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[/] [fpu_double/] [trunk/] [fpu_mul.vhd] - Rev 13
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--------------------------------------------------------------------- ---- ---- ---- FPU ---- ---- Floating Point Unit (Double precision) ---- ---- ---- ---- Author: David Lundgren ---- ---- davidklun@gmail.com ---- ---- ---- --------------------------------------------------------------------- ---- ---- ---- Copyright (C) 2009 David Lundgren ---- ---- davidklun@gmail.com ---- ---- ---- ---- This source file may be used and distributed without ---- ---- restriction provided that this copyright statement is not ---- ---- removed from the file and that any derivative work contains ---- ---- the original copyright notice and the associated disclaimer.---- ---- ---- ---- THIS SOFTWARE IS PROVIDED ``AS IS'' AND WITHOUT ANY ---- ---- EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED ---- ---- TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS ---- ---- FOR A PARTICULAR PURPOSE. IN NO EVENT SHALL THE AUTHOR ---- ---- OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, ---- ---- INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES ---- ---- (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE ---- ---- GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR ---- ---- BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF ---- ---- LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT ---- ---- (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT ---- ---- OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE ---- ---- POSSIBILITY OF SUCH DAMAGE. ---- ---- ---- --------------------------------------------------------------------- LIBRARY ieee; USE ieee.std_logic_1164.all; USE ieee.std_logic_arith.all; use ieee.std_logic_unsigned.all; use ieee.std_logic_misc.all; library work; use work.fpupack.all; ENTITY fpu_mul IS PORT( clk : IN std_logic; rst : IN std_logic; enable : IN std_logic; opa : IN std_logic_vector (63 DOWNTO 0); opb : IN std_logic_vector (63 DOWNTO 0); sign : OUT std_logic; product_7 : OUT std_logic_vector (55 DOWNTO 0); exponent_5 : OUT std_logic_vector (11 DOWNTO 0) ); END fpu_mul; architecture rtl of fpu_mul is signal product_shift : std_logic_vector(5 downto 0); signal product_shift_2 : std_logic_vector(5 downto 0); signal mantissa_a : std_logic_vector(51 downto 0); signal mantissa_b : std_logic_vector(51 downto 0); signal exponent_a : std_logic_vector(11 downto 0); signal exponent_b : std_logic_vector(11 downto 0); signal a_is_norm : std_logic; signal b_is_norm : std_logic; signal a_is_zero : std_logic; signal b_is_zero : std_logic; signal in_zero : std_logic; signal exponent_terms : std_logic_vector(11 downto 0); signal exponent_gt_expoffset : std_logic; signal exponent_under : std_logic_vector(11 downto 0); signal exponent_1 : std_logic_vector(11 downto 0); signal exponent : std_logic_vector(11 downto 0); signal exponent_2 : std_logic_vector(11 downto 0); signal exponent_gt_prodshift : std_logic; signal exponent_3 : std_logic_vector(11 downto 0); signal exponent_4 : std_logic_vector(11 downto 0); signal exponent_et_zero : std_logic; signal mul_a : std_logic_vector(52 downto 0); signal mul_b : std_logic_vector(52 downto 0); signal product_a : std_logic_vector(40 downto 0); signal product_b : std_logic_vector(40 downto 0); signal product_c : std_logic_vector(40 downto 0); signal product_d : std_logic_vector(25 downto 0); signal product_e : std_logic_vector(33 downto 0); signal product_f : std_logic_vector(33 downto 0); signal product_g : std_logic_vector(35 downto 0); signal product_h : std_logic_vector(28 downto 0); signal product_i : std_logic_vector(28 downto 0); signal product_j : std_logic_vector(30 downto 0); signal sum_0 : std_logic_vector(41 downto 0); signal sum_1 : std_logic_vector(35 downto 0); signal sum_2 : std_logic_vector(41 downto 0); signal sum_3 : std_logic_vector(35 downto 0); signal sum_4 : std_logic_vector(36 downto 0); signal sum_5 : std_logic_vector(27 downto 0); signal sum_6 : std_logic_vector(29 downto 0); signal sum_7 : std_logic_vector(36 downto 0); signal sum_8 : std_logic_vector(30 downto 0); signal product : std_logic_vector(105 downto 0); signal product_1 : std_logic_vector(105 downto 0); signal product_2 : std_logic_vector(105 downto 0); signal product_3 : std_logic_vector(105 downto 0); signal product_4 : std_logic_vector(105 downto 0); signal product_5 : std_logic_vector(105 downto 0); signal product_6 : std_logic_vector(105 downto 0); signal product_lsb : std_logic; begin product_7 <= '0' & product_6(105 downto 52) & product_lsb; exponent <= "000000000000"; process begin wait until clk'event and clk = '1'; if (rst = '1') then sign <= '0'; mantissa_a <= (others =>'0'); mantissa_b <= (others =>'0'); exponent_a <= (others =>'0'); exponent_b <= (others =>'0'); a_is_norm <= '0'; b_is_norm <= '0'; a_is_zero <= '0'; b_is_zero <= '0'; in_zero <= '0'; exponent_terms <= (others =>'0'); exponent_gt_expoffset <= '0'; exponent_under <= (others =>'0'); exponent_1 <= (others =>'0'); exponent_2 <= (others =>'0'); exponent_gt_prodshift <= '0'; exponent_3 <= (others =>'0'); exponent_4 <= (others =>'0'); exponent_et_zero <= '0'; mul_a <= (others =>'0'); mul_b <= (others =>'0'); product_a <= (others =>'0'); product_b <= (others =>'0'); product_c <= (others =>'0'); product_d <= (others =>'0'); product_e <= (others =>'0'); product_f <= (others =>'0'); product_g <= (others =>'0'); product_h <= (others =>'0'); product_i <= (others =>'0'); product_j <= (others =>'0'); sum_0 <= (others =>'0'); sum_1 <= (others =>'0'); sum_2 <= (others =>'0'); sum_3 <= (others =>'0'); sum_4 <= (others =>'0'); sum_5 <= (others =>'0'); sum_6 <= (others =>'0'); sum_7 <= (others =>'0'); sum_8 <= (others =>'0'); product <= (others =>'0'); product_1 <= (others =>'0'); product_2 <= (others =>'0'); product_3 <= (others =>'0'); product_4 <= (others =>'0'); product_5 <= (others =>'0'); product_6 <= (others =>'0'); product_lsb <= '0'; exponent_5 <= (others =>'0'); product_shift <= (others =>'0'); product_shift_2 <= (others =>'0'); elsif (enable = '1') then sign <= opa(63) xor opb(63); exponent_a <= '0' & opa(62 downto 52); exponent_b <= '0' & opb(62 downto 52); mantissa_a <= opa(51 downto 0); mantissa_b <= opb(51 downto 0); a_is_norm <= or_reduce(exponent_a); b_is_norm <= or_reduce(exponent_b); a_is_zero <= not or_reduce(opa(62 downto 0)); b_is_zero <= not or_reduce(opb(62 downto 0)); in_zero <= a_is_zero or b_is_zero; exponent_terms <= exponent_a + exponent_b + ( "0000000000" & not a_is_norm) + ("0000000000" & not b_is_norm); if (exponent_terms > "001111111101") then exponent_gt_expoffset <= '1'; else exponent_gt_expoffset <= '0'; end if; exponent_under <= "001111111110" - exponent_terms; exponent_1 <= exponent_terms - "001111111110"; if (exponent_gt_expoffset = '1') then exponent_2 <= exponent_1; else exponent_2 <= exponent; end if; if (exponent_2 > product_shift_2) then exponent_gt_prodshift <= '1'; else exponent_gt_prodshift <= '0'; end if; exponent_3 <= exponent_2 - product_shift_2; if (exponent_gt_prodshift = '1') then exponent_4 <= exponent_3; else exponent_4 <= exponent; end if; if (exponent_4 = "000000000000") then exponent_et_zero <= '1'; else exponent_et_zero <= '0'; end if; mul_a <= a_is_norm & mantissa_a; mul_b <= b_is_norm & mantissa_b; product_a <= mul_a(23 downto 0) * mul_b(16 downto 0); product_b <= mul_a(23 downto 0) * mul_b(33 downto 17); product_c <= mul_a(23 downto 0) * mul_b(50 downto 34); product_d <= mul_a(23 downto 0) * mul_b(52 downto 51); product_e <= mul_a(40 downto 24) * mul_b(16 downto 0); product_f <= mul_a(40 downto 24) * mul_b(33 downto 17); product_g <= mul_a(40 downto 24) * mul_b(52 downto 34); product_h <= mul_a(52 downto 41) * mul_b(16 downto 0); product_i <= mul_a(52 downto 41) * mul_b(33 downto 17); product_j <= mul_a(52 downto 41) * mul_b(52 downto 34); sum_0 <= product_a(40 downto 17) + ( '0' & product_b); sum_1 <= ('0' & sum_0(41 downto 7)) + product_e; sum_2 <= sum_1(35 downto 10) + ('0' & product_c); sum_3 <= ( '0' & sum_2(41 downto 7)) + product_h; sum_4 <= ( '0' & sum_3) + product_f; sum_5 <= ('0' & sum_4(36 downto 10)) + product_d; sum_6 <= sum_5(27 downto 7) + ('0' & product_i); sum_7 <= sum_6 + ('0' & product_g); sum_8 <= sum_7(36 downto 17) + product_j; product <= sum_8 & sum_7(16 downto 0) & sum_5(6 downto 0) & sum_4(9 downto 0) & sum_2(6 downto 0) & sum_1(9 downto 0) & sum_0(6 downto 0) & product_a(16 downto 0); product_1 <= shr(product, exponent_under); if (exponent_gt_prodshift = '1') then product_5 <= product_3; else product_5 <= product_4; end if; if (exponent_gt_expoffset = '1') then product_2 <= product; else product_2 <= product_1; end if; product_3 <= shl(product_2, product_shift_2); product_4 <= shl(product_2, exponent_2); if (exponent_gt_prodshift = '1') then product_5 <= product_3; else product_5 <= product_4; end if; if (exponent_et_zero = '1') then product_6 <= shr(product_5, conv_std_logic_vector('1', 106)); else product_6 <= product_5; end if; product_lsb <= or_reduce(product_6(51 downto 0)); if (in_zero = '1') then exponent_5 <= "000000000000"; else exponent_5 <= exponent_4; end if; product_shift <= count_zeros_mul(product(105 downto 0)); product_shift_2 <= product_shift; end if; end process; end rtl;
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