MacPlus_MiSTer/rtl/tg68k/TG68K_ALU.vhd
2021-03-20 20:16:45 +08:00

1331 lines
44 KiB
VHDL

------------------------------------------------------------------------------
------------------------------------------------------------------------------
-- --
-- Copyright (c) 2009-2020 Tobias Gubener --
-- Patches by MikeJ, Till Harbaum, Rok Krajnk, ... --
-- Subdesign fAMpIGA by TobiFlex --
-- --
-- This source file is free software: you can redistribute it and/or modify --
-- it under the terms of the GNU Lesser General Public License as published --
-- by the Free Software Foundation, either version 3 of the License, or --
-- (at your option) any later version. --
-- --
-- This source file is distributed in the hope that it will be useful, --
-- but WITHOUT ANY WARRANTY; without even the implied warranty of --
-- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the --
-- GNU General Public License for more details. --
-- --
-- You should have received a copy of the GNU General Public License --
-- along with this program. If not, see <http://www.gnu.org/licenses/>. --
-- --
------------------------------------------------------------------------------
------------------------------------------------------------------------------
library ieee;
use ieee.std_logic_1164.all;
use ieee.std_logic_unsigned.all;
use IEEE.numeric_std.all;
use work.TG68K_Pack.all;
entity TG68K_ALU is
generic(
MUL_Mode : integer; --0=>16Bit, 1=>32Bit, 2=>switchable with CPU(1), 3=>no MUL,
MUL_Hardware : integer; --0=>no, 1=>yes,
DIV_Mode : integer; --0=>16Bit, 1=>32Bit, 2=>switchable with CPU(1), 3=>no DIV,
BarrelShifter :integer --0=>no, 1=>yes, 2=>switchable with CPU(1)
);
port(clk : in std_logic;
Reset : in std_logic;
clkena_lw : in std_logic:='1';
CPU : in std_logic_vector(1 downto 0):="00"; -- 00->68000 01->68010 11->68020(only some parts - yet)
execOPC : in bit;
decodeOPC : in bit;
exe_condition : in std_logic;
exec_tas : in std_logic;
long_start : in bit;
non_aligned : in std_logic;
check_aligned : in std_logic;
movem_presub : in bit;
set_stop : in bit;
Z_error : in bit;
rot_bits : in std_logic_vector(1 downto 0);
exec : in bit_vector(lastOpcBit downto 0);
OP1out : in std_logic_vector(31 downto 0);
OP2out : in std_logic_vector(31 downto 0);
reg_QA : in std_logic_vector(31 downto 0);
reg_QB : in std_logic_vector(31 downto 0);
opcode : in std_logic_vector(15 downto 0);
exe_opcode : in std_logic_vector(15 downto 0);
exe_datatype : in std_logic_vector(1 downto 0);
sndOPC : in std_logic_vector(15 downto 0);
last_data_read : in std_logic_vector(15 downto 0);
data_read : in std_logic_vector(15 downto 0);
FlagsSR : in std_logic_vector(7 downto 0);
micro_state : in micro_states;
bf_ext_in : in std_logic_vector(7 downto 0);
bf_ext_out : out std_logic_vector(7 downto 0);
bf_shift : in std_logic_vector(5 downto 0);
bf_width : in std_logic_vector(5 downto 0);
bf_ffo_offset : in std_logic_vector(31 downto 0);
bf_loffset : in std_logic_vector(4 downto 0);
set_V_Flag : buffer bit;
Flags : buffer std_logic_vector(7 downto 0);
c_out : buffer std_logic_vector(2 downto 0);
addsub_q : buffer std_logic_vector(31 downto 0);
ALUout : out std_logic_vector(31 downto 0)
);
end TG68K_ALU;
architecture logic of TG68K_ALU is
-----------------------------------------------------------------------------
-----------------------------------------------------------------------------
-- ALU and more
-----------------------------------------------------------------------------
-----------------------------------------------------------------------------
signal OP1in : std_logic_vector(31 downto 0);
signal addsub_a : std_logic_vector(31 downto 0);
signal addsub_b : std_logic_vector(31 downto 0);
signal notaddsub_b : std_logic_vector(33 downto 0);
signal add_result : std_logic_vector(33 downto 0);
signal addsub_ofl : std_logic_vector(2 downto 0);
signal opaddsub : bit;
signal c_in : std_logic_vector(3 downto 0);
signal flag_z : std_logic_vector(2 downto 0);
signal set_Flags : std_logic_vector(3 downto 0); --NZVC
signal CCRin : std_logic_vector(7 downto 0);
signal last_Flags1 : std_logic_vector(3 downto 0); --NZVC
--BCD
signal bcd_pur : std_logic_vector(9 downto 0);
signal bcd_kor : std_logic_vector(8 downto 0);
signal halve_carry : std_logic;
signal Vflag_a : std_logic;
signal bcd_a_carry : std_logic;
signal bcd_a : std_logic_vector(8 downto 0);
signal result_mulu : std_logic_vector(127 downto 0);
signal result_div : std_logic_vector(63 downto 0);
signal result_div_pre : std_logic_vector(31 downto 0);
signal set_mV_Flag : std_logic;
signal V_Flag : bit;
signal rot_rot : std_logic;
signal rot_lsb : std_logic;
signal rot_msb : std_logic;
signal rot_X : std_logic;
signal rot_C : std_logic;
signal rot_out : std_logic_vector(31 downto 0);
signal asl_VFlag : std_logic;
signal bit_bits : std_logic_vector(1 downto 0);
signal bit_number : std_logic_vector(4 downto 0);
signal bits_out : std_logic_vector(31 downto 0);
signal one_bit_in : std_logic;
signal bchg : std_logic;
signal bset : std_logic;
signal mulu_sign : std_logic;
signal mulu_signext : std_logic_vector(16 downto 0);
signal muls_msb : std_logic;
signal mulu_reg : std_logic_vector(63 downto 0);
signal FAsign : std_logic;
signal faktorA : std_logic_vector(31 downto 0);
signal faktorB : std_logic_vector(31 downto 0);
signal div_reg : std_logic_vector(63 downto 0);
signal div_quot : std_logic_vector(63 downto 0);
signal div_ovl : std_logic;
signal div_neg : std_logic;
signal div_bit : std_logic;
signal div_sub : std_logic_vector(32 downto 0);
signal div_over : std_logic_vector(32 downto 0);
signal nozero : std_logic;
signal div_qsign : std_logic;
signal dividend : std_logic_vector(63 downto 0);
signal divs : std_logic;
signal signedOP : std_logic;
signal OP1_sign : std_logic;
signal OP2_sign : std_logic;
signal OP2outext : std_logic_vector(15 downto 0);
signal in_offset : std_logic_vector(5 downto 0);
signal datareg : std_logic_vector(31 downto 0);
signal insert : std_logic_vector(31 downto 0);
signal bf_datareg : std_logic_vector(31 downto 0);
signal result : std_logic_vector(39 downto 0);
signal result_tmp : std_logic_vector(39 downto 0);
signal unshifted_bitmask: std_logic_vector(31 downto 0);
signal bf_set1 : std_logic_vector(39 downto 0);
signal inmux0 : std_logic_vector(39 downto 0);
signal inmux1 : std_logic_vector(39 downto 0);
signal inmux2 : std_logic_vector(39 downto 0);
signal inmux3 : std_logic_vector(31 downto 0);
signal shifted_bitmask : std_logic_vector(39 downto 0);
signal bitmaskmux0 : std_logic_vector(37 downto 0);
signal bitmaskmux1 : std_logic_vector(35 downto 0);
signal bitmaskmux2 : std_logic_vector(31 downto 0);
signal bitmaskmux3 : std_logic_vector(31 downto 0);
signal bf_set2 : std_logic_vector(31 downto 0);
signal shift : std_logic_vector(39 downto 0);
signal bf_firstbit : std_logic_vector(5 downto 0);
signal mux : std_logic_vector(3 downto 0);
signal bitnr : std_logic_vector(4 downto 0);
signal mask : std_logic_vector(31 downto 0);
signal mask_not_zero : std_logic;
signal bf_bset : std_logic;
signal bf_NFlag : std_logic;
signal bf_bchg : std_logic;
signal bf_ins : std_logic;
signal bf_exts : std_logic;
signal bf_fffo : std_logic;
signal bf_d32 : std_logic;
signal bf_s32 : std_logic;
signal index : std_logic_vector(4 downto 0);
-- signal i : integer range 0 to 31;
-- signal i : integer range 0 to 31;
-- signal i : std_logic_vector(5 downto 0);
signal hot_msb : std_logic_vector(33 downto 0);
signal vector : std_logic_vector(32 downto 0);
signal result_bs : std_logic_vector(65 downto 0);
signal bit_nr : std_logic_vector(5 downto 0);
signal bit_msb : std_logic_vector(5 downto 0);
signal bs_shift : std_logic_vector(5 downto 0);
signal bs_shift_mod : std_logic_vector(5 downto 0);
signal asl_over : std_logic_vector(32 downto 0);
signal asl_over_xor : std_logic_vector(32 downto 0);
signal asr_sign : std_logic_vector(32 downto 0);
signal msb : std_logic;
signal ring : std_logic_vector(5 downto 0);
signal ALU : std_logic_vector(31 downto 0);
signal BSout : std_logic_vector(31 downto 0);
signal bs_V : std_logic;
signal bs_C : std_logic;
signal bs_X : std_logic;
BEGIN
-----------------------------------------------------------------------------
-- set OP1in
-----------------------------------------------------------------------------
PROCESS (OP2out, reg_QB, opcode, OP1out, OP1in, exe_datatype, addsub_q, execOPC, exec,
bcd_a, result_mulu, result_div, exe_condition, bf_shift, bf_ffo_offset, mulu_reg, BSout,
Flags, FlagsSR, bits_out, exec_tas, rot_out, exe_opcode, result, bf_fffo, bf_firstbit, bf_datareg)
BEGIN
ALUout <= OP1in;
ALUout(7) <= OP1in(7) OR exec_tas;
IF exec(opcBFwb)='1' THEN
ALUout <= result(31 downto 0);
IF bf_fffo='1' THEN
ALUout <= bf_ffo_offset - bf_firstbit;
END IF;
END IF;
OP1in <= addsub_q;
IF exec(opcABCD)='1' OR exec(opcSBCD)='1' THEN
OP1in(7 downto 0) <= bcd_a(7 downto 0);
ELSIF exec(opcMULU)='1' AND MUL_Mode/=3 THEN
IF MUL_Hardware=0 THEN
IF exec(write_lowlong)='1' AND (MUL_Mode=1 OR MUL_Mode=2) THEN
OP1in <= result_mulu(31 downto 0);
ELSE
OP1in <= result_mulu(63 downto 32);
END IF;
ELSE
IF exec(write_lowlong)='1' THEN --AND (MUL_Mode=1 OR MUL_Mode=2) THEN
OP1in <= result_mulu(31 downto 0);
ELSE
-- OP1in <= result_mulu(63 downto 32);
OP1in <= mulu_reg(31 downto 0);
END IF;
END IF;
ELSIF exec(opcDIVU)='1' AND DIV_Mode/=3 THEN
IF exe_opcode(15)='1' OR DIV_Mode=0 THEN
-- IF exe_opcode(15)='1' THEN
OP1in <= result_div(47 downto 32)&result_div(15 downto 0); --word
ELSE --64bit
IF exec(write_reminder)='1' THEN
OP1in <= result_div(63 downto 32);
ELSE
OP1in <= result_div(31 downto 0);
END IF;
END IF;
ELSIF exec(opcOR)='1' THEN
OP1in <= OP2out OR OP1out;
ELSIF exec(opcAND)='1' THEN
OP1in <= OP2out AND OP1out;
ELSIF exec(opcScc)='1' THEN
OP1in(7 downto 0) <= (others=>exe_condition);
ELSIF exec(opcEOR)='1' THEN
OP1in <= OP2out XOR OP1out;
-- ELSIF exec(alu_move)='1' OR exec(exg)='1' THEN
ELSIF exec(alu_move)='1' THEN
-- OP1in <= OP2out(31 downto 8)&(OP2out(7)OR exec_tas)&OP2out(6 downto 0);
OP1in <= OP2out;
ELSIF exec(opcROT)='1' THEN
OP1in <= rot_out;
ELSIF exec(exec_BS)='1' THEN
OP1in <= BSout;
ELSIF exec(opcSWAP)='1' THEN
OP1in <= OP1out(15 downto 0)& OP1out(31 downto 16);
ELSIF exec(opcBITS)='1' THEN
OP1in <= bits_out;
ELSIF exec(opcBF)='1' THEN
OP1in <= bf_datareg; --new bitfieldvector for bfins - for others the old bitfieldvector
ELSIF exec(opcMOVESR)='1' THEN
OP1in(7 downto 0) <= Flags;
IF exe_opcode(9)='1' THEN
OP1in(15 downto 8) <= "00000000";
ELSE
OP1in(15 downto 8) <= FlagsSR;
END IF;
ELSIF exec(opcPACK)='1' THEN
OP1in(7 downto 0) <= addsub_q(11 downto 8) & addsub_q(3 downto 0);
END IF;
END PROCESS;
-----------------------------------------------------------------------------
-- addsub
-----------------------------------------------------------------------------
PROCESS (OP1out, OP2out, execOPC, Flags, long_start, movem_presub, exe_datatype, exec, addsub_a, addsub_b, opaddsub,
notaddsub_b, add_result, c_in, sndOPC, non_aligned, check_aligned)
BEGIN
addsub_a <= OP1out;
IF exec(get_bfoffset)='1' THEN
IF sndOPC(11)='1' THEN
addsub_a <= OP1out(31)&OP1out(31)&OP1out(31)&OP1out(31 downto 3);
ELSE
addsub_a <= "000000000000000000000000000000"&sndOPC(10 downto 9);
END IF;
END IF;
IF exec(subidx)='1' THEN
opaddsub <= '1';
ELSE
opaddsub <= '0';
END IF;
c_in(0) <='0';
addsub_b <= OP2out;
IF exec(opcUNPACK)='1' THEN
addsub_b(15 downto 0) <= "0000" & OP2out(7 downto 4) & "0000" & OP2out(3 downto 0);
ELSIF execOPC='0' AND exec(OP2out_one)='0' AND exec(get_bfoffset)='0'THEN
IF long_start='0' AND exe_datatype="00" AND exec(use_SP)='0' THEN
addsub_b <= "00000000000000000000000000000001";
ELSIF long_start='0' AND exe_datatype="10" AND (exec(presub) OR exec(postadd) OR movem_presub)='1' THEN
IF exec(movem_action)='1' THEN
addsub_b <= "00000000000000000000000000000110";
ELSE
addsub_b <= "00000000000000000000000000000100";
END IF;
ELSE
addsub_b <= "00000000000000000000000000000010";
END IF;
ELSE
IF (exec(use_XZFlag)='1' AND Flags(4)='1') OR exec(opcCHK)='1' THEN
c_in(0) <= '1';
END IF;
opaddsub <= exec(addsub);
END IF;
-- patch for un-aligned movem --mikej
if exec(movem_action)='1' OR check_aligned='1' then
if (movem_presub = '0') then -- up
if (non_aligned = '1') and (long_start = '0') then -- hold
addsub_b <= (others => '0');
end if;
else
if (non_aligned = '1') and (long_start = '0') then
if (exe_datatype = "10") then
addsub_b <= "00000000000000000000000000001000";
else
addsub_b <= "00000000000000000000000000000100";
end if;
end if;
end if;
end if;
IF opaddsub='0' OR long_start='1' THEN --ADD
notaddsub_b <= '0'&addsub_b&c_in(0);
ELSE --SUB
notaddsub_b <= NOT ('0'&addsub_b&c_in(0));
END IF;
add_result <= (('0'&addsub_a&notaddsub_b(0))+notaddsub_b);
c_in(1) <= add_result(9) XOR addsub_a(8) XOR addsub_b(8);
c_in(2) <= add_result(17) XOR addsub_a(16) XOR addsub_b(16);
c_in(3) <= add_result(33);
addsub_q <= add_result(32 downto 1);
addsub_ofl(0) <= (c_in(1) XOR add_result(8) XOR addsub_a(7) XOR addsub_b(7)); --V Byte
addsub_ofl(1) <= (c_in(2) XOR add_result(16) XOR addsub_a(15) XOR addsub_b(15)); --V Word
addsub_ofl(2) <= (c_in(3) XOR add_result(32) XOR addsub_a(31) XOR addsub_b(31)); --V Long
c_out <= c_in(3 downto 1);
END PROCESS;
------------------------------------------------------------------------------
--ALU
------------------------------------------------------------------------------
PROCESS (OP1out, OP2out, CPU, exec, add_result, bcd_pur, bcd_a, bcd_kor, halve_carry, c_in)
BEGIN
--BCD_ARITH-------------------------------------------------------------------
--04.04.2017 by Tobiflex - BCD handling with all undefined behavior!
bcd_pur <= c_in(1)&add_result(8 downto 0);
bcd_kor <= "000000000";
halve_carry <= OP1out(4) XOR OP2out(4) XOR bcd_pur(5);
IF halve_carry='1' THEN
bcd_kor(3 downto 0) <= "0110"; -- -6
END IF;
IF bcd_pur(9)='1' THEN
bcd_kor(7 downto 4) <= "0110"; -- -60
END IF;
IF exec(opcABCD)='1' THEN
Vflag_a <= NOT bcd_pur(8) AND bcd_a(7);
-- bcd_pur <= ('0'&OP1out(7 downto 0)&'1') + ('0'&OP2out(7 downto 0)&Flags(4));
bcd_a <= bcd_pur(9 downto 1) + bcd_kor;
IF (bcd_pur(4) AND (bcd_pur(3) OR bcd_pur(2)))='1' THEN
bcd_kor(3 downto 0) <= "0110"; -- +6
END IF;
IF (bcd_pur(8) AND (bcd_pur(7) OR bcd_pur(6) OR (bcd_pur(5) AND bcd_pur(4) AND (bcd_pur(3) OR bcd_pur(2)))))='1' THEN
bcd_kor(7 downto 4) <= "0110"; -- +60
END IF;
ELSE --opcSBCD
Vflag_a <= bcd_pur(8) AND NOT bcd_a(7);
-- bcd_pur <= ('0'&OP1out(7 downto 0)&'0') - ('0'&OP2out(7 downto 0)&Flags(4));
bcd_a <= bcd_pur(9 downto 1) - bcd_kor;
END IF;
IF cpu(1)='1' THEN
Vflag_a <= '0'; --68020
END IF;
bcd_a_carry <= bcd_pur(9) OR bcd_a(8);
END PROCESS;
-----------------------------------------------------------------------------
-- Bits
-----------------------------------------------------------------------------
PROCESS (clk, exe_opcode, OP1out, OP2out, reg_QB, one_bit_in, bchg, bset, bit_Number, sndOPC)
BEGIN
IF rising_edge(clk) THEN
IF clkena_lw = '1' THEN
bchg <= '0';
bset <= '0';
CASE opcode(7 downto 6) IS
WHEN "01" => --bchg
bchg <= '1';
WHEN "11" => --bset
bset <= '1';
WHEN OTHERS => NULL;
END CASE;
END IF;
END IF;
IF exe_opcode(8)='0' THEN
IF exe_opcode(5 downto 4)="00" THEN
bit_number <= sndOPC(4 downto 0);
ELSE
bit_number <= "00"&sndOPC(2 downto 0);
END IF;
ELSE
IF exe_opcode(5 downto 4)="00" THEN
bit_number <= reg_QB(4 downto 0);
ELSE
bit_number <= "00"&reg_QB(2 downto 0);
END IF;
END IF;
one_bit_in <= OP1out(conv_integer(bit_Number));
bits_out <= OP1out;
bits_out(conv_integer(bit_Number)) <= (bchg AND NOT one_bit_in) OR bset ;
END PROCESS;
-----------------------------------------------------------------------------
-- Bit Field
-----------------------------------------------------------------------------
PROCESS (clk, mux, mask, bitnr, bf_ins, bf_bchg, bf_bset, bf_exts, bf_shift, inmux0, inmux1, inmux2, inmux3, bf_set2, OP1out, OP2out,
result_tmp, bf_ext_in, mask_not_zero, exec, shift, datareg, bf_NFlag, result, reg_QB, unshifted_bitmask, bf_d32, bf_s32,
shifted_bitmask, bf_loffset, bitmaskmux0, bitmaskmux1, bitmaskmux2, bitmaskmux3, bf_width)
BEGIN
IF rising_edge(clk) THEN
IF clkena_lw = '1' THEN
bf_bset <= '0';
bf_bchg <= '0';
bf_ins <= '0';
bf_exts <= '0';
bf_fffo <= '0';
bf_d32 <= '0';
bf_s32 <= '0';
-- 000-bftst, 001-bfextu, 010-bfchg, 011-bfexts, 100-bfclr, 101-bfff0, 110-bfset, 111-bfins
IF opcode(5 downto 4) ="00" THEN
bf_s32 <= '1';
END IF;
CASE opcode(10 downto 8) IS
WHEN "010" => bf_bchg <= '1'; --BFCHG
WHEN "011" => bf_exts <= '1'; --BFEXTS
-- WHEN "100" => insert <= (OTHERS =>'0'); --BFCLR
WHEN "101" => bf_fffo <= '1'; --BFFFO
WHEN "110" => bf_bset <= '1'; --BFSET
WHEN "111" => bf_ins <= '1'; --BFINS
bf_s32 <= '1';
WHEN OTHERS => NULL;
END CASE;
IF opcode(4 downto 3)="00" THEN
bf_d32 <= '1';
END IF;
bf_ext_out <= result(39 downto 32);
END IF;
END IF;
IF bf_ins='1' THEN
datareg <= reg_QB;
ELSE
datareg <= bf_set2;
END IF;
-- create bitmask for operation
-- unshifted bitmask '0' => bit is in the Bitfieldvector
-- '1' => bit isn't in the Bitfieldvector
-- Example bf_with=11 => "11111111 11111111 11111000 00000000"
-- datareg
unshifted_bitmask <= (OTHERS => '0');
FOR i in 0 to 31 LOOP
IF i>bf_width(4 downto 0) THEN
datareg(i) <= '0';
unshifted_bitmask(i) <= '1';
END IF;
END LOOP;
bf_NFlag <= datareg(conv_integer(bf_width));
IF bf_exts='1' AND bf_NFlag='1' THEN
bf_datareg <= datareg OR unshifted_bitmask;
ELSE
bf_datareg <= datareg;
END IF;
-- shift bitmask for operation
IF bf_loffset(4)='1' THEN
bitmaskmux3 <= unshifted_bitmask(15 downto 0)&unshifted_bitmask(31 downto 16);
ELSE
bitmaskmux3 <= unshifted_bitmask;
END IF;
IF bf_loffset(3)='1' THEN
bitmaskmux2(31 downto 0) <= bitmaskmux3(23 downto 0)&bitmaskmux3(31 downto 24);
ELSE
bitmaskmux2(31 downto 0) <= bitmaskmux3;
END IF;
IF bf_loffset(2)='1' THEN
bitmaskmux1 <= bitmaskmux2&"1111";
IF bf_d32='1' THEN
bitmaskmux1(3 downto 0) <= bitmaskmux2(31 downto 28);
END IF;
ELSE
bitmaskmux1 <= "1111"&bitmaskmux2;
END IF;
IF bf_loffset(1)='1' THEN
bitmaskmux0 <= bitmaskmux1&"11";
IF bf_d32='1' THEN
bitmaskmux0(1 downto 0) <= bitmaskmux1(31 downto 30);
END IF;
ELSE
bitmaskmux0 <= "11"&bitmaskmux1;
END IF;
IF bf_loffset(0)='1' THEN
shifted_bitmask <= '1'&bitmaskmux0&'1';
IF bf_d32='1' THEN
shifted_bitmask(0) <= bitmaskmux0(31);
END IF;
ELSE
shifted_bitmask <= "11"&bitmaskmux0;
END IF;
-- shift for ins
shift <= bf_ext_in&OP2out;
IF bf_s32='1' THEN
shift(39 downto 32) <= OP2out(7 downto 0);
END IF;
IF bf_shift(0)='1' THEN
inmux0 <= shift(0)&shift(39 downto 1);
ELSE
inmux0 <= shift;
END IF;
IF bf_shift(1)='1' THEN
inmux1 <= inmux0(1 downto 0)&inmux0(39 downto 2);
ELSE
inmux1 <= inmux0;
END IF;
IF bf_shift(2)='1' THEN
inmux2 <= inmux1(3 downto 0)&inmux1(39 downto 4);
ELSE
inmux2 <= inmux1;
END IF;
IF bf_shift(3)='1' THEN
inmux3 <= inmux2(7 downto 0)&inmux2(31 downto 8);
ELSE
inmux3 <= inmux2(31 downto 0);
END IF;
IF bf_shift(4)='1' THEN
bf_set2(31 downto 0) <= inmux3(15 downto 0)&inmux3(31 downto 16);
ELSE
bf_set2(31 downto 0) <= inmux3;
END IF;
IF bf_ins='1' THEN
result(31 downto 0) <= bf_set2;
result(39 downto 32) <= bf_set2(7 downto 0);
ELSIF bf_bchg='1' THEN
result(31 downto 0) <= NOT OP2out;
result(39 downto 32) <= NOT bf_ext_in;
ELSE
result <= (OTHERS => '0');
END IF;
IF bf_bset='1' THEN
result <= (OTHERS => '1');
END IF;
--
IF bf_ins='1' THEN
result_tmp <= bf_ext_in&OP1out;
ELSE
result_tmp <= bf_ext_in&OP2out;
END IF;
FOR i in 0 to 39 LOOP
IF shifted_bitmask(i)='1' THEN
result(i) <= result_tmp(i); --restore old data
END IF;
END LOOP;
--BFFFO
mask <= datareg;
bf_firstbit <= ('0'&bitnr)+mask_not_zero;
bitnr <= "11111";
mask_not_zero <= '1';
IF mask(31 downto 28)="0000" THEN
IF mask(27 downto 24)="0000" THEN
IF mask(23 downto 20)="0000" THEN
IF mask(19 downto 16)="0000" THEN
bitnr(4) <= '0';
IF mask(15 downto 12)="0000" THEN
IF mask(11 downto 8)="0000" THEN
bitnr(3) <= '0';
IF mask(7 downto 4)="0000" THEN
bitnr(2) <= '0';
mux <= mask(3 downto 0);
ELSE
mux <= mask(7 downto 4);
END IF;
ELSE
mux <= mask(11 downto 8);
bitnr(2) <= '0';
END IF;
ELSE
mux <= mask(15 downto 12);
END IF;
ELSE
mux <= mask(19 downto 16);
bitnr(3) <= '0';
bitnr(2) <= '0';
END IF;
ELSE
mux <= mask(23 downto 20);
bitnr(3) <= '0';
END IF;
ELSE
mux <= mask(27 downto 24);
bitnr(2) <= '0';
END IF;
ELSE
mux <= mask(31 downto 28);
END IF;
IF mux(3 downto 2)="00" THEN
bitnr(1) <= '0';
IF mux(1)='0' THEN
bitnr(0) <= '0';
IF mux(0)='0' THEN
mask_not_zero <= '0';
END IF;
END IF;
ELSE
IF mux(3)='0' THEN
bitnr(0) <= '0';
END IF;
END IF;
END PROCESS;
-----------------------------------------------------------------------------
-- Rotation
-----------------------------------------------------------------------------
PROCESS (exe_opcode, OP1out, Flags, rot_bits, rot_msb, rot_lsb, rot_rot, exec, BSout)
BEGIN
CASE exe_opcode(7 downto 6) IS
WHEN "00" => --Byte
rot_rot <= OP1out(7);
WHEN "01"|"11" => --Word
rot_rot <= OP1out(15);
WHEN "10" => --Long
rot_rot <= OP1out(31);
WHEN OTHERS => NULL;
END CASE;
CASE rot_bits IS
WHEN "00" => --ASL, ASR
rot_lsb <= '0';
rot_msb <= rot_rot;
WHEN "01" => --LSL, LSR
rot_lsb <= '0';
rot_msb <= '0';
WHEN "10" => --ROXL, ROXR
rot_lsb <= Flags(4);
rot_msb <= Flags(4);
WHEN "11" => --ROL, ROR
rot_lsb <= rot_rot;
rot_msb <= OP1out(0);
WHEN OTHERS => NULL;
END CASE;
IF exec(rot_nop)='1' THEN
rot_out <= OP1out;
rot_X <= Flags(4);
IF rot_bits="10" THEN --ROXL, ROXR
rot_C <= Flags(4);
ELSE
rot_C <= '0';
END IF;
ELSE
IF exe_opcode(8)='1' THEN --left
rot_out <= OP1out(30 downto 0)&rot_lsb;
rot_X <= rot_rot;
rot_C <= rot_rot;
ELSE --right
rot_X <= OP1out(0);
rot_C <= OP1out(0);
rot_out <= rot_msb&OP1out(31 downto 1);
CASE exe_opcode(7 downto 6) IS
WHEN "00" => --Byte
rot_out(7) <= rot_msb;
WHEN "01"|"11" => --Word
rot_out(15) <= rot_msb;
WHEN OTHERS => NULL;
END CASE;
END IF;
IF BarrelShifter/=0 THEN
rot_out <= BSout;
END IF;
END IF;
END PROCESS;
-----------------------------------------------------------------------------
-- Barrel Shifter
-----------------------------------------------------------------------------
process (OP1out, OP2out, opcode, bit_nr, bit_msb, bs_shift, bs_shift_mod, ring, result_bs, exe_opcode, vector,
rot_bits, Flags, bs_C, msb, hot_msb, asl_over, asl_over_xor, ALU, asr_sign, exec)
begin
ring <= "100000";
IF rot_bits="10" THEN --ROX L/R
CASE exe_opcode(7 downto 6) IS
WHEN "00" => --Byte
ring <= "001001";
WHEN "01"|"11" => --Word
ring <= "010001";
WHEN "10" => --Long
ring <= "100001";
WHEN OTHERS => NULL;
END CASE;
ELSE
CASE exe_opcode(7 downto 6) IS
WHEN "00" => --Byte
ring <= "001000";
WHEN "01"|"11" => --Word
ring <= "010000";
WHEN "10" => --Long
ring <= "100000";
WHEN OTHERS => NULL;
END CASE;
END IF;
IF exe_opcode(7 downto 6)="11" OR exec(exec_BS)='0' THEN
bs_shift <="000001";
ELSIF exe_opcode(5)='1' THEN
bs_shift <= OP2out(5 downto 0);
ELSE
bs_shift(2 downto 0) <= exe_opcode(11 downto 9);
IF exe_opcode(11 downto 9)="000" THEN
bs_shift(5 downto 3) <="001";
ELSE
bs_shift(5 downto 3) <="000";
END IF;
END IF;
-- calc V-Flag by ASL
bit_msb <= "000000";
hot_msb <= (OTHERS =>'0');
hot_msb(conv_integer(bit_msb)) <= '1';
IF bs_shift < ring THEN
bit_msb <= ring-bs_shift;
END IF;
asl_over_xor <= (('0'&vector(30 downto 0)) XOR ('0'&vector(31 downto 1)))&msb;
CASE exe_opcode(7 downto 6) IS
WHEN "00" => --Byte
asl_over_xor(8) <= '0';
WHEN "01"|"11" => --Word
asl_over_xor(16) <= '0';
WHEN OTHERS => NULL;
END CASE;
asl_over <= asl_over_xor - ('0'&hot_msb(31 downto 0));
bs_V <= '0';
IF rot_bits="00" AND exe_opcode(8)='1' THEN --ASL
bs_V <= not asl_over(32);
END IF;
bs_X <= bs_C;
IF exe_opcode(8)='0' THEN --right shift
bs_C <= result_bs(31);
ELSE --left shift
CASE exe_opcode(7 downto 6) IS
WHEN "00" => --Byte
bs_C <= result_bs(8);
WHEN "01"|"11" => --Word
bs_C <= result_bs(16);
WHEN "10" => --Long
bs_C <= result_bs(32);
WHEN OTHERS => NULL;
END CASE;
END IF;
ALU <= (others=>'-');
IF rot_bits="11" THEN --RO L/R
bs_X <= Flags(4);
CASE exe_opcode(7 downto 6) IS
WHEN "00" => --Byte
ALU(7 downto 0) <= result_bs(7 downto 0) OR result_bs(15 downto 8);
bs_C <= ALU(7);
WHEN "01"|"11" => --Word
ALU(15 downto 0) <= result_bs(15 downto 0) OR result_bs(31 downto 16);
bs_C <= ALU(15);
WHEN "10" => --Long
ALU <= result_bs(31 downto 0) OR result_bs(63 downto 32);
bs_C <= ALU(31);
WHEN OTHERS => NULL;
END CASE;
IF exe_opcode(8)='1' THEN --left shift
bs_C <= ALU(0);
END IF;
ELSIF rot_bits="10" THEN --ROX L/R
CASE exe_opcode(7 downto 6) IS
WHEN "00" => --Byte
ALU(7 downto 0) <= result_bs(7 downto 0) OR result_bs(16 downto 9);
bs_C <= result_bs(8) OR result_bs(17);
WHEN "01"|"11" => --Word
ALU(15 downto 0) <= result_bs(15 downto 0) OR result_bs(32 downto 17);
bs_C <= result_bs(16) OR result_bs(33);
WHEN "10" => --Long
ALU <= result_bs(31 downto 0) OR result_bs(64 downto 33);
bs_C <= result_bs(32) OR result_bs(65);
WHEN OTHERS => NULL;
END CASE;
ELSE
IF exe_opcode(8)='0' THEN --right shift
ALU <= result_bs(63 downto 32);
ELSE --left shift
ALU <= result_bs(31 downto 0);
END IF;
END IF;
IF(bs_shift = "000000") THEN
IF rot_bits="10" THEN --ROX L/R
bs_C <= Flags(4);
ELSE
bs_C <= '0';
END IF;
bs_X <= Flags(4);
bs_V <= '0';
END IF;
-- calc shift count
-- bs_shift_mod <= std_logic_vector(unsigned(bs_shift) rem unsigned(ring));
-- replace the divider with logic
CASE ring IS
WHEN "001001" =>
IF bs_shift = 63 THEN
bs_shift_mod <= "000000";
ELSIF bs_shift > 6*9-1 THEN
bs_shift_mod <= bs_shift - 6*9;
ELSIF bs_shift > 5*9-1 THEN
bs_shift_mod <= bs_shift - 5*9;
ELSIF bs_shift > 4*9-1 THEN
bs_shift_mod <= bs_shift - 4*9;
ELSIF bs_shift > 3*9-1 THEN
bs_shift_mod <= bs_shift - 3*9;
ELSIF bs_shift > 2*9-1 THEN
bs_shift_mod <= bs_shift - 2*9;
ELSIF bs_shift > 9-1 THEN
bs_shift_mod <= bs_shift - 9;
ELSE
bs_shift_mod <= bs_shift;
END IF;
WHEN "010001" =>
IF bs_shift > 3*17-1 THEN
bs_shift_mod <= bs_shift - 3*17;
ELSIF bs_shift > 2*17-1 THEN
bs_shift_mod <= bs_shift - 2*17;
ELSIF bs_shift > 17-1 THEN
bs_shift_mod <= bs_shift - 17;
ELSE
bs_shift_mod <= bs_shift;
END IF;
WHEN "100001" =>
IF bs_shift > 32 THEN
bs_shift_mod <= bs_shift - 33;
ELSE
bs_shift_mod <= bs_shift;
END IF;
WHEN "001000" => bs_shift_mod <= "000" & bs_shift(2 downto 0);
WHEN "010000" => bs_shift_mod <= "00" & bs_shift(3 downto 0);
WHEN "100000" => bs_shift_mod <= "0" & bs_shift(4 downto 0);
WHEN OTHERS => bs_shift_mod <= (OTHERS => '0');
END CASE;
bit_nr <= bs_shift_mod(5 downto 0);
IF exe_opcode(8)='0' THEN --right shift
bit_nr <= ring-bs_shift_mod;
END IF;
IF rot_bits(1)='0' THEN --only shift
IF exe_opcode(8)='0' THEN --right shift
bit_nr <= 32-bs_shift_mod;
END IF;
IF bs_shift = ring THEN
IF exe_opcode(8)='0' THEN --right shift
bit_nr <= 32-ring;
ELSE
bit_nr <= ring;
END IF;
END IF;
IF bs_shift > ring THEN
IF exe_opcode(8)='0' THEN --right shift
bit_nr <= "000000";
bs_C <= '0';
ELSE
bit_nr <= ring+1;
END IF;
END IF;
END IF;
-- calc ASR sign
BSout <= ALU;
asr_sign <= (OTHERS =>'0');
asr_sign(32 downto 1) <= asr_sign(31 downto 0) OR hot_msb(31 downto 0);
IF rot_bits="00" AND exe_opcode(8)='0' AND msb='1' THEN --ASR
BSout <= ALU or asr_sign(32 downto 1);
IF bs_shift > ring THEN
bs_C <= '1';
END IF;
END IF;
vector(32 downto 0) <= '0'&OP1out;
CASE exe_opcode(7 downto 6) IS
WHEN "00" => --Byte
msb <= OP1out(7);
vector(31 downto 8) <= X"000000";
BSout(31 downto 8) <= X"000000";
IF rot_bits="10" THEN --ROX L/R
vector(8) <= Flags(4);
END IF;
WHEN "01"|"11" => --Word
msb <= OP1out(15);
vector(31 downto 16) <= X"0000";
BSout(31 downto 16) <= X"0000";
IF rot_bits="10" THEN --ROX L/R
vector(16) <= Flags(4);
END IF;
WHEN "10" => --Long
msb <= OP1out(31);
IF rot_bits="10" THEN --ROX L/R
vector(32) <= Flags(4);
END IF;
WHEN OTHERS => NULL;
END CASE;
result_bs <= std_logic_vector(unsigned('0'&X"00000000"&vector) sll to_integer(unsigned(bit_nr(5 downto 0))));
end process;
------------------------------------------------------------------------------
--CCR op
------------------------------------------------------------------------------
PROCESS (clk, Reset, exe_opcode, exe_datatype, Flags, last_data_read, OP2out, flag_z, OP1IN, c_out, addsub_ofl,
bcd_a, bcd_a_carry, Vflag_a, exec)
BEGIN
IF exec(andiSR)='1' THEN
CCRin <= Flags AND last_data_read(7 downto 0);
ELSIF exec(eoriSR)='1' THEN
CCRin <= Flags XOR last_data_read(7 downto 0);
ELSIF exec(oriSR)='1' THEN
CCRin <= Flags OR last_data_read(7 downto 0);
ELSE
CCRin <= OP2out(7 downto 0);
END IF;
------------------------------------------------------------------------------
--Flags
------------------------------------------------------------------------------
flag_z <= "000";
IF exec(use_XZFlag)='1' AND flags(2)='0' THEN
flag_z <= "000";
ELSIF OP1in(7 downto 0)="00000000" THEN
flag_z(0) <= '1';
IF OP1in(15 downto 8)="00000000" THEN
flag_z(1) <= '1';
IF OP1in(31 downto 16)="0000000000000000" THEN
flag_z(2) <= '1';
END IF;
END IF;
END IF;
-- --Flags NZVC
IF exe_datatype="00" THEN --Byte
set_flags <= OP1IN(7)&flag_z(0)&addsub_ofl(0)&c_out(0);
IF exec(opcABCD)='1' OR exec(opcSBCD)='1' THEN
set_flags(0) <= bcd_a_carry;
set_flags(1) <= Vflag_a;
END IF;
ELSIF exe_datatype="10" OR exec(opcCPMAW)='1' THEN --Long
set_flags <= OP1IN(31)&flag_z(2)&addsub_ofl(2)&c_out(2);
ELSE --Word
set_flags <= OP1IN(15)&flag_z(1)&addsub_ofl(1)&c_out(1);
END IF;
IF rising_edge(clk) THEN
IF Reset='1' THEN
Flags(7 downto 0) <= "00000000";
ELSIF clkena_lw = '1' THEN
IF exec(directSR)='1' OR set_stop='1' THEN
Flags(7 downto 0) <= data_read(7 downto 0);
END IF;
IF exec(directCCR)='1' THEN
Flags(7 downto 0) <= data_read(7 downto 0);
END IF;
IF exec(opcROT)='1' AND decodeOPC='0' THEN
asl_VFlag <= ((set_flags(3) XOR rot_rot) OR asl_VFlag);
ELSE
asl_VFlag <= '0';
END IF;
IF exec(to_CCR)='1' THEN
Flags(7 downto 0) <= CCRin(7 downto 0); --CCR
ELSIF Z_error='1' THEN
IF micro_state = trap0 THEN
-- Undocumented behavior (flags when div by zero)
IF exe_opcode(8)='0' THEN
-- Flags(3 downto 0) <= reg_QA(31)&"000";
Flags(3 downto 0) <= '0'&NOT reg_QA(31)&"00";
ELSE
Flags(3 downto 0) <= "0100";
END IF;
END IF;
ELSIF exec(no_Flags)='0' THEN
last_Flags1 <= Flags(3 downto 0);
IF exec(opcADD)='1' THEN
Flags(4) <= set_flags(0);
ELSIF exec(opcROT)='1' AND rot_bits/="11" AND exec(rot_nop)='0' THEN
Flags(4) <= rot_X;
ELSIF exec(exec_BS)='1' THEN
Flags(4) <= BS_X;
END IF;
IF (exec(opcCMP) OR exec(alu_setFlags))='1' THEN
Flags(3 downto 0) <= set_flags;
ELSIF exec(opcDIVU)='1' AND DIV_Mode/=3 THEN
IF V_Flag='1' THEN
Flags(3 downto 0) <= "1010";
ELSIF exe_opcode(15)='1' OR DIV_Mode=0 THEN
Flags(3 downto 0) <= OP1IN(15)&flag_z(1)&"00";
ELSE
Flags(3 downto 0) <= OP1IN(31)&flag_z(2)&"00";
END IF;
ELSIF exec(write_reminder)='1' AND MUL_Mode/=3 THEN -- z-flag MULU.l
Flags(3) <= set_flags(3);
Flags(2) <= set_flags(2) AND Flags(2);
Flags(1) <= '0';
Flags(0) <= '0';
ELSIF exec(write_lowlong)='1' AND (MUL_Mode=1 OR MUL_Mode=2) THEN -- flag MULU.l
Flags(3) <= set_flags(3);
Flags(2) <= set_flags(2);
Flags(1) <= set_mV_Flag; --V
Flags(0) <= '0';
ELSIF exec(opcOR)='1' OR exec(opcAND)='1' OR exec(opcEOR)='1' OR exec(opcMOVE)='1' OR exec(opcMOVEQ)='1' OR exec(opcSWAP)='1' OR exec(opcBF)='1' OR (exec(opcMULU)='1' AND MUL_Mode/=3) THEN
Flags(1 downto 0) <= "00";
Flags(3 downto 2) <= set_flags(3 downto 2);
IF exec(opcBF)='1' THEN
Flags(3) <= bf_NFlag;
END IF;
ELSIF exec(opcROT)='1' THEN
Flags(3 downto 2) <= set_flags(3 downto 2);
Flags(0) <= rot_C;
IF rot_bits="00" AND ((set_flags(3) XOR rot_rot) OR asl_VFlag)='1' THEN --ASL/ASR
Flags(1) <= '1';
ELSE
Flags(1) <= '0';
END IF;
ELSIF exec(exec_BS)='1' THEN
Flags(3 downto 2) <= set_flags(3 downto 2);
Flags(0) <= BS_C;
Flags(1) <= BS_V;
ELSIF exec(opcBITS)='1' THEN
Flags(2) <= NOT one_bit_in;
ELSIF exec(opcCHK2)='1' THEN --micro_state = chk23
--micro_state chk21 chk22 chk23
--OP1out UB R R
--OP2out LB LB UB
----lower bound first
IF last_Flags1(0)='0' THEN --unsigned OP
Flags(0) <= Flags(0) OR (NOT set_flags(0) AND NOT set_flags(2));
ELSE --signed OP
Flags(0) <= (Flags(0) XOR set_flags(0)) AND NOT Flags(2) AND NOT set_flags(2);
END IF;
Flags(1) <= '0';
Flags(2) <= Flags(2) OR set_flags(2);
Flags(3) <= NOT last_Flags1(0);
ELSIF exec(opcCHK)='1' THEN
IF exe_datatype="01" THEN --Word
Flags(3) <= OP1out(15);
ELSE
Flags(3) <= OP1out(31);
END IF;
IF OP1out(15 downto 0)=X"0000" AND (exe_datatype="01" OR OP1out(31 downto 16)=X"0000") THEN
Flags(2) <='1';
ELSE
Flags(2) <='0';
END IF;
Flags(1) <= '0';
Flags(0) <= '0';
END IF;
END IF;
END IF;
Flags(7 downto 5) <= "000";
END IF;
END PROCESS;
---------------------------------------------------------------------------------
------ MULU/MULS
---------------------------------------------------------------------------------
PROCESS (exe_opcode, OP2out, muls_msb, mulu_reg, FAsign, mulu_sign, reg_QA, faktorA, faktorB, result_mulu, signedOP)
--PROCESS (exec, reg_QA, OP2out, faktorA, faktorB, signedOP)
BEGIN
IF MUL_Hardware=1 THEN
-- IF exe_opcode(15)='1' OR MUL_Mode=0 THEN -- 16 Bit
IF MUL_Mode=0 THEN -- 16 Bit
IF signedOP='1' AND reg_QA(15)='1' THEN
faktorA <= X"FFFFFFFF";
ELSE
faktorA <= X"00000000";
END IF;
IF signedOP='1' AND OP2out(15)='1' THEN
faktorB <= X"FFFFFFFF";
ELSE
faktorB <= X"00000000";
END IF;
result_mulu(63 downto 0) <= (faktorA(15 downto 0) & reg_QA(15 downto 0)) * (faktorB(15 downto 0) & OP2out(15 downto 0));
ELSE
IF exe_opcode(15)='1' THEN -- 16 Bit
IF signedOP='1' AND reg_QA(15)='1' THEN
faktorA <= X"FFFFFFFF";
ELSE
faktorA <= X"00000000";
END IF;
IF signedOP='1' AND OP2out(15)='1' THEN
faktorB <= X"FFFFFFFF";
ELSE
faktorB <= X"00000000";
END IF;
ELSE
faktorA(15 downto 0) <= reg_QA(31 downto 16);
faktorB(15 downto 0) <= OP2out(31 downto 16);
IF signedOP='1' AND reg_QA(31)='1' THEN
faktorA(31 downto 16) <= X"FFFF";
ELSE
faktorA(31 downto 16) <= X"0000";
END IF;
IF signedOP='1' AND OP2out(31)='1' THEN
faktorB(31 downto 16) <= X"FFFF";
ELSE
faktorB(31 downto 16) <= X"0000";
END IF;
END IF;
result_mulu(127 downto 0) <= (faktorA(31 downto 16) & faktorA(31 downto 0) & reg_QA(15 downto 0)) * (faktorB(31 downto 16) & faktorB(31 downto 0) & OP2out(15 downto 0));
END IF;
-- END PROCESS;
-------------------------------------------------------------------------------
---- MULU/MULS
-------------------------------------------------------------------------------
--PROCESS (exe_opcode, OP2out, muls_msb, mulu_reg, FAsign, mulu_sign, reg_QA, faktorB, result_mulu, signedOP)
-- BEGIN
ELSE
IF (signedOP='1' AND faktorB(31)='1') OR FAsign='1' THEN
muls_msb <= mulu_reg(63);
ELSE
muls_msb <= '0';
END IF;
IF signedOP='1' AND faktorB(31)='1' THEN
mulu_sign <= '1';
ELSE
mulu_sign <= '0';
END IF;
IF MUL_Mode=0 THEN -- 16 Bit
result_mulu(63 downto 32) <= muls_msb&mulu_reg(63 downto 33);
result_mulu(15 downto 0) <= 'X'&mulu_reg(15 downto 1);
IF mulu_reg(0)='1' THEN
IF FAsign='1' THEN
result_mulu(63 downto 47) <= (muls_msb&mulu_reg(63 downto 48)-(mulu_sign&faktorB(31 downto 16)));
ELSE
result_mulu(63 downto 47) <= (muls_msb&mulu_reg(63 downto 48)+(mulu_sign&faktorB(31 downto 16)));
END IF;
END IF;
ELSE -- 32 Bit
result_mulu(63 downto 0) <= muls_msb&mulu_reg(63 downto 1);
IF mulu_reg(0)='1' THEN
IF FAsign='1' THEN
result_mulu(63 downto 31) <= (muls_msb&mulu_reg(63 downto 32)-(mulu_sign&faktorB));
ELSE
result_mulu(63 downto 31) <= (muls_msb&mulu_reg(63 downto 32)+(mulu_sign&faktorB));
END IF;
END IF;
END IF;
IF exe_opcode(15)='1' OR MUL_Mode=0 THEN
faktorB(31 downto 16) <= OP2out(15 downto 0);
faktorB(15 downto 0) <= (OTHERS=>'0');
ELSE
faktorB <= OP2out;
END IF;
END IF;
IF (result_mulu(63 downto 32)=X"00000000" AND (signedOP='0' OR result_mulu(31)='0')) OR
(result_mulu(63 downto 32)=X"FFFFFFFF" AND signedOP='1' AND result_mulu(31)='1') THEN
set_mV_Flag <= '0';
ELSE
set_mV_Flag <= '1';
END IF;
END PROCESS;
PROCESS (clk)
BEGIN
IF rising_edge(clk) THEN
IF clkena_lw='1' THEN
IF MUL_Hardware=0 THEN
IF micro_state=mul1 THEN
mulu_reg(63 downto 32) <= (OTHERS=>'0');
IF divs='1' AND ((exe_opcode(15)='1' AND reg_QA(15)='1') OR (exe_opcode(15)='0' AND reg_QA(31)='1')) THEN --MULS Neg faktor
FAsign <= '1';
mulu_reg(31 downto 0) <= 0-reg_QA;
ELSE
FAsign <= '0';
mulu_reg(31 downto 0) <= reg_QA;
END IF;
ELSIF exec(opcMULU)='0' THEN
mulu_reg <= result_mulu(63 downto 0);
END IF;
ELSE
mulu_reg(31 downto 0) <= result_mulu(63 downto 32);
END IF;
END IF;
END IF;
END PROCESS;
-------------------------------------------------------------------------------
---- DIVU/DIVS
-------------------------------------------------------------------------------
PROCESS (execOPC, OP1out, OP2out, div_reg, div_neg, div_bit, div_sub, div_quot, OP1_sign, div_over, result_div, reg_QA, opcode, sndOPC, divs, exe_opcode, reg_QB,
signedOP, nozero, div_qsign, OP2outext, result_div_pre)
BEGIN
divs <= (opcode(15) AND opcode(8)) OR (NOT opcode(15) AND sndOPC(11));
dividend(15 downto 0) <= (OTHERS=> '0');
dividend(63 downto 32) <= (OTHERS=> divs AND reg_QA(31));
IF exe_opcode(15)='1' OR DIV_Mode=0 THEN --DIV.W
dividend(47 downto 16) <= reg_QA;
div_qsign <= result_div_pre(15);
ELSE --DIV.l
dividend(31 downto 0) <= reg_QA;
IF exe_opcode(14)='1' AND sndOPC(10)='1' THEN
dividend(63 downto 32) <= reg_QB;
END IF;
div_qsign <= result_div_pre(31);
END IF;
IF signedOP='1' OR opcode(15)='0' THEN
OP2outext <= OP2out(31 downto 16);
ELSE
OP2outext <= (OTHERS=> '0');
END IF;
IF signedOP='1' AND OP2out(31) ='1' THEN
div_sub <= (div_reg(63 downto 31))+('1'&OP2out(31 downto 0));
ELSE
div_sub <= (div_reg(63 downto 31))-('0'&OP2outext(15 downto 0)&OP2out(15 downto 0));
END IF;
IF DIV_Mode=0 THEN
div_bit <= div_sub(16);
ELSE
div_bit <= div_sub(32);
END IF;
IF div_bit='1' THEN
div_quot(63 downto 32) <= div_reg(62 downto 31);
ELSE
div_quot(63 downto 32) <= div_sub(31 downto 0);
END IF;
div_quot(31 downto 0) <= div_reg(30 downto 0)&NOT div_bit;
IF div_neg='1' THEN
result_div_pre(31 downto 0) <= 0-div_quot(31 downto 0);
ELSE
result_div_pre(31 downto 0) <= div_quot(31 downto 0);
END IF;
IF (((nozero='1' OR div_bit='0') AND signedOP='1' AND (OP2out(31) XOR OP1_sign XOR div_qsign)='1' ) --Overflow DIVS
OR (signedOP='0' AND div_over(32)='0')) AND DIV_Mode/=3 THEN --Overflow DIVU
set_V_Flag <= '1';
ELSE
set_V_Flag <= '0';
END IF;
END PROCESS;
PROCESS (clk)
BEGIN
IF rising_edge(clk) THEN
IF clkena_lw='1' THEN
IF micro_state/=div_end2 THEN
V_Flag <= set_V_Flag;
END IF;
signedOP <= divs;
IF micro_state=div1 THEN
nozero <= '0';
IF divs='1' AND dividend(63)='1' THEN -- Neg dividend
OP1_sign <= '1';
div_reg <= 0-dividend;
ELSE
OP1_sign <= '0';
div_reg <= dividend;
END IF;
ELSE
div_reg <= div_quot;
nozero <= NOT div_bit OR nozero;
END IF;
IF micro_state=div2 THEN
div_neg <= signedOP AND (OP2out(31) XOR OP1_sign);
IF DIV_Mode=0 THEN
div_over(32 downto 16) <= ('0'&div_reg(47 downto 32))-('0'&OP2out(15 downto 0));
ELSE
div_over <= ('0'&div_reg(63 downto 32))-('0'&OP2outext(15 downto 0)&OP2out(15 downto 0));
END IF;
END IF;
IF exec(write_reminder)='0' THEN
result_div(31 downto 0) <= result_div_pre;
IF OP1_sign='1' THEN
result_div(63 downto 32) <= 0-div_quot(63 downto 32);
ELSE
result_div(63 downto 32) <= div_quot(63 downto 32);
END IF;
END IF;
END IF;
END IF;
END PROCESS;
END;