I am trying to make a 32-bit floating point multiplier with *combinational* logic.
So far as I can tell I have done so, except when I try to simulate my test bench in it.
If I simulate with my code in, I get U's in ALL values. If I take my code out and simulate I get my input vectors. I know I haven't normalized my mantissa completely yet.
I can't understand why at all. Everything compiles perfectly. The only problem I am having is getting values when I simulate my test bench...
Everything is calling everything correctly as well.
Any help would be much appreciated.

**Please note the test-bench does work, I have simulated it with other VHDL which did return correct values**

Here is my code for the multiplier:

```
library IEEE ;
use IEeE.std_logic_1164.all ;
use ieee.std_logic_arith.all ;
use ieee.numeric_std.all ;
Use Ieee.std_logic_unsigned.all;
entity FP_MULTIPLIER is
port( A_VAL, B_VAL : in std_logic_vector (31 downto 0);
F_VAL : out std_logic_vector (31 downto 0));
end FP_MULTIPLIER;--
architecture Behavioral of FP_MULTIPLIER is
signal exponant : std_logic_vector (8 downto 0);
signal holder : std_logic_vector (47 downto 0);
signal PPA1 : std_logic_vector (47 downto 0);
signal PPA2 : std_logic_vector (47 downto 0);
signal PPA3 : std_logic_vector (47 downto 0);
signal PPA4 : std_logic_vector (47 downto 0);
signal PPA5 : std_logic_vector (47 downto 0);
signal PPA6 : std_logic_vector (47 downto 0);
signal PPA7 : std_logic_vector (47 downto 0);
signal PPA8 : std_logic_vector (47 downto 0);
signal PPA9 : std_logic_vector (47 downto 0);
signal AD1 : std_logic_vector (47 downto 0);
signal AD2 : std_logic_vector (47 downto 0);
signal AD3 : std_logic_vector (47 downto 0);
signal almost:std_logic_vector (23 downto 0);
signal F0:std_logic_vector (47 downto 0);
signal F1:std_logic_vector (47 downto 0);
constant ZERO : std_logic_vector := "000000000000000000000000000000000000000000000000"; --zero vektir for imputs
type temp_MP is array (6 downto 1) of std_logic_vector (47 downto 0);
signal MP :temp_MP;
type temp_PPA is array (23 downto 0) of std_logic_vector (47 downto 0); --creates 24 vectir array of 49 length
signal temp :temp_PPA := (others => (others => '0'));
begin
exponant(8) <= A_VAL(31) xor B_VAL(31); --gets sign bit
exponant (7 downto 0) <= ((A_VAL (30 downto 23) + B_VAL (30 downto 23)) - 127 ); --gets exponant
partial : for I in 0 to 23 generate
temp(I) (23+I downto I) <= '1'& A_VAL(22 downto 0) WHEN B_VAL(I)='1' ELSE --fills vector array and shifts it properly
(others => '0');
end generate partial;
RRU1 : entity work.RRU7_3 port map (temp(0),temp(1),temp(2),temp(3),temp(4),temp(5),temp(6),PPA1,PPA2,PPA3);
RRU2 : entity work.RRU7_3 port map (temp(7),temp(8),temp(9),temp(10),temp(11),temp(12),temp(13),PPA4,PPA5,PPA6);
RRU3 : entity work.RRU7_3 port map (temp(14),temp(15),temp(16),temp(17),temp(18),temp(19),temp(20),PPA7,PPA8,PPA9);
RRU4 : entity work.RRU7_3 port map (temp(21),temp(22),temp(23),ZERO,PPA7,PPA8,PPA9,MP(1),MP(2),MP(3));
RRU5 : entity work.RRU7_3 port map (PPA1,PPA2,PPA3,PPA4,PPA5,PPA6,ZERO,MP(4),MP(5),MP(6));
RRU6 : entity work.RRU7_3 port map (MP(1),MP(2),MP(3),MP(4),MP(5),MP(6),ZERO,AD1,AD2,AD3);
RRU32: entity work.RRU3_2 port map (AD1,AD2,AD3,F1,F0);
holder <= F1+ F0; --implement with CSA?
almost <= holder(46 downto 22) WHEN holder(47)='1' ELSE --fix for rounding and radix point
holder(45 downto 21);
F_VAL <= exponant & almost;
end Behavioral;
```

Here is the code for my test bench:

```
library IEEE;
use IEEE.STD_LOGIC_1164.all;
use STD.TEXTIO.all;
use IEEE.STD_LOGIC_TEXTIO.all;
entity ATB_FPM is
end entity ATB_FPM;
architecture ATB_FPM of ATB_FPM is
component FP_MULTIPLIER is
port (
A_VAL : in STD_LOGIC_VECTOR ( 31 downto 0 );
B_VAL : in STD_LOGIC_VECTOR ( 31 downto 0 );
F_VAL : out STD_LOGIC_VECTOR ( 31 downto 0 )
);
end component FP_MULTIPLIER;
type F_VALS_ARRAY is array ( 0 to 15 ) of STD_LOGIC_VECTOR ( 31 downto 0 );
constant A_VALS : F_VALS_ARRAY := (
X"3F800000", X"3F800000", X"3FA33333", X"38D1B717",
X"41160000", X"41020831", X"43000000", X"40300000",
X"47129320", X"41B80A3D", X"42C80000", X"46EC8E00",
X"49791900", X"45800000", X"46733D52", X"390164EF"
);
constant B_VALS : F_VALS_ARRAY := (
X"40000000", X"449F6000", X"42C80000", X"3951B717",
X"460CAF00", X"42F61EB8", X"43800000", X"46210100",
X"47000600", X"3B8B4396", X"43480000", X"4641BC00",
X"3C4A42AF", X"46000000", X"44FC8666", X"3959945B"
);
signal X_A_VAL : STD_LOGIC_VECTOR ( 31 downto 0 );
signal X_B_VAL : STD_LOGIC_VECTOR ( 31 downto 0 );
signal X_F_VAL : STD_LOGIC_VECTOR ( 31 downto 0 );
begin
UUT: FP_MULTIPLIER
port map (
A_VAL => X_A_VAL,
B_VAL => X_B_VAL,
F_VAL => X_F_VAL
);
process
variable DLAY : TIME;
constant T50N : TIME := 50 ns;
file OUT_FILE : TEXT open WRITE_MODE is "results.txt";
variable BUF : LINE;
constant SP2 : STRING( 1 to 2 ) := " ";
constant SP4 : STRING( 1 to 4 ) := " ";
constant HDR : STRING( 1 to 38 ) := " A_VAL B_VAL F_VAL TIME";
variable LNO : INTEGER := 1;
begin
for I in 0 to 15 loop
if LNO = 1 then
LNO := LNO + 1;
write ( BUF, HDR );
writeline ( OUT_FILE, BUF );
elsif LNO = 25 then
LNO := 1;
else
LNO := LNO + 1;
end if;
X_A_VAL <= A_VALS(I) ; X_B_VAL <= B_VALS(I);
wait for 50 ns;
DLAY := T50N - X_F_VAL'LAST_EVENT;
hwrite ( BUF, X_A_VAL ); write ( BUF, SP2 );
hwrite ( BUF, X_B_VAL ); write ( BUF, SP4 );
hwrite ( BUF, X_F_VAL ); write ( BUF, SP4 );
write ( BUF, DLAY );
writeline ( OUT_FILE, BUF );
end loop;
end process;
end architecture ATB_FPM;
```

By popular demand, here is my RRU7to3;

```
library IEEE;
use IEEE.STD_LOGIC_1164.all;
entity RRU7_3 is
port (
A_VEC : in STD_LOGIC_VECTOR ( 47 downto 0 );
B_VEC : in STD_LOGIC_VECTOR ( 47 downto 0 );
C_VEC : in STD_LOGIC_VECTOR ( 47 downto 0 );
D_VEC : in STD_LOGIC_VECTOR ( 47 downto 0 );
E_VEC : in STD_LOGIC_VECTOR ( 47 downto 0 );
F_VEC : in STD_LOGIC_VECTOR ( 47 downto 0 );
G_VEC : in STD_LOGIC_VECTOR ( 47 downto 0 );
F2_VEC : out STD_LOGIC_VECTOR ( 47 downto 0 );
F1_VEC : out STD_LOGIC_VECTOR ( 47 downto 0 );
F0_VEC : out STD_LOGIC_VECTOR ( 47 downto 0 )
);
end entity RRU7_3;
architecture WASTEFUL of RRU7_3 is
component WTA7_3 is
port (
A : in STD_LOGIC;
B : in STD_LOGIC;
C : in STD_LOGIC;
D : in STD_LOGIC;
E : in STD_LOGIC;
F : in STD_LOGIC;
G : in STD_LOGIC;
F0 : out STD_LOGIC;
F1 : out STD_LOGIC;
F2 : out STD_LOGIC
);
end component WTA7_3;
signal ROW2 : STD_LOGIC_VECTOR ( 65 downto 0 );
signal ROW1 : STD_LOGIC_VECTOR ( 65 downto 0 );
signal ROW0 : STD_LOGIC_VECTOR ( 65 downto 0 );
begin
GEN_LABEL: for I in 0 to 47 generate
WTAUNIT: WTA7_3
port map (
A => A_VEC(I),
B => B_VEC(I),
C => C_VEC(I),
D => D_VEC(I),
E => E_VEC(I),
F => F_VEC(I),
G => G_VEC(I),
F0 => ROW0(I),
F1 => ROW1(I+1),
F2 => ROW2(I+2)
);
end generate;
F0_VEC <= ROW0( 47 downto 0 );
F1_VEC <= ROW1( 47 downto 1 ) & '0';
F2_VEC <= ROW2( 47 downto 2 ) & "00";
end architecture WASTEFUL;
```

Now here is the RRU3to2

```
library IEEE;
use IEEE.STD_LOGIC_1164.all;
entity RRU3_2 is
port (
A_VEC : in STD_LOGIC_VECTOR ( 47 downto 0 );
B_VEC : in STD_LOGIC_VECTOR ( 47 downto 0 );
C_VEC : in STD_LOGIC_VECTOR ( 47 downto 0 );
F1_VEC : out STD_LOGIC_VECTOR ( 47 downto 0 );
F0_VEC : out STD_LOGIC_VECTOR ( 47 downto 0 )
);
end entity RRU3_2;
architecture WASTEFUL of RRU3_2 is
component CSADDER is
generic (
G_DELAY : TIME := 1 ns
);
port (
A : in STD_LOGIC;
B : in STD_LOGIC;
C : in STD_LOGIC;
F0: out STD_LOGIC;
F1: out STD_LOGIC
);
end component CSADDER;
signal ROW1 : STD_LOGIC_VECTOR ( 48 downto 0 );
signal ROW0 : STD_LOGIC_VECTOR ( 48 downto 0 );
begin
GEN_LABEL: for I in 0 to 47 generate
WTAUNIT: CSADDER
port map (
A => A_VEC(I),
B => B_VEC(I),
C => C_VEC(I),
F0 => ROW0(I),
F1 => ROW1(I+1)
);
end generate;
F0_VEC <= ROW0( 47 downto 0 );
F1_VEC <= ROW1( 47 downto 1 ) & '0';
end architecture WASTEFUL;
```

I also edited my above FP_Multiplier to reflect changes made which were suggested for ease of reading (tested and compiles fine still, simply no values.)

Here is an image of simulation: