only one cycle (sync)
"""
-from nmigen import Elaboratable, Signal, Module, Const, Mux
+from nmigen import Elaboratable, Signal, Module, Const, Mux, Array
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 soc.decoder.power_enums import InternalOp, CryIn
+from soc.decoder.power_enums import InternalOp, Function, CryIn
+
+from soc.fu.alu.alu_input_record import CompALUOpSubset
import operator
-class CompALUOpSubset(Record):
- """CompALUOpSubset
-
- a copy of the relevant subset information from Decode2Execute1Type
- needed for ALU operations. use with eq_from_execute1 (below) to
- grab subsets.
- """
- def __init__(self):
- layout = (('insn_type', InternalOp),
- ('nia', 64),
- ('imm_data', Layout((("imm", 64), ("imm_ok", 1)))),
- #'cr = Signal(32, reset_less=True) # NO: this is from the CR SPR
- #'xerc = XerBits() # NO: this is from the XER SPR
- ('lk', 1),
- ('rc', Layout((("rc", 1), ("rc_ok", 1)))),
- ('oe', Layout((("oe", 1), ("oe_ok", 1)))),
- ('invert_a', 1),
- ('invert_out', 1),
- ('input_carry', CryIn),
- ('output_carry', 1),
- ('input_cr', 1),
- ('output_cr', 1),
- ('is_32bit', 1),
- ('is_signed', 1),
- ('byte_reverse', 1),
- ('sign_extend', 1))
-
- Record.__init__(self, Layout(layout))
-
- # grrr. Record does not have kwargs
- self.insn_type.reset_less = True
- self.nia.reset_less = True
- #self.cr = Signal(32, reset_less = True
- #self.xerc = XerBits(
- self.lk.reset_less = True
- self.invert_a.reset_less = True
- self.invert_out.reset_less = True
- self.input_carry.reset_less = True
- self.output_carry.reset_less = True
- self.input_cr.reset_less = True
- self.output_cr.reset_less = True
- self.is_32bit.reset_less = True
- self.is_signed.reset_less = True
- self.byte_reverse.reset_less = True
- self.sign_extend.reset_less = True
-
- def eq_from_execute1(self, other):
- """ use this to copy in from Decode2Execute1Type
- """
- res = []
- for fname, sig in self.fields.items():
- eqfrom = other.fields[fname]
- res.append(sig.eq(eqfrom)
- return res
- def ports(self):
- return [self.insn_type,
- self.nia,
- #self.cr,
- #self.xerc,
- self.lk,
- self.invert_a,
- self.invert_out,
- self.input_carry,
- self.output_carry,
- self.input_cr,
- self.output_cr,
- self.is_32bit,
- self.is_signed,
- self.byte_reverse,
- self.sign_extend,
- ]
class Adder(Elaboratable):
def __init__(self, width):
m.d.comb += self.o.eq(self.a >> btrunc)
return m
+class Dummy:
+ pass
class ALU(Elaboratable):
def __init__(self, width):
- self.p_valid_i = Signal()
- self.p_ready_o = Signal()
- self.n_ready_i = Signal()
- self.n_valid_o = Signal()
+ 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 = CompALUOpSubset()
- self.a = Signal(width)
- self.b = Signal(width)
- self.o = Signal(width)
+ i = []
+ i.append(Signal(width, name="i1"))
+ i.append(Signal(width, name="i2"))
+ self.i = Array(i)
+ self.a, self.b = i[0], i[1]
+ self.out = Array([Signal(width)])
+ 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.n.data_o.o = self.o
def elaborate(self, platform):
m = Module()
go_now = Signal(reset_less=True) # testing no-delay ALU
- with m.If(self.p_valid_i):
+ with m.If(self.p.valid_i):
# input is valid. next check, if we already said "ready" or not
- with m.If(~self.p_ready_o):
+ with m.If(~self.p.ready_o):
# 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.ready_o.eq(1)
# as this is a "fake" pipeline, just grab the output right now
with m.If(self.op.insn_type == InternalOp.OP_ADD):
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.ready_o.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.valid_o.eq(1)
+ with m.If(self.n.ready_i & self.n.valid_o):
+ m.d.sync += self.n.valid_o.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
class BranchALU(Elaboratable):
def __init__(self, width):
- self.p_valid_i = Signal()
- self.p_ready_o = Signal()
- self.n_ready_i = Signal()
- self.n_valid_o = Signal()
+ 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.a = Signal(width)
- self.b = Signal(width)
- self.o = Signal(width)
+ i = []
+ i.append(Signal(width, name="i1"))
+ i.append(Signal(width, name="i2"))
+ self.i = Array(i)
+ self.a, self.b = i[0], i[1]
+ self.out = Array([Signal(width)])
+ self.o = self.out[0]
self.width = width
def elaborate(self, platform):
]
go_now = Signal(reset_less=True) # testing no-delay ALU
- with m.If(self.p_valid_i):
+ with m.If(self.p.valid_i):
# input is valid. next check, if we already said "ready" or not
- with m.If(~self.p_ready_o):
+ with m.If(~self.p.ready_o):
# 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.ready_o.eq(1)
# as this is a "fake" pipeline, just grab the output right now
with m.Switch(self.op):
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.ready_o.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.valid_o.eq(1)
+ with m.If(self.n.ready_i & self.n.valid_o):
+ m.d.sync += self.n.valid_o.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
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)
+ yield dut.n.ready_i.eq(0)
+ yield dut.p.valid_i.eq(1)
yield
while True:
yield
- n_valid_o = yield dut.n_valid_o
- if n_valid_o:
+ n.valid_o = yield dut.n.valid_o
+ if n.valid_o:
break
yield
result = yield dut.o
- yield dut.p_valid_i.eq(0)
- yield dut.n_ready_i.eq(0)
+ yield dut.p.valid_i.eq(0)
+ yield dut.n.ready_i.eq(0)
yield
return result