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我想用4个寄存器来控制8个灯,一个控制2个灯,控制编码用C写 应该掌握哪些技术要点?
library ieee;
use ieee.std_logic_1164.all;
use ieee.std_logic_arith.all;
use ieee.std_logic_unsigned.all;
library proc_common_v3_00_a;
use proc_common_v3_00_a.proc_common_pkg.all;
entity user_logic is
generic
(
-- ADD USER GENERICS BELOW THIS LINE ---------------
--USER generics added here
-- ADD USER GENERICS ABOVE THIS LINE ---------------
-- DO NOT EDIT BELOW THIS LINE ---------------------
-- Bus protocol parameters, do not add to or delete
C_SLV_DWIDTH : integer := 32;
C_NUM_REG : integer := 4
-- DO NOT EDIT ABOVE THIS LINE ---------------------
);
port
(
-- ADD USER PORTS BELOW THIS LINE ------------------
--USER ports added here
LED : out std_logic_vector(0 to 7);
-- ADD USER PORTS ABOVE THIS LINE ------------------
-- DO NOT EDIT BELOW THIS LINE ---------------------
-- Bus protocol ports, do not add to or delete
Bus2IP_Clk : in std_logic;
Bus2IP_Reset : in std_logic;
Bus2IP_Addr : in std_logic_vector(0 to 31);
Bus2IP_CS : in std_logic_vector(0 to 0);
Bus2IP_RNW : in std_logic;
Bus2IP_Data : in std_logic_vector(0 to C_SLV_DWIDTH-1);
Bus2IP_BE : in std_logic_vector(0 to C_SLV_DWIDTH/8-1);
Bus2IP_RdCE : in std_logic_vector(0 to C_NUM_REG-1);
Bus2IP_WrCE : in std_logic_vector(0 to C_NUM_REG-1);
IP2Bus_Data : out std_logic_vector(0 to C_SLV_DWIDTH-1);
IP2Bus_RdAck : out std_logic;
IP2Bus_WrAck : out std_logic;
IP2Bus_Error : out std_logic
-- DO NOT EDIT ABOVE THIS LINE ---------------------
);
attribute SIGIS : string;
attribute SIGIS of Bus2IP_Clk : signal is "CLK";
attribute SIGIS of Bus2IP_Reset : signal is "RST";
end entity user_logic;
signal slv_reg0 : std_logic_vector(0 to C_SLV_DWIDTH-1);
signal slv_reg1 : std_logic_vector(0 to C_SLV_DWIDTH-1);
signal slv_reg2 : std_logic_vector(0 to C_SLV_DWIDTH-1);
signal slv_reg3 : std_logic_vector(0 to C_SLV_DWIDTH-1);
signal slv_reg_write_sel : std_logic_vector(0 to 3);
signal slv_reg_read_sel : std_logic_vector(0 to 3);
signal slv_ip2bus_data : std_logic_vector(0 to C_SLV_DWIDTH-1);
signal slv_read_ack : std_logic;
signal slv_write_ack : std_logic;
begin
--USER logic implementation added here
process( Bus2IP_Clk ) is
begin
if Bus2IP_Clk'event and Bus2IP_Clk = '1' then
if Bus2IP_Reset = '1' then
slv_reg0 <= (others => '0');
slv_reg1 <= (others => '0');
slv_reg2 <= (others => '0');
slv_reg3 <= (others => '0');
else
case slv_reg_write_sel is
when "1000" =>
LED(0 to 1) <= slv_reg0(0 to 1);
when "0100" =>
LED(2 to 3) <= slv_reg1(2 to 3);
when "0010" =>
LED(4 to 5) <= slv_reg2(4 to 5);
when "0001" =>
LED(6 to 7) <= slv_reg3(6 to 7);
when others => null;
end case;
end if;
end if;
end process;
--
-- Bus2IP_WrCE/Bus2IP_RdCE Memory Mapped Register
-- "1000" C_BASEADDR + 0x0
-- "0100" C_BASEADDR + 0x4
-- "0010" C_BASEADDR + 0x8
-- "0001" C_BASEADDR + 0xC
--
------------------------------------------
slv_reg_write_sel <= Bus2IP_WrCE(0 to 3);
slv_reg_read_sel <= Bus2IP_RdCE(0 to 3);
slv_write_ack <= Bus2IP_WrCE(0) or Bus2IP_WrCE(1) or Bus2IP_WrCE(2) or Bus2IP_WrCE(3);
slv_read_ack <= Bus2IP_RdCE(0) or Bus2IP_RdCE(1) or Bus2IP_RdCE(2) or Bus2IP_RdCE(3);
-- implement slave model software accessible register(s)
SLAVE_REG_WRITE_PROC : process( Bus2IP_Clk ) is
begin
if Bus2IP_Clk'event and Bus2IP_Clk = '1' then
if Bus2IP_Reset = '1' then
slv_reg0 <= (others => '0');
slv_reg1 <= (others => '0');
slv_reg2 <= (others => '0');
slv_reg3 <= (others => '0');
else
case slv_reg_write_sel is
when "1000" =>
for byte_index in 0 to (C_SLV_DWIDTH/8)-1 loop
if ( Bus2IP_BE(byte_index) = '1' ) then
slv_reg0(byte_index*8 to byte_index*8+7) <= Bus2IP_Data(byte_index*8 to byte_index*8+7);
end if;
end loop;
when "0100" =>
for byte_index in 0 to (C_SLV_DWIDTH/8)-1 loop
if ( Bus2IP_BE(byte_index) = '1' ) then
slv_reg1(byte_index*8 to byte_index*8+7) <= Bus2IP_Data(byte_index*8 to byte_index*8+7);
end if;
end loop;
when "0010" =>
for byte_index in 0 to (C_SLV_DWIDTH/8)-1 loop
if ( Bus2IP_BE(byte_index) = '1' ) then
slv_reg2(byte_index*8 to byte_index*8+7) <= Bus2IP_Data(byte_index*8 to byte_index*8+7);
end if;
end loop;
when "0001" =>
for byte_index in 0 to (C_SLV_DWIDTH/8)-1 loop
if ( Bus2IP_BE(byte_index) = '1' ) then
slv_reg3(byte_index*8 to byte_index*8+7) <= Bus2IP_Data(byte_index*8 to byte_index*8+7);
end if;
end loop;
when others => null;
end case;
end if;
end if;
end process SLAVE_REG_WRITE_PROC;
-- implement slave model software accessible register(s) read mux
SLAVE_REG_READ_PROC : process( slv_reg_read_sel, slv_reg0, slv_reg1, slv_reg2, slv_reg3 ) is
begin
case slv_reg_read_sel is
when "1000" => slv_ip2bus_data <= slv_reg0;
when "0100" => slv_ip2bus_data <= slv_reg1;
when "0010" => slv_ip2bus_data <= slv_reg2;
when "0001" => slv_ip2bus_data <= slv_reg3;
when others => slv_ip2bus_data <= (others => '0');
end case;
end process SLAVE_REG_READ_PROC;
------------------------------------------
-- Example code to drive IP to Bus signals
------------------------------------------
IP2Bus_Data <= slv_ip2bus_data when slv_read_ack = '1' else
(others => '0');
IP2Bus_WrAck <= slv_write_ack;
IP2Bus_RdAck <= slv_read_ack;
IP2Bus_Error <= '0';
end IMP; |
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