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-- $Id: ibdr_rl11.vhd 784 2016-07-09 22:17:01Z mueller $ -- -- Copyright 2014-2016 by Walter F.J. Mueller <W.F.J.Mueller@gsi.de> -- -- This program is free software; you may redistribute and/or modify it under -- the terms of the GNU General Public License as published by the Free -- Software Foundation, either version 2, or at your option any later version. -- -- This program 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 General Public License -- for complete details. -- ------------------------------------------------------------------------------ -- Module Name: ibdr_rl11 - syn -- Description: ibus dev(rem): RL11 -- -- Dependencies: ram_1swar_gen -- Test bench: - -- Target Devices: generic -- Tool versions: ise 14.7; viv 2014.4-2016.1; ghdl 0.31-0.33 -- -- Synthesized (xst): -- Date Rev ise Target flop lutl lutm slic t peri -- 2015-02-28 653 14.7 131013 xc6slx16-2 80 197 12 80 s 7.9 -- 2014-06-15 562 14.7 131013 xc6slx16-2 81 199 13 78 s 8.0 -- -- Revision History: -- Date Rev Version Comment -- 2016-05-22 767 1.0.2 don't init N_REGS (vivado fix for fsm inference) -- 2015-03-04 655 1.0.1 seek: ignore da(6:5), don't check for 0 anymore -- 2015-02-28 653 1.0 Initial verison -- 2014-06-09 561 0.1 First draft ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; use work.slvtypes.all; use work.memlib.all; use work.iblib.all; -- ---------------------------------------------------------------------------- entity ibdr_rl11 is -- ibus dev(rem): RL11 -- fixed address: 174400 port ( CLK : in slbit; -- clock CE_MSEC : in slbit; -- msec pulse BRESET : in slbit; -- ibus reset RB_LAM : out slbit; -- remote attention IB_MREQ : in ib_mreq_type; -- ibus request IB_SRES : out ib_sres_type; -- ibus response EI_REQ : out slbit; -- interrupt request EI_ACK : in slbit -- interrupt acknowledge ); end ibdr_rl11; architecture syn of ibdr_rl11 is constant ibaddr_rl11 : slv16 := slv(to_unsigned(8#174400#,16)); constant ibaddr_rlcs : slv2 := "00"; -- rlcs address offset constant ibaddr_rlba : slv2 := "01"; -- rlba address offset constant ibaddr_rlda : slv2 := "10"; -- rlda address offset constant ibaddr_rlmp : slv2 := "11"; -- rlmp address offset -- usage of 16x16 memory bank -- 0 0000 unused (but mirrors rlcs) -- 1 0001 rlba -- 2 0010 unused (but mirrors rlda) -- 3 0011 rlmp (1st value) -- 4 0100 rlmp (3rd value after gs; the crc) -- 5 0101 unused -- 6 0110 unused -- 7 0111 unused (target for bad mprem states) -- 11: 8 10-- sta(ds) (drive status) -- 15:12 11-- pos(ds) (drive disk address) constant imem_cs : slv4 := "0000"; -- unused constant imem_ba : slv4 := "0001"; constant imem_da : slv4 := "0010"; -- unused constant imem_mp : slv4 := "0011"; constant imem_crc : slv4 := "0100"; constant imem_bad : slv4 := "0111"; -- target for bad mprem states constant imem_sta : slv4 := "1000"; constant imem_pos : slv4 := "1100"; subtype imf_typ is integer range 3 downto 2; subtype imf_ds is integer range 1 downto 0; constant rlcs_ibf_err : integer := 15; constant rlcs_ibf_de : integer := 14; subtype rlcs_ibf_e is integer range 13 downto 10; subtype rlcs_ibf_ds is integer range 9 downto 8; constant rlcs_ibf_crdy : integer := 7; constant rlcs_ibf_ie : integer := 6; subtype rlcs_ibf_bae is integer range 5 downto 4; subtype rlcs_ibf_func is integer range 3 downto 1; constant rlcs_ibf_drdy : integer := 0; constant func_noop : slv3 := "000"; -- func: noop constant func_wchk : slv3 := "001"; -- func: write check constant func_gs : slv3 := "010"; -- func: get status constant func_seek : slv3 := "011"; -- func: seek constant func_rhdr : slv3 := "100"; -- func: read header constant func_write : slv3 := "101"; -- func: write data constant func_read : slv3 := "110"; -- func: read data constant func_rnhc : slv3 := "111"; -- func: read data without header check constant e_ok : slv4 := "0000"; -- e code: ok constant e_incomp : slv4 := "0001"; -- e code: operation incomplete -- defs for rem access of rlcs; func codes constant rfunc_wcs : slv3 := "001"; -- rem func: write cs (err,de,e,drdy) constant rfunc_wmp : slv3 := "010"; -- rem func: write mprem or mploc -- rlcs usage or rem func=wmp subtype rlcs_ibf_mprem is integer range 15 downto 11; subtype rlcs_ibf_mploc is integer range 10 downto 8; constant rlcs_ibf_ena_mprem : integer := 5; constant rlcs_ibf_ena_mploc : integer := 4; subtype rlda_ibf_seek_df is integer range 15 downto 7; constant rlda_ibf_seek_hs : integer := 4; constant rlda_ibf_seek_dir : integer := 2; constant rlda_msk_seek : slv16 := "0000000000001011"; constant rlda_val_seek : slv16 := "0000000000000001"; constant rlda_ibf_gs_rst : integer := 3; constant rlda_msk_gs : slv16 := "0000000011110111"; constant rlda_val_gs : slv16 := "0000000000000011"; constant sta_ibf_wde : integer := 15; -- Write data error - always 0 constant sta_ibf_che : integer := 14; -- Current head error - always 0 constant sta_ibf_wl : integer := 13; -- Write lock - used constant sta_ibf_sto : integer := 12; -- Seek time out - used constant sta_ibf_spe : integer := 11; -- Spin error - used constant sta_ibf_wge : integer := 10; -- Write gate error - used constant sta_ibf_vce : integer := 9; -- Volume check - used constant sta_ibf_dse : integer := 8; -- Drive select error - used constant sta_ibf_dt : integer := 7; -- Drive type - used constant sta_ibf_hs : integer := 6; -- Head select - used constant sta_ibf_co : integer := 5; -- Cover open - used constant sta_ibf_ho : integer := 4; -- Heads out - used constant sta_ibf_bh : integer := 3; -- Brush home - always 1 subtype sta_ibf_st is integer range 2 downto 0; -- Drive state constant st_load : slv3 := "000"; -- st: Load(ing) cartidge - used constant st_spin : slv3 := "001"; -- st: Spin(ing) up - !unused! constant st_brush : slv3 := "010"; -- st: Brush(ing) cycle - !unused! constant st_hload : slv3 := "011"; -- st: Load(ing) heads - !unused! constant st_seek : slv3 := "100"; -- st: Seek(ing) - may be used constant st_lock : slv3 := "101"; -- st: Lock(ed) on - used constant st_unl : slv3 := "110"; -- st: Unload(ing) heads - !unused! constant st_down : slv3 := "111"; -- st: Spin(ing) down - !unused! -- only two mayor drive states are used -- on: st=lock; ho=1; co=0; ( file connected in backend) -- off: st=load; ho=0; co=1; (no file connected in backend) subtype pos_ibf_ca is integer range 15 downto 7; constant pos_ibf_hs : integer := 6; subtype pos_ibf_sa is integer range 5 downto 0; constant mploc_mp : slv3 := "000"; -- return imem(mp) constant mploc_sta : slv3 := "001"; -- return sta(ds) constant mploc_pos : slv3 := "010"; -- return pos(ds) constant mploc_zero : slv3 := "011"; -- return 0 constant mploc_crc : slv3 := "100"; -- return imem(crc) constant mprem_f_map : integer := 4; -- mprem map enable subtype mprem_f_addr is integer range 3 downto 0; constant mprem_f_seq : integer := 3; -- mprem seq enable subtype mprem_f_state is integer range 2 downto 0; constant mprem_mapseq : slv2 := "11"; -- enable map + seq constant mprem_s_mp : slv3 := "000"; -- access imem(mp) constant mprem_s_sta : slv3 := "001"; -- access sta(ds) constant mprem_s_pos : slv3 := "010"; -- access pos(ds) constant mprem_init : slv5 := "10000"; -- enable map,fix, show mp constant ca_max_rl01 : slv9 := "011111111"; -- max cylinder for RL01 (255) constant ca_max_rl02 : slv9 := "111111111"; -- max cylinder for RL02 (511) type state_type is ( s_idle, -- idle: handle ibus s_csread, -- csread: handle cs read s_gs_rpos, -- gs_rpos: read pos(ds) s_gs_sta, -- gs_sta: handle status s_seek_rsta, -- seek_rsta: read sta(ds) s_seek_rpos, -- seek_rpos: read pos(ds) s_seek_clip, -- seek_clip: clip new ca s_seek_wpos, -- seek_wpos: write pos(ds) s_init -- init: handle init ); type regs_type is record -- state registers ibsel : slbit; -- ibus select state : state_type; -- state iaddr : slv4; -- init addr counter cserr : slbit; -- rlcs: composite error csde : slbit; -- rlcs: drive error cse : slv4; -- rlcs: error csds : slv2; -- rlcs: drive select cscrdy : slbit; -- rlcs: controller ready csie : slbit; -- rlcs: interrupt enable csbae : slv2; -- rlcs: bus address extenstion csfunc : slv3; -- rlcs: function code csdrdy : slbit; -- rlcs: drive ready da : slv16; -- rlda shadow reg gshs : slbit; -- gs: pos(ds)(hs) (head select) seekdt : slbit; -- seek: drive type: 0=RL01, 1=RL02 seekcan: slv10; -- seek: cylinder address, new seekcac: slv9; -- seek: cylinder address, clipped ireq : slbit; -- interrupt request flag mploc : slv3; -- mp loc state mprem : slv5; -- mp rem state crdone : slbit; -- control reset done since last fdone end record regs_type; constant regs_init : regs_type := ( '0', -- ibsel s_init, -- state imem_ba, -- iaddr '0','0', -- cserr,csde (others=>'0'), -- cse (others=>'0'), -- csds '1','0', -- cscrdy, csie (others=>'0'), -- csbae (others=>'0'), -- csfunc '0', -- csdrdy (others=>'0'), -- da '0', -- gshs '0', -- seekdt (others=>'0'), -- seekcan (others=>'0'), -- seekcac '0', -- ireq mploc_mp, -- mploc mprem_init, -- mprem '1' -- crdone ); signal R_REGS : regs_type := regs_init; signal N_REGS : regs_type; -- don't init (vivado fix for fsm infer) signal MEM_1_WE : slbit := '0'; signal MEM_0_WE : slbit := '0'; signal MEM_ADDR : slv4 := (others=>'0'); signal MEM_DIN : slv16 := (others=>'0'); signal MEM_DOUT : slv16 := (others=>'0'); begin MEM_1 : ram_1swar_gen generic map ( AWIDTH => 4, DWIDTH => 8) port map ( CLK => CLK, WE => MEM_1_WE, ADDR => MEM_ADDR, DI => MEM_DIN(ibf_byte1), DO => MEM_DOUT(ibf_byte1)); MEM_0 : ram_1swar_gen generic map ( AWIDTH => 4, DWIDTH => 8) port map ( CLK => CLK, WE => MEM_0_WE, ADDR => MEM_ADDR, DI => MEM_DIN(ibf_byte0), DO => MEM_DOUT(ibf_byte0)); proc_regs: process (CLK) begin if rising_edge(CLK) then if BRESET='1' then R_REGS <= regs_init; else R_REGS <= N_REGS; end if; end if; end process proc_regs; proc_next : process (R_REGS, CE_MSEC, IB_MREQ, MEM_DOUT, EI_ACK) variable r : regs_type := regs_init; variable n : regs_type := regs_init; variable ibhold : slbit := '0'; variable idout : slv16 := (others=>'0'); variable ibrem : slbit := '0'; variable ibreq : slbit := '0'; variable ibrd : slbit := '0'; variable ibw0 : slbit := '0'; variable ibw1 : slbit := '0'; variable ibwrem : slbit := '0'; variable ilam : slbit := '0'; variable iei_req : slbit := '0'; variable imem_we0 : slbit := '0'; variable imem_we1 : slbit := '0'; variable imem_addr : slv4 := (others=>'0'); variable imem_din : slv16 := (others=>'0'); begin r := R_REGS; n := R_REGS; ibhold := '0'; idout := (others=>'0'); ibrem := IB_MREQ.racc; ibreq := IB_MREQ.re or IB_MREQ.we; ibrd := IB_MREQ.re; ibw0 := IB_MREQ.we and IB_MREQ.be0; ibw1 := IB_MREQ.we and IB_MREQ.be1; ibwrem := IB_MREQ.we and ibrem; ilam := '0'; iei_req := '0'; imem_we0 := '0'; imem_we1 := '0'; imem_addr := "00" & IB_MREQ.addr(2 downto 1); imem_din := IB_MREQ.din; -- ibus address decoder n.ibsel := '0'; if IB_MREQ.aval = '1' and IB_MREQ.addr(12 downto 3)=ibaddr_rl11(12 downto 3) then n.ibsel := '1'; end if; -- internal state machine case r.state is when s_idle => -- idle: handle ibus ----------------- if r.ibsel='1' then -- selected idout := MEM_DOUT; imem_we0 := ibw0; imem_we1 := ibw1; case IB_MREQ.addr(2 downto 1) is when ibaddr_rlcs => -- RLCS - control register ------- imem_we0 := '0'; -- MEM not used for rlcs imem_we1 := '0'; imem_addr := imem_sta(imf_typ) & r.csds; -- get sta(ds) -- determine DRDY n.csdrdy := '1'; if MEM_DOUT(sta_ibf_st) /= st_lock or -- drive not on and locked MEM_DOUT(sta_ibf_vce) = '1' then -- or volume check -- ??? also CRDY=0 here ??? n.csdrdy := '0'; end if; -- determine DE and ERR n.cserr := '0'; if MEM_DOUT(sta_ibf_st) = st_load or -- drive off MEM_DOUT(sta_ibf_vce) = '1' then -- or volume check n.csde := '1'; n.cserr := '1'; end if; if r.csde = '1' or r.cse /= e_ok then n.cserr := '1'; end if; if ibrd = '1' then -- cs read ibhold := '1'; n.state := s_csread; elsif IB_MREQ.we = '1' then -- cs write if ibrem = '0' then -- loc write access if IB_MREQ.be1 = '1' then if r.cscrdy = '1' then -- freeze csds when busy n.csds := IB_MREQ.din(rlcs_ibf_ds); end if; end if; if IB_MREQ.be0 = '1' then n.csie := IB_MREQ.din(rlcs_ibf_ie); n.csbae := IB_MREQ.din(rlcs_ibf_bae); if r.cscrdy = '1' then -- controller ready n.csfunc := IB_MREQ.din(rlcs_ibf_func); -- latch func if IB_MREQ.din(rlcs_ibf_crdy) = '1' then -- no crdy clr if IB_MREQ.din(rlcs_ibf_ie) = '1' and r.csie = '0' then n.ireq := '1'; end if; else -- crdy clr --> handle func n.cserr := '0'; -- clear errors n.csde := '0'; n.cse := "0000"; case IB_MREQ.din(rlcs_ibf_func) is when func_noop => -- noop ------- n.ireq := r.csie; -- interrupt when func_gs => -- get status - if (r.da and rlda_msk_gs) /= rlda_val_gs then n.cserr := '1'; n.cse := e_incomp; n.ireq := IB_MREQ.din(rlcs_ibf_ie); else ibhold := '1'; n.state := s_gs_rpos; end if; when func_seek => -- seek ------- if (r.da and rlda_msk_seek) /= rlda_val_seek then n.cserr := '1'; n.cse := e_incomp; n.ireq := IB_MREQ.din(rlcs_ibf_ie); else ibhold := '1'; n.state := s_seek_rsta; end if; when others => -- all other funcs n.cscrdy := '0'; -- signal cntl busy ilam := '1'; -- issue lam end case; end if; -- else IB_MREQ.din(rlcs_ibf_crdy) = '1' end if; -- r.cscrdy = '1' end if; -- IB_MREQ.be0 = '1' else -- rem write access case IB_MREQ.din(rlcs_ibf_func) is when rfunc_wcs => n.csde := IB_MREQ.din(rlcs_ibf_de); n.cse := IB_MREQ.din(rlcs_ibf_e); n.cscrdy := IB_MREQ.din(rlcs_ibf_crdy); n.csbae := IB_MREQ.din(rlcs_ibf_bae); if r.cscrdy = '0' and IB_MREQ.din(rlcs_ibf_crdy) = '1' then n.ireq := r.csie; end if; when rfunc_wmp => if IB_MREQ.din(rlcs_ibf_ena_mprem) = '1' then n.mprem := IB_MREQ.din(rlcs_ibf_mprem); end if; if IB_MREQ.din(rlcs_ibf_ena_mploc) = '1' then n.mploc := IB_MREQ.din(rlcs_ibf_mploc); end if; when others => null; end case; end if; end if; when ibaddr_rlba => -- RLBA - bus address register --- imem_din(0) := '0'; -- lsb forced 0 null; when ibaddr_rlda => -- RLDA - disk address register -- if ibw1 = '1' then n.da(15 downto 8) := IB_MREQ.din(15 downto 8); end if; if ibw0 = '1' then n.da( 7 downto 0) := IB_MREQ.din( 7 downto 0); end if; when ibaddr_rlmp => -- RLMP - multipurpose register -- if ibrem = '0' then -- loc access if ibrd = '1' then -- loc mp read case r.mploc is when mploc_mp => -- return imem(mp) null; when mploc_sta => -- return sta(ds) imem_addr := imem_sta(imf_typ) & r.csds; when mploc_pos => -- return pos(ds) imem_addr := imem_pos(imf_typ) & r.csds; n.mploc := mploc_zero; when mploc_zero => -- return 0 idout := (others => '0'); n.mploc := mploc_crc; when mploc_crc => -- return imem(crc) imem_addr := imem_crc; when others => null; end case; elsif IB_MREQ.we = '1' then -- loc mp write n.mploc := mploc_mp; -- use main mp reg in future end if; else -- rem access if r.mprem(mprem_f_map) = '0' then -- map off - fixed addr imem_addr := r.mprem(mprem_f_addr); else -- sequence case r.mprem(mprem_f_state) is when mprem_s_mp => -- mp {used as wc} imem_addr := imem_mp; if r.mprem(mprem_f_seq) = '1' then -- ??? check re&we !!! n.mprem := mprem_mapseq & mprem_s_sta; end if; when mprem_s_sta => -- sta(ds) imem_addr := imem_sta(imf_typ) & r.csds; if r.mprem(mprem_f_seq) = '1' then -- ??? check re&we !!! n.mprem := mprem_mapseq & mprem_s_pos; end if; when mprem_s_pos => -- pos(ds) imem_addr := imem_pos(imf_typ) & r.csds; when others => -- bad state imem_addr := imem_bad; end case; end if; end if; when others => null; end case; end if; when s_csread => -- csread: handle cs read ----------- idout(rlcs_ibf_err) := r.cserr; idout(rlcs_ibf_de) := r.csde; idout(rlcs_ibf_e) := r.cse; idout(rlcs_ibf_ds) := r.csds; idout(rlcs_ibf_crdy) := r.cscrdy; idout(rlcs_ibf_ie) := r.csie; idout(rlcs_ibf_bae) := r.csbae; idout(rlcs_ibf_func) := r.csfunc; idout(rlcs_ibf_drdy) := r.csdrdy; n.state := s_idle; when s_gs_rpos => -- gs_rpos: read pos(ds) ----------- imem_addr := imem_pos(imf_typ) & r.csds; -- get pos(ds) n.gshs := MEM_DOUT(pos_ibf_hs); -- get hs bit ibhold := r.ibsel; n.state := s_gs_sta; when s_gs_sta => -- gs_sta: handle status ----------- imem_addr := imem_sta(imf_typ) & r.csds; -- get sta(ds) imem_we0 := '1'; -- always update imem_we1 := '1'; imem_din := MEM_DOUT; imem_din(sta_ibf_hs) := r.gshs; if r.da(rlda_ibf_gs_rst) = '1' then -- if RST set imem_din(sta_ibf_wde) := '0'; -- clear error bits imem_din(sta_ibf_che) := '0'; imem_din(sta_ibf_sto) := '0'; imem_din(sta_ibf_spe) := '0'; imem_din(sta_ibf_wge) := '0'; imem_din(sta_ibf_vce) := '0'; imem_din(sta_ibf_dse) := '0'; end if; n.mploc := mploc_sta; -- use sta(ds) as mp n.ireq := r.csie; -- interrupt n.state := s_idle; when s_seek_rsta => -- seek_rsta: read sta(ds) ----------- imem_addr := imem_sta(imf_typ) & r.csds; -- get sta(ds) n.seekdt := MEM_DOUT(sta_ibf_dt); imem_din := MEM_DOUT; if MEM_DOUT(sta_ibf_st) /= st_lock then -- drive off imem_we0 := '1'; -- update sta imem_we1 := '1'; imem_din(sta_ibf_sto) := '1'; -- set STO (seek time out) n.cse := e_incomp; n.ireq := r.csie; -- interrupt n.state := s_idle; else -- drive on ibhold := r.ibsel; n.state := s_seek_rpos; end if; when s_seek_rpos => -- seek_rpos: read pos(ds) ----------- imem_addr := imem_pos(imf_typ) & r.csds; -- get pos(ds) if r.da(rlda_ibf_seek_dir) = '1' then n.seekcan := slv(unsigned('0' & MEM_DOUT(pos_ibf_ca)) + unsigned('0' & r.da(rlda_ibf_seek_df)) ); else n.seekcan := slv(unsigned('0' & MEM_DOUT(pos_ibf_ca)) - unsigned('0' & r.da(rlda_ibf_seek_df)) ); end if; ibhold := r.ibsel; n.state := s_seek_clip; when s_seek_clip => -- seek_clip: clip new ca ------------ n.seekcac := r.seekcan(8 downto 0); -- new ca overflowed ? for RL02 (9) and for RL01 (9:8) must be "00" if r.seekcan(9) = '1' or (r.seekdt = '0' and r.seekcan(8) = '1') then if r.da(rlda_ibf_seek_dir) = '1' then -- outward seek if r.seekdt = '1' then -- is RL02 n.seekcac := ca_max_rl02; -- clip to RL02 max ca else -- is RL01 n.seekcac := ca_max_rl01; -- clip to RL01 max ca end if; else -- inward seek n.seekcac := "000000000"; -- clip to 0 end if; end if; ibhold := r.ibsel; n.state := s_seek_wpos; when s_seek_wpos => -- seek_wpos: write pos(ds) ---------- imem_addr := imem_pos(imf_typ) & r.csds; -- get pos(ds) imem_we0 := '1'; imem_we1 := '1'; imem_din := MEM_DOUT; imem_din(pos_ibf_ca) := r.seekcac; imem_din(pos_ibf_hs) := r.da(rlda_ibf_seek_hs); n.ireq := r.csie; -- interrupt n.state := s_idle; when s_init => -- init: handle init ----------------- ibhold := r.ibsel; -- hold ibus when controller busy imem_addr := r.iaddr; imem_din := (others=>'0'); imem_we0 := '1'; imem_we1 := '1'; if r.iaddr(imf_typ) = imem_sta(imf_typ) then -- if sta(x) imem_din := MEM_DOUT; -- keep state imem_din(sta_ibf_wde) := '0'; -- and clear err imem_din(sta_ibf_che) := '0'; imem_din(sta_ibf_sto) := '0'; imem_din(sta_ibf_spe) := '0'; imem_din(sta_ibf_wge) := '0'; imem_din(sta_ibf_vce) := '0'; imem_din(sta_ibf_dse) := '0'; end if; n.iaddr := slv(unsigned(r.iaddr) + 1); if unsigned(r.iaddr) = unsigned(imem_sta)+3 then -- stop after sta(3) n.state := s_idle; end if; when others => null; end case; iei_req := r.ireq; -- ??? simplify, use r.ireq directly if EI_ACK = '1' or r.csie = '0' then -- interrupt executed or ie disabled n.ireq := '0'; -- cancel request end if; N_REGS <= n; MEM_0_WE <= imem_we0; MEM_1_WE <= imem_we1; MEM_ADDR <= imem_addr; MEM_DIN <= imem_din; IB_SRES.dout <= idout; IB_SRES.ack <= r.ibsel and ibreq; IB_SRES.busy <= ibhold and ibreq; RB_LAM <= ilam; EI_REQ <= iei_req; end process proc_next; end syn;
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