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------------------------------------------------------------------------------- -- -- Title : 8b/10b Decoder -- Design : 10-bit to 8-bit Decoder -- Project : 8000 - 8b10b_encdec -- Author : Ken Boyette -- Company : Critia Computer, Inc. -- ------------------------------------------------------------------------------- -- -- File : 8b10b_dec.vhd -- Version : 1.0 -- Generated : 09.27.2006 -- By : Itf2Vhdl ver. 1.20 -- ------------------------------------------------------------------------------- -- -- Description : -- This module provides 10-bit to 9-bit encoding. -- It accepts 10-bit encoded parallel data input and generates 8-bit decoded -- data output in accordance with the 8b/10b standard method. This method was -- described in the 1983 IBM publication "A DC-Balanced, Partitioned-Block, -- 8B/10B Transmission Code" by A.X. Widmer and P.A. Franaszek. The method -- WAS granted a U.S. Patent #4,486,739 in 1984; now expired. -- -- The parallel 10-bit Binary input represent 1024 possible values, called -- characters - only 268 of which are valid. -- -- The input is a 10-bit encoded character whose bits are identified as: -- AI, BI, CI, DI, EI, II, FI, GI, HI, JI (Least Significant to Most) -- -- In addition to 256 data output characters, there are 12 special control -- or K, characters defined for command and synchronization use. -- -- The eight data output bits are identified as: -- HI, GI, FI, EI, DI, CI, BI, AI (Most Significant to Least) -- -- The output, KO, is used to indicate the output value is one of the -- control characters. -- -- All inputs and outputs are synchronous with an externally supplied -- byte rate clock BYTECLK. -- The encoded output is valid one clock after the input. -- There is a reset input, RESET, to reset the logic. The next rising -- BYTECLK after RESET is deasserted latches valid input data. -- -- Note: This VHDL structure closely follows the discrete logic defined -- in the original article and the subsequent patent. The Figures -- referenced are those in the patent. ------------------------------------------------------------------------------- -- This program is licensed under the GPL ------------------------------------------------------------------------------- library IEEE; use IEEE.STD_LOGIC_1164.all; entity dec_8b10b is port( RESET : in std_logic ; -- Global asynchronous reset (AH) RBYTECLK : in std_logic ; -- Master synchronous receive byte clock AI, BI, CI, DI, EI, II : in std_logic ; FI, GI, HI, JI : in std_logic ; -- Encoded input (LS..MS) KO : out std_logic ; -- Control (K) character indicator (AH) HO, GO, FO, EO, DO, CO, BO, AO : out std_logic -- Decoded out (MS..LS) ); end dec_8b10b; architecture behavioral of dec_8b10b is -- Signals to tie things together signal ANEB, CNED, EEI, P13, P22, P31 : std_logic ; -- Figure 10 Signals signal IKA, IKB, IKC : std_logic ; -- Figure 11 Signals signal XA, XB, XC, XD, XE : std_logic ; -- Figure 12 Signals signal OR121, OR122, OR123, OR124, OR125, OR126, OR127 : std_logic ; signal XF, XG, XH : std_logic ; -- Figure 13 Signals signal OR131, OR132, OR133, OR134, IOR134 : std_logic ; begin -- -- 6b Input Function (Reference: Figure 10) -- -- One 1 and three 0's P13 <= (ANEB and (not CI and not DI)) or (CNED and (not AI and not BI)) ; -- Three 1's and one 0 P31 <= (ANEB and CI and DI) or (CNED and AI and BI) ; -- Two 1's and two 0's P22 <= (AI and BI and (not CI and not DI)) or (CI and DI and (not AI and not BI)) or (ANEB and CNED) ; -- Intermediate term for "AI is Not Equal to BI" ANEB <= AI xor BI ; -- Intermediate term for "CI is Not Equal to DI" CNED <= CI xor DI ; -- Intermediate term for "E is Equal to I" EEI <= EI xnor II ; -- -- K Decoder - Figure 11 -- -- Intermediate terms IKA <= (CI and DI and EI and II) or (not CI and not DI and not EI and not II) ; IKB <= P13 and (not EI and II and GI and HI and JI) ; IKC <= P31 and (EI and not II and not GI and not HI and not JI) ; -- PROCESS: KFN; Determine K output KFN: process (RESET, RBYTECLK, IKA, IKB, IKC) begin if RESET = '1' then KO <= '0'; elsif RBYTECLK'event and RBYTECLK = '0' then KO <= IKA or IKB or IKC; end if; end process KFN; -- -- 5b Decoder Figure 12 -- -- Logic to determine complimenting A,B,C,D,E,I inputs OR121 <= (P22 and (not AI and not CI and EEI)) or (P13 and not EI) ; OR122 <= (AI and BI and EI and II) or (not CI and not DI and not EI and not II) or (P31 and II) ; OR123 <= (P31 and II) or (P22 and BI and CI and EEI) or (P13 and DI and EI and II) ; OR124 <= (P22 and AI and CI and EEI) or (P13 and not EI) ; OR125 <= (P13 and not EI) or (not CI and not DI and not EI and not II) or (not AI and not BI and not EI and not II) ; OR126 <= (P22 and not AI and not CI and EEI) or (P13 and not II) ; OR127 <= (P13 and DI and EI and II) or (P22 and not BI and not CI and EEI) ; XA <= OR127 or OR121 or OR122 ; XB <= OR122 or OR123 or OR124 ; XC <= OR121 or OR123 or OR125 ; XD <= OR122 or OR124 or OR127 ; XE <= OR125 or OR126 or OR127 ; -- PROCESS: DEC5B; Generate and latch LS 5 decoded bits DEC5B: process (RESET, RBYTECLK, XA, XB, XC, XD, XE, AI, BI, CI, DI, EI) begin if RESET = '1' then AO <= '0' ; BO <= '0' ; CO <= '0' ; DO <= '0' ; EO <= '0' ; elsif RBYTECLK'event and RBYTECLK = '0' then AO <= XA XOR AI ; -- Least significant bit 0 BO <= XB XOR BI ; CO <= XC XOR CI ; DO <= XD XOR DI ; EO <= XE XOR EI ; -- Most significant bit 6 end if; end process DEC5B; -- -- 3b Decoder - Figure 13 -- -- Logic for complimenting F,G,H outputs OR131 <= (GI and HI and JI) or (FI and HI and JI) or (IOR134); OR132 <= (FI and GI and JI) or (not FI and not GI and not HI) or (not FI and not GI and HI and JI); OR133 <= (not FI and not HI and not JI) or (IOR134) or (not GI and not HI and not JI) ; OR134 <= (not GI and not HI and not JI) or (FI and HI and JI) or (IOR134) ; IOR134 <= (not (HI and JI)) and (not (not HI and not JI)) and (not CI and not DI and not EI and not II) ; XF <= OR131 or OR132 ; XG <= OR132 or OR133 ; XH <= OR132 or OR134 ; -- PROCESS: DEC3B; Generate and latch MS 3 decoded bits DEC3B: process (RESET, RBYTECLK, XF, XG, XH, FI, GI, HI) begin if RESET = '1' then FO <= '0' ; GO <= '0' ; HO <= '0' ; elsif RBYTECLK'event and RBYTECLK ='0' then FO <= XF XOR FI ; -- Least significant bit 7 GO <= XG XOR GI ; HO <= XH XOR HI ; -- Most significant bit 10 end if; end process DEC3B ; end behavioral;