URL
https://opencores.org/ocsvn/w11/w11/trunk
Subversion Repositories w11
[/] [w11/] [tags/] [w11a_V0.74/] [rtl/] [vlib/] [rlink/] [rlink_core.vhd] - Rev 2
Go to most recent revision | Compare with Previous | Blame | View Log
-- $Id: rri_core.vhd 314 2010-07-09 17:38:41Z mueller $ -- -- Copyright 2007-2010 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: rri_core - syn -- Description: rri: core interface -- -- Dependencies: comlib/crc8 -- -- Test bench: tb/tb_rri_core -- tb/tb_rritba_ttcombo -- tb/tb_rriext_ttcombo -- -- Target Devices: generic -- Tool versions: xst 8.1, 8.2, 9.1, 9.2, 11.4; ghdl 0.18-0.26 -- -- Synthesized (xst): -- Date Rev ise Target flop lutl lutm slic t peri -- 2010-06-06 302 11.4 L68 xc3s1000-4 151 323 0 197 s 8.9 -- 2010-04-03 274 11.4 L68 xc3s1000-4 148 313 0 190 s 8.0 -- 2009-07-11 232 10.1.03 K39 xc3s1000-4 147 321 0 197 s 8.3 -- -- Revision History: -- Date Rev Version Comment -- 2010-06-20 308 2.6 use rbinit,rbreq,rbwe state flops to drive rb_mreq; -- now nak on reserved cmd 111; use do_comma_abort(); -- 2010-06-18 306 2.5.1 rename rbus data fields to _rbf_ -- 2010-06-06 302 2.5 use sop/eop framing instead of soc+chaining -- 2010-06-03 299 2.1.2 drop unneeded unsigned casts; change init encoding -- 2010-05-02 287 2.1.1 ren CE_XSEC->CE_INT,RP_STAT->RB_STAT,AP_LAM->RB_LAM -- drop RP_IINT signal from interfaces -- 2010-04-03 274 2.1 add CP_FLUSH output -- 2009-07-12 233 2.0.1 remove snoopers -- 2008-08-24 162 2.0 with new rb_mreq/rb_sres interface -- 2008-03-02 121 1.1.1 comment out snoopers -- 2007-11-24 98 1.1 new internal init handling (addr=11111111) -- 2007-10-12 88 1.0.1 avoid ieee.std_logic_unsigned, use cast to unsigned -- 2007-09-15 82 1.0 Initial version, fully functional -- 2007-06-17 58 0.5 First preliminary version ------------------------------------------------------------------------------ -- -- Overall protocol: -- _idle : expect -- sop -> _txsop (echo sop, , to _txsop, _rxcmd) -- eop -> _txeop (send nak,eop , to _txnak, _txeop, _idle) -- nak -> _txnak (silently ignore nak) -- attn -> _txito (send ito , to _idle) -- data -> _idle (silently ignore data) -- _error: expect -- sop -> _txnak (send nak , to _txnak, _error) -- eop -> _txeop (echo eop , to _txeop, _idle) -- nak -> _txnak (echo nak , to _txnak, _error) -- attn -> _txito (silently ignore attn) -- data -> _idle (silently ignore data) -- _rxcmd: expect -- sop -> _txnak (send nak , to _txnak, _error) -- eop -> _txeop (echo eop , to _txeop, _idle) -- nak -> _txnak (echo nak , to _txnak, _error) -- attn -> _txito (silently ignore attn) -- data -> _idle (decode command) -- _rx...: expect -- sop -> _txnak (send nak , to _txnak, _error) -- eop -> _txnak (send nak,eop , to _txnak, _txeop, _idle) -- nak -> _txnak (echo nak , to _txnak, _error) -- attn -> _txito (silently ignore attn) -- data -> _idle (decode data) -- -- 7 supported commands: -- -- 000 read reg (rreg): -- rx: cmd addr ccrc -- tx: cmd dl dh stat crc -- seq: _rxcmd _rxaddr _rxccrc (_txcmd|_txnak) -- _rreg _txdatl _txdath _txstat _txcrc (_rxcmd|_idle) -- -- 001 read blk (rblk): -- rx: cmd addr cnt ccrc -- tx: cmd cnt dl dh ... stat crc -- seq: _rxcmd _rxaddr _rxcnt _rxccrc (_txcmd|_txnak) _txcnt -- {_rreg _txdatl _txdath _blk}* _txstat _txcrc (_rxcmd|_idle) -- -- 010 write reg (wreg): -- rx: cmd addr dl dh ccrc -- tx: cmd stat crc -- seq: _rxcmd _rxaddr _rxdatl _rxdath _rxccrc (_txcmd|_txnak) -- seq: _wreg _txstat _txcrc (_rxcmd|_idle) -- -- 011 write blk (wblk): -- rx: cmd addr cnt ccrc dl dh ... dcrc -- tx: cmd stat crc -- seq: _rxcmd _rxaddr _rxcnt _rxccrc (_txcmd|_txnak) -- {_rxdatl _rxdath _wreg _blk}* _rxdcrc _txstat _txcrc (_rxcmd|_idle) -- -- 100 read stat (stat): -- rx: cmd ccrc -- tx: cmd ccmd dl dh stat crc -- seq: _rxcmd _rxccrc (_txcmd|_txnak) -- _txccmd _txdatl _txdath _txstat _txcrc (_rxcmd|_idle) -- -- 101 read attn (attn): -- rx: cmd ccrc -- tx: cmd dl dh stat crc -- seq: _rxcmd _rxccrc (_txcmd|_txnak) -- _attn _txdatl _txdath _txstat _txcrc (_rxcmd|_idle) -- -- 110 write init (init): -- rx: cmd addr dl dh ccrc -- tx: cmd stat crc -- seq: _rxcmd _rxaddr _rxdatl _rxdath _rxccrc (_txcmd|_txnak) -- seq: _txstat _txcrc (_rxcmd|_idle) -- like wreg, but no rp_we - rp_hold, just a 1 cycle rp_init pulse -- -- 111 is currently not a legal command and causes a nak -- seq: _txnak -- -- The different rbus cycle types are encoded as: -- -- init ack we -- 0 0 0 idle -- 0 0 1 idle -- 0 1 0 read -- 0 1 1 write -- 1 0 0 internal init -- 1 0 1 external init -- 1 1 0 not allowed -- 1 1 1 not allowed -- library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_arith.all; use work.slvtypes.all; use work.comlib.all; use work.rrilib.all; entity rri_core is -- rri, core interface generic ( ATOWIDTH : positive := 5; -- access timeout counter width ITOWIDTH : positive := 6); -- idle timeout counter width port ( CLK : in slbit; -- clock CE_INT : in slbit := '0'; -- rri ito time unit clock enable RESET : in slbit; -- reset CP_DI : in slv9; -- comm port: data in CP_ENA : in slbit; -- comm port: data enable CP_BUSY : out slbit; -- comm port: data busy CP_DO : out slv9; -- comm port: data out CP_VAL : out slbit; -- comm port: data valid CP_HOLD : in slbit; -- comm port: data hold CP_FLUSH : out slbit; -- comm port: data flush RB_MREQ : out rb_mreq_type; -- rbus: request RB_SRES : in rb_sres_type; -- rbus: response RB_LAM : in slv16; -- rbus: look at me RB_STAT : in slv3 -- rbus: status flags ); end entity rri_core; architecture syn of rri_core is type state_type is ( s_idle, -- s_idle: wait for sop s_txito, -- s_txito: send timeout symbol s_txsop, -- s_txsop: send sop s_txnak, -- s_txnak: send nak s_txeop, -- s_txeop: send eop s_error, -- s_error: wait for eop s_rxcmd, -- s_rxcmd: wait for cmd s_rxaddr, -- s_rxaddr: wait for addr s_rxdatl, -- s_rxdatl: wait for data low s_rxdath, -- s_rxdath: wait for data high s_rxcnt, -- s_rxcnt: wait for count s_rxccrc, -- s_rxccrc: wait for command crc s_txcmd, -- s_txcmd: send cmd s_txcnt, -- s_txcnt: send cnt s_rreg, -- s_rreg: reg or blk read s_txdatl, -- s_txdatl: send data low s_txdath, -- s_txdath: send data high s_wreg, -- s_wreg: reg or blk write s_blk, -- s_blk: block count handling s_rxdcrc, -- s_rxdcrc: wait for data crc s_attn, -- s_attn: handle attention flags s_txccmd, -- s_txccmd: send last command s_txstat, -- s_txstat: send status s_txcrc -- s_txcrc: send crc ); type regs_type is record state : state_type; -- state rcmd : slv8; -- received command ccmd : slv8; -- current command addr : slv8; -- register address dil : slv8; -- input data, lsb dih : slv8; -- input data, msb dol : slv8; -- output data, lsb doh : slv8; -- output data, msb cnt : slv8; -- block transfer count attn : slv16; -- attn mask atocnt : slv(ATOWIDTH-1 downto 0); -- access timeout counter itocnt : slv(ITOWIDTH-1 downto 0); -- idle timeout counter itoval : slv(ITOWIDTH-1 downto 0); -- idle timeout value itoena : slbit; -- idle timeout enable flag anena : slbit; -- attn notification enable flag andone : slbit; -- attn notification done ccrc : slbit; -- stat: command crc error dcrc : slbit; -- stat: data crc error ioto : slbit; -- stat: i/o time out ioerr : slbit; -- stat: i/o time error nakeop : slbit; -- send eop after nak rbinit : slbit; -- rbus init signal rbreq : slbit; -- rbus req signal rbwe : slbit; -- rbus we signal flush : slbit; -- flush pulse stat : slv3; -- external status flags end record regs_type; constant atocnt_init : slv(ATOWIDTH-1 downto 0) := (others=>'1'); constant itocnt_init : slv(ITOWIDTH-1 downto 0) := (others=>'0'); constant c_idle : slv4 := "0000"; constant c_sop : slv4 := "0001"; constant c_eop : slv4 := "0010"; constant c_nak : slv4 := "0011"; constant c_attn : slv4 := "0100"; constant regs_init : regs_type := ( s_idle, -- (others=>'0'), -- rcmd (others=>'0'), -- ccmd (others=>'0'), -- addr (others=>'0'), -- dil (others=>'0'), -- dih (others=>'0'), -- dol (others=>'0'), -- doh (others=>'0'), -- cnt (others=>'0'), -- attn atocnt_init, -- atocnt itocnt_init, -- itocnt itocnt_init, -- itoval '0', -- itoena '0','0', -- anena, andone '0','0','0','0', -- stat flags '0', -- nakeop '0','0','0', -- rbinit,rbreq,rbwe '0', -- flush (others=>'0') -- stat ); signal R_REGS : regs_type := regs_init; -- state registers signal N_REGS : regs_type := regs_init; -- next value state regs signal CRC_RESET : slbit := '0'; signal ICRC_ENA : slbit := '0'; signal OCRC_ENA : slbit := '0'; signal ICRC_OUT : slv8 := (others=>'0'); signal OCRC_OUT : slv8 := (others=>'0'); signal OCRC_IN : slv8 := (others=>'0'); begin assert ITOWIDTH<=8 report "assert(ITOWIDTH<=8): max byte size ITO counter supported" severity failure; ICRC : crc8 -- crc generator for input data port map ( CLK => CLK, RESET => CRC_RESET, ENA => ICRC_ENA, DI => CP_DI(7 downto 0), CRC => ICRC_OUT ); OCRC : crc8 -- crc generator for output data port map ( CLK => CLK, RESET => CRC_RESET, ENA => OCRC_ENA, DI => OCRC_IN, CRC => OCRC_OUT ); proc_regs: process (CLK) begin if CLK'event and CLK='1' then if RESET = '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_INT, CP_DI, CP_ENA, CP_HOLD, RB_LAM, RB_SRES, RB_STAT, ICRC_OUT, OCRC_OUT) variable r : regs_type := regs_init; variable n : regs_type := regs_init; variable ival : slbit := '0'; variable ibusy : slbit := '0'; variable ido : slv9 := (others=>'0'); variable ato_go : slbit := '0'; variable ato_end : slbit := '0'; variable ito_go : slbit := '0'; variable ito_end : slbit := '0'; variable crcreset : slbit := '0'; variable icrcena : slbit := '0'; variable ocrcena : slbit := '0'; variable has_attn : slbit := '0'; variable idi8 : slv8 := (others=>'0'); variable is_comma : slbit := '0'; variable comma_typ : slv4 := "0000"; procedure do_comma_abort(nstate : inout state_type; nnakeop : inout slbit; comma_typ : in slv4) is begin if comma_typ=c_sop or comma_typ=c_eop or comma_typ=c_nak then if comma_typ = c_eop then nnakeop := '1'; end if; nstate := s_txnak; -- next: send nak end if; end procedure do_comma_abort; begin r := R_REGS; n := R_REGS; idi8 := CP_DI(7 downto 0); -- get data part of CP_DI is_comma := CP_DI(8); -- get comma marker comma_typ := CP_DI(3 downto 0); -- get comma type n.rbinit := '0'; -- clear rbinit,rbreq,rbwe by default n.rbreq := '0'; -- they must always be set by the n.rbwe := '0'; -- 'previous state' n.flush := '0'; -- dito for flush ibusy := '1'; -- default is to hold input ival := '0'; ido := (others=>'0'); crcreset := '0'; icrcena := '0'; ocrcena := '0'; for i in RB_LAM'range loop -- handle attention "LAM's" if RB_LAM(i) = '1' then -- if LAM bit set n.attn(i) := '1'; -- set attention bit end if; end loop; has_attn := '0'; if unsigned(r.attn) /= 0 then -- is any of the attn bits set ? has_attn := '1'; end if; ato_go := '0'; -- default: keep access timeout in reset ato_end := '0'; if unsigned(r.atocnt) = 0 then -- if access timeout count at zero ato_end := '1'; -- signal expiration end if; ito_go := '0'; -- default: keep idle timeout in reset ito_end := '0'; if unsigned(r.itocnt) = 0 then -- if idle timeout count at zero ito_end := '1'; -- signal expiration end if; case r.state is when s_idle => -- s_idle: wait for sop -------------- ito_go := '1'; -- idle timeout active if (r.anena='1' and -- if attn notification to send has_attn='1' and r.andone='0') then n.state := s_txito; -- next send ito byte else ibusy := '0'; -- accept input if CP_ENA = '1' then -- if input if is_comma = '1' then -- if comma case comma_typ is when c_sop => -- if sop crcreset := '1'; -- reset crc generators n.state := s_txsop; -- next: echo it when c_eop => -- if eop (unexpected) n.nakeop := '1'; -- send nak,eop n.state := s_txnak; -- next: send nak when c_attn => -- if attn n.state := s_txito; -- next: send ito byte when others => null; -- other commas: silently ignore end case; else -- if normal data n.state := s_idle; -- silently dropped end if; elsif (r.itoena='1' and -- if ito enable, expired and XSEC ito_end='1' and CE_INT='1') then n.state := s_txito; -- next: send ito byte end if; end if; when s_txito => -- s_txito: send timeout symbol ------ if has_attn = '1' then ido := c_rri_dat_attn; -- if attn pending: send attn symbol n.andone := '1'; else ido := c_rri_dat_idle; -- otherwise: send idle symbol end if; ival := '1'; if CP_HOLD = '0' then -- wait for accept n.state := s_idle; -- next: wait for sop end if; when s_txsop => -- s_txsop: send sop ----------------- ido := c_rri_dat_sop; -- send sop character ival := '1'; if CP_HOLD = '0' then -- wait for accept n.state := s_rxcmd; -- next: read first command end if; when s_txnak => -- s_txnak: send nak ----------------- ido := c_rri_dat_nak; -- send nak character ival := '1'; if CP_HOLD = '0' then -- wait for accept n.nakeop := '0'; if r.nakeop = '1' then -- if eop after nak requested n.state := s_txeop; -- next: send eop else n.state := s_error; -- next: error state, wait for eop end if; end if; when s_txeop => -- s_txeop: send eop ----------------- ido := c_rri_dat_eop; -- send eop character ival := '1'; if CP_HOLD = '0' then -- wait for accept n.flush := '1'; -- send flush pulse n.state := s_idle; -- next: idle state, wait for sop end if; when s_error => -- s_error: wait for eop ------------- ibusy := '0'; -- accept input if CP_ENA = '1' then if is_comma = '1' then -- if comma case comma_typ is when c_sop => -- if sop (unexpected) n.state := s_txnak; -- next: send nak when c_eop => -- if eop n.state := s_txeop; -- next: echo eop when c_nak => -- if nak n.state := s_txnak; -- next: echo nak when others => null; -- other commas: silently ignore end case; else -- if normal data n.state := s_error; -- silently dropped end if; end if; when s_rxcmd => -- s_rxcmd: wait for cmd ------------- ibusy := '0'; -- accept input if CP_ENA = '1' then if is_comma = '1' then -- if comma case comma_typ is when c_sop => -- if sop (unexpected) n.state := s_txnak; -- next: send nak when c_eop => -- if eop n.state := s_txeop; -- next: echo eop when c_nak => -- if nak n.state := s_txnak; -- next: echo nak when others => null; --other commas: silently ignore end case; else icrcena := '1'; -- update input crc n.rcmd := idi8; -- latch read command code case CP_DI(c_rri_cmd_rbf_code) is when c_rri_cmd_rreg | c_rri_cmd_rblk | c_rri_cmd_wreg | c_rri_cmd_wblk | c_rri_cmd_init => -- for commands needing addr(data) n.state := s_rxaddr; -- next: read address when c_rri_cmd_stat | c_rri_cmd_attn => -- stat and attn commands n.state := s_rxccrc; -- next: read command crc when others => n.state := s_idle; -- if bad command abort here end case; -- rcmd,ccmd always hold good cmd end if; end if; when s_rxaddr => -- s_rxaddr: wait for addr ----------- ibusy := '0'; -- accept input if CP_ENA = '1' then if is_comma = '1' then -- if comma do_comma_abort(n.state, n.nakeop, comma_typ); else icrcena := '1'; -- update input crc n.addr := idi8; -- latch read address case r.rcmd(c_rri_cmd_rbf_code) is when c_rri_cmd_rreg => -- for rreg command n.state := s_rxccrc; -- next: read command crc when c_rri_cmd_wreg | c_rri_cmd_init => -- for wreg, init command n.state := s_rxdatl; -- next: read data lsb when others => -- for rblk or wblk n.state := s_rxcnt; -- next: read count end case; end if; end if; when s_rxdatl => -- s_rxdatl: wait for data low ------- ibusy := '0'; -- accept input if CP_ENA = '1' then if is_comma = '1' then -- if comma do_comma_abort(n.state, n.nakeop, comma_typ); else icrcena := '1'; -- update input crc n.dil := idi8; -- latch data lsb part n.state := s_rxdath; -- next: read data msb end if; end if; when s_rxdath => -- s_rxdath: wait for data high ------ ibusy := '0'; -- accept input if CP_ENA = '1' then if is_comma = '1' then -- if comma do_comma_abort(n.state, n.nakeop, comma_typ); else icrcena := '1'; -- update input crc n.dih := idi8; -- latch data msb part if r.rcmd(c_rri_cmd_rbf_code) = c_rri_cmd_wblk then -- if wblk n.rbreq := '1'; n.rbwe := '1'; n.state := s_wreg; -- next: write reg else -- otherwise n.state := s_rxccrc; -- next: read command crc end if; end if; end if; when s_rxcnt => -- s_rxcnt: wait for count ----------- ibusy := '0'; -- accept input if CP_ENA = '1' then if is_comma = '1' then -- if comma do_comma_abort(n.state, n.nakeop, comma_typ); else icrcena := '1'; -- update input crc n.cnt := idi8; -- latch count n.state := s_rxccrc; -- next: read command crc end if; end if; when s_rxccrc => -- s_rxccrc: wait for command crc ---- ibusy := '0'; -- accept input if CP_ENA = '1' then if is_comma = '1' then -- if comma do_comma_abort(n.state, n.nakeop, comma_typ); else if idi8 /= ICRC_OUT then -- if crc error n.ccrc := '1'; -- set command crc error flag n.state := s_txnak; -- next: send nak else -- if crc ok n.state := s_txcmd; -- next: echo command end if; end if; end if; when s_txcmd => -- s_txcmd: send cmd ----------------- ido := '0' & r.rcmd; -- send read command ival := '1'; if CP_HOLD = '0' then -- wait for accept ocrcena := '1'; -- update output crc if r.rcmd(c_rri_cmd_rbf_code) /= c_rri_cmd_stat then -- unless stat n.ccmd := r.rcmd; -- latch read command in ccmd n.stat := RB_STAT; -- latch external status bits n.ccrc := '0'; n.dcrc := '0'; n.ioto := '0'; n.ioerr := '0'; end if; case r.rcmd(c_rri_cmd_rbf_code) is -- main command dispatcher when c_rri_cmd_rreg => -- rreg ---------------- n.rbreq := '1'; n.state := s_rreg; when c_rri_cmd_rblk => -- rblk ---------------- n.state := s_txcnt; when c_rri_cmd_wreg => -- wreg ---------------- n.rbreq := '1'; n.rbwe := '1'; n.state := s_wreg; when c_rri_cmd_wblk => -- wblk ---------------- n.state := s_rxdatl; when c_rri_cmd_stat => -- stat ---------------- n.state := s_txccmd; when c_rri_cmd_attn => -- attn ---------------- n.state := s_attn; when c_rri_cmd_init => -- init ---------------- n.rbinit := '1'; -- send init pulse if r.addr(7 downto 3) = "11111" then -- is internal init if r.addr(2 downto 0) = "111" then -- is rri init n.anena := r.dih(c_rri_iint_rbf_anena - 8); n.itoena := r.dih(c_rri_iint_rbf_itoena - 8); n.itoval := r.dil(ITOWIDTH-1 downto 0); -- note: itocnt will load in next -- cycle because ito_go=0, so no -- action required here end if; else -- is external init n.rbwe := '1'; -- send init with we end if; n.state := s_txstat; when others => -- '111' --------------- n.state := s_txnak; -- send NAK on reserved command end case; end if; when s_txcnt => -- s_txcnt: send cnt ----------------- ido := '0' & r.cnt; -- send cnt ival := '1'; if CP_HOLD = '0' then -- wait for accept ocrcena := '1'; -- update output crc n.rbreq := '1'; n.state := s_rreg; -- next: first read reg end if; when s_rreg => -- s_rreg: reg or blk read ----------- -- this state handles all rbus reads. Expects that previous state -- sets n.rbreq := '1' to start an rbus read cycle ato_go := '1'; -- activate timeout counter if RB_SRES.err = '1' then -- latch error flag n.ioerr := '1'; end if; n.doh := RB_SRES.dout(15 downto 8); -- latch data n.dol := RB_SRES.dout( 7 downto 0); n.stat := RB_STAT; -- latch external status bits if RB_SRES.busy='0' or ato_end='1' then -- wait for non-busy or timeout if RB_SRES.busy='1' and ato_end='1' then -- if timeout and still busy n.ioto := '1'; -- set timeout flag elsif RB_SRES.ack = '0' then -- if non-busy and no ack n.ioto := '1'; -- set timeout flag end if; n.state := s_txdatl; -- next: send data lsb else -- otherwise rbus read continues n.rbreq := '1'; -- extend req end if; when s_txdatl => -- s_txdatl: send data low ----------- ido := '0' & r.dol; -- send data ival := '1'; if CP_HOLD = '0' then -- wait for accept ocrcena := '1'; -- update output crc n.state := s_txdath; -- next: send data msb end if; when s_txdath => -- s_txdath: send data high ido := '0' & r.doh; -- send data ival := '1'; if CP_HOLD = '0' then -- wait for accept ocrcena := '1'; -- update output crc if r.rcmd(c_rri_cmd_rbf_code) = c_rri_cmd_rblk then -- if rblk n.state := s_blk; -- next: block count handling else -- otherwise n.state := s_txstat; -- next: send stat end if; end if; when s_wreg => -- s_wreg: reg or blk write ---------- -- this state handles all rbus writes. Expects that previous state -- sets n.rbreq := '1' and n.rbwe := '1' to start an rbus write cycle ato_go := '1'; -- activate timeout counter if RB_SRES.err = '1' then -- latch error flag n.ioerr := '1'; end if; n.stat := RB_STAT; -- latch external status bits if RB_SRES.busy='0' or ato_end='1' then -- wait for non-busy or timeout if RB_SRES.busy='1' and ato_end='1' then -- if timeout and still busy n.ioto := '1'; -- set timeout flag elsif RB_SRES.ack='0' then -- if non-busy and no ack n.ioto := '1'; -- set timeout flag end if; if r.rcmd(c_rri_cmd_rbf_code) = c_rri_cmd_wblk then -- if wblk n.state := s_blk; -- next: block count handling else -- otherwise n.state := s_txstat; -- next: send stat end if; else -- otherwise rbus write continues n.rbreq := '1'; -- extend req n.rbwe := '1'; -- extend we end if; when s_blk => -- s_blk: block count handling ------- n.cnt := unsigned(r.cnt) - 1; -- decrement transfer count if unsigned(r.cnt) = 0 then -- if last transfer if r.rcmd(c_rri_cmd_rbf_code) = c_rri_cmd_rblk then -- if rblk n.state := s_txstat; -- next: send stat else -- otherwise n.state := s_rxdcrc; -- next: read data crc end if; else -- otherwise more to transfer if r.rcmd(c_rri_cmd_rbf_code) = c_rri_cmd_rblk then -- if rblk n.rbreq := '1'; n.state := s_rreg; -- next: read blk else -- otherwise n.state := s_rxdatl; -- next: read data end if; end if; when s_rxdcrc => -- s_rxdcrc: wait for data crc ------- ibusy := '0'; -- accept input if CP_ENA = '1' then if is_comma = '1' then -- if comma do_comma_abort(n.state, n.nakeop, comma_typ); else if idi8 /= ICRC_OUT then -- if crc error n.dcrc := '1'; -- set data crc error flag end if; n.state := s_txstat; -- next: echo command end if; end if; when s_attn => -- s_attn: handle attention flags ---- n.dol := r.attn(7 downto 0); -- move attention flags to do buffer n.doh := r.attn(15 downto 8); n.attn := RB_LAM; -- LAM in current cycle send next time n.andone := '0'; -- reenable attn nofification n.state := s_txdatl; -- next: send data lsb when s_txccmd => -- s_txccmd: send last command ido := '0' & r.ccmd; -- send last accepted command ival := '1'; if CP_HOLD = '0' then -- wait for accept ocrcena := '1'; -- update output crc n.state := s_txdatl; -- next: send last data lsb end if; when s_txstat => -- s_txstat: send status ------------- ido := (others=>'0'); ido(c_rri_stat_rbf_stat) := r.stat; ido(c_rri_stat_rbf_attn) := has_attn; ido(c_rri_stat_rbf_ccrc) := r.ccrc; ido(c_rri_stat_rbf_dcrc) := r.dcrc; ido(c_rri_stat_rbf_ioto) := r.ioto; ido(c_rri_stat_rbf_ioerr) := r.ioerr; ival := '1'; if CP_HOLD ='0' then -- wait for accept ocrcena := '1'; -- update output crc n.state := s_txcrc; -- next: send crc end if; when s_txcrc => -- s_txcrc: send crc ----------------- ido := "0" & OCRC_OUT; -- send crc code ival := '1'; if CP_HOLD = '0' then -- wait for accept n.state := s_rxcmd; -- next: read command or eop end if; when others => null; -- <> -------------------------------- end case; if ato_go = '0' then -- handle access timeout counter n.atocnt := atocnt_init; -- if ato_go=0, keep in reset else n.atocnt := unsigned(r.atocnt) - 1;-- otherwise count down end if; if ito_go = '0' then -- handle idle timeout counter n.itocnt := r.itoval; -- if ito_go=0, keep at start value else if CE_INT = '1' then n.itocnt := unsigned(r.itocnt) - 1;-- otherwise count down every CE_INT end if; end if; N_REGS <= n; CP_BUSY <= ibusy; CP_DO <= ido; CP_VAL <= ival; CP_FLUSH <= r.flush; RB_MREQ <= rb_mreq_init; RB_MREQ.req <= r.rbreq; RB_MREQ.we <= r.rbwe; RB_MREQ.init <= r.rbinit; RB_MREQ.addr <= r.addr; RB_MREQ.din <= r.dih & r.dil; CRC_RESET <= crcreset; ICRC_ENA <= icrcena; OCRC_ENA <= ocrcena; OCRC_IN <= ido(7 downto 0); end process proc_next; end syn;
Go to most recent revision | Compare with Previous | Blame | View Log