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-------------------------------------------------------------------------------

--

-- (C) Copyright 2013 DFC Design, s.r.o., Brno, Czech Republic

-- Author: Marek Kvas (m.kvas@dfcdesign.cz)

--

-------------------------------------------------------------------------------

-- This file is part of UDP/IPv4 for 10 G Ethernet core.

-- 

-- UDP/IPv4 for 10 G Ethernet core is free software: you can 

-- redistribute it and/or modify it under the terms of 

-- the GNU Lesser General Public License as published by the Free 

-- Software Foundation, either version 3 of the License, or

-- (at your option) any later version.

-- 

-- UDP/IPv4 for 10 G Ethernet core 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 Lesser General Public License 

-- for more details.

-- 

-- You should have received a copy of the GNU Lesser General Public 

-- License along with UDP/IPv4 for 10 G Ethernet core.  If not, 

-- see <http://www.gnu.org/licenses/>.

-------------------------------------------------------------------------------

--

-- This core processes UDP/IPv4 frames. It is supposed to be connected to

-- frame_received core on input as it assumes aligned raw data with

-- convenient data valid and byte enable signals + checksum validation flags.

--

-- The purpose of this block is to filter out packets that are not intended

-- for us. All packets thats destination MAC and IP addresses don't match

-- set host addresses are rejected. Broadcast packets can be accepted too.

--

--

-------------------------------------------------------------------------------

library ieee;

use ieee.std_logic_1164.all;

use ieee.numeric_std.all;

library work;

use work.frame_pkg.all;

Library UNISIM;

use UNISIM.vcomponents.all;

entity frame_process is

   port (

      RST               : in  std_logic;

      CLK               : in  std_logic;

      -- Interface towards frame receiver

      RX_DATA           : in  std_logic_vector(63 downto 0);

      RX_DV             : in  std_logic;

      RX_BE             : in  std_logic_vector(7 downto 0);

      RX_ERR            : in  std_logic;

      RX_ERR_VALID      : in  std_logic;

      -- Interfaces of tag and data fifos

      DFIFO_DATA        : out fp_dfifo_data_type;

      DFIFO_WR_EN       : out std_logic;

      DFIFO_FULL        : in  std_logic;

      TFIFO_DATA        : out fp_tfifo_data_type;

      TFIFO_WR_EN       : out std_logic;

      TFIFO_FULL        : in  std_logic;

      -- Host MAC and IP addresses

      MAC_ADDR          : in  mac_addr_type;

      IP_ADDR           : in  ip_addr_type;

      IP_NET_MASK       : in  ip_addr_type

        );

end entity;

architecture synthesis of frame_process is

   -- Constants

   constant LC_MAC_ADDR_BITLEN      : integer := 48;

   constant LC_DST_MAC_POS_RIGHT    : integer := 0;

   constant LC_DST_MAC_POS_LEFT     : integer := LC_DST_MAC_POS_RIGHT +

                                                 LC_MAC_ADDR_BITLEN - 1;

   constant LC_MAC_BROADCAST_ADDR   : std_logic_vector(LC_MAC_ADDR_BITLEN - 1

                                                   downto 0) := (others => '1');

   constant LC_MAC_ETHERTYPE_BITLEN : integer := 16;

   constant LC_MAC_ETHERTYPE_POS_RIGHT : integer := 12 * 8;

   constant LC_MAC_ETHERTYPE_POS_LEFT  : integer := LC_MAC_ETHERTYPE_POS_RIGHT +

                                                    LC_MAC_ETHERTYPE_BITLEN - 1;

   constant LC_MAC_ETHERTYPE_IPV4   : std_logic_vector(LC_MAC_ETHERTYPE_BITLEN -1

                                       downto 0) := x"0800";

   constant LC_MAC_ETHERTYPE_ARP    : std_logic_vector(LC_MAC_ETHERTYPE_BITLEN -1

                                       downto 0) := x"0806";

   constant LC_IP_ADDR_BITLEN       : integer := 32;

   constant LC_DST_IP_POS_RIGHT     : integer := 6*8;

   constant LC_DST_IP_POS_LEFT      : integer := LC_DST_IP_POS_RIGHT +

                                                 LC_IP_ADDR_BITLEN - 1;

   constant LC_IP_PROTO_BITLEN      : integer := 8;

   constant LC_IP_PROTO_POS_RIGHT   : integer := 7*8;

   constant LC_IP_PROTO_POS_LEFT    : integer := LC_IP_PROTO_POS_RIGHT +

                                                 LC_IP_PROTO_BITLEN - 1;

   constant LC_IP_PROTO_UDP         : std_logic_vector(LC_IP_PROTO_BITLEN - 1

                                                         downto 0) := x"11";

   constant LC_THIS_NET_BROADCAST_IP: std_logic_vector(LC_IP_ADDR_BITLEN - 1

                                                      downto 0) := x"ffffffff";

   constant LC_UDP_ADDR_BITLEN      : integer := 16;

   constant LC_DST_UDP_POS_RIGHT    : integer := 4*8;

   constant LC_DST_UDP_POS_LEFT     : integer := LC_DST_UDP_POS_RIGHT +

                                                 LC_UDP_ADDR_BITLEN - 1;

   constant LC_UDP_LENGTH_BITLEN    : integer := 16;

   constant LC_UDP_LENGTH_POS_RIGHT : integer := 6*8;

   constant LC_UDP_LENGTH_POS_LEFT  : integer := LC_UDP_LENGTH_POS_RIGHT +

                                                 LC_UDP_LENGTH_BITLEN - 1;

   constant LC_UDP_DATA_POS         : integer := 2*8;

   constant LC_UDP_HDR_LEN          : integer := 8;

   constant LC_SRC_MAC_BITLEN       : integer := 32;

   constant LC_SRC_MAC_POS_RIGHT0   : integer := 6*8;

   constant LC_SRC_MAC_POS_LEFT0    : integer := LC_SRC_MAC_POS_RIGHT0 +

                                          LC_SRC_MAC_BITLEN - 1;

   constant LC_SRC_MAC_BITLEN1      : integer := 16;

   constant LC_SRC_MAC_POS_RIGHT1   : integer := 2*8;

   constant LC_SRC_MAC_POS_LEFT1    : integer := LC_SRC_MAC_POS_RIGHT1 +

                                          LC_SRC_MAC_BITLEN1 - 1;

   constant LC_SRC_IP_BITLEN        : integer := 16;

   constant LC_SRC_IP_POS_RIGHT0    : integer := 18*8;

   constant LC_SRC_IP_POS_LEFT0     : integer := LC_SRC_IP_POS_RIGHT0 +

                                         LC_SRC_IP_BITLEN - 1;

   constant LC_SRC_IP_BITLEN1       : integer := 16;

   constant LC_SRC_IP_POS_RIGHT1    : integer := 4*8;

   constant LC_SRC_IP_POS_LEFT1     : integer := LC_SRC_IP_POS_RIGHT1 +

                                         LC_SRC_IP_BITLEN1 - 1;

   constant LC_SRC_UDP_BITLEN       : integer := 16;

   constant LC_SRC_UDP_POS_RIGHT    : integer := 10*8;

   constant LC_SRC_UDP_POS_LEFT     : integer := LC_SRC_UDP_POS_RIGHT +

                                                 LC_SRC_UDP_BITLEN - 1;

   -- Main FSM sorting frames and stripping headers

   type sort_fsm_type is (S_MAC0, S_MAC1_IP0, S_IP1, S_IP2, S_IP3_UDP0,

                          S_UDP1_DATA,

                          --S_CHECK_ERR, 

                          S_TAG,

                          S_TAG_DISCARD,

                          S_MAC1_ARP

                       --   ,S_FILTERED

                       );

   signal sort_fsm_cur  : sort_fsm_type;

   signal sort_fsm_next : sort_fsm_type;

   -- FSM control signals

   signal all_data_written    : std_logic;

   signal load_udp_data_length: std_logic;

   signal write_udp_data      : std_logic;

   signal cur_broadcast       : std_logic;

   signal cur_broadcast_s     : std_logic;

   signal cur_broadcast_r     : std_logic;

   signal mac_ethertype_ipv4  : std_logic;

   signal mac_ethertype_arp   : std_logic;

   signal mac_filter_unicast  : std_logic;

   signal mac_filter_broadcast: std_logic;

   signal ip_filter_unicast   : std_logic;

   signal ip_filter_broadcast : std_logic;

   signal ip_next_proto_udp   : std_logic;

   signal udp_data_length     : unsigned(C_FP_TAG_LENGTH_BITLEN - 1 downto 0);

   signal udp_data_length_reg : unsigned(udp_data_length'range);

   signal rx_udp_be           : std_logic_vector(RX_BE'range);

   signal rx_udp_data         : std_logic_vector(RX_DATA'range);

   -- internal form of output ports

   signal tfifo_wr_en_i       : std_logic;

   signal tfifo_data_i        : fp_tfifo_data_type;

   -- Counter of data to send

   signal data_cnt            : unsigned(15 downto 0);

   -- Counter of data to be discarded if needed

   signal data_to_discard     : unsigned(data_cnt'range);

   signal dst_udp_reg         : udp_port_type;

   signal dst_udp_port        : udp_port_type;

   -- Register versions of inputs

   signal rx_data_d           : std_logic_vector(63 downto 0);

   signal rx_dv_d             : std_logic;

   signal rx_be_d             : std_logic_vector(7 downto 0);

   signal rx_err_d            : std_logic;

   signal rx_err_valid_d      : std_logic;

   signal rx_err_dd           : std_logic;

   signal rx_be_dd            : std_logic_vector(7 downto 0);

   signal rx_dv_dd            : std_logic;

   signal rx_data_dd          : std_logic_vector(63 downto 0);

   signal rx_err_valid_dd     : std_logic;

   signal rx_err_ddd          : std_logic;

   signal rx_be_ddd           : std_logic_vector(7 downto 0);

   signal rx_dv_ddd           : std_logic;

   signal rx_dv_dddd          : std_logic;

   signal rx_data_ddd         : std_logic_vector(63 downto 0);

   signal rx_err_valid_ddd    : std_logic;

   -- Function definitions

   -- Cut out byte enables from two delayed words - compensate for shift in UDP

   function derive_udp_be_func(be_ddd : std_logic_vector;

                           be_dd : std_logic_vector) return std_logic_vector is

      variable res : std_logic_vector(be_dd'range);

      variable tmp : std_logic_vector(be_dd'length * 2 - 1 downto 0);

   begin

      -- We know the offset for standard UDP packet (without options)

      tmp := be_dd & be_ddd;

      res := tmp(LC_UDP_DATA_POS/8 + be_dd'left downto LC_UDP_DATA_POS/8);

      return res;

   end function;

   -- Cut out data from two delayed words - compensate for shift in UDP

   function derive_udp_data_func(data_ddd : std_logic_vector;

                           data_dd : std_logic_vector) return std_logic_vector is

      variable res : std_logic_vector(data_dd'range);

      variable tmp : std_logic_vector(data_dd'length * 2 - 1 downto 0);

   begin

      -- We know the offset for standard UDP packet (without options)

      tmp := data_dd & data_ddd;

      res := tmp(LC_UDP_DATA_POS + data_dd'left downto LC_UDP_DATA_POS);

      return res;

   end function;

   -- Basically finds first 1 bit from left (MSB) to find out

   -- how many byte enables is 1 (gaps are not alowed)

   function be_to_cnt_udp_func(be_ddd : std_logic_vector;

                           be_dd : std_logic_vector) return integer is

      variable tmp : std_logic_vector(be_ddd'range);

      variable res : integer range 0 to be_ddd'length;

   begin

      tmp := derive_udp_be_func(be_ddd, be_dd);

      for i in tmp'left downto 0 loop

         if tmp(i) = '1' then

            return i + 1;

         end if;

      end loop;

      return 0;

   end function;

   -- Change endians

   function swap_bytes(fi : std_logic_vector) return std_logic_vector is

      variable f   : std_logic_vector(fi'length - 1 downto 0);

      variable res : std_logic_vector(f'length - 1 downto 0);

      variable blen : integer;

   begin

      f := fi;

      blen := f'length/8 - 1;

      for i in 0 to blen loop

         res(i*8 + 7 downto i * 8) := f((blen - i)*8 + 7 downto (blen - i) * 8);

      end loop;

      return res;

   end Function;

   function swap_bytes(f : unsigned) return unsigned is

   begin

      return unsigned(swap_bytes(std_logic_vector(f)));

   end function;

begin

   -- Create delayed signal, first to isolate from previous

   -- block, second to align filter results with data

   delay_input_proc : process (RST, CLK)

   begin

      if RST = '1' then

         rx_data_d         <= (others => '0');

         rx_data_dd        <= (others => '0');

         rx_data_ddd       <= (others => '0');

         rx_dv_d           <= '0';

         rx_dv_dd          <= '0';

         rx_dv_ddd         <= '0';

         rx_dv_dddd         <= '0';

         rx_be_d           <= (others => '0');

         rx_be_dd          <= (others => '0');

         rx_be_ddd         <= (others => '0');

         rx_err_d          <= '0';

         rx_err_dd         <= '0';

         rx_err_ddd        <= '0';

         rx_err_valid_d    <= '0';

         rx_err_valid_dd   <= '0';

         rx_err_valid_ddd  <= '0';

      elsif rising_edge(CLK) then

         rx_data_d         <= RX_DATA;

         rx_data_dd        <= rx_data_d;

         rx_data_ddd       <= rx_data_dd;

         rx_dv_d           <= RX_DV;

         rx_dv_dd          <= rx_dv_d;

         rx_dv_ddd         <= rx_dv_dd;

         rx_dv_dddd        <= rx_dv_ddd;

         rx_be_d           <= RX_BE;

         rx_be_dd          <= rx_be_d;

         rx_be_ddd         <= rx_be_dd;

         rx_err_d          <= RX_ERR;

         rx_err_dd         <= rx_err_d;

         rx_err_ddd        <= rx_err_dd;

         rx_err_valid_d    <= RX_ERR_VALID;

         rx_err_valid_dd   <= rx_err_valid_d;

         rx_err_valid_ddd  <= rx_err_valid_dd;

      end if;

   end process;

   -- Main FSM sorting frames and stripping headers

   sort_fsm_adv_proc : process (CLK, RST)

   begin

      if RST ='1' then

         sort_fsm_cur <= S_MAC0;

         cur_broadcast <= '0';

      elsif rising_edge(CLK) then

         sort_fsm_cur <= sort_fsm_next;

         if cur_broadcast_s = '1' then

            cur_broadcast <= '1';

         elsif cur_broadcast_r = '1' then

            cur_broadcast <= '0';

         end if;

      end if;

   end process;

   sort_fsm_trans_out_proc : process (sort_fsm_cur, dst_udp_port,

                                      udp_data_length, rx_dv_ddd, rx_dv_dddd,

                                      mac_filter_unicast, mac_filter_broadcast,

                                      mac_ethertype_ipv4, mac_ethertype_arp,

                                      ip_filter_unicast, ip_filter_broadcast,

                                      all_data_written, ip_next_proto_udp,

                                      DFIFO_FULL, rx_err_valid_ddd,

                                      rx_err_ddd, TFIFO_FULL, cur_broadcast,

                                      data_to_discard, rx_data_d, rx_data_dd, rx_data_ddd)

     variable header : std_logic_vector(3*64-1 downto 0);

   begin

      header := rx_data_d & rx_data_dd & rx_data_ddd;

      load_udp_data_length  <= '0';

      write_udp_data <= '0';

      tfifo_wr_en_i <= '0';

      cur_broadcast_s <= '0';

      cur_broadcast_r <= '0';

      -- Dafault state of tfifo data

      tfifo_data_i <= C_FP_TAG_UDP & dst_udp_port &

                                             std_logic_vector(udp_data_length);

      sort_fsm_next <= sort_fsm_cur;

      case sort_fsm_cur is

         when S_MAC0 =>

            cur_broadcast_r <= '1';

            if rx_dv_ddd = '1' and rx_dv_dddd = '0' then

               -- Process only our packets and broadcast

               if mac_filter_unicast = '1' or

                  mac_filter_broadcast = '1' then

                  if mac_filter_broadcast = '1' then

                     -- Remember we process broadcast

                     -- because we will need to know later

                     cur_broadcast_s <= '1';

                  end if;

                  -- Differentiate between IPv4 and ARP

                  if mac_ethertype_ipv4 = '1' then

                     sort_fsm_next <= S_MAC1_IP0;

                  elsif mac_ethertype_arp = '1' then

                     sort_fsm_next <= S_MAC1_ARP;

                  else

                     -- We process IPv4 and ARP packets only

                     NULL;

                  end if;

                  -- Save the first part of return info - part of src MAC addr

                  if TFIFO_FULL = '0' then

                     tfifo_wr_en_i <= '1';

                  else

                     -- tag FIFO full; As nothing has been written yet

                     -- we can stay in this state and wait for next frame

                     sort_fsm_next <= S_MAC0;

                  end if;

                  tfifo_data_i <= C_FP_TAG_RETINF &

                     swap_bytes(header(LC_SRC_MAC_POS_LEFT0 downto

                                                      LC_SRC_MAC_POS_RIGHT0));

               end if;

            end if;

         when S_MAC1_ARP =>

            -- ARP not supported in this version

            sort_fsm_next <= S_MAC0;

         when S_MAC1_IP0 =>

            -- Only first ten bytes of IP header available

            if rx_dv_ddd = '1' then

               sort_fsm_next <= S_IP1;

               -- Save the second part of return info - rest of src MAC addr

               -- and part of src IP

               if TFIFO_FULL = '0' then

                  tfifo_wr_en_i <= '1';

               else

                  -- tag FIFO full; no date have been written so just ignere pkt

                  sort_fsm_next <= S_MAC0;

               end if;

               tfifo_data_i <= C_FP_TAG_RETINF &

                  swap_bytes(header(LC_SRC_MAC_POS_LEFT1 downto

                                                   LC_SRC_MAC_POS_RIGHT1)) &

                  swap_bytes(header(LC_SRC_IP_POS_LEFT0 downto

                                                   LC_SRC_IP_POS_RIGHT0));

            else

               sort_fsm_next <= S_TAG_DISCARD;

            end if;

         when S_IP1 =>

            -- Check if next protocol is UDP

            -- Destination IP is not yet completely loaded

            if rx_dv_ddd = '1' and

               ip_next_proto_udp = '1' then

               sort_fsm_next <= S_IP2;

            else

               sort_fsm_next <= S_MAC0;

            end if;

         when S_IP2 =>

            -- Continue if destination address is ours or

            -- broadcast and MAC was broadcast too

            if rx_dv_ddd = '1' and

               ((ip_filter_unicast = '1' and   cur_broadcast = '0')or

                (ip_filter_broadcast = '1' and cur_broadcast = '1')

               ) then

               sort_fsm_next <= S_IP3_UDP0;

               -- Save the third part of return info - rest of src IP addr

               -- and src UDP port

               if TFIFO_FULL = '0' then

                  tfifo_wr_en_i <= '1';

               else

                  -- data FIFO full; discard if anything has been written

                  sort_fsm_next <= S_MAC0;

               end if;

               tfifo_data_i <= C_FP_TAG_RETINF &

                  swap_bytes(header(LC_SRC_IP_POS_LEFT1 downto

                                                LC_SRC_IP_POS_RIGHT1)) &

                  swap_bytes(header(LC_SRC_UDP_POS_LEFT downto

                                                LC_SRC_UDP_POS_RIGHT));

            else

               sort_fsm_next <= S_MAC0;

            end if;

         when S_IP3_UDP0 =>

            -- Now we can determine destination socket

            -- based on destination UDP port

            if rx_dv_ddd = '1' then

               load_udp_data_length <= '1';

               sort_fsm_next <= S_UDP1_DATA;

            else

               sort_fsm_next <= S_MAC0;

            end if;

         when S_UDP1_DATA =>

            -- For UDP data are not aligned and first two bytes

            -- are mixed with header; because we want data aligned

            -- in fifo it may happen that there are no data

            -- to write in last cycle of dv

            if rx_dv_ddd = '1' then

               if all_data_written = '0' then

                  if DFIFO_FULL = '0' then

                     write_udp_data <= '1';

                  else

                     -- We dont have space in data fifo; data will be 

                     -- corrupted; discard packet

                     -- Data are still valid so we have enough time

                     -- to go to discard state

                     sort_fsm_next <= S_TAG_DISCARD;

                  end if;

               end if;

            else

               if all_data_written = '0' or

                  rx_err_ddd = '1'then

                  -- DV deasserted before all data received

                  -- or error occurred in packet

                  -- We don't have time to go to discard state

                  -- write discard tag now (minimal IFG is only one cycle)

                  if TFIFO_FULL = '0' then

                     tfifo_wr_en_i <= '1';

                     sort_fsm_next <= S_MAC0;

                  else

                     -- Tag fifo is full go waiting for space for discard tag

                     sort_fsm_next <= S_TAG_DISCARD;

                  end if;

                  tfifo_data_i <= C_FP_TAG_DISCARD & dst_udp_port &

                                          std_logic_vector(data_to_discard);

               else

                  -- All is fine, write ok tag

                  if TFIFO_FULL = '0' then

                     -- Write default - i.e. length and destination port

                     tfifo_wr_en_i <= '1';

                     sort_fsm_next <= S_MAC0;

                  else

                     -- There is no space for tag, go waiting

                     sort_fsm_next <= S_TAG;

                  end if;

               end if;

            end if;

         when S_TAG =>

            -- Wait until there is space in tag fifo and write ok tag

            if TFIFO_FULL = '0' then

               -- Write default - i.e. length and destination port

               tfifo_wr_en_i <= '1';

               sort_fsm_next <= S_MAC0;

            end if;

         when S_TAG_DISCARD =>

            -- Wait until there is space in tag fifo and write discard tag

            if TFIFO_FULL = '0' then

               tfifo_wr_en_i <= '1';

               sort_fsm_next <= S_MAC0;

            end if;

            tfifo_data_i <= C_FP_TAG_DISCARD & dst_udp_port &

                                             std_logic_vector(data_to_discard);

--         when S_FILTERED =>

--            -- Wait until packet that we don't care of ends

--            if rx_dv_ddd = '0' then

--               sort_fsm_next <= S_MAC0;

--            end if;

      end case;

   end process;

   -- Count data written; check against

   -- header info - valid for UDP only

   data_cnt_proc : process (RST, CLK)

      variable be_cnt : integer;

   begin

      if RST = '1' then

         data_cnt <= (others => '0');

         data_to_discard <= (others => '0');

         all_data_written <= '0';

      elsif rising_edge(CLK) then

         if load_udp_data_length = '1' then

            -- Subtract 8 as a length of UDP_HEADER

            udp_data_length <= swap_bytes(udp_data_length_reg) - LC_UDP_HDR_LEN;

            data_cnt <= swap_bytes(udp_data_length_reg) - LC_UDP_HDR_LEN;

            dst_udp_port <= swap_bytes(dst_udp_reg);

            all_data_written <= '0';

            data_to_discard <= (others => '0');

         elsif write_udp_data = '1' then

            -- Count data for case of discarding

            -- hede we don't have to play on byte enables

            data_to_discard <= data_to_discard + 8;

            -- Now, we have to derive how many bytes to write

            if data_cnt > 8 then

               -- Most often case

               data_cnt <= data_cnt - 8;

            elsif data_cnt = 8 then

               -- Data were 8 by aligned

               data_cnt <= data_cnt - 8;

               all_data_written <= '1';

            elsif data_cnt < 8 then

               be_cnt := be_to_cnt_udp_func(rx_be_ddd, rx_be_dd);

               if be_cnt >= data_cnt then

                  -- If equal it is ok; if more there are 

                  -- trailing data in packet and it is fine too

                  data_cnt <= (others => '0');

                  all_data_written <= '1';

               else

                  -- Packet was shorter and will be discarded

                  -- because DV will go down

                  null;

               end if;

            end if;

         end if;

      end if;

   end process;

   rx_udp_be   <= derive_udp_be_func(rx_be_ddd, rx_be_dd);

   rx_udp_data <= derive_udp_data_func(rx_data_ddd, rx_data_dd);

   -- Register udp length and dst port

   udp_length_reg_proc : process (RST, CLK)

      variable header : std_logic_vector(127 downto 0);

   begin

      if RST = '1' then

         udp_data_length_reg <= (others => '0');

      elsif rising_edge(CLK) then

         header := rx_data_d & rx_data_dd;

         udp_data_length_reg <= unsigned(

                  header(LC_UDP_LENGTH_POS_LEFT downto LC_UDP_LENGTH_POS_RIGHT));

         dst_udp_reg <= header(LC_DST_UDP_POS_LEFT downto LC_DST_UDP_POS_RIGHT);

      end if;

   end process;

   -- Filters for various info from header

   -- Output is aligned with data in ddd version

   -- MAC filter; Check ethertype field of MAC

   mac_filter_proc : process (RST, CLK)

      variable header      : std_logic_vector(127 downto 0);

      variable dst_mac     : std_logic_vector(LC_MAC_ADDR_BITLEN - 1 downto 0);

      variable ethertype   : std_logic_vector(LC_MAC_ETHERTYPE_BITLEN -1

                                                                     downto 0);

   begin

      if RST = '1' then

         mac_filter_unicast   <= '0';

         mac_filter_broadcast <= '0';

         mac_ethertype_ipv4   <= '0';

         mac_ethertype_arp    <= '0';

      elsif rising_edge(CLK) then

         mac_filter_unicast   <= '0';

         mac_filter_broadcast <= '0';

         mac_ethertype_ipv4   <= '0';

         mac_ethertype_arp    <= '0';

         -- Extract destination MAC and ethertype from received headers

         header := rx_data_d & rx_data_dd;

         dst_mac := header(LC_DST_MAC_POS_LEFT downto LC_DST_MAC_POS_RIGHT);

         ethertype := header(LC_MAC_ETHERTYPE_POS_LEFT downto

                                                   LC_MAC_ETHERTYPE_POS_RIGHT);

         -- Check for broadcast MAC

         if dst_mac = LC_MAC_BROADCAST_ADDR then

            mac_filter_broadcast <= '1';

         end if;

         -- Check for unicast with our MAC

         if dst_mac = swap_bytes(MAC_ADDR) then

            mac_filter_unicast <= '1';

         end if;

         -- Check for ipv4 ethertype

         if ethertype = swap_bytes(LC_MAC_ETHERTYPE_IPV4) then

            mac_ethertype_ipv4 <= '1';

         end if;

         -- Check for arp ethertype

         if ethertype = swap_bytes(LC_MAC_ETHERTYPE_ARP) then

            mac_ethertype_arp <= '1';

         end if;

      end if;

   end process;

   -- IP filter; Check for UDP as next protocol

   ip_filter_proc : process (RST, CLK)

      variable header : std_logic_vector(127 downto 0);

      variable dst_ip : std_logic_vector(LC_IP_ADDR_BITLEN - 1 downto 0);

      variable next_proto : std_logic_vector(LC_IP_PROTO_BITLEN - 1 downto 0);

      variable tmpip : ip_addr_type;

   begin

      if RST = '1' then

         ip_filter_unicast <= '0';

         ip_filter_broadcast <= '0';

         ip_next_proto_udp <= '0';

      elsif rising_edge(CLK) then

         ip_filter_unicast <= '0';

         ip_filter_broadcast <= '0';

         ip_next_proto_udp <= '0';