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--===========================================================================--
--
--  S Y N T H E Z I A B L E    ACIA 6850   C O R E
--
--  www.OpenCores.Org - January 2007
--  This core adheres to the GNU public license  
--
-- Design units   : 6850 ACIA core for the System68/09
--
-- File name      : ACIA_RX.vhd
--
-- Purpose        : Implements a 6850 ACIA device for communication purposes 
--                  between the cpu68/09 cpu and the Host computer through
--                  an RS-232 communication protocol.
--                  
-- Dependencies   : ieee.std_logic_1164.all;
--                  ieee.numeric_std.all;
--                  ieee.std_logic_unsigned.all;
--                  unisim.vcomponents.all;
--
--===========================================================================--
-------------------------------------------------------------------------------
-- Revision list
-- Version   Author                 Date                        Changes
--
-- 0.1      Ovidiu Lupas     15 January 2000                   New model
-- 2.0      Ovidiu Lupas     17 April   2000  samples counter cleared for bit 0
--        olupas@opencores.org
--
-- 3.0      John Kent         5 January 2003  Added 6850 word format control
-- 3.1      John Kent        12 January 2003  Significantly revamped receive code.
-- 3.2      John Kent        10 January 2004  Rewrite of code.
-- 4.0      John Kent        3 February 2007  Renamed to ACIA 6850
--                                            Removed input debounce
-- 4.1      John Kent         4 February 2007 Cleaned up Rx state machine
--      4.2      John Kent        25 February 2007 Modified sensitivity lists
--
--        dilbert57@opencores.org
-------------------------------------------------------------------------------
--
-- Description    : Implements the receive unit of the ACIA_6850 core.
--                  Samples 16 times the RxD line and retain the value
--                  in the middle of the time interval. 
--
library ieee;
   use ieee.std_logic_1164.all;
   use ieee.numeric_std.all;
   use ieee.std_logic_unsigned.all;
--library unisim;
--      use unisim.vcomponents.all;
 
-------------------------------------------------------------------------------
-- Entity for the ACIA Receiver
-------------------------------------------------------------------------------
entity ACIA_RX is
  port (
     Clk    : in  Std_Logic;                    -- Clock signal
     RxRst  : in  Std_Logic;                    -- Reset input
     RxRd   : in  Std_Logic;                    -- Read data strobe
     WdFmt  : in  Std_Logic_Vector(2 downto 0); -- word format
     BdFmt  : in  Std_Logic_Vector(1 downto 0); -- baud format
     RxClk  : in  Std_Logic;                    -- RS-232 clock input
     RxDat  : in  Std_Logic;                    -- RS-232 data input
     RxFErr : out Std_Logic;                    -- Framing Error status
     RxOErr : out Std_Logic;                    -- Over Run Error Status
          RxPErr : out Std_logic;                    -- Parity Error Status
     RxRdy  : out Std_Logic;                    -- Data Ready Status
     RxDout : out Std_Logic_Vector(7 downto 0)
          );
end ACIA_RX; --================== End of entity ==============================--
 
-------------------------------------------------------------------------------
-- Architecture for ACIA receiver
-------------------------------------------------------------------------------
 
architecture rtl of ACIA_RX is
 
  type RxStateType is ( RxStart_State, RxData_state,
                                                                RxParity_state, RxStop_state );
 
  -----------------------------------------------------------------------------
  -- Signals
  -----------------------------------------------------------------------------
  signal RxDatDel0  : Std_Logic := '0';             -- Delayed Rx Data
  signal RxDatDel1  : Std_Logic := '0';             -- Delayed Rx Data
  signal RxDatDel2  : Std_Logic := '0';             -- Delayed Rx Data
  signal RxDatEdge  : Std_Logic := '0';             -- Rx Data Edge pulse
  signal RxClkDel   : Std_Logic := '0';             -- Delayed Rx Input Clock
  signal RxClkEdge  : Std_Logic := '0';             -- Rx Input Clock Edge pulse
  signal RxStart    : Std_Logic := '0';             -- Rx Start request
  signal RxEnable   : Std_Logic := '0';             -- Rx Enabled
  signal RxClkCnt   : Std_Logic_Vector(5 downto 0) := (others => '0'); -- Rx Baud Clock Counter
  signal RxBdClk    : Std_Logic := '0';             -- Rx Baud Clock
  signal RxBdDel    : Std_Logic := '0';             -- Delayed Rx Baud Clock
  signal RxBdEdge   : Std_Logic := '0';             -- Rx Baud Clock Edge pulse
 
  signal RxReady    : Std_Logic := '0';             -- Data Ready flag
  signal RxReq      : Std_Logic := '0';             -- Rx Data Valid
  signal RxAck      : Std_Logic := '0';             -- Rx Data Valid
  signal RxParity   : Std_Logic := '0';             -- Calculated RX parity bit
  signal RxState    : RxStateType;           -- receive bit state
  signal RxBitCount : Std_Logic_Vector(2 downto 0) := (others => '0');  -- Rx Bit counter
  signal RxShiftReg : Std_Logic_Vector(7 downto 0) := (others => '0');  -- Shift Register
 
begin
 
  ---------------------------------------------------------------------
  -- Receiver Clock Edge Detection
  ---------------------------------------------------------------------
  -- A rising edge will produce a one clock cycle pulse
  --
--  acia_rx_clock_edge : process( Clk, RxRst, RxClk, RxClkDel )
  acia_rx_clock_edge : process( RxRst, Clk )
  begin
    if RxRst = '1' then
           RxClkDel  <= '0';
                RxClkEdge <= '0';
         elsif Clk'event and Clk = '0' then
           RxClkDel  <= RxClk;
                RxClkEdge <= (not RxClkDel) and RxClk;
         end if;
  end process;
 
  ---------------------------------------------------------------------
  -- Receiver Data Edge Detection
  ---------------------------------------------------------------------
  -- A falling edge will produce a pulse on RxClk wide
  --
--  acia_rx_data_edge : process(Clk, RxRst, RxClkEdge, RxDat, RxDatDel0, RxDatDel1, RxDatDel2 )
  acia_rx_data_edge : process( RxRst, Clk )
  begin
    if RxRst = '1' then
           RxDatDel0 <= '0';
           RxDatDel1 <= '0';
           RxDatDel2 <= '0';
                RxDatEdge <= '0';
         elsif Clk'event and Clk = '0' then
--         if RxClkEdge = '1' then
             RxDatDel0 <= RxDat;
             RxDatDel1 <= RxDatDel0;
             RxDatDel2 <= RxDatDel1;
                  RxDatEdge <= RxDatDel0 and (not RxDat);
--    end if;
         end if;
  end process;
 
  ---------------------------------------------------------------------
  -- Receiver Start / Stop
  ---------------------------------------------------------------------
  -- Enable the receive clock on detection of a start bit
  -- Disable the receive clock after a byte is received.
  -- 
--  acia_rx_start_stop : process( Clk, RxRst, RxDatEdge, RxAck, RxStart, RxEnable )
  acia_rx_start_stop : process( RxRst, Clk )
  begin
    if RxRst = '1' then
        RxEnable <= '0';
                  RxStart  <= '0';
    elsif Clk'event and Clk='0' then
        if (RxEnable = '0') and (RxDatEdge = '1') then
                    -- Data Edge detected 
                         -- Request Start and Enable Receive Clock.
          RxEnable <= '1';
                         RxStart  <= '1';
                  else
                    if (RxStart = '1') and (RxAck = '1') then
                           -- Data is being received
                                -- reset start request
                                RxStart <= '0';
                         else
                           -- Data has now been received
                                -- Disable Receiver until next start bit
                           if (RxStart = '0') and (RxAck = '0') then
                             RxEnable <= '0';
                                end if;
                         end if; -- RxStart
        end if; -- RxDatEdge
    end if; -- clk / RxRst
  end process;
 
  ---------------------------------------------------------------------
  -- Receiver Clock Divider
  ---------------------------------------------------------------------
  -- Hold the Rx Clock divider in reset when the receiver is disabled
  -- Advance the count only on a rising Rx clock edge
  --
--  acia_rx_clock_divide : process( Clk, RxRst, RxEnable, RxClkEdge, RxClkCnt )
  acia_rx_clock_divide : process( RxRst, Clk )
  begin
    if RxRst = '1' then
           RxClkCnt  <= (others => '0');
         elsif Clk'event and Clk = '0' then
--         if RxEnable = '0' then
      if RxDatEdge = '1' then
                    RxClkCnt <= (others => '0');   -- reset on falling data edge
                else
                  if RxClkEdge = '1' then          -- increment count on Clock edge
                    RxClkCnt <= RxClkCnt + "000001";
        end if; -- RxClkEdge
      end if; -- RxState
         end if;         -- clk / RxRst
  end process;
 
  ---------------------------------------------------------------------
  -- Receiver Baud Clock Selector
  ---------------------------------------------------------------------
  -- BdFmt
  -- 0 0     - Baud Clk divide by 1
  -- 0 1     - Baud Clk divide by 16
  -- 1 0     - Baud Clk divide by 64
  -- 1 1     - Reset
  --
  acia_rx_baud_clock_select : process( BdFmt, RxClk, RxClkCnt )
  begin
    case BdFmt is
         when "00" =>     -- Div by 1
           RxBdClk <= RxClk;
         when "01" =>     -- Div by 16
           RxBdClk <= RxClkCnt(3);
         when "10" =>     -- Div by 64
           RxBdClk <= RxClkCnt(5);
         when others =>  -- RxRst
           RxBdClk <= '0';
    end case;
  end process;
 
  ---------------------------------------------------------------------
  -- Receiver Baud Clock Edge Detect
  ---------------------------------------------------------------------
  --
  -- Generate one clock strobe on rising baud clock edge
  --
--  acia_rx_baud_clock_edge : process( Clk, RxRst, RxBdClk, RxBdDel )
  acia_rx_baud_clock_edge : process( RxRst, Clk )
  begin
    if RxRst = '1' then
           RxBdDel  <= '0';
                RxBdEdge <= '0';
         elsif Clk'event and Clk = '0' then
           RxBdDel  <= RxBdClk;
                RxBdEdge <= RxBdClk and (not RxBdDel);
         end if;
  end process;
 
  ---------------------------------------------------------------------
  -- Receiver process
  ---------------------------------------------------------------------
  -- WdFmt - Bits[4..2]
  -- 0 0 0   - 7 data, even parity, 2 stop
  -- 0 0 1   - 7 data, odd  parity, 2 stop
  -- 0 1 0   - 7 data, even parity, 1 stop
  -- 0 1 1   - 7 data, odd  parity, 1 stop
  -- 1 0 0   - 8 data, no   parity, 2 stop
  -- 1 0 1   - 8 data, no   parity, 1 stop
  -- 1 1 0   - 8 data, even parity, 1 stop
  -- 1 1 1   - 8 data, odd  parity, 1 stop
--  acia_rx_receive : process( Clk, RxRst, RxState, RxBdEdge, RxDatDel2, RxBitCount, RxReady, RxShiftReg )
  acia_rx_receive : process( RxRst, Clk )
  begin
    if RxRst = '1' then
        RxFErr     <= '0';
        RxOErr     <= '0';
                  RxPErr     <= '0';
        RxShiftReg <= (others => '0');         -- Resert Shift register
                  RxDOut     <= (others => '0');
                  RxParity   <= '0';                     -- reset Parity bit
                  RxAck      <= '0';                     -- Receiving data
                  RxBitCount <= (others => '0');
        RxState    <= RxStart_state;
    elsif Clk'event and Clk='0' then
        if RxBdEdge = '1' then
          case RxState is
          when RxStart_state =>
            RxShiftReg <= (others => '0');     -- Reset Shift register
                      RxParity   <= '0';                 -- Parity bit
                           if WdFmt(2) = '0' then
                                  -- WdFmt(2) = '0' => 7 data
                        RxBitCount <= "110";
                                else
                                  -- WdFmt(2) = '1' => 8 data                            
                        RxBitCount <= "111";
                                end if;
                           if RxDatDel2 = '0' then            -- look for start request
              RxState <= RxData_state;         -- yes, read data
                           end if;
 
          when RxData_state => -- data bits 0 to 6
            RxShiftReg <= RxDatDel2 & RxShiftReg(7 downto 1);
                           RxParity   <= RxParity xor RxDatDel2;
                                RxAck      <= '1';                                -- Flag receive in progress
            RxBitCount <= RxBitCount - "001";
                                if RxBitCount = "000" then
                             if WdFmt(2) = '0' then           -- WdFmt(2) = '0' => 7 data
                 RxState <= RxParity_state;    -- 7 bits always has parity
                             else                             -- WdFmt(2) = '1' => 8 data                                
                               if WdFmt(1) = '0' then
                  RxState <= RxStop_state;     -- WdFmt(1) = '0' no parity
                                    else
                  RxState <= RxParity_state;   -- WdFmt(1) = '1' parity
                               end if;  -- WdFmt(1)
                                  end if; -- WdFmt(2)
                                end if; -- RxBitCount
 
               when RxParity_state =>               -- parity bit
                           if WdFmt(2) = '0' then             -- 7 data, shift right
              RxShiftReg <= RxDatDel2 & RxShiftReg(7 downto 1); -- 7 data + parity
            end if;
                                if WdFmt(0) = '0' then             -- parity polarity ?
                                  if RxParity = RxDatDel2 then     -- check even parity
                                          RxPErr <= '1';
                                  else
                                          RxPErr <= '0';
                                  end if;
                                else
                                  if RxParity = RxDatDel2 then     -- check for odd parity
                                          RxPErr <= '0';
                                  else
                                          RxPErr <= '1';
                                  end if;
                                end if;
            RxState <= RxStop_state;
 
          when RxStop_state =>                 -- stop bit (Only one required for RX)
                                RxAck  <= '0';                     -- Flag Receive Complete
                                RxDOut <= RxShiftReg;
            if RxDatDel2 = '1' then            -- stop bit expected
              RxFErr <= '0';                   -- yes, no framing error
            else
              RxFErr <= '1';                   -- no, framing error
            end if;
            if RxReady = '1' then              -- Has previous data been read ? 
              RxOErr <= '1';                   -- no, overrun error
            else
              RxOErr <= '0';                   -- yes, no over run error
            end if;
            RxState <= RxStart_state;
 
          when others =>
                                RxAck   <= '0';                     -- Flag Receive Complete
            RxState <= RxStart_state;
          end case; -- RxState
 
        end if; -- RxBdEdge
    end if; -- clk / RxRst
 
  end process;
 
  ---------------------------------------------------------------------
  -- Receiver Read process
  ---------------------------------------------------------------------
--  acia_rx_read : process(Clk, RxRst, RxRd, RxReq, RxAck, RxReady )
  acia_rx_read : process( RxRst, Clk, RxReady )
  begin
    if RxRst = '1' then
        RxReady <= '0';
                  RxReq   <= '0';
    elsif Clk'event and Clk='0' then
        if RxRd = '1' then
                    -- Data was read, Reset data ready
                         -- Request more data
          RxReady <= '0';
                         RxReq   <= '1';
                  else
                    if RxReq = '1' and RxAck = '1' then
                           -- Data is being received
                                -- reset receive request
                                RxReq   <= '0';
                         else
                           -- Data now received
                                -- Flag RxReady and read Shift Register
                           if RxReq = '0' and RxAck = '0' then
                             RxReady <= '1';
                                end if;
                         end if; -- RxReq
        end if; -- RxRd
    end if; -- clk / RxRst
    RxRdy  <= RxReady;
  end process;
 
end rtl; --==================== End of architecture ====================--

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[/] [System09/] [branches/] [mkfiles_rev1/] [rtl/] [VHDL/] [ACIA_RX.vhd] - Blame information for rev 127

Line No.	Rev	Author	Line
1	19	dilbert57	`--===========================================================================--`
2			`--`
3			`-- S Y N T H E Z I A B L E ACIA 6850 C O R E`
4			`--`
5			`-- www.OpenCores.Org - January 2007`
6			`-- This core adheres to the GNU public license`
7			`--`
8			`-- Design units : 6850 ACIA core for the System68/09`
9			`--`
10			`-- File name : ACIA_RX.vhd`
11			`--`
12			`-- Purpose : Implements a 6850 ACIA device for communication purposes`
13			`-- between the cpu68/09 cpu and the Host computer through`
14			`-- an RS-232 communication protocol.`
15			`--`
16			`-- Dependencies : ieee.std_logic_1164.all;`
17			`-- ieee.numeric_std.all;`
18			`-- ieee.std_logic_unsigned.all;`
19			`-- unisim.vcomponents.all;`
20			`--`
21			`--===========================================================================--`
22			`-------------------------------------------------------------------------------`
23			`-- Revision list`
24			`-- Version Author Date Changes`
25			`--`
26			`-- 0.1 Ovidiu Lupas 15 January 2000 New model`
27			`-- 2.0 Ovidiu Lupas 17 April 2000 samples counter cleared for bit 0`
28			`-- olupas@opencores.org`
29			`--`
30			`-- 3.0 John Kent 5 January 2003 Added 6850 word format control`
31			`-- 3.1 John Kent 12 January 2003 Significantly revamped receive code.`
32			`-- 3.2 John Kent 10 January 2004 Rewrite of code.`
33			`-- 4.0 John Kent 3 February 2007 Renamed to ACIA 6850`
34			`-- Removed input debounce`
35			`-- 4.1 John Kent 4 February 2007 Cleaned up Rx state machine`
36			`-- 4.2 John Kent 25 February 2007 Modified sensitivity lists`
37			`--`
38			`-- dilbert57@opencores.org`
39			`-------------------------------------------------------------------------------`
40			`--`
41			`-- Description : Implements the receive unit of the ACIA_6850 core.`
42			`-- Samples 16 times the RxD line and retain the value`
43			`-- in the middle of the time interval.`
44			`--`
45			`library ieee;`
46			`use ieee.std_logic_1164.all;`
47			`use ieee.numeric_std.all;`
48			`use ieee.std_logic_unsigned.all;`
49			`--library unisim;`
50			`-- use unisim.vcomponents.all;`
51
52			`-------------------------------------------------------------------------------`
53			`-- Entity for the ACIA Receiver`
54			`-------------------------------------------------------------------------------`
55			`entity ACIA_RX is`
56			`port (`
57			`Clk : in Std_Logic; -- Clock signal`
58			`RxRst : in Std_Logic; -- Reset input`
59			`RxRd : in Std_Logic; -- Read data strobe`
60			`WdFmt : in Std_Logic_Vector(2 downto 0); -- word format`
61			`BdFmt : in Std_Logic_Vector(1 downto 0); -- baud format`
62			`RxClk : in Std_Logic; -- RS-232 clock input`
63			`RxDat : in Std_Logic; -- RS-232 data input`
64			`RxFErr : out Std_Logic; -- Framing Error status`
65			`RxOErr : out Std_Logic; -- Over Run Error Status`
66			`RxPErr : out Std_logic; -- Parity Error Status`
67			`RxRdy : out Std_Logic; -- Data Ready Status`
68			`RxDout : out Std_Logic_Vector(7 downto 0)`
69			`);`
70			`end ACIA_RX; --================== End of entity ==============================--`
71
72			`-------------------------------------------------------------------------------`
73			`-- Architecture for ACIA receiver`
74			`-------------------------------------------------------------------------------`
75
76			`architecture rtl of ACIA_RX is`
77
78			`type RxStateType is ( RxStart_State, RxData_state,`
79			`RxParity_state, RxStop_state );`
80
81			`-----------------------------------------------------------------------------`
82			`-- Signals`
83			`-----------------------------------------------------------------------------`
84			`signal RxDatDel0 : Std_Logic := '0'; -- Delayed Rx Data`
85			`signal RxDatDel1 : Std_Logic := '0'; -- Delayed Rx Data`
86			`signal RxDatDel2 : Std_Logic := '0'; -- Delayed Rx Data`
87			`signal RxDatEdge : Std_Logic := '0'; -- Rx Data Edge pulse`
88			`signal RxClkDel : Std_Logic := '0'; -- Delayed Rx Input Clock`
89			`signal RxClkEdge : Std_Logic := '0'; -- Rx Input Clock Edge pulse`
90			`signal RxStart : Std_Logic := '0'; -- Rx Start request`
91			`signal RxEnable : Std_Logic := '0'; -- Rx Enabled`
92			`signal RxClkCnt : Std_Logic_Vector(5 downto 0) := (others => '0'); -- Rx Baud Clock Counter`
93			`signal RxBdClk : Std_Logic := '0'; -- Rx Baud Clock`
94			`signal RxBdDel : Std_Logic := '0'; -- Delayed Rx Baud Clock`
95			`signal RxBdEdge : Std_Logic := '0'; -- Rx Baud Clock Edge pulse`
96
97			`signal RxReady : Std_Logic := '0'; -- Data Ready flag`
98			`signal RxReq : Std_Logic := '0'; -- Rx Data Valid`
99			`signal RxAck : Std_Logic := '0'; -- Rx Data Valid`
100			`signal RxParity : Std_Logic := '0'; -- Calculated RX parity bit`
101			`signal RxState : RxStateType; -- receive bit state`
102			`signal RxBitCount : Std_Logic_Vector(2 downto 0) := (others => '0'); -- Rx Bit counter`
103			`signal RxShiftReg : Std_Logic_Vector(7 downto 0) := (others => '0'); -- Shift Register`
104
105			`begin`
106
107			`---------------------------------------------------------------------`
108			`-- Receiver Clock Edge Detection`
109			`---------------------------------------------------------------------`
110			`-- A rising edge will produce a one clock cycle pulse`
111			`--`
112			`-- acia_rx_clock_edge : process( Clk, RxRst, RxClk, RxClkDel )`
113			`acia_rx_clock_edge : process( RxRst, Clk )`
114			`begin`
115			`if RxRst = '1' then`
116			`RxClkDel <= '0';`
117			`RxClkEdge <= '0';`
118			`elsif Clk'event and Clk = '0' then`
119			`RxClkDel <= RxClk;`
120			`RxClkEdge <= (not RxClkDel) and RxClk;`
121			`end if;`
122			`end process;`
123
124			`---------------------------------------------------------------------`
125			`-- Receiver Data Edge Detection`
126			`---------------------------------------------------------------------`
127			`-- A falling edge will produce a pulse on RxClk wide`
128			`--`
129			`-- acia_rx_data_edge : process(Clk, RxRst, RxClkEdge, RxDat, RxDatDel0, RxDatDel1, RxDatDel2 )`
130			`acia_rx_data_edge : process( RxRst, Clk )`
131			`begin`
132			`if RxRst = '1' then`
133			`RxDatDel0 <= '0';`
134			`RxDatDel1 <= '0';`
135			`RxDatDel2 <= '0';`
136			`RxDatEdge <= '0';`
137			`elsif Clk'event and Clk = '0' then`
138			`-- if RxClkEdge = '1' then`
139			`RxDatDel0 <= RxDat;`
140			`RxDatDel1 <= RxDatDel0;`
141			`RxDatDel2 <= RxDatDel1;`
142			`RxDatEdge <= RxDatDel0 and (not RxDat);`
143			`-- end if;`
144			`end if;`
145			`end process;`
146
147			`---------------------------------------------------------------------`
148			`-- Receiver Start / Stop`
149			`---------------------------------------------------------------------`
150			`-- Enable the receive clock on detection of a start bit`
151			`-- Disable the receive clock after a byte is received.`
152			`--`
153			`-- acia_rx_start_stop : process( Clk, RxRst, RxDatEdge, RxAck, RxStart, RxEnable )`
154			`acia_rx_start_stop : process( RxRst, Clk )`
155			`begin`
156			`if RxRst = '1' then`
157			`RxEnable <= '0';`
158			`RxStart <= '0';`
159			`elsif Clk'event and Clk='0' then`
160			`if (RxEnable = '0') and (RxDatEdge = '1') then`
161			`-- Data Edge detected`
162			`-- Request Start and Enable Receive Clock.`
163			`RxEnable <= '1';`
164			`RxStart <= '1';`
165			`else`
166			`if (RxStart = '1') and (RxAck = '1') then`
167			`-- Data is being received`
168			`-- reset start request`
169			`RxStart <= '0';`
170			`else`
171			`-- Data has now been received`
172			`-- Disable Receiver until next start bit`
173			`if (RxStart = '0') and (RxAck = '0') then`
174			`RxEnable <= '0';`
175			`end if;`
176			`end if; -- RxStart`
177			`end if; -- RxDatEdge`
178			`end if; -- clk / RxRst`
179			`end process;`
180
181			`---------------------------------------------------------------------`
182			`-- Receiver Clock Divider`
183			`---------------------------------------------------------------------`
184			`-- Hold the Rx Clock divider in reset when the receiver is disabled`
185			`-- Advance the count only on a rising Rx clock edge`
186			`--`
187			`-- acia_rx_clock_divide : process( Clk, RxRst, RxEnable, RxClkEdge, RxClkCnt )`
188			`acia_rx_clock_divide : process( RxRst, Clk )`
189			`begin`
190			`if RxRst = '1' then`
191			`RxClkCnt <= (others => '0');`
192			`elsif Clk'event and Clk = '0' then`
193			`-- if RxEnable = '0' then`
194			`if RxDatEdge = '1' then`
195			`RxClkCnt <= (others => '0'); -- reset on falling data edge`
196			`else`
197			`if RxClkEdge = '1' then -- increment count on Clock edge`
198			`RxClkCnt <= RxClkCnt + "000001";`
199			`end if; -- RxClkEdge`
200			`end if; -- RxState`
201			`end if; -- clk / RxRst`
202			`end process;`
203
204			`---------------------------------------------------------------------`
205			`-- Receiver Baud Clock Selector`
206			`---------------------------------------------------------------------`
207			`-- BdFmt`
208			`-- 0 0 - Baud Clk divide by 1`
209			`-- 0 1 - Baud Clk divide by 16`
210			`-- 1 0 - Baud Clk divide by 64`
211			`-- 1 1 - Reset`
212			`--`
213			`acia_rx_baud_clock_select : process( BdFmt, RxClk, RxClkCnt )`
214			`begin`
215			`case BdFmt is`
216			`when "00" => -- Div by 1`
217			`RxBdClk <= RxClk;`
218			`when "01" => -- Div by 16`
219			`RxBdClk <= RxClkCnt(3);`
220			`when "10" => -- Div by 64`
221			`RxBdClk <= RxClkCnt(5);`
222			`when others => -- RxRst`
223			`RxBdClk <= '0';`
224			`end case;`
225			`end process;`
226
227			`---------------------------------------------------------------------`
228			`-- Receiver Baud Clock Edge Detect`
229			`---------------------------------------------------------------------`
230			`--`
231			`-- Generate one clock strobe on rising baud clock edge`
232			`--`
233			`-- acia_rx_baud_clock_edge : process( Clk, RxRst, RxBdClk, RxBdDel )`
234			`acia_rx_baud_clock_edge : process( RxRst, Clk )`
235			`begin`
236			`if RxRst = '1' then`
237			`RxBdDel <= '0';`
238			`RxBdEdge <= '0';`
239			`elsif Clk'event and Clk = '0' then`
240			`RxBdDel <= RxBdClk;`
241			`RxBdEdge <= RxBdClk and (not RxBdDel);`
242			`end if;`
243			`end process;`
244
245			`---------------------------------------------------------------------`
246			`-- Receiver process`
247			`---------------------------------------------------------------------`
248			`-- WdFmt - Bits[4..2]`
249			`-- 0 0 0 - 7 data, even parity, 2 stop`
250			`-- 0 0 1 - 7 data, odd parity, 2 stop`
251			`-- 0 1 0 - 7 data, even parity, 1 stop`
252			`-- 0 1 1 - 7 data, odd parity, 1 stop`
253			`-- 1 0 0 - 8 data, no parity, 2 stop`
254			`-- 1 0 1 - 8 data, no parity, 1 stop`
255			`-- 1 1 0 - 8 data, even parity, 1 stop`
256			`-- 1 1 1 - 8 data, odd parity, 1 stop`
257			`-- acia_rx_receive : process( Clk, RxRst, RxState, RxBdEdge, RxDatDel2, RxBitCount, RxReady, RxShiftReg )`
258			`acia_rx_receive : process( RxRst, Clk )`
259			`begin`
260			`if RxRst = '1' then`
261			`RxFErr <= '0';`
262			`RxOErr <= '0';`
263			`RxPErr <= '0';`
264			`RxShiftReg <= (others => '0'); -- Resert Shift register`
265			`RxDOut <= (others => '0');`
266			`RxParity <= '0'; -- reset Parity bit`
267			`RxAck <= '0'; -- Receiving data`
268			`RxBitCount <= (others => '0');`
269			`RxState <= RxStart_state;`
270			`elsif Clk'event and Clk='0' then`
271			`if RxBdEdge = '1' then`
272			`case RxState is`
273			`when RxStart_state =>`
274			`RxShiftReg <= (others => '0'); -- Reset Shift register`
275			`RxParity <= '0'; -- Parity bit`
276			`if WdFmt(2) = '0' then`
277			`-- WdFmt(2) = '0' => 7 data`
278			`RxBitCount <= "110";`
279			`else`
280			`-- WdFmt(2) = '1' => 8 data`
281			`RxBitCount <= "111";`
282			`end if;`
283			`if RxDatDel2 = '0' then -- look for start request`
284			`RxState <= RxData_state; -- yes, read data`
285			`end if;`
286
287			`when RxData_state => -- data bits 0 to 6`
288			`RxShiftReg <= RxDatDel2 & RxShiftReg(7 downto 1);`
289			`RxParity <= RxParity xor RxDatDel2;`
290			`RxAck <= '1'; -- Flag receive in progress`
291			`RxBitCount <= RxBitCount - "001";`
292			`if RxBitCount = "000" then`
293			`if WdFmt(2) = '0' then -- WdFmt(2) = '0' => 7 data`
294			`RxState <= RxParity_state; -- 7 bits always has parity`
295			`else -- WdFmt(2) = '1' => 8 data`
296			`if WdFmt(1) = '0' then`
297			`RxState <= RxStop_state; -- WdFmt(1) = '0' no parity`
298			`else`
299			`RxState <= RxParity_state; -- WdFmt(1) = '1' parity`
300			`end if; -- WdFmt(1)`
301			`end if; -- WdFmt(2)`
302			`end if; -- RxBitCount`
303
304			`when RxParity_state => -- parity bit`
305			`if WdFmt(2) = '0' then -- 7 data, shift right`
306			`RxShiftReg <= RxDatDel2 & RxShiftReg(7 downto 1); -- 7 data + parity`
307			`end if;`
308			`if WdFmt(0) = '0' then -- parity polarity ?`
309			`if RxParity = RxDatDel2 then -- check even parity`
310			`RxPErr <= '1';`
311			`else`
312			`RxPErr <= '0';`
313			`end if;`
314			`else`
315			`if RxParity = RxDatDel2 then -- check for odd parity`
316			`RxPErr <= '0';`
317			`else`
318			`RxPErr <= '1';`
319			`end if;`
320			`end if;`
321			`RxState <= RxStop_state;`
322
323			`when RxStop_state => -- stop bit (Only one required for RX)`
324			`RxAck <= '0'; -- Flag Receive Complete`
325			`RxDOut <= RxShiftReg;`
326			`if RxDatDel2 = '1' then -- stop bit expected`
327			`RxFErr <= '0'; -- yes, no framing error`
328			`else`
329			`RxFErr <= '1'; -- no, framing error`
330			`end if;`
331			`if RxReady = '1' then -- Has previous data been read ?`
332			`RxOErr <= '1'; -- no, overrun error`
333			`else`
334			`RxOErr <= '0'; -- yes, no over run error`
335			`end if;`
336			`RxState <= RxStart_state;`
337
338			`when others =>`
339			`RxAck <= '0'; -- Flag Receive Complete`
340			`RxState <= RxStart_state;`
341			`end case; -- RxState`
342
343			`end if; -- RxBdEdge`
344			`end if; -- clk / RxRst`
345
346			`end process;`
347
348			`---------------------------------------------------------------------`
349			`-- Receiver Read process`
350			`---------------------------------------------------------------------`
351			`-- acia_rx_read : process(Clk, RxRst, RxRd, RxReq, RxAck, RxReady )`
352			`acia_rx_read : process( RxRst, Clk, RxReady )`
353			`begin`
354			`if RxRst = '1' then`
355			`RxReady <= '0';`
356			`RxReq <= '0';`
357			`elsif Clk'event and Clk='0' then`
358			`if RxRd = '1' then`
359			`-- Data was read, Reset data ready`
360			`-- Request more data`
361			`RxReady <= '0';`
362			`RxReq <= '1';`
363			`else`
364			`if RxReq = '1' and RxAck = '1' then`
365			`-- Data is being received`
366			`-- reset receive request`
367			`RxReq <= '0';`
368			`else`
369			`-- Data now received`
370			`-- Flag RxReady and read Shift Register`
371			`if RxReq = '0' and RxAck = '0' then`
372			`RxReady <= '1';`
373			`end if;`
374			`end if; -- RxReq`
375			`end if; -- RxRd`
376			`end if; -- clk / RxRst`
377			`RxRdy <= RxReady;`
378			`end process;`
379
380			`end rtl; --==================== End of architecture ====================--`