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[/] [udp_ip_stack/] [trunk/] [rtl/] [vhdl/] [arp_RX.vhd] - Rev 18

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----------------------------------------------------------------------------------
-- Company: 
-- Engineer:            Peter Fall
-- 
-- Create Date:    12:00:04 05/31/2011 
-- Design Name: 
-- Module Name:    arp_rx - Behavioral 
-- Project Name: 
-- Target Devices: 
-- Tool versions: 
-- Description:
--              handle receipt of arp pkt
--              ignores other types of pkt
--
--              When it receives an ARP pkt that is either addressed to our IP or is a global request,
--              it outputs for a single clock cycle either recv_who_has or recv_I_have along
--              with associated mac or arp entry data.
--
--              Note that if recv who_has and we have it, then we also assert I_have so that we can cache the rev lookup
--              on the expectation that we will want to reply to this host.
--
-- Dependencies: 
--
-- Revision: 
-- Revision 0.01 - File Created - refactored from arp v0.02 module
-- Additional Comments: 
--
----------------------------------------------------------------------------------
library IEEE;
use IEEE.STD_LOGIC_1164.all;
use IEEE.NUMERIC_STD.all;
use work.arp_types.all;
 
entity arp_rx is
  port (
    -- MAC layer RX signals
    data_in               : in  std_logic_vector (7 downto 0);  -- ethernet frame (from dst mac addr through to last byte of frame)
    data_in_valid         : in  std_logic;    -- indicates data_in valid on clock
    data_in_last          : in  std_logic;    -- indicates last data in frame
    -- ARP output signals
    recv_who_has          : out std_logic;    -- pulse will be latched
    arp_entry_for_who_has : out arp_entry_t;  -- target for who_has msg (Iie, who to reply to)
    recv_I_have           : out std_logic;    -- pulse will be latched
    arp_entry_for_I_have  : out arp_entry_t;  -- arp target for I_have msg
    -- control and status signals
    req_count             : out std_logic_vector(7 downto 0);   -- count of arp pkts received
    -- system signals
    our_ip_address        : in  std_logic_vector (31 downto 0);
    rx_clk                : in  std_logic;
    reset                 : in  std_logic
    );
end arp_rx;
 
 
architecture Behavioral of arp_rx is
 
  type rx_state_t is (IDLE, PARSE, PROCESS_ARP, WAIT_END);
  type rx_event_t is (NO_EVENT, DATA);
  type count_mode_t is (RST, INCR, HOLD);
  type arp_oper_t is (NOP, REQUEST, REPLY);
 
  type tx_state_type is (IDLE, WAIT_MAC, SEND);
 
  -- state variables
  signal send_request_needed : std_logic;
  signal tx_mac_chn_reqd     : std_logic;
 
  signal rx_state      : rx_state_t;
  signal rx_count      : unsigned (7 downto 0);
  signal arp_operation : arp_oper_t;
  signal arp_req_count : unsigned (7 downto 0);
  signal new_arp_entry : arp_entry_t;
 
-- FIXME        - remove these debug state signals
  signal arp_err_data : std_logic_vector (7 downto 0);
  signal set_err_data : std_logic;
 
  attribute keep                 : string;
  attribute keep of arp_err_data : signal is "true";
 
 
  -- rx control signals
  signal next_rx_state    : rx_state_t;
  signal set_rx_state     : std_logic;
  signal rx_event         : rx_event_t;
  signal rx_count_mode    : count_mode_t;
  signal set_arp_oper     : std_logic;
  signal arp_oper_set_val : arp_oper_t;
  signal dataval          : std_logic_vector (7 downto 0);
  signal count_arp_rcvd   : std_logic;
 
  signal set_mac5 : std_logic;
  signal set_mac4 : std_logic;
  signal set_mac3 : std_logic;
  signal set_mac2 : std_logic;
  signal set_mac1 : std_logic;
  signal set_mac0 : std_logic;
 
  signal set_ip3 : std_logic;
  signal set_ip2 : std_logic;
  signal set_ip1 : std_logic;
  signal set_ip0 : std_logic;
 
 
 
  -- function to determine whether the rx pkt is an arp pkt and whether we want to process it
  -- Returns 1 if we should discard
  -- The following will make us ignore the frame (all values hexadecimal):
  -- PDU type /= 0806
  -- Protocol Type /= 0800
  -- Hardware Type /= 1
  -- Hardware Length /= 6
  -- Protocol Length /= 4
  -- Operation /= 1 or 2
  -- Target IP /= our IP (i.er. message is not meant for us)
  --
  function not_our_arp(data : std_logic_vector; count : unsigned; our_ip : std_logic_vector) return std_logic is
  begin
    if
      (count = 12 and data /= x"08") or                 -- PDU type 0806 : ARP
      (count = 13 and data /= x"06") or
      (count = 14 and data /= x"00") or                 -- HW type 1 : eth
      (count = 15 and data /= x"01") or
      (count = 16 and data /= x"08") or                 -- Protocol 0800 : IP
      (count = 17 and data /= x"00") or
      (count = 18 and data /= x"06") or                 -- HW Length 6
      (count = 19 and data /= x"04") or                 -- protocol length 4
      (count = 20 and data /= x"00") or                 -- operation 1 or 2 (req or reply)
      (count = 21 and data /= x"01" and data /= x"02") or
      (count = 38 and data /= our_ip(31 downto 24)) or  -- target IP is ours
      (count = 39 and data /= our_ip(23 downto 16)) or
      (count = 40 and data /= our_ip(15 downto 8)) or
      (count = 41 and data /= our_ip(7 downto 0))
    then
      return '1';
    else
      return '0';
    end if;
  end function not_our_arp;
 
begin
 
  rx_combinatorial : process (
    -- input signals
    data_in, data_in_valid, data_in_last, our_ip_address,
    -- state variables
    rx_state, rx_count, arp_operation, arp_req_count, arp_err_data, new_arp_entry,
    -- control signals
    next_rx_state, set_rx_state, rx_event, rx_count_mode, set_arp_oper, arp_oper_set_val,
    dataval, set_mac5, set_mac4, set_mac3, set_mac2, set_mac1, set_mac0, set_ip3, set_ip2, set_ip1, set_ip0, set_err_data,
    count_arp_rcvd
    )
  begin
    -- set output followers
    req_count <= std_logic_vector(arp_req_count);
 
    -- set defaults for combinatorial outputs
    recv_who_has              <= '0';
    arp_entry_for_who_has.ip  <= (others => '0');
    arp_entry_for_who_has.mac <= (others => '0');
    recv_I_have               <= '0';
    arp_entry_for_I_have.ip   <= (others => '0');
    arp_entry_for_I_have.mac  <= (others => '0');
 
    -- set signal defaults
    next_rx_state    <= IDLE;
    set_rx_state     <= '0';
    rx_event         <= NO_EVENT;
    rx_count_mode    <= HOLD;
    set_arp_oper     <= '0';
    arp_oper_set_val <= NOP;
    dataval          <= (others => '0');
    set_mac5         <= '0';
    set_mac4         <= '0';
    set_mac3         <= '0';
    set_mac2         <= '0';
    set_mac1         <= '0';
    set_mac0         <= '0';
    set_ip3          <= '0';
    set_ip2          <= '0';
    set_ip1          <= '0';
    set_ip0          <= '0';
    count_arp_rcvd   <= '0';
    set_err_data     <= '0';
 
    -- determine event (if any)
    if data_in_valid = '1' then
      rx_event <= DATA;
    end if;
 
    -- RX FSM
    case rx_state is
      when IDLE =>
        rx_count_mode <= RST;
        case rx_event is
          when NO_EVENT =>              -- (nothing to do)
          when DATA =>
            next_rx_state <= PARSE;
            set_rx_state  <= '1';
            rx_count_mode <= INCR;
        end case;
 
      when PARSE =>
        case rx_event is
          when NO_EVENT =>              -- (nothing to do)
          when DATA =>
            rx_count_mode <= INCR;
                                        -- handle early frame termination
            if data_in_last = '1' then
              next_rx_state <= IDLE;
              set_rx_state  <= '1';              
            --else
            end if;
                                        -- check for end of frame. Also, detect and discard if not our frame
              if rx_count = 41 then     -- TB 2013-01-14 15:09:45 was 42
                next_rx_state <= PROCESS_ARP;
                set_rx_state  <= '1';
              elsif not_our_arp(data_in, rx_count, our_ip_address) = '1' then
                dataval       <= data_in;
                set_err_data  <= '1';
                next_rx_state <= WAIT_END;
                set_rx_state  <= '1';
              elsif rx_count = 21 then
                                        -- capture ARP operation
                case data_in is
                  when x"01" =>
                    arp_oper_set_val <= REQUEST;
                    set_arp_oper     <= '1';
                  when x"02" =>
                    arp_oper_set_val <= REPLY;
                    set_arp_oper     <= '1';
                  when others =>        -- ignore other values
                end case;
                                        -- capture source mac addr
              elsif rx_count = 22 then
                set_mac5 <= '1';
                dataval  <= data_in;
              elsif rx_count = 23 then
                set_mac4 <= '1';
                dataval  <= data_in;
              elsif rx_count = 24 then
                set_mac3 <= '1';
                dataval  <= data_in;
              elsif rx_count = 25 then
                set_mac2 <= '1';
                dataval  <= data_in;
              elsif rx_count = 26 then
                set_mac1 <= '1';
                dataval  <= data_in;
              elsif rx_count = 27 then
                set_mac0 <= '1';
                dataval  <= data_in;
                                        -- capture source ip addr
              elsif rx_count = 28 then
                set_ip3 <= '1';
                dataval <= data_in;
              elsif rx_count = 29 then
                set_ip2 <= '1';
                dataval <= data_in;
              elsif rx_count = 30 then
                set_ip1 <= '1';
                dataval <= data_in;
              elsif rx_count = 31 then
                set_ip0 <= '1';
                dataval <= data_in;
              end if;
--            end if;
        end case;
 
      when PROCESS_ARP =>
        next_rx_state    <= WAIT_END;
        set_rx_state     <= '1';
        arp_oper_set_val <= NOP;
        set_arp_oper     <= '1';
        case arp_operation is
          when NOP =>                   -- (nothing to do)
          when REQUEST =>
            count_arp_rcvd        <= '1';
            recv_who_has          <= '1';
            arp_entry_for_who_has <= new_arp_entry;
                                        -- setting I_Have as well allows us to cache the remote node's entry immediately
            recv_I_have           <= '1';
            arp_entry_for_I_have  <= new_arp_entry;
          when REPLY =>
            count_arp_rcvd       <= '1';
            recv_I_have          <= '1';
            arp_entry_for_I_have <= new_arp_entry;
        end case;
 
      when WAIT_END =>
        case rx_event is
          when NO_EVENT =>              -- (nothing to do)
          when DATA =>
            if data_in_last = '1' then
              next_rx_state <= IDLE;
              set_rx_state  <= '1';
            end if;
        end case;
 
    end case;
 
  end process;
 
  rx_sequential : process (rx_clk)
  begin
    if rising_edge(rx_clk) then
      if reset = '1' then
        -- reset state variables
        rx_state      <= IDLE;
        rx_count      <= x"00";
        arp_operation <= NOP;
        arp_req_count <= x"00";
        arp_err_data  <= (others => '0');
      else
        -- Next rx_state processing
        if set_rx_state = '1' then
          rx_state <= next_rx_state;
        else
          rx_state <= rx_state;
        end if;
 
        -- rx_count processing
        case rx_count_mode is
          when RST =>
            rx_count <= x"00";
          when INCR =>
            rx_count <= rx_count + 1;
          when HOLD =>
            rx_count <= rx_count;
        end case;
 
        -- err data
        if set_err_data = '1' then
          arp_err_data <= data_in;
        else
          arp_err_data <= arp_err_data;
        end if;
 
        -- arp operation processing
        if set_arp_oper = '1' then
          arp_operation <= arp_oper_set_val;
        else
          arp_operation <= arp_operation;
        end if;
 
        -- source mac capture
        if (set_mac5 = '1') then new_arp_entry.mac(47 downto 40) <= dataval; end if;
        if (set_mac4 = '1') then new_arp_entry.mac(39 downto 32) <= dataval; end if;
        if (set_mac3 = '1') then new_arp_entry.mac(31 downto 24) <= dataval; end if;
        if (set_mac2 = '1') then new_arp_entry.mac(23 downto 16) <= dataval; end if;
        if (set_mac1 = '1') then new_arp_entry.mac(15 downto 8)  <= dataval; end if;
        if (set_mac0 = '1') then new_arp_entry.mac(7 downto 0)   <= dataval; end if;
 
        -- source ip capture
        if (set_ip3 = '1') then new_arp_entry.ip(31 downto 24) <= dataval; end if;
        if (set_ip2 = '1') then new_arp_entry.ip(23 downto 16) <= dataval; end if;
        if (set_ip1 = '1') then new_arp_entry.ip(15 downto 8)  <= dataval; end if;
        if (set_ip0 = '1') then new_arp_entry.ip(7 downto 0)   <= dataval; end if;
 
        -- set arp entry request
        if count_arp_rcvd = '1' then
                                        -- count another ARP pkt received
          arp_req_count <= arp_req_count + 1;
        else
          arp_req_count <= arp_req_count;
        end if;
 
      end if;
    end if;
  end process;
 
end Behavioral;
 
 

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