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507 lines
14 KiB
VHDL
507 lines
14 KiB
VHDL
library ieee;
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use ieee.std_logic_1164.all;
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use ieee.numeric_std.all;
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library work;
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use work.decode_types.all;
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use work.common.all;
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use work.helpers.all;
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use work.crhelpers.all;
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use work.insn_helpers.all;
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use work.ppc_fx_insns.all;
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entity execute1 is
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port (
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clk : in std_ulogic;
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-- asynchronous
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flush_out : out std_ulogic;
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stall_out : out std_ulogic;
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e_in : in Decode2ToExecute1Type;
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-- asynchronous
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f_out : out Execute1ToFetch1Type;
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e_out : out Execute1ToWritebackType;
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icache_inval : out std_ulogic;
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terminate_out : out std_ulogic
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);
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end entity execute1;
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architecture behaviour of execute1 is
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type reg_type is record
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e : Execute1ToWritebackType;
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lr_update : std_ulogic;
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next_lr : std_ulogic_vector(63 downto 0);
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end record;
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signal r, rin : reg_type;
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signal ctrl: ctrl_t := (others => (others => '0'));
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signal ctrl_tmp: ctrl_t := (others => (others => '0'));
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signal right_shift, rot_clear_left, rot_clear_right: std_ulogic;
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signal rotator_result: std_ulogic_vector(63 downto 0);
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signal rotator_carry: std_ulogic;
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signal logical_result: std_ulogic_vector(63 downto 0);
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signal countzero_result: std_ulogic_vector(63 downto 0);
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procedure set_carry(e: inout Execute1ToWritebackType;
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carry32 : in std_ulogic;
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carry : in std_ulogic) is
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begin
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e.xerc.ca32 := carry32;
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e.xerc.ca := carry;
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e.write_xerc_enable := '1';
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end;
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procedure set_ov(e: inout Execute1ToWritebackType;
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ov : in std_ulogic;
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ov32 : in std_ulogic) is
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begin
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e.xerc.ov32 := ov32;
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e.xerc.ov := ov;
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if ov = '1' then
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e.xerc.so := '1';
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end if;
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e.write_xerc_enable := '1';
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end;
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function calc_ov(msb_a : std_ulogic; msb_b: std_ulogic;
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ca: std_ulogic; msb_r: std_ulogic) return std_ulogic is
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begin
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return (ca xor msb_r) and not (msb_a xor msb_b);
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end;
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function decode_input_carry(ic : carry_in_t;
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xerc : xer_common_t) return std_ulogic is
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begin
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case ic is
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when ZERO =>
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return '0';
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when CA =>
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return xerc.ca;
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when ONE =>
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return '1';
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end case;
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end;
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begin
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rotator_0: entity work.rotator
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port map (
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rs => e_in.read_data3,
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ra => e_in.read_data1,
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shift => e_in.read_data2(6 downto 0),
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insn => e_in.insn,
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is_32bit => e_in.is_32bit,
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right_shift => right_shift,
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arith => e_in.is_signed,
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clear_left => rot_clear_left,
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clear_right => rot_clear_right,
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result => rotator_result,
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carry_out => rotator_carry
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);
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logical_0: entity work.logical
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port map (
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rs => e_in.read_data3,
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rb => e_in.read_data2,
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op => e_in.insn_type,
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invert_in => e_in.invert_a,
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invert_out => e_in.invert_out,
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result => logical_result
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);
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countzero_0: entity work.zero_counter
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port map (
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rs => e_in.read_data3,
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count_right => e_in.insn(10),
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is_32bit => e_in.is_32bit,
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result => countzero_result
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);
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execute1_0: process(clk)
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begin
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if rising_edge(clk) then
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r <= rin;
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ctrl <= ctrl_tmp;
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assert not (r.lr_update = '1' and e_in.valid = '1')
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report "LR update collision with valid in EX1"
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severity failure;
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if r.lr_update = '1' then
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report "LR update to " & to_hstring(r.next_lr);
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end if;
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end if;
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end process;
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execute1_1: process(all)
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variable v : reg_type;
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variable a_inv : std_ulogic_vector(63 downto 0);
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variable result : std_ulogic_vector(63 downto 0);
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variable newcrf : std_ulogic_vector(3 downto 0);
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variable result_with_carry : std_ulogic_vector(64 downto 0);
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variable result_en : std_ulogic;
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variable crnum : crnum_t;
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variable crbit : integer range 0 to 31;
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variable scrnum : crnum_t;
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variable lo, hi : integer;
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variable sh, mb, me : std_ulogic_vector(5 downto 0);
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variable sh32, mb32, me32 : std_ulogic_vector(4 downto 0);
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variable bo, bi : std_ulogic_vector(4 downto 0);
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variable bf, bfa : std_ulogic_vector(2 downto 0);
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variable l : std_ulogic;
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variable next_nia : std_ulogic_vector(63 downto 0);
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variable carry_32, carry_64 : std_ulogic;
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begin
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result := (others => '0');
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result_with_carry := (others => '0');
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result_en := '0';
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newcrf := (others => '0');
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v := r;
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v.e := Execute1ToWritebackInit;
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-- XER forwarding. To avoid having to track XER hazards, we
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-- use the previously latched value.
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--
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-- If the XER was modified by a multiply or a divide, those are
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-- single issue, we'll get the up to date value from decode2 from
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-- the register file.
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--
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-- If it was modified by an instruction older than the previous
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-- one in EX1, it will have also hit writeback and will be up
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-- to date in decode2.
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--
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-- That leaves us with the case where it was updated by the previous
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-- instruction in EX1. In that case, we can forward it back here.
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--
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-- This will break if we allow pipelining of multiply and divide,
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-- but ideally, those should go via EX1 anyway and run as a state
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-- machine from here.
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--
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-- One additional hazard to beware of is an XER:SO modifying instruction
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-- in EX1 followed immediately by a store conditional. Due to our
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-- writeback latency, the store will go down the LSU with the previous
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-- XER value, thus the stcx. will set CR0:SO using an obsolete SO value.
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--
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-- We will need to handle that if we ever make stcx. not single issue
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--
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-- We always pass a valid XER value downto writeback even when
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-- we aren't updating it, in order for XER:SO -> CR0:SO transfer
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-- to work for RC instructions.
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--
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if r.e.write_xerc_enable = '1' then
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v.e.xerc := r.e.xerc;
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else
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v.e.xerc := e_in.xerc;
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end if;
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v.lr_update := '0';
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ctrl_tmp <= ctrl;
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-- FIXME: run at 512MHz not core freq
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ctrl_tmp.tb <= std_ulogic_vector(unsigned(ctrl.tb) + 1);
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terminate_out <= '0';
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icache_inval <= '0';
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stall_out <= '0';
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f_out <= Execute1ToFetch1TypeInit;
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-- Next insn adder used in a couple of places
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next_nia := std_ulogic_vector(unsigned(e_in.nia) + 4);
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-- rotator control signals
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right_shift <= '1' when e_in.insn_type = OP_SHR else '0';
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rot_clear_left <= '1' when e_in.insn_type = OP_RLC or e_in.insn_type = OP_RLCL else '0';
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rot_clear_right <= '1' when e_in.insn_type = OP_RLC or e_in.insn_type = OP_RLCR else '0';
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if e_in.valid = '1' then
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v.e.valid := '1';
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v.e.write_reg := e_in.write_reg;
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v.e.write_len := x"8";
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v.e.sign_extend := '0';
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case_0: case e_in.insn_type is
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when OP_ILLEGAL =>
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terminate_out <= '1';
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report "illegal";
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when OP_NOP =>
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-- Do nothing
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when OP_ADD =>
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if e_in.invert_a = '0' then
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a_inv := e_in.read_data1;
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else
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a_inv := not e_in.read_data1;
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end if;
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result_with_carry := ppc_adde(a_inv, e_in.read_data2,
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decode_input_carry(e_in.input_carry, v.e.xerc));
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result := result_with_carry(63 downto 0);
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carry_32 := result(32) xor a_inv(32) xor e_in.read_data2(32);
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carry_64 := result_with_carry(64);
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if e_in.output_carry = '1' then
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set_carry(v.e, carry_32, carry_64);
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end if;
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if e_in.oe = '1' then
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set_ov(v.e,
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calc_ov(a_inv(63), e_in.read_data2(63), carry_64, result_with_carry(63)),
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calc_ov(a_inv(31), e_in.read_data2(31), carry_32, result_with_carry(31)));
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end if;
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result_en := '1';
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when OP_AND | OP_OR | OP_XOR =>
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result := logical_result;
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result_en := '1';
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when OP_B =>
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f_out.redirect <= '1';
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if (insn_aa(e_in.insn)) then
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f_out.redirect_nia <= std_ulogic_vector(signed(e_in.read_data2));
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else
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f_out.redirect_nia <= std_ulogic_vector(signed(e_in.nia) + signed(e_in.read_data2));
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end if;
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when OP_BC =>
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-- read_data1 is CTR
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bo := insn_bo(e_in.insn);
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bi := insn_bi(e_in.insn);
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if bo(4-2) = '0' then
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result := std_ulogic_vector(unsigned(e_in.read_data1) - 1);
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result_en := '1';
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v.e.write_reg := fast_spr_num(SPR_CTR);
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end if;
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if ppc_bc_taken(bo, bi, e_in.cr, e_in.read_data1) = 1 then
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f_out.redirect <= '1';
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if (insn_aa(e_in.insn)) then
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f_out.redirect_nia <= std_ulogic_vector(signed(e_in.read_data2));
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else
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f_out.redirect_nia <= std_ulogic_vector(signed(e_in.nia) + signed(e_in.read_data2));
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end if;
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end if;
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when OP_BCREG =>
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-- read_data1 is CTR
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-- read_data2 is target register (CTR, LR or TAR)
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bo := insn_bo(e_in.insn);
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bi := insn_bi(e_in.insn);
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if bo(4-2) = '0' and e_in.insn(10) = '0' then
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result := std_ulogic_vector(unsigned(e_in.read_data1) - 1);
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result_en := '1';
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v.e.write_reg := fast_spr_num(SPR_CTR);
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end if;
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if ppc_bc_taken(bo, bi, e_in.cr, e_in.read_data1) = 1 then
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f_out.redirect <= '1';
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f_out.redirect_nia <= e_in.read_data2(63 downto 2) & "00";
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end if;
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when OP_CMPB =>
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result := ppc_cmpb(e_in.read_data3, e_in.read_data2);
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result_en := '1';
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when OP_CMP =>
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bf := insn_bf(e_in.insn);
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l := insn_l(e_in.insn);
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v.e.write_cr_enable := '1';
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crnum := to_integer(unsigned(bf));
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v.e.write_cr_mask := num_to_fxm(crnum);
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for i in 0 to 7 loop
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lo := i*4;
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hi := lo + 3;
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v.e.write_cr_data(hi downto lo) := ppc_cmp(l, e_in.read_data1, e_in.read_data2, v.e.xerc.so);
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end loop;
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when OP_CMPL =>
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bf := insn_bf(e_in.insn);
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l := insn_l(e_in.insn);
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v.e.write_cr_enable := '1';
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crnum := to_integer(unsigned(bf));
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v.e.write_cr_mask := num_to_fxm(crnum);
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for i in 0 to 7 loop
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lo := i*4;
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hi := lo + 3;
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v.e.write_cr_data(hi downto lo) := ppc_cmpl(l, e_in.read_data1, e_in.read_data2, v.e.xerc.so);
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end loop;
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when OP_CNTZ =>
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result := countzero_result;
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result_en := '1';
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when OP_EXTS =>
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v.e.write_len := e_in.data_len;
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v.e.sign_extend := '1';
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result := e_in.read_data3;
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result_en := '1';
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when OP_ISEL =>
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crbit := to_integer(unsigned(insn_bc(e_in.insn)));
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if e_in.cr(31-crbit) = '1' then
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result := e_in.read_data1;
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else
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result := e_in.read_data2;
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end if;
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result_en := '1';
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when OP_MCRF =>
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bf := insn_bf(e_in.insn);
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bfa := insn_bfa(e_in.insn);
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v.e.write_cr_enable := '1';
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crnum := to_integer(unsigned(bf));
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scrnum := to_integer(unsigned(bfa));
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v.e.write_cr_mask := num_to_fxm(crnum);
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for i in 0 to 7 loop
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lo := (7-i)*4;
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hi := lo + 3;
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if i = scrnum then
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newcrf := e_in.cr(hi downto lo);
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end if;
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end loop;
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for i in 0 to 7 loop
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lo := i*4;
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hi := lo + 3;
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v.e.write_cr_data(hi downto lo) := newcrf;
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end loop;
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when OP_MFSPR =>
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if is_fast_spr(e_in.read_reg1) then
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result := e_in.read_data1;
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if decode_spr_num(e_in.insn) = SPR_XER then
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result(63-32) := v.e.xerc.so;
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result(63-33) := v.e.xerc.ov;
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result(63-34) := v.e.xerc.ca;
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result(63-35 downto 63-43) := "000000000";
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result(63-44) := v.e.xerc.ov32;
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result(63-45) := v.e.xerc.ca32;
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end if;
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else
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case decode_spr_num(e_in.insn) is
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when SPR_TB =>
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result := ctrl.tb;
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when others =>
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result := (others => '0');
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end case;
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end if;
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result_en := '1';
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when OP_MFCR =>
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if e_in.insn(20) = '0' then
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-- mfcr
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result := x"00000000" & e_in.cr;
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else
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-- mfocrf
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crnum := fxm_to_num(insn_fxm(e_in.insn));
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result := (others => '0');
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for i in 0 to 7 loop
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lo := (7-i)*4;
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hi := lo + 3;
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if crnum = i then
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result(hi downto lo) := e_in.cr(hi downto lo);
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end if;
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end loop;
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end if;
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result_en := '1';
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when OP_MTCRF =>
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v.e.write_cr_enable := '1';
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if e_in.insn(20) = '0' then
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-- mtcrf
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v.e.write_cr_mask := insn_fxm(e_in.insn);
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else
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-- mtocrf: We require one hot priority encoding here
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crnum := fxm_to_num(insn_fxm(e_in.insn));
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v.e.write_cr_mask := num_to_fxm(crnum);
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end if;
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v.e.write_cr_data := e_in.read_data3(31 downto 0);
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when OP_MTSPR =>
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report "MTSPR to SPR " & integer'image(decode_spr_num(e_in.insn)) &
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"=" & to_hstring(e_in.read_data3);
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if is_fast_spr(e_in.write_reg) then
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result := e_in.read_data3;
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result_en := '1';
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if decode_spr_num(e_in.insn) = SPR_XER then
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v.e.xerc.so := e_in.read_data3(63-32);
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v.e.xerc.ov := e_in.read_data3(63-33);
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v.e.xerc.ca := e_in.read_data3(63-34);
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v.e.xerc.ov32 := e_in.read_data3(63-44);
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v.e.xerc.ca32 := e_in.read_data3(63-45);
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v.e.write_xerc_enable := '1';
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end if;
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else
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-- TODO: Implement slow SPRs
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-- case decode_spr_num(e_in.insn) is
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-- when others =>
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-- end case;
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end if;
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when OP_POPCNTB =>
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result := ppc_popcntb(e_in.read_data3);
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result_en := '1';
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when OP_POPCNTW =>
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result := ppc_popcntw(e_in.read_data3);
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result_en := '1';
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when OP_POPCNTD =>
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result := ppc_popcntd(e_in.read_data3);
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result_en := '1';
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when OP_PRTYD =>
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result := ppc_prtyd(e_in.read_data3);
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result_en := '1';
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when OP_PRTYW =>
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result := ppc_prtyw(e_in.read_data3);
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result_en := '1';
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when OP_RLC | OP_RLCL | OP_RLCR | OP_SHL | OP_SHR =>
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result := rotator_result;
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if e_in.output_carry = '1' then
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set_carry(v.e, rotator_carry, rotator_carry);
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end if;
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result_en := '1';
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when OP_SIM_CONFIG =>
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-- bit 0 was used to select the microwatt console, which
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-- we no longer support.
|
|
result := x"0000000000000000";
|
|
result_en := '1';
|
|
|
|
when OP_TDI =>
|
|
-- Keep our test cases happy for now, ignore trap instructions
|
|
report "OP_TDI FIXME";
|
|
|
|
when OP_ISYNC =>
|
|
f_out.redirect <= '1';
|
|
f_out.redirect_nia <= next_nia;
|
|
|
|
when OP_ICBI =>
|
|
icache_inval <= '1';
|
|
|
|
when others =>
|
|
terminate_out <= '1';
|
|
report "illegal";
|
|
end case;
|
|
|
|
-- Update LR on the next cycle after a branch link
|
|
--
|
|
-- WARNING: The LR update isn't tracked by our hazard tracker. This
|
|
-- will work (well I hope) because it only happens on branches
|
|
-- which will flush all decoded instructions. By the time
|
|
-- fetch catches up, we'll have the new LR. This will
|
|
-- *not* work properly however if we have a branch predictor,
|
|
-- in which case the solution would probably be to keep a
|
|
-- local cache of the updated LR in execute1 (flushed on
|
|
-- exceptions) that is used instead of the value from
|
|
-- decode when its content is valid.
|
|
if e_in.lr = '1' then
|
|
v.lr_update := '1';
|
|
v.next_lr := next_nia;
|
|
v.e.valid := '0';
|
|
report "Delayed LR update to " & to_hstring(next_nia);
|
|
stall_out <= '1';
|
|
end if;
|
|
elsif r.lr_update = '1' then
|
|
result_en := '1';
|
|
result := r.next_lr;
|
|
v.e.write_reg := fast_spr_num(SPR_LR);
|
|
v.e.write_len := x"8";
|
|
v.e.sign_extend := '0';
|
|
v.e.valid := '1';
|
|
end if;
|
|
|
|
v.e.write_data := result;
|
|
v.e.write_enable := result_en;
|
|
v.e.rc := e_in.rc and e_in.valid;
|
|
|
|
-- Update registers
|
|
rin <= v;
|
|
|
|
-- update outputs
|
|
--f_out <= r.f;
|
|
e_out <= r.e;
|
|
flush_out <= f_out.redirect;
|
|
end process;
|
|
end architecture behaviour;
|