projet-vlsi/exec.vhdl

254 lines
6.1 KiB
VHDL

library ieee;
use ieee.std_logic_1164.all;
use ieee.numeric_std.all;
entity EXec is
port(
-- Decode interface synchro
dec2exe_empty : in Std_logic;
exe_pop : out Std_logic;
-- Decode interface operands
dec_op1 : in Std_Logic_Vector(31 downto 0); -- first alu input
dec_op2 : in Std_Logic_Vector(31 downto 0); -- shifter input
dec_exe_dest : in Std_Logic_Vector(3 downto 0) ; -- Rd destination
dec_exe_wb : in Std_Logic; -- Rd destination write back
dec_flag_wb : in Std_Logic; -- CSPR modifiy
-- Decode to mem interface
dec_mem_data : in Std_Logic_Vector(31 downto 0); -- data to MEM W
dec_mem_dest : in Std_Logic_Vector(3 downto 0) ; -- Destination MEM R
dec_pre_index : in Std_logic;
dec_mem_lw : in Std_Logic;
dec_mem_lb : in Std_Logic;
dec_mem_sw : in Std_Logic;
dec_mem_sb : in Std_Logic;
-- Shifter command
dec_shift_lsl : in Std_Logic;
dec_shift_lsr : in Std_Logic;
dec_shift_asr : in Std_Logic;
dec_shift_ror : in Std_Logic;
dec_shift_rrx : in Std_Logic;
dec_shift_val : in Std_Logic_Vector(4 downto 0);
dec_cy : in Std_Logic;
-- Alu operand selection
dec_comp_op1 : in Std_Logic;
dec_comp_op2 : in Std_Logic;
dec_alu_cy : in Std_Logic;
-- Alu command
dec_alu_cmd : in Std_Logic_Vector(1 downto 0);
-- Exe bypass to decod
exe_res : out Std_Logic_Vector(31 downto 0);
exe_c : out Std_Logic;
exe_v : out Std_Logic;
exe_n : out Std_Logic;
exe_z : out Std_Logic;
exe_dest : out Std_Logic_Vector(3 downto 0); -- Rd destination
exe_wb : out Std_Logic; -- Rd destination write back
exe_flag_wb : out Std_Logic; -- CSPR modifiy
-- Mem interface
exe_mem_adr : out Std_Logic_Vector(31 downto 0); -- Alu res register
exe_mem_data : out Std_Logic_Vector(31 downto 0);
exe_mem_dest : out Std_Logic_Vector(3 downto 0);
exe_mem_lw : out Std_Logic;
exe_mem_lb : out Std_Logic;
exe_mem_sw : out Std_Logic;
exe_mem_sb : out Std_Logic;
exe2mem_empty : out Std_logic;
mem_pop : in Std_logic;
-- global interface
ck : in Std_logic;
reset_n : in Std_logic;
vdd : in bit;
vss : in bit);
end EXec;
----------------------------------------------------------------------
architecture Behavior OF EXec is
-- creation des components utilisés par EXEC
component alu
port ( op1 : in Std_Logic_Vector(31 downto 0);
op2 : in Std_Logic_Vector(31 downto 0);
cin : in Std_Logic;
cmd : in Std_Logic_Vector(1 downto 0);
res : out Std_Logic_Vector(31 downto 0);
cout : out Std_Logic;
z : out Std_Logic;
n : out Std_Logic;
v : out Std_Logic;
vdd : in bit;
vss : in bit);
end component;
component shifter
port (
shift_lsl : in Std_Logic;
shift_lsr : in Std_Logic;
shift_asr : in Std_Logic;
shift_ror : in Std_Logic; -- rotation sans extension
shift_rrx : in Std_Logic; -- avec extension
shift_val : in Std_Logic_Vector(4 downto 0);
din : in Std_Logic_Vector(31 downto 0);
cin : in Std_Logic;
dout : out Std_Logic_Vector(31 downto 0);
cout : out Std_Logic;
-- global interface
vdd : in bit;
vss : in bit
);
end component;
component fifo_72b
port(
din : in std_logic_vector(71 downto 0);
dout : out std_logic_vector(71 downto 0);
-- commands
push : in std_logic;
pop : in std_logic;
-- flags
full : out std_logic;
empty : out std_logic;
reset_n : in std_logic;
ck : in std_logic;
vdd : in bit;
vss : in bit
);
end component;
-- signal reliant les instances
-- signal sortant du shifter
signal shifter_op2 : std_logic_vector(31 downto 0);
signal shifter_op2_carry : std_logic;
-- signal entrant de l'alu
signal alu_op1_in, alu_op2_in : std_logic_vector(31 downto 0);
-- signal sortant de l'alu
signal alu_value_out : std_logic_vector(31 downto 0);
signal alu_value_cout : std_logic;
-- signal entrant fifo
signal mem_adr : std_logic_vector(31 downto 0);
signal exe_push, exe2mem_full : std_logic;
begin
-- Component instantiation.
-- shifter
shifter_int : shifter
port map (
shift_lsl => dec_shift_lsl,
shift_lsr => dec_shift_lsr,
shift_asr => dec_shift_asr,
shift_ror => dec_shift_ror,
shift_rrx => dec_shift_rrx,
shift_val => dec_shift_val,
din => dec_op2,
cin => dec_cy,
dout => shifter_op2,
cout => shifter_op2_carry,
-- global interface
vdd => vdd,
vss => vss
);
-- l'alu
alu_inst : alu
port map (
op1 => alu_op1_in,
op2 => alu_op2_in,
cin => dec_alu_cy,
cmd => dec_alu_cmd,
res => alu_value_out,
cout => alu_value_cout,
z => exe_z,
n => exe_n,
v => exe_v,
-- global interface
vdd => vdd,
vss => vss
);
-- étage de pipeline entre exec et mem
exec2mem : fifo_72b
port map ( din(71) => dec_mem_lw,
din(70) => dec_mem_lb,
din(69) => dec_mem_sw,
din(68) => dec_mem_sb,
din(67 downto 64) => dec_mem_dest,
din(63 downto 32) => dec_mem_data,
din(31 downto 0) => mem_adr,
dout(71) => exe_mem_lw,
dout(70) => exe_mem_lb,
dout(69) => exe_mem_sw,
dout(68) => exe_mem_sb,
dout(67 downto 64) => exe_mem_dest,
dout(63 downto 32) => exe_mem_data,
dout(31 downto 0) => exe_mem_adr,
push => exe_push,
pop => mem_pop,
empty => exe2mem_empty,
full => exe2mem_full,
reset_n => reset_n,
ck => ck,
vdd => vdd,
vss => vss
);
-- multiplexeurs entrée ALU
alu_op1_in <= (not dec_op1) when dec_comp_op1='1' else dec_op1;
alu_op2_in <= (not shifter_op2) when dec_comp_op2='1' else shifter_op2;
-- bypass 2 decod
-- resultat ALU
exe_res <= alu_value_out;
-- carry flag
exe_c <= alu_value_cout;
-- sortie mutex entre ALU et fifo
mem_adr <= (dec_op1) when dec_pre_index='1' else alu_value_out;
-- Sortie restante
-- exe_pop <= dec2exe_empty;
-- exe_dest <= dec_exe_dest;
-- exe_wb <= dec_exe_wb;
-- exe_flag_wb <= dec_flag_wb;
end Behavior;