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--------------------------------------------------------------------------------
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-- Light8080 simulation test bench.
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--------------------------------------------------------------------------------
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-- This test bench was built from a generic template. The details on what tests
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-- are performed by this test bench can be found in the assembly source for the
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-- 8080 program, in file asm\@PROGNAME@.asm.
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--------------------------------------------------------------------------------
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--
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-- This test bench provides a simulated CPU system to test programs. This test
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-- bench does not do any assertions or checks, all assertions are left to the
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-- software.
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--
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-- The simulated environment has 2KB of RAM, mirror-mapped to all the memory
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-- map of the 8080, initialized with the test program object code. See the perl
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-- script 'util\hexconv.pl' and BAT files in the asm directory.
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--
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-- Besides, it provides some means to trigger hardware irq from software,
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-- including the specification of the instructions fed to the CPU as interrupt
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-- vectors during inta cycles.
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--
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-- We will simulate 8 possible irq sources. The software can trigger any one of
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-- them by writing at ports 0x010 to 0x011. Port 0x010 holds the irq source to
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-- be triggered (0 to 7) and port 0x011 holds the number of clock cycles that
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-- will elapse from the end of the instruction that writes to the register to
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-- the assertion of intr. Port 0x012 holds the number of cycles intr will remain
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-- high. Intr will be asserted for 1 cycle at least, so writing a 0 here is the
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-- same as writing 1.
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--
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-- When the interrupt is acknowledged and inta is asserted, the test bench reads
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-- the value at register 0x010 as the irq source, and feeds an instruction to
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-- the CPU starting from the RAM address 0040h+source*4.
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-- That is, address range 0040h-005fh is reserved for the simulated 'interrupt
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-- vectors', a total of 4 bytes for each of the 8 sources. This allows the
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-- software to easily test different interrupt vectors without any hand
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-- assembly. All of this is strictly simulation-only stuff.
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--
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-- Upon completion, the software must write a value to register 0x020. Writing
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-- a 0x055 means 'success', writing a 0x0aa means 'failure'. The write operation
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-- will stop the simulation. Success and failure conditions are defined by the
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-- software.
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--
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-- If a time period defined as constant MAX_SIM_LENGTH passes before anything
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-- is written to io address 0x020, the test bench assumes the software ran away
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-- and quits with an error message.
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--------------------------------------------------------------------------------
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library ieee;
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use ieee.std_logic_1164.ALL;
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use ieee.std_logic_unsigned.all;
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use ieee.numeric_std.ALL;
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entity light8080_@PROGNAME@ is
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end entity light8080_@PROGNAME@;
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architecture behavior of light8080_@PROGNAME@ is
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--------------------------------------------------------------------------------
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-- Simulation parameters
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-- T: simulated clock period
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constant T : time := 100 ns;
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-- MAX_SIM_LENGTH: maximum simulation time
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constant MAX_SIM_LENGTH : time := T*7000; -- enough for the tb0
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--------------------------------------------------------------------------------
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-- Component Declaration for the Unit Under Test (UUT)
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component light8080
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port (
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addr_out : out std_logic_vector(15 downto 0);
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inta : out std_logic;
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inte : out std_logic;
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halt : out std_logic;
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intr : in std_logic;
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vma : out std_logic;
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io : out std_logic;
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rd : out std_logic;
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wr : out std_logic;
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fetch : out std_logic;
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data_in : in std_logic_vector(7 downto 0);
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data_out : out std_logic_vector(7 downto 0);
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clk : in std_logic;
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reset : in std_logic );
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end component;
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signal data_i : std_logic_vector(7 downto 0) := (others=>'0');
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signal vma_o : std_logic;
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signal rd_o : std_logic;
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signal wr_o : std_logic;
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signal io_o : std_logic;
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signal data_o : std_logic_vector(7 downto 0);
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signal data_mem : std_logic_vector(7 downto 0);
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signal addr_o : std_logic_vector(15 downto 0);
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signal fetch_o : std_logic;
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signal inta_o : std_logic;
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signal inte_o : std_logic;
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signal intr_i : std_logic := '0';
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signal halt_o : std_logic;
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signal reset : std_logic := '0';
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signal clk : std_logic := '1';
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signal done : std_logic := '0';
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type t_rom is array(0 to 2047) of std_logic_vector(7 downto 0);
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signal rom : t_rom := (
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--@rom_data
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);
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signal irq_vector_byte: std_logic_vector(7 downto 0);
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signal irq_source : integer range 0 to 7;
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signal cycles_to_intr : integer range -10 to 255;
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signal intr_width : integer range 0 to 255;
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signal int_vector_index : integer range 0 to 3;
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signal addr_vector_table: integer range 0 to 65535;
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begin
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-- Instantiate the Unit Under Test (UUT)
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uut: light8080 PORT MAP(
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clk => clk,
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reset => reset,
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vma => vma_o,
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rd => rd_o,
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wr => wr_o,
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io => io_o,
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fetch => fetch_o,
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addr_out => addr_o,
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data_in => data_i,
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data_out => data_o,
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intr => intr_i,
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inte => inte_o,
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inta => inta_o,
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halt => halt_o
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);
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-- clock: run clock until test is done
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clock:
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process(done, clk)
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begin
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if done = '0' then
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clk <= not clk after T/2;
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end if;
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end process clock;
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-- Drive reset and done
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main_test:
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process
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begin
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-- Assert reset for at least one full clk period
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reset <= '1';
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wait until clk = '1';
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wait for T/2;
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reset <= '0';
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-- Remember to 'cut away' the preceding 3 clk semiperiods from
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-- the wait statement...
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wait for (MAX_SIM_LENGTH - T*1.5);
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-- Maximum sim time elapsed, assume the program ran away and
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-- stop the clk process asserting 'done' (which will stop the simulation)
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done <= '1';
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assert (done = '1')
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report "Test timed out."
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severity failure;
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wait;
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end process main_test;
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-- Synchronous RAM; 2KB mirrored everywhere
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synchronous_ram:
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process(clk)
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begin
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if (clk'event and clk='1') then
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data_mem <= rom(conv_integer(addr_o(10 downto 0)));
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if wr_o = '1' and addr_o(15 downto 11)="00000" then
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rom(conv_integer(addr_o(10 downto 0))) <= data_o;
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end if;
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end if;
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end process synchronous_ram;
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irq_trigger_register:
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process(clk)
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begin
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if (clk'event and clk='1') then
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if reset='1' then
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cycles_to_intr <= -10; -- meaning no interrupt pending
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else
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if io_o='1' and wr_o='1' and addr_o(7 downto 0)=X"11" then
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cycles_to_intr <= conv_integer(data_o) + 1;
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else
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if cycles_to_intr >= 0 then
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cycles_to_intr <= cycles_to_intr - 1;
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end if;
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end if;
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end if;
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end if;
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end process irq_trigger_register;
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irq_pulse_width_register:
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process(clk)
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variable intr_pulse_countdown : integer;
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begin
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if (clk'event and clk='1') then
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if reset='1' then
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intr_width <= 1;
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intr_pulse_countdown := 0;
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intr_i <= '0';
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else
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if io_o='1' and wr_o='1' and addr_o(7 downto 0)=X"12" then
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intr_width <= conv_integer(data_o) + 1;
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end if;
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if cycles_to_intr = 0 then
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intr_i <= '1';
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intr_pulse_countdown := intr_width;
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elsif intr_pulse_countdown <= 1 then
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intr_i <= '0';
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else
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intr_pulse_countdown := intr_pulse_countdown - 1;
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end if;
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end if;
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end if;
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end process irq_pulse_width_register;
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irq_source_register:
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process(clk)
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begin
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if (clk'event and clk='1') then
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if reset='1' then
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irq_source <= 0;
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else
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if io_o='1' and wr_o='1' and addr_o(7 downto 0)=X"10" then
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irq_source <= conv_integer(data_o(2 downto 0));
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end if;
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end if;
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end if;
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end process irq_source_register;
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-- 'interrupt vector' logic.
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irq_vector_table:
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process(clk)
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begin
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if (clk'event and clk='1') then
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if vma_o = '1' and rd_o='1' then
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if inta_o = '1' then
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int_vector_index <= int_vector_index + 1;
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else
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int_vector_index <= 0;
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end if;
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end if;
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-- this is the address of the byte we'll feed to the CPU
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addr_vector_table <= 64+irq_source*4+int_vector_index;
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end if;
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end process irq_vector_table;
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irq_vector_byte <= rom(addr_vector_table);
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data_i <= data_mem when inta_o='0' else irq_vector_byte;
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test_outcome_register:
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process(clk)
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variable outcome : std_logic_vector(7 downto 0);
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begin
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if (clk'event and clk='1') then
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if io_o='1' and wr_o='1' and addr_o(7 downto 0)=X"20" then
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assert (data_o /= X"55") report "Software reports SUCCESS" severity failure;
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assert (data_o /= X"aa") report "Software reports FAILURE" severity failure;
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assert ((data_o = X"aa") or (data_o = X"55"))
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report "Software reports unexpected outcome value."
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severity failure;
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end if;
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end if;
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end process test_outcome_register;
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end;
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