library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; library work; use work.decode_types.all; use work.common.all; use work.insn_helpers.all; use work.helpers.all; -- 2 cycle LSU -- We calculate the address in the first cycle entity loadstore1 is generic ( HAS_FPU : boolean := true; -- Non-zero to enable log data collection LOG_LENGTH : natural := 0 ); port ( clk : in std_ulogic; rst : in std_ulogic; l_in : in Execute1ToLoadstore1Type; e_out : out Loadstore1ToExecute1Type; l_out : out Loadstore1ToWritebackType; d_out : out Loadstore1ToDcacheType; d_in : in DcacheToLoadstore1Type; m_out : out Loadstore1ToMmuType; m_in : in MmuToLoadstore1Type; dc_stall : in std_ulogic; events : out Loadstore1EventType; log_out : out std_ulogic_vector(9 downto 0) ); end loadstore1; architecture behave of loadstore1 is -- State machine for unaligned loads/stores type state_t is (IDLE, -- ready for instruction MMU_WAIT -- waiting for MMU to finish doing something ); type byte_index_t is array(0 to 7) of unsigned(2 downto 0); subtype byte_trim_t is std_ulogic_vector(1 downto 0); type trim_ctl_t is array(0 to 7) of byte_trim_t; type request_t is record valid : std_ulogic; dc_req : std_ulogic; load : std_ulogic; store : std_ulogic; tlbie : std_ulogic; dcbz : std_ulogic; read_spr : std_ulogic; write_spr : std_ulogic; mmu_op : std_ulogic; instr_fault : std_ulogic; do_update : std_ulogic; mode_32bit : std_ulogic; addr : std_ulogic_vector(63 downto 0); byte_sel : std_ulogic_vector(7 downto 0); second_bytes : std_ulogic_vector(7 downto 0); store_data : std_ulogic_vector(63 downto 0); instr_tag : instr_tag_t; write_reg : gspr_index_t; length : std_ulogic_vector(3 downto 0); elt_length : std_ulogic_vector(3 downto 0); byte_reverse : std_ulogic; brev_mask : unsigned(2 downto 0); sign_extend : std_ulogic; update : std_ulogic; xerc : xer_common_t; reserve : std_ulogic; atomic : std_ulogic; atomic_last : std_ulogic; rc : std_ulogic; nc : std_ulogic; -- non-cacheable access virt_mode : std_ulogic; priv_mode : std_ulogic; load_sp : std_ulogic; sprn : std_ulogic_vector(9 downto 0); is_slbia : std_ulogic; align_intr : std_ulogic; dword_index : std_ulogic; two_dwords : std_ulogic; incomplete : std_ulogic; end record; constant request_init : request_t := (valid => '0', dc_req => '0', load => '0', store => '0', tlbie => '0', dcbz => '0', read_spr => '0', write_spr => '0', mmu_op => '0', instr_fault => '0', do_update => '0', mode_32bit => '0', addr => (others => '0'), byte_sel => x"00", second_bytes => x"00", store_data => (others => '0'), instr_tag => instr_tag_init, write_reg => 7x"00", length => x"0", elt_length => x"0", byte_reverse => '0', brev_mask => "000", sign_extend => '0', update => '0', xerc => xerc_init, reserve => '0', atomic => '0', atomic_last => '0', rc => '0', nc => '0', virt_mode => '0', priv_mode => '0', load_sp => '0', sprn => 10x"0", is_slbia => '0', align_intr => '0', dword_index => '0', two_dwords => '0', incomplete => '0'); type reg_stage1_t is record req : request_t; busy : std_ulogic; issued : std_ulogic; addr0 : std_ulogic_vector(63 downto 0); end record; type reg_stage2_t is record req : request_t; byte_index : byte_index_t; use_second : std_ulogic_vector(7 downto 0); busy : std_ulogic; wait_dc : std_ulogic; wait_mmu : std_ulogic; one_cycle : std_ulogic; wr_sel : std_ulogic_vector(1 downto 0); addr0 : std_ulogic_vector(63 downto 0); end record; type reg_stage3_t is record state : state_t; complete : std_ulogic; instr_tag : instr_tag_t; write_enable : std_ulogic; write_reg : gspr_index_t; write_data : std_ulogic_vector(63 downto 0); rc : std_ulogic; xerc : xer_common_t; store_done : std_ulogic; load_data : std_ulogic_vector(63 downto 0); dar : std_ulogic_vector(63 downto 0); dsisr : std_ulogic_vector(31 downto 0); ld_sp_data : std_ulogic_vector(31 downto 0); ld_sp_nz : std_ulogic; ld_sp_lz : std_ulogic_vector(5 downto 0); stage1_en : std_ulogic; interrupt : std_ulogic; intr_vec : integer range 0 to 16#fff#; srr1 : std_ulogic_vector(15 downto 0); events : Loadstore1EventType; end record; signal req_in : request_t; signal r1, r1in : reg_stage1_t; signal r2, r2in : reg_stage2_t; signal r3, r3in : reg_stage3_t; signal flush : std_ulogic; signal busy : std_ulogic; signal complete : std_ulogic; signal flushing : std_ulogic; signal store_sp_data : std_ulogic_vector(31 downto 0); signal load_dp_data : std_ulogic_vector(63 downto 0); signal store_data : std_ulogic_vector(63 downto 0); signal stage1_req : request_t; signal stage1_dcreq : std_ulogic; signal stage1_dreq : std_ulogic; -- Generate byte enables from sizes function length_to_sel(length : in std_logic_vector(3 downto 0)) return std_ulogic_vector is begin case length is when "0001" => return "00000001"; when "0010" => return "00000011"; when "0100" => return "00001111"; when "1000" => return "11111111"; when others => return "00000000"; end case; end function length_to_sel; -- Calculate byte enables -- This returns 16 bits, giving the select signals for two transfers, -- to account for unaligned loads or stores function xfer_data_sel(size : in std_logic_vector(3 downto 0); address : in std_logic_vector(2 downto 0)) return std_ulogic_vector is variable longsel : std_ulogic_vector(15 downto 0); begin longsel := "00000000" & length_to_sel(size); return std_ulogic_vector(shift_left(unsigned(longsel), to_integer(unsigned(address)))); end function xfer_data_sel; -- 23-bit right shifter for DP -> SP float conversions function shifter_23r(frac: std_ulogic_vector(22 downto 0); shift: unsigned(4 downto 0)) return std_ulogic_vector is variable fs1 : std_ulogic_vector(22 downto 0); variable fs2 : std_ulogic_vector(22 downto 0); begin case shift(1 downto 0) is when "00" => fs1 := frac; when "01" => fs1 := '0' & frac(22 downto 1); when "10" => fs1 := "00" & frac(22 downto 2); when others => fs1 := "000" & frac(22 downto 3); end case; case shift(4 downto 2) is when "000" => fs2 := fs1; when "001" => fs2 := x"0" & fs1(22 downto 4); when "010" => fs2 := x"00" & fs1(22 downto 8); when "011" => fs2 := x"000" & fs1(22 downto 12); when "100" => fs2 := x"0000" & fs1(22 downto 16); when others => fs2 := x"00000" & fs1(22 downto 20); end case; return fs2; end; -- 23-bit left shifter for SP -> DP float conversions function shifter_23l(frac: std_ulogic_vector(22 downto 0); shift: unsigned(4 downto 0)) return std_ulogic_vector is variable fs1 : std_ulogic_vector(22 downto 0); variable fs2 : std_ulogic_vector(22 downto 0); begin case shift(1 downto 0) is when "00" => fs1 := frac; when "01" => fs1 := frac(21 downto 0) & '0'; when "10" => fs1 := frac(20 downto 0) & "00"; when others => fs1 := frac(19 downto 0) & "000"; end case; case shift(4 downto 2) is when "000" => fs2 := fs1; when "001" => fs2 := fs1(18 downto 0) & x"0" ; when "010" => fs2 := fs1(14 downto 0) & x"00"; when "011" => fs2 := fs1(10 downto 0) & x"000"; when "100" => fs2 := fs1(6 downto 0) & x"0000"; when others => fs2 := fs1(2 downto 0) & x"00000"; end case; return fs2; end; begin loadstore1_reg: process(clk) begin if rising_edge(clk) then if rst = '1' then r1.busy <= '0'; r1.issued <= '0'; r1.req.valid <= '0'; r1.req.dc_req <= '0'; r1.req.incomplete <= '0'; r1.req.tlbie <= '0'; r1.req.is_slbia <= '0'; r1.req.instr_fault <= '0'; r1.req.load <= '0'; r1.req.priv_mode <= '0'; r1.req.sprn <= (others => '0'); r1.req.xerc <= xerc_init; r2.req.valid <= '0'; r2.busy <= '0'; r2.req.tlbie <= '0'; r2.req.is_slbia <= '0'; r2.req.instr_fault <= '0'; r2.req.load <= '0'; r2.req.priv_mode <= '0'; r2.req.sprn <= (others => '0'); r2.req.xerc <= xerc_init; r2.wait_dc <= '0'; r2.wait_mmu <= '0'; r2.one_cycle <= '0'; r3.dar <= (others => '0'); r3.dsisr <= (others => '0'); r3.state <= IDLE; r3.write_enable <= '0'; r3.interrupt <= '0'; r3.complete <= '0'; r3.stage1_en <= '1'; r3.events.load_complete <= '0'; r3.events.store_complete <= '0'; flushing <= '0'; else r1 <= r1in; r2 <= r2in; r3 <= r3in; flushing <= (flushing or (r1in.req.valid and r1in.req.align_intr)) and not flush; end if; stage1_dreq <= stage1_dcreq; if d_in.valid = '1' then assert r2.req.valid = '1' and r2.req.dc_req = '1' and r3.state = IDLE severity failure; end if; if d_in.error = '1' then assert r2.req.valid = '1' and r2.req.dc_req = '1' and r3.state = IDLE severity failure; end if; if m_in.done = '1' or m_in.err = '1' then assert r2.req.valid = '1' and r3.state = MMU_WAIT severity failure; end if; end if; end process; ls_fp_conv: if HAS_FPU generate -- Convert DP data to SP for stfs dp_to_sp: process(all) variable exp : unsigned(10 downto 0); variable frac : std_ulogic_vector(22 downto 0); variable shift : unsigned(4 downto 0); begin store_sp_data(31) <= l_in.data(63); store_sp_data(30 downto 0) <= (others => '0'); exp := unsigned(l_in.data(62 downto 52)); if exp > 896 then store_sp_data(30) <= l_in.data(62); store_sp_data(29 downto 0) <= l_in.data(58 downto 29); elsif exp >= 874 then -- denormalization required frac := '1' & l_in.data(51 downto 30); shift := 0 - exp(4 downto 0); store_sp_data(22 downto 0) <= shifter_23r(frac, shift); end if; end process; -- Convert SP data to DP for lfs sp_to_dp: process(all) variable exp : unsigned(7 downto 0); variable exp_dp : unsigned(10 downto 0); variable exp_nz : std_ulogic; variable exp_ao : std_ulogic; variable frac : std_ulogic_vector(22 downto 0); variable frac_shift : unsigned(4 downto 0); begin frac := r3.ld_sp_data(22 downto 0); exp := unsigned(r3.ld_sp_data(30 downto 23)); exp_nz := or (r3.ld_sp_data(30 downto 23)); exp_ao := and (r3.ld_sp_data(30 downto 23)); frac_shift := (others => '0'); if exp_ao = '1' then exp_dp := to_unsigned(2047, 11); -- infinity or NaN elsif exp_nz = '1' then exp_dp := 896 + resize(exp, 11); -- finite normalized value elsif r3.ld_sp_nz = '0' then exp_dp := to_unsigned(0, 11); -- zero else -- denormalized SP operand, need to normalize exp_dp := 896 - resize(unsigned(r3.ld_sp_lz), 11); frac_shift := unsigned(r3.ld_sp_lz(4 downto 0)) + 1; end if; load_dp_data(63) <= r3.ld_sp_data(31); load_dp_data(62 downto 52) <= std_ulogic_vector(exp_dp); load_dp_data(51 downto 29) <= shifter_23l(frac, frac_shift); load_dp_data(28 downto 0) <= (others => '0'); end process; end generate; -- Translate a load/store instruction into the internal request format -- XXX this should only depend on l_in, but actually depends on -- r1.addr0 as well (in the l_in.second = 1 case). loadstore1_in: process(all) variable v : request_t; variable lsu_sum : std_ulogic_vector(63 downto 0); variable brev_lenm1 : unsigned(2 downto 0); variable long_sel : std_ulogic_vector(15 downto 0); variable addr : std_ulogic_vector(63 downto 0); variable sprn : std_ulogic_vector(9 downto 0); variable misaligned : std_ulogic; variable addr_mask : std_ulogic_vector(2 downto 0); begin v := request_init; sprn := std_ulogic_vector(to_unsigned(decode_spr_num(l_in.insn), 10)); v.valid := l_in.valid; v.instr_tag := l_in.instr_tag; v.mode_32bit := l_in.mode_32bit; v.write_reg := l_in.write_reg; v.length := l_in.length; v.elt_length := l_in.length; v.byte_reverse := l_in.byte_reverse; v.sign_extend := l_in.sign_extend; v.update := l_in.update; v.xerc := l_in.xerc; v.reserve := l_in.reserve; v.rc := l_in.rc; v.nc := l_in.ci; v.virt_mode := l_in.virt_mode; v.priv_mode := l_in.priv_mode; v.sprn := sprn; lsu_sum := std_ulogic_vector(unsigned(l_in.addr1) + unsigned(l_in.addr2)); if HAS_FPU and l_in.is_32bit = '1' then v.store_data := x"00000000" & store_sp_data; else v.store_data := l_in.data; end if; addr := lsu_sum; if l_in.second = '1' then if l_in.update = '0' then -- for the second half of a 16-byte transfer, -- use the previous address plus 8. addr := std_ulogic_vector(unsigned(r1.addr0(63 downto 3)) + 1) & r1.addr0(2 downto 0); else -- for an update-form load, use the previous address -- as the value to write back to RA. addr := r1.addr0; end if; end if; if l_in.mode_32bit = '1' then addr(63 downto 32) := (others => '0'); end if; v.addr := addr; -- XXX Temporary hack. Mark the op as non-cachable if the address -- is the form 0xc------- for a real-mode access. if addr(31 downto 28) = "1100" and l_in.virt_mode = '0' then v.nc := '1'; end if; addr_mask := std_ulogic_vector(unsigned(l_in.length(2 downto 0)) - 1); -- Do length_to_sel and work out if we are doing 2 dwords long_sel := xfer_data_sel(v.length, addr(2 downto 0)); v.byte_sel := long_sel(7 downto 0); v.second_bytes := long_sel(15 downto 8); if long_sel(15 downto 8) /= "00000000" then v.two_dwords := '1'; end if; -- check alignment for larx/stcx misaligned := or (addr_mask and addr(2 downto 0)); v.align_intr := l_in.reserve and misaligned; v.atomic := not misaligned; v.atomic_last := not misaligned and (l_in.second or not l_in.repeat); case l_in.op is when OP_STORE => v.store := '1'; when OP_LOAD => if l_in.update = '0' or l_in.second = '0' then v.load := '1'; if HAS_FPU and l_in.is_32bit = '1' then -- Allow an extra cycle for SP->DP precision conversion v.load_sp := '1'; end if; else -- write back address to RA v.do_update := '1'; end if; when OP_DCBZ => v.dcbz := '1'; v.align_intr := v.nc; when OP_TLBIE => v.tlbie := '1'; v.addr := l_in.addr2; -- address from RB for tlbie v.is_slbia := l_in.insn(7); v.mmu_op := '1'; when OP_MFSPR => v.read_spr := '1'; when OP_MTSPR => v.write_spr := '1'; v.mmu_op := sprn(8) or sprn(5); when OP_FETCH_FAILED => -- send it to the MMU to do the radix walk v.instr_fault := '1'; v.addr := l_in.nia; v.mmu_op := '1'; when others => end case; v.dc_req := l_in.valid and (v.load or v.store or v.dcbz) and not v.align_intr; v.incomplete := v.dc_req and v.two_dwords; -- Work out controls for load and store formatting brev_lenm1 := "000"; if v.byte_reverse = '1' then brev_lenm1 := unsigned(v.length(2 downto 0)) - 1; end if; v.brev_mask := brev_lenm1; req_in <= v; end process; busy <= dc_stall or d_in.error or r1.busy or r2.busy; complete <= r2.one_cycle or (r2.wait_dc and d_in.valid) or r3.complete; -- Processing done in the first cycle of a load/store instruction loadstore1_1: process(all) variable v : reg_stage1_t; variable req : request_t; variable dcreq : std_ulogic; variable issue : std_ulogic; begin v := r1; issue := '0'; dcreq := '0'; if r1.busy = '0' then req := req_in; req.valid := l_in.valid; if flushing = '1' then -- Make this a no-op request rather than simply invalid. -- It will never get to stage 3 since there is a request ahead of -- it with align_intr = 1. req.dc_req := '0'; end if; issue := l_in.valid and req.dc_req; if l_in.valid = '1' then v.addr0 := req.addr; end if; else req := r1.req; if r1.req.dc_req = '1' and r1.issued = '0' then issue := '1'; elsif r1.req.incomplete = '1' then -- construct the second request for a misaligned access req.dword_index := '1'; req.incomplete := '0'; req.addr := std_ulogic_vector(unsigned(r1.req.addr(63 downto 3)) + 1) & "000"; if r1.req.mode_32bit = '1' then req.addr(32) := '0'; end if; req.byte_sel := r1.req.second_bytes; issue := '1'; else -- For the lfs conversion cycle, leave the request valid -- for another cycle but with req.dc_req = 0. -- For an MMU request last cycle, we have nothing -- to do in this cycle, so make it invalid. if r1.req.load_sp = '0' then req.valid := '0'; end if; req.dc_req := '0'; end if; end if; if flush = '1' then v.req.valid := '0'; v.req.dc_req := '0'; v.req.incomplete := '0'; v.issued := '0'; v.busy := '0'; elsif (dc_stall or d_in.error or r2.busy) = '0' then -- we can change what's in r1 next cycle because the current thing -- in r1 will go into r2 v.req := req; dcreq := issue; v.issued := issue; v.busy := (issue and (req.incomplete or req.load_sp)) or (req.valid and req.mmu_op); else -- pipeline is stalled if r1.issued = '1' and d_in.error = '1' then v.issued := '0'; v.busy := '1'; end if; end if; stage1_req <= req; stage1_dcreq <= dcreq; r1in <= v; end process; -- Processing done in the second cycle of a load/store instruction. -- Store data is formatted here and sent to the dcache. -- The request in r1 is sent to stage 3 if stage 3 will not be busy next cycle. loadstore1_2: process(all) variable v : reg_stage2_t; variable j : integer; variable k : unsigned(2 downto 0); variable kk : unsigned(3 downto 0); variable idx : unsigned(2 downto 0); variable byte_offset : unsigned(2 downto 0); variable interrupt : std_ulogic; begin v := r2; -- Byte reversing and rotating for stores. -- Done in the second cycle (the cycle after l_in.valid = 1). byte_offset := unsigned(r1.addr0(2 downto 0)); for i in 0 to 7 loop k := (to_unsigned(i, 3) - byte_offset) xor r1.req.brev_mask; j := to_integer(k) * 8; store_data(i * 8 + 7 downto i * 8) <= r1.req.store_data(j + 7 downto j); end loop; if (dc_stall or d_in.error or r2.busy or l_in.e2stall) = '0' then if r1.req.valid = '0' or r1.issued = '1' or r1.req.dc_req = '0' then v.req := r1.req; v.addr0 := r1.addr0; v.req.store_data := store_data; v.wait_dc := r1.req.valid and r1.req.dc_req and not r1.req.load_sp and not r1.req.incomplete; v.wait_mmu := r1.req.valid and r1.req.mmu_op; v.busy := r1.req.valid and r1.req.mmu_op; v.one_cycle := r1.req.valid and not (r1.req.dc_req or r1.req.mmu_op); if r1.req.read_spr = '1' then v.wr_sel := "00"; elsif r1.req.do_update = '1' or r1.req.store = '1' then v.wr_sel := "01"; elsif r1.req.load_sp = '1' then v.wr_sel := "10"; else v.wr_sel := "11"; end if; -- Work out load formatter controls for next cycle for i in 0 to 7 loop idx := to_unsigned(i, 3) xor r1.req.brev_mask; kk := ('0' & idx) + ('0' & byte_offset); v.use_second(i) := kk(3); v.byte_index(i) := kk(2 downto 0); end loop; else v.req.valid := '0'; v.wait_dc := '0'; v.wait_mmu := '0'; v.one_cycle := '0'; end if; end if; if r2.wait_mmu = '1' and m_in.done = '1' then if r2.req.mmu_op = '1' then v.req.valid := '0'; v.busy := '0'; end if; v.wait_mmu := '0'; end if; if r2.busy = '1' and r2.wait_mmu = '0' then v.busy := '0'; end if; interrupt := (r2.req.valid and r2.req.align_intr) or (d_in.error and d_in.cache_paradox) or m_in.err; if interrupt = '1' then v.req.valid := '0'; v.busy := '0'; v.wait_dc := '0'; v.wait_mmu := '0'; elsif d_in.error = '1' then v.wait_mmu := '1'; v.busy := '1'; end if; r2in <= v; end process; -- Processing done in the third cycle of a load/store instruction. -- At this stage we can do things that have side effects without -- fear of the instruction getting flushed. This is the point at -- which requests get sent to the MMU. loadstore1_3: process(all) variable v : reg_stage3_t; variable j : integer; variable req : std_ulogic; variable mmureq : std_ulogic; variable mmu_mtspr : std_ulogic; variable write_enable : std_ulogic; variable write_data : std_ulogic_vector(63 downto 0); variable do_update : std_ulogic; variable done : std_ulogic; variable exception : std_ulogic; variable data_permuted : std_ulogic_vector(63 downto 0); variable data_trimmed : std_ulogic_vector(63 downto 0); variable sprval : std_ulogic_vector(63 downto 0); variable negative : std_ulogic; variable dsisr : std_ulogic_vector(31 downto 0); variable itlb_fault : std_ulogic; variable trim_ctl : trim_ctl_t; begin v := r3; req := '0'; mmureq := '0'; mmu_mtspr := '0'; done := '0'; exception := '0'; dsisr := (others => '0'); write_enable := '0'; sprval := (others => '0'); do_update := '0'; v.complete := '0'; v.srr1 := (others => '0'); v.events := (others => '0'); -- load data formatting -- shift and byte-reverse data bytes for i in 0 to 7 loop j := to_integer(r2.byte_index(i)) * 8; data_permuted(i * 8 + 7 downto i * 8) := d_in.data(j + 7 downto j); end loop; -- Work out the sign bit for sign extension. -- For unaligned loads crossing two dwords, the sign bit is in the -- first dword for big-endian (byte_reverse = 1), or the second dword -- for little-endian. if r2.req.dword_index = '1' and r2.req.byte_reverse = '1' then negative := (r2.req.length(3) and r3.load_data(63)) or (r2.req.length(2) and r3.load_data(31)) or (r2.req.length(1) and r3.load_data(15)) or (r2.req.length(0) and r3.load_data(7)); else negative := (r2.req.length(3) and data_permuted(63)) or (r2.req.length(2) and data_permuted(31)) or (r2.req.length(1) and data_permuted(15)) or (r2.req.length(0) and data_permuted(7)); end if; -- trim and sign-extend for i in 0 to 7 loop if i < to_integer(unsigned(r2.req.length)) then if r2.req.dword_index = '1' then trim_ctl(i) := '1' & not r2.use_second(i); else trim_ctl(i) := "10"; end if; else trim_ctl(i) := "00"; end if; end loop; for i in 0 to 7 loop case trim_ctl(i) is when "11" => data_trimmed(i * 8 + 7 downto i * 8) := r3.load_data(i * 8 + 7 downto i * 8); when "10" => data_trimmed(i * 8 + 7 downto i * 8) := data_permuted(i * 8 + 7 downto i * 8); when others => data_trimmed(i * 8 + 7 downto i * 8) := (others => negative and r2.req.sign_extend); end case; end loop; if HAS_FPU then -- Single-precision FP conversion for loads v.ld_sp_data := data_trimmed(31 downto 0); v.ld_sp_nz := or (data_trimmed(22 downto 0)); v.ld_sp_lz := count_left_zeroes(data_trimmed(22 downto 0)); end if; if d_in.valid = '1' and r2.req.load = '1' then v.load_data := data_permuted; end if; if r2.req.valid = '1' then if r2.req.read_spr = '1' then write_enable := '1'; -- partial decode on SPR number should be adequate given -- the restricted set that get sent down this path if r2.req.sprn(8) = '0' and r2.req.sprn(5) = '0' then if r2.req.sprn(0) = '0' then sprval := x"00000000" & r3.dsisr; else sprval := r3.dar; end if; else -- reading one of the SPRs in the MMU sprval := m_in.sprval; end if; end if; if r2.req.align_intr = '1' then -- generate alignment interrupt exception := '1'; end if; if r2.req.do_update = '1' then do_update := '1'; end if; if r2.req.load_sp = '1' and r2.req.dc_req = '0' then write_enable := '1'; end if; if r2.req.write_spr = '1' and r2.req.mmu_op = '0' then if r2.req.sprn(0) = '0' then v.dsisr := r2.req.store_data(31 downto 0); else v.dar := r2.req.store_data; end if; end if; end if; if r3.state = IDLE and r2.req.valid = '1' and r2.req.mmu_op = '1' then -- send request (tlbie, mtspr, itlb miss) to MMU mmureq := not r2.req.write_spr; mmu_mtspr := r2.req.write_spr; if r2.req.instr_fault = '1' then v.events.itlb_miss := '1'; end if; v.state := MMU_WAIT; end if; if d_in.valid = '1' then if r2.req.incomplete = '0' then write_enable := r2.req.load and not r2.req.load_sp; -- stores write back rA update do_update := r2.req.update and r2.req.store; end if; end if; if d_in.error = '1' then if d_in.cache_paradox = '1' then -- signal an interrupt straight away exception := '1'; dsisr(63 - 38) := not r2.req.load; -- XXX there is no architected bit for this -- (probably should be a machine check in fact) dsisr(63 - 35) := d_in.cache_paradox; else -- Look up the translation for TLB miss -- and also for permission error and RC error -- in case the PTE has been updated. mmureq := '1'; v.state := MMU_WAIT; v.stage1_en := '0'; end if; end if; if m_in.done = '1' then if r2.req.dc_req = '1' then -- retry the request now that the MMU has installed a TLB entry req := '1'; else v.complete := '1'; end if; end if; if m_in.err = '1' then exception := '1'; dsisr(63 - 33) := m_in.invalid; dsisr(63 - 36) := m_in.perm_error; dsisr(63 - 38) := r2.req.store or r2.req.dcbz; dsisr(63 - 44) := m_in.badtree; dsisr(63 - 45) := m_in.rc_error; end if; if (m_in.done or m_in.err) = '1' then v.stage1_en := '1'; v.state := IDLE; end if; v.events.load_complete := r2.req.load and complete; v.events.store_complete := (r2.req.store or r2.req.dcbz) and complete; -- generate DSI or DSegI for load/store exceptions -- or ISI or ISegI for instruction fetch exceptions v.interrupt := exception; if exception = '1' then if r2.req.align_intr = '1' then v.intr_vec := 16#600#; v.dar := r2.req.addr; elsif r2.req.instr_fault = '0' then v.dar := r2.req.addr; if m_in.segerr = '0' then v.intr_vec := 16#300#; v.dsisr := dsisr; else v.intr_vec := 16#380#; end if; else if m_in.segerr = '0' then v.srr1(47 - 33) := m_in.invalid; v.srr1(47 - 35) := m_in.perm_error; -- noexec fault v.srr1(47 - 44) := m_in.badtree; v.srr1(47 - 45) := m_in.rc_error; v.intr_vec := 16#400#; else v.intr_vec := 16#480#; end if; end if; end if; case r2.wr_sel is when "00" => -- mfspr result write_data := sprval; when "01" => -- update reg write_data := r2.addr0; when "10" => -- lfs result write_data := load_dp_data; when others => -- load data write_data := data_trimmed; end case; -- Update outputs to dcache if r3.stage1_en = '1' then d_out.valid <= stage1_dcreq; d_out.load <= stage1_req.load; d_out.dcbz <= stage1_req.dcbz; d_out.nc <= stage1_req.nc; d_out.reserve <= stage1_req.reserve; d_out.atomic <= stage1_req.atomic; d_out.atomic_last <= stage1_req.atomic_last; d_out.addr <= stage1_req.addr; d_out.byte_sel <= stage1_req.byte_sel; d_out.virt_mode <= stage1_req.virt_mode; d_out.priv_mode <= stage1_req.priv_mode; else d_out.valid <= req; d_out.load <= r2.req.load; d_out.dcbz <= r2.req.dcbz; d_out.nc <= r2.req.nc; d_out.reserve <= r2.req.reserve; d_out.atomic <= r2.req.atomic; d_out.atomic_last <= r2.req.atomic_last; d_out.addr <= r2.req.addr; d_out.byte_sel <= r2.req.byte_sel; d_out.virt_mode <= r2.req.virt_mode; d_out.priv_mode <= r2.req.priv_mode; end if; if stage1_dreq = '1' then d_out.data <= store_data; else d_out.data <= r2.req.store_data; end if; d_out.hold <= l_in.e2stall; -- Update outputs to MMU m_out.valid <= mmureq; m_out.iside <= r2.req.instr_fault; m_out.load <= r2.req.load; m_out.priv <= r2.req.priv_mode; m_out.tlbie <= r2.req.tlbie; m_out.mtspr <= mmu_mtspr; m_out.sprn <= r2.req.sprn; m_out.addr <= r2.req.addr; m_out.slbia <= r2.req.is_slbia; m_out.rs <= r2.req.store_data; -- Update outputs to writeback l_out.valid <= complete; l_out.instr_tag <= r2.req.instr_tag; l_out.write_enable <= write_enable or do_update; l_out.write_reg <= r2.req.write_reg; l_out.write_data <= write_data; l_out.xerc <= r2.req.xerc; l_out.rc <= r2.req.rc and complete; l_out.store_done <= d_in.store_done; l_out.interrupt <= r3.interrupt; l_out.intr_vec <= r3.intr_vec; l_out.srr1 <= r3.srr1; -- update busy signal back to execute1 e_out.busy <= busy; e_out.l2stall <= dc_stall or d_in.error or r2.busy; events <= r3.events; flush <= exception; -- Update registers r3in <= v; end process; l1_log: if LOG_LENGTH > 0 generate signal log_data : std_ulogic_vector(9 downto 0); begin ls1_log: process(clk) begin if rising_edge(clk) then log_data <= e_out.busy & l_out.interrupt & l_out.valid & m_out.valid & d_out.valid & m_in.done & r2.req.dword_index & r2.req.valid & r2.wait_dc & std_ulogic_vector(to_unsigned(state_t'pos(r3.state), 1)); end if; end process; log_out <= log_data; end generate; end;