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[/] [openfpu64/] [trunk/] [fpu_mul.vhd] - Blame information for rev 6

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--------------------------------------------------------------------------------
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-- Project    : openFPU64 Multiplier Component
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-------------------------------------------------------------------------------
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-- File       : fpu_mul.vhd
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-- Author     : Peter Huewe  <peterhuewe@gmx.de>
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-- Created    : 2010-04-19
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-- Last update: 2010-04-19
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-- Standard   : VHDL'87
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-------------------------------------------------------------------------------
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-- Description: double precision floating point multiplier component
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--                     for openFPU64, includes rounding and normalization
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-- 
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-------------------------------------------------------------------------------
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-- Copyright (c) 2010 
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-------------------------------------------------------------------------------
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-- License: gplv3, see licence.txt
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-------------------------------------------------------------------------------
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library ieee;
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use ieee.std_logic_1164.all;
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use ieee.numeric_std.all;
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use work.fpu_package.all;
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-------------------------------------------------------------------------------
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entity fpu_mul is
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  port (
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    clk, reset_n           : in  std_logic;  -- reset = standard active low
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    cs                     : in  std_logic;  --  mode: 0 = add , 1= sub
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    sign_a, sign_b         : in  std_logic;  -- sign bits
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    exponent_a, exponent_b : in  std_logic_vector (11 downto 0);  -- exponents of the operands
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    mantissa_a, mantissa_b : in  std_logic_vector (57 downto 0);  -- mantissa of operands
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    sign_res               : out std_logic;
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    exponent_res           : out std_logic_vector(11 downto 0);
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    mantissa_res           : out std_logic_vector (57 downto 0);
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    rounding_needed        : out std_logic;
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    valid                  : out std_logic
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    );
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end fpu_mul;
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-------------------------------------------------------------------------------
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architecture rtl of fpu_mul is
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  -----------------------------------------------------------------------------
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  -- Internal signal declarations
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  -----------------------------------------------------------------------------
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-------------------------------------------------------------------------------
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-------------------------------------------------------------------------------
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  signal add_result, add_op_a : unsigned (54 downto 0);
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  signal add_op_b             : unsigned (12 downto 0);
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--  signal mul_result           : unsigned(35 downto 0);
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--  signal mul_op_a, mul_op_b   : unsigned(17 downto 0);
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  type t_state is (s_calc1, s_calc2, s_calc3, s_finished, s_normalize_right_1, s_load_for_round, s_round, s_load_normalizer_right_2, s_normalize_right_2, s_normalize_left);  -- possible states
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  signal state                : t_state;  -- current state
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  signal exponent_out : std_logic_vector(11 downto 0);
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  signal tmp_result   : std_logic_vector (57 downto 0);
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  signal tmp_result2  : std_logic_vector (107 downto 0);
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  signal a_is_normal, b_is_normal : std_logic;
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-----------------------------------------------------------------------------
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-- Component declarations
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-----------------------------------------------------------------------------
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begin
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----------------------------------------------------------------
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  -- Component instantiations
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  -----------------------------------------------------------------------------
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  -- purpose: calculates the result of a multiplication
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  -- type   : combinational
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  -- inputs : sign_a, sign_b, exponent_a, exponent_b, mantissa_a, mantissa_b
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  -- outputs: result
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  add_result  <= add_op_a + add_op_b;
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  a_is_normal <= '0' when unsigned(exponent_a(10 downto 0)) = ALL_ZEROS else '1';
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  b_is_normal <= '0' when unsigned(exponent_b(10 downto 0)) = ALL_ZEROS else '1';
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  state_trans : process (clk, reset_n, cs)
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    variable tmp : unsigned(57 downto 0);
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  begin  -- process state_trans
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    rounding_needed <= '1';
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    if reset_n = '0' then
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      state        <= s_calc1;
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      sign_res     <= '0';
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      valid        <= '0';
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      exponent_res <= (others => '0');
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      mantissa_res <= (others => '0');
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      tmp_result   <= (others => '0');
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      tmp_result2  <= (others => '0');
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      add_op_a     <= (others => '0');
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      add_op_b     <= (others => '0');
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    elsif rising_edge(clk) then
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      if cs = '0' then
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        state        <= s_calc1;
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        sign_res     <= '0';
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        valid        <= '0';
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        exponent_res <= (others => '0');
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        mantissa_res <= (others => '0');
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        tmp_result   <= (others => '0');
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        tmp_result2  <= (others => '0');
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        add_op_a     <= (others => '0');
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        add_op_b     <= (others => '0');
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      else
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        sign_res     <= sign_a xor sign_b;
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        valid        <= '0';
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        --    result       <= (others => '0');
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        exponent_res <= exponent_out(11 downto 0);
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        mantissa_res <= (others => '0');
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        mantissa_res <= tmp_result;
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        tmp_result   <= tmp_result;
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        tmp_result2  <= tmp_result2;
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        case state is
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          -- calculate new exponent and load multiplier
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          when s_calc1 =>
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            add_op_a              <= (others => '0');
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            add_op_b              <= (others => '0');
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            add_op_a(10 downto 0) <= unsigned(exponent_a(10 downto 0));
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            add_op_b(10 downto 0) <= unsigned(exponent_b(10 downto 0));
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            tmp_result2           <= std_logic_vector(unsigned(mantissa_a(56 downto 3)) * unsigned(mantissa_b(56 downto 3)));
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            state <= s_calc2;
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            -- check if one of the operands is zero
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            if (unsigned(exponent_a (10 downto 0)) = ZEROS(10 downto 0) and unsigned(mantissa_a (56 downto 3)) = ZEROS(56 downto 3))
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              or (unsigned(exponent_b (10 downto 0)) = ZEROS(10 downto 0) and unsigned(mantissa_b (56 downto 3)) = ZEROS(56 downto 3))
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            then
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              exponent_out <= (others => '0');
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              tmp_result   <= (others => '0');
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              state        <= s_finished;
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            end if;
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            -- Nan bu Nan :) is A NotANumber
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            if (unsigned(exponent_a (10 downto 0)) = ONES(10 downto 0) and unsigned(mantissa_a (56 downto 3)) /= ZEROS(56 downto 3))
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            then
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              exponent_out <= (others => '1');
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              tmp_result   <= mantissa_a;
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              state        <= s_finished;
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            end if;
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            -- is B NotANumber
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            if (unsigned(exponent_b (10 downto 0)) = ONES(10 downto 0) and unsigned(mantissa_b (56 downto 3)) /= ZEROS(56 downto 3))
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            then
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              exponent_out <= (others => '1');
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              tmp_result   <= mantissa_b;
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              state        <= s_finished;
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            end if;
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          -- calculate new exponent, part II, subtract bias
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          when s_calc2 =>
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            add_op_a (12 downto 0) <= '0'&add_result(11 downto 0);
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            add_op_b (12 downto 0) <= DOUBLE_BIAS_2COMPLEMENT(12 downto 0);
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            state <= s_calc3;
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          -- check if new exponent has to be zero, this happens if result is zero or subnormal
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          -- also select upper 57 bits of multiplication and generate stickybit of lower result
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          when s_calc3 =>
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            state <= s_load_for_round;
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            -- if lower bits != zero, sticky bit is 1
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            if (unsigned(tmp_result2(49 downto 0)) /= ZEROS(49 downto 0))
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            then
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              tmp_result <= std_logic_vector(tmp_result2(106 downto 50)) &'1';
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            else
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              tmp_result <= std_logic_vector(tmp_result2(106 downto 50)) &'0';
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            end if;
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            -- Is normalization needed?
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            if tmp_result2 (105) = '1' then
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              state <= s_normalize_right_1;
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            end if;
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            -- check if exponent is out of range
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            -- if it is in preload adder, maybe we need exponent +1 in next state
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            exponent_out <= std_logic_vector(add_result(11 downto 0));
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            add_op_a     <= (others => '0');
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            add_op_b     <= (others => '0');
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            add_op_a(11 downto 0) <= add_result(11 downto 0);
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            add_op_b(0)           <= '1';
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            -- overflow
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            if (add_result(12) = '0' and add_result(11) = '1')
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            then
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              exponent_out <= (others => '1');
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              tmp_result   <= (others => '0');
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              state        <= s_finished;
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            end if;
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            -- lower than subnormal - underflow to zero
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            if (add_result(12) = '1')
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              --and (a_is_normal = '0' or b_is_normal = '0'))
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              or (a_is_normal = '0' and b_is_normal = '0')
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            then
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              exponent_out <= (others => '0');
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              add_op_a     <= (others => '0');
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              add_op_b     <= (others => '0');
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              add_op_b(0)  <= '1';
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              tmp_result   <= (others => '0');
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              state        <= s_finished;
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            else
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            end if;
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          --Normalization is necessary
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          when s_normalize_right_1=>
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            tmp_result(57 downto 1) <= '0'&tmp_result(57 downto 2);
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            tmp_result(0)           <= tmp_result(1) or tmp_result(0);
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            exponent_out            <= std_logic_vector(add_result(11 downto 0));
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            state <= s_load_for_round;
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          -- preload adder with mantissa and 1, maybe we need this for rounding next step
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          when s_load_for_round =>
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            add_op_a    <= unsigned(tmp_result(57 downto 3));
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            add_op_b    <= (others => '0');
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            add_op_b(0) <= '1';
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            state       <= s_normalize_left;
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          -- shift leading one to correct position
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          when s_normalize_left=>
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            state <= s_round;
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            if tmp_result(55) = '0' and unsigned(exponent_out(11 downto 0)) /= ZEROS(11 downto 0)
223
            then
224
              tmp_result(55 downto 0) <= tmp_result(54 downto 0) & tmp_result(0);
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              exponent_out            <= std_logic_vector(unsigned(exponent_out) - "1");
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              state                   <= s_normalize_left;
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            end if;
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          --round if necessary
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          when s_round=>
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            case tmp_result(3 downto 0) is
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              when "0101" => tmp_result(3) <= '1';
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              when "0110" => tmp_result(3) <= '1';
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              when "0111" => tmp_result(3) <= '1';
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              when "1100" => tmp_result(57 downto 3) <= std_logic_vector(add_result);
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              when "1101" => tmp_result(57 downto 3) <= std_logic_vector(add_result);
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              when "1110" => tmp_result(57 downto 3) <= std_logic_vector(add_result);
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              when "1111" => tmp_result(57 downto 3) <= std_logic_vector(add_result);
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241
              when others => null;      -- others remain unchanged
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            end case;
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            state <= s_load_normalizer_right_2;
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          -- Check again if Normalization needed, preload adder
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          when s_load_normalizer_right_2=>
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            add_op_a              <= (others => '0');
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            add_op_b              <= (others => '0');
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            add_op_a(11 downto 0) <= unsigned(exponent_out(11 downto 0));
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            add_op_b(0)           <= '1';
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            state <= s_finished;
256
            if tmp_result(56) = '1' then
257
              state <= s_normalize_right_2;
258
            end if;
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260
 
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          -- .Normalize
262
          when s_normalize_right_2=>
263
            tmp_result(57 downto 1) <= '0'&tmp_result(57 downto 2);
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            tmp_result(0)           <= tmp_result(1) or tmp_result(0);
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            exponent_out            <= std_logic_vector(add_result(11 downto 0));
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            state                   <= s_finished;
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          -- finished  
270
          when s_finished =>
271
            state <= s_finished;
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            valid <= '1';
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274
          when others => null;
275
        end case;
276
      end if;
277
    end if;
278
  end process state_trans;
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end rtl;
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-------------------------------------------------------------------------------

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