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microwatt/decode2.vhdl

409 lines
13 KiB
VHDL

library ieee;
use ieee.std_logic_1164.all;
use ieee.numeric_std.all;
library work;
use work.decode_types.all;
use work.common.all;
use work.helpers.all;
use work.insn_helpers.all;
entity decode2 is
port (
clk : in std_ulogic;
rst : in std_ulogic;
complete_in : in std_ulogic;
stall_out : out std_ulogic;
stopped_out : out std_ulogic;
flush_in: in std_ulogic;
d_in : in Decode1ToDecode2Type;
e_out : out Decode2ToExecute1Type;
m_out : out Decode2ToMultiplyType;
d_out : out Decode2ToDividerType;
l_out : out Decode2ToLoadstore1Type;
r_in : in RegisterFileToDecode2Type;
r_out : out Decode2ToRegisterFileType;
c_in : in CrFileToDecode2Type;
c_out : out Decode2ToCrFileType
);
end entity decode2;
architecture behaviour of decode2 is
type reg_type is record
e : Decode2ToExecute1Type;
m : Decode2ToMultiplyType;
d : Decode2ToDividerType;
l : Decode2ToLoadstore1Type;
end record;
signal r, rin : reg_type;
type decode_input_reg_t is record
reg_valid : std_ulogic;
reg : std_ulogic_vector(4 downto 0);
data : std_ulogic_vector(63 downto 0);
end record;
function decode_input_reg_a (t : input_reg_a_t; insn_in : std_ulogic_vector(31 downto 0);
reg_data : std_ulogic_vector(63 downto 0)) return decode_input_reg_t is
variable is_reg : std_ulogic;
begin
is_reg := '0' when insn_ra(insn_in) = "00000" else '1';
if t = RA or (t = RA_OR_ZERO and insn_ra(insn_in) /= "00000") then
--return (is_reg, insn_ra(insn_in), reg_data);
return ('1', insn_ra(insn_in), reg_data);
else
return ('0', (others => '0'), (others => '0'));
end if;
end;
function decode_input_reg_b (t : input_reg_b_t; insn_in : std_ulogic_vector(31 downto 0);
reg_data : std_ulogic_vector(63 downto 0)) return decode_input_reg_t is
begin
case t is
when RB =>
return ('1', insn_rb(insn_in), reg_data);
when CONST_UI =>
return ('0', (others => '0'), std_ulogic_vector(resize(unsigned(insn_ui(insn_in)), 64)));
when CONST_SI =>
return ('0', (others => '0'), std_ulogic_vector(resize(signed(insn_si(insn_in)), 64)));
when CONST_SI_HI =>
return ('0', (others => '0'), std_ulogic_vector(resize(signed(insn_si(insn_in)) & x"0000", 64)));
when CONST_UI_HI =>
return ('0', (others => '0'), std_ulogic_vector(resize(unsigned(insn_si(insn_in)) & x"0000", 64)));
when CONST_LI =>
return ('0', (others => '0'), std_ulogic_vector(resize(signed(insn_li(insn_in)) & "00", 64)));
when CONST_BD =>
return ('0', (others => '0'), std_ulogic_vector(resize(signed(insn_bd(insn_in)) & "00", 64)));
when CONST_DS =>
return ('0', (others => '0'), std_ulogic_vector(resize(signed(insn_ds(insn_in)) & "00", 64)));
when CONST_M1 =>
return ('0', (others => '0'), x"FFFFFFFFFFFFFFFF");
when CONST_SH =>
return ('0', (others => '0'), x"00000000000000" & "00" & insn_in(1) & insn_in(15 downto 11));
when CONST_SH32 =>
return ('0', (others => '0'), x"00000000000000" & "000" & insn_in(15 downto 11));
when NONE =>
return ('0', (others => '0'), (others => '0'));
end case;
end;
function decode_input_reg_c (t : input_reg_c_t; insn_in : std_ulogic_vector(31 downto 0);
reg_data : std_ulogic_vector(63 downto 0)) return decode_input_reg_t is
begin
case t is
when RS =>
return ('1', insn_rs(insn_in), reg_data);
when NONE =>
return ('0', (others => '0'), (others => '0'));
end case;
end;
function decode_output_reg (t : output_reg_a_t; insn_in : std_ulogic_vector(31 downto 0)) return std_ulogic_vector is
begin
case t is
when RT =>
return insn_rt(insn_in);
when RA =>
return insn_ra(insn_in);
when NONE =>
return "00000";
end case;
end;
function decode_rc (t : rc_t; insn_in : std_ulogic_vector(31 downto 0)) return std_ulogic is
begin
case t is
when RC =>
return insn_rc(insn_in);
when ONE =>
return '1';
when NONE =>
return '0';
end case;
end;
-- issue control signals
signal control_valid_in : std_ulogic;
signal control_valid_out : std_ulogic;
signal control_sgl_pipe : std_logic;
signal gpr_write_valid : std_ulogic;
signal gpr_write : std_ulogic_vector(4 downto 0);
signal gpr_a_read_valid : std_ulogic;
signal gpr_a_read : std_ulogic_vector(4 downto 0);
signal gpr_b_read_valid : std_ulogic;
signal gpr_b_read : std_ulogic_vector(4 downto 0);
signal gpr_c_read_valid : std_ulogic;
signal gpr_c_read : std_ulogic_vector(4 downto 0);
signal cr_write_valid : std_ulogic;
begin
control_0: entity work.control
generic map (
PIPELINE_DEPTH => 2
)
port map (
clk => clk,
rst => rst,
complete_in => complete_in,
valid_in => control_valid_in,
flush_in => flush_in,
sgl_pipe_in => control_sgl_pipe,
stop_mark_in => d_in.stop_mark,
gpr_write_valid_in => gpr_write_valid,
gpr_write_in => gpr_write,
gpr_a_read_valid_in => gpr_a_read_valid,
gpr_a_read_in => gpr_a_read,
gpr_b_read_valid_in => gpr_b_read_valid,
gpr_b_read_in => gpr_b_read,
gpr_c_read_valid_in => gpr_c_read_valid,
gpr_c_read_in => gpr_c_read,
cr_read_in => d_in.decode.input_cr,
cr_write_in => cr_write_valid,
valid_out => control_valid_out,
stall_out => stall_out,
stopped_out => stopped_out
);
decode2_0: process(clk)
begin
if rising_edge(clk) then
if rin.e.valid = '1' or rin.l.valid = '1' or rin.m.valid = '1' or rin.d.valid = '1' then
report "execute " & to_hstring(rin.e.nia);
end if;
r <= rin;
end if;
end process;
r_out.read1_reg <= insn_ra(d_in.insn);
r_out.read2_reg <= insn_rb(d_in.insn);
r_out.read3_reg <= insn_rs(d_in.insn);
c_out.read <= d_in.decode.input_cr;
decode2_1: process(all)
variable v : reg_type;
variable mul_a : std_ulogic_vector(63 downto 0);
variable mul_b : std_ulogic_vector(63 downto 0);
variable decoded_reg_a : decode_input_reg_t;
variable decoded_reg_b : decode_input_reg_t;
variable decoded_reg_c : decode_input_reg_t;
variable signed_division: std_ulogic;
begin
v := r;
v.e := Decode2ToExecute1Init;
v.l := Decode2ToLoadStore1Init;
v.m := Decode2ToMultiplyInit;
v.d := Decode2ToDividerInit;
mul_a := (others => '0');
mul_b := (others => '0');
--v.e.input_cr := d_in.decode.input_cr;
--v.m.input_cr := d_in.decode.input_cr;
--v.e.output_cr := d_in.decode.output_cr;
decoded_reg_a := decode_input_reg_a (d_in.decode.input_reg_a, d_in.insn, r_in.read1_data);
decoded_reg_b := decode_input_reg_b (d_in.decode.input_reg_b, d_in.insn, r_in.read2_data);
decoded_reg_c := decode_input_reg_c (d_in.decode.input_reg_c, d_in.insn, r_in.read3_data);
r_out.read1_enable <= decoded_reg_a.reg_valid;
r_out.read2_enable <= decoded_reg_b.reg_valid;
r_out.read3_enable <= decoded_reg_c.reg_valid;
-- execute unit
v.e.nia := d_in.nia;
v.e.insn_type := d_in.decode.insn_type;
v.e.read_reg1 := decoded_reg_a.reg;
v.e.read_data1 := decoded_reg_a.data;
v.e.read_reg2 := decoded_reg_b.reg;
v.e.read_data2 := decoded_reg_b.data;
v.e.read_data3 := decoded_reg_c.data;
v.e.write_reg := decode_output_reg(d_in.decode.output_reg_a, d_in.insn);
v.e.rc := decode_rc(d_in.decode.rc, d_in.insn);
v.e.cr := c_in.read_cr_data;
v.e.invert_a := d_in.decode.invert_a;
v.e.invert_out := d_in.decode.invert_out;
v.e.input_carry := d_in.decode.input_carry;
v.e.output_carry := d_in.decode.output_carry;
v.e.is_32bit := d_in.decode.is_32bit;
v.e.is_signed := d_in.decode.is_signed;
if d_in.decode.lr = '1' then
v.e.lr := insn_lk(d_in.insn);
end if;
v.e.insn := d_in.insn;
-- multiply unit
v.m.insn_type := d_in.decode.insn_type;
mul_a := decoded_reg_a.data;
mul_b := decoded_reg_b.data;
v.m.write_reg := decode_output_reg(d_in.decode.output_reg_a, d_in.insn);
v.m.rc := decode_rc(d_in.decode.rc, d_in.insn);
if d_in.decode.is_32bit = '1' then
if d_in.decode.is_signed = '1' then
v.m.data1 := (others => mul_a(31));
v.m.data1(31 downto 0) := mul_a(31 downto 0);
v.m.data2 := (others => mul_b(31));
v.m.data2(31 downto 0) := mul_b(31 downto 0);
else
v.m.data1 := '0' & x"00000000" & mul_a(31 downto 0);
v.m.data2 := '0' & x"00000000" & mul_b(31 downto 0);
end if;
else
if d_in.decode.is_signed = '1' then
v.m.data1 := mul_a(63) & mul_a;
v.m.data2 := mul_b(63) & mul_b;
else
v.m.data1 := '0' & mul_a;
v.m.data2 := '0' & mul_b;
end if;
end if;
-- divide unit
-- PPC divide and modulus instruction words have these bits in
-- the bottom 11 bits: o1dns 010t1 r
-- where o = OE for div instrs, signedness for mod instrs
-- d = 1 for div*, 0 for mod*
-- n = 1 for normal, 0 for extended (dividend << 32/64)
-- s = 1 for signed, 0 for unsigned (for div*)
-- t = 1 for 32-bit, 0 for 64-bit
-- r = RC bit (record condition code)
v.d.write_reg := decode_output_reg(d_in.decode.output_reg_a, d_in.insn);
v.d.is_modulus := not d_in.insn(8);
v.d.is_32bit := d_in.insn(2);
if d_in.insn(8) = '1' then
signed_division := d_in.insn(6);
else
signed_division := d_in.insn(10);
end if;
v.d.is_signed := signed_division;
if d_in.insn(2) = '0' then
-- 64-bit forms
if d_in.insn(8) = '1' and d_in.insn(7) = '0' then
v.d.is_extended := '1';
end if;
v.d.dividend := decoded_reg_a.data;
v.d.divisor := decoded_reg_b.data;
else
-- 32-bit forms
if d_in.insn(8) = '1' and d_in.insn(7) = '0' then -- extended forms
v.d.dividend := decoded_reg_a.data(31 downto 0) & x"00000000";
elsif signed_division = '1' and decoded_reg_a.data(31) = '1' then
-- sign extend to 64 bits
v.d.dividend := x"ffffffff" & decoded_reg_a.data(31 downto 0);
else
v.d.dividend := x"00000000" & decoded_reg_a.data(31 downto 0);
end if;
if signed_division = '1' and decoded_reg_b.data(31) = '1' then
v.d.divisor := x"ffffffff" & decoded_reg_b.data(31 downto 0);
else
v.d.divisor := x"00000000" & decoded_reg_b.data(31 downto 0);
end if;
end if;
v.d.rc := decode_rc(d_in.decode.rc, d_in.insn);
-- load/store unit
v.l.update_reg := decoded_reg_a.reg;
v.l.addr1 := decoded_reg_a.data;
v.l.addr2 := decoded_reg_b.data;
v.l.data := decoded_reg_c.data;
v.l.write_reg := decode_output_reg(d_in.decode.output_reg_a, d_in.insn);
if d_in.decode.insn_type = OP_LOAD then
v.l.load := '1';
else
v.l.load := '0';
end if;
case d_in.decode.length is
when is1B =>
v.l.length := "0001";
when is2B =>
v.l.length := "0010";
when is4B =>
v.l.length := "0100";
when is8B =>
v.l.length := "1000";
when NONE =>
v.l.length := "0000";
end case;
v.l.byte_reverse := d_in.decode.byte_reverse;
v.l.sign_extend := d_in.decode.sign_extend;
v.l.update := d_in.decode.update;
-- issue control
control_valid_in <= d_in.valid;
control_sgl_pipe <= d_in.decode.sgl_pipe;
gpr_write_valid <= '1' when d_in.decode.output_reg_a /= NONE else '0';
gpr_write <= decode_output_reg(d_in.decode.output_reg_a, d_in.insn);
gpr_a_read_valid <= decoded_reg_a.reg_valid;
gpr_a_read <= decoded_reg_a.reg;
gpr_b_read_valid <= decoded_reg_b.reg_valid;
gpr_b_read <= decoded_reg_b.reg;
gpr_c_read_valid <= decoded_reg_c.reg_valid;
gpr_c_read <= decoded_reg_c.reg;
cr_write_valid <= d_in.decode.output_cr or decode_rc(d_in.decode.rc, d_in.insn);
v.e.valid := '0';
v.m.valid := '0';
v.d.valid := '0';
v.l.valid := '0';
case d_in.decode.unit is
when ALU =>
v.e.valid := control_valid_out;
when LDST =>
v.l.valid := control_valid_out;
when MUL =>
v.m.valid := control_valid_out;
when DIV =>
v.d.valid := control_valid_out;
when NONE =>
v.e.valid := control_valid_out;
v.e.insn_type := OP_ILLEGAL;
end case;
if rst = '1' then
v.e := Decode2ToExecute1Init;
v.l := Decode2ToLoadStore1Init;
v.m := Decode2ToMultiplyInit;
v.d := Decode2ToDividerInit;
end if;
-- Update registers
rin <= v;
-- Update outputs
e_out <= r.e;
l_out <= r.l;
m_out <= r.m;
d_out <= r.d;
end process;
end architecture behaviour;