only one cycle (sync)
"""
-from nmigen import Elaboratable, Signal, Module, Const, Mux, Array
+from nmigen import Elaboratable, Signal, Module, Const, Mux
from nmigen.hdl.rec import Record, Layout
from nmigen.cli import main
from nmigen.cli import verilog, rtlil
from nmigen.compat.sim import run_simulation
+from nmutil.extend import exts
+from nmutil.gtkw import write_gtkw
-from soc.decoder.power_enums import InternalOp, Function, CryIn
+# NOTE: to use cxxsim, export NMIGEN_SIM_MODE=cxxsim from the shell
+# Also, check out the cxxsim nmigen branch, and latest yosys from git
+from nmutil.sim_tmp_alternative import (Simulator, nmigen_sim_top_module,
+ is_engine_pysim)
+
+from openpower.decoder.decode2execute1 import Data
+from openpower.decoder.power_enums import MicrOp, Function, CryIn
from soc.fu.alu.alu_input_record import CompALUOpSubset
from soc.fu.cr.cr_input_record import CompCROpSubset
-import operator
-
+from soc.fu.pipe_data import FUBaseData
+from soc.fu.alu.pipe_data import CommonPipeSpec
+from soc.fu.compunits.compunits import FunctionUnitBaseSingle
+import operator
class Adder(Elaboratable):
def __init__(self, width):
- self.invert_a = Signal()
- self.a = Signal(width)
- self.b = Signal(width)
- self.o = Signal(width, name="add_o")
+ self.invert_in = Signal()
+ self.a = Signal(width)
+ self.b = Signal(width)
+ self.o = Signal(width, name="add_o")
def elaborate(self, platform):
m = Module()
- with m.If(self.invert_a):
+ with m.If(self.invert_in):
m.d.comb += self.o.eq((~self.a) + self.b)
with m.Else():
m.d.comb += self.o.eq(self.a + self.b)
class Subtractor(Elaboratable):
def __init__(self, width):
- self.a = Signal(width)
- self.b = Signal(width)
- self.o = Signal(width, name="sub_o")
+ self.a = Signal(width)
+ self.b = Signal(width)
+ self.o = Signal(width, name="sub_o")
def elaborate(self, platform):
m = Module()
class Multiplier(Elaboratable):
def __init__(self, width):
- self.a = Signal(width)
- self.b = Signal(width)
- self.o = Signal(width, name="mul_o")
+ self.a = Signal(width)
+ self.b = Signal(width)
+ self.o = Signal(width, name="mul_o")
def elaborate(self, platform):
m = Module()
class Shifter(Elaboratable):
def __init__(self, width):
self.width = width
- self.a = Signal(width)
- self.b = Signal(width)
- self.o = Signal(width, name="shf_o")
+ self.a = Signal(width)
+ self.b = Signal(width)
+ self.o = Signal(width, name="shf_o")
def elaborate(self, platform):
m = Module()
btrunc = Signal(self.width)
- m.d.comb += btrunc.eq(self.b & Const((1<<self.width)-1))
+ m.d.comb += btrunc.eq(self.b & Const((1 << self.width)-1))
m.d.comb += self.o.eq(self.a >> btrunc)
return m
+
+class SignExtend(Elaboratable):
+ def __init__(self, width):
+ self.width = width
+ self.a = Signal(width)
+ self.o = Signal(width, name="exts_o")
+
+ def elaborate(self, platform):
+ m = Module()
+ m.d.comb += self.o.eq(exts(self.a, 8, self.width))
+ return m
+
+
class Dummy:
pass
class DummyALU(Elaboratable):
def __init__(self, width):
- self.p = Dummy() # make look like nmutil pipeline API
- self.p.data_i = Dummy()
- self.p.data_i.ctx = Dummy()
- self.n = Dummy() # make look like nmutil pipeline API
- self.n.data_o = Dummy()
- self.p.valid_i = Signal()
- self.p.ready_o = Signal()
- self.n.ready_i = Signal()
- self.n.valid_o = Signal()
- self.counter = Signal(4)
- self.op = CompCROpSubset()
+ self.p = Dummy() # make look like nmutil pipeline API
+ self.p.i_data = Dummy()
+ self.p.i_data.ctx = Dummy()
+ self.n = Dummy() # make look like nmutil pipeline API
+ self.n.o_data = Dummy()
+ self.p.i_valid = Signal()
+ self.p.o_ready = Signal()
+ self.n.i_ready = Signal()
+ self.n.o_valid = Signal()
+ self.counter = Signal(4)
+ self.op = CompCROpSubset()
i = []
i.append(Signal(width, name="i1"))
i.append(Signal(width, name="i2"))
i.append(Signal(width, name="i3"))
- self.i = Array(i)
+ self.i = i
self.a, self.b, self.c = i[0], i[1], i[2]
- self.out = Array([Signal(width, name="alu_o")])
+ self.out = tuple([Signal(width, name="alu_o")])
self.o = self.out[0]
self.width = width
# more "look like nmutil pipeline API"
- self.p.data_i.ctx.op = self.op
- self.p.data_i.a = self.a
- self.p.data_i.b = self.b
- self.p.data_i.c = self.c
- self.n.data_o.o = self.o
+ self.p.i_data.ctx.op = self.op
+ self.p.i_data.a = self.a
+ self.p.i_data.b = self.b
+ self.p.i_data.c = self.c
+ self.n.o_data.o = self.o
def elaborate(self, platform):
m = Module()
- go_now = Signal(reset_less=True) # testing no-delay ALU
+ go_now = Signal(reset_less=True) # testing no-delay ALU
- with m.If(self.p.valid_i):
+ with m.If(self.p.i_valid):
# input is valid. next check, if we already said "ready" or not
- with m.If(~self.p.ready_o):
+ with m.If(~self.p.o_ready):
# we didn't say "ready" yet, so say so and initialise
- m.d.sync += self.p.ready_o.eq(1)
+ m.d.sync += self.p.o_ready.eq(1)
m.d.sync += self.o.eq(self.a)
m.d.comb += go_now.eq(1)
with m.Else():
# input says no longer valid, so drop ready as well.
# a "proper" ALU would have had to sync in the opcode and a/b ops
- m.d.sync += self.p.ready_o.eq(0)
+ m.d.sync += self.p.o_ready.eq(0)
# ok so the counter's running: when it gets to 1, fire the output
with m.If((self.counter == 1) | go_now):
# set the output as valid if the recipient is ready for it
- m.d.sync += self.n.valid_o.eq(1)
- with m.If(self.n.ready_i & self.n.valid_o):
- m.d.sync += self.n.valid_o.eq(0)
+ m.d.sync += self.n.o_valid.eq(1)
+ with m.If(self.n.i_ready & self.n.o_valid):
+ m.d.sync += self.n.o_valid.eq(0)
# recipient said it was ready: reset back to known-good.
- m.d.sync += self.counter.eq(0) # reset the counter
- m.d.sync += self.o.eq(0) # clear the output for tidiness sake
+ m.d.sync += self.counter.eq(0) # reset the counter
+ m.d.sync += self.o.eq(0) # clear the output for tidiness sake
# countdown to 1 (transition from 1 to 0 only on acknowledgement)
with m.If(self.counter > 1):
def ports(self):
return list(self)
+#####################
+# converting even this dummy ALU over to the FunctionUnit RegSpecs API
+# which, errr, note that the regspecs are totally ignored below, but
+# at least the widths are all 64-bit so it's okay.
+#####################
+
+# input (and output) for logical initial stage (common input)
+
+
+class ALUInputData(FUBaseData):
+ regspec = [('INT', 'a', '0:63'), # RA
+ ('INT', 'b', '0:63'), # RB/immediate
+ ]
+
+ def __init__(self, pspec):
+ super().__init__(pspec, False)
+
+
+# output from ALU final stage
+class ALUOutputData(FUBaseData):
+ regspec = [('INT', 'o', '0:63'), # RT
+ ]
+
+ def __init__(self, pspec):
+ super().__init__(pspec, True)
+
+
+# ALU pipe specification class
+class ALUPipeSpec(CommonPipeSpec):
+ regspec = (ALUInputData.regspec, ALUOutputData.regspec)
+ opsubsetkls = CompALUOpSubset
+
+
+class ALUFunctionUnit(FunctionUnitBaseSingle):
+ # class ALUFunctionUnit(FunctionUnitBaseMulti):
+ fnunit = Function.ALU
+
+ def __init__(self, idx, parent_pspec):
+ super().__init__(ALUPipeSpec, ALU, 1, parent_pspec)
+
class ALU(Elaboratable):
def __init__(self, width):
- self.p = Dummy() # make look like nmutil pipeline API
- self.p.data_i = Dummy()
- self.p.data_i.ctx = Dummy()
- self.n = Dummy() # make look like nmutil pipeline API
- self.n.data_o = Dummy()
- self.p.valid_i = Signal()
- self.p.ready_o = Signal()
- self.n.ready_i = Signal()
- self.n.valid_o = Signal()
- self.counter = Signal(4)
+ # XXX major temporary hack: attempting to convert
+ # ALU over to RegSpecs API, FunctionUnitBaseSingle passes in
+ # a regspec here which we can't cope with. therefore, errr...
+ # just throw it away and set the width to 64
+ if not isinstance(width, int):
+ width = 64
+ # TODO, really this should just inherit from ControlBase it would
+ # be a lot less messy.
+ self.p = Dummy() # make look like nmutil pipeline API
+ self.p.i_data = Dummy()
+ self.p.i_data.ctx = Dummy()
+ self.n = Dummy() # make look like nmutil pipeline API
+ self.n.o_data = Dummy()
+ self.p.i_valid = Signal()
+ self.p.o_ready = Signal()
+ self.n.i_ready = Signal()
+ self.n.o_valid = Signal()
+ self.counter = Signal(4)
self.op = CompALUOpSubset(name="op")
i = []
i.append(Signal(width, name="i1"))
i.append(Signal(width, name="i2"))
- self.i = Array(i)
+ self.i = i
self.a, self.b = i[0], i[1]
- self.out = Array([Signal(width, name="alu_o")])
+ out = []
+ out.append(Data(width, name="alu_o"))
+ out.append(Data(width, name="alu_cr"))
+ self.out = tuple(out)
self.o = self.out[0]
+ self.cr = self.out[1]
self.width = width
- # more "look like nmutil pipeline API"
- self.p.data_i.ctx.op = self.op
- self.p.data_i.a = self.a
- self.p.data_i.b = self.b
- self.n.data_o.o = self.o
+ # more "look like nmutil ControlBase pipeline API" stuff
+ self.p.i_data.ctx.op = self.op
+ self.p.i_data.a = self.a
+ self.p.i_data.b = self.b
+ self.n.o_data.o = self.o
+ self.n.o_data.cr = self.cr
def elaborate(self, platform):
m = Module()
mul = Multiplier(self.width)
shf = Shifter(self.width)
sub = Subtractor(self.width)
+ ext_sign = SignExtend(self.width)
m.submodules.add = add
m.submodules.mul = mul
m.submodules.shf = shf
m.submodules.sub = sub
+ m.submodules.ext_sign = ext_sign
# really should not activate absolutely all ALU inputs like this
for mod in [add, mul, shf, sub]:
mod.a.eq(self.a),
mod.b.eq(self.b),
]
+ # EXTS sign extends the first input
+ with m.If(self.op.insn_type == MicrOp.OP_EXTS):
+ m.d.comb += ext_sign.a.eq(self.a)
+ # EXTSWSLI sign extends the second input
+ with m.Elif(self.op.insn_type == MicrOp.OP_EXTSWSLI):
+ m.d.comb += ext_sign.a.eq(self.b)
# pass invert (and carry later)
- m.d.comb += add.invert_a.eq(self.op.invert_a)
+ m.d.comb += add.invert_in.eq(self.op.invert_in)
- go_now = Signal(reset_less=True) # testing no-delay ALU
+ go_now = Signal(reset_less=True) # testing no-delay ALU
# ALU sequencer is idle when the count is zero
alu_idle = Signal(reset_less=True)
with m.If(go_now):
# with a combinatorial, no-delay ALU, just pass through
# the handshake signals to the other side
- m.d.comb += self.p.ready_o.eq(self.n.ready_i)
- m.d.comb += self.n.valid_o.eq(self.p.valid_i)
+ m.d.comb += self.p.o_ready.eq(self.n.i_ready)
+ m.d.comb += self.n.o_valid.eq(self.p.i_valid)
with m.Else():
# sequential ALU handshake:
- # ready_o responds to valid_i, but only if the ALU is idle
- m.d.comb += self.p.ready_o.eq(alu_idle)
- # select the internally generated valid_o, above
- m.d.comb += self.n.valid_o.eq(alu_done)
+ # o_ready responds to i_valid, but only if the ALU is idle
+ m.d.comb += self.p.o_ready.eq(alu_idle)
+ # select the internally generated o_valid, above
+ m.d.comb += self.n.o_valid.eq(alu_done)
- # hold the ALU result until ready_o is asserted
+ # hold the ALU result until o_ready is asserted
alu_r = Signal(self.width)
+ # output masks
+ # NOP and ILLEGAL don't output anything
+ with m.If((self.op.insn_type != MicrOp.OP_NOP) &
+ (self.op.insn_type != MicrOp.OP_ILLEGAL)):
+ m.d.comb += self.o.ok.eq(1)
+ # CR is output when rc bit is active
+ m.d.comb += self.cr.ok.eq(self.op.rc.rc)
+
with m.If(alu_idle):
- with m.If(self.p.valid_i):
+ with m.If(self.p.i_valid):
# as this is a "fake" pipeline, just grab the output right now
- with m.If(self.op.insn_type == InternalOp.OP_ADD):
+ with m.If(self.op.insn_type == MicrOp.OP_ADD):
m.d.sync += alu_r.eq(add.o)
- with m.Elif(self.op.insn_type == InternalOp.OP_MUL_L64):
+ with m.Elif(self.op.insn_type == MicrOp.OP_MUL_L64):
m.d.sync += alu_r.eq(mul.o)
- with m.Elif(self.op.insn_type == InternalOp.OP_SHR):
+ with m.Elif(self.op.insn_type == MicrOp.OP_SHR):
m.d.sync += alu_r.eq(shf.o)
+ with m.Elif(self.op.insn_type == MicrOp.OP_EXTS):
+ m.d.sync += alu_r.eq(ext_sign.o)
+ with m.Elif(self.op.insn_type == MicrOp.OP_EXTSWSLI):
+ m.d.sync += alu_r.eq(ext_sign.o)
# SUB is zero-delay, no need to register
# NOTE: all of these are fake, just something to test
# MUL, to take 5 instructions
- with m.If(self.op.insn_type == InternalOp.OP_MUL_L64):
+ with m.If(self.op.insn_type == MicrOp.OP_MUL_L64):
m.d.sync += self.counter.eq(5)
# SHIFT to take 1, straight away
- with m.Elif(self.op.insn_type == InternalOp.OP_SHR):
+ with m.Elif(self.op.insn_type == MicrOp.OP_SHR):
m.d.sync += self.counter.eq(1)
# ADD/SUB to take 3
- with m.Elif(self.op.insn_type == InternalOp.OP_ADD):
+ with m.Elif(self.op.insn_type == MicrOp.OP_ADD):
m.d.sync += self.counter.eq(3)
+ # EXTS to take 1
+ with m.Elif(self.op.insn_type == MicrOp.OP_EXTS):
+ m.d.sync += self.counter.eq(1)
+ # EXTSWSLI to take 1
+ with m.Elif(self.op.insn_type == MicrOp.OP_EXTSWSLI):
+ m.d.sync += self.counter.eq(1)
# others to take no delay
with m.Else():
m.d.comb += go_now.eq(1)
- with m.Elif(~alu_done | self.n.ready_i):
+ with m.Elif(~alu_done | self.n.i_ready):
# decrement the counter while the ALU is neither idle nor finished
m.d.sync += self.counter.eq(self.counter - 1)
# choose between zero-delay output, or registered
with m.If(go_now):
- m.d.comb += self.o.eq(sub.o)
+ m.d.comb += self.o.data.eq(sub.o)
# only present the result at the last computation cycle
with m.Elif(alu_done):
- m.d.comb += self.o.eq(alu_r)
+ m.d.comb += self.o.data.eq(alu_r)
+
+ # determine condition register bits based on the data output value
+ with m.If(~self.o.data.any()):
+ m.d.comb += self.cr.data.eq(0b001)
+ with m.Elif(self.o.data[-1]):
+ m.d.comb += self.cr.data.eq(0b010)
+ with m.Else():
+ m.d.comb += self.cr.data.eq(0b100)
return m
yield from self.op.ports()
yield self.a
yield self.b
- yield self.o
- yield self.p.valid_i
- yield self.p.ready_o
- yield self.n.valid_o
- yield self.n.ready_i
+ yield from self.o.ports()
+ yield self.p.i_valid
+ yield self.p.o_ready
+ yield self.n.o_valid
+ yield self.n.i_ready
def ports(self):
return list(self)
class BranchOp(Elaboratable):
def __init__(self, width, op):
- self.a = Signal(width)
- self.b = Signal(width)
- self.o = Signal(width)
+ self.a = Signal(width)
+ self.b = Signal(width)
+ self.o = Signal(width)
self.op = op
def elaborate(self, platform):
class BranchALU(Elaboratable):
def __init__(self, width):
- self.p = Dummy() # make look like nmutil pipeline API
- self.p.data_i = Dummy()
- self.p.data_i.ctx = Dummy()
- self.n = Dummy() # make look like nmutil pipeline API
- self.n.data_o = Dummy()
- self.p.valid_i = Signal()
- self.p.ready_o = Signal()
- self.n.ready_i = Signal()
- self.n.valid_o = Signal()
- self.counter = Signal(4)
- self.op = Signal(2)
+ self.p = Dummy() # make look like nmutil pipeline API
+ self.p.i_data = Dummy()
+ self.p.i_data.ctx = Dummy()
+ self.n = Dummy() # make look like nmutil pipeline API
+ self.n.o_data = Dummy()
+ self.p.i_valid = Signal()
+ self.p.o_ready = Signal()
+ self.n.i_ready = Signal()
+ self.n.o_valid = Signal()
+ self.counter = Signal(4)
+ self.op = Signal(2)
i = []
i.append(Signal(width, name="i1"))
i.append(Signal(width, name="i2"))
- self.i = Array(i)
+ self.i = i
self.a, self.b = i[0], i[1]
- self.out = Array([Signal(width)])
+ self.out = tuple([Signal(width)])
self.o = self.out[0]
self.width = width
mod.b.eq(self.b),
]
- go_now = Signal(reset_less=True) # testing no-delay ALU
- with m.If(self.p.valid_i):
+ go_now = Signal(reset_less=True) # testing no-delay ALU
+ with m.If(self.p.i_valid):
# input is valid. next check, if we already said "ready" or not
- with m.If(~self.p.ready_o):
+ with m.If(~self.p.o_ready):
# we didn't say "ready" yet, so say so and initialise
- m.d.sync += self.p.ready_o.eq(1)
+ m.d.sync += self.p.o_ready.eq(1)
# as this is a "fake" pipeline, just grab the output right now
with m.Switch(self.op):
for i, mod in enumerate([bgt, blt, beq, bne]):
with m.Case(i):
m.d.sync += self.o.eq(mod.o)
- m.d.sync += self.counter.eq(5) # branch to take 5 cycles (fake)
+ # branch to take 5 cycles (fake)
+ m.d.sync += self.counter.eq(5)
#m.d.comb += go_now.eq(1)
with m.Else():
# input says no longer valid, so drop ready as well.
# a "proper" ALU would have had to sync in the opcode and a/b ops
- m.d.sync += self.p.ready_o.eq(0)
+ m.d.sync += self.p.o_ready.eq(0)
# ok so the counter's running: when it gets to 1, fire the output
with m.If((self.counter == 1) | go_now):
# set the output as valid if the recipient is ready for it
- m.d.sync += self.n.valid_o.eq(1)
- with m.If(self.n.ready_i & self.n.valid_o):
- m.d.sync += self.n.valid_o.eq(0)
+ m.d.sync += self.n.o_valid.eq(1)
+ with m.If(self.n.i_ready & self.n.o_valid):
+ m.d.sync += self.n.o_valid.eq(0)
# recipient said it was ready: reset back to known-good.
- m.d.sync += self.counter.eq(0) # reset the counter
- m.d.sync += self.o.eq(0) # clear the output for tidiness sake
+ m.d.sync += self.counter.eq(0) # reset the counter
+ m.d.sync += self.o.eq(0) # clear the output for tidiness sake
# countdown to 1 (transition from 1 to 0 only on acknowledgement)
with m.If(self.counter > 1):
def ports(self):
return list(self)
+
def run_op(dut, a, b, op, inv_a=0):
- from nmigen.back.pysim import Settle
yield dut.a.eq(a)
yield dut.b.eq(b)
yield dut.op.insn_type.eq(op)
- yield dut.op.invert_a.eq(inv_a)
- yield dut.n.ready_i.eq(0)
- yield dut.p.valid_i.eq(1)
-
- # if valid_o rose on the very first cycle, it is a
- # zero-delay ALU
- yield Settle()
- vld = yield dut.n.valid_o
- if vld:
- # special case for zero-delay ALU
- # we must raise ready_i first, since the combinatorial ALU doesn't
- # have any storage, and doesn't dare to assert ready_o back to us
- # until we accepted the output data
- yield dut.n.ready_i.eq(1)
- result = yield dut.o
- yield
- yield dut.p.valid_i.eq(0)
- yield dut.n.ready_i.eq(0)
- yield
- return result
-
+ yield dut.op.invert_in.eq(inv_a)
+ yield dut.n.i_ready.eq(0)
+ yield dut.p.i_valid.eq(1)
+ yield dut.n.i_ready.eq(1)
yield
# wait for the ALU to accept our input data
- while True:
- rdy = yield dut.p.ready_o
- if rdy:
- break
+ while not (yield dut.p.o_ready):
yield
- yield dut.p.valid_i.eq(0)
+ yield dut.p.i_valid.eq(0)
+ yield dut.a.eq(0)
+ yield dut.b.eq(0)
+ yield dut.op.insn_type.eq(0)
+ yield dut.op.invert_in.eq(0)
# wait for the ALU to present the output data
- while True:
- yield Settle()
- vld = yield dut.n.valid_o
- if vld:
- break
+ while not (yield dut.n.o_valid):
yield
# latch the result and lower read_i
- yield dut.n.ready_i.eq(1)
- result = yield dut.o
- yield
- yield dut.n.ready_i.eq(0)
- yield
+ result = yield dut.o.data
+ yield dut.n.i_ready.eq(0)
return result
def alu_sim(dut):
- result = yield from run_op(dut, 5, 3, InternalOp.OP_ADD)
- print ("alu_sim add", result)
+ result = yield from run_op(dut, 5, 3, MicrOp.OP_ADD)
+ print("alu_sim add", result)
assert (result == 8)
- result = yield from run_op(dut, 2, 3, InternalOp.OP_MUL_L64)
- print ("alu_sim mul", result)
+ result = yield from run_op(dut, 2, 3, MicrOp.OP_MUL_L64)
+ print("alu_sim mul", result)
assert (result == 6)
- result = yield from run_op(dut, 5, 3, InternalOp.OP_ADD, inv_a=1)
- print ("alu_sim add-inv", result)
+ result = yield from run_op(dut, 5, 3, MicrOp.OP_ADD, inv_a=1)
+ print("alu_sim add-inv", result)
assert (result == 65533)
# test zero-delay ALU
# don't have OP_SUB, so use any other
- result = yield from run_op(dut, 5, 3, InternalOp.OP_NOP)
- print ("alu_sim sub", result)
+ result = yield from run_op(dut, 5, 3, MicrOp.OP_CMP)
+ print("alu_sim sub", result)
assert (result == 2)
- result = yield from run_op(dut, 13, 2, InternalOp.OP_SHR)
- print ("alu_sim shr", result)
+ result = yield from run_op(dut, 13, 2, MicrOp.OP_SHR)
+ print("alu_sim shr", result)
assert (result == 3)
def test_alu():
alu = ALU(width=16)
+ write_alu_gtkw("test_alusim.gtkw", clk_period=10e-9)
run_simulation(alu, {"sync": alu_sim(alu)}, vcd_name='test_alusim.vcd')
vl = rtlil.convert(alu, ports=alu.ports())
f.write(vl)
+def test_alu_parallel():
+ # Compare with the sequential test implementation, above.
+ m = Module()
+ m.submodules.alu = dut = ALU(width=16)
+ write_alu_gtkw("test_alu_parallel.gtkw", sub_module='alu',
+ pysim=is_engine_pysim())
+
+ sim = Simulator(m)
+ sim.add_clock(1e-6)
+
+ def send(a, b, op, inv_a=0, rc=0):
+ # present input data and assert i_valid
+ yield dut.a.eq(a)
+ yield dut.b.eq(b)
+ yield dut.op.insn_type.eq(op)
+ yield dut.op.invert_in.eq(inv_a)
+ yield dut.op.rc.rc.eq(rc)
+ yield dut.p.i_valid.eq(1)
+ yield
+ # wait for o_ready to be asserted
+ while not (yield dut.p.o_ready):
+ yield
+ # clear input data and negate i_valid
+ # if send is called again immediately afterwards, there will be no
+ # visible transition (they will not be negated, after all)
+ yield dut.p.i_valid.eq(0)
+ yield dut.a.eq(0)
+ yield dut.b.eq(0)
+ yield dut.op.insn_type.eq(0)
+ yield dut.op.invert_in.eq(0)
+ yield dut.op.rc.rc.eq(0)
+
+ def receive():
+ # signal readiness to receive data
+ yield dut.n.i_ready.eq(1)
+ yield
+ # wait for o_valid to be asserted
+ while not (yield dut.n.o_valid):
+ yield
+ # read results
+ result = yield dut.o.data
+ cr = yield dut.cr.data
+ # negate i_ready
+ # if receive is called again immediately afterwards, there will be no
+ # visible transition (it will not be negated, after all)
+ yield dut.n.i_ready.eq(0)
+ return result, cr
+
+ def producer():
+ # send a few test cases, interspersed with wait states
+ # note that, for this test, we do not wait for the result to be ready,
+ # before presenting the next input
+ # 5 + 3
+ yield from send(5, 3, MicrOp.OP_ADD)
+ yield
+ yield
+ # 2 * 3
+ yield from send(2, 3, MicrOp.OP_MUL_L64, rc=1)
+ # (-6) + 3
+ yield from send(5, 3, MicrOp.OP_ADD, inv_a=1, rc=1)
+ yield
+ # 5 - 3
+ # note that this is a zero-delay operation
+ yield from send(5, 3, MicrOp.OP_CMP)
+ yield
+ yield
+ # NOP
+ yield from send(5, 3, MicrOp.OP_NOP)
+ # 13 >> 2
+ yield from send(13, 2, MicrOp.OP_SHR)
+ # sign extent 13
+ yield from send(13, 2, MicrOp.OP_EXTS)
+ # sign extend -128 (8 bits)
+ yield from send(0x80, 2, MicrOp.OP_EXTS, rc=1)
+ # sign extend -128 (8 bits)
+ yield from send(2, 0x80, MicrOp.OP_EXTSWSLI)
+ # 5 - 5
+ yield from send(5, 5, MicrOp.OP_CMP, rc=1)
+
+ def consumer():
+ # receive and check results, interspersed with wait states
+ # the consumer is not in step with the producer, but the
+ # order of the results are preserved
+ yield
+ # 5 + 3 = 8
+ result = yield from receive()
+ assert result[0] == 8
+ # 2 * 3 = 6
+ # 6 > 0 => CR = 0b100
+ result = yield from receive()
+ assert result == (6, 0b100)
+ yield
+ yield
+ # (-6) + 3 = -3
+ # -3 < 0 => CR = 0b010
+ result = yield from receive()
+ assert result == (65533, 0b010) # unsigned equivalent to -2
+ # 5 - 3 = 2
+ # note that this is a zero-delay operation
+ # this, and the previous result, will be received back-to-back
+ # (check the output waveform to see this)
+ result = yield from receive()
+ assert result[0] == 2
+ yield
+ yield
+ # NOP
+ yield from receive()
+ # 13 >> 2 = 3
+ result = yield from receive()
+ assert result[0] == 3
+ # sign extent 13 = 13
+ result = yield from receive()
+ assert result[0] == 13
+ # sign extend -128 (8 bits) = -128 (16 bits)
+ # -128 < 0 => CR = 0b010
+ result = yield from receive()
+ assert result == (0xFF80, 0b010)
+ # sign extend -128 (8 bits) = -128 (16 bits)
+ result = yield from receive()
+ assert result[0] == 0xFF80
+ # 5 - 5 = 0
+ # 0 == 0 => CR = 0b001
+ result = yield from receive()
+ assert result == (0, 0b001)
+
+ sim.add_sync_process(producer)
+ sim.add_sync_process(consumer)
+ sim_writer = sim.write_vcd("test_alu_parallel.vcd")
+ with sim_writer:
+ sim.run()
+
+
+def write_alu_gtkw(gtkw_name, clk_period=1e-6, sub_module=None,
+ pysim=True):
+ """Common function to write the GTKWave documents for this module"""
+ gtkwave_desc = [
+ 'clk',
+ 'i1[15:0]',
+ 'i2[15:0]',
+ 'op__insn_type' if pysim else 'op__insn_type[6:0]',
+ 'op__invert_in',
+ 'i_valid',
+ 'o_ready',
+ 'o_valid',
+ 'i_ready',
+ 'alu_o[15:0]',
+ 'alu_o_ok',
+ 'alu_cr[15:0]',
+ 'alu_cr_ok'
+ ]
+ # determine the module name of the DUT
+ module = 'top'
+ if sub_module is not None:
+ module = nmigen_sim_top_module + sub_module
+ vcd_name = gtkw_name.replace('.gtkw', '.vcd')
+ write_gtkw(gtkw_name, vcd_name, gtkwave_desc, module=module,
+ loc=__file__, clk_period=clk_period, base='signed')
+
+
if __name__ == "__main__":
test_alu()
+ test_alu_parallel()
# alu = BranchALU(width=16)
# vl = rtlil.convert(alu, ports=alu.ports())
# with open("test_branch_alu.il", "w") as f:
# f.write(vl)
-