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@ -80,7 +80,7 @@ architecture behaviour of fpu is
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IDIV_NORMB, IDIV_NORMB2, IDIV_NORMB3,
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IDIV_NORMB, IDIV_NORMB2, IDIV_NORMB3,
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IDIV_CLZA, IDIV_CLZA2, IDIV_CLZA3,
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IDIV_CLZA, IDIV_CLZA2, IDIV_CLZA3,
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IDIV_NR0, IDIV_NR1, IDIV_NR2, IDIV_USE0_5,
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IDIV_NR0, IDIV_NR1, IDIV_NR2, IDIV_USE0_5,
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IDIV_DODIV,
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IDIV_DODIV, IDIV_SH32,
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IDIV_DIV, IDIV_DIV2, IDIV_DIV3, IDIV_DIV4, IDIV_DIV5,
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IDIV_DIV, IDIV_DIV2, IDIV_DIV3, IDIV_DIV4, IDIV_DIV5,
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IDIV_DIV6, IDIV_DIV7, IDIV_DIV8, IDIV_DIV9,
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IDIV_DIV6, IDIV_DIV7, IDIV_DIV8, IDIV_DIV9,
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IDIV_EXT_TBH, IDIV_EXT_TBH2, IDIV_EXT_TBH3,
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IDIV_EXT_TBH, IDIV_EXT_TBH2, IDIV_EXT_TBH3,
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@ -445,17 +445,20 @@ architecture behaviour of fpu is
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-- Split a DP floating-point number into components and work out its class.
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-- Split a DP floating-point number into components and work out its class.
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-- If is_int = 1, the input is considered an integer
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-- If is_int = 1, the input is considered an integer
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function decode_dp(fpr: std_ulogic_vector(63 downto 0); is_int: std_ulogic) return fpu_reg_type is
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function decode_dp(fpr: std_ulogic_vector(63 downto 0); is_int: std_ulogic;
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is_32bint: std_ulogic; is_signed: std_ulogic) return fpu_reg_type is
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variable r : fpu_reg_type;
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variable r : fpu_reg_type;
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variable exp_nz : std_ulogic;
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variable exp_nz : std_ulogic;
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variable exp_ao : std_ulogic;
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variable exp_ao : std_ulogic;
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variable frac_nz : std_ulogic;
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variable frac_nz : std_ulogic;
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variable low_nz : std_ulogic;
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variable cls : std_ulogic_vector(2 downto 0);
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variable cls : std_ulogic_vector(2 downto 0);
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begin
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begin
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r.negative := fpr(63);
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r.negative := fpr(63);
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exp_nz := or (fpr(62 downto 52));
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exp_nz := or (fpr(62 downto 52));
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exp_ao := and (fpr(62 downto 52));
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exp_ao := and (fpr(62 downto 52));
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frac_nz := or (fpr(51 downto 0));
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frac_nz := or (fpr(51 downto 0));
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low_nz := or (fpr(31 downto 0));
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if is_int = '0' then
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if is_int = '0' then
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r.exponent := signed(resize(unsigned(fpr(62 downto 52)), EXP_BITS)) - to_signed(1023, EXP_BITS);
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r.exponent := signed(resize(unsigned(fpr(62 downto 52)), EXP_BITS)) - to_signed(1023, EXP_BITS);
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if exp_nz = '0' then
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if exp_nz = '0' then
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@ -472,6 +475,16 @@ architecture behaviour of fpu is
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when "110" => r.class := INFINITY;
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when "110" => r.class := INFINITY;
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when others => r.class := NAN;
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when others => r.class := NAN;
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end case;
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end case;
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elsif is_32bint = '1' then
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r.negative := fpr(31);
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r.mantissa(31 downto 0) := fpr(31 downto 0);
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r.mantissa(63 downto 32) := (others => (is_signed and fpr(31)));
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r.exponent := (others => '0');
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if low_nz = '1' then
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r.class := FINITE;
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else
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r.class := ZERO;
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end if;
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else
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else
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r.mantissa := fpr;
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r.mantissa := fpr;
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r.exponent := (others => '0');
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r.exponent := (others => '0');
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@ -659,6 +672,7 @@ begin
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variable j, k : integer;
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variable j, k : integer;
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variable flm : std_ulogic_vector(7 downto 0);
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variable flm : std_ulogic_vector(7 downto 0);
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variable int_input : std_ulogic;
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variable int_input : std_ulogic;
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variable is_32bint : std_ulogic;
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variable mask : std_ulogic_vector(63 downto 0);
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variable mask : std_ulogic_vector(63 downto 0);
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variable in_a0 : std_ulogic_vector(63 downto 0);
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variable in_a0 : std_ulogic_vector(63 downto 0);
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variable in_b0 : std_ulogic_vector(63 downto 0);
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variable in_b0 : std_ulogic_vector(63 downto 0);
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@ -710,6 +724,8 @@ begin
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variable round_inc : std_ulogic_vector(63 downto 0);
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variable round_inc : std_ulogic_vector(63 downto 0);
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variable rbit_inc : std_ulogic;
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variable rbit_inc : std_ulogic;
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variable mult_mask : std_ulogic;
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variable mult_mask : std_ulogic;
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variable sign_bit : std_ulogic;
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variable rnd_b32 : std_ulogic;
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variable int_result : std_ulogic;
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variable int_result : std_ulogic;
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variable illegal : std_ulogic;
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variable illegal : std_ulogic;
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begin
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begin
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@ -717,6 +733,7 @@ begin
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v.complete := '0';
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v.complete := '0';
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v.do_intr := '0';
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v.do_intr := '0';
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int_input := '0';
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int_input := '0';
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is_32bint := '0';
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if r.complete = '1' or r.do_intr = '1' then
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if r.complete = '1' or r.do_intr = '1' then
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v.instr_done := '0';
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v.instr_done := '0';
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@ -735,12 +752,25 @@ begin
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v.fe_mode := or (e_in.fe_mode);
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v.fe_mode := or (e_in.fe_mode);
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v.dest_fpr := e_in.frt;
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v.dest_fpr := e_in.frt;
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v.single_prec := e_in.single;
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v.single_prec := e_in.single;
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v.longmask := e_in.single;
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v.is_signed := e_in.is_signed;
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v.rc := e_in.rc;
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v.rc := e_in.rc;
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v.is_cmp := e_in.out_cr;
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v.is_cmp := e_in.out_cr;
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int_input := '0';
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v.longmask := '0';
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if e_in.op = OP_FPOP_I then
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v.divext := '0';
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v.divmod := '0';
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if e_in.op = OP_FPOP or e_in.op = OP_FPOP_I then
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v.longmask := e_in.single;
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if e_in.op = OP_FPOP_I then
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int_input := '1';
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end if;
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else -- OP_DIV, OP_DIVE, OP_MOD
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int_input := '1';
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int_input := '1';
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is_32bint := e_in.single;
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if e_in.op = OP_DIVE then
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v.divext := '1';
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elsif e_in.op = OP_MOD then
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v.divmod := '1';
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end if;
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end if;
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end if;
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v.quieten_nan := '1';
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v.quieten_nan := '1';
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v.tiny := '0';
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v.tiny := '0';
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@ -751,15 +781,12 @@ begin
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v.is_sqrt := '0';
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v.is_sqrt := '0';
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v.add_bsmall := '0';
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v.add_bsmall := '0';
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v.doing_ftdiv := "00";
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v.doing_ftdiv := "00";
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v.divext := e_in.insn(8) and not e_in.insn(7);
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v.divmod := not e_in.insn(8);
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v.is_signed := e_in.is_signed;
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v.int_ovf := '0';
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v.int_ovf := '0';
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v.div_close := '0';
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v.div_close := '0';
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adec := decode_dp(e_in.fra, int_input);
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adec := decode_dp(e_in.fra, int_input, is_32bint, e_in.is_signed);
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bdec := decode_dp(e_in.frb, int_input);
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bdec := decode_dp(e_in.frb, int_input, is_32bint, e_in.is_signed);
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cdec := decode_dp(e_in.frc, int_input);
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cdec := decode_dp(e_in.frc, int_input, '0', '0');
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v.a := adec;
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v.a := adec;
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v.b := bdec;
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v.b := bdec;
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v.c := cdec;
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v.c := cdec;
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@ -870,6 +897,7 @@ begin
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shiftin0 := '0';
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shiftin0 := '0';
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rbit_inc := '0';
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rbit_inc := '0';
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mult_mask := '0';
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mult_mask := '0';
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rnd_b32 := '0';
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int_result := '0';
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int_result := '0';
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illegal := '0';
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illegal := '0';
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case r.state is
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case r.state is
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@ -918,7 +946,7 @@ begin
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else
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else
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v.state := DO_FRI;
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v.state := DO_FRI;
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end if;
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end if;
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when "01001" =>
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when "01001" | "01011" =>
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-- integer divides and mods, major opcode 31
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-- integer divides and mods, major opcode 31
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v.opsel_a := AIN_B;
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v.opsel_a := AIN_B;
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v.state := DO_IDIVMOD;
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v.state := DO_IDIVMOD;
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@ -2552,6 +2580,10 @@ begin
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v.shift := to_signed(-UNIT_BIT, EXP_BITS);
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v.shift := to_signed(-UNIT_BIT, EXP_BITS);
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v.first := '1';
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v.first := '1';
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v.state := IDIV_DIV;
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v.state := IDIV_DIV;
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elsif r.single_prec = '1' then
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-- divwe[u][o], shift A left 32 bits
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v.shift := to_signed(32, EXP_BITS);
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v.state := IDIV_SH32;
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elsif r.div_close = '0' then
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elsif r.div_close = '0' then
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v.shift := to_signed(64 - UNIT_BIT, EXP_BITS);
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v.shift := to_signed(64 - UNIT_BIT, EXP_BITS);
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v.state := IDIV_EXTDIV;
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v.state := IDIV_EXTDIV;
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@ -2561,6 +2593,12 @@ begin
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v.opsel_a := AIN_C;
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v.opsel_a := AIN_C;
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v.state := IDIV_EXT_TBH;
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v.state := IDIV_EXT_TBH;
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end if;
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end if;
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when IDIV_SH32 =>
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-- r.shift = 32, R contains the dividend
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opsel_r <= RES_SHIFT;
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v.shift := to_signed(-UNIT_BIT, EXP_BITS);
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v.first := '1';
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v.state := IDIV_DIV;
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when IDIV_DIV =>
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when IDIV_DIV =>
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-- Dividing A by C, r.shift = -56; A is in R
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-- Dividing A by C, r.shift = -56; A is in R
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-- Put A into the bottom 64 bits of Ahi/A/Alo
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-- Put A into the bottom 64 bits of Ahi/A/Alo
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@ -2805,13 +2843,22 @@ begin
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-- and also negate R if the answer is negative
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-- and also negate R if the answer is negative
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opsel_ainv <= r.result_sign;
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opsel_ainv <= r.result_sign;
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carry_in <= r.inc_quot xor r.result_sign;
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carry_in <= r.inc_quot xor r.result_sign;
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rnd_b32 := '1';
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if r.divmod = '0' then
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opsel_b <= BIN_RND;
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end if;
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if r.is_signed = '0' then
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if r.is_signed = '0' then
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v.state := IDIV_DONE;
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v.state := IDIV_DONE;
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else
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else
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v.state := IDIV_OVFCHK;
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v.state := IDIV_OVFCHK;
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end if;
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end if;
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when IDIV_OVFCHK =>
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when IDIV_OVFCHK =>
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v.int_ovf := r.r(63) xor r.result_sign;
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if r.single_prec = '0' then
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sign_bit := r.r(63);
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else
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sign_bit := r.r(31);
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end if;
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v.int_ovf := sign_bit xor r.result_sign;
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if v.int_ovf = '1' then
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if v.int_ovf = '1' then
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v.state := IDIV_ZERO;
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v.state := IDIV_ZERO;
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else
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else
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@ -2953,7 +3000,9 @@ begin
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when BIN_R =>
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when BIN_R =>
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in_b0 := r.r;
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in_b0 := r.r;
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when BIN_RND =>
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when BIN_RND =>
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if rbit_inc = '0' then
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if rnd_b32 = '1' then
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round_inc := (32 => r.result_sign and r.single_prec, others => '0');
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elsif rbit_inc = '0' then
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round_inc := (SP_LSB => r.single_prec, DP_LSB => not r.single_prec, others => '0');
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round_inc := (SP_LSB => r.single_prec, DP_LSB => not r.single_prec, others => '0');
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else
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else
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round_inc := (DP_RBIT => '1', others => '0');
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|
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round_inc := (DP_RBIT => '1', others => '0');
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|