signal_processing_vorlage/hardware/signal_processing/sine.vhd

library ieee;
use ieee.std_logic_1164.all;
use ieee.numeric_std.all;

library work;
use work.reg32.all;
use work.float.all;
use work.task.all;

entity sine is
    port (
        clk   : in std_logic;
        reset : in std_logic;

        task_start : in std_logic; --Startsignal
        task_state : out work.task.State; --Ausgang

        step_size : in work.reg32.word; --Winkelinkrement pro Sample
        phase     : in work.reg32.word; --Startwinkel
        amplitude : in work.reg32.word; --Amplitude

        signal_write     : out std_logic;
        signal_writedata : out std_logic_vector(31 downto 0)
    );
end entity sine;


architecture rtl of sine is

	--Task-FSM
    signal current_task_state : work.task.State := work.task.TASK_IDLE;
    signal next_task_state    : work.task.State := work.task.TASK_IDLE;
    signal index              : integer range 0 to work.task.STREAM_LEN := 0;
	--Flanken-Erkennung
    signal task_start_d  : std_logic := '0';
    signal task_start_re : std_logic := '0';
	--float_sine-IP-core
    signal fs_data_valid   : std_logic := '0'; --eingabe
    signal fs_busy         : std_logic; -- Steuerung
    signal fs_result_valid : std_logic;
    signal fs_angle        : signed(31 downto 0) := (others => '0');
    signal fs_sine         : signed(31 downto 0); --Ausgabe
	--Datenpfad
    signal angle_reg      : signed(31 downto 0) := (others => '0'); --aktueller Winkel
    signal sine_raw_fp    : std_logic_vector(31 downto 0) := (others => '0'); --Ergebnis des IP-Cores
    signal sine_scaled_fp : std_logic_vector(31 downto 0) := (others => '0'); --skaliertes Ergebnis
	--Calc-FSM
    type calc_state_t is (
        C_IDLE,
        C_START,
        C_WAIT,
        C_SCALE,
        C_WRITE
    );

    signal calc_state : calc_state_t := C_IDLE;

begin

    task_state <= current_task_state;

    --------------------------------------------------------------------------
    -- Task-FSM transitions
    --------------------------------------------------------------------------
    task_state_transitions : process(current_task_state, task_start_re, index, calc_state)
    begin
        next_task_state <= current_task_state;

        case current_task_state is

            when work.task.TASK_IDLE =>
                if task_start_re = '1' then
                    next_task_state <= work.task.TASK_RUNNING;
                end if;

            when work.task.TASK_RUNNING =>
                if (index = work.task.STREAM_LEN ) and (calc_state = C_WRITE) then
                    next_task_state <= work.task.TASK_DONE;
                end if;

            when work.task.TASK_DONE =>
                if task_start_re = '1' then
                    next_task_state <= work.task.TASK_RUNNING;
                end if;

        end case;
    end process;


    --------------------------------------------------------------------------
    -- float_sine instantiation
    --------------------------------------------------------------------------
    fs_angle <= angle_reg;

    u_float_sine : entity work.float_sine
        generic map (
            ITERATIONS => 8
        )
        port map (
            clk          => clk,
            reset        => reset,
            data_valid   => fs_data_valid, --Eingabe starten
            busy         => fs_busy, --Core arbeitet
            result_valid => fs_result_valid, --Ergebnis fertig
            angle        => fs_angle, --Eingabewinkel
            sine         => fs_sine --Ergebnis
        );


    --------------------------------------------------------------------------
    -- Sync / Datenpfad
    --------------------------------------------------------------------------
	--Multiplikation über: neuer_exponent = sin_exp + (amp_exp -127)
    sync : process(clk, reset)
        variable sin_exp  : unsigned(7 downto 0); --Speichern Sinuszahl
        variable amp_exp  : unsigned(7 downto 0); --Speichern Amplitude
        variable new_exp  : unsigned(7 downto 0); --Speichern neuen Exponenten

	--Exponenten als Integerwerte für Berechnung
        variable sin_e_i  : integer range -255 to 511;
        variable amp_e_i  : integer range -255 to 511;
        variable new_e_i  : integer range -255 to 511;

    begin
        if reset = '1' then

            current_task_state <= work.task.TASK_IDLE;
            index              <= 0;

            task_start_d       <= '0';
            task_start_re      <= '0';

            calc_state         <= C_IDLE;

            angle_reg          <= (others => '0');
            sine_raw_fp        <= (others => '0');
            sine_scaled_fp     <= (others => '0');

            fs_data_valid      <= '0';
            signal_write       <= '0';
            signal_writedata   <= (others => '0');

        elsif rising_edge(clk) then

            ------------------------------------------------------------------
            -- rising edge detect
            ------------------------------------------------------------------
            task_start_re <= task_start and not task_start_d;
            task_start_d  <= task_start;

            ------------------------------------------------------------------
            -- Defaults
            ------------------------------------------------------------------
            signal_write  <= '0';
            fs_data_valid <= '0';

            ------------------------------------------------------------------
            -- Task-FSM update
            ------------------------------------------------------------------
            current_task_state <= next_task_state;


		
            ------------------------------------------------------------------
            -- Berechnungs-FSM
            ------------------------------------------------------------------
            case calc_state is

                ------------------------------------------------------------------
                -- Start: Sofort mit erstem Winkel beginnen
                ------------------------------------------------------------------
                when C_IDLE =>
                    if (current_task_state = work.task.TASK_RUNNING) then
                        angle_reg  <= signed(phase);
                        calc_state <= C_START;
                    end if;

                ------------------------------------------------------------------
                -- Wert in den Core laden, sobald busy='0'
                ------------------------------------------------------------------
                when C_START =>
                    if fs_busy = '0' then --Wenn Core ist frei
                        fs_data_valid <= '1'; --Input-Latch im Core
                        calc_state    <= C_WAIT;
                    end if;

                ------------------------------------------------------------------
                -- Warten auf Ergebnis
                ------------------------------------------------------------------
                when C_WAIT => --Warten auf Ergebnis
                    if fs_result_valid = '1' then
                        sine_raw_fp <= std_logic_vector(fs_sine);
                        calc_state  <= C_SCALE;
                    end if;

                ------------------------------------------------------------------
                -- Skalierung
                ------------------------------------------------------------------
                when C_SCALE =>
                    sin_exp := unsigned(sine_raw_fp(30 downto 23)); --Liest die 8 Exponentenbits des Sinuswerts
                    amp_exp := unsigned(amplitude(30 downto 23)); --Liese die 8 der Amplitude

                    sin_e_i := to_integer(sin_exp); --Umwandlung in Integer
                    amp_e_i := to_integer(amp_exp);

                    new_e_i := sin_e_i + (amp_e_i - 127); --Eigentliche Multiplikation 

                    if new_e_i < 0 then -- Falls Wert negativ
                        new_exp := (others => '0'); --Setze Wert auf 0 
                    else
                        new_exp := to_unsigned(new_e_i, 8); --Zurückwandeln in 8-Bit-Exponent
                    end if;

			--Berechnten Exponenten wieder zusammensetzen
                    sine_scaled_fp(31)            <= sine_raw_fp(31); 
                    sine_scaled_fp(30 downto 23) <= std_logic_vector(new_exp);
                    sine_scaled_fp(22 downto 0)  <= sine_raw_fp(22 downto 0);

                    calc_state <= C_WRITE;

                ------------------------------------------------------------------
                -- Schreiben + nächsten Winkel
                ------------------------------------------------------------------
                when C_WRITE =>
                    signal_write     <= '1';
                    signal_writedata <= sine_scaled_fp;

                    if index = work.task.STREAM_LEN then
                        calc_state <= C_IDLE;
                    else
                        angle_reg  <= angle_reg + signed(step_size);
                        calc_state <= C_START;
                    end if;

            end case;

		 ------------------------------------------------------------------
            -- Index update
            ------------------------------------------------------------------
            case next_task_state is

                when work.task.TASK_IDLE =>	
                    index <= 0;

                when work.task.TASK_RUNNING =>
                    if calc_state = C_WRITE then
                        if index < work.task.STREAM_LEN then
                            index <= index + 1;
                        end if;
                    end if;

                when work.task.TASK_DONE =>
                    index <= 0;

            end case;


        end if;
    end process;

end architecture rtl;