p_wdone_int <= '0';
p_read_int <= (others => '0');
p_sp_read_int <= (others => '0');
- p_sp_write_int <= std_logic_vector(to_unsigned(71,p_sp_write_int'length));
+ p_sp_write_int <= std_logic_vector(to_unsigned(HSPALTE_MAX,p_sp_write_int'length));
pc_char_int <= (others => '0');
pc_done_int <= '0';
when S_S_FIN_POSUP =>
state_next <= S_S_CLEAR_NEXT0;
when S_S_CLEAR_NEXT0 =>
- if s_cnt_int = hspalte(to_unsigned(71,hspalte'length)) then
+ if s_cnt_int = hspalte(to_unsigned(HSPALTE_MAX,hspalte'length)) then
state_next <= S_S_CLEAR_NEXT1;
end if;
when S_S_CLEAR_NEXT1 =>
- if s_cnt_int = hspalte(to_unsigned(71,hspalte'length)) then
+ if s_cnt_int = hspalte(to_unsigned(HSPALTE_MAX,hspalte'length)) then
state_next <= SIDLE;
end if;
when S_S_DONE =>
when S_PC_INIT =>
state_next <= S_PC_READ;
when S_PC_READ =>
- if d_get = '0' then
+ if pc_get = '0' then
state_next <= SIDLE;
end if;
when S_P_READ =>
process(state_int, s_cnt_int, d_spalte, d_zeile, data_out, s_char, address_int,
data_in_int, d_new_result_int, d_new_eingabe_int, d_new_bs_int,
was_bs_int, s_take, pos_int, p_rdone_int, p_wdone_int, p_read_int,
- p_write, p_sp_read_int, p_sp_write_int)
+ p_write, p_sp_read_int, p_sp_write_int, pc_char_int, pc_zeile, pc_spalte)
variable addr_tmp : std_logic_vector(H_RAM_WIDTH - 1 downto 0);
variable spalte_tmp : hspalte;
variable mul_tmp : std_logic_vector((H_RAM_WIDTH*2) -1 downto 0);
address_next <= address_int;
data_in_next <= data_in_int;
pc_done_next <= '0';
- pc_char_next <= pc_char_int; --(others => '0');
+ pc_char_next <= pc_char_int;
p_rdone_next <= p_rdone_int;
p_wdone_next <= p_wdone_int;
p_read_next <= p_read_int;
when S_S_INIT =>
null;
when S_S_WRITE =>
- -- nur bei < 71 weiter machen
+ -- nur bei < HSPALTE_MAX weiter machen
-- Hint: '/=' billiger als '<'
- if unsigned(s_cnt_int) /= 71 then
+ if unsigned(s_cnt_int) /= HSPALTE_MAX then
wr_next <= '1';
address_next <= std_logic_vector(unsigned(pos_int) + unsigned(s_cnt_int));
data_in_next <= s_char;
addr_tmp(hspalte'length - 1 downto 0) := s_cnt_int;
end if;
s_cnt_next <= addr_tmp(hspalte'length - 1 downto 0);
-
wr_next <= '1';
address_next <= std_logic_vector(unsigned(pos_int) + unsigned(addr_tmp));
data_in_next <= (others => '0');
d_new_result_next <= '1';
-- resetten der parser counter
p_sp_read_next <= (others => '0');
- p_sp_write_next <= std_logic_vector(to_unsigned(71,p_sp_write_next'length));
+ p_sp_write_next <= std_logic_vector(to_unsigned(HSPALTE_MAX,p_sp_write_next'length));
when S_S_FIN_POSUP =>
-- overflowcheck nach 50 berechnungen => wieder von vorne anfangen
if pos_int = std_logic_vector(to_unsigned(H_RAM_SIZE-142,H_RAM_WIDTH)) then
wr_next <= '1';
address_next <= std_logic_vector(unsigned(pos_int) + unsigned(s_cnt_int));
data_in_next <= (others => '0');
- if s_cnt_int = hspalte(to_unsigned(71,hspalte'length)) then
+ if s_cnt_int = hspalte(to_unsigned(HSPALTE_MAX,hspalte'length)) then
s_cnt_next <= (0 => '1', others => '0');
else
s_cnt_next <= std_logic_vector(unsigned(s_cnt_int) + 1);
when S_S_CLEAR_NEXT1 =>
-- die naechsten 142 bytes im speicher resetten
wr_next <= '1';
- address_next <= std_logic_vector(unsigned(pos_int) + to_unsigned(71,H_RAM_WIDTH) + unsigned(s_cnt_int));
+ address_next <= std_logic_vector(unsigned(pos_int) + to_unsigned(HSPALTE_MAX,H_RAM_WIDTH) + unsigned(s_cnt_int));
data_in_next <= (others => '0');
- if s_cnt_int = hspalte(to_unsigned(71,hspalte'length)) then
+ if s_cnt_int = hspalte(to_unsigned(HSPALTE_MAX,hspalte'length)) then
s_cnt_next <= (0 => '1', others => '0');
else
s_cnt_next <= std_logic_vector(unsigned(s_cnt_int) + 1);
when S_D_INIT =>
addr_tmp := (others => '0');
addr_tmp(hzeile'length - 1 downto 0) := d_zeile;
- mul_tmp := std_logic_vector(unsigned(addr_tmp) * to_unsigned(71,H_RAM_WIDTH));
+ mul_tmp := std_logic_vector(unsigned(addr_tmp) * to_unsigned(HSPALTE_MAX,H_RAM_WIDTH));
addr_tmp := mul_tmp((addr_tmp'length - 1) downto 0);
addr_tmp := std_logic_vector(unsigned(addr_tmp) + unsigned(d_spalte));
address_next <= addr_tmp;
when S_PC_INIT =>
addr_tmp := (others => '0');
addr_tmp(hzeile'length - 1 downto 0) := pc_zeile;
- mul_tmp := std_logic_vector(unsigned(addr_tmp) * to_unsigned(71,H_RAM_WIDTH));
+ mul_tmp := std_logic_vector(unsigned(addr_tmp) * to_unsigned(HSPALTE_MAX,H_RAM_WIDTH));
addr_tmp := mul_tmp((addr_tmp'length - 1) downto 0);
addr_tmp := std_logic_vector(unsigned(addr_tmp) + unsigned(pc_spalte));
address_next <= addr_tmp;
when S_PC_READ =>
- pc_char_next <= data_out;
pc_done_next <= '1';
+ pc_char_next <= data_out;
+
when S_P_READ =>
wr_next <= '0';
spalte_tmp := std_logic_vector(unsigned(p_sp_read_int) + 1);
data_in_next <= p_write;
spalte_tmp := std_logic_vector(unsigned(p_sp_write_int) - 1);
p_sp_write_next <= spalte_tmp;
- address_next <= std_logic_vector(unsigned(pos_int) + to_unsigned(71,H_RAM_WIDTH) + unsigned(spalte_tmp));
+ address_next <= std_logic_vector(unsigned(pos_int) + to_unsigned(HSPALTE_MAX,H_RAM_WIDTH) + unsigned(spalte_tmp));
when S_P_WRITE_DONE =>
p_wdone_next <= '1';
when S_P_DONE =>
end case;
end process;
- sp_ram_inst : entity work.sp_ram(beh)
+ sp_ram_inst : sp_ram
generic map (
ADDR_WIDTH => H_RAM_WIDTH
)