from nmutil.util import treereduce
from nmutil.singlepipe import ControlBase
-from soc.fu.compunits.compunits import AllFunctionUnits
+from soc.fu.compunits.compunits import AllFunctionUnits, LDSTFunctionUnit
from soc.regfile.regfiles import RegFiles
-from openpower.decoder.decode2execute1 import Decode2ToExecute1Type
-from openpower.decoder.decode2execute1 import IssuerDecode2ToOperand
from openpower.decoder.power_decoder2 import get_rdflags
-from openpower.decoder.decode2execute1 import Data
from soc.experiment.l0_cache import TstL0CacheBuffer # test only
from soc.config.test.test_loadstore import TestMemPspec
from openpower.decoder.power_enums import MicrOp, Function
-from soc.config.state import CoreState
+from soc.simple.core_data import CoreInput, CoreOutput
from collections import defaultdict
import operator
return res # enumerate(res)
-class CoreInput:
- """CoreInput: this is the input specification for Signals coming into core.
-
- * state. this contains PC, MSR, and SVSTATE. this is crucial information.
- (TODO: bigendian_i should really be read from the relevant MSR bit)
-
- * the previously-decoded instruction goes into the Decode2Execute1Type
- data structure. no need for Core to re-decode that. however note
- that *satellite* decoders *are* part of Core.
-
- * the raw instruction. this is used by satellite decoders internal to
- Core, to provide Function-Unit-specific information. really, they
- should be part of the actual ALU itself (in order to reduce wires),
- but hey.
-
- * other stuff is related to SVP64. the 24-bit SV REMAP field containing
- Vector context, etc.
- """
- def __init__(self, pspec, svp64_en, regreduce_en):
- self.pspec = pspec
- self.svp64_en = svp64_en
- self.e = Decode2ToExecute1Type("core", opkls=IssuerDecode2ToOperand,
- regreduce_en=regreduce_en)
-
- # SVP64 RA_OR_ZERO needs to know if the relevant EXTRA2/3 field is zero
- self.sv_a_nz = Signal()
-
- # state and raw instruction (and SVP64 ReMap fields)
- self.state = CoreState("core")
- self.raw_insn_i = Signal(32) # raw instruction
- self.bigendian_i = Signal() # bigendian - TODO, set by MSR.BE
- if svp64_en:
- self.sv_rm = SVP64Rec(name="core_svp64_rm") # SVP64 RM field
- self.is_svp64_mode = Signal() # set if SVP64 mode is enabled
- self.use_svp64_ldst_dec = Signal() # use alternative LDST decoder
- self.sv_pred_sm = Signal() # TODO: SIMD width
- self.sv_pred_dm = Signal() # TODO: SIMD width
-
- def eq(self, i):
- self.e.eq(i.e)
- self.sv_a_nz.eq(i.sv_a_nz)
- self.state.eq(i.state)
- self.raw_insn_i.eq(i.raw_insn_i)
- self.bigendian_i.eq(i.bigendian_i)
- if not self.svp64_en:
- return
- self.sv_rm.eq(i.sv_rm)
- self.is_svp64_mode.eq(i.is_svp64_mode)
- self.use_svp64_ldst_dec.eq(i.use_svp64_ldst_dec)
- self.sv_pred_sm.eq(i.sv_pred_sm)
- self.sv_pred_dm.eq(i.sv_pred_dm)
-
-
-class CoreOutput:
- def __init__(self):
- # start/stop and terminated signalling
- self.core_terminate_o = Signal() # indicates stopped
- self.busy_o = Signal(name="corebusy_o") # at least one ALU busy
- self.exc_happened = Signal() # exception happened
-
- def eq(self, i):
- self.core_terminate_o.eq(i.core_terminate_o)
- self.busy_o.eq(i.busy_o)
- self.exc_happened.eq(i.exc_happened)
-
-
# derive from ControlBase rather than have a separate Stage instance,
# this is simpler to do
class NonProductionCore(ControlBase):
self.regreduce_en = (hasattr(pspec, "regreduce") and
(pspec.regreduce == True))
+ # test to see if overlapping of instructions is allowed
+ # (not normally enabled for TestIssuer FSM but useful for checking
+ # the bitvector hazard detection, before doing In-Order)
+ self.allow_overlap = (hasattr(pspec, "allow_overlap") and
+ (pspec.allow_overlap == True))
+
# test core type
+ self.make_hazard_vecs = True
self.core_type = "fsm"
- if hasattr(pspec, "core_type":
+ if hasattr(pspec, "core_type"):
self.core_type = pspec.core_type
super().__init__(stage=self)
mmu = self.fus.get_fu('mmu0')
print ("core pspec", pspec.ldst_ifacetype)
print ("core mmu", mmu)
- print ("core lsmem.lsi", l0.cmpi.lsmem.lsi)
if mmu is not None:
+ print ("core lsmem.lsi", l0.cmpi.lsmem.lsi)
mmu.alu.set_ldst_interface(l0.cmpi.lsmem.lsi)
# register files (yes plural)
- self.regs = RegFiles(pspec, make_hazard_vecs=True)
+ self.regs = RegFiles(pspec, make_hazard_vecs=self.make_hazard_vecs)
# set up input and output: unusual requirement to set data directly
# (due to the way that the core is set up in a different domain,
# see TestIssuer.setup_peripherals
- self.i, self.o = self.new_specs(None)
+ self.p.i_data, self.n.o_data = self.new_specs(None)
self.i, self.o = self.p.i_data, self.n.o_data
- # create per-FU instruction decoders (subsetted)
+ # actual internal input data used (captured)
+ self.ireg = self.ispec()
+
+ # create per-FU instruction decoders (subsetted). these "satellite"
+ # decoders reduce wire fan-out from the one (main) PowerDecoder2
+ # (used directly by the trap unit) to the *twelve* (or more)
+ # Function Units. we can either have 32 wires (the instruction)
+ # to each, or we can have well over a 200 wire fan-out (to 12
+ # ALUs). it's an easy choice to make.
self.decoders = {}
self.des = {}
continue
self.decoders[funame] = PowerDecodeSubset(None, opkls, f_name,
final=True,
- state=self.i.state,
+ state=self.ireg.state,
svp64_en=self.svp64_en,
regreduce_en=self.regreduce_en)
self.des[funame] = self.decoders[funame].do
+ # share the SPR decoder with the MMU if it exists
if "mmu0" in self.decoders:
self.decoders["mmu0"].mmu0_spr_dec = self.decoders["spr0"]
+ # next 3 functions are Stage API Compliance
def setup(self, m, i):
pass
def ospec(self):
return CoreOutput()
+ # elaborate function to create HDL
def elaborate(self, platform):
m = super().elaborate(platform)
self.connect_satellite_decoders(m)
# ssh, cheat: trap uses the main decoder because of the rewriting
- self.des[self.trapunit] = self.i.e.do
+ self.des[self.trapunit] = self.ireg.e.do
- # connect up Function Units, then read/write ports
- fu_bitdict, fu_selected = self.connect_instruction(m)
- self.connect_rdports(m, fu_selected)
+ # connect up Function Units, then read/write ports, and hazard conflict
+ issue_conflict = Signal()
+ fu_bitdict, fu_selected = self.connect_instruction(m, issue_conflict)
+ raw_hazard = self.connect_rdports(m, fu_selected)
self.connect_wrports(m, fu_selected)
+ if self.allow_overlap:
+ comb += issue_conflict.eq(raw_hazard)
# note if an exception happened. in a pipelined or OoO design
# this needs to be accompanied by "shadowing" (or stalling)
# as subset decoders this massively reduces wire fanout given
# the large number of ALUs
setattr(m.submodules, "dec_%s" % v.fn_name, v)
- comb += v.dec.raw_opcode_in.eq(self.i.raw_insn_i)
- comb += v.dec.bigendian.eq(self.i.bigendian_i)
+ comb += v.dec.raw_opcode_in.eq(self.ireg.raw_insn_i)
+ comb += v.dec.bigendian.eq(self.ireg.bigendian_i)
# sigh due to SVP64 RA_OR_ZERO detection connect these too
- comb += v.sv_a_nz.eq(self.i.sv_a_nz)
+ comb += v.sv_a_nz.eq(self.ireg.sv_a_nz)
if self.svp64_en:
- comb += v.pred_sm.eq(self.i.sv_pred_sm)
- comb += v.pred_dm.eq(self.i.sv_pred_dm)
+ comb += v.pred_sm.eq(self.ireg.sv_pred_sm)
+ comb += v.pred_dm.eq(self.ireg.sv_pred_dm)
if k != self.trapunit:
- comb += v.sv_rm.eq(self.i.sv_rm) # pass through SVP64 ReMap
- comb += v.is_svp64_mode.eq(self.i.is_svp64_mode)
+ comb += v.sv_rm.eq(self.ireg.sv_rm) # pass through SVP64 RM
+ comb += v.is_svp64_mode.eq(self.ireg.is_svp64_mode)
# only the LDST PowerDecodeSubset *actually* needs to
# know to use the alternative decoder. this is all
# a terrible hack
if k.lower().startswith("ldst"):
comb += v.use_svp64_ldst_dec.eq(
- self.i.use_svp64_ldst_dec)
+ self.ireg.use_svp64_ldst_dec)
- def connect_instruction(self, m):
+ def connect_instruction(self, m, issue_conflict):
"""connect_instruction
uses decoded (from PowerOp) function unit information from CSV files
# indicate if core is busy
busy_o = self.o.busy_o
+ # connect up temporary copy of incoming instruction. the FSM will
+ # either blat the incoming instruction (if valid) into self.ireg
+ # or if the instruction could not be delivered, keep dropping the
+ # latched copy into ireg
+ ilatch = self.ispec()
+ self.instr_active = Signal()
+
# enable/busy-signals for each FU, get one bit for each FU (by name)
fu_enable = Signal(len(fus), reset_less=True)
fu_busy = Signal(len(fus), reset_less=True)
# instruction.
fnunit = fu.fnunit.value
en_req = Signal(name="issue_en_%s" % funame, reset_less=True)
- fnmatch = (self.i.e.do.fn_unit & fnunit).bool()
- comb += en_req.eq(fnmatch & ~fu.busy_o & self.p.i_valid)
+ fnmatch = (self.ireg.e.do.fn_unit & fnunit).bool()
+ comb += en_req.eq(fnmatch & ~fu.busy_o & self.instr_active)
i_l.append(en_req) # store in list for doing the Cat-trick
# picker output, gated by enable: store in fu_bitdict
po = Signal(name="o_issue_pick_"+funame) # picker output
# if we don't do this, then when there are no FUs available,
# the "p.o_ready" signal will go back "ok we accepted this
# instruction" which of course isn't true.
- comb += fu_found.eq(~fnmatch | i_pp.en_o)
+ with m.If(~issue_conflict & i_pp.en_o):
+ comb += fu_found.eq(1)
# for each input, Cat them together and drop them into the picker
comb += i_pp.i.eq(Cat(*i_l))
+ # rdmask, which is for registers needs to come from the *main* decoder
+ for funame, fu in fus.items():
+ rdmask = get_rdflags(self.ireg.e, fu)
+ comb += fu.rdmaskn.eq(~rdmask)
+
# sigh - need a NOP counter
counter = Signal(2)
with m.If(counter != 0):
sync += counter.eq(counter - 1)
comb += busy_o.eq(1)
- with m.If(self.p.i_valid): # run only when valid
- with m.Switch(self.i.e.do.insn_type):
- # check for ATTN: halt if true
- with m.Case(MicrOp.OP_ATTN):
- m.d.sync += self.o.core_terminate_o.eq(1)
-
- # fake NOP - this isn't really used (Issuer detects NOP)
- with m.Case(MicrOp.OP_NOP):
- sync += counter.eq(2)
- comb += busy_o.eq(1)
-
- with m.Default():
- # connect up instructions. only one enabled at a time
+ # default to reading from incoming instruction: may be overridden
+ # by copy from latch when "waiting"
+ comb += self.ireg.eq(self.i)
+ # always say "ready" except if overridden
+ comb += self.p.o_ready.eq(1)
+
+ l_issue_conflict = Signal()
+
+ with m.FSM():
+ with m.State("READY"):
+ with m.If(self.p.i_valid): # run only when valid
+ with m.Switch(self.ireg.e.do.insn_type):
+ # check for ATTN: halt if true
+ with m.Case(MicrOp.OP_ATTN):
+ m.d.sync += self.o.core_terminate_o.eq(1)
+
+ # fake NOP - this isn't really used (Issuer detects NOP)
+ with m.Case(MicrOp.OP_NOP):
+ sync += counter.eq(2)
+ comb += busy_o.eq(1)
+
+ with m.Default():
+ comb += self.instr_active.eq(1)
+ comb += self.p.o_ready.eq(0)
+ # connect instructions. only one enabled at a time
+ for funame, fu in fus.items():
+ do = self.des[funame]
+ enable = fu_bitdict[funame]
+
+ # run this FunctionUnit if enabled route op,
+ # issue, busy, read flags and mask to FU
+ with m.If(enable & ~issue_conflict):
+ # operand comes from the *local* decoder
+ comb += fu.oper_i.eq_from(do)
+ comb += fu.issue_i.eq(1) # issue when valid
+ # instruction ok, indicate ready
+ comb += self.p.o_ready.eq(1)
+
+ if self.allow_overlap:
+ with m.If(~fu_found):
+ # latch copy of instruction
+ sync += ilatch.eq(self.i)
+ sync += l_issue_conflict.eq(issue_conflict)
+ comb += self.p.o_ready.eq(1) # accept
+ comb += busy_o.eq(1)
+ m.next = "WAITING"
+
+ with m.State("WAITING"):
+ comb += self.instr_active.eq(1)
+ with m.If(fu_found):
+ sync += l_issue_conflict.eq(0)
+ comb += self.p.o_ready.eq(0)
+ comb += busy_o.eq(1)
+ # using copy of instruction, keep waiting until an FU is free
+ comb += self.ireg.eq(ilatch)
+ with m.If(~l_issue_conflict): # wait for conflict to clear
+ # connect instructions. only one enabled at a time
for funame, fu in fus.items():
do = self.des[funame]
enable = fu_bitdict[funame]
- # run this FunctionUnit if enabled
- # route op, issue, busy, read flags and mask to FU
+ # run this FunctionUnit if enabled route op,
+ # issue, busy, read flags and mask to FU
with m.If(enable):
# operand comes from the *local* decoder
comb += fu.oper_i.eq_from(do)
- comb += fu.issue_i.eq(1) # issue when input valid
- # rdmask, which is for registers, needs to come
- # from the *main* decoder
- rdmask = get_rdflags(self.i.e, fu)
- comb += fu.rdmaskn.eq(~rdmask)
-
- # if instruction is busy, set busy output for core.
- busys = map(lambda fu: fu.busy_o, fus.values())
- comb += busy_o.eq(Cat(*busys).bool())
-
- # ready/valid signalling. if busy, means refuse incoming issue.
- # (this is a global signal, TODO, change to one which allows
- # overlapping instructions)
- # also, if there was no fu found we must not send back a valid
- # indicator. BUT, of course, when there is no instruction
- # we must ignore the fu_found flag, otherwise o_ready will never
- # be set when everything is idle
- comb += self.p.o_ready.eq(fu_found | ~self.p.i_valid)
+ comb += fu.issue_i.eq(1) # issue when valid
+ comb += self.p.o_ready.eq(1)
+ comb += busy_o.eq(0)
+ m.next = "READY"
+
+ print ("core: overlap allowed", self.allow_overlap)
+ if not self.allow_overlap:
+ # for simple non-overlap, if any instruction is busy, set
+ # busy output for core.
+ busys = map(lambda fu: fu.busy_o, fus.values())
+ comb += busy_o.eq(Cat(*busys).bool())
# return both the function unit "enable" dict as well as the "busy".
# the "busy-or-issued" can be passed in to the Read/Write port
print("read regfile", rpidx, regfile, regs.rf.keys(),
rfile, rfile.unary)
+ # for checking if the read port has an outstanding write
+ if self.make_hazard_vecs:
+ wv = regs.wv[regfile.lower()]
+ wvchk = wv.r_ports["issue"] # write-vec bit-level hazard check
+
fspecs = fspec
if not isinstance(fspecs, list):
fspecs = [fspecs]
rdflags = []
pplen = 0
- reads = []
ppoffs = []
for i, fspec in enumerate(fspecs):
# get the regfile specs for this regfile port
- (rf, read, write, wid, fuspec) = fspec
+ (rf, wf, read, write, wid, fuspec) = fspec
print ("fpsec", i, fspec, len(fuspec))
ppoffs.append(pplen) # record offset for picker
pplen += len(fuspec)
rdflag = Signal(name=name, reset_less=True)
comb += rdflag.eq(rf)
rdflags.append(rdflag)
- reads.append(read)
print ("pplen", pplen)
rens = []
addrs = []
+ wvens = []
+
for i, fspec in enumerate(fspecs):
- (rf, read, write, wid, fuspec) = fspec
+ (rf, wf, _read, _write, wid, fuspec) = fspec
# connect up the FU req/go signals, and the reg-read to the FU
# and create a Read Broadcast Bus
for pi, (funame, fu, idx) in enumerate(fuspec):
pi += ppoffs[i]
+ name = "%s_%s_%s_%i" % (regfile, rpidx, funame, pi)
+ fu_active = fu_bitdict[funame]
+
+ # get (or set up) a latched copy of read register number
+ rname = "%s_%s_%s_%d" % (funame, regfile, regname, pi)
+ read = Signal.like(_read, name="read_"+name)
+ if rname not in fu.rd_latches:
+ rdl = Signal.like(_read, name="rdlatch_"+rname)
+ fu.rd_latches[rname] = rdl
+ with m.If(fu.issue_i):
+ sync += rdl.eq(_read)
+ else:
+ rdl = fu.rd_latches[rname]
+ # latch to make the read immediately available on issue cycle
+ # after the read cycle, use the latched copy
+ with m.If(fu.issue_i):
+ comb += read.eq(_read)
+ with m.Else():
+ comb += read.eq(rdl)
# connect request-read to picker input, and output to go-rd
- fu_active = fu_bitdict[funame]
- name = "%s_%s_%s_%i" % (regfile, rpidx, funame, pi)
- addr_en = Signal.like(reads[i], name="addr_en_"+name)
+ addr_en = Signal.like(read, name="addr_en_"+name)
pick = Signal(name="pick_"+name) # picker input
rp = Signal(name="rp_"+name) # picker output
delay_pick = Signal(name="dp_"+name) # read-enable "underway"
# if picked, select read-port "reg select" number to port
comb += rp.eq(rdpick.o[pi] & rdpick.en_o)
sync += delay_pick.eq(rp) # delayed "pick"
- comb += addr_en.eq(Mux(rp, reads[i], 0))
+ comb += addr_en.eq(Mux(rp, read, 0))
# the read-enable happens combinatorially (see mux-bus below)
# but it results in the data coming out on a one-cycle delay.
# all FUs connect to same port
comb += src.eq(rport.o_data)
+ if not self.make_hazard_vecs:
+ continue
+
+ # read the write-hazard bitvector (wv) for any bit that is
+ wvchk_en = Signal(len(wvchk.ren), name="wv_chk_addr_en_"+name)
+ issue_active = Signal(name="rd_iactive_"+name)
+ # XXX combinatorial loop here
+ comb += issue_active.eq(self.instr_active & rf)
+ with m.If(issue_active):
+ if rfile.unary:
+ comb += wvchk_en.eq(read)
+ else:
+ comb += wvchk_en.eq(1<<read)
+ wvens.append(wvchk_en)
+
# or-reduce the muxed read signals
if rfile.unary:
# for unary-addressed
comb += rport.ren.eq(Cat(*rens).bool())
print ("binary", regfile, rpidx, rport, rport.ren, rens, addrs)
+ if not self.make_hazard_vecs:
+ return Const(0) # declare "no hazards"
+
+ # enable the read bitvectors for this issued instruction
+ # and return whether any write-hazard bit is set
+ comb += wvchk.ren.eq(ortreereduce_sig(wvens))
+ hazard_detected = Signal(name="raw_%s_%s" % (regfile, rpidx))
+ comb += hazard_detected.eq(wvchk.o_data.bool())
+ return hazard_detected
+
def connect_rdports(self, m, fu_bitdict):
"""connect read ports
comb, sync = m.d.comb, m.d.sync
fus = self.fus.fus
regs = self.regs
+ rd_hazard = []
# dictionary of lists of regfile read ports
byregfiles_rd, byregfiles_rdspec = self.get_byregfiles(True)
fuspecs['fast1'].append(fuspecs.pop('fast3'))
# for each named regfile port, connect up all FUs to that port
+ # also return (and collate) hazard detection)
for (regname, fspec) in sort_fuspecs(fuspecs):
print("connect rd", regname, fspec)
- self.connect_rdport(m, fu_bitdict, rdpickers, regfile,
+ rh = self.connect_rdport(m, fu_bitdict, rdpickers, regfile,
regname, fspec)
+ rd_hazard.append(rh)
+
+ return Cat(*rd_hazard).bool()
+
+ def make_hazards(self, m, regfile, rfile, wvclr, wvset,
+ funame, regname, idx,
+ addr_en, wp, fu, fu_active, wrflag, write,
+ fu_wrok):
+ """make_hazards: a setter and a clearer for the regfile write ports
+
+ setter is at issue time (using PowerDecoder2 regfile write numbers)
+ clearer is at regfile write time (when FU has said what to write to)
+
+ there is *one* unusual case here which has to be dealt with:
+ when the Function Unit does *NOT* request a write to the regfile
+ (has its data.ok bit CLEARED). this is perfectly legitimate.
+ and a royal pain.
+ """
+ comb, sync = m.d.comb, m.d.sync
+ name = "%s_%s_%d" % (funame, regname, idx)
+
+ # connect up the bitvector write hazard. unlike the
+ # regfile writeports, a ONE must be written to the corresponding
+ # bit of the hazard bitvector (to indicate the existence of
+ # the hazard)
+
+ # the detection of what shall be written to is based
+ # on *issue*
+ print ("write vector (for regread)", regfile, wvset)
+ wviaddr_en = Signal(len(wvset.wen), name="wv_issue_addr_en_"+name)
+ issue_active = Signal(name="iactive_"+name)
+ comb += issue_active.eq(fu.issue_i & fu_active & wrflag)
+ with m.If(issue_active):
+ if rfile.unary:
+ comb += wviaddr_en.eq(write)
+ else:
+ comb += wviaddr_en.eq(1<<write)
+
+ # deal with write vector clear: this kicks in when the regfile
+ # is written to, and clears the corresponding bitvector entry
+ print ("write vector", regfile, wvclr)
+ wvaddr_en = Signal(len(wvclr.wen), name="wvaddr_en_"+name)
+ if rfile.unary:
+ comb += wvaddr_en.eq(addr_en)
+ else:
+ with m.If(wp):
+ comb += wvaddr_en.eq(1<<addr_en)
+
+ # XXX ASSUME that LDSTFunctionUnit always sets the data it intends to
+ # this may NOT be the case when an exception occurs
+ if isinstance(fu, LDSTFunctionUnit):
+ return wvaddr_en, wviaddr_en
+
+ # okaaay, this is preparation for the awkward case.
+ # * latch a copy of wrflag when issue goes high.
+ # * when the fu_wrok (data.ok) flag is NOT set,
+ # but the FU is done, the FU is NEVER going to write
+ # so the bitvector has to be cleared.
+ latch_wrflag = Signal(name="latch_wrflag_"+name)
+ with m.If(~fu.busy_o):
+ sync += latch_wrflag.eq(0)
+ with m.If(fu.issue_i & fu_active):
+ sync += latch_wrflag.eq(wrflag)
+ with m.If(fu.alu_done_o & latch_wrflag & ~fu_wrok):
+ if rfile.unary:
+ comb += wvaddr_en.eq(write) # addr_en gated with wp, don't use
+ else:
+ comb += wvaddr_en.eq(1<<addr_en) # binary addr_en not gated
+
+ return wvaddr_en, wviaddr_en
def connect_wrport(self, m, fu_bitdict, wrpickers, regfile, regname, fspec):
comb, sync = m.d.comb, m.d.sync
fus = self.fus.fus
regs = self.regs
- print("connect wr", regname, fspec)
rpidx = regname
# select the required write port. these are pre-defined sizes
- print(regfile, regs.rf.keys())
rfile = regs.rf[regfile.lower()]
wport = rfile.w_ports[rpidx]
+ print("connect wr", regname, "unary", rfile.unary, fspec)
+ print(regfile, regs.rf.keys())
+
+ # select the write-protection hazard vector. note that this still
+ # requires to WRITE to the hazard bitvector! read-requests need
+ # to RAISE the bitvector (set it to 1), which, duh, requires a WRITE
+ if self.make_hazard_vecs:
+ wv = regs.wv[regfile.lower()]
+ wvset = wv.w_ports["set"] # write-vec bit-level hazard ctrl
+ wvclr = wv.w_ports["clr"] # write-vec bit-level hazard ctrl
+
fspecs = fspec
if not isinstance(fspecs, list):
fspecs = [fspecs]
pplen = 0
writes = []
ppoffs = []
+ rdflags = []
+ wrflags = []
for i, fspec in enumerate(fspecs):
# get the regfile specs for this regfile port
- (rf, read, write, wid, fuspec) = fspec
- print ("fpsec", i, fspec, len(fuspec))
+ (rf, wf, read, write, wid, fuspec) = fspec
+ print ("fpsec", i, "wrflag", wf, fspec, len(fuspec))
ppoffs.append(pplen) # record offset for picker
pplen += len(fuspec)
+ name = "%s_%s_%d" % (regfile, regname, i)
+ rdflag = Signal(name="rd_flag_"+name)
+ wrflag = Signal(name="wr_flag_"+name)
+ if rf is not None:
+ comb += rdflag.eq(rf)
+ else:
+ comb += rdflag.eq(0)
+ if wf is not None:
+ comb += wrflag.eq(wf)
+ else:
+ comb += wrflag.eq(0)
+ rdflags.append(rdflag)
+ wrflags.append(wrflag)
+
# create a priority picker to manage this port
wrpickers[regfile][rpidx] = wrpick = PriorityPicker(pplen)
setattr(m.submodules, "wrpick_%s_%s" % (regfile, rpidx), wrpick)
wsigs = []
wens = []
+ wvsets = []
+ wvseten = []
+ wvclren = []
addrs = []
for i, fspec in enumerate(fspecs):
# connect up the FU req/go signals and the reg-read to the FU
# these are arbitrated by Data.ok signals
- (rf, read, write, wid, fuspec) = fspec
+ (rf, wf, read, _write, wid, fuspec) = fspec
for pi, (funame, fu, idx) in enumerate(fuspec):
pi += ppoffs[i]
+ name = "%s_%s_%s_%d" % (funame, regfile, regname, idx)
+ # get (or set up) a write-latched copy of write register number
+ write = Signal.like(_write, name="write_"+name)
+ rname = "%s_%s_%s" % (funame, regfile, regname)
+ if rname not in fu.wr_latches:
+ wrl = Signal.like(_write, name="wrlatch_"+rname)
+ fu.wr_latches[rname] = write
+ with m.If(fu.issue_i):
+ sync += wrl.eq(_write)
+ comb += write.eq(_write)
+ with m.Else():
+ comb += write.eq(wrl)
+ else:
+ write = fu.wr_latches[rname]
# write-request comes from dest.ok
dest = fu.get_out(idx)
fu_dest_latch = fu.get_fu_out(idx) # latched output
- name = "wrflag_%s_%s_%d" % (funame, regname, idx)
- wrflag = Signal(name=name, reset_less=True)
- comb += wrflag.eq(dest.ok & fu.busy_o)
+ name = "fu_wrok_%s_%s_%d" % (funame, regname, idx)
+ fu_wrok = Signal(name=name, reset_less=True)
+ comb += fu_wrok.eq(dest.ok & fu.busy_o)
# connect request-write to picker input, and output to go-wr
fu_active = fu_bitdict[funame]
- pick = fu.wr.rel_o[idx] & fu_active # & wrflag
+ pick = fu.wr.rel_o[idx] & fu_active
comb += wrpick.i[pi].eq(pick)
# create a single-pulse go write from the picker output
wr_pick = Signal(name="wpick_%s_%s_%d" % (funame, regname, idx))
# connect the regspec write "reg select" number to this port
# only if one FU actually requests (and is granted) the port
# will the write-enable be activated
- addr_en = Signal.like(write)
+ wname = "waddr_en_%s_%s_%d" % (funame, regname, idx)
+ addr_en = Signal.like(write, name=wname)
wp = Signal()
comb += wp.eq(wr_pick & wrpick.en_o)
comb += addr_en.eq(Mux(wp, write, 0))
dest.shape(), wport.i_data.shape())
wsigs.append(fu_dest_latch)
+ # now connect up the bitvector write hazard
+ if not self.make_hazard_vecs:
+ continue
+ res = self.make_hazards(m, regfile, rfile, wvclr, wvset,
+ funame, regname, idx,
+ addr_en, wp, fu, fu_active,
+ wrflags[i], write, fu_wrok)
+ wvaddr_en, wv_issue_en = res
+ wvclren.append(wvaddr_en) # set only: no data => clear bit
+ wvseten.append(wv_issue_en) # set data same as enable
+ wvsets.append(wv_issue_en) # because enable needs a 1
+
# here is where we create the Write Broadcast Bus. simple, eh?
comb += wport.i_data.eq(ortreereduce_sig(wsigs))
if rfile.unary:
comb += wport.addr.eq(ortreereduce_sig(addrs))
comb += wport.wen.eq(ortreereduce_sig(wens))
+ if not self.make_hazard_vecs:
+ return
+
+ # for write-vectors
+ comb += wvclr.wen.eq(ortreereduce_sig(wvclren)) # clear (regfile write)
+ comb += wvset.wen.eq(ortreereduce_sig(wvseten)) # set (issue time)
+ comb += wvset.i_data.eq(ortreereduce_sig(wvsets))
+
def connect_wrports(self, m, fu_bitdict):
"""connect write ports
mode = "read" if readmode else "write"
regs = self.regs
fus = self.fus.fus
- e = self.i.e # decoded instruction to execute
+ e = self.ireg.e # decoded instruction to execute
+
+ # dictionary of dictionaries of lists of regfile ports.
+ # first key: regfile. second key: regfile port name
+ byregfiles = defaultdict(dict)
+ byregfiles_spec = defaultdict(dict)
- # dictionary of lists of regfile ports
- byregfiles = {}
- byregfiles_spec = {}
for (funame, fu) in fus.items():
+ # create in each FU a receptacle for the read/write register
+ # hazard numbers. to be latched in connect_rd/write_ports
+ # XXX better that this is moved into the actual FUs, but
+ # the issue there is that this function is actually better
+ # suited at the moment
+ if readmode:
+ fu.rd_latches = {}
+ else:
+ fu.wr_latches = {}
+
print("%s ports for %s" % (mode, funame))
for idx in range(fu.n_src if readmode else fu.n_dst):
+ # construct regfile specs: read uses inspec, write outspec
if readmode:
(regfile, regname, wid) = fu.get_in_spec(idx)
else:
(regfile, regname, wid) = fu.get_out_spec(idx)
print(" %d %s %s %s" % (idx, regfile, regname, str(wid)))
+
+ # the PowerDecoder2 (main one, not the satellites) contains
+ # the decoded regfile numbers. obtain these now
if readmode:
rdflag, read = regspec_decode_read(e, regfile, regname)
- write = None
+ wrport, write = None, None
else:
rdflag, read = None, None
wrport, write = regspec_decode_write(e, regfile, regname)
- if regfile not in byregfiles:
- byregfiles[regfile] = {}
- byregfiles_spec[regfile] = {}
+
+ # construct the dictionary of regspec information by regfile
if regname not in byregfiles_spec[regfile]:
byregfiles_spec[regfile][regname] = \
- (rdflag, read, write, wid, [])
+ (rdflag, wrport, read, write, wid, [])
# here we start to create "lanes"
if idx not in byregfiles[regfile]:
byregfiles[regfile][idx] = []
fuspec = (funame, fu, idx)
byregfiles[regfile][idx].append(fuspec)
- byregfiles_spec[regfile][regname][4].append(fuspec)
+ byregfiles_spec[regfile][regname][5].append(fuspec)
+
+ continue
+ # append a latch Signal to the FU's list of latches
+ rname = "%s_%s" % (regfile, regname)
+ if readmode:
+ if rname not in fu.rd_latches:
+ rdl = Signal.like(read, name="rdlatch_"+rname)
+ fu.rd_latches[rname] = rdl
+ else:
+ if rname not in fu.wr_latches:
+ wrl = Signal.like(write, name="wrlatch_"+rname)
+ fu.wr_latches[rname] = wrl
- # ok just print that out, for convenience
+ # ok just print that all out, for convenience
for regfile, spec in byregfiles.items():
print("regfile %s ports:" % mode, regfile)
fuspecs = byregfiles_spec[regfile]
for regname, fspec in fuspecs.items():
- [rdflag, read, write, wid, fuspec] = fspec
+ [rdflag, wrflag, read, write, wid, fuspec] = fspec
print(" rf %s port %s lane: %s" % (mode, regfile, regname))
- print(" %s" % regname, wid, read, write, rdflag)
+ print(" %s" % regname, wid, read, write, rdflag, wrflag)
for (funame, fu, idx) in fuspec:
fusig = fu.src_i[idx] if readmode else fu.dest[idx]
- print(" ", funame, fu, idx, fusig)
+ print(" ", funame, fu.__class__.__name__, idx, fusig)
print()
return byregfiles, byregfiles_spec