-from nmigen.compat.sim import run_simulation
-from nmigen.cli import verilog, rtlil
-from nmigen import Module, Signal, Mux, Elaboratable, Repl, Array, Record
-from nmigen.hdl.rec import (DIR_FANIN, DIR_FANOUT)
+"""Computation Unit (aka "ALU Manager").
-from nmutil.latch import SRLatch, latchregister
-from nmutil.iocontrol import RecordObject
-
-from soc.decoder.power_decoder2 import Data
-from soc.decoder.power_enums import InternalOp
-
-
-""" Computation Unit (aka "ALU Manager").
-
- This module runs a "revolving door" set of three latches, based on
- * Issue
- * Go_Read
- * Go_Write
- where one of them cannot be set on any given cycle.
+Manages a Pipeline or FSM, ensuring that the start and end time are 100%
+monitored. At no time may the ALU proceed without this module notifying
+the Dependency Matrices. At no time is a result production "abandoned".
+This module blocks (indicates busy) starting from when it first receives
+an opcode until it receives notification that
+its result(s) have been successfully stored in the regfile(s)
- * When issue is first raised, a busy signal is sent out.
- The src1 and src2 registers and the operand can be latched in
- at this point
-
- * Read request is set, which is acknowledged through the Scoreboard
- to the priority picker, which generates (one and only one) Go_Read
- at a time. One of those will (eventually) be this Computation Unit.
-
- * Once Go_Read is set, the src1/src2/operand latch door shuts (locking
- src1/src2/operand in place), and the ALU is told to proceed.
-
- * when the ALU pipeline is ready, this activates "write request release",
- and the ALU's output is captured into a temporary register.
-
- * Write request release is *HELD UP* (prevented from proceeding) if shadowN
- is asserted LOW. This is how all speculation, precise exceptions,
- predication - everything - is achieved.
+Documented at http://libre-soc.org/3d_gpu/architecture/compunit
+"""
- * Write request release will go through a similar process as Read request,
- resulting (eventually) in Go_Write being asserted.
+from nmigen import Module, Signal, Mux, Elaboratable, Repl, Cat, Const
+from nmigen.hdl.rec import (Record, DIR_FANIN, DIR_FANOUT)
- * When Go_Write is asserted, two things happen: (1) the data in the temp
- register is placed combinatorially onto the output, and (2) the
- req_l latch is cleared, busy is dropped, and the Comp Unit is back
- through its revolving door to do another task.
+from nmutil.latch import SRLatch, latchregister
+from nmutil.iocontrol import RecordObject
+from nmutil.util import rising_edge
- Note that the read and write latches are held synchronously for one cycle,
- i.e. that when Go_Read comes in, one cycle is given in which the incoming
- register (broadcast over a Regfile Read Port) may have time to be latched.
+from soc.fu.regspec import RegSpec, RegSpecALUAPI
- It is REQUIRED that Go_Read be held valid only for one cycle, and it is
- REQUIRED that the corresponding Read_Req be dropped exactly one cycle after
- Go_Read is asserted HI.
- Likewise for Go_Write: this is asserted for one cycle, and Req_Writes must
- likewise be dropped exactly one cycle after assertion of Go_Write.
+def find_ok(fields):
+ """find_ok helper function - finds field ending in "_ok"
+ """
+ for field_name in fields:
+ if field_name.endswith("_ok"):
+ return field_name
+ return None
- When Go_Die is asserted then strictly speaking the entire FSM should be
- fully reset and that includes sending a cancellation request to the ALU.
- (XXX TODO: alu "go die" is not presently wired up)
-"""
def go_record(n, name):
- r = Record([('go', n, DIR_FANIN),
- ('rel', n, DIR_FANOUT)], name=name)
- r.go.reset_less = True
- r.rel.reset_less = True
+ r = Record([('go_i', n, DIR_FANIN),
+ ('rel_o', n, DIR_FANOUT)], name=name)
+ r.go_i.reset_less = True
+ r.rel_o.reset_less = True
return r
+
# see https://libre-soc.org/3d_gpu/architecture/regfile/ section on regspecs
-def get_regspec_bitwidth(regspec, srcdest, idx):
- bitspec = regspec[srcdest][idx]
- wid = 0
- print (bitspec)
- for ranges in bitspec[2].split(","):
- ranges = ranges.split(":")
- print (ranges)
- if len(ranges) == 1: # only one bit
- wid += 1
- else:
- start, end = map(int, ranges)
- wid += (end-start)+1
- return wid
-
-
-class CompUnitRecord(RecordObject):
+
+class CompUnitRecord(RegSpec, RecordObject):
"""CompUnitRecord
base class for Computation Units, to provide a uniform API
see https://libre-soc.org/3d_gpu/architecture/regfile/ section on regspecs
"""
+
def __init__(self, subkls, rwid, n_src=None, n_dst=None, name=None):
- RecordObject.__init__(self, name)
- self._rwid = rwid
- if isinstance(rwid, int):
- # rwid: integer (covers all registers)
- self._n_src, self._n_dst = n_src, n_dst
- else:
- # rwid: a regspec.
- self._n_src, self._n_dst = len(rwid[0]), len(rwid[1])
+ RegSpec.__init__(self, rwid, n_src, n_dst)
+ print ("name", name)
+ RecordObject.__init__(self)
self._subkls = subkls
+ n_src, n_dst = self._n_src, self._n_dst
+ # create source operands
src = []
for i in range(n_src):
- j = i + 1 # name numbering to match src1/src2
- name = "src%d_i" % j
+ j = i + 1 # name numbering to match src1/src2
+ sname = "src%d_i" % j
rw = self._get_srcwid(i)
- sreg = Signal(rw, name=name, reset_less=True)
- setattr(self, name, sreg)
+ sreg = Signal(rw, name=sname, reset_less=True)
+ setattr(self, sname, sreg)
src.append(sreg)
self._src_i = src
+ # create dest operands
dst = []
for i in range(n_dst):
- j = i + 1 # name numbering to match dest1/2...
- name = "dest%d_i" % j
+ j = i + 1 # name numbering to match dest1/2...
+ dname = "dest%d_o" % j
rw = self._get_dstwid(i)
- dreg = Signal(rw, name=name, reset_less=True)
- setattr(self, name, dreg)
+ # dreg = Data(rw, name=name) XXX ??? output needs to be a Data type?
+ dreg = Signal(rw, name=dname, reset_less=True)
+ setattr(self, dname, dreg)
dst.append(dreg)
self._dest = dst
- self.rd = go_record(n_src, name="rd") # read in, req out
- self.wr = go_record(n_dst, name="wr") # write in, req out
- self.issue_i = Signal(reset_less=True) # fn issue in
- self.shadown_i = Signal(reset=1) # shadow function, defaults to ON
- self.go_die_i = Signal() # go die (reset)
-
# operation / data input
- self.oper_i = subkls() # operand
+ self.oper_i = subkls(name="oper_i_%s" % name) # operand
+
+ # create read/write and other scoreboard signalling
+ self.rd = go_record(n_src, name="cu_rd") # read in, req out
+ self.wr = go_record(n_dst, name="cu_wr") # write in, req out
+ # read / write mask
+ self.rdmaskn = Signal(n_src, name="cu_rdmaskn_i", reset_less=True)
+ self.wrmask = Signal(n_dst, name="cu_wrmask_o", reset_less=True)
+
+ # fn issue in
+ self.issue_i = Signal(name="cu_issue_i", reset_less=True)
+ # shadow function, defaults to ON
+ self.shadown_i = Signal(name="cu_shadown_i", reset=1)
+ # go die (reset)
+ self.go_die_i = Signal(name="cu_go_die_i")
# output (busy/done)
- self.busy_o = Signal(reset_less=True) # fn busy out
- self.done_o = Signal(reset_less=True)
-
- def _get_dstwid(self, i):
- if isinstance(self._rwid, int):
- return self._rwid
- return get_regspec_bitwidth(self._rwid, 1, i)
-
- def _get_srcwid(self, i):
- if isinstance(self._rwid, int):
- return self._rwid
- return get_regspec_bitwidth(self._rwid, 0, i)
-
-
-class RegSpecALUAPI:
- def __init__(self, rwid, alu):
- """RegSpecAPI
-
- * :rwid: regspec
- * :alu: ALU covered by this regspec
- """
- self.rwid = rwid
- self.alu = alu # actual ALU - set as a "submodule" of the CU
-
- def get_out(self, i):
- if isinstance(self.rwid, int): # old - testing - API (rwid is int)
- return self.alu.out[i]
- # regspec-based API: look up variable through regspec according to row number
- return getattr(self.alu.n.data_o, self.rwid[1][i][1])
-
- def get_in(self, i):
- if isinstance(self.rwid, int): # old - testing - API (rwid is int)
- return self.alu.i[i]
- # regspec-based API: look up variable through regspec according to row number
- return getattr(self.alu.p.data_i, self.rwid[0][i][1])
-
- def get_op(self):
- if isinstance(self.rwid, int): # old - testing - API (rwid is int)
- return self.alu.op
- return self.alu.p.data_i.ctx.op
+ self.busy_o = Signal(name="cu_busy_o", reset_less=True) # fn busy out
+ self.done_o = Signal(name="cu_done_o", reset_less=True)
class MultiCompUnit(RegSpecALUAPI, Elaboratable):
- def __init__(self, rwid, alu, opsubsetkls, n_src=2, n_dst=1):
+ def __init__(self, rwid, alu, opsubsetkls, n_src=2, n_dst=1, name=None):
"""MultiCompUnit
* :rwid: width of register latches (TODO: allocate per regspec)
- * :alu: the ALU (pipeline, FSM) - must conform to nmutil Pipe API
- * :opsubsetkls: the subset of Decode2ExecuteType
+ * :alu: ALU (pipeline, FSM) - must conform to nmutil Pipe API
+ * :opsubsetkls: subset of Decode2ExecuteType
* :n_src: number of src operands
* :n_dst: number of destination operands
"""
RegSpecALUAPI.__init__(self, rwid, alu)
- self.n_src, self.n_dst = n_src, n_dst
+ self.alu_name = name or "alu"
self.opsubsetkls = opsubsetkls
- self.cu = cu = CompUnitRecord(opsubsetkls, rwid, n_src, n_dst)
+ self.cu = cu = CompUnitRecord(opsubsetkls, rwid, n_src, n_dst,
+ name=name)
+ n_src, n_dst = self.n_src, self.n_dst = cu._n_src, cu._n_dst
+ print("n_src %d n_dst %d" % (self.n_src, self.n_dst))
+ # convenience names for src operands
for i in range(n_src):
- j = i + 1 # name numbering to match src1/src2
+ j = i + 1 # name numbering to match src1/src2
name = "src%d_i" % j
setattr(self, name, getattr(cu, name))
+ # convenience names for dest operands
for i in range(n_dst):
- j = i + 1 # name numbering to match dest1/2...
- name = "dest%d_i" % j
+ j = i + 1 # name numbering to match dest1/2...
+ name = "dest%d_o" % j
setattr(self, name, getattr(cu, name))
- # convenience names
+ # more convenience names
self.rd = cu.rd
self.wr = cu.wr
- self.go_rd_i = self.rd.go # temporary naming
- self.go_wr_i = self.wr.go # temporary naming
- self.rd_rel_o = self.rd.rel # temporary naming
- self.req_rel_o = self.wr.rel # temporary naming
+ self.rdmaskn = cu.rdmaskn
+ self.wrmask = cu.wrmask
+ self.go_rd_i = self.rd.go_i # temporary naming
+ self.go_wr_i = self.wr.go_i # temporary naming
+ self.rd_rel_o = self.rd.rel_o # temporary naming
+ self.req_rel_o = self.wr.rel_o # temporary naming
self.issue_i = cu.issue_i
self.shadown_i = cu.shadown_i
self.go_die_i = cu.go_die_i
self.busy_o = cu.busy_o
self.dest = cu._dest
- self.data_o = self.dest[0] # Dest out
+ self.data_o = self.dest[0] # Dest out
self.done_o = cu.done_o
+ def _mux_op(self, m, sl, op_is_imm, imm, i):
+ # select imm if opcode says so. however also change the latch
+ # to trigger *from* the opcode latch instead.
+ src_or_imm = Signal(self.cu._get_srcwid(i), reset_less=True)
+ src_sel = Signal(reset_less=True)
+ m.d.comb += src_sel.eq(Mux(op_is_imm, self.opc_l.q, sl[i][2]))
+ m.d.comb += src_or_imm.eq(Mux(op_is_imm, imm, self.src_i[i]))
+ # overwrite 1st src-latch with immediate-muxed stuff
+ sl[i][0] = src_or_imm
+ sl[i][2] = src_sel
+ sl[i][3] = ~op_is_imm # change rd.rel[i] gate condition
+
def elaborate(self, platform):
m = Module()
- m.submodules.alu = self.alu
+ setattr(m.submodules, self.alu_name, self.alu)
m.submodules.src_l = src_l = SRLatch(False, self.n_src, name="src")
m.submodules.opc_l = opc_l = SRLatch(sync=False, name="opc")
m.submodules.req_l = req_l = SRLatch(False, self.n_dst, name="req")
m.submodules.rst_l = rst_l = SRLatch(sync=False, name="rst")
m.submodules.rok_l = rok_l = SRLatch(sync=False, name="rdok")
+ self.opc_l, self.src_l = opc_l, src_l
# ALU only proceeds when all src are ready. rd_rel_o is delayed
# so combine it with go_rd_i. if all bits are set we're good
all_rd = Signal(reset_less=True)
m.d.comb += all_rd.eq(self.busy_o & rok_l.q &
- (((~self.rd.rel) | self.rd.go).all()))
+ (((~self.rd.rel_o) | self.rd.go_i).all()))
+
+ # generate read-done pulse
+ all_rd_pulse = Signal(reset_less=True)
+ m.d.comb += all_rd_pulse.eq(rising_edge(m, all_rd))
+
+ # create rising pulse from alu valid condition.
+ alu_done = Signal(reset_less=True)
+ alu_pulse = Signal(reset_less=True)
+ alu_pulsem = Signal(self.n_dst, reset_less=True)
+ m.d.comb += alu_done.eq(self.alu.n.valid_o)
+ m.d.comb += alu_pulse.eq(rising_edge(m, alu_done))
+ m.d.comb += alu_pulsem.eq(Repl(alu_pulse, self.n_dst))
+
+ # sigh bug where req_l gets both set and reset raised at same time
+ prev_wr_go = Signal(self.n_dst)
+ brd = Repl(self.busy_o, self.n_dst)
+ m.d.sync += prev_wr_go.eq(self.wr.go_i & brd)
# write_requests all done
# req_done works because any one of the last of the writes
# is enough, when combined with when read-phase is done (rst_l.q)
wr_any = Signal(reset_less=True)
req_done = Signal(reset_less=True)
- m.d.comb += self.done_o.eq(self.busy_o & ~(self.wr.rel.bool()))
- m.d.comb += wr_any.eq(self.wr.go.bool())
- m.d.comb += req_done.eq(rst_l.q & wr_any)
+ m.d.comb += self.done_o.eq(self.busy_o &
+ ~((self.wr.rel_o & ~self.wrmask).bool()))
+ m.d.comb += wr_any.eq(self.wr.go_i.bool() | prev_wr_go.bool())
+ m.d.comb += req_done.eq(wr_any & ~self.alu.n.ready_i &
+ ((req_l.q & self.wrmask) == 0))
+ # argh, complicated hack: if there are no regs to write,
+ # instead of waiting for regs that are never going to happen,
+ # we indicate "done" when the ALU is "done"
+ with m.If((self.wrmask == 0) &
+ self.alu.n.ready_i & self.alu.n.valid_o & self.busy_o):
+ m.d.comb += req_done.eq(1)
# shadow/go_die
reset = Signal(reset_less=True)
- rst_r = Signal(reset_less=True) # reset latch off
+ rst_r = Signal(reset_less=True) # reset latch off
reset_w = Signal(self.n_dst, reset_less=True)
reset_r = Signal(self.n_src, reset_less=True)
m.d.comb += reset.eq(req_done | self.go_die_i)
m.d.comb += rst_r.eq(self.issue_i | self.go_die_i)
- m.d.comb += reset_w.eq(self.wr.go | Repl(self.go_die_i, self.n_dst))
- m.d.comb += reset_r.eq(self.rd.go | Repl(self.go_die_i, self.n_src))
+ m.d.comb += reset_w.eq(self.wr.go_i | Repl(self.go_die_i, self.n_dst))
+ m.d.comb += reset_r.eq(self.rd.go_i | Repl(self.go_die_i, self.n_src))
# read-done,wr-proceed latch
- m.d.comb += rok_l.s.eq(self.issue_i) # set up when issue starts
- m.d.comb += rok_l.r.eq(self.alu.p.ready_o) # off when ALU acknowledges
+ m.d.sync += rok_l.s.eq(self.issue_i) # set up when issue starts
+ m.d.sync += rok_l.r.eq(self.alu.n.valid_o & self.busy_o) # ALU done
# wr-done, back-to-start latch
- m.d.comb += rst_l.s.eq(all_rd) # set when read-phase is fully done
- m.d.comb += rst_l.r.eq(rst_r) # *off* on issue
+ m.d.sync += rst_l.s.eq(all_rd) # set when read-phase is fully done
+ m.d.sync += rst_l.r.eq(rst_r) # *off* on issue
# opcode latch (not using go_rd_i) - inverted so that busy resets to 0
m.d.sync += opc_l.s.eq(self.issue_i) # set on issue
- m.d.sync += opc_l.r.eq(self.alu.n.valid_o & req_done) # reset on ALU
+ m.d.sync += opc_l.r.eq(req_done) # reset on ALU
# src operand latch (not using go_wr_i)
m.d.sync += src_l.s.eq(Repl(self.issue_i, self.n_src))
m.d.sync += src_l.r.eq(reset_r)
# dest operand latch (not using issue_i)
- m.d.sync += req_l.s.eq(Repl(all_rd, self.n_dst))
- m.d.sync += req_l.r.eq(reset_w)
+ m.d.sync += req_l.s.eq(alu_pulsem & self.wrmask)
+ m.d.sync += req_l.r.eq(reset_w | prev_wr_go)
- # create a latch/register for the operand
- oper_r = self.opsubsetkls()
- latchregister(m, self.oper_i, oper_r, self.issue_i, "oper_r")
+ # pass operation to the ALU (sync: plenty time to wait for src reads)
+ op = self.get_op()
+ with m.If(self.issue_i):
+ m.d.sync += op.eq(self.oper_i)
- # and for each output from the ALU
+ # and for each output from the ALU: capture when ALU output is valid
drl = []
+ wrok = []
for i in range(self.n_dst):
name = "data_r%d" % i
- data_r = Signal(self.cu._get_srcwid(i), name=name, reset_less=True)
- latchregister(m, self.get_out(i), data_r, req_l.q[i], name)
+ lro = self.get_out(i)
+ ok = Const(1, 1)
+ if isinstance(lro, Record):
+ data_r = Record.like(lro, name=name)
+ print("wr fields", i, lro, data_r.fields)
+ # bye-bye abstract interface design..
+ fname = find_ok(data_r.fields)
+ if fname:
+ ok = getattr(lro, fname)
+ else:
+ data_r = Signal.like(lro, name=name, reset_less=True)
+ wrok.append(ok & self.busy_o)
+ with m.If(alu_pulse):
+ m.d.sync += data_r.eq(lro)
+ with m.If(self.issue_i):
+ m.d.sync += data_r.eq(0)
drl.append(data_r)
- # pass the operation to the ALU
- m.d.comb += self.get_op().eq(oper_r)
+ # ok, above we collated anything with an "ok" on the output side
+ # now actually use those to create a write-mask. this basically
+ # is now the Function Unit API tells the Comp Unit "do not request
+ # a regfile port because this particular output is not valid"
+ m.d.comb += self.wrmask.eq(Cat(*wrok))
# create list of src/alu-src/src-latch. override 1st and 2nd one below.
- # in the case, for ALU and Logical pipelines, we assume RB is the 2nd operand
- # in the input "regspec". see for example soc.fu.alu.pipe_data.ALUInputData
- # TODO: assume RA is the 1st operand, zero_a detection is needed.
+ # in the case, for ALU and Logical pipelines, we assume RB is the
+ # 2nd operand in the input "regspec". see for example
+ # soc.fu.alu.pipe_data.ALUInputData
sl = []
+ print("src_i", self.src_i)
for i in range(self.n_src):
- sl.append([self.src_i[i], self.get_in(i), src_l.q[i]])
+ sl.append([self.src_i[i], self.get_in(i), src_l.q[i], Const(1, 1)])
# if the operand subset has "zero_a" we implicitly assume that means
- # src_i[0] is an INT register type where zero can be multiplexed in, instead.
+ # src_i[0] is an INT reg type where zero can be multiplexed in, instead.
# see https://bugs.libre-soc.org/show_bug.cgi?id=336
- #if hasattr(oper_r, "zero_a"):
- # select zero immediate if opcode says so. however also change the latch
+ if hasattr(op, "zero_a"):
+ # select zero imm if opcode says so. however also change the latch
# to trigger *from* the opcode latch instead.
- # ...
- # ...
+ self._mux_op(m, sl, op.zero_a, 0, 0)
# if the operand subset has "imm_data" we implicitly assume that means
- # "this is an INT ALU/Logical FU jobbie, RB is multiplexed with the immediate"
- if hasattr(oper_r, "imm_data"):
- # select immediate if opcode says so. however also change the latch
+ # "this is an INT ALU/Logical FU jobbie, RB is muxed with the immediate"
+ if hasattr(op, "imm_data"):
+ # select immediate if opcode says so. however also change the latch
# to trigger *from* the opcode latch instead.
- op_is_imm = oper_r.imm_data.imm_ok
- src2_or_imm = Signal(self.cu._get_srcwid(1), reset_less=True)
- src_sel = Signal(reset_less=True)
- m.d.comb += src_sel.eq(Mux(op_is_imm, opc_l.q, src_l.q[1]))
- m.d.comb += src2_or_imm.eq(Mux(op_is_imm, oper_r.imm_data.imm,
- self.src2_i))
- # overwrite 2nd src-latch with immediate-muxed stuff
- sl[1][0] = src2_or_imm
- sl[1][2] = src_sel
-
- # create a latch/register for src1/src2 (even if it is a copy of an immediate)
+ op_is_imm = op.imm_data.ok
+ imm = op.imm_data.data
+ self._mux_op(m, sl, op_is_imm, imm, 1)
+
+ # create a latch/register for src1/src2 (even if it is a copy of imm)
for i in range(self.n_src):
- src, alusrc, latch = sl[i]
+ src, alusrc, latch, _ = sl[i]
latchregister(m, src, alusrc, latch, name="src_r%d" % i)
+ # -----
+ # ALU connection / interaction
+ # -----
+
+ # on a go_read, tell the ALU we're accepting data.
+ m.submodules.alui_l = alui_l = SRLatch(False, name="alui")
+ m.d.comb += self.alu.p.valid_i.eq(alui_l.q)
+ m.d.sync += alui_l.r.eq(self.alu.p.ready_o & alui_l.q)
+ m.d.comb += alui_l.s.eq(all_rd_pulse)
+
+ # ALU output "ready" side. alu "ready" indication stays hi until
+ # ALU says "valid".
+ m.submodules.alu_l = alu_l = SRLatch(False, name="alu")
+ m.d.comb += self.alu.n.ready_i.eq(alu_l.q)
+ m.d.sync += alu_l.r.eq(self.alu.n.valid_o & alu_l.q)
+ m.d.comb += alu_l.s.eq(all_rd_pulse)
+
# -----
# outputs
# -----
+ slg = Cat(*map(lambda x: x[3], sl)) # get req gate conditions
# all request signals gated by busy_o. prevents picker problems
- m.d.comb += self.busy_o.eq(opc_l.q) # busy out
- bro = Repl(self.busy_o, self.n_src)
- m.d.comb += self.rd.rel.eq(src_l.q & bro) # src1/src2 req rel
+ m.d.comb += self.busy_o.eq(opc_l.q) # busy out
- # on a go_read, tell the ALU we're accepting data.
- # NOTE: this spells TROUBLE if the ALU isn't ready!
- # go_read is only valid for one clock!
- with m.If(all_rd): # src operands ready, GO!
- with m.If(~self.alu.p.ready_o): # no ACK yet
- m.d.comb += self.alu.p.valid_i.eq(1) # so indicate valid
+ # read-release gated by busy (and read-mask)
+ bro = Repl(self.busy_o, self.n_src)
+ m.d.comb += self.rd.rel_o.eq(src_l.q & bro & slg & ~self.rdmaskn)
+ # write-release gated by busy and by shadow (and write-mask)
brd = Repl(self.busy_o & self.shadown_i, self.n_dst)
- # only proceed if ALU says its output is valid
- with m.If(self.alu.n.valid_o):
- # when ALU ready, write req release out. waits for shadow
- m.d.comb += self.wr.rel.eq(req_l.q & brd)
- # when output latch is ready, and ALU says ready, accept ALU output
- with m.If(reset):
- m.d.comb += self.alu.n.ready_i.eq(1) # tells ALU "thanks got it"
+ m.d.comb += self.wr.rel_o.eq(req_l.q & brd & self.wrmask)
# output the data from the latch on go_write
for i in range(self.n_dst):
- with m.If(self.wr.go[i]):
+ with m.If(self.wr.go_i[i] & self.busy_o):
m.d.comb += self.dest[i].eq(drl[i])
return m
+ def get_fu_out(self, i):
+ return self.dest[i]
+
def __iter__(self):
- yield self.rd.go
- yield self.wr.go
+ yield self.rd.go_i
+ yield self.wr.go_i
yield self.issue_i
yield self.shadown_i
yield self.go_die_i
yield self.src1_i
yield self.src2_i
yield self.busy_o
- yield self.rd.rel
- yield self.wr.rel
+ yield self.rd.rel_o
+ yield self.wr.rel_o
yield self.data_o
def ports(self):
return list(self)
-
-
-def op_sim(dut, a, b, op, inv_a=0, imm=0, imm_ok=0):
- yield dut.issue_i.eq(0)
- yield
- yield dut.src_i[0].eq(a)
- yield dut.src_i[1].eq(b)
- yield dut.oper_i.insn_type.eq(op)
- yield dut.oper_i.invert_a.eq(inv_a)
- yield dut.oper_i.imm_data.imm.eq(imm)
- yield dut.oper_i.imm_data.imm_ok.eq(imm_ok)
- yield dut.issue_i.eq(1)
- yield
- yield dut.issue_i.eq(0)
- yield
- yield dut.rd.go.eq(0b11)
- while True:
- yield
- rd_rel_o = yield dut.rd.rel
- print ("rd_rel", rd_rel_o)
- if rd_rel_o:
- break
- yield
- yield dut.rd.go.eq(0)
- req_rel_o = yield dut.wr.rel
- result = yield dut.data_o
- print ("req_rel", req_rel_o, result)
- while True:
- req_rel_o = yield dut.wr.rel
- result = yield dut.data_o
- print ("req_rel", req_rel_o, result)
- if req_rel_o:
- break
- yield
- yield dut.wr.go[0].eq(1)
- yield
- result = yield dut.data_o
- print ("result", result)
- yield dut.wr.go[0].eq(0)
- yield
- return result
-
-
-def scoreboard_sim(dut):
- result = yield from op_sim(dut, 5, 2, InternalOp.OP_ADD, inv_a=0,
- imm=8, imm_ok=1)
- assert result == 13
-
- result = yield from op_sim(dut, 5, 2, InternalOp.OP_ADD)
- assert result == 7
-
- result = yield from op_sim(dut, 5, 2, InternalOp.OP_ADD, inv_a=1)
- assert result == 65532
-
-
-def test_compunit():
- from alu_hier import ALU
- from soc.fu.alu.alu_input_record import CompALUOpSubset
-
- m = Module()
- alu = ALU(16)
- dut = MultiCompUnit(16, alu, CompALUOpSubset)
- m.submodules.cu = dut
-
- vl = rtlil.convert(dut, ports=dut.ports())
- with open("test_compunit1.il", "w") as f:
- f.write(vl)
-
- run_simulation(m, scoreboard_sim(dut), vcd_name='test_compunit1.vcd')
-
-
-def test_compunit_regspec1():
- from alu_hier import ALU
- from soc.fu.alu.alu_input_record import CompALUOpSubset
-
- inspec = [('INT', 'a', '0:15'),
- ('INT', 'b', '0:15')]
- outspec = [('INT', 'o', '0:15'),
- ]
-
- regspec = (inspec, outspec)
-
- m = Module()
- alu = ALU(16)
- dut = MultiCompUnit(regspec, alu, CompALUOpSubset)
- m.submodules.cu = dut
-
- vl = rtlil.convert(dut, ports=dut.ports())
- with open("test_compunit_regspec1.il", "w") as f:
- f.write(vl)
-
- run_simulation(m, scoreboard_sim(dut), vcd_name='test_compunit1.vcd')
-
-
-if __name__ == '__main__':
- test_compunit()
- test_compunit_regspec1()