usrp2/timing/time_receiver.v


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module time_receiver
  (input clk, input rst,
   output [31:0] master_time,
   output sync_rcvd,
   input exp_pps_in);

   wire       code_err, disp_err, dispout, complete_word;
   reg 	      disp_reg;
   reg [9:0]  shiftreg;
   reg [3:0]  bit_count;
   wire [8:0] dataout;
   reg [8:0]  dataout_reg;
 	      
   always @(posedge clk)
     shiftreg <= {exp_pps_in, shiftreg[9:1]};

   localparam COMMA_0 = 10'h283;
   localparam COMMA_1 = 10'h17c;
   
   wire       found_comma = (shiftreg == COMMA_0) | (shiftreg == COMMA_1);
   wire       set_disp = (shiftreg == COMMA_1);

   always @(posedge clk)
     if(rst)
       bit_count <= 0;
     else if(found_comma | complete_word)
       bit_count <= 0;
     else 
       bit_count <= bit_count + 1;
   assign     complete_word = (bit_count == 9);

   always @(posedge clk)
     if(set_disp)
       disp_reg <= 1;
     else if(complete_word)
       disp_reg <= dispout;

   always @(posedge clk)
     if(complete_word)
       dataout_reg <= dataout;
     
   decode_8b10b decode_8b10b 
     (.datain(shiftreg),.dispin(disp_reg),
      .dataout(dataout),.dispout(dispout),
      .code_err(code_err),.disp_err(disp_err) );

   reg 	      error;
   always @(posedge clk)
     if(complete_word)
       error <= code_err | disp_err;
   
   localparam STATE_IDLE = 0;
   localparam STATE_T0 = 1;
   localparam STATE_T1 = 2;
   localparam STATE_T2 = 3;
   localparam STATE_T3 = 4;
   
   localparam HEAD = 9'h13c;   

   reg [7:0]  clock_a, clock_b, clock_c;
   reg [2:0]  state;
   
   always @(posedge clk)
     if(rst)
       state <= STATE_IDLE;
     else if(complete_word)
       case(state)
	 STATE_IDLE :
	   if(dataout_reg == HEAD)
	     state <= STATE_T0;
	 STATE_T0 :
	   begin
	      clock_a <= dataout_reg[7:0];
	      state <= STATE_T1;
	   end
	 STATE_T1 :
	   begin
	      clock_b <= dataout_reg[7:0];
	      state <= STATE_T2;
	   end
	 STATE_T2 :
	   begin
	      clock_c <= dataout_reg[7:0];
	      state <= STATE_T3;
	   end
	 STATE_T3 :
	   state <= STATE_IDLE;
       endcase // case(state)

   assign master_time =  {clock_a, clock_b, clock_c, dataout_reg[7:0]};
   assign sync_rcvd = (complete_word & (state == STATE_T3));

endmodule // time_sender