+"""
+Based on microwatt mmu.vhdl
+
+* https://bugs.libre-soc.org/show_bug.cgi?id=491
+* https://bugs.libre-soc.org/show_bug.cgi?id=450
+"""
+
from nmigen import Elaboratable, Module, Signal, Shape, unsigned, Cat, Mux
from nmigen import Record, Memory
from nmigen import Const
from nmutil.util import rising_edge
from soc.experiment.mmu import MMU
-from soc.experiment.dcache import DCache
from openpower.consts import MSR
from openpower.decoder.power_fields import DecodeFields
from openpower.decoder.power_fieldsn import SignalBitRange
from openpower.decoder.power_decoder2 import decode_spr_num
-from openpower.decoder.power_enums import MicrOp, XER_bits
-
-from soc.experiment.pimem import PortInterface
-from soc.experiment.pimem import PortInterfaceBase
-
-from soc.experiment.mem_types import LoadStore1ToDCacheType, LoadStore1ToMMUType
-from soc.experiment.mem_types import DCacheToLoadStore1Type, MMUToLoadStore1Type
-
-from soc.minerva.wishbone import make_wb_layout
-from soc.bus.sram import SRAM
-
-
-# glue logic for microwatt mmu and dcache
-class LoadStore1(PortInterfaceBase):
- def __init__(self, pspec):
- self.pspec = pspec
- self.disable_cache = (hasattr(pspec, "disable_cache") and
- pspec.disable_cache == True)
- regwid = pspec.reg_wid
- addrwid = pspec.addr_wid
-
- super().__init__(regwid, addrwid)
- self.dcache = DCache()
- self.d_in = self.dcache.d_in
- self.d_out = self.dcache.d_out
- self.l_in = LoadStore1ToMMUType()
- self.l_out = MMUToLoadStore1Type()
- # TODO microwatt
- self.mmureq = Signal()
- self.derror = Signal()
-
- # TODO, convert dcache wb_in/wb_out to "standard" nmigen Wishbone bus
- self.dbus = Record(make_wb_layout(pspec))
-
- # for creating a single clock blip to DCache
- self.d_valid = Signal()
- self.d_w_data = Signal(64) # XXX
- self.d_w_valid = Signal()
- self.d_validblip = Signal()
-
- def set_wr_addr(self, m, addr, mask):
- # this gets complicated: actually a FSM is needed which
- # first checks dcache, then if that fails (in virt mode)
- # it checks the MMU instead.
- #m.d.comb += self.l_in.valid.eq(1)
- #m.d.comb += self.l_in.addr.eq(addr)
- #m.d.comb += self.l_in.load.eq(0)
- m.d.comb += self.d_in.load.eq(0)
- m.d.comb += self.d_in.byte_sel.eq(mask)
- m.d.comb += self.d_in.addr.eq(addr)
- # option to disable the cache entirely for write
- if self.disable_cache:
- m.d.comb += self.d_in.nc.eq(1)
- return None
-
- def set_rd_addr(self, m, addr, mask):
- # this gets complicated: actually a FSM is needed which
- # first checks dcache, then if that fails (in virt mode)
- # it checks the MMU instead.
- #m.d.comb += self.l_in.valid.eq(1)
- #m.d.comb += self.l_in.load.eq(1)
- #m.d.comb += self.l_in.addr.eq(addr)
- m.d.comb += self.d_valid.eq(1)
- m.d.comb += self.d_in.valid.eq(self.d_validblip)
- m.d.comb += self.d_in.load.eq(1)
- m.d.comb += self.d_in.byte_sel.eq(mask)
- m.d.comb += self.d_in.addr.eq(addr)
- # BAD HACK! disable cacheing on LD when address is 0xCxxx_xxxx
- # this is for peripherals. same thing done in Microwatt loadstore1.vhdl
- with m.If(addr[28:] == Const(0xc, 4)):
- m.d.comb += self.d_in.nc.eq(1)
- # option to disable the cache entirely for read
- if self.disable_cache:
- m.d.comb += self.d_in.nc.eq(1)
- return None #FIXME return value
-
- def set_wr_data(self, m, data, wen):
- # do the "blip" on write data
- m.d.comb += self.d_valid.eq(1)
- m.d.comb += self.d_in.valid.eq(self.d_validblip)
- # put data into comb which is picked up in main elaborate()
- m.d.comb += self.d_w_valid.eq(1)
- m.d.comb += self.d_w_data.eq(data)
- #m.d.sync += self.d_in.byte_sel.eq(wen) # this might not be needed
- st_ok = self.d_out.valid # TODO indicates write data is valid
- #st_ok = Const(1, 1)
- return st_ok
-
- def get_rd_data(self, m):
- ld_ok = self.d_out.valid # indicates read data is valid
- data = self.d_out.data # actual read data
- return data, ld_ok
+from openpower.decoder.power_enums import MicrOp
- """
- 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_LOOKUP;
- v.stage1_en := '0';
- end if;
- end if;
- """
+from soc.experiment.mem_types import LoadStore1ToMMUType
+from soc.experiment.mem_types import MMUToLoadStore1Type
- def elaborate(self, platform):
- m = super().elaborate(platform)
- comb = m.d.comb
-
- # create dcache module
- m.submodules.dcache = dcache = self.dcache
-
- # temp vars
- d_out, l_out, dbus = self.d_out, self.l_out, self.dbus
-
- with m.If(d_out.error):
- with m.If(d_out.cache_paradox):
- comb += self.derror.eq(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;
- with m.Else():
- # Look up the translation for TLB miss
- # and also for permission error and RC error
- # in case the PTE has been updated.
- comb += self.mmureq.eq(1)
- # v.state := MMU_LOOKUP;
- # v.stage1_en := '0';
-
- exc = self.pi.exc_o
-
- #happened, alignment, instr_fault, invalid,
- comb += exc.happened.eq(d_out.error | l_out.err)
- comb += exc.invalid.eq(l_out.invalid)
-
- #badtree, perm_error, rc_error, segment_fault
- comb += exc.badtree.eq(l_out.badtree)
- comb += exc.perm_error.eq(l_out.perm_error)
- comb += exc.rc_error.eq(l_out.rc_error)
- comb += exc.segment_fault.eq(l_out.segerr)
-
- # TODO connect those signals somewhere
- #print(d_out.valid) -> no error
- #print(d_out.store_done) -> no error
- #print(d_out.cache_paradox) -> ?
- #print(l_out.done) -> no error
-
- # TODO some exceptions set SPRs
-
- # TODO, connect dcache wb_in/wb_out to "standard" nmigen Wishbone bus
- comb += dbus.adr.eq(dcache.wb_out.adr)
- comb += dbus.dat_w.eq(dcache.wb_out.dat)
- comb += dbus.sel.eq(dcache.wb_out.sel)
- comb += dbus.cyc.eq(dcache.wb_out.cyc)
- comb += dbus.stb.eq(dcache.wb_out.stb)
- comb += dbus.we.eq(dcache.wb_out.we)
-
- comb += dcache.wb_in.dat.eq(dbus.dat_r)
- comb += dcache.wb_in.ack.eq(dbus.ack)
- if hasattr(dbus, "stall"):
- comb += dcache.wb_in.stall.eq(dbus.stall)
-
- # create a blip (single pulse) on valid read/write request
- m.d.comb += self.d_validblip.eq(rising_edge(m, self.d_valid))
-
- # write out d data only when flag set
- with m.If(self.d_w_valid):
- m.d.sync += self.d_in.data.eq(self.d_w_data)
- with m.Else():
- m.d.sync += self.d_in.data.eq(0)
-
- return m
-
- def ports(self):
- yield from super().ports()
- # TODO: memory ports
-
-
-class TestSRAMLoadStore1(LoadStore1):
- def __init__(self, pspec):
- super().__init__(pspec)
- pspec = self.pspec
- # small 32-entry Memory
- if (hasattr(pspec, "dmem_test_depth") and
- isinstance(pspec.dmem_test_depth, int)):
- depth = pspec.dmem_test_depth
- else:
- depth = 32
- print("TestSRAMBareLoadStoreUnit depth", depth)
-
- self.mem = Memory(width=pspec.reg_wid, depth=depth)
-
- def elaborate(self, platform):
- m = super().elaborate(platform)
- comb = m.d.comb
- m.submodules.sram = sram = SRAM(memory=self.mem, granularity=8,
- features={'cti', 'bte', 'err'})
- dbus = self.dbus
-
- # directly connect the wishbone bus of LoadStoreUnitInterface to SRAM
- # note: SRAM is a target (slave), dbus is initiator (master)
- fanouts = ['dat_w', 'sel', 'cyc', 'stb', 'we', 'cti', 'bte']
- fanins = ['dat_r', 'ack', 'err']
- for fanout in fanouts:
- print("fanout", fanout, getattr(sram.bus, fanout).shape(),
- getattr(dbus, fanout).shape())
- comb += getattr(sram.bus, fanout).eq(getattr(dbus, fanout))
- comb += getattr(sram.bus, fanout).eq(getattr(dbus, fanout))
- for fanin in fanins:
- comb += getattr(dbus, fanin).eq(getattr(sram.bus, fanin))
- # connect address
- comb += sram.bus.adr.eq(dbus.adr)
-
- return m
+from soc.fu.ldst.loadstore import LoadStore1, TestSRAMLoadStore1
class FSMMMUStage(ControlBase):
FSM-based MMU: must call set_ldst_interface and pass in an instance
of a LoadStore1. this to comply with the ConfigMemoryPortInterface API
+
+ this Function Unit is extremely unusual in that it actually stores a
+ "thing" rather than "processes inputs and produces outputs". hence
+ why it has to be a FSM. linking up LD/ST however is going to have
+ to be done back in Issuer (or Core). sorted: call set_ldst_interface
"""
def __init__(self, pspec):
super().__init__()
self.pspec = pspec
# set up p/n data
- self.p.data_i = MMUInputData(pspec)
- self.n.data_o = MMUOutputData(pspec)
-
- # this Function Unit is extremely unusual in that it actually stores a
- # "thing" rather than "processes inputs and produces outputs". hence
- # why it has to be a FSM. linking up LD/ST however is going to have
- # to be done back in Issuer (or Core)
+ self.p.i_data = MMUInputData(pspec)
+ self.n.o_data = MMUOutputData(pspec)
self.mmu = MMU()
- # make life a bit easier in Core XXX mustn't really do this,
- # pspec is designed for config variables, rather than passing
- # things around. have to think about it, design a way to do
- # it that makes "sense"
- # comment out for now self.pspec.mmu = self.mmu
- # comment out for now self.pspec.dcache = self.dcache
-
# debugging output for gtkw
self.debug0 = Signal(4)
self.illegal = Signal()
# for SPR field number access
- i = self.p.data_i
+ i = self.p.i_data
self.fields = DecodeFields(SignalBitRange, [i.ctx.op.insn])
self.fields.create_specs()
def elaborate(self, platform):
assert hasattr(self, "dcache"), "remember to call set_ldst_interface"
m = super().elaborate(platform)
- comb = m.d.comb
+ comb, sync = m.d.comb, m.d.sync
dcache = self.dcache
# link mmu and dcache together
wb_out, wb_in = dcache.wb_out, dcache.wb_in
# link ldst and MMU together
- comb += l_in.eq(ldst.l_in)
- comb += ldst.l_out.eq(l_out)
+ comb += l_in.eq(ldst.m_out)
+ comb += ldst.m_in.eq(l_out)
- data_i, data_o = self.p.data_i, self.n.data_o
- a_i, b_i, o, spr1_o = data_i.ra, data_i.rb, data_o.o, data_o.spr1
- op = data_i.ctx.op
+ i_data, o_data = self.p.i_data, self.n.o_data
+ a_i, b_i, o, spr1_o = i_data.ra, i_data.rb, o_data.o, o_data.spr1
+ op = i_data.ctx.op
msr_i = op.msr
- spr1_i = data_i.spr1
+ spr1_i = i_data.spr1
- # TODO: link these SPRs somewhere
- dsisr = Signal(64)
- dar = Signal(64)
+ # these are set / got here *ON BEHALF* of LoadStore1
+ dsisr, dar = ldst.dsisr, ldst.dar
# busy/done signals
busy = Signal()
with m.If(~busy):
with m.If(self.p.valid_i):
- m.d.sync += busy.eq(1)
+ sync += busy.eq(1)
with m.Else():
# based on the Micro-Op, we work out which of MMU or DCache
# regfile because the CSV file entry for OP_MTSPR
# categorically defines and requires the expectation
# that the CompUnit **WILL** write to the regfile.
- comb += spr1_o.data.eq(spr)
+ comb += spr1_o.data.eq(a_i)
comb += spr1_o.ok.eq(1)
# subset SPR: first check a few bits
+ # XXX NOTE this must now cover **FOUR** values: this
+ # test might not be adequate. DSISR, DAR, PGTBL and PID
+ # must ALL be covered here.
with m.If(~spr[9] & ~spr[5]):
comb += self.debug0.eq(3)
#if matched update local cached value
- with m.If(spr[0]):
- sync += dsisr.eq(a_i[:32])
- with m.Else():
- sync += dar.eq(a_i)
+ #commented out because there is a driver conflict
+ #with m.If(spr[0]):
+ # sync += dsisr.eq(a_i[:32])
+ #with m.Else():
+ # sync += dar.eq(a_i)
comb += done.eq(1)
# pass it over to the MMU instead
with m.Else():
comb += self.illegal.eq(1)
with m.If(self.n.ready_i & self.n.valid_o):
- m.d.sync += busy.eq(0)
+ sync += busy.eq(0)
return m