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library IEEE;
use IEEE.std_logic_1164.all;
use IEEE.numeric_std.all;
entity gc_reset is
generic(
g_clocks : natural := 1;
g_logdelay : natural := 10;
g_syncdepth : natural := 3);
port(
free_clk_i : in std_logic;
locked_i : in std_logic := '1'; -- All the PLL locked signals ANDed together
clks_i : in std_logic_vector(g_clocks-1 downto 0);
rstn_o : out std_logic_vector(g_clocks-1 downto 0));
end gc_reset;
architecture rtl of gc_reset is
subtype t_shifter is std_logic_vector(g_syncdepth-1 downto 0);
type t_shifters is array(natural range <>) of t_shifter;
signal shifters : t_shifters(g_clocks-1 downto 0) := (others => (others => '0')); -- start reset
signal locked_count : unsigned(g_logdelay-1 downto 0) := (others => '0');
signal master_rstn : std_logic;
begin
lock : process(free_clk_i)
constant locked_done : unsigned(g_logdelay-1 downto 0) := (others => '1');
begin
if rising_edge(free_clk_i) then
if locked_i = '0' then
master_rstn <= '0';
locked_count <= (others => '0');
else
if locked_count = locked_done then
master_rstn <= '1';
else
master_rstn <= '0';
locked_count <= locked_count + 1;
end if;
end if;
end if;
end process;
-- Generate the sync chains for each clock domain
syncs : for i in g_clocks-1 downto 0 generate
sync : process(clks_i(i))
begin
if rising_edge(clks_i(i)) then
shifters(i) <= master_rstn & shifters(i)(g_syncdepth-1 downto 1);
end if;
end process;
end generate;
-- Output the synchronized reset
rstn : for i in g_clocks-1 downto 0 generate
rstn_o(i) <= shifters(i)(0);
end generate;
end rtl;