# How to solve a combinatorial logic with an output feeding back to the input, forming a loop?

I have this warnig in my code for a FSM:

``````WARNING:Xst:2170 - Unit P22_MustangSecuentialTailLight_Structural : the following signal(s) form a combinatorial loop: Lights<5>, U1/next_state_cmp_eq0000, next_state_int<0>, pres_state_int<0>.

WARNING:Xst:2170 - Unit P22_MustangSecuentialTailLight_Structural : the following signal(s) form a combinatorial loop: Lights<4>, next_state_int<1>, pres_state_int<1>.

WARNING:Xst:2170 - Unit P22_MustangSecuentialTailLight_Structural : the following signal(s) form a combinatorial loop: next_state_int<2>, U1/next_state_cmp_eq0003, Lights<3>, pres_state_int<2>.

WARNING:Xst:2170 - Unit P22_MustangSecuentialTailLight_Structural : the following signal(s) form a combinatorial loop: next_state_int<3>, pres_state_int<4>, U1/next_state_cmp_eq0013, pres_state_int<3>, Lights<2>, next_state_int<4>.
``````

Its for a loop made in the code, the image of my diagram

But that enbedded signal(pres_state_int) is necessary for update the next state logic block. The code:

``````library IEEE;
use IEEE.STD_LOGIC_1164.ALL;
use work.States.all;

entity P22_MustangSecuentialTailLight_Structural is
Port  ( Lturn     : in   STD_LOGIC;
Rturn     : in   STD_LOGIC;
Hazard    : in   STD_LOGIC;
Rst       : in   STD_LOGIC;
Break     : in   STD_LOGIC;
Clk100MHz : in   STD_LOGIC;
Lights    : out  STD_LOGIC_VECTOR (5 downto 0));
end P22_MustangSecuentialTailLight_Structural;

architecture Behavioral of P22_MustangSecuentialTailLight_Structural is

component NextStateLogic
port (
BLRH       : in   STD_LOGIC_VECTOR (3 downto 0);
pres_state : in   STD_LOGIC_VECTOR (4 downto 0);
next_state : out  STD_LOGIC_VECTOR (4 downto 0));
end component;

component CurrentStateRegister
port (
pres_state_b : out   STD_LOGIC_VECTOR (4 downto 0);
next_state_b : in  STD_LOGIC_VECTOR (4 downto 0);
Rst          : in STD_LOGIC;
Clk          : in STD_LOGIC );
end component;

component OutputLogic
port (
pres_state_c : in   STD_LOGIC_VECTOR (4 downto 0);
Lights     : out  STD_LOGIC_VECTOR (5 downto 0));
end component;

component Clk1Hz
port (
Rst       : in    STD_LOGIC;
Clk_in    : in    STD_LOGIC;
Clk_out   : out   STD_LOGIC);
end component;

--Embedded signal declaration
signal LRH_int        : STD_LOGIC_VECTOR (3 downto 0);
signal next_state_int : state_values := ST0;
signal pres_state_int : state_values := ST0;
signal Clk1Hz_int     : STD_LOGIC;

begin
LRH_int <= Break & Lturn & Rturn & Hazard;

U1 : NextStateLogic
port map(
BLRH       => LRH_int,
pres_state => pres_state_int,
next_state => next_state_int
);

U2 : CurrentStateRegister
port map(
pres_state_b => pres_state_int,
next_state_b => next_state_int,
Rst => Rst,
Clk => Clk1Hz_int
);

U3 : OutputLogic
port map(
pres_state_c => pres_state_int,
Lights     => Lights
);

U4 : Clk1Hz
port map(
Rst      => Rst,
Clk_in   => Clk100MHz,
Clk_out  => Clk1Hz_int
);

end Behavioral;
``````

Next is the package use for encoding the code:

``````library IEEE;
use IEEE.STD_LOGIC_1164.all;

package States is

subtype state_values is std_logic_vector(4 downto 0);
constant ST0: state_values := "00000";
constant ST1: state_values := "00001";
constant ST2: state_values := "00010";
constant ST3: state_values := "00011";
constant ST4: state_values := "00100";
constant ST5: state_values := "00101";
constant ST6: state_values := "00110";
constant ST7: state_values := "00111";
constant ST8: state_values := "01000";
constant ST9: state_values := "01001";
constant ST10: state_values := "01010";
constant ST11: state_values := "01011";
constant ST12: state_values := "01100";
constant ST13: state_values := "01101";
constant ST14: state_values := "01110";
constant ST15: state_values := "01111";
constant ST16: state_values := "10000";
signal pres_state, next_state: state_values;

end States;
``````

NextStateLogic component code:

``````library IEEE;
use IEEE.STD_LOGIC_1164.ALL;
use work.States.all;

entity NextStateLogic is
Port(   BLRH       : in   STD_LOGIC_VECTOR (3 downto 0);
pres_state : in   STD_LOGIC_VECTOR (4 downto 0);
next_state : out  STD_LOGIC_VECTOR (4 downto 0));
end NextStateLogic;

architecture NextStateLogicl of NextStateLogic is

begin

FSM: process (pres_state, BLRH)
begin
case pres_state is

when "00000" =>
case BLRH is
when "0000"  => next_state <= "00000";--ST0; -- All off
when "0010"  => next_state <= "00100";--ST4; -- Right Turn
when "0100"  => next_state <= "00111";--ST7; -- Left Turn
when "0110"  => next_state <= "00101";--ST5; -- All off
when others  => next_state <= "00001";--ST1; -- Hazard
end case;
when "00001"         => next_state <= "00010";--ST2;
when "00010"         => next_state <= "00011";
when "00011"         =>
case BLRH is
when "1000"  => next_state <= "00011"; -- Break
when "1110"  => next_state <= "00011"; --
when "1010"  => next_state <= "01101"; -- Right Turn & Break
when "1100"  => next_state <= "01010"; -- Left Turn & Break
when others  => next_state <= "00000"; -- Hazard
end case;
when "00100"         => next_state <= "00101";
when "00101"         => next_state <= "00110";
when "00110"         => next_state <= "00000";
when "00111"         => next_state <= "01000";
when "01000"         => next_state <= "01001";
when "01001"         => next_state <= "01010";
when "01010"        => next_state <= "01011";
when "01011"        => next_state <= "01100";
when "01100"        =>
case BLRH is
when "1100"  => next_state <= "01111"; -- Right Turn & Break
when "1010"  => next_state <= "10000"; -- Left Turn & Break
when others  => next_state <= "00000";
end case;
when "01101"        => next_state <= "01110";
when "01110"        => next_state <= "01100";
when "01111"        => next_state <= "01010";
when "10000"        => next_state <= "01101";

-- Include when others to avoid latches
when others      => next_state <= "00000";
end case;
end process FSM;

end NextStateLogicl;
``````

CurrentStateRegister component code:

``````library IEEE;
use IEEE.STD_LOGIC_1164.ALL;

entity CurrentStateRegister is
Port(
pres_state_b : out   STD_LOGIC_VECTOR (4 downto 0);
next_state_b : in  STD_LOGIC_VECTOR (4 downto 0);
Rst          : in STD_LOGIC;
Clk          : in STD_LOGIC
);
end CurrentStateRegister;

architecture CurrentStateRegister of CurrentStateRegister is

begin

StateReg: process (Clk,Rst,next_state_b)
begin
if (Rst = '1') then
pres_state_b <= "00000";
elsif Clk = '1' then
pres_state_b <= next_state_b;
else
pres_state_b<= "00000";
end if;
end process StateReg;

end CurrentStateRegister;
``````

OutputLogic component code:

``````library IEEE;
use IEEE.STD_LOGIC_1164.ALL;

entity OutputLogic is
Port(
pres_state_c : in   STD_LOGIC_VECTOR (4 downto 0);
Lights     : out  STD_LOGIC_VECTOR (5 downto 0));

end OutputLogic;

architecture OutputLogic of OutputLogic is

begin

Outputs: process (pres_state_c)
begin
case pres_state_c is

when "00000" => Lights <= "000000";
----------------------------------------------- Hazard
when "00001" => Lights <= "001100";
when "00010" => Lights <= "011110";
when "00011" => Lights <= "111111";
-----------------------------------------------   Right Turn
when "00100" => Lights <= "000100";
when "00101" => Lights <= "000110";
when "00110" => Lights <= "000111";
----------------------------------------------- Left Turn
when "00111" => Lights <= "001000";
when "01000" => Lights <= "011000";
when "01001" => Lights <= "111000";
----------------------------------------------- Right Turn & Break
when "01010" => Lights <= "001111";
when "01011" => Lights <= "011111";
-----------------------------------------------
when "01111" => Lights <= "000111";
when "01100" => Lights <= "111111"; -- Common Case
when "10000" => Lights <= "111000";
----------------------------------------------- Left Turn & Break
when "01101" => Lights <= "111100";
when "01110" => Lights <= "111110";

when others => Lights <= "000000";
end case;
end process Outputs;

end OutputLogic;
``````

And finally the Clk1Hz component code:

``````library IEEE;
use IEEE.STD_LOGIC_1164.ALL;
use IEEE.NUMERIC_STD.ALL;
use IEEE.STD_LOGIC_UNSIGNED.ALL;

entity Clk1Hz is

port (
Rst       : in    STD_LOGIC;
Clk_in    : in    STD_LOGIC;
Clk_out   : out   STD_LOGIC);
end Clk1Hz;

architecture Clk1Hz of Clk1Hz is
-- Definition of embedded signals and constants
-- Constants used for frequency division
constant Fosc    : integer := 100000000;   --Frecuencia del oscilador de tabletas NEXYS 3
constant Fdiv    : integer := 5;           --Frecuencia deseada del divisor
constant CtaMax  : integer := Fosc / Fdiv; --Cuenta maxima a la que hay que llegar
-- Signal used by the frequency division process
signal Cont      : integer range 0 to CtaMax;

begin
-- Frequency divider to obtain a 2Hz signal from
-- the 100 MHz board oscillator
FreqDiv: process (Rst, Clk_in)
begin
if Rst = '1' then
Cont <= 0;
elsif (rising_edge(Clk_in)) then
if Cont = CtaMax - 1 then
Cont      <= 0;
Clk_out    <= '1';
else
Cont      <= Cont + 1;
Clk_out    <= '0';
end if;
end if;
end process FreqDiv;

end Clk1Hz;
``````

Iam missing something?? Is there another way to instanciate the component NextStateLogic?

Thanks:D

-
Without the rest of the code we can only guess. My guess would be there is something wrong in the entity you have used for component "CurrentStateRegister". Best thing you can do: Get it working in simulation (Xilinx ISIM is OK) before you try synthesis again. –  Brian Drummond Nov 2 '13 at 22:20
My guess was right : see Godel's answer. –  Brian Drummond Nov 3 '13 at 8:59

In CurrentStateRegister, you need to test for `rising_edge(clk)` instead of `clk = '1'`. Your current code infers a latch instead of a register, causing a loop whenever `clk = '1'`. Also, lose the final `else` in the ControlStateRegister module:

``````StateReg: process (Clk,Rst,next_state_b)
begin
if (Rst = '1') then
pres_state_b <= "00000";
elsif (rising_edge(Clk)) then
pres_state_b <= next_state_b;
end if;
end process StateReg;
``````
-