module Asyn_FIFO_tb;

     parameter WIDTH = ;

     reg clk_wr;

     reg clk_rd;

     reg rst_n_rd;

     reg rst_n_wr;

     reg  [WIDTH-:] data_wr;

     reg  wr_en;

     wire wr_full;

     wire [WIDTH-:] data_rd;

     reg  rd_en;

     wire rd_empty;

     Asyn_FIFO fifo_inst(

     .clk_wr(clk_wr),

     .rst_n_rd(rst_n_rd),

     .rst_n_wr(rst_n_wr),

     .wr_en(wr_en),

     .data_wr(data_wr),

     .clk_rd(clk_rd),

     .rd_en(rd_en),

     .data_rd(data_rd),

     .rd_empty(rd_empty),

     .wr_full(wr_full)

     );

     initial begin

         rst_n_rd = ;

         rst_n_wr = ;

         clk_wr = ;

         clk_rd = ;

         wr_en = ;

         rd_en = ;

         #

         rst_n_rd = ;

         rst_n_wr = ;

         #

         wr_en = ;

         rd_en = ;

         #

         wr_en = ;

         rd_en = ;

     end

     always # clk_wr = ~clk_wr;

     always # clk_rd = ~clk_rd;

 /*     always @(posedge clk_rd)

         rd_en <= ($random) % 2;

     always @(posedge clk_wr)

         wr_en <= ($random) % 2; */

     always @(posedge clk_wr)

         data_wr <= ($random) % ;

 endmodule

 module Asyn_FIFO

 #(

     parameter WIDTH = ,

     parameter DEPTH =

 )

 (

     input  clk_wr,

     input  clk_rd,

     input  rst_n_rd,

     input  rst_n_wr,

     input  wr_en,

     input  rd_en,

     input  [WIDTH-:] data_wr,

     output [WIDTH-:] data_rd,

     output reg rd_empty,

     output reg wr_full

 );

     //defination

     reg  [WIDTH- : ] mem [ : (<<DEPTH)-];        //2^DEPTH numbers

     reg  [DEPTH   : ] wp, rp;

     reg  [DEPTH   : ] wr1_rp, wr2_rp, rd1_wp, rd2_wp;

     reg  [DEPTH   : ] wbin, rbin;

     wire [DEPTH- : ] waddr, raddr;

     wire [DEPTH   : ] wbin_next, rbin_next;        //bincode

     wire [DEPTH   : ] wgray_next, rgray_next;        //graycode

     wire rd_empty_val, wr_full_val;

     //output

     assign data_rd = (rd_en && !rd_empty) ? mem[raddr] : ;        //clear "xx" state

     //input

     always@(posedge clk_wr)

         if(wr_en && !wr_full)

             mem[waddr] <= data_wr;

 /*----------generate waddr and raddr-------------------------*/

     //gen raddr and read gray code

     always@(posedge clk_rd or negedge rst_n_rd)

         if(!rst_n_rd)

             {rbin, rp} <= ;

         else

             {rbin, rp} <= {rbin_next, rgray_next};

     assign raddr = rbin[DEPTH- : ];

     assign rbin_next = rbin + (rd_en & ~rd_empty);

     assign rgray_next = rbin_next ^ (rbin_next >> );

     //gen waddr and write gray code

     always@(posedge clk_wr or negedge rst_n_wr)

         if(!rst_n_wr)

             {wbin, wp} <= ;

         else

             {wbin, wp} <= {wbin_next, wgray_next};

     assign waddr = wbin[DEPTH- : ];

     assign wbin_next = wbin + (wr_en & ~wr_full);

     assign wgray_next = wbin_next ^ (wbin_next >> );

 /*---------------synchro rp and wp--------------------------*/

     //synchro rp

     always@(posedge clk_wr or negedge rst_n_wr)

         if(!rst_n_wr)

             {wr2_rp, wr1_rp} <= ;

         else

             {wr2_rp, wr1_rp} <= {wr1_rp, rp}; //delay two clock

     //synchro wp

     always@(posedge clk_rd or negedge rst_n_rd)

         if(!rst_n_rd)

             {rd2_wp, rd1_wp} <= ;

         else

             {rd2_wp, rd1_wp} <= {rd1_wp, wp};

 /*---------------empty and full flags--------------------------*/

     //gen rd_empty

     assign rd_empty_val = (rd2_wp == rgray_next);

     always@(posedge clk_rd or negedge rst_n_rd)

         if(!rst_n_rd)

             rd_empty <= 'b1;

         else

             rd_empty <= rd_empty_val;

     //gen wr_full, two high bit do not equal

     assign wr_full_val = ({~wr2_rp[DEPTH : DEPTH-], wr2_rp[DEPTH- : ]} == wgray_next);

     always@(posedge clk_wr or negedge rst_n_wr)

         if(!rst_n_wr)

             wr_full <= 'b0;

         else

             wr_full <= wr_full_val;

 endmodule