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[/] [1000base-x/] [trunk/] [rtl/] [verilog/] [encoder_8b10b.v] - Rev 3
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////////////////////////////////////////////////////////////////////// //// //// //// File name "encoder_8b10b.v" //// //// //// //// This file is part of the : //// //// //// //// "1000BASE-X IEEE 802.3-2008 Clause 36 - PCS project" //// //// //// //// http://opencores.org/project,1000base-x //// //// //// //// Author(s): //// //// - D.W.Pegler Cambridge Broadband Networks Ltd //// //// //// //// { peglerd@gmail.com, dwp@cambridgebroadand.com } //// //// //// ////////////////////////////////////////////////////////////////////// //// //// //// Copyright (C) 2009 AUTHORS. All rights reserved. //// //// //// //// This source file may be used and distributed without //// //// restriction provided that this copyright statement is not //// //// removed from the file and that any derivative work contains //// //// the original copyright notice and the associated disclaimer. //// //// //// //// This source file is free software; you can redistribute it //// //// and/or modify it under the terms of the GNU Lesser General //// //// Public License as published by the Free Software Foundation; //// //// either version 2.1 of the License, or (at your option) any //// //// later version. //// //// //// //// This source is distributed in the hope that it will be //// //// useful, but WITHOUT ANY WARRANTY; without even the implied //// //// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR //// //// PURPOSE. See the GNU Lesser General Public License for more //// //// details. //// //// //// //// You should have received a copy of the GNU Lesser General //// //// Public License along with this source; if not, download it //// //// from http://www.opencores.org/lgpl.shtml //// //// //// ////////////////////////////////////////////////////////////////////// //// //// //// This module is based on the coding method described in //// //// IEEE Std 802.3-2008 Section 36.2.4 which is available from : //// //// //// //// http://standards.ieee.org/about/get/802/802.3.html //// //// //// //// and the 8B/10B coding scheme from the 1993 IBM publication //// //// "DC-Balanced, Partitioned-Block, 8B/10B Transmission Code" //// //// by A.X. Widmer and P.A. Franasze" see doc/01-581v1.pdf //// //// //// //// and US patent #4,486,739 "BYTE ORIENTED DC BALANCED //// //// (0,4) 8B/10B PARTITIONED BLOCK TRANSMISSION CODE "; see : //// //// //// //// doc/US4486739.pdf //// //// //// //// http://en.wikipedia.org/wiki/8b/10b_encoding //// //// //// ////////////////////////////////////////////////////////////////////// `include "timescale.v" module encoder_8b10b ( // --- Resets input reset, // --- Clocks input SBYTECLK, // --- Control (K) input input K, // --- Eight Bt input bus input [7:0] ebi, // --- TB (Ten Bt Interface) output bus output [9:0] tbi, output reg disparity ); // Figure 3 - Encoder: 5B/6B classification, L functions wire L40, L04, L13, L31, L22, AeqB, CeqD; // Figure 5 - 5B/6B Encoder: disparity classifications wire PD_1S6, NDOS6, PDOS6, ND_1S6; // Figure 5 - 3B/4B Encoder: disparity classifications wire ND_1S4, PD_1S4, NDOS4, PDOS4; // Figure 6 - Encoder: control of complementation wire illegalk, DISPARITY6; reg COMPLS6, COMPLS4; // Figure 7 - 5B/6B encoding wire NAO, NBO, NCO, NDO, NEO, NIO; // Figure 8: 3B/4B encoding wire NFO, NGO, NHO, NJO; // 8B Inputs wire A,B,C,D,E,F,G,H; assign {H,G,F,E,D,C,B,A} = ebi[7:0]; // 10B Outputs reg a,b,c,d,e,i,f,g,h,j; assign tbi[9:0] = {a,b,c,d,e,i,f,g,h,j}; wire [9:0] tst; assign tst[9:0] = {NAO,NBO,NCO,NDO,NEO,NIO,NFO,NGO,NHO,NJO}; // ****************************************************************************** // Figures 7 & 8 - Latched 5B/6B and 3B/4B encoder outputs // ****************************************************************************** always @(posedge SBYTECLK, posedge reset) if (reset) begin disparity <= 1'b0; {a,b,c,d,e,i,f,g,h,j} <= 10'b0; end else begin disparity <= (PDOS4 | NDOS4) ^ DISPARITY6; {a,b,c,d,e,i,f,g,h,j} <= { NAO^COMPLS6, NBO^COMPLS6, NCO^COMPLS6, NDO^COMPLS6, NEO^COMPLS6, NIO^COMPLS6, NFO^COMPLS4, NGO^COMPLS4, NHO^COMPLS4, NJO^COMPLS4 }; end // else: !if(reset) // ****************************************************************************** // Figure 3 - Encoder: 5B/6B classification, L functions // ****************************************************************************** assign AeqB = (A & B) | (!A & !B); assign CeqD = (C & D) | (!C & !D); assign L40 = A & B & C & D ; assign L04 = !A & !B & !C & !D; assign L13 = (!AeqB & !C & !D) | (!CeqD & !A & !B); assign L31 = (!AeqB & C & D) | (!CeqD & A & B); assign L22 = (A & B & !C & !D) | (C & D & !A & !B) | ( !AeqB & !CeqD) ; // ****************************************************************************** // Figure 5 - 5B/6B Encoder: disparity classifications // ****************************************************************************** assign PD_1S6 = (E & D & !C & !B & !A) | (!E & !L22 & !L31) ; //assign PD_1S6 = (L13 & D & E) | (!E & !L22 & !L31) ; assign NDOS6 = PD_1S6 ; assign PDOS6 = K | (E & !L22 & !L13) ; assign ND_1S6 = K | (E & !L22 & !L13) | (!E & !D & C & B & A) ; // ****************************************************************************** // Figure 5 - 3B/4B Encoder: disparity classifications // ****************************************************************************** assign ND_1S4 = F & G ; assign NDOS4 = (!F & !G) ; assign PD_1S4 = (!F & !G) | (K & ((F & !G) | (!F & G))); assign PDOS4 = F & G & H ; // ****************************************************************************** // Figure 6 - Encoder: control of complementation // ****************************************************************************** // not K28.0->7 & K23/27/29/30.7 assign illegalk = K & (A | B | !C | !D | !E) & (!F | !G | !H | !E | !L31); assign DISPARITY6 = disparity ^ (NDOS6 | PDOS6) ; always @(posedge SBYTECLK, posedge reset) if(reset) begin COMPLS4 <= 0; COMPLS6 <= 0; end else begin COMPLS4 <= (PD_1S4 & !DISPARITY6) | (ND_1S4 & DISPARITY6); COMPLS6 <= (PD_1S6 & !disparity) | (ND_1S6 & disparity); end // ****************************************************************************** // Figure 7 - 5B/6B encoding // ****************************************************************************** reg tNAO, tNBOx, tNBOy, tNCOx, tNCOy, tNDO , tNEOx, tNEOy, tNIOw, tNIOx, tNIOy, tNIOz; always @(posedge SBYTECLK, posedge reset) if(reset) begin tNAO <= 0; tNBOx <= 0; tNBOy <= 0; tNCOx <= 0; tNCOy <= 0; tNDO <= 0; tNEOx <= 0; tNEOy <= 0; tNIOw <= 0; tNIOx <= 0; tNIOy <= 0; tNIOz <= 0; end else begin tNAO <= A ; tNBOx <= B & !L40; tNBOy <= L04 ; tNCOx <= L04 | C ; tNCOy <= E & D & !C & !B & !A ; tNDO <= D & ! (A & B & C) ; tNEOx <= E | L13; tNEOy <= !(E & D & !C & !B & !A) ; tNIOw <= (L22 & !E) | (E & L40) ; tNIOx <= E & !D & !C & !(A & B) ; tNIOy <= K & E & D & C & !B & !A ; tNIOz <= E & !D & C & !B & !A ; end assign NAO = tNAO ; assign NBO = tNBOx | tNBOy ; assign NCO = tNCOx | tNCOy ; assign NDO = tNDO ; assign NEO = tNEOx & tNEOy ; assign NIO = tNIOw | tNIOx | tNIOy | tNIOz; // ****************************************************************************** // Figure 8: 3B/4B encoding // ****************************************************************************** reg alt7, tNFO, tNGO, tNHO, tNJO; always @(posedge SBYTECLK, posedge reset) if(reset) begin alt7 <= 0; tNFO <= 0; tNGO <= 0; tNHO <= 0; tNJO <= 0; end else begin alt7 <= F & G & H & (K | (disparity ? (!E & D & L31) : (E & !D & L13))) ; tNFO <= F; tNGO <= G | (!F & !G & !H) ; tNHO <= H ; tNJO <= !H & (G ^ F) ; end assign NFO = tNFO & !alt7 ; assign NGO = tNGO ; assign NHO = tNHO ; assign NJO = tNJO | alt7 ; endmodule