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[/] [spacewiresystemc/] [trunk/] [rtl/] [RTL_VB/] [rx_spw.v] - Rev 34
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//+FHDR------------------------------------------------------------------------ //Copyright (c) 2013 Latin Group American Integhrated Circuit, Inc. All rights reserved //GLADIC Open Source RTL //----------------------------------------------------------------------------- //FILE NAME : //DEPARTMENT : IC Design / Verification //AUTHOR : Felipe Fernandes da Costa //AUTHOR’S EMAIL : //----------------------------------------------------------------------------- //RELEASE HISTORY //VERSION DATE AUTHOR DESCRIPTION //1.0 YYYY-MM-DD name //----------------------------------------------------------------------------- //KEYWORDS : General file searching keywords, leave blank if none. //----------------------------------------------------------------------------- //PURPOSE : ECSS_E_ST_50_12C_31_july_2008 //----------------------------------------------------------------------------- //PARAMETERS //PARAM NAME RANGE : DESCRIPTION : DEFAULT : UNITS //e.g.DATA_WIDTH [32,16] : width of the data : 32: //----------------------------------------------------------------------------- //REUSE ISSUES //Reset Strategy : //Clock Domains : //Critical Timing : //Test Features : //Asynchronous I/F : //Scan Methodology : //Instantiations : //Synthesizable (y/n) : //Other : //-FHDR------------------------------------------------------------------------ `timescale 1ns/1ns module RX_SPW ( input rx_din, input rx_sin, input rx_resetn, output reg rx_error, output reg rx_got_bit, output reg rx_got_null, output reg rx_got_nchar, output reg rx_got_time_code, output reg rx_got_fct, output reg rx_got_fct_fsm, output reg [8:0] rx_data_flag, output reg rx_buffer_write, output [7:0] rx_time_out, output reg rx_tick_out ); reg [5:0] counter_neg; reg control_bit_found; reg data_bit_found; wire posedge_clk; wire negedge_clk; reg bit_c_0;//N reg bit_c_1;//P reg bit_c_2;//N reg bit_c_3;//P reg bit_d_0;//N reg bit_d_1;//P reg bit_d_2;//N reg bit_d_3;//P reg bit_d_4;//N reg bit_d_5;//P reg bit_d_6;//N reg bit_d_7;//P reg bit_d_8;//N reg bit_d_9;//P reg is_control; //reg is_data; reg last_is_control; reg last_is_data; reg last_is_timec; reg last_was_control; reg last_was_data; reg last_was_timec; reg [3:0] control; reg [3:0] control_r; reg [3:0] control_p_r; reg [9:0] data; reg [9:0] timecode; reg [3:0] control_l_r; reg [9:0] data_l_r; reg [9:0] dta_timec; reg [9:0] dta_timec_p; reg rx_data_take; reg rx_data_take_0; reg ready_control; reg ready_data; reg ready_control_p; reg ready_data_p; reg ready_control_p_r; reg ready_data_p_r; reg posedge_p; //CLOCK RECOVERY assign posedge_clk = posedge_p; assign negedge_clk = !posedge_p; assign rx_time_out = timecode[7:0]; always@(*) begin rx_got_bit = 1'b0; if(rx_din | rx_sin) begin rx_got_bit = 1'b1; end end always@(*) begin ready_control = 1'b0; ready_data = 1'b0; if(counter_neg[5:0] == 6'd4 && !posedge_p) begin ready_control = 1'b1; end else if(counter_neg[5:0] == 6'd32 && !posedge_p) begin ready_data = 1'b1; end end always@(*) begin ready_control_p = 1'b0; ready_data_p = 1'b0; if(counter_neg[5:0] == 6'd4 && posedge_p) begin ready_control_p = 1'b1; end else if(counter_neg[5:0] == 6'd32 && posedge_p) begin ready_data_p = 1'b1; end end always@(*) begin posedge_p = 1'b0; if(rx_din ^ rx_sin) begin posedge_p = 1'b1; end else begin posedge_p = 1'b0; end end always@(posedge posedge_clk or negedge rx_resetn) begin if(!rx_resetn) begin bit_d_1 <= 1'b0; bit_d_3 <= 1'b0; bit_d_5 <= 1'b0; bit_d_7 <= 1'b0; bit_d_9 <= 1'b0; end else begin bit_d_1 <= rx_din; bit_d_3 <= bit_d_1; bit_d_5 <= bit_d_3; bit_d_7 <= bit_d_5; bit_d_9 <= bit_d_7; end end always@(posedge negedge_clk or negedge rx_resetn) begin if(!rx_resetn) begin bit_d_0 <= 1'b0; bit_d_2 <= 1'b0; bit_d_4 <= 1'b0; bit_d_6 <= 1'b0; bit_d_8 <= 1'b0; end else begin bit_d_0 <= rx_din; bit_d_2 <= bit_d_0; bit_d_4 <= bit_d_2; bit_d_6 <= bit_d_4; bit_d_8 <= bit_d_6; end end always@(posedge posedge_clk or negedge rx_resetn) begin if(!rx_resetn) begin bit_c_1 <= 1'b0; bit_c_3 <= 1'b0; end else begin bit_c_1 <= rx_din; bit_c_3 <= bit_c_1; end end always@(posedge negedge_clk or negedge rx_resetn) begin if(!rx_resetn) begin bit_c_0 <= 1'b0; bit_c_2 <= 1'b0; end else begin bit_c_0 <= rx_din; bit_c_2 <= bit_c_0; end end always@(posedge negedge_clk or negedge rx_resetn) begin if(!rx_resetn) begin rx_got_fct <= 1'b0; end else begin if(control_l_r[2:0] != 3'd7 && control[2:0] == 3'd4 && (ready_control_p_r)) begin rx_got_fct <= 1'b1; end else begin rx_got_fct <= 1'b0; end end end always@(posedge negedge_clk or negedge rx_resetn) begin if(!rx_resetn) begin rx_error <= 1'b0; end else begin if(last_is_control == 1'b1) begin if(last_was_control == 1'b1) begin if(!(control[2]^control_l_r[0]^control_l_r[1]) != control[3]) begin rx_error <= 1'b1; end else begin rx_error <= 1'b0; end end else if(last_was_timec == 1'b1) begin if(!(control[2]^timecode[0]^timecode[1]^timecode[2]^timecode[3]^timecode[4]^timecode[5]^timecode[6]^timecode[7]) != control[3]) begin rx_error <= 1'b1; end else begin rx_error <= 1'b0; end end else if(last_was_data == 1'b1) begin if(!(control[2]^data[0]^data[1]^data[2]^data[3]^data[4]^data[5]^data[6]^data[7]) != control[3]) begin rx_error <= 1'b1; end else begin rx_error <= 1'b0; end end end else if(last_is_data == 1'b1) begin if(last_was_control == 1'b1) begin if(!(data[8]^control[1]^control[0]) != data[9]) begin rx_error <= 1'b1; end else begin rx_error <= 1'b0; end end else if(last_was_timec == 1'b1) begin if(!(data[8]^timecode[0]^timecode[1]^timecode[2]^timecode[3]^timecode[4]^timecode[5]^timecode[6]^timecode[7]) != data[9]) begin rx_error <= 1'b1; end else begin rx_error <= 1'b0; end end else if(last_was_data == 1'b1) begin if(!(data[8]^data[0]^data_l_r[1]^data_l_r[2]^data_l_r[3]^data_l_r[4]^data_l_r[5]^data_l_r[6]^data_l_r[7]) != data[9]) begin rx_error <= 1'b1; end else begin rx_error <= 1'b0; end end end end end always@(posedge negedge_clk or negedge rx_resetn) begin if(!rx_resetn) begin rx_got_null <= 1'b0; rx_got_nchar <= 1'b0; rx_got_time_code <= 1'b0; end else begin if(last_is_data == 1'b1 ) begin rx_got_nchar <= 1'b1; end else if(last_is_timec == 1'b1) begin rx_got_time_code <= 1'b1; end else if(last_is_control == 1'b1) begin rx_got_null <= 1'b1; end else begin rx_got_null <= 1'b0; rx_got_nchar <= 1'b0; rx_got_time_code <= 1'b0; end end end always@(posedge negedge_clk or negedge rx_resetn) begin if(!rx_resetn) begin rx_got_fct_fsm <= 1'b0; rx_buffer_write <= 1'b0; rx_data_take_0 <= 1'b0; ready_control_p_r <= 1'b0; ready_data_p_r <= 1'b0; end else begin rx_data_take_0 <= rx_data_take; rx_buffer_write <= rx_data_take_0; if(ready_control || ready_control_p) begin if(is_control) ready_control_p_r <= 1'b1; end else begin ready_control_p_r <= 1'b0; end if(ready_data || ready_data_p) begin if(!is_control) ready_data_p_r <= 1'b1; end else begin ready_data_p_r <= 1'b0; end if((control_l_r[2:0] != 3'd7 && control[2:0] == 3'd4 && last_is_control == 1'b1 ) == 1'b1) rx_got_fct_fsm <= 1'b1; else rx_got_fct_fsm <= rx_got_fct_fsm; end end always@(posedge ready_control or negedge rx_resetn ) begin if(!rx_resetn) begin control_r <= 4'd0; end else begin //if(is_control) control_r <= {bit_c_3,bit_c_2,bit_c_1,bit_c_0}; end end always@(posedge ready_control_p or negedge rx_resetn ) begin if(!rx_resetn) begin control_p_r <= 4'd0; end else begin //if(is_control) control_p_r <= control_r; end end always@(posedge ready_data or negedge rx_resetn ) begin if(!rx_resetn) begin dta_timec <= 10'd0; end else begin //if(!is_control) dta_timec <= {bit_d_9,bit_d_8,bit_d_0,bit_d_1,bit_d_2,bit_d_3,bit_d_4,bit_d_5,bit_d_6,bit_d_7}; end end always@(posedge ready_data_p or negedge rx_resetn ) begin if(!rx_resetn) begin dta_timec_p <= 10'd0; end else begin //if(!is_control) dta_timec_p <= dta_timec; end end always@(posedge negedge_clk or negedge rx_resetn) begin if(!rx_resetn) begin is_control <= 1'b0; control_bit_found <= 1'b0; counter_neg[5:0] <= 6'd1; end else begin control_bit_found <= rx_din; case(counter_neg) 6'd1: begin counter_neg[5:0] <= 6'd2; end 6'd2: begin if(control_bit_found == 1'b1) begin is_control <= 1'b1; end else begin is_control <= 1'b0; end counter_neg[5:0] <= 6'd4; end 6'd4: begin if(is_control == 1'b1) begin counter_neg[5:0] <= 6'd2; is_control <= 1'b0; end else begin counter_neg[5:0] <= 6'd8; end end 6'd8: begin counter_neg[5:0] <= 6'd16; end 6'd16: begin counter_neg[5:0] <= 6'd32; end 6'd32: begin is_control <= 1'b0; counter_neg[5:0] <= 6'd2; end default: begin is_control <= is_control; counter_neg[5:0] <= counter_neg[5:0]; end endcase end end always@(posedge posedge_clk or negedge rx_resetn ) begin if(!rx_resetn) begin control_l_r <= 4'd0; control <= 4'd0; data <= 10'd0; data_l_r <= 10'd0; rx_data_flag <= 9'd0; rx_data_take <= 1'b0; timecode <= 10'd0; rx_tick_out <= 1'b0; last_is_control <= 1'b0; last_is_data <= 1'b0; last_is_timec <= 1'b0; last_was_control <= 1'b0; last_was_data <= 1'b0; last_was_timec <= 1'b0; end else begin if(ready_control_p_r) begin control <= control_p_r; control_l_r <= control; last_is_control <= 1'b1; last_is_data <= 1'b0; last_is_timec <= 1'b0; last_was_control <= last_is_control; last_was_data <= last_is_data ; last_was_timec <= last_is_timec; end else if(ready_data_p_r) begin if(control[2:0] != 3'd7) begin rx_data_flag <= {dta_timec_p[8],dta_timec_p[7],dta_timec_p[6],dta_timec_p[5],dta_timec_p[4],dta_timec_p[3],dta_timec_p[2],dta_timec_p[1],dta_timec_p[0]}; data <= {dta_timec_p[9],dta_timec_p[8],dta_timec_p[7],dta_timec_p[6],dta_timec_p[5],dta_timec_p[4],dta_timec_p[3],dta_timec_p[2],dta_timec_p[1],dta_timec_p[0]}; data_l_r <= data; last_is_control <=1'b0; last_is_data <=1'b1; last_is_timec <=1'b0; last_was_control <= last_is_control; last_was_data <= last_is_data ; last_was_timec <= last_is_timec; end else if(control[2:0] == 3'd7) begin timecode <= dta_timec; last_is_control <= 1'b0; last_is_data <= 1'b0; last_is_timec <= 1'b1; last_was_control <= last_is_control; last_was_data <= last_is_data ; last_was_timec <= last_is_timec; end end else if(last_is_timec == 1'b1) begin rx_data_take <= 1'b0; rx_tick_out <= 1'b1; end else if(last_is_data == 1'b1) begin rx_tick_out <= 1'b0; rx_data_take <= 1'b1; end else if(last_is_control == 1'b1) begin if(control[2:0] == 3'd6) begin rx_data_flag <= 9'd257; rx_data_take <= 1'b1; end else if(control[2:0] == 3'd5) begin rx_data_flag <= 9'd256; rx_data_take <= 1'b1; end else begin rx_data_take <= 1'b0; end rx_tick_out <= 1'b0; end end end endmodule
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