pc_zeile : out hzeile;
pc_spalte : out hspalte;
pc_get : out std_logic;
- pc_busy : in std_logic; --signals if the history module actually grants our request.
pc_done : in std_logic;
pc_char : in hbyte
);
end entity pc_communication;
architecture beh of pc_communication is
- signal spalte, spalte_next : integer range 1 to hspalte_max + 1;
- signal zeile , zeile_next : integer range 1 to hzeile_max + 1;
+ signal spalte, spalte_next : integer range 1 to HSPALTE_MAX + 2;
+ signal zeile , zeile_next : integer range 0 to HZEILE_MAX + 1;
signal get, get_next : std_logic;
signal new_i, new_i_next : std_logic;
signal tx_done_i, tx_done_i_next : std_logic;
signal tx_data_i, tx_data_i_next : std_logic_vector (7 downto 0);
- type STATE_PC is (IDLE, WAIT_HIST, FETCH, FORWARD, WAIT_UART, UART_DONE);
+ type STATE_PC is (IDLE, FETCH, FORWARD, WAIT_UART, UART_DONE, CR, CR_WAIT, NL, NL_WAIT);
signal state, state_next : STATE_PC ;
-
begin
-
-
pc_zeile <= hzeile(std_logic_vector(to_unsigned(zeile,7)));
pc_spalte <= hspalte(std_logic_vector(to_unsigned(spalte,7)));
pc_get <= get;
if sys_res_n = '0' then
state <= IDLE;
spalte <= 1;
- zeile <= 1;
+ zeile <= 0;
get <= '0';
new_i <= '0';
- tx_data_i <= "00000000";
+ tx_data_i <= x"00";
tx_done_i <= '0';
elsif rising_edge(sys_clk) then
spalte <= spalte_next;
end if;
end process sync;
- output_pc : process (state, zeile, spalte, tx_data_i, tx_done_i, pc_char)
+ process (state, zeile, spalte, tx_data_i, tx_done_i, pc_char, rx_new, btn_a,
+ pc_done)
begin
get_next <= '0';
new_i_next <= '0';
-
spalte_next <= spalte;
zeile_next <= zeile;
tx_data_i_next <= tx_data_i;
- case state is
- when IDLE =>
- null;
- when FETCH =>
- get_next <= '1';
- when WAIT_HIST =>
- tx_data_i_next <= pc_char;
- when FORWARD =>
- new_i_next <= '1';
- when WAIT_UART =>
- null;
- when UART_DONE =>
- if tx_data_i = x"00" or spalte = hspalte_max then
- zeile_next <= zeile + 1;
- spalte_next <= 1;
- if zeile = hzeile_max then
- zeile_next <= 1;
- end if;
- else
- spalte_next <= spalte + 1;
- end if;
- end case;
- end process output_pc;
-
- next_state_pc : process (btn_a, pc_busy, pc_done, rx_new, rx_data, spalte,
- state, tx_data_i ,tx_done_i, zeile)
- begin
state_next <= state;
case state is
when IDLE =>
- if (rx_new = '1' and rx_data = x"0a" ) or btn_a = '0' then
+-- if (rx_new = '1' and rx_data = x"0a") or btn_a = '0' then
+ if (rx_new = '1') or btn_a = '0' then
state_next <= FETCH;
end if;
when FETCH =>
- if pc_busy = '1' then
- state_next <= WAIT_HIST;
- else
- state_next <= FETCH;
- end if;
- when WAIT_HIST =>
- if (pc_done = '1') then
- state_next <= FORWARD;
+ get_next <= '1';
+ if pc_done = '1' and tx_done_i = '0' then
+ if pc_char = x"00" then
+ state_next <= UART_DONE;
+ else
+ state_next <= FORWARD;
+ end if;
end if;
when FORWARD =>
+ tx_data_i_next <= pc_char;
+ new_i_next <= '1';
+ -- halte pc_get weiterhin high sodass pc_char garantiert gleich bleibt
+ get_next <= '1';
state_next <= WAIT_UART;
when WAIT_UART =>
- if (tx_done_i = '1') then
+ new_i_next <= '1';
+ get_next <= '1';
+ if tx_done_i = '1' then
state_next <= UART_DONE;
end if;
- when UART_DONE =>
- if (tx_data_i = x"00" or spalte = hspalte_max) and
- zeile = hzeile_max then
+ when UART_DONE => null;
+ state_next <= FETCH;
+ spalte_next <= spalte + 1;
+ if spalte = HSPALTE_MAX + 1 then
+ state_next <= NL;
+ spalte_next <= 1;
+ zeile_next <= zeile + 1;
+ end if;
+ when NL =>
+ tx_data_i_next <= x"0a";
+ new_i_next <= '1';
+ if tx_done_i = '1' then
+ state_next <= NL_WAIT;
+ end if;
+ when NL_WAIT =>
+ state_next <= CR;
+ when CR =>
+ tx_data_i_next <= x"0d";
+ new_i_next <= '1';
+ if tx_done_i = '1' then
+ state_next <= CR_WAIT;
+ end if;
+ when CR_WAIT =>
+ state_next <= FETCH;
+ if zeile = HZEILE_MAX then
state_next <= IDLE;
- else
- state_next <= FETCH;
+ zeile_next <= 0;
+ spalte_next <= 1;
end if;
end case;
- end process next_state_pc;
-
+ end process;
end architecture beh;