dct1d.vhd

来自「Pure hardware JPEG Encoder design. Packa」· VHDL 代码 · 共 335 行

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----------------------------------------------------------------------------------                                                                            ----                          V H D L    F I L E                                ----                          COPYRIGHT (C) 2006                                ----                                                                            -------------------------------------------------------------------------------------- Title       : DCT1D-- Design      : MDCT Core-- Author      : Michal Krepa-------------------------------------------------------------------------------------- File        : DCT1D.VHD-- Created     : Sat Mar 5 7:37 2006--------------------------------------------------------------------------------------  Description : 1D Discrete Cosine Transform (1st stage)----------------------------------------------------------------------------------library IEEE;  use IEEE.STD_LOGIC_1164.all;  use IEEE.NUMERIC_STD.all; library WORK;  use WORK.MDCT_PKG.all;---------------------------------------------------------------------------------- ENTITY--------------------------------------------------------------------------------entity DCT1D is	 	port(	  		  clk          : in STD_LOGIC;  		  rst          : in std_logic;      dcti         : in std_logic_vector(IP_W-1 downto 0);      idv          : in STD_LOGIC;      romedatao    : in T_ROM1DATAO;      romodatao    : in T_ROM1DATAO;      odv          : out STD_LOGIC;      dcto         : out std_logic_vector(OP_W-1 downto 0);      romeaddro    : out T_ROM1ADDRO;      romoaddro    : out T_ROM1ADDRO;      ramwaddro    : out STD_LOGIC_VECTOR(RAMADRR_W-1 downto 0);      ramdatai     : out STD_LOGIC_VECTOR(RAMDATA_W-1 downto 0);      ramwe        : out STD_LOGIC;      wmemsel      : out STD_LOGIC				);end DCT1D;---------------------------------------------------------------------------------- ARCHITECTURE--------------------------------------------------------------------------------architecture RTL of DCT1D is       type INPUT_DATA is array (N-1 downto 0) of SIGNED(IP_W downto 0);    signal databuf_reg     : INPUT_DATA;  signal latchbuf_reg    : INPUT_DATA;  signal col_reg         : UNSIGNED(RAMADRR_W/2-1 downto 0);  signal row_reg         : UNSIGNED(RAMADRR_W/2-1 downto 0);  signal rowr_reg        : UNSIGNED(RAMADRR_W/2-1 downto 0);  signal inpcnt_reg      : UNSIGNED(RAMADRR_W/2-1 downto 0);  signal ramwe_s         : STD_LOGIC;  signal wmemsel_reg     : STD_LOGIC;	  signal stage2_reg      : STD_LOGIC;   signal stage2_cnt_reg  : UNSIGNED(RAMADRR_W-1 downto 0);   signal col_2_reg       : UNSIGNED(RAMADRR_W/2-1 downto 0);   signal ramwaddro_s     : STD_LOGIC_VECTOR(RAMADRR_W-1 downto 0);    signal even_not_odd    : std_logic;  signal even_not_odd_d1 : std_logic;  signal even_not_odd_d2 : std_logic;  signal even_not_odd_d3 : std_logic;  signal ramwe_d1        : STD_LOGIC;  signal ramwe_d2        : STD_LOGIC;  signal ramwe_d3        : STD_LOGIC;  signal ramwe_d4        : STD_LOGIC;  signal ramwaddro_d1    : STD_LOGIC_VECTOR(RAMADRR_W-1 downto 0);  signal ramwaddro_d2    : STD_LOGIC_VECTOR(RAMADRR_W-1 downto 0);  signal ramwaddro_d3    : STD_LOGIC_VECTOR(RAMADRR_W-1 downto 0);  signal ramwaddro_d4    : STD_LOGIC_VECTOR(RAMADRR_W-1 downto 0);  signal wmemsel_d1      : STD_LOGIC;  signal wmemsel_d2      : STD_LOGIC;  signal wmemsel_d3      : STD_LOGIC;  signal wmemsel_d4      : STD_LOGIC;  signal romedatao_d1    : T_ROM1DATAO;  signal romodatao_d1    : T_ROM1DATAO;  signal romedatao_d2    : T_ROM1DATAO;  signal romodatao_d2    : T_ROM1DATAO;  signal romedatao_d3    : T_ROM1DATAO;  signal romodatao_d3    : T_ROM1DATAO;  signal dcto_1          : STD_LOGIC_VECTOR(DA_W-1 downto 0);  signal dcto_2          : STD_LOGIC_VECTOR(DA_W-1 downto 0);  signal dcto_3          : STD_LOGIC_VECTOR(DA_W-1 downto 0);  signal dcto_4          : STD_LOGIC_VECTOR(DA_W-1 downto 0);  begin  ramwaddro <= ramwaddro_d4;  ramwe     <= ramwe_d4;  ramdatai  <= dcto_4(DA_W-1 downto 12);  wmemsel   <= wmemsel_d4;   process(clk,rst)  begin    if rst = '1' then      inpcnt_reg      <= (others => '0');      latchbuf_reg    <= (others => (others => '0'));       databuf_reg     <= (others => (others => '0'));      stage2_reg      <= '0';      stage2_cnt_reg  <= (others => '1');      ramwe_s         <= '0';      ramwaddro_s     <= (others => '0');      col_reg         <= (others => '0');      row_reg         <= (others => '0');      wmemsel_reg     <= '0';      col_2_reg       <= (others => '0');     elsif clk = '1' and clk'event then      stage2_reg     <= '0';      ramwe_s        <= '0';       --------------------------------      -- 1st stage      --------------------------------      if idv = '1' then              inpcnt_reg    <= inpcnt_reg + 1;        -- right shift input data        latchbuf_reg(N-2 downto 0) <= latchbuf_reg(N-1 downto 1);        latchbuf_reg(N-1)          <= SIGNED('0' & dcti) - LEVEL_SHIFT;        if inpcnt_reg = N-1 then          -- after this sum databuf_reg is in range of -256 to 254 (min to max)           databuf_reg(0)  <= latchbuf_reg(1)+(SIGNED('0' & dcti) - LEVEL_SHIFT);          databuf_reg(1)  <= latchbuf_reg(2)+latchbuf_reg(7);          databuf_reg(2)  <= latchbuf_reg(3)+latchbuf_reg(6);          databuf_reg(3)  <= latchbuf_reg(4)+latchbuf_reg(5);          databuf_reg(4)  <= latchbuf_reg(1)-(SIGNED('0' & dcti) - LEVEL_SHIFT);          databuf_reg(5)  <= latchbuf_reg(2)-latchbuf_reg(7);          databuf_reg(6)  <= latchbuf_reg(3)-latchbuf_reg(6);          databuf_reg(7)  <= latchbuf_reg(4)-latchbuf_reg(5);          stage2_reg      <= '1';        end if;      end if;      --------------------------------            --------------------------------      -- 2nd stage      --------------------------------      if stage2_cnt_reg < N then                stage2_cnt_reg <= stage2_cnt_reg + 1;                -- write RAM        ramwe_s   <= '1';        -- reverse col/row order for transposition purpose        ramwaddro_s <= STD_LOGIC_VECTOR(col_2_reg & row_reg);        -- increment column counter        col_reg   <= col_reg + 1;        col_2_reg <= col_2_reg + 1;                -- finished processing one input row        if col_reg = 0 then          row_reg         <= row_reg + 1;          -- switch to 2nd memory          if row_reg = N - 1 then            wmemsel_reg <= not wmemsel_reg;            col_reg         <= (others => '0');          end if;        end if;         end if;            if stage2_reg = '1' then        stage2_cnt_reg <= (others => '0');        col_reg        <= (0=>'1',others => '0');        col_2_reg      <= (others => '0');      end if;      ----------------------------------                   end if;  end process;    -- output data pipeline  p_data_out_pipe : process(CLK, RST)  begin    if RST = '1' then      even_not_odd    <= '0';      even_not_odd_d1 <= '0';      even_not_odd_d2 <= '0';      even_not_odd_d3 <= '0';      ramwe_d1        <= '0';      ramwe_d2        <= '0';      ramwe_d3        <= '0';      ramwe_d4        <= '0';      ramwaddro_d1    <= (others => '0');      ramwaddro_d2    <= (others => '0');      ramwaddro_d3    <= (others => '0');      ramwaddro_d4    <= (others => '0');      wmemsel_d1      <= '0';      wmemsel_d2      <= '0';      wmemsel_d3      <= '0';      wmemsel_d4      <= '0';      dcto_1          <= (others => '0');      dcto_2          <= (others => '0');      dcto_3          <= (others => '0');      dcto_4          <= (others => '0');    elsif CLK'event and CLK = '1' then      even_not_odd    <= stage2_cnt_reg(0);      even_not_odd_d1 <= even_not_odd;      even_not_odd_d2 <= even_not_odd_d1;      even_not_odd_d3 <= even_not_odd_d2;      ramwe_d1        <= ramwe_s;      ramwe_d2        <= ramwe_d1;      ramwe_d3        <= ramwe_d2;      ramwe_d4        <= ramwe_d3;      ramwaddro_d1    <= ramwaddro_s;      ramwaddro_d2    <= ramwaddro_d1;      ramwaddro_d3    <= ramwaddro_d2;      ramwaddro_d4    <= ramwaddro_d3;      wmemsel_d1      <= wmemsel_reg;      wmemsel_d2      <= wmemsel_d1;      wmemsel_d3      <= wmemsel_d2;      wmemsel_d4      <= wmemsel_d3;            if even_not_odd = '0' then        dcto_1 <= STD_LOGIC_VECTOR(RESIZE          (RESIZE(SIGNED(romedatao(0)),DA_W) +           (RESIZE(SIGNED(romedatao(1)),DA_W-1) & '0') +          (RESIZE(SIGNED(romedatao(2)),DA_W-2) & "00"),          DA_W));      else        dcto_1 <= STD_LOGIC_VECTOR(RESIZE          (RESIZE(SIGNED(romodatao(0)),DA_W) +           (RESIZE(SIGNED(romodatao(1)),DA_W-1) & '0') +          (RESIZE(SIGNED(romodatao(2)),DA_W-2) & "00"),          DA_W));      end if;            if even_not_odd_d1 = '0' then        dcto_2 <= STD_LOGIC_VECTOR(RESIZE          (signed(dcto_1) +          (RESIZE(SIGNED(romedatao_d1(3)),DA_W-3) & "000") +          (RESIZE(SIGNED(romedatao_d1(4)),DA_W-4) & "0000"),          DA_W));      else        dcto_2 <= STD_LOGIC_VECTOR(RESIZE          (signed(dcto_1) +           (RESIZE(SIGNED(romodatao_d1(3)),DA_W-3) & "000") +          (RESIZE(SIGNED(romodatao_d1(4)),DA_W-4) & "0000"),          DA_W));      end if;            if even_not_odd_d2 = '0' then        dcto_3 <= STD_LOGIC_VECTOR(RESIZE          (signed(dcto_2) +          (RESIZE(SIGNED(romedatao_d2(5)),DA_W-5) & "00000") +          (RESIZE(SIGNED(romedatao_d2(6)),DA_W-6) & "000000"),          DA_W));      else        dcto_3 <= STD_LOGIC_VECTOR(RESIZE          (signed(dcto_2) +           (RESIZE(SIGNED(romodatao_d2(5)),DA_W-5) & "00000") +          (RESIZE(SIGNED(romodatao_d2(6)),DA_W-6) & "000000"),          DA_W));      end if;            if even_not_odd_d3 = '0' then        dcto_4 <= STD_LOGIC_VECTOR(RESIZE          (signed(dcto_3) +          (RESIZE(SIGNED(romedatao_d3(7)),DA_W-7) & "0000000") -          (RESIZE(SIGNED(romedatao_d3(8)),DA_W-8) & "00000000"),          DA_W));      else        dcto_4 <= STD_LOGIC_VECTOR(RESIZE          (signed(dcto_3) +           (RESIZE(SIGNED(romodatao_d3(7)),DA_W-7) & "0000000") -          (RESIZE(SIGNED(romodatao_d3(8)),DA_W-8) & "00000000"),          DA_W));      end if;    end if;  end process;    -- read precomputed MAC results from LUT  p_romaddr : process(CLK, RST)  begin    if RST = '1' then      romeaddro   <= (others => (others => '0'));       romoaddro   <= (others => (others => '0'));     elsif CLK'event and CLK = '1' then      for i in 0 to 8 loop        -- even        romeaddro(i) <= STD_LOGIC_VECTOR(col_reg(RAMADRR_W/2-1 downto 1)) &                  databuf_reg(0)(i) &                  databuf_reg(1)(i) &                 databuf_reg(2)(i) &                 databuf_reg(3)(i);        -- odd        romoaddro(i) <= STD_LOGIC_VECTOR(col_reg(RAMADRR_W/2-1 downto 1)) &                  databuf_reg(4)(i) &                  databuf_reg(5)(i) &                 databuf_reg(6)(i) &                 databuf_reg(7)(i);      end loop;    end if;  end process;     p_romdatao_d1 : process(CLK, RST)  begin    if RST = '1' then      romedatao_d1    <= (others => (others => '0'));      romodatao_d1    <= (others => (others => '0'));      romedatao_d2    <= (others => (others => '0'));      romodatao_d2    <= (others => (others => '0'));      romedatao_d3    <= (others => (others => '0'));      romodatao_d3    <= (others => (others => '0'));    elsif CLK'event and CLK = '1' then      romedatao_d1   <= romedatao;      romodatao_d1   <= romodatao;      romedatao_d2   <= romedatao_d1;      romodatao_d2   <= romodatao_d1;      romedatao_d3   <= romedatao_d2;      romodatao_d3   <= romodatao_d2;    end if;  end process;  end RTL;--------------------------------------------------------------------------------

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