from nmigen import Module, Const, Signal, Array, Cat, Elaboratable
from regfile.regfile import RegFileArray, treereduce
-from scoreboard.fn_unit import IntFnUnit, FPFnUnit, LDFnUnit, STFnUnit
from scoreboard.fu_fu_matrix import FUFUDepMatrix
from scoreboard.fu_reg_matrix import FURegDepMatrix
from scoreboard.global_pending import GlobalPending
from scoreboard.group_picker import GroupPicker
-from scoreboard.issue_unit import IntFPIssueUnit, RegDecode
+from scoreboard.issue_unit import IssueUnitGroup, IssueUnitArray, RegDecode
+from scoreboard.shadow import ShadowMatrix, BranchSpeculationRecord
+from scoreboard.instruction_q import Instruction, InstructionQ
from compalu import ComputationUnitNoDelay
-from alu_hier import ALU
+from alu_hier import ALU, BranchALU
from nmutil.latch import SRLatch
+from nmutil.nmoperator import eq
-from random import randint
+from random import randint, seed
+from copy import deepcopy
+from math import log
-class CompUnits(Elaboratable):
- def __init__(self, rwid, n_units):
+class Memory(Elaboratable):
+ def __init__(self, regwid, addrw):
+ self.ddepth = regwid/8
+ depth = (1<<addrw) / self.ddepth
+ self.adr = Signal(addrw)
+ self.dat_r = Signal(regwid)
+ self.dat_w = Signal(regwid)
+ self.we = Signal()
+ self.mem = Memory(width=regwid, depth=depth, init=range(0, depth))
+
+ def elaborate(self, platform):
+ m = Module()
+ m.submodules.rdport = rdport = self.mem.read_port()
+ m.submodules.wrport = wrport = self.mem.write_port()
+ m.d.comb += [
+ rdport.addr.eq(self.adr[self.ddepth:]), # ignore low bits
+ self.dat_r.eq(rdport.data),
+ wrport.addr.eq(self.adr),
+ wrport.data.eq(self.dat_w),
+ wrport.en.eq(self.we),
+ ]
+ return m
+
+
+class MemSim:
+ def __init__(self, regwid, addrw):
+ self.regwid = regwid
+ self.ddepth = regwid//8
+ depth = (1<<addrw) // self.ddepth
+ self.mem = list(range(0, depth))
+
+ def ld(self, addr):
+ return self.mem[addr>>self.ddepth]
+
+ def st(self, addr, data):
+ self.mem[addr>>self.ddepth] = data & ((1<<self.regwid)-1)
+
+
+class CompUnitsBase(Elaboratable):
+ """ Computation Unit Base class.
+
+ Amazingly, this class works recursively. It's supposed to just
+ look after some ALUs (that can handle the same operations),
+ grouping them together, however it turns out that the same code
+ can also group *groups* of Computation Units together as well.
+
+ Basically it was intended just to concatenate the ALU's issue,
+ go_rd etc. signals together, which start out as bits and become
+ sequences. Turns out that the same trick works just as well
+ on Computation Units!
+
+ So this class may be used recursively to present a top-level
+ sequential concatenation of all the signals in and out of
+ ALUs, whilst at the same time making it convenient to group
+ ALUs together.
+
+ At the lower level, the intent is that groups of (identical)
+ ALUs may be passed the same operation. Even beyond that,
+ the intent is that that group of (identical) ALUs actually
+ share the *same pipeline* and as such become a "Concurrent
+ Computation Unit" as defined by Mitch Alsup (see section
+ 11.4.9.3)
+ """
+ def __init__(self, rwid, units):
""" Inputs:
* :rwid: bit width of register file(s) - both FP and INT
- * :n_units: number of ALUs
+ * :units: sequence of ALUs (or CompUnitsBase derivatives)
"""
- self.n_units = n_units
+ self.units = units
self.rwid = rwid
+ self.rwid = rwid
+ if units and isinstance(units[0], CompUnitsBase):
+ self.n_units = 0
+ for u in self.units:
+ self.n_units += u.n_units
+ else:
+ self.n_units = len(units)
+
+ n_units = self.n_units
+ # inputs
self.issue_i = Signal(n_units, reset_less=True)
self.go_rd_i = Signal(n_units, reset_less=True)
self.go_wr_i = Signal(n_units, reset_less=True)
+ self.shadown_i = Signal(n_units, reset_less=True)
+ self.go_die_i = Signal(n_units, reset_less=True)
+
+ # outputs
self.busy_o = Signal(n_units, reset_less=True)
+ self.rd_rel_o = Signal(n_units, reset_less=True)
self.req_rel_o = Signal(n_units, reset_less=True)
- self.dest_o = Signal(rwid, reset_less=True)
- self.src1_data_i = Signal(rwid, reset_less=True)
- self.src2_data_i = Signal(rwid, reset_less=True)
+ # in/out register data (note: not register#, actual data)
+ self.data_o = Signal(rwid, reset_less=True)
+ self.src1_i = Signal(rwid, reset_less=True)
+ self.src2_i = Signal(rwid, reset_less=True)
+ # input operand
def elaborate(self, platform):
m = Module()
+ comb = m.d.comb
- # Int ALUs
- add = ALU(self.rwid)
- sub = ALU(self.rwid)
- m.submodules.comp1 = comp1 = ComputationUnitNoDelay(self.rwid, 1, add)
- m.submodules.comp2 = comp2 = ComputationUnitNoDelay(self.rwid, 1, sub)
- int_alus = [comp1, comp2]
-
- m.d.comb += comp1.oper_i.eq(Const(0)) # temporary/experiment: op=add
- m.d.comb += comp2.oper_i.eq(Const(1)) # temporary/experiment: op=sub
+ for i, alu in enumerate(self.units):
+ setattr(m.submodules, "comp%d" % i, alu)
go_rd_l = []
go_wr_l = []
issue_l = []
busy_l = []
req_rel_l = []
- for alu in int_alus:
+ rd_rel_l = []
+ shadow_l = []
+ godie_l = []
+ for alu in self.units:
req_rel_l.append(alu.req_rel_o)
+ rd_rel_l.append(alu.rd_rel_o)
+ shadow_l.append(alu.shadown_i)
+ godie_l.append(alu.go_die_i)
go_wr_l.append(alu.go_wr_i)
go_rd_l.append(alu.go_rd_i)
issue_l.append(alu.issue_i)
busy_l.append(alu.busy_o)
- m.d.comb += self.req_rel_o.eq(Cat(*req_rel_l))
- m.d.comb += self.busy_o.eq(Cat(*busy_l))
- m.d.comb += Cat(*go_wr_l).eq(self.go_wr_i)
- m.d.comb += Cat(*go_rd_l).eq(self.go_rd_i)
- m.d.comb += Cat(*issue_l).eq(self.issue_i)
+ comb += self.rd_rel_o.eq(Cat(*rd_rel_l))
+ comb += self.req_rel_o.eq(Cat(*req_rel_l))
+ comb += self.busy_o.eq(Cat(*busy_l))
+ comb += Cat(*godie_l).eq(self.go_die_i)
+ comb += Cat(*shadow_l).eq(self.shadown_i)
+ comb += Cat(*go_wr_l).eq(self.go_wr_i)
+ comb += Cat(*go_rd_l).eq(self.go_rd_i)
+ comb += Cat(*issue_l).eq(self.issue_i)
# connect data register input/output
# merge (OR) all integer FU / ALU outputs to a single value
- # bit of a hack: treereduce needs a list with an item named "dest_o"
- dest_o = treereduce(int_alus)
- m.d.comb += self.dest_o.eq(dest_o)
+ # bit of a hack: treereduce needs a list with an item named "data_o"
+ if self.units:
+ data_o = treereduce(self.units)
+ comb += self.data_o.eq(data_o)
- for i, alu in enumerate(int_alus):
- m.d.comb += alu.src1_i.eq(self.src1_data_i)
- m.d.comb += alu.src2_i.eq(self.src2_data_i)
+ for i, alu in enumerate(self.units):
+ comb += alu.src1_i.eq(self.src1_i)
+ comb += alu.src2_i.eq(self.src2_i)
+
+ return m
+
+
+class CompUnitALUs(CompUnitsBase):
+
+ def __init__(self, rwid, opwid):
+ """ Inputs:
+
+ * :rwid: bit width of register file(s) - both FP and INT
+ * :opwid: operand bit width
+ """
+ self.opwid = opwid
+
+ # inputs
+ self.oper_i = Signal(opwid, reset_less=True)
+ self.imm_i = Signal(rwid, reset_less=True)
+
+ # Int ALUs
+ add = ALU(rwid)
+ sub = ALU(rwid)
+ mul = ALU(rwid)
+ shf = ALU(rwid)
+
+ units = []
+ for alu in [add, sub, mul, shf]:
+ aluopwid = 3 # extra bit for immediate mode
+ units.append(ComputationUnitNoDelay(rwid, aluopwid, alu))
+
+ CompUnitsBase.__init__(self, rwid, units)
+
+ def elaborate(self, platform):
+ m = CompUnitsBase.elaborate(self, platform)
+ comb = m.d.comb
+
+ # hand the same operation to all units, only lower 2 bits though
+ for alu in self.units:
+ comb += alu.oper_i[0:3].eq(self.oper_i)
+ comb += alu.imm_i.eq(self.imm_i)
+
+ return m
+
+
+class CompUnitBR(CompUnitsBase):
+
+ def __init__(self, rwid, opwid):
+ """ Inputs:
+
+ * :rwid: bit width of register file(s) - both FP and INT
+ * :opwid: operand bit width
+
+ Note: bgt unit is returned so that a shadow unit can be created
+ for it
+ """
+ self.opwid = opwid
+
+ # inputs
+ self.oper_i = Signal(opwid, reset_less=True)
+ self.imm_i = Signal(rwid, reset_less=True)
+
+ # Branch ALU and CU
+ self.bgt = BranchALU(rwid)
+ aluopwid = 3 # extra bit for immediate mode
+ self.br1 = ComputationUnitNoDelay(rwid, aluopwid, self.bgt)
+ CompUnitsBase.__init__(self, rwid, [self.br1])
+
+ def elaborate(self, platform):
+ m = CompUnitsBase.elaborate(self, platform)
+ comb = m.d.comb
+
+ # hand the same operation to all units
+ for alu in self.units:
+ comb += alu.oper_i.eq(self.oper_i)
+ comb += alu.imm_i.eq(self.imm_i)
return m
self.src1_i = Signal(n_regs, reset_less=True) # oper1 R# in
self.src2_i = Signal(n_regs, reset_less=True) # oper2 R# in
+ self.g_int_rd_pend_o = Signal(n_regs, reset_less=True)
+ self.g_int_wr_pend_o = Signal(n_regs, reset_less=True)
+
self.dest_rsel_o = Signal(n_regs, reset_less=True) # dest reg (bot)
self.src1_rsel_o = Signal(n_regs, reset_less=True) # src1 reg (bot)
self.src2_rsel_o = Signal(n_regs, reset_less=True) # src2 reg (bot)
- self.req_rel_i = Signal(n_int_alus, reset_less = True)
- self.g_int_rd_pend_o = Signal(n_regs, reset_less=True)
- self.g_int_wr_pend_o = Signal(n_regs, reset_less=True)
self.readable_o = Signal(n_int_alus, reset_less=True)
self.writable_o = Signal(n_int_alus, reset_less=True)
self.go_rd_i = Signal(n_int_alus, reset_less=True)
self.go_wr_i = Signal(n_int_alus, reset_less=True)
- self.req_rel_o = Signal(n_int_alus, reset_less=True)
+ self.go_die_i = Signal(n_int_alus, reset_less=True)
self.fn_issue_i = Signal(n_int_alus, reset_less=True)
+ # Note: FURegs wr_pend_o is also outputted from here, for use in WaWGrid
+
def elaborate(self, platform):
m = Module()
+ comb = m.d.comb
+ sync = m.d.sync
- n_int_fus = self.n_int_alus
+ n_intfus = self.n_int_alus
# Integer FU-FU Dep Matrix
- intfudeps = FUFUDepMatrix(n_int_fus, n_int_fus)
+ intfudeps = FUFUDepMatrix(n_intfus, n_intfus)
m.submodules.intfudeps = intfudeps
# Integer FU-Reg Dep Matrix
- intregdeps = FURegDepMatrix(n_int_fus, self.n_regs)
+ intregdeps = FURegDepMatrix(n_intfus, self.n_regs, 2)
m.submodules.intregdeps = intregdeps
- m.d.comb += self.g_int_rd_pend_o.eq(intregdeps.rd_pend_o)
- m.d.comb += self.g_int_wr_pend_o.eq(intregdeps.wr_pend_o)
+ comb += self.g_int_rd_pend_o.eq(intregdeps.v_rd_rsel_o)
+ comb += self.g_int_wr_pend_o.eq(intregdeps.v_wr_rsel_o)
+
+ comb += intregdeps.rd_pend_i.eq(intregdeps.v_rd_rsel_o)
+ comb += intregdeps.wr_pend_i.eq(intregdeps.v_wr_rsel_o)
- m.d.comb += intfudeps.rd_pend_i.eq(self.g_int_rd_pend_o)
- m.d.comb += intfudeps.wr_pend_i.eq(self.g_int_wr_pend_o)
+ comb += intfudeps.rd_pend_i.eq(intregdeps.rd_pend_o)
+ comb += intfudeps.wr_pend_i.eq(intregdeps.wr_pend_o)
+ self.wr_pend_o = intregdeps.wr_pend_o # also output for use in WaWGrid
- m.d.sync += intfudeps.issue_i.eq(self.fn_issue_i)
- m.d.sync += intfudeps.go_rd_i.eq(self.go_rd_i)
- m.d.sync += intfudeps.go_wr_i.eq(self.go_wr_i)
- m.d.comb += self.readable_o.eq(intfudeps.readable_o)
- m.d.comb += self.writable_o.eq(intfudeps.writable_o)
+ comb += intfudeps.issue_i.eq(self.fn_issue_i)
+ comb += intfudeps.go_rd_i.eq(self.go_rd_i)
+ comb += intfudeps.go_wr_i.eq(self.go_wr_i)
+ comb += intfudeps.go_die_i.eq(self.go_die_i)
+ comb += self.readable_o.eq(intfudeps.readable_o)
+ comb += self.writable_o.eq(intfudeps.writable_o)
# Connect function issue / arrays, and dest/src1/src2
- m.d.comb += intregdeps.dest_i.eq(self.dest_i)
- m.d.comb += intregdeps.src1_i.eq(self.src1_i)
- m.d.comb += intregdeps.src2_i.eq(self.src2_i)
+ comb += intregdeps.dest_i.eq(self.dest_i)
+ comb += intregdeps.src_i[0].eq(self.src1_i)
+ comb += intregdeps.src_i[1].eq(self.src2_i)
- m.d.comb += intregdeps.go_rd_i.eq(self.go_rd_i)
- m.d.comb += intregdeps.go_wr_i.eq(self.go_wr_i)
- m.d.comb += intregdeps.issue_i.eq(self.fn_issue_i)
+ comb += intregdeps.go_rd_i.eq(self.go_rd_i)
+ comb += intregdeps.go_wr_i.eq(self.go_wr_i)
+ comb += intregdeps.go_die_i.eq(self.go_die_i)
+ comb += intregdeps.issue_i.eq(self.fn_issue_i)
- m.d.comb += self.dest_rsel_o.eq(intregdeps.dest_rsel_o)
- m.d.comb += self.src1_rsel_o.eq(intregdeps.src1_rsel_o)
- m.d.comb += self.src2_rsel_o.eq(intregdeps.src2_rsel_o)
+ comb += self.dest_rsel_o.eq(intregdeps.dest_rsel_o)
+ comb += self.src1_rsel_o.eq(intregdeps.src_rsel_o[0])
+ comb += self.src2_rsel_o.eq(intregdeps.src_rsel_o[1])
return m
self.intregs = RegFileArray(rwid, n_regs)
self.fpregs = RegFileArray(rwid, n_regs)
+ # issue q needs to get at these
+ self.aluissue = IssueUnitGroup(4)
+ self.brissue = IssueUnitGroup(1)
+ # and these
+ self.alu_oper_i = Signal(4, reset_less=True)
+ self.alu_imm_i = Signal(rwid, reset_less=True)
+ self.br_oper_i = Signal(4, reset_less=True)
+ self.br_imm_i = Signal(rwid, reset_less=True)
+
# inputs
- self.int_store_i = Signal(reset_less=True) # instruction is a store
self.int_dest_i = Signal(max=n_regs, reset_less=True) # Dest R# in
self.int_src1_i = Signal(max=n_regs, reset_less=True) # oper1 R# in
self.int_src2_i = Signal(max=n_regs, reset_less=True) # oper2 R# in
+ self.reg_enable_i = Signal(reset_less=True) # enable reg decode
+ # outputs
self.issue_o = Signal(reset_less=True) # instruction was accepted
+ self.busy_o = Signal(reset_less=True) # at least one CU is busy
+
+ # for branch speculation experiment. branch_direction = 0 if
+ # the branch hasn't been met yet. 1 indicates "success", 2 is "fail"
+ # branch_succ and branch_fail are requests to have the current
+ # instruction be dependent on the branch unit "shadow" capability.
+ self.branch_succ_i = Signal(reset_less=True)
+ self.branch_fail_i = Signal(reset_less=True)
+ self.branch_direction_o = Signal(2, reset_less=True)
def elaborate(self, platform):
m = Module()
+ comb = m.d.comb
+ sync = m.d.sync
m.submodules.intregs = self.intregs
m.submodules.fpregs = self.fpregs
fp_src2 = self.fpregs.read_port("src2")
# Int ALUs and Comp Units
- n_int_alus = 2
- m.submodules.cu = cu = CompUnits(self.rwid, n_int_alus)
+ n_int_alus = 5
+ cua = CompUnitALUs(self.rwid, 3)
+ cub = CompUnitBR(self.rwid, 3)
+ m.submodules.cu = cu = CompUnitsBase(self.rwid, [cua, cub])
+ bgt = cub.bgt # get at the branch computation unit
+ br1 = cub.br1
# Int FUs
m.submodules.intfus = intfus = FunctionUnits(self.n_regs, n_int_alus)
# Count of number of FUs
- n_int_fus = n_int_alus
+ n_intfus = n_int_alus
n_fp_fus = 0 # for now
# Integer Priority Picker 1: Adder + Subtractor
- intpick1 = GroupPicker(2) # picks between add and sub
+ intpick1 = GroupPicker(n_intfus) # picks between add, sub, mul and shf
m.submodules.intpick1 = intpick1
# INT/FP Issue Unit
regdecode = RegDecode(self.n_regs)
m.submodules.regdecode = regdecode
- issueunit = IntFPIssueUnit(self.n_regs, n_int_fus, n_fp_fus)
+ issueunit = IssueUnitArray([self.aluissue, self.brissue])
m.submodules.issueunit = issueunit
+ # Shadow Matrix. currently n_intfus shadows, to be used for
+ # write-after-write hazards. NOTE: there is one extra for branches,
+ # so the shadow width is increased by 1
+ m.submodules.shadows = shadows = ShadowMatrix(n_intfus, n_intfus, True)
+ m.submodules.bshadow = bshadow = ShadowMatrix(n_intfus, 1, False)
+
+ # record previous instruction to cast shadow on current instruction
+ prev_shadow = Signal(n_intfus)
+
+ # Branch Speculation recorder. tracks the success/fail state as
+ # each instruction is issued, so that when the branch occurs the
+ # allow/cancel can be issued as appropriate.
+ m.submodules.specrec = bspec = BranchSpeculationRecord(n_intfus)
+
#---------
# ok start wiring things together...
# "now hear de word of de looord... dem bones dem bones dem dryy bones"
#---------
# Issue Unit is where it starts. set up some in/outs for this module
#---------
- m.d.comb += [issueunit.i.store_i.eq(self.int_store_i),
- regdecode.dest_i.eq(self.int_dest_i),
+ comb += [ regdecode.dest_i.eq(self.int_dest_i),
regdecode.src1_i.eq(self.int_src1_i),
regdecode.src2_i.eq(self.int_src2_i),
- regdecode.enable_i.eq(1),
- issueunit.i.dest_i.eq(regdecode.dest_o),
+ regdecode.enable_i.eq(self.reg_enable_i),
self.issue_o.eq(issueunit.issue_o)
]
- self.int_insn_i = issueunit.i.insn_i # enabled by instruction decode
- # connect global rd/wr pending vectors
- m.d.comb += issueunit.i.g_wr_pend_i.eq(intfus.g_int_wr_pend_o)
+ # take these to outside (issue needs them)
+ comb += cua.oper_i.eq(self.alu_oper_i)
+ comb += cua.imm_i.eq(self.alu_imm_i)
+ comb += cub.oper_i.eq(self.br_oper_i)
+ comb += cub.imm_i.eq(self.br_imm_i)
+
# TODO: issueunit.f (FP)
# and int function issue / busy arrays, and dest/src1/src2
- m.d.comb += intfus.dest_i.eq(regdecode.dest_o)
- m.d.comb += intfus.src1_i.eq(regdecode.src1_o)
- m.d.comb += intfus.src2_i.eq(regdecode.src2_o)
+ comb += intfus.dest_i.eq(regdecode.dest_o)
+ comb += intfus.src1_i.eq(regdecode.src1_o)
+ comb += intfus.src2_i.eq(regdecode.src2_o)
- fn_issue_o = issueunit.i.fn_issue_o
+ fn_issue_o = issueunit.fn_issue_o
+
+ comb += intfus.fn_issue_i.eq(fn_issue_o)
+ comb += issueunit.busy_i.eq(cu.busy_o)
+ comb += self.busy_o.eq(cu.busy_o.bool())
+
+ #---------
+ # merge shadow matrices outputs
+ #---------
- m.d.comb += intfus.fn_issue_i.eq(fn_issue_o)
- # XXX sync, so as to stop a simulation infinite loop
- m.d.sync += issueunit.i.busy_i.eq(cu.busy_o)
+ # these are explained in ShadowMatrix docstring, and are to be
+ # connected to the FUReg and FUFU Matrices, to get them to reset
+ anydie = Signal(n_intfus, reset_less=True)
+ allshadown = Signal(n_intfus, reset_less=True)
+ shreset = Signal(n_intfus, reset_less=True)
+ comb += allshadown.eq(shadows.shadown_o & bshadow.shadown_o)
+ comb += anydie.eq(shadows.go_die_o | bshadow.go_die_o)
+ comb += shreset.eq(bspec.match_g_o | bspec.match_f_o)
#---------
# connect fu-fu matrix
#---------
- # Group Picker... done manually for now. TODO: cat array of pick sigs
+ # Group Picker... done manually for now.
go_rd_o = intpick1.go_rd_o
go_wr_o = intpick1.go_wr_o
go_rd_i = intfus.go_rd_i
go_wr_i = intfus.go_wr_i
- m.d.comb += go_rd_i[0:2].eq(go_rd_o[0:2]) # add rd
- m.d.comb += go_wr_i[0:2].eq(go_wr_o[0:2]) # add wr
+ go_die_i = intfus.go_die_i
+ # NOTE: connect to the shadowed versions so that they can "die" (reset)
+ comb += go_rd_i[0:n_intfus].eq(go_rd_o[0:n_intfus]) # rd
+ comb += go_wr_i[0:n_intfus].eq(go_wr_o[0:n_intfus]) # wr
+ comb += go_die_i[0:n_intfus].eq(anydie[0:n_intfus]) # die
# Connect Picker
#---------
- m.d.sync += intpick1.go_rd_i[0:2].eq(~go_rd_i[0:2])
- m.d.comb += intpick1.req_rel_i[0:2].eq(cu.req_rel_o[0:2])
- int_readable_o = intfus.readable_o
- int_writable_o = intfus.writable_o
- m.d.comb += intpick1.readable_i[0:2].eq(int_readable_o[0:2])
- m.d.comb += intpick1.writable_i[0:2].eq(int_writable_o[0:2])
+ comb += intpick1.rd_rel_i[0:n_intfus].eq(cu.rd_rel_o[0:n_intfus])
+ comb += intpick1.req_rel_i[0:n_intfus].eq(cu.req_rel_o[0:n_intfus])
+ int_rd_o = intfus.readable_o
+ int_wr_o = intfus.writable_o
+ comb += intpick1.readable_i[0:n_intfus].eq(int_rd_o[0:n_intfus])
+ comb += intpick1.writable_i[0:n_intfus].eq(int_wr_o[0:n_intfus])
+
+ #---------
+ # Shadow Matrix
+ #---------
+
+ comb += shadows.issue_i.eq(fn_issue_o)
+ #comb += shadows.reset_i[0:n_intfus].eq(bshadow.go_die_o[0:n_intfus])
+ comb += shadows.reset_i[0:n_intfus].eq(bshadow.go_die_o[0:n_intfus])
+ #---------
+ # NOTE; this setup is for the instruction order preservation...
+
+ # connect shadows / go_dies to Computation Units
+ comb += cu.shadown_i[0:n_intfus].eq(allshadown)
+ comb += cu.go_die_i[0:n_intfus].eq(anydie)
+
+ # ok connect first n_int_fu shadows to busy lines, to create an
+ # instruction-order linked-list-like arrangement, using a bit-matrix
+ # (instead of e.g. a ring buffer).
+ # XXX TODO
+
+ # when written, the shadow can be cancelled (and was good)
+ for i in range(n_intfus):
+ comb += shadows.s_good_i[i][0:n_intfus].eq(go_wr_o[0:n_intfus])
+
+ # *previous* instruction shadows *current* instruction, and, obviously,
+ # if the previous is completed (!busy) don't cast the shadow!
+ comb += prev_shadow.eq(~fn_issue_o & cu.busy_o)
+ for i in range(n_intfus):
+ comb += shadows.shadow_i[i][0:n_intfus].eq(prev_shadow)
+
+ #---------
+ # ... and this is for branch speculation. it uses the extra bit
+ # tacked onto the ShadowMatrix (hence shadow_wid=n_intfus+1)
+ # only needs to set shadow_i, s_fail_i and s_good_i
+
+ # issue captures shadow_i (if enabled)
+ comb += bshadow.reset_i[0:n_intfus].eq(shreset[0:n_intfus])
+
+ bactive = Signal(reset_less=True)
+ comb += bactive.eq((bspec.active_i | br1.issue_i) & ~br1.go_wr_i)
+
+ # instruction being issued (fn_issue_o) has a shadow cast by the branch
+ with m.If(bactive & (self.branch_succ_i | self.branch_fail_i)):
+ comb += bshadow.issue_i.eq(fn_issue_o)
+ for i in range(n_intfus):
+ with m.If(fn_issue_o & (Const(1<<i))):
+ comb += bshadow.shadow_i[i][0].eq(1)
+
+ # finally, we need an indicator to the test infrastructure as to
+ # whether the branch succeeded or failed, plus, link up to the
+ # "recorder" of whether the instruction was under shadow or not
+
+ with m.If(br1.issue_i):
+ sync += bspec.active_i.eq(1)
+ with m.If(self.branch_succ_i):
+ comb += bspec.good_i.eq(fn_issue_o & 0x1f)
+ with m.If(self.branch_fail_i):
+ comb += bspec.fail_i.eq(fn_issue_o & 0x1f)
+
+ # branch is active (TODO: a better signal: this is over-using the
+ # go_write signal - actually the branch should not be "writing")
+ with m.If(br1.go_wr_i):
+ sync += self.branch_direction_o.eq(br1.data_o+Const(1, 2))
+ sync += bspec.active_i.eq(0)
+ comb += bspec.br_i.eq(1)
+ # branch occurs if data == 1, failed if data == 0
+ comb += bspec.br_ok_i.eq(br1.data_o == 1)
+ for i in range(n_intfus):
+ # *expected* direction of the branch matched against *actual*
+ comb += bshadow.s_good_i[i][0].eq(bspec.match_g_o[i])
+ # ... or it didn't
+ comb += bshadow.s_fail_i[i][0].eq(bspec.match_f_o[i])
#---------
# Connect Register File(s)
#---------
- print ("intregdeps wen len", len(intfus.dest_rsel_o))
- m.d.sync += int_dest.wen.eq(intfus.dest_rsel_o)
- m.d.comb += int_src1.ren.eq(intfus.src1_rsel_o)
- m.d.comb += int_src2.ren.eq(intfus.src2_rsel_o)
+ comb += int_dest.wen.eq(intfus.dest_rsel_o)
+ comb += int_src1.ren.eq(intfus.src1_rsel_o)
+ comb += int_src2.ren.eq(intfus.src2_rsel_o)
# connect ALUs to regfule
- m.d.comb += int_dest.data_i.eq(cu.dest_o)
- m.d.comb += cu.src1_data_i.eq(int_src1.data_o)
- m.d.comb += cu.src2_data_i.eq(int_src2.data_o)
+ comb += int_dest.data_i.eq(cu.data_o)
+ comb += cu.src1_i.eq(int_src1.data_o)
+ comb += cu.src2_i.eq(int_src2.data_o)
# connect ALU Computation Units
- m.d.sync += cu.go_rd_i[0:2].eq(go_rd_o[0:2])
- m.d.sync += cu.go_wr_i[0:2].eq(go_wr_o[0:2])
- m.d.sync += cu.issue_i[0:2].eq(fn_issue_o[0:2])
+ comb += cu.go_rd_i[0:n_intfus].eq(go_rd_o[0:n_intfus])
+ comb += cu.go_wr_i[0:n_intfus].eq(go_wr_o[0:n_intfus])
+ comb += cu.issue_i[0:n_intfus].eq(fn_issue_o[0:n_intfus])
return m
-
def __iter__(self):
yield from self.intregs
yield from self.fpregs
- yield self.int_store_i
yield self.int_dest_i
yield self.int_src1_i
yield self.int_src2_i
yield self.issue_o
- #yield from self.int_src1
- #yield from self.int_dest
- #yield from self.int_src1
- #yield from self.int_src2
- #yield from self.fp_dest
- #yield from self.fp_src1
- #yield from self.fp_src2
+ yield self.branch_succ_i
+ yield self.branch_fail_i
+ yield self.branch_direction_o
+
+ def ports(self):
+ return list(self)
+
+
+class IssueToScoreboard(Elaboratable):
+
+ def __init__(self, qlen, n_in, n_out, rwid, opwid, n_regs):
+ self.qlen = qlen
+ self.n_in = n_in
+ self.n_out = n_out
+ self.rwid = rwid
+ self.opw = opwid
+ self.n_regs = n_regs
+
+ mqbits = (int(log(qlen) / log(2))+2, False)
+ self.p_add_i = Signal(mqbits) # instructions to add (from data_i)
+ self.p_ready_o = Signal() # instructions were added
+ self.data_i = Instruction.nq(n_in, "data_i", rwid, opwid)
+
+ self.busy_o = Signal(reset_less=True) # at least one CU is busy
+ self.qlen_o = Signal(mqbits, reset_less=True)
+
+ def elaborate(self, platform):
+ m = Module()
+ comb = m.d.comb
+ sync = m.d.sync
+
+ iq = InstructionQ(self.rwid, self.opw, self.qlen, self.n_in, self.n_out)
+ sc = Scoreboard(self.rwid, self.n_regs)
+ m.submodules.iq = iq
+ m.submodules.sc = sc
+
+ # get at the regfile for testing
+ self.intregs = sc.intregs
+
+ # and the "busy" signal and instruction queue length
+ comb += self.busy_o.eq(sc.busy_o)
+ comb += self.qlen_o.eq(iq.qlen_o)
+
+ # link up instruction queue
+ comb += iq.p_add_i.eq(self.p_add_i)
+ comb += self.p_ready_o.eq(iq.p_ready_o)
+ for i in range(self.n_in):
+ comb += eq(iq.data_i[i], self.data_i[i])
+
+ # take instruction and process it. note that it's possible to
+ # "inspect" the queue contents *without* actually removing the
+ # items. items are only removed when the
+
+ # in "waiting" state
+ wait_issue_br = Signal()
+ wait_issue_alu = Signal()
+
+ with m.If(wait_issue_br | wait_issue_alu):
+ # set instruction pop length to 1 if the unit accepted
+ with m.If(wait_issue_br & (sc.brissue.fn_issue_o != 0)):
+ with m.If(iq.qlen_o != 0):
+ comb += iq.n_sub_i.eq(1)
+ with m.If(wait_issue_alu & (sc.aluissue.fn_issue_o != 0)):
+ with m.If(iq.qlen_o != 0):
+ comb += iq.n_sub_i.eq(1)
+
+ # see if some instruction(s) are here. note that this is
+ # "inspecting" the in-place queue. note also that on the
+ # cycle following "waiting" for fn_issue_o to be set, the
+ # "resetting" done above (insn_i=0) could be re-ASSERTed.
+ with m.If(iq.qlen_o != 0):
+ # get the operands and operation
+ imm = iq.data_o[0].imm_i
+ dest = iq.data_o[0].dest_i
+ src1 = iq.data_o[0].src1_i
+ src2 = iq.data_o[0].src2_i
+ op = iq.data_o[0].oper_i
+ opi = iq.data_o[0].opim_i # immediate set
+
+ # set the src/dest regs
+ comb += sc.int_dest_i.eq(dest)
+ comb += sc.int_src1_i.eq(src1)
+ comb += sc.int_src2_i.eq(src2)
+ comb += sc.reg_enable_i.eq(1) # enable the regfile
+
+ # choose a Function-Unit-Group
+ with m.If((op & (0x3<<2)) != 0): # branch
+ comb += sc.brissue.insn_i.eq(1)
+ comb += sc.br_oper_i.eq(Cat(op[0:2], opi))
+ comb += sc.br_imm_i.eq(imm)
+ comb += wait_issue_br.eq(1)
+ with m.Else(): # alu
+ comb += sc.aluissue.insn_i.eq(1)
+ comb += sc.alu_oper_i.eq(Cat(op[0:2], opi))
+ comb += sc.alu_imm_i.eq(imm)
+ comb += wait_issue_alu.eq(1)
+
+ # XXX TODO
+ # these indicate that the instruction is to be made
+ # shadow-dependent on
+ # (either) branch success or branch fail
+ #yield sc.branch_fail_i.eq(branch_fail)
+ #yield sc.branch_succ_i.eq(branch_success)
+
+ return m
+
+ def __iter__(self):
+ yield self.p_ready_o
+ for o in self.data_i:
+ yield from list(o)
+ yield self.p_add_i
def ports(self):
return list(self)
+
IADD = 0
ISUB = 1
+IMUL = 2
+ISHF = 3
+IBGT = 4
+IBLT = 5
+IBEQ = 6
+IBNE = 7
class RegSim:
def __init__(self, rwidth, nregs):
self.rwidth = rwidth
self.regs = [0] * nregs
- def op(self, op, src1, src2, dest):
- src1 = self.regs[src1]
- src2 = self.regs[src2]
+ def op(self, op, op_imm, imm, src1, src2, dest):
+ maxbits = (1 << self.rwidth) - 1
+ src1 = self.regs[src1] & maxbits
+ if op_imm:
+ src2 = imm
+ else:
+ src2 = self.regs[src2] & maxbits
if op == IADD:
- val = (src1 + src2) & ((1<<(self.rwidth))-1)
+ val = src1 + src2
elif op == ISUB:
- val = (src1 - src2) & ((1<<(self.rwidth))-1)
- self.regs[dest] = val
+ val = src1 - src2
+ elif op == IMUL:
+ val = src1 * src2
+ elif op == ISHF:
+ val = src1 >> (src2 & maxbits)
+ elif op == IBGT:
+ val = int(src1 > src2)
+ elif op == IBLT:
+ val = int(src1 < src2)
+ elif op == IBEQ:
+ val = int(src1 == src2)
+ elif op == IBNE:
+ val = int(src1 != src2)
+ val &= maxbits
+ self.setval(dest, val)
+ return val
def setval(self, dest, val):
+ print ("sim setval", dest, hex(val))
self.regs[dest] = val
def dump(self, dut):
yield from self.dump(dut)
assert False
-def int_instr(dut, alusim, op, src1, src2, dest):
- for i in range(len(dut.int_insn_i)):
- yield dut.int_insn_i[i].eq(0)
+def instr_q(dut, op, op_imm, imm, src1, src2, dest,
+ branch_success, branch_fail):
+ instrs = [{'oper_i': op, 'dest_i': dest, 'imm_i': imm, 'opim_i': op_imm,
+ 'src1_i': src1, 'src2_i': src2}]
+
+ sendlen = 1
+ for idx in range(sendlen):
+ yield from eq(dut.data_i[idx], instrs[idx])
+ di = yield dut.data_i[idx]
+ print ("senddata %d %x" % (idx, di))
+ yield dut.p_add_i.eq(sendlen)
+ yield
+ o_p_ready = yield dut.p_ready_o
+ while not o_p_ready:
+ yield
+ o_p_ready = yield dut.p_ready_o
+
+ yield dut.p_add_i.eq(0)
+
+
+def int_instr(dut, op, imm, src1, src2, dest, branch_success, branch_fail):
+ yield from disable_issue(dut)
yield dut.int_dest_i.eq(dest)
yield dut.int_src1_i.eq(src1)
yield dut.int_src2_i.eq(src2)
- yield dut.int_insn_i[op].eq(1)
- alusim.op(op, src1, src2, dest)
+ if (op & (0x3<<2)) != 0: # branch
+ yield dut.brissue.insn_i.eq(1)
+ yield dut.br_oper_i.eq(Const(op & 0x3, 2))
+ yield dut.br_imm_i.eq(imm)
+ dut_issue = dut.brissue
+ else:
+ yield dut.aluissue.insn_i.eq(1)
+ yield dut.alu_oper_i.eq(Const(op & 0x3, 2))
+ yield dut.alu_imm_i.eq(imm)
+ dut_issue = dut.aluissue
+ yield dut.reg_enable_i.eq(1)
+
+ # these indicate that the instruction is to be made shadow-dependent on
+ # (either) branch success or branch fail
+ yield dut.branch_fail_i.eq(branch_fail)
+ yield dut.branch_succ_i.eq(branch_success)
+
+ yield
+ yield from wait_for_issue(dut, dut_issue)
def print_reg(dut, rnums):
print ("reg %s: %s" % (','.join(rnums), ','.join(rs)))
-def scoreboard_sim(dut, alusim):
- yield dut.int_store_i.eq(0)
+def create_random_ops(dut, n_ops, shadowing=False, max_opnums=3):
+ insts = []
+ for i in range(n_ops):
+ src1 = randint(1, dut.n_regs-1)
+ src2 = randint(1, dut.n_regs-1)
+ imm = randint(1, (1<<dut.rwid)-1)
+ dest = randint(1, dut.n_regs-1)
+ op = randint(0, max_opnums)
+ opi = 0 if randint(0, 2) else 1 # set true if random is nonzero
+
+ if shadowing:
+ insts.append((src1, src2, dest, op, opi, imm, (0, 0)))
+ else:
+ insts.append((src1, src2, dest, op, opi, imm))
+ return insts
+
+
+def wait_for_busy_clear(dut):
+ while True:
+ busy_o = yield dut.busy_o
+ if not busy_o:
+ break
+ print ("busy",)
+ yield
- for i in range(1, dut.n_regs):
- yield dut.intregs.regs[i].reg.eq(i*2)
- alusim.setval(i, i*2)
+def disable_issue(dut):
+ yield dut.aluissue.insn_i.eq(0)
+ yield dut.brissue.insn_i.eq(0)
- yield
- if False:
- yield from int_instr(dut, alusim, IADD, 4, 3, 5)
- yield from print_reg(dut, [3,4,5])
- yield
- yield from int_instr(dut, alusim, IADD, 5, 2, 5)
- yield from print_reg(dut, [3,4,5])
- yield
- yield from int_instr(dut, alusim, ISUB, 5, 1, 3)
- yield from print_reg(dut, [3,4,5])
- yield
- for i in range(len(dut.int_insn_i)):
- yield dut.int_insn_i[i].eq(0)
- yield from print_reg(dut, [3,4,5])
- yield
- yield from print_reg(dut, [3,4,5])
+def wait_for_issue(dut, dut_issue):
+ while True:
+ issue_o = yield dut_issue.fn_issue_o
+ if issue_o:
+ yield from disable_issue(dut)
+ yield dut.reg_enable_i.eq(0)
+ break
+ print ("busy",)
+ #yield from print_reg(dut, [1,2,3])
yield
- yield from print_reg(dut, [3,4,5])
+ #yield from print_reg(dut, [1,2,3])
+
+def scoreboard_branch_sim(dut, alusim):
+
+ iseed = 3
+
+ for i in range(1):
+
+ print ("rseed", iseed)
+ seed(iseed)
+ iseed += 1
+
+ yield dut.branch_direction_o.eq(0)
+
+ # set random values in the registers
+ for i in range(1, dut.n_regs):
+ val = 31+i*3
+ val = randint(0, (1<<alusim.rwidth)-1)
+ yield dut.intregs.regs[i].reg.eq(val)
+ alusim.setval(i, val)
+
+ if False:
+ # create some instructions: branches create a tree
+ insts = create_random_ops(dut, 1, True, 1)
+ #insts.append((6, 6, 1, 2, (0, 0)))
+ #insts.append((4, 3, 3, 0, (0, 0)))
+
+ src1 = randint(1, dut.n_regs-1)
+ src2 = randint(1, dut.n_regs-1)
+ #op = randint(4, 7)
+ op = 4 # only BGT at the moment
+
+ branch_ok = create_random_ops(dut, 1, True, 1)
+ branch_fail = create_random_ops(dut, 1, True, 1)
+
+ insts.append((src1, src2, (branch_ok, branch_fail), op, (0, 0)))
+
+ if True:
+ insts = []
+ insts.append( (3, 5, 2, 0, (0, 0)) )
+ branch_ok = []
+ branch_fail = []
+ #branch_ok.append ( (5, 7, 5, 1, (1, 0)) )
+ branch_ok.append( None )
+ branch_fail.append( (1, 1, 2, 0, (0, 1)) )
+ #branch_fail.append( None )
+ insts.append( (6, 4, (branch_ok, branch_fail), 4, (0, 0)) )
+
+ siminsts = deepcopy(insts)
+
+ # issue instruction(s)
+ i = -1
+ instrs = insts
+ branch_direction = 0
+ while instrs:
+ yield
+ yield
+ i += 1
+ branch_direction = yield dut.branch_direction_o # way branch went
+ (src1, src2, dest, op, (shadow_on, shadow_off)) = insts.pop(0)
+ if branch_direction == 1 and shadow_on:
+ print ("skip", i, src1, src2, dest, op, shadow_on, shadow_off)
+ continue # branch was "success" and this is a "failed"... skip
+ if branch_direction == 2 and shadow_off:
+ print ("skip", i, src1, src2, dest, op, shadow_on, shadow_off)
+ continue # branch was "fail" and this is a "success"... skip
+ if branch_direction != 0:
+ shadow_on = 0
+ shadow_off = 0
+ is_branch = op >= 4
+ if is_branch:
+ branch_ok, branch_fail = dest
+ dest = src2
+ # ok zip up the branch success / fail instructions and
+ # drop them into the queue, one marked "to have branch success"
+ # the other to be marked shadow branch "fail".
+ # one out of each of these will be cancelled
+ for ok, fl in zip(branch_ok, branch_fail):
+ if ok:
+ instrs.append((ok[0], ok[1], ok[2], ok[3], (1, 0)))
+ if fl:
+ instrs.append((fl[0], fl[1], fl[2], fl[3], (0, 1)))
+ print ("instr %d: (%d, %d, %d, %d, (%d, %d))" % \
+ (i, src1, src2, dest, op, shadow_on, shadow_off))
+ yield from int_instr(dut, op, src1, src2, dest,
+ shadow_on, shadow_off)
+
+ # wait for all instructions to stop before checking
yield
-
+ yield from wait_for_busy_clear(dut)
+
+ i = -1
+ while siminsts:
+ instr = siminsts.pop(0)
+ if instr is None:
+ continue
+ (src1, src2, dest, op, (shadow_on, shadow_off)) = instr
+ i += 1
+ is_branch = op >= 4
+ if is_branch:
+ branch_ok, branch_fail = dest
+ dest = src2
+ print ("sim %d: (%d, %d, %d, %d, (%d, %d))" % \
+ (i, src1, src2, dest, op, shadow_on, shadow_off))
+ branch_res = alusim.op(op, src1, src2, dest)
+ if is_branch:
+ if branch_res:
+ siminsts += branch_ok
+ else:
+ siminsts += branch_fail
+
+ # check status
yield from alusim.check(dut)
+ yield from alusim.dump(dut)
- for i in range(5):
- src1 = randint(1, dut.n_regs-1)
- src2 = randint(1, dut.n_regs-1)
+
+def scoreboard_sim(dut, alusim):
+
+ seed(0)
+
+ for i in range(50):
+
+ # set random values in the registers
+ for i in range(1, dut.n_regs):
+ val = randint(0, (1<<alusim.rwidth)-1)
+ #val = 31+i*3
+ #val = i
+ yield dut.intregs.regs[i].reg.eq(val)
+ alusim.setval(i, val)
+
+ # create some instructions (some random, some regression tests)
+ instrs = []
+ if True:
+ instrs = create_random_ops(dut, 15, True, 4)
+
+ if False:
+ instrs.append( (1, 2, 2, 1, 1, 20, (0, 0)) )
+
+ if False:
+ instrs.append( (7, 3, 2, 4, (0, 0)) )
+ instrs.append( (7, 6, 6, 2, (0, 0)) )
+ instrs.append( (1, 7, 2, 2, (0, 0)) )
+
+ if False:
+ instrs.append((2, 3, 3, 0, 0, 0, (0, 0)))
+ instrs.append((5, 3, 3, 1, 0, 0, (0, 0)))
+ instrs.append((3, 5, 5, 2, 0, 0, (0, 0)))
+ instrs.append((5, 3, 3, 3, 0, 0, (0, 0)))
+ instrs.append((3, 5, 5, 0, 0, 0, (0, 0)))
+
+ if False:
+ instrs.append( (3, 3, 4, 0, 0, 13979, (0, 0)))
+ instrs.append( (6, 4, 1, 2, 0, 40976, (0, 0)))
+ instrs.append( (1, 4, 7, 4, 1, 23652, (0, 0)))
+
+ if False:
+ instrs.append((5, 6, 2, 1))
+ instrs.append((2, 2, 4, 0))
+ #instrs.append((2, 2, 3, 1))
+
+ if False:
+ instrs.append((2, 1, 2, 3))
+
+ if False:
+ instrs.append((2, 6, 2, 1))
+ instrs.append((2, 1, 2, 0))
+
+ if False:
+ instrs.append((1, 2, 7, 2))
+ instrs.append((7, 1, 5, 0))
+ instrs.append((4, 4, 1, 1))
+
+ if False:
+ instrs.append((5, 6, 2, 2))
+ instrs.append((1, 1, 4, 1))
+ instrs.append((6, 5, 3, 0))
+
+ if False:
+ # Write-after-Write Hazard
+ instrs.append( (3, 6, 7, 2) )
+ instrs.append( (4, 4, 7, 1) )
+
+ if False:
+ # self-read/write-after-write followed by Read-after-Write
+ instrs.append((1, 1, 1, 1))
+ instrs.append((1, 5, 3, 0))
+
+ if False:
+ # Read-after-Write followed by self-read-after-write
+ instrs.append((5, 6, 1, 2))
+ instrs.append((1, 1, 1, 1))
+
+ if False:
+ # self-read-write sandwich
+ instrs.append((5, 6, 1, 2))
+ instrs.append((1, 1, 1, 1))
+ instrs.append((1, 5, 3, 0))
+
+ if False:
+ # very weird failure
+ instrs.append( (5, 2, 5, 2) )
+ instrs.append( (2, 6, 3, 0) )
+ instrs.append( (4, 2, 2, 1) )
+
+ if False:
+ v1 = 4
+ yield dut.intregs.regs[5].reg.eq(v1)
+ alusim.setval(5, v1)
+ yield dut.intregs.regs[3].reg.eq(5)
+ alusim.setval(3, 5)
+ instrs.append((5, 3, 3, 4, (0, 0)))
+ instrs.append((4, 2, 1, 2, (0, 1)))
+
+ if False:
+ v1 = 6
+ yield dut.intregs.regs[5].reg.eq(v1)
+ alusim.setval(5, v1)
+ yield dut.intregs.regs[3].reg.eq(5)
+ alusim.setval(3, 5)
+ instrs.append((5, 3, 3, 4, (0, 0)))
+ instrs.append((4, 2, 1, 2, (1, 0)))
+
+ if False:
+ instrs.append( (4, 3, 5, 1, 0, (0, 0)) )
+ instrs.append( (5, 2, 3, 1, 0, (0, 0)) )
+ instrs.append( (7, 1, 5, 2, 0, (0, 0)) )
+ instrs.append( (5, 6, 6, 4, 0, (0, 0)) )
+ instrs.append( (7, 5, 2, 2, 0, (1, 0)) )
+ instrs.append( (1, 7, 5, 0, 0, (0, 1)) )
+ instrs.append( (1, 6, 1, 2, 0, (1, 0)) )
+ instrs.append( (1, 6, 7, 3, 0, (0, 0)) )
+ instrs.append( (6, 7, 7, 0, 0, (0, 0)) )
+
+ # issue instruction(s), wait for issue to be free before proceeding
+ for i, instr in enumerate(instrs):
+ src1, src2, dest, op, opi, imm, (br_ok, br_fail) = instr
+
+ print ("instr %d: (%d, %d, %d, %d, %d, %d)" % \
+ (i, src1, src2, dest, op, opi, imm))
+ alusim.op(op, opi, imm, src1, src2, dest)
+ yield from instr_q(dut, op, opi, imm, src1, src2, dest,
+ br_ok, br_fail)
+
+ # wait for all instructions to stop before checking
while True:
- dest = randint(1, dut.n_regs-1)
- break
- if dest not in [src1, src2]:
+ iqlen = yield dut.qlen_o
+ if iqlen == 0:
break
- #src1 = 2
- #src2 = 3
- #dest = 2
-
- op = randint(0, 1)
- #op = i % 2
- print ("random %d: %d %d %d %d\n" % (i, op, src1, src2, dest))
- yield from int_instr(dut, alusim, op, src1, src2, dest)
- yield from print_reg(dut, [3,4,5])
+ yield
yield
- yield from print_reg(dut, [3,4,5])
- for i in range(len(dut.int_insn_i)):
- yield dut.int_insn_i[i].eq(0)
yield
yield
+ yield
+ yield from wait_for_busy_clear(dut)
-
- yield
- yield from print_reg(dut, [3,4,5])
- yield
- yield from print_reg(dut, [3,4,5])
- yield
- yield
- yield
- yield
- yield from alusim.check(dut)
- yield from alusim.dump(dut)
-
-
-def explore_groups(dut):
- from nmigen.hdl.ir import Fragment
- from nmigen.hdl.xfrm import LHSGroupAnalyzer
-
- fragment = dut.elaborate(platform=None)
- fr = Fragment.get(fragment, platform=None)
-
- groups = LHSGroupAnalyzer()(fragment._statements)
-
- print (groups)
+ # check status
+ yield from alusim.check(dut)
+ yield from alusim.dump(dut)
def test_scoreboard():
- dut = Scoreboard(32, 8)
- alusim = RegSim(32, 8)
+ dut = IssueToScoreboard(2, 1, 1, 16, 8, 8)
+ alusim = RegSim(16, 8)
+ memsim = MemSim(16, 16)
vl = rtlil.convert(dut, ports=dut.ports())
with open("test_scoreboard6600.il", "w") as f:
f.write(vl)
run_simulation(dut, scoreboard_sim(dut, alusim),
vcd_name='test_scoreboard6600.vcd')
+ #run_simulation(dut, scoreboard_branch_sim(dut, alusim),
+ # vcd_name='test_scoreboard6600.vcd')
+
if __name__ == '__main__':
test_scoreboard()