-# Proof of correctness for partitioned equal signal combiner
+# Proof of correctness for ALU pipeline, main stage
# Copyright (C) 2020 Michael Nolan <mtnolan2640@gmail.com>
+"""
+Links:
+* https://bugs.libre-soc.org/show_bug.cgi?id=306
+* https://bugs.libre-soc.org/show_bug.cgi?id=305
+* https://bugs.libre-soc.org/show_bug.cgi?id=343
+"""
from nmigen import (Module, Signal, Elaboratable, Mux, Cat, Repl,
signed)
from nmigen.asserts import Assert, AnyConst, Assume, Cover
-from nmigen.test.utils import FHDLTestCase
+from nmutil.formaltest import FHDLTestCase
from nmigen.cli import rtlil
from soc.fu.alu.main_stage import ALUMainStage
from soc.fu.alu.pipe_data import ALUPipeSpec
from soc.fu.alu.alu_input_record import CompALUOpSubset
-from soc.decoder.power_enums import InternalOp
+from openpower.decoder.power_enums import MicrOp
import unittest
width = p.width
comb += p.eq(AnyConst(width))
- pspec = ALUPipeSpec(id_wid=2)
+ pspec = ALUPipeSpec(id_wid=2, parent_pspec=None)
m.submodules.dut = dut = ALUMainStage(pspec)
# convenience variables
a = dut.i.a
b = dut.i.b
ca_in = dut.i.xer_ca[0] # CA carry in
- ca32_in = dut.i.xer_ca[1] # CA32 carry in 32
+ ca32_in = dut.i.xer_ca[1] # CA32 carry in 32
so_in = dut.i.xer_so # SO sticky overflow
ca_o = dut.o.xer_ca.data[0] # CA carry out
- ca32_o = dut.o.xer_ca.data[1] # CA32 carry out32
+ ca32_o = dut.o.xer_ca.data[1] # CA32 carry out32
ov_o = dut.o.xer_ov.data[0] # OV overflow
- ov32_o = dut.o.xer_ov.data[1] # OV32 overflow32
+ ov32_o = dut.o.xer_ov.data[1] # OV32 overflow32
o = dut.o.o.data
# setup random inputs
ca_in.eq(AnyConst(0b11)),
so_in.eq(AnyConst(1))]
+ # and for the context muxid
+ width = dut.i.ctx.muxid.width
+ comb += dut.i.ctx.muxid.eq(AnyConst(width))
+
+ # assign the PowerDecode2 operation subset
comb += dut.i.ctx.op.eq(rec)
- # Assert that op gets copied from the input to output
- for rec_sig in rec.ports():
- name = rec_sig.name
- dut_sig = getattr(dut.o.ctx.op, name)
- comb += Assert(dut_sig == rec_sig)
+ # check that the operation (op) is passed through (and muxid)
+ comb += Assert(dut.o.ctx.op == dut.i.ctx.op)
+ comb += Assert(dut.o.ctx.muxid == dut.i.ctx.muxid)
# signed and signed/32 versions of input a
a_signed = Signal(signed(64))
comb += a_signed.eq(a)
comb += a_signed_32.eq(a[0:32])
- comb += Assume(a[32:64] == 0)
- comb += Assume(b[32:64] == 0)
+ # do not check MSBs of a/b in 32-bit mode
+ with m.If(rec.is_32bit):
+ comb += Assume(a[32:64] == 0)
+ comb += Assume(b[32:64] == 0)
+ # Data.ok checking. these only to be valid when there is a change
+ # in the output that needs to go into a regfile
o_ok = Signal()
- comb += o_ok.eq(1) # will be set to zero if no op takes place
+ cr0_ok = Signal()
+ ov_ok = Signal()
+ ca_ok = Signal()
+ comb += cr0_ok.eq(0)
+ comb += ov_ok.eq(0)
+ comb += ca_ok.eq(0)
# main assertion of arithmetic operations
with m.Switch(rec.insn_type):
- with m.Case(InternalOp.OP_ADD):
+ with m.Case(MicrOp.OP_ADD):
+ # check result of 65-bit add-with-carry
comb += Assert(Cat(o, ca_o) == (a + b + ca_in))
# CA32 - XXX note this fails! replace with ca_in and it works
comb += Assert((a[0:32] + b[0:32] + ca_in)[32] == ca32_o)
- # From microwatt execute1.vhdl line 130
+ # From microwatt execute1.vhdl line 130, calc_ov() function
comb += Assert(ov_o == ((ca_o ^ o[-1]) & ~(a[-1] ^ b[-1])))
comb += Assert(ov32_o == ((ca32_o ^ o[31]) & ~(a[31] ^ b[31])))
+ comb += ov_ok.eq(1)
+ comb += ca_ok.eq(1)
+ comb += o_ok.eq(1)
- with m.Case(InternalOp.OP_EXTS):
+ with m.Case(MicrOp.OP_EXTS):
for i in [1, 2, 4]:
with m.If(rec.data_len == i):
+ # main part, then sign-bit replicated up
comb += Assert(o[0:i*8] == a[0:i*8])
comb += Assert(o[i*8:64] == Repl(a[i*8-1], 64-(i*8)))
+ comb += o_ok.eq(1)
- with m.Case(InternalOp.OP_CMP):
+ with m.Case(MicrOp.OP_CMP):
# CMP is defined as not taking in carry
comb += Assume(ca_in == 0)
comb += Assert(o == (a+b)[0:64])
- with m.Case(InternalOp.OP_CMPEQB):
+ with m.Case(MicrOp.OP_CMPEQB):
src1 = a[0:8]
eqs = Signal(8)
for i in range(8):
comb += eqs[i].eq(src1 == b[i*8:(i+1)*8])
- comb += Assert(dut.o.cr0[2] == eqs.any())
-
- with m.Default():
- comb += o_ok.eq(0)
+ comb += Assert(dut.o.cr0.data[2] == eqs.any())
+ comb += cr0_ok.eq(1)
# check that data ok was only enabled when op actioned
comb += Assert(dut.o.o.ok == o_ok)
+ comb += Assert(dut.o.cr0.ok == cr0_ok)
+ comb += Assert(dut.o.xer_ov.ok == ov_ok)
+ comb += Assert(dut.o.xer_ca.ok == ca_ok)
return m
module = Driver()
self.assertFormal(module, mode="bmc", depth=2)
self.assertFormal(module, mode="cover", depth=2)
+
def test_ilang(self):
dut = Driver()
vl = rtlil.convert(dut, ports=[])