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float_synth.vhdl
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float_synth.vhdl
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-------------------------------------------------------------------------------
-- Synthesis test for the floating point math package
-- This test is designed to be synthesizable and exercise much of the package.
-- Created for vhdl-200x by David Bishop ([email protected])
-- --------------------------------------------------------------------
-- modification history : Last Modified $Date: 2006-06-08 10:50:32-04 $
-- Version $Id: float_synth.vhdl,v 1.1 2006-06-08 10:50:32-04 l435385 Exp $
-------------------------------------------------------------------------------
library ieee, ieee_proposed;
use ieee.std_logic_1164.all;
use ieee.numeric_std.all;
use ieee_proposed.fixed_float_types.all;
use ieee_proposed.fixed_pkg.all;
use ieee_proposed.float_pkg.all;
use ieee.math_real.all;
entity float_synth is
port (
in1, in2 : in std_logic_vector (31 downto 0); -- inputs
out1 : out std_logic_vector (31 downto 0); -- output
cmd : in std_logic_vector (3 downto 0);
clk, rst_n : in std_ulogic); -- clk and reset
end entity float_synth;
architecture rtl of float_synth is
subtype fp16 is float (6 downto -9); -- 16 bit
type cmd_type is array (1 to 15) of std_ulogic_vector (cmd'range); -- cmd
signal cmdarray : cmd_type; -- command pipeline
type cry_type is array (0 to 15) of float32; -- arrays
signal outx : cry_type;
signal in1reg3, in2reg3 : float32; -- register stages
begin -- architecture rtl
-- purpose: "0000" test the "+" operator
cmd0reg: process (clk, rst_n) is
variable outarray : cry_type; -- array for output
begin -- process cmd0reg
if rst_n = '0' then -- asynchronous reset (active low)
outx(0) <= ( others => '0');
jrloop: for j in 0 to 7 loop
outarray (j) := (others => '0');
end loop jrloop;
elsif rising_edge(clk) then -- rising clock edge
outx(0) <= outarray(7);
jcloop: for j in 7 downto 1 loop
outarray (j) := outarray(j-1);
end loop jcloop;
outarray(0) := in1reg3 + in2reg3;
end if;
end process cmd0reg;
-- purpose: "0001" test the "-" operator
cmd1reg: process (clk, rst_n) is
variable outarray : cry_type; -- array for output
begin -- process cmd1reg
if rst_n = '0' then -- asynchronous reset (active low)
outx(1) <= ( others => '0');
jrloop: for j in 0 to 7 loop
outarray (j) := (others => '0');
end loop jrloop;
elsif rising_edge(clk) then -- rising clock edge
outx(1) <= outarray(7);
jcloop: for j in 7 downto 1 loop
outarray (j) := outarray(j-1);
end loop jcloop;
outarray(0) := in1reg3 - in2reg3;
end if;
end process cmd1reg;
-- purpose: "0010" test the "*" operator
cmd2reg: process (clk, rst_n) is
variable outarray : cry_type; -- array for output
begin -- process cmd2reg
if rst_n = '0' then -- asynchronous reset (active low)
outx(2) <= ( others => '0');
jrloop: for j in 0 to 7 loop
outarray (j) := (others => '0');
end loop jrloop;
elsif rising_edge(clk) then -- rising clock edge
outx(2) <= outarray(7);
jcloop: for j in 7 downto 1 loop
outarray (j) := outarray(j-1);
end loop jcloop;
outarray(0) := in1reg3 * in2reg3;
end if;
end process cmd2reg;
-- purpose: "0011" performs test the "/" operator
cmd3reg: process (clk, rst_n) is
variable outarray : cry_type; -- array for output
begin -- process cmd1reg
if rst_n = '0' then -- asynchronous reset (active low)
outx(3) <= ( others => '0');
jrloop: for j in 0 to 7 loop
outarray (j) := (others => '0');
end loop jrloop;
elsif rising_edge(clk) then -- rising clock edge
outx(3) <= outarray(7);
jcloop: for j in 7 downto 1 loop
outarray (j) := outarray(j-1);
end loop jcloop;
if (cmdarray(4) = "0011") then
outarray(0) := in1reg3 / in2reg3;
else
outarray(0) := (others => '0');
end if;
end if;
end process cmd3reg;
-- purpose: "0100" test the "resize" function
cmd4reg: process (clk, rst_n) is
variable tmpfp161, tmpfp162 : fp16; -- 16 bit fp number
variable outarray : cry_type; -- array for output
variable tmpcmd : STD_LOGIC_VECTOR (2 downto 0);
begin -- process cmd1reg
if rst_n = '0' then -- asynchronous reset (active low)
outx(4) <= ( others => '0');
jrloop: for j in 0 to 7 loop
outarray (j) := (others => '0');
end loop jrloop;
elsif rising_edge(clk) then -- rising clock edge
outx(4) <= outarray(7);
jcloop: for j in 7 downto 1 loop
outarray (j) := outarray(j-1);
end loop jcloop;
tmpcmd := to_slv (in2reg3 (in2reg3'low+2 downto in2reg3'low));
case tmpcmd is
when "000" =>
tmpfp161 := resize ( arg => in1reg3,
exponent_width => tmpfp161'high,
fraction_width => -tmpfp161'low,
denormalize_in => true,
denormalize => false,
round_style => round_zero);
when "001" =>
tmpfp161 := resize ( arg => in1reg3,
-- size_res => tmpfp161,
exponent_width => tmpfp161'high,
fraction_width => -tmpfp161'low,
denormalize_in => false,
denormalize => false);
when "010" =>
tmpfp161 := resize ( arg => in1reg3,
exponent_width => tmpfp161'high,
fraction_width => -tmpfp161'low,
denormalize_in => false,
denormalize => false);
when "011" =>
tmpfp161 := resize ( arg => in1reg3,
-- size_res => tmpfp161,
exponent_width => tmpfp161'high,
fraction_width => -tmpfp161'low,
denormalize_in => true,
denormalize => false,
round_style => round_inf);
when "100" =>
tmpfp161 := resize ( arg => in1reg3,
exponent_width => tmpfp161'high,
fraction_width => -tmpfp161'low,
denormalize_in => true,
denormalize => false,
round_style => round_neginf);
when "101" =>
tmpfp161 := resize ( arg => in1reg3,
-- size_res => tmpfp161,
exponent_width => tmpfp161'high,
fraction_width => -tmpfp161'low,
denormalize_in => true,
denormalize => false,
check_error => false,
round_style => round_zero);
when "110" =>
tmpfp161 := resize ( arg => in1reg3,
exponent_width => tmpfp161'high,
fraction_width => -tmpfp161'low);
when "111" =>
tmpfp161 := resize ( arg => in1reg3,
exponent_width => tmpfp161'high,
fraction_width => -tmpfp161'low
-- size_res => tmpfp161
);
when others => null;
end case;
outarray(0)(-8 downto -23) := tmpfp161;
outarray(0)(8 downto 6) := float(tmpcmd);
outarray(0)(6 downto -7) := (others => '0');
end if;
end process cmd4reg;
-- purpose: "0101" Conversion function test
cmd5reg: process (clk, rst_n) is
variable uns : unsigned (15 downto 0); -- unsigned number
variable s : signed (15 downto 0); -- signed number
variable uf : ufixed (8 downto -7); -- unsigned fixed
variable sf : sfixed (8 downto -7); -- signed fixed point
variable outarray : cry_type; -- array for output
variable tmpcmd : STD_LOGIC_VECTOR (2 downto 0);
begin -- process cmd1reg
if rst_n = '0' then -- asynchronous reset (active low)
outx(5) <= ( others => '0');
jrloop: for j in 0 to 7 loop
outarray (j) := (others => '0');
end loop jrloop;
elsif rising_edge(clk) then -- rising clock edge
outx(5) <= outarray(7);
jcloop: for j in 7 downto 1 loop
outarray (j) := outarray(j-1);
end loop jcloop;
tmpcmd := to_slv (in2reg3 (in2reg3'low+2 downto in2reg3'low));
case tmpcmd is
when "000" =>
uns := to_unsigned (in1reg3, uns'length);
outarray(0)(-8 downto -23) := float(std_logic_vector(uns));
when "001" =>
uns := to_unsigned (in1reg3, uns);
outarray(0)(-8 downto -23) := float(std_logic_vector(uns));
when "010" =>
s := to_signed (in1reg3, s'length);
outarray(0)(-8 downto -23) := float(std_logic_vector(s));
when "011" =>
s := to_signed (in1reg3, s);
outarray(0)(-8 downto -23) := float(std_logic_vector(s));
when "100" =>
uf := to_ufixed (in1reg3, uf'high, uf'low);
outarray(0)(-8 downto -23) := float(to_slv(uf));
when "101" =>
uf := to_ufixed (in1reg3, uf);
outarray(0)(-8 downto -23) := float(to_slv(uf));
when "110" =>
sf := to_sfixed (in1reg3, sf'high, sf'low);
outarray(0)(-8 downto -23) := float(to_slv(sf));
when "111" =>
sf := to_sfixed (in1reg3, sf);
outarray(0)(-8 downto -23) := float(to_slv(sf));
when others => null;
end case;
outarray(0)(8 downto 6) := float(tmpcmd);
outarray(0)(5 downto -7) := (others => '0');
end if;
end process cmd5reg;
-- purpose: "0110" to_float()
cmd6reg: process (clk, rst_n) is
variable uns : unsigned (15 downto 0); -- unsigned number
variable s : signed (15 downto 0); -- signed number
variable uf : ufixed (8 downto -7); -- unsigned fixed
variable sf : sfixed (8 downto -7); -- signed fixed point
variable outarray : cry_type; -- array for output
variable tmpcmd : STD_LOGIC_VECTOR (2 downto 0);
begin -- process cmd1reg
if rst_n = '0' then -- asynchronous reset (active low)
outx(6) <= ( others => '0');
jrloop: for j in 0 to 7 loop
outarray (j) := (others => '0');
end loop jrloop;
elsif rising_edge(clk) then -- rising clock edge
outx(6) <= outarray(7);
jcloop: for j in 7 downto 1 loop
outarray (j) := outarray(j-1);
end loop jcloop;
tmpcmd := to_slv (in2reg3 (in2reg3'low+2 downto in2reg3'low));
case tmpcmd is
when "000" =>
uns := UNSIGNED (to_slv (in1reg3(-8 downto -23)));
outarray(0) := to_float(uns, 8, 23);
when "001" =>
uns := UNSIGNED (to_slv (in1reg3(-8 downto -23)));
outarray(0) := to_float(uns, in1reg3);
when "010" =>
s := SIGNED (to_slv (in1reg3(-8 downto -23)));
outarray(0) := to_float(s, 8, 23);
when "011" =>
s := SIGNED (to_slv (in1reg3(-8 downto -23)));
outarray(0) := to_float(s, in1reg3);
when "100" =>
uf := to_ufixed (to_slv (in1reg3(-8 downto -23)), uf'high, uf'low);
outarray(0) := to_float(uf, 8, 23);
when "101" =>
uf := to_ufixed (to_slv (in1reg3(-8 downto -23)), uf);
outarray(0) := to_float(uf, in1reg3);
when "110" =>
sf := to_sfixed (to_slv (in1reg3(-8 downto -23)), sf'high, sf'low);
outarray(0) := to_float(sf, 8, 23);
when "111" =>
sf := to_sfixed (to_slv (in1reg3(-8 downto -23)), sf);
outarray(0) := to_float(sf, in1reg3);
when others => null;
end case;
end if;
end process cmd6reg;
-- purpose: "0111" mod function
cmd7reg: process (clk, rst_n) is
variable tmpuns : unsigned (31 downto 0); -- unsigned number
variable outarray : cry_type; -- array for output
begin -- process cmd1reg
if rst_n = '0' then -- asynchronous reset (active low)
outx(7) <= ( others => '0');
jrloop: for j in 0 to 7 loop
outarray (j) := (others => '0');
end loop jrloop;
elsif rising_edge(clk) then -- rising clock edge
outx(7) <= outarray(7);
jcloop: for j in 7 downto 1 loop
outarray (j) := outarray(j-1);
end loop jcloop;
outarray(0) := in1reg3 mod in2reg3;
end if;
end process cmd7reg;
-- purpose: "1000" rem function
cmd8reg: process (clk, rst_n) is
variable outarray : cry_type; -- array for output
begin -- process cmd2reg
if rst_n = '0' then -- asynchronous reset (active low)
outx(8) <= ( others => '0');
jrloop: for j in 0 to 7 loop
outarray (j) := (others => '0');
end loop jrloop;
elsif rising_edge(clk) then -- rising clock edge
outx(8) <= outarray(7);
jcloop: for j in 7 downto 1 loop
outarray (j) := outarray(j-1);
end loop jcloop;
outarray(0) := in1reg3 rem in2reg3;
end if;
end process cmd8reg;
-- purpose: "1001" to_float (constants) test
cmd9reg: process (clk, rst_n) is
variable outarray : cry_type; -- array for output
variable tmpcmd : STD_LOGIC_VECTOR (2 downto 0);
begin -- process cmd2reg
if rst_n = '0' then -- asynchronous reset (active low)
outx(9) <= ( others => '0');
jrloop: for j in 0 to 7 loop
outarray (j) := (others => '0');
end loop jrloop;
elsif rising_edge(clk) then -- rising clock edge
outx(9) <= outarray(7);
jcloop: for j in 7 downto 1 loop
outarray (j) := outarray(j-1);
end loop jcloop;
tmpcmd := to_slv (in2reg3 (in2reg3'low+2 downto in2reg3'low));
case tmpcmd is
when "000" =>
outarray(0) := to_float(0, 8, 23);
when "001" =>
outarray(0) := to_float(0.0, 8, 23);
when "010" =>
outarray(0) := to_float(8, in1reg3);
when "011" =>
outarray(0) := to_float(8.0, in1reg3);
when "100" =>
outarray(0) := to_float(-8, 8, 23);
when "101" =>
outarray(0) := to_float(-8.0, 8, 23);
when "110" =>
outarray(0) := to_float(27000, in2reg3);
when "111" =>
-- outarray(0) := "01000000010010010000111111011011";
outarray(0) := to_float(MATH_PI, in2reg3);
when others => null;
end case;
end if;
end process cmd9reg;
-- purpose: "1010" data manipulation (+, -, scalb, etc)
cmd10reg: process (clk, rst_n) is
variable tmpcmd : STD_LOGIC_VECTOR (2 downto 0);
variable s : SIGNED (7 downto 0); -- signed number
variable outarray : cry_type; -- array for output
constant posinf : float32 := "01111111100000000000000000000000"; -- +inf
constant neginf : float32 := "11111111100000000000000000000000"; -- +inf
constant onept5 : float32 := "00111111110000000000000000000000"; -- 1.5
begin -- process cmd2reg
if rst_n = '0' then -- asynchronous reset (active low)
outx(10) <= ( others => '0');
jrloop: for j in 0 to 7 loop
outarray (j) := (others => '0');
end loop jrloop;
elsif rising_edge(clk) then -- rising clock edge
outx(10) <= outarray(7);
jcloop: for j in 7 downto 1 loop
outarray (j) := outarray(j-1);
end loop jcloop;
tmpcmd := to_slv (in2reg3 (in2reg3'low+2 downto in2reg3'low));
case tmpcmd is
when "000" =>
outarray(0) := - in1reg3;
when "001" =>
outarray(0) := abs( in1reg3);
when "010" =>
if (cmdarray(4) = "1010") then
s := resize (SIGNED (to_slv (in2reg3(8 downto 5))), s'length);
outarray(0) := Scalb (in1reg3, s);
else
outarray(0) := (others => '0');
end if;
when "011" =>
if (cmdarray(4) = "1010") then
s := logb (in1reg3);
outarray(0) := (others => '0');
outarray(0)(-16 downto -23) := float(std_logic_vector(s));
else
outarray(0) := (others => '0');
end if;
when "100" =>
outarray(0) := Nextafter ( in1reg3, onept5);
when "101" =>
outarray(0) := Nextafter ( in1reg3, -onept5);
when "110" =>
outarray(0) := Nextafter ( x => in1reg3, y => posinf,
check_error => false,
denormalize => false);
when "111" =>
outarray(0) := Nextafter (x => in1reg3, y => neginf,
check_error => false,
denormalize => false);
when others => null;
end case;
end if;
end process cmd10reg;
-- purpose "1011" copysign
cmd11reg: process (clk, rst_n) is
variable outarray : cry_type; -- array for output
begin -- process cmd2reg
if rst_n = '0' then -- asynchronous reset (active low)
outx(11) <= ( others => '0');
jrloop: for j in 0 to 7 loop
outarray (j) := (others => '0');
end loop jrloop;
elsif rising_edge(clk) then -- rising clock edge
outx(11) <= outarray(7);
jcloop: for j in 7 downto 1 loop
outarray (j) := outarray(j-1);
end loop jcloop;
outarray(0) := Copysign (in1reg3, in2reg3);
end if;
end process cmd11reg;
-- purpose "1100" compare test
cmd12reg: process (clk, rst_n) is
variable outarray : cry_type; -- array for output
constant fifteenpt5 : float32 := "01000001011110000000000000000000";-- 15.5
begin -- process cmd2reg
if rst_n = '0' then -- asynchronous reset (active low)
outx(12) <= ( others => '0');
jrloop: for j in 0 to 7 loop
outarray (j) := (others => '0');
end loop jrloop;
elsif rising_edge(clk) then -- rising clock edge
outx(12) <= outarray(7);
jcloop: for j in 7 downto 1 loop
outarray (j) := outarray(j-1);
end loop jcloop;
outarray(0) := (others => '0');
if (in1reg3 = in2reg3) then
outarray(0)(outarray(0)'high) := '1';
else
outarray(0)(outarray(0)'high) := '0';
end if;
if (in1reg3 /= in2reg3) then
outarray(0)(outarray(0)'high-1) := '1';
else
outarray(0)(outarray(0)'high-1) := '0';
end if;
if (in1reg3 > in2reg3) then
outarray(0)(outarray(0)'high-2) := '1';
else
outarray(0)(outarray(0)'high-2) := '0';
end if;
if (in1reg3 < in2reg3) then
outarray(0)(outarray(0)'high-3) := '1';
else
outarray(0)(outarray(0)'high-3) := '0';
end if;
if (in1reg3 >= in2reg3) then
outarray(0)(outarray(0)'high-4) := '1';
else
outarray(0)(outarray(0)'high-4) := '0';
end if;
if (in1reg3 <= in2reg3) then
outarray(0)(outarray(0)'high-5) := '1';
else
outarray(0)(outarray(0)'high-5) := '0';
end if;
outarray(0)(outarray(0)'high-6) := \?=\ (in1reg3, 15);
outarray(0)(outarray(0)'high-7) := \?=\ (in1reg3, 15.5);
if (Unordered (in1reg3, in2reg3)) then
outarray(0)(outarray(0)'high-8) := '1';
else
outarray(0)(outarray(0)'high-8) := '0';
end if;
if (Finite (in1reg3)) then
outarray(0)(outarray(0)'high-9) := '1';
else
outarray(0)(outarray(0)'high-9) := '0';
end if;
if (Isnan (in1reg3)) then
outarray(0)(outarray(0)'high-10) := '1';
else
outarray(0)(outarray(0)'high-10) := '0';
end if;
end if;
end process cmd12reg;
-- purpose "1101" boolean test
cmd13reg: process (clk, rst_n) is
variable tmpcmd : STD_LOGIC_VECTOR (2 downto 0);
variable outarray : cry_type; -- array for output
begin -- process cmd2reg
if rst_n = '0' then -- asynchronous reset (active low)
outx(13) <= ( others => '0');
jrloop: for j in 0 to 7 loop
outarray (j) := (others => '0');
end loop jrloop;
elsif rising_edge(clk) then -- rising clock edge
outx(13) <= outarray(7);
jcloop: for j in 7 downto 1 loop
outarray (j) := outarray(j-1);
end loop jcloop;
tmpcmd := to_slv (in2reg3 (in2reg3'low+2 downto in2reg3'low));
case tmpcmd is
when "000" =>
outarray(0) := not (in1reg3);
when "001" =>
outarray(0) := in1reg3 and in2reg3;
when "010" =>
outarray(0) := in1reg3 or in2reg3;
when "011" =>
outarray(0) := in1reg3 nand in2reg3;
when "100" =>
outarray(0) := in1reg3 nor in2reg3;
when "101" =>
outarray(0) := in1reg3 xor in2reg3;
when "110" =>
outarray(0) := in1reg3 xnor in2reg3;
when "111" =>
outarray(0) := in1reg3 xor '1';
when others => null;
end case;
end if;
end process cmd13reg;
-- purpose "1110" reduce and vector test
cmd14reg: process (clk, rst_n) is
variable tmpcmd : STD_LOGIC_VECTOR (2 downto 0);
variable outarray : cry_type; -- array for output
begin -- process cmd2reg
if rst_n = '0' then -- asynchronous reset (active low)
outx(14) <= ( others => '0');
jrloop: for j in 0 to 7 loop
outarray (j) := (others => '0');
end loop jrloop;
elsif rising_edge(clk) then -- rising clock edge
outx(14) <= outarray(7);
jcloop: for j in 7 downto 1 loop
outarray (j) := outarray(j-1);
end loop jcloop;
tmpcmd := to_slv (in2reg3 (in2reg3'low+2 downto in2reg3'low));
case tmpcmd is
when "000" =>
outarray(0) := (others => '0');
outarray(0)(outarray(0)'high) := and_reduce (in1reg3);
outarray(0)(outarray(0)'high-1) := nand_reduce (in1reg3);
outarray(0)(outarray(0)'high-2) := or_reduce (in1reg3);
outarray(0)(outarray(0)'high-3) := nor_reduce (in1reg3);
outarray(0)(outarray(0)'high-4) := xor_reduce (in1reg3);
outarray(0)(outarray(0)'high-5) := xnor_reduce (in1reg3);
when "001" =>
outarray(0) := in1reg3 and in2reg3(in2reg3'high);
when "010" =>
outarray(0) := in1reg3 or in2reg3(in2reg3'high);
when "011" =>
outarray(0) := in1reg3 nand in2reg3(in2reg3'high);
when "100" =>
outarray(0) := in1reg3 nor in2reg3(in2reg3'high);
when "101" =>
outarray(0) := in2reg3(in2reg3'high) xor in1reg3;
when "110" =>
outarray(0) := in2reg3(in2reg3'high) xnor in1reg3;
when "111" =>
outarray(0) := in2reg3(in2reg3'high) and in1reg3;
when others => null;
end case;
end if;
end process cmd14reg;
-- purpose "1111" + constant
cmd15reg: process (clk, rst_n) is
variable tmpcmd : STD_LOGIC_VECTOR (2 downto 0);
variable outarray : cry_type; -- array for output
begin -- process cmd2reg
if rst_n = '0' then -- asynchronous reset (active low)
outx(15) <= ( others => '0');
jrloop: for j in 0 to 7 loop
outarray (j) := (others => '0');
end loop jrloop;
elsif rising_edge(clk) then -- rising clock edge
outx(15) <= outarray(7);
jcloop: for j in 7 downto 1 loop
outarray (j) := outarray(j-1);
end loop jcloop;
tmpcmd := to_slv (in2reg3 (in2reg3'low+2 downto in2reg3'low));
case tmpcmd is
when "000" =>
outarray(0) := in1reg3 + 1;
when "001" =>
outarray(0) := 1 + in1reg3;
when "010" =>
outarray(0) := in1reg3 + 1.0;
when "011" =>
outarray(0) := 1.0 + in1reg3;
when "100" =>
outarray(0) := in1reg3 * 1;
when "101" =>
outarray(0) := 1 * in1reg3;
when "110" =>
outarray(0) := in1reg3 * 1.0;
when "111" =>
outarray(0) := 1.0 * in1reg3;
when others => null;
end case;
end if;
end process cmd15reg;
-- purpose: multiply floating point
-- type : sequential
-- inputs : clk, rst_n, in1, in2
-- outputs: out1
cmdreg: process (clk, rst_n) is
variable outreg : float32; -- register stages
variable in1reg, in2reg : float32; -- register stages
variable in1reg2, in2reg2 : float32; -- register stages
begin -- process mulreg
if rst_n = '0' then -- asynchronous reset (active low)
in1reg := ( others => '0');
in2reg := ( others => '0');
in1reg2 := ( others => '0');
in2reg2 := ( others => '0');
in1reg3 <= ( others => '0');
in2reg3 <= ( others => '0');
out1 <= ( others => '0');
outreg := (others => '0');
rcloop: for i in 1 to 15 loop
cmdarray (i) <= (others => '0');
end loop rcloop;
elsif rising_edge(clk) then -- rising clock edge
out1 <= to_slv (outreg);
outregc: case cmdarray (13) is
when "0000" => outreg := outx (0);
when "0001" => outreg := outx (1);
when "0010" => outreg := outx (2);
when "0011" => outreg := outx (3);
when "0100" => outreg := outx (4);
when "0101" => outreg := outx (5);
when "0110" => outreg := outx (6);
when "0111" => outreg := outx (7);
when "1000" => outreg := outx (8);
when "1001" => outreg := outx (9);
when "1010" => outreg := outx (10);
when "1011" => outreg := outx (11);
when "1100" => outreg := outx (12);
when "1101" => outreg := outx (13);
when "1110" => outreg := outx (14);
when "1111" => outreg := outx (15);
when others => null;
end case outregc;
cmdpipe: for i in 15 downto 3 loop
cmdarray (i) <= cmdarray (i-1);
end loop cmdpipe;
cmdarray (2) <= std_ulogic_vector(cmd);
in1reg3 <= in1reg2;
in2reg3 <= in2reg2;
in1reg2 := in1reg;
in2reg2 := in2reg;
in1reg := to_float (in1, in1reg);
in2reg := to_float (in2, in2reg);
end if;
end process cmdreg;
end architecture rtl;