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[/] [mdct/] [trunk/] [source/] [DCT1D.vhd] - Rev 10
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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; romedatao0 : in STD_LOGIC_VECTOR(ROMDATA_W-1 downto 0); romedatao1 : in STD_LOGIC_VECTOR(ROMDATA_W-1 downto 0); romedatao2 : in STD_LOGIC_VECTOR(ROMDATA_W-1 downto 0); romedatao3 : in STD_LOGIC_VECTOR(ROMDATA_W-1 downto 0); romedatao4 : in STD_LOGIC_VECTOR(ROMDATA_W-1 downto 0); romedatao5 : in STD_LOGIC_VECTOR(ROMDATA_W-1 downto 0); romedatao6 : in STD_LOGIC_VECTOR(ROMDATA_W-1 downto 0); romedatao7 : in STD_LOGIC_VECTOR(ROMDATA_W-1 downto 0); romedatao8 : in STD_LOGIC_VECTOR(ROMDATA_W-1 downto 0); romodatao0 : in STD_LOGIC_VECTOR(ROMDATA_W-1 downto 0); romodatao1 : in STD_LOGIC_VECTOR(ROMDATA_W-1 downto 0); romodatao2 : in STD_LOGIC_VECTOR(ROMDATA_W-1 downto 0); romodatao3 : in STD_LOGIC_VECTOR(ROMDATA_W-1 downto 0); romodatao4 : in STD_LOGIC_VECTOR(ROMDATA_W-1 downto 0); romodatao5 : in STD_LOGIC_VECTOR(ROMDATA_W-1 downto 0); romodatao6 : in STD_LOGIC_VECTOR(ROMDATA_W-1 downto 0); romodatao7 : in STD_LOGIC_VECTOR(ROMDATA_W-1 downto 0); romodatao8 : in STD_LOGIC_VECTOR(ROMDATA_W-1 downto 0); reqwrfail : in STD_LOGIC; ready : out STD_LOGIC; -- read from FIFO odv : out STD_LOGIC; dcto : out std_logic_vector(OP_W-1 downto 0); romeaddro0 : out STD_LOGIC_VECTOR(ROMADDR_W-1 downto 0); romeaddro1 : out STD_LOGIC_VECTOR(ROMADDR_W-1 downto 0); romeaddro2 : out STD_LOGIC_VECTOR(ROMADDR_W-1 downto 0); romeaddro3 : out STD_LOGIC_VECTOR(ROMADDR_W-1 downto 0); romeaddro4 : out STD_LOGIC_VECTOR(ROMADDR_W-1 downto 0); romeaddro5 : out STD_LOGIC_VECTOR(ROMADDR_W-1 downto 0); romeaddro6 : out STD_LOGIC_VECTOR(ROMADDR_W-1 downto 0); romeaddro7 : out STD_LOGIC_VECTOR(ROMADDR_W-1 downto 0); romeaddro8 : out STD_LOGIC_VECTOR(ROMADDR_W-1 downto 0); romoaddro0 : out STD_LOGIC_VECTOR(ROMADDR_W-1 downto 0); romoaddro1 : out STD_LOGIC_VECTOR(ROMADDR_W-1 downto 0); romoaddro2 : out STD_LOGIC_VECTOR(ROMADDR_W-1 downto 0); romoaddro3 : out STD_LOGIC_VECTOR(ROMADDR_W-1 downto 0); romoaddro4 : out STD_LOGIC_VECTOR(ROMADDR_W-1 downto 0); romoaddro5 : out STD_LOGIC_VECTOR(ROMADDR_W-1 downto 0); romoaddro6 : out STD_LOGIC_VECTOR(ROMADDR_W-1 downto 0); romoaddro7 : out STD_LOGIC_VECTOR(ROMADDR_W-1 downto 0); romoaddro8 : out STD_LOGIC_VECTOR(ROMADDR_W-1 downto 0); ramwaddro : out STD_LOGIC_VECTOR(RAMADRR_W-1 downto 0); ramdatai : out STD_LOGIC_VECTOR(RAMDATA_W-1 downto 0); ramwe : out STD_LOGIC; requestwr : out STD_LOGIC; releasewr : out STD_LOGIC ); end DCT1D; -------------------------------------------------------------------------------- -- ARCHITECTURE -------------------------------------------------------------------------------- architecture RTL of DCT1D is type STATE_T is ( MEMREQ, IDLE, GET_ROM, SUM, WRITE_ODD ); type ISTATE_T is ( ACQUIRE_1ROW ); type INPUT_DATA is array (N-1 downto 0) of SIGNED(IP_W downto 0); signal ready_reg : STD_LOGIC; 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 inpcnt_reg : UNSIGNED(2 downto 0); signal state_reg : STATE_T; signal istate_reg : ISTATE_T; signal cnt_reg : UNSIGNED(3 downto 0); signal ramdatai_s : STD_LOGIC_VECTOR(RAMDATA_W-1 downto 0); signal ramwe_s : STD_LOGIC; signal latch_done_reg : STD_LOGIC; signal requestwr_reg : STD_LOGIC; signal releasewr_reg : STD_LOGIC; signal col_tmp_reg : UNSIGNED(RAMADRR_W/2-1 downto 0); begin ready_sg: ready <= ready_reg; ramwe_sg: ramwe <= ramwe_s; ramdatai_sg: ramdatai <= ramdatai_s; -- temporary odv_sg: odv <= ramwe_s; dcto_sg: dcto <= ramdatai_s(RAMDATA_W-1) & ramdatai_s(RAMDATA_W-1) & ramdatai_s; releasewr_sg: releasewr <= releasewr_reg; requestwr_sg: requestwr <= requestwr_reg; -------------------------------------- -- PROCESS -------------------------------------- GET_PROC : process(rst,clk) begin if rst = '1' then inpcnt_reg <= (others => '0'); ready_reg <= '0'; latchbuf_reg <= (others => (others => '0')); latch_done_reg <= '0'; elsif clk = '1' and clk'event then if latch_done_reg = '0' or (state_reg = IDLE and reqwrfail = '0') then -- wait until DCT1D_PROC process 1D DCT computation -- before latching new 8 input words if state_reg = IDLE and reqwrfail = '0' then latch_done_reg <= '0'; end if; if idv = '1' then -- read next data from input FIFO ready_reg <= '1'; if ready_reg = '1' then -- 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; inpcnt_reg <= inpcnt_reg + 1; if inpcnt_reg = N-1 then latch_done_reg <= '1'; ready_reg <= '0'; end if; end if; else ready_reg <= '0'; end if; end if; end if; end process; -------------------------------------- -- PROCESS -------------------------------------- DCT1D_PROC: process(rst, clk) begin if rst = '1' then col_reg <= (others => '0'); row_reg <= (others => '0'); state_reg <= MEMREQ; cnt_reg <= (others => '0'); databuf_reg <= (others => (others => '0')); ramwaddro <= (others => '0'); ramdatai_s <= (others => '0'); ramwe_s <= '0'; releasewr_reg <= '0'; col_tmp_reg <= (others => '0'); requestwr_reg <= '0'; elsif rising_edge(clk) then case state_reg is when MEMREQ => ramwe_s <= '0'; -- release memory fully written releasewr_reg <= '0'; -- request free memory for writing requestwr_reg <= '1'; -- DBUFCTL 1T delay if requestwr_reg = '1' then requestwr_reg <= '0'; state_reg <= IDLE; end if; ---------------------- -- wait for input data ---------------------- when IDLE => ramwe_s <= '0'; -- failure to allocate any memory buffer if reqwrfail = '1' then -- restart allocation procedure state_reg <= MEMREQ; -- wait until 8 input words are latched in latchbuf_reg -- by GET_PROC elsif latch_done_reg = '1' then -- after this sum databuf_reg is in range of -256 to 254 (min to max) databuf_reg(0) <= latchbuf_reg(0)+latchbuf_reg(7); databuf_reg(1) <= latchbuf_reg(1)+latchbuf_reg(6); databuf_reg(2) <= latchbuf_reg(2)+latchbuf_reg(5); databuf_reg(3) <= latchbuf_reg(3)+latchbuf_reg(4); databuf_reg(4) <= latchbuf_reg(0)-latchbuf_reg(7); databuf_reg(5) <= latchbuf_reg(1)-latchbuf_reg(6); databuf_reg(6) <= latchbuf_reg(2)-latchbuf_reg(5); databuf_reg(7) <= latchbuf_reg(3)-latchbuf_reg(4); state_reg <= GET_ROM; end if; ---------------------- -- get MAC results from ROM even and ROM odd memories ---------------------- when GET_ROM => ramwe_s <='0'; state_reg <= SUM; --------------------- -- do distributed arithmetic sum on even part, -- write even part to RAM --------------------- when SUM => ramdatai_s <= STD_LOGIC_VECTOR(RESIZE (RESIZE(SIGNED(romedatao0),DA_W) + (RESIZE(SIGNED(romedatao1),DA_W-1) & '0') + (RESIZE(SIGNED(romedatao2),DA_W-2) & "00") + (RESIZE(SIGNED(romedatao3),DA_W-3) & "000") + (RESIZE(SIGNED(romedatao4),DA_W-4) & "0000") + (RESIZE(SIGNED(romedatao5),DA_W-5) & "00000") + (RESIZE(SIGNED(romedatao6),DA_W-6) & "000000") + (RESIZE(SIGNED(romedatao7),DA_W-7) & "0000000") - (RESIZE(SIGNED(romedatao8),DA_W-8) & "00000000"),DA_W)(DA_W-1 downto 12)); -- write even part ramwe_s <= '1'; -- reverse col/row order for transposition purpose ramwaddro <= STD_LOGIC_VECTOR(col_reg & row_reg); col_reg <= col_reg + 1; col_tmp_reg <= col_reg + 2; state_reg <= WRITE_ODD; --------------------- -- do distributed arithmetic sum on odd part, -- write odd part to RAM --------------------- when WRITE_ODD => -- write odd part --ramwe_s <= '1'; ramdatai_s <= STD_LOGIC_VECTOR(RESIZE (RESIZE(SIGNED(romodatao0),DA_W) + (RESIZE(SIGNED(romodatao1),DA_W-1) & '0') + (RESIZE(SIGNED(romodatao2),DA_W-2) & "00") + (RESIZE(SIGNED(romodatao3),DA_W-3) & "000") + (RESIZE(SIGNED(romodatao4),DA_W-4) & "0000") + (RESIZE(SIGNED(romodatao5),DA_W-5) & "00000") + (RESIZE(SIGNED(romodatao6),DA_W-6) & "000000") + (RESIZE(SIGNED(romodatao7),DA_W-7) & "0000000") - (RESIZE(SIGNED(romodatao8),DA_W-8) & "00000000"), DA_W)(DA_W-1 downto 12)); -- write odd part -- reverse col/row order for transposition purpose ramwaddro <= STD_LOGIC_VECTOR(col_reg & row_reg); -- move to next column col_reg <= col_reg + 1; col_tmp_reg <= col_reg + 1; -- finished processing one input row if col_reg = N - 1 then row_reg <= row_reg + 1; col_reg <= (others => '0'); col_tmp_reg <= (others => '0'); if row_reg = N - 1 then releasewr_reg <= '1'; state_reg <= MEMREQ; else state_reg <= IDLE; end if; else state_reg <= SUM; end if; -------------------------------- -- OTHERS -------------------------------- when others => state_reg <= IDLE; end case; end if; end process; -- read precomputed MAC results from LUT romeaddro0 <= STD_LOGIC_VECTOR(col_tmp_reg(RAMADRR_W/2-1 downto 1)) & databuf_reg(0)(0) & databuf_reg(1)(0) & databuf_reg(2)(0) & databuf_reg(3)(0); romeaddro1 <= STD_LOGIC_VECTOR(col_tmp_reg(RAMADRR_W/2-1 downto 1)) & databuf_reg(0)(1) & databuf_reg(1)(1) & databuf_reg(2)(1) & databuf_reg(3)(1); romeaddro2 <= STD_LOGIC_VECTOR(col_tmp_reg(RAMADRR_W/2-1 downto 1)) & databuf_reg(0)(2) & databuf_reg(1)(2) & databuf_reg(2)(2) & databuf_reg(3)(2); romeaddro3 <= STD_LOGIC_VECTOR(col_tmp_reg(RAMADRR_W/2-1 downto 1)) & databuf_reg(0)(3) & databuf_reg(1)(3) & databuf_reg(2)(3) & databuf_reg(3)(3); romeaddro4 <= STD_LOGIC_VECTOR(col_tmp_reg(RAMADRR_W/2-1 downto 1)) & databuf_reg(0)(4) & databuf_reg(1)(4) & databuf_reg(2)(4) & databuf_reg(3)(4); romeaddro5 <= STD_LOGIC_VECTOR(col_tmp_reg(RAMADRR_W/2-1 downto 1)) & databuf_reg(0)(5) & databuf_reg(1)(5) & databuf_reg(2)(5) & databuf_reg(3)(5); romeaddro6 <= STD_LOGIC_VECTOR(col_tmp_reg(RAMADRR_W/2-1 downto 1)) & databuf_reg(0)(6) & databuf_reg(1)(6) & databuf_reg(2)(6) & databuf_reg(3)(6); romeaddro7 <= STD_LOGIC_VECTOR(col_tmp_reg(RAMADRR_W/2-1 downto 1)) & databuf_reg(0)(7) & databuf_reg(1)(7) & databuf_reg(2)(7) & databuf_reg(3)(7); romeaddro8 <= STD_LOGIC_VECTOR(col_tmp_reg(RAMADRR_W/2-1 downto 1)) & databuf_reg(0)(8) & databuf_reg(1)(8) & databuf_reg(2)(8) & databuf_reg(3)(8); -- odd romoaddro0 <= STD_LOGIC_VECTOR(col_reg(RAMADRR_W/2-1 downto 1)) & databuf_reg(4)(0) & databuf_reg(5)(0) & databuf_reg(6)(0) & databuf_reg(7)(0); romoaddro1 <= STD_LOGIC_VECTOR(col_reg(RAMADRR_W/2-1 downto 1)) & databuf_reg(4)(1) & databuf_reg(5)(1) & databuf_reg(6)(1) & databuf_reg(7)(1); romoaddro2 <= STD_LOGIC_VECTOR(col_reg(RAMADRR_W/2-1 downto 1)) & databuf_reg(4)(2) & databuf_reg(5)(2) & databuf_reg(6)(2) & databuf_reg(7)(2); romoaddro3 <= STD_LOGIC_VECTOR(col_reg(RAMADRR_W/2-1 downto 1)) & databuf_reg(4)(3) & databuf_reg(5)(3) & databuf_reg(6)(3) & databuf_reg(7)(3); romoaddro4 <= STD_LOGIC_VECTOR(col_reg(RAMADRR_W/2-1 downto 1)) & databuf_reg(4)(4) & databuf_reg(5)(4) & databuf_reg(6)(4) & databuf_reg(7)(4); romoaddro5 <= STD_LOGIC_VECTOR(col_reg(RAMADRR_W/2-1 downto 1)) & databuf_reg(4)(5) & databuf_reg(5)(5) & databuf_reg(6)(5) & databuf_reg(7)(5); romoaddro6 <= STD_LOGIC_VECTOR(col_reg(RAMADRR_W/2-1 downto 1)) & databuf_reg(4)(6) & databuf_reg(5)(6) & databuf_reg(6)(6) & databuf_reg(7)(6); romoaddro7 <= STD_LOGIC_VECTOR(col_reg(RAMADRR_W/2-1 downto 1)) & databuf_reg(4)(7) & databuf_reg(5)(7) & databuf_reg(6)(7) & databuf_reg(7)(7); romoaddro8 <= STD_LOGIC_VECTOR(col_reg(RAMADRR_W/2-1 downto 1)) & databuf_reg(4)(8) & databuf_reg(5)(8) & databuf_reg(6)(8) & databuf_reg(7)(8); end RTL; --------------------------------------------------------------------------------
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