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I am just starting with learning vhdl. Consider the code here : - http://esd.cs.ucr.edu/labs/tutorial/jkff.vhd

I can't understand what are concurrent statements and why are they needed here? Will it be correct if we modify Q and Qbar directly in process p without using internal signal 'state'? Also why are J,K not in sensitivity list of process p in the snippet?

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up vote 2 down vote accepted

Concurrent statements, as you may know, in a pure functional sense (i.e. not considering hardware implementation) do not incur any delay. So when you write

Q <= state;

Functionally, Q exactly follows state without any delay.

I am going to guess that the reason an intermediate signal state was used, instead of directly assigning Q inside the process, is that if you directly assign one of your outputs Q in the process, then you cannot "read" the output to derive your Qbar signal.

That is, you couldn't do this:

Qbar <= not Q;

This is because it is not strictly allowable to read an output signal in VHDL. By using "state" you have an internal signal from which you can derive both Q and Qbar.

An alternative, equivalent implementation to this would be to assign both outputs Q and Qbar in each of the cases in the state machine, and eliminate the intermediate state signal completely. However, this seems a bit more complicated since you will have nearly twice as many lines of code for an equivalent functionality.

To answer your second question: J,K are not in the sensitivity list because the process p is a synchronous process. You are describing a memory element (JK FlipFlop), which by definition only updates its outputs when clock or reset change. Input signals J and K can change and the process will not update its outputs. Every time there is a clock edge, or reset is asserted, the process "wakes up" and evaluates inputs, and determines what the output should be. Even in J,K were included in the sensitivity list, provided your ouputs were only updated on rising_edge(clock), then the overall function would be the same (although your code would be confusing).

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Pedant mode: a concurrent assignment does incur a delta-cycle delay. sigasi.com/content/vhdls-crown-jewel – Martin Thompson Sep 16 '13 at 12:10

There is no reason not to have the Q and Qbar assignments inside the process. You need to be slightly careful though.

Whenever a signal is assigned to, the value does not update until the simulator moves on to the next "delta-cycle". This means that within processes, when you assign to a signal, you are axtually only cheduling and update and if you read the signal you will get the "old" value. In order to have the sort of sequential updates you might expect, you use a variable. So you could model the JKFF like this:

architecture behv of JK_FF is
    p : process(clock, reset) is
    variable state : std_logic;
        variable input : std_logic_vector(1 downto 0);
        if (reset = '1') then
            state := '0';
        elsif (rising_edge(clock)) then
            input := J & K;
            case (input) is
                when "11" =>
                    state := not state;
                when "10" =>
                    state := '1';
                when "01" =>
                    state := '0';
                when others =>
            end case;
        end if;
        Q  <= state;
        Qbar <= not state;
    end process;
end behv;

A synthesis note: the assignments to Q and Qbar occur outside of the if rising_edge(clk) so will be interpreted as just like concurrent drivers.

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