_IP     (P_SOURCE_IP                           )
)
ARP_tx_u0
(.i_clk           (i_clk                                 ),.i_rst           (i_rst                                 ),.i_target_ip     (i_target_ip                           ),.i_target_valid  (i_target_valid                        ),.i_source_mac    (i_source_mac                          ),.i_s_mac_valid   (i_s_mac_valid                         ),.i_source_ip     (i_source_ip                           ),.i_s_ip_valid    (i_s_ip_valid                          ),.i_reply_mac     (w_rec_target_mac                      ),.i_trig_reply    (w_trig_reply                          ),.i_active_send   (0),.o_seek_ip       (w_arp_seek_ip   ),.o_seek_valid    (w_arp_seek_valid),.o_mac_data      (o_mac_data                            ),.o_mac_last      (o_mac_last                            ),.o_mac_valid     (o_mac_valid                           )
);ARP_Table ARP_Table_u0(.i_clk           (i_clk                                 ),.i_rst           (i_rst                                 ),.i_seek_ip       (i_seek_ip                             ),.i_seek_valid    (i_seek_valid                          ),.i_updata_ip     (w_target_ip                           ),.i_updata_mac    (w_rec_target_mac                      ),.i_updata_valid  (w_rec_target_valid                    ),.o_active_mac    (o_rec_target_mac                      ),.o_active_valid  (o_rec_target_valid                    )
);  ARP_rx#(.P_TARGET_IP     (P_TARGET_IP                           ),.P_SOURCE_MAC    (P_SOURCE_MAC                          ),.P_SOURCE_IP     (P_SOURCE_IP                           )
)
ARP_rx_U0
(.i_clk           (i_clk                                 ),.i_rst           (i_rst                                 ),.i_source_ip     (i_source_ip                           ),.i_s_ip_valid    (i_s_ip_valid                          ),.o_target_mac    (w_rec_target_mac                      ),.o_target_ip     (w_target_ip                           ),.o_target_valid  (w_rec_target_valid                    ),.o_tirg_reply    (w_trig_reply                          ),.i_mac_data      (i_mac_data                            ),.i_mac_last      (i_mac_last                            ),.i_mac_valid     (i_mac_valid                           )
);endmodule

2 IP层收发

module Ethernet_IP#(parameter       P_ST_TARGET_IP = {8'd192,8'd168,8'd1,8'd0},parameter       P_ST_SOURCE_IP = {8'd192,8'd168,8'd1,8'd1}
)(input               i_clk       ,input               i_rst       ,/*--------info port --------*/input  [31:0]   i_target_ip         ,input           i_target_valid      ,input  [31:0]   i_source_ip         ,input           i_source_valid      ,/*--------data port--------*/input  [7 :0]   i_send_type         ,input  [15:0]   i_send_len          ,input  [7 :0]   i_send_data         ,input           i_send_last         ,input           i_send_valid        ,output [15:0]   o_udp_len           ,output [7 :0]   o_udp_data          ,output          o_udp_last          ,output          o_udp_valid         ,output [15:0]   o_icmp_len          ,output [7 :0]   o_icmp_data         ,output          o_icmp_last         ,output          o_icmp_valid        ,output [31:0]   o_source_ip         ,output          o_source_ip_valid   ,/*--------arp port--------*/output [31:0]   o_arp_seek_ip       ,output          o_arp_seek_valid    ,/*--------mac port--------*/output [15:0]   o_mac_type          ,output [15:0]   o_mac_len           ,output [7 :0]   o_mac_data          ,output          o_mac_last          ,output          o_mac_valid         ,input  [7 :0]   i_mac_data          ,input           i_mac_last          ,input           i_mac_valid );IP_tx#(.P_ST_TARGET_IP         (P_ST_TARGET_IP         ),.P_ST_SOURCE_IP         (P_ST_SOURCE_IP         )
)
IP_tx_u0
(.i_clk                  (i_clk                  ),.i_rst                  (i_rst                  ),.i_target_ip            (i_target_ip            ),.i_target_valid         (i_target_valid         ),.i_source_ip            (i_source_ip            ),.i_source_valid         (i_source_valid         ),.i_send_type            (i_send_type            ),.i_send_len             (i_send_len             ),.i_send_data            (i_send_data            ),.i_send_last            (i_send_last            ),.i_send_valid           (i_send_valid           ),.o_arp_seek_ip          (o_arp_seek_ip          ),.o_arp_seek_valid       (o_arp_seek_valid       ),.o_mac_type             (o_mac_type             ),.o_mac_len              (o_mac_len              ),.o_mac_data             (o_mac_data             ),.o_mac_last             (o_mac_last             ),.o_mac_valid            (o_mac_valid            )  
);IP_rx#(.P_ST_TARGET_IP         (P_ST_TARGET_IP         ),   .P_ST_SOURCE_IP         (P_ST_SOURCE_IP         )
)
IP_rx_u0
(.i_clk                  (i_clk                  ),.i_rst                  (i_rst                  ),.i_target_ip            (i_target_ip            ),.i_target_valid         (i_target_valid         ),.i_source_ip            (i_source_ip            ),.i_source_valid         (i_source_valid         ),.o_udp_len              (o_udp_len              ),.o_udp_data             (o_udp_data             ),.o_udp_last             (o_udp_last             ),.o_udp_valid            (o_udp_valid            ),.o_icmp_len             (o_icmp_len             ),.o_icmp_data            (o_icmp_data            ),.o_icmp_last            (o_icmp_last            ),.o_icmp_valid           (o_icmp_valid           ),.o_source_ip            (o_source_ip            ),.o_source_ip_valid      (o_source_ip_valid      ),.i_mac_data             (i_mac_data             ),.i_mac_last             (i_mac_last             ),.i_mac_valid            (i_mac_valid            )   );endmodule
3 ICMP层收发
module Ethernet_ICMP(input           i_clk           ,input           i_rst           ,input  [15:0]   i_icmp_len      ,input  [7 :0]   i_icmp_data     ,input           i_icmp_last     ,input           i_icmp_valid    , output [15:0]   o_icmp_len      ,output [7 :0]   o_icmp_data     ,output          o_icmp_last     ,output          o_icmp_valid    
);wire        w_trig_reply    ;   
wire [31:0] w_trig_seq      ;   ICMP_tx ICMP_tx_u0(.i_clk              (i_clk          ),.i_rst              (i_rst          ),.i_trig_reply       (w_trig_reply   ),.i_trig_seq         (w_trig_seq     ),.o_icmp_len         (o_icmp_len     ),.o_icmp_data        (o_icmp_data    ),.o_icmp_last        (o_icmp_last    ),.o_icmp_valid       (o_icmp_valid   )
);ICMP_rx ICMP_rx_u0(.i_clk              (i_clk          ),.i_rst              (i_rst          ),.i_icmp_len         (i_icmp_len     ),.i_icmp_data        (i_icmp_data    ),.i_icmp_last        (i_icmp_last    ),.i_icmp_valid       (i_icmp_valid   ),           .o_trig_reply       (w_trig_reply   ),.o_trig_seq         (w_trig_seq     )         
);endmodule
3 UDP层收发
module Ethernet_UDP#(parameter           P_TARGET_PORT   =  16'h8080 ,P_SOURCE_PORT   =  16'h8080
)(input               i_clk           ,input               i_rst           ,/*--------info port-------*/input  [15:0]       i_target_port   ,input               i_target_valid  ,input  [15:0]       i_source_port   ,input               i_source_valid  ,/*--------data port--------*/input  [15:0]       i_send_len      ,input  [7 :0]       i_send_data     ,input               i_send_last     ,input               i_send_valid    ,output [15:0]       o_udp_len       ,output [7 :0]       o_udp_data      ,output              o_udp_last      ,output              o_udp_valid     ,/*--------ip port--------*/output [15:0]       o_ip_len        ,output [7 :0]       o_ip_data       ,output              o_ip_last       ,output              o_ip_valid      ,input  [15:0]       i_ip_len        ,input  [7 :0]       i_ip_data       ,input               i_ip_last       ,input               i_ip_valid      
);UDP_tx#(.P_TARGET_PORT      (P_TARGET_PORT),.P_SOURCE_PORT      (P_SOURCE_PORT)
)
UDP_tx_u0
(.i_clk              (i_clk          ),.i_rst              (i_rst          ),.i_target_port      (i_target_port  ),.i_target_valid     (i_target_valid ),.i_source_port      (i_source_port  ),.i_source_valid     (i_source_valid ),.i_send_len         (i_send_len     ),.i_send_data        (i_send_data    ),.i_send_last        (i_send_last    ),.i_send_valid       (i_send_valid   ),.o_ip_len           (o_ip_len       ),.o_ip_data          (o_ip_data      ),.o_ip_last          (o_ip_last      ),.o_ip_valid         (o_ip_valid     )
);UDP_rx#(.P_TARGET_PORT      (P_TARGET_PORT),.P_SOURCE_PORT      (P_SOURCE_PORT)
)
UDP_rx_u0
(.i_clk              (i_clk          ),.i_rst              (i_rst          ),.i_target_port      (i_target_port  ),.i_target_valid     (i_target_valid ),.i_source_port      (i_source_port  ),.i_source_valid     (i_source_valid ),.o_udp_len          (o_udp_len      ),.o_udp_data         (o_udp_data     ),.o_udp_last         (o_udp_last     ),.o_udp_valid        (o_udp_valid    ),.i_ip_len           (i_ip_len       ),.i_ip_data          (i_ip_data      ),.i_ip_last          (i_ip_last      ),.i_ip_valid         (i_ip_valid     )
);
endmodule

UDP协议栈

在这里插入图片描述

 module UDP_Stack_Module#(parameter           P_TARGET_PORT   = 16'h8080                                 ,P_SOURCE_PORT   = 16'h8080                                 ,P_TARGET_IP     = {8'd192,8'd168,8'd1,8'd0}                ,P_SOURCE_IP     = {8'd192,8'd168,8'd1,8'd1}                ,P_TARTGET_MAC   = {8'h00,8'h00,8'h00,8'h00,8'h00,8'h00}    ,P_SOURCE_MAC    = {8'h00,8'h00,8'h00,8'h00,8'h00,8'h00}    ,P_CRC_CHEKC     =  1                                                                               
)(input               i_clk               ,input               i_rst               ,/*--------info port-------*/    input  [15:0]       i_target_port       ,input               i_target_port_valid ,input  [15:0]       i_source_port       ,input               i_source_port_valid ,input  [31:0]       i_target_ip         ,input               i_target_ip_valid   ,input  [31:0]       i_source_ip         ,input               i_source_ip_valid   ,input  [47:0]       i_target_mac        ,input               i_target_mac_valid  ,input  [47:0]       i_source_mac        ,input               i_source_mac_valid  ,/*--------data port--------*/input  [15:0]       i_send_len          ,input  [7 :0]       i_send_data         ,input               i_send_last         ,input               i_send_valid        ,output              o_send_ready        ,output [15:0]       o_rec_len           ,output [7 :0]       o_rec_data          ,output              o_rec_last          ,output              o_rec_valid         ,output [31:0]       o_source_ip         ,output              o_source_ip_valid   ,output [47:0]       o_rec_src_mac       ,output              o_rec_src_valid     ,output              o_crc_error         ,   output              o_crc_valid         , /*--------GMII port--------*/output [7 :0]       o_GMII_data         ,output              o_GMII_valid        ,input  [7 :0]       i_GMII_data         ,input               i_GMII_valid
);wire                    w_udp_ready             ;
wire                    w_ip_next_frame_stop    ;
wire                    w_udp_next_frame_stop   ;
wire [15:0]             w_udp2ip_len            ;    
wire [7 :0]             w_udp2ip_data           ;    
wire                    w_udp2ip_last           ;    
wire                    w_udp2ip_valid          ;    
(* mark_debug = "true" *)wire [15:0]             w_ip2udp_len            ;    
(* mark_debug = "true" *)wire [7 :0]             w_ip2udp_data           ;    
(* mark_debug = "true" *)wire                    w_ip2udp_last           ;    
(* mark_debug = "true" *)wire                    w_ip2udp_valid          ;    wire [15:0]             w_icmp_rec_len          ;
wire [7 :0]             w_icmp_rec_data         ;
wire                    w_icmp_rec_last         ;
wire                    w_icmp_rec_valid        ;
wire [15:0]             w_icmp_send_len         ;
wire [7 :0]             w_icmp_send_data        ;
wire                    w_icmp_send_last        ;
wire                    w_icmp_send_valid       ;wire [15:0]             w_icmp_udp_type         ;
wire [15:0]             w_icmp_udp_len          ;
wire [7 :0]             w_icmp_udp_data         ;
wire                    w_icmp_udp_last         ;
wire                    w_icmp_udp_valid        ;wire [47:0]             w_arp_rec_target_mac    ;
wire                    w_arp_rec_target_valid  ;wire [7 :0]             w_arp2mac_data          ;
wire                    w_arp2mac_last          ;
wire                    w_arp2mac_valid         ;
wire [7 :0]             w_mac2arp_data          ;
wire                    w_mac2arp_last          ;
wire                    w_mac2arp_valid         ;wire [15:0]             w_ip2mac_type           ;
wire [15:0]             w_ip2mac_len            ;
wire [7 :0]             w_ip2mac_data           ;
wire                    w_ip2mac_last           ;
wire                    w_ip2mac_valid          ;
(* mark_debug = "true" *)wire [7 :0]             w_mac2ip_data           ;
(* mark_debug = "true" *)wire                    w_mac2ip_last           ;
(* mark_debug = "true" *)wire                    w_mac2ip_valid          ;wire [15:0]             w_ip_icmp_2_mac_type    ;
wire [15:0]             w_ip_icmp_2_mac_len     ;
wire [7 :0]             w_ip_icmp_2_mac_data    ;
wire                    w_ip_icmp_2_mac_last    ;
wire                    w_ip_icmp_2_mac_valid   ;wire [31:0]             w_arp_seek_ip           ;
wire                    w_arp_seek_valid        ;wire                    w_send_ready            ;
reg                     ro_send_ready           ;
reg  [7 :0]             r_ready_cnt             ;
reg                     ri_send_valid           ;assign o_send_ready     = w_send_ready;
assign w_send_ready     = ~w_ip_next_frame_stop & ~w_udp_next_frame_stop & w_udp_ready;Ethernet_UDP#(.P_TARGET_PORT              (P_TARGET_PORT      ),.P_SOURCE_PORT              (P_SOURCE_PORT      )  
)           
Ethernet_UDP_u0         
(           .i_clk                      (i_clk              ),.i_rst                      (i_rst              ),.i_target_port              (i_target_port      ),.i_target_valid             (i_target_port_valid),.i_source_port              (i_source_port      ),.i_source_valid             (i_source_port_valid),.i_send_len                 (i_send_len         ),.i_send_data                (i_send_data        ),.i_send_last                (i_send_last        ),.i_send_valid               (i_send_valid       ),.o_udp_len                  (o_rec_len          ),.o_udp_data                 (o_rec_data         ),.o_udp_last                 (o_rec_last         ),.o_udp_valid                (o_rec_valid        ),.o_ip_len                   (w_udp2ip_len       ),.o_ip_data                  (w_udp2ip_data      ),.o_ip_last                  (w_udp2ip_last      ),.o_ip_valid                 (w_udp2ip_valid     ),.i_ip_len                   (w_ip2udp_len       ),.i_ip_data                  (w_ip2udp_data      ),.i_ip_last                  (w_ip2udp_last      ),.i_ip_valid                 (w_ip2udp_valid     )
);Ethernet_ICMP Ethernet_ICMP_u0(.i_clk                      (i_clk              ),.i_rst                      (i_rst              ),.i_icmp_len                 (w_icmp_rec_len     ),.i_icmp_data                (w_icmp_rec_data    ),.i_icmp_last                (w_icmp_rec_last    ),.i_icmp_valid               (w_icmp_rec_valid   ), .o_icmp_len                 (w_icmp_send_len    ),.o_icmp_data                (w_icmp_send_data   ),.o_icmp_last                (w_icmp_send_last   ),.o_icmp_valid               (w_icmp_send_valid  )
);Data_2to1 Data_2to1_ICMP_UDP(.i_clk                      (i_clk              ),.i_rst                      (i_rst              ),.i_type_A                   (17                 ),.i_len_A                    (w_udp2ip_len       ),.i_data_A                   (w_udp2ip_data      ),.i_last_A                   (w_udp2ip_last      ),.i_valid_A                  (w_udp2ip_valid     ),.o_next_frame_stop          (w_udp_next_frame_stop),.i_type_B                   (1                  ),.i_len_B                    (w_icmp_send_len    ),.i_data_B                   (w_icmp_send_data   ),.i_last_B                   (w_icmp_send_last   ),.i_valid_B                  (w_icmp_send_valid  ),.o_type                     (w_icmp_udp_type    ),.o_len                      (w_icmp_udp_len     ),.o_data                     (w_icmp_udp_data    ),.o_last                     (w_icmp_udp_last    ),.o_valid                    (w_icmp_udp_valid   )
);Ethernet_ARP#(.P_TARGET_IP                (P_TARGET_IP                            ),.P_SOURCE_MAC               (P_SOURCE_MAC                           ),.P_SOURCE_IP                (P_SOURCE_IP                            )
)   
Ethernet_ARP_u0 
(   .i_clk                      (i_clk                                  ),.i_rst                      (i_rst                                  ),.i_source_ip                (i_source_ip                            ),.i_s_ip_valid               (i_source_ip_valid                      ),.i_source_mac               (i_source_mac                           ),.i_s_mac_valid              (i_source_mac_valid                     ),.i_target_ip                (i_target_ip                            ),.i_target_valid             (i_target_ip_valid                      ), .i_seek_ip                  (w_arp_seek_ip                          ),.i_seek_valid               (w_arp_seek_valid                       ),.o_rec_target_mac           (w_arp_rec_target_mac                   ),.o_rec_target_valid         (w_arp_rec_target_valid                 ),.o_mac_data                 (w_arp2mac_data                         ),.o_mac_last                 (w_arp2mac_last                         ),.o_mac_valid                (w_arp2mac_valid                        ),.i_mac_data                 (w_mac2arp_data                         ),.i_mac_last                 (w_mac2arp_last                         ),.i_mac_valid                (w_mac2arp_valid                        )
);Ethernet_IP#(.P_ST_TARGET_IP             (P_TARGET_IP            ),.P_ST_SOURCE_IP             (P_SOURCE_IP            )
)
Ethernet_IP_u0
(.i_clk                      (i_clk                  ),.i_rst                      (i_rst                  ),.i_target_ip                (i_target_ip            ),.i_target_valid             (i_target_ip_valid      ),.i_source_ip                (i_source_ip            ),.i_source_valid             (i_source_ip_valid      ),.i_send_type                (w_icmp_udp_type[7 :0]  ),.i_send_len                 (w_icmp_udp_len         ),.i_send_data                (w_icmp_udp_data        ),.i_send_last                (w_icmp_udp_last        ),.i_send_valid               (w_icmp_udp_valid       ),.o_udp_len                  (w_ip2udp_len           ),.o_udp_data                 (w_ip2udp_data          ),.o_udp_last                 (w_ip2udp_last          ),.o_udp_valid                (w_ip2udp_valid         ),.o_icmp_len                 (w_icmp_rec_len         ),.o_icmp_data                (w_icmp_rec_data        ),.o_icmp_last                (w_icmp_rec_last        ),.o_icmp_valid               (w_icmp_rec_valid       ),.o_source_ip                (o_source_ip            ),.o_source_ip_valid          (o_source_ip_valid      ),.o_arp_seek_ip              (w_arp_seek_ip          ),.o_arp_seek_valid           (w_arp_seek_valid       ),.o_mac_type                 (w_ip2mac_type          ),.o_mac_len                  (w_ip2mac_len           ),.o_mac_data                 (w_ip2mac_data          ),.o_mac_last                 (w_ip2mac_last          ),.o_mac_valid                (w_ip2mac_valid         ),.i_mac_data                 (w_mac2ip_data          ),.i_mac_last                 (w_mac2ip_last          ),.i_mac_valid                (w_mac2ip_valid         )   );Data_2to1 Data_2to1_ARP_IP(.i_clk                      (i_clk              ),.i_rst                      (i_rst              ),.i_type_A                   (16'h0806           ),.i_len_A                    (50                 ),.i_data_A                   (w_arp2mac_data     ),.i_last_A                   (w_arp2mac_last     ),.i_valid_A                  (w_arp2mac_valid    ),.o_next_frame_stop          (w_ip_next_frame_stop),.i_type_B                   (w_ip2mac_type      ),.i_len_B                    (w_ip2mac_len       ),.i_data_B                   (w_ip2mac_data      ),.i_last_B                   (w_ip2mac_last      ),.i_valid_B                  (w_ip2mac_valid     ),.o_type                     (w_ip_icmp_2_mac_type   ),.o_len                      (w_ip_icmp_2_mac_len    ),.o_data                     (w_ip_icmp_2_mac_data   ),.o_last                     (w_ip_icmp_2_mac_last   ),.o_valid                    (w_ip_icmp_2_mac_valid  )
);Ethernet_MAC#(.P_TARTGET_MAC              (P_TARTGET_MAC                          ),.P_SOURCE_MAC               (P_SOURCE_MAC                           ),.P_CRC_CHECK                (P_CRC_CHEKC                            ) 
)   
Ethernet_MAC_u0 
(   .i_clk                      (i_clk                              ),.i_rst                      (i_rst                              ),.i_target_mac               (w_arp_rec_target_mac               ),.i_target_mac_valid         (w_arp_rec_target_valid             ),.i_source_mac               (i_source_mac                       ),.i_source_mac_valid         (i_source_mac_valid                 ),.i_udp_valid                (i_send_valid                       ),.o_udp_ready                (w_udp_ready                        ),.i_send_type                (w_ip_icmp_2_mac_type               ),.i_send_len                 (w_ip_icmp_2_mac_len                ),.i_send_data                (w_ip_icmp_2_mac_data               ),.i_send_last                (w_ip_icmp_2_mac_last               ),.i_send_valid               (w_ip_icmp_2_mac_valid              ),.o_ip_data                  (w_mac2ip_data                      ),.o_ip_last                  (w_mac2ip_last                      ),.o_ip_valid                 (w_mac2ip_valid                     ),.o_arp_data                 (w_mac2arp_data                     ),.o_arp_last                 (w_mac2arp_last                     ),.o_arp_valid                (w_mac2arp_valid                    ),.o_rec_src_mac              (o_rec_src_mac                      ),.o_rec_src_valid            (o_rec_src_valid                    ),.o_crc_error                (o_crc_error                        ),   .o_crc_valid                (o_crc_valid                        ), .o_GMII_data                (o_GMII_data                        ),.o_GMII_valid               (o_GMII_valid                       ),.i_GMII_data                (i_GMII_data                        ),.i_GMII_valid               (i_GMII_valid                       )    
);endmodule

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