from nmutil.formaltest import FHDLTestCase
from nmigen.cli import rtlil
import unittest
-from teststate import SimState, HDLState, TestState
+from openpower.test.state import (SimState, teststate_check_regs,
+ teststate_check_mem)
+from soc.simple.test.teststate import HDLState
from openpower.decoder.isa.caller import special_sprs
from openpower.decoder.power_decoder import create_pdecode
from openpower.decoder.power_decoder2 import PowerDecode2
from openpower.decoder.selectable_int import SelectableInt
from openpower.decoder.isa.all import ISA
+from openpower.decoder.decode2execute1 import IssuerDecode2ToOperand
+from openpower.state import CoreState
# note that using SPRreduced has to be done to match the
# PowerDecoder2 SPR map
from openpower.decoder.power_enums import spr_dict, Function, XER_bits
from soc.config.test.test_loadstore import TestMemPspec
from openpower.endian import bigendian
+from soc.regfile.regfiles import StateRegs
from soc.simple.core import NonProductionCore
from soc.experiment.compalu_multi import find_ok # hack
from soc.fu.cr.test.test_pipe_caller import CRTestCase
from soc.fu.branch.test.test_pipe_caller import BranchTestCase
from soc.fu.ldst.test.test_pipe_caller import LDSTTestCase
-from openpower.util import spr_to_fast_reg
+from openpower.test.general.overlap_hazards import (HazardTestCase,
+ RandomHazardTestCase)
+from openpower.util import spr_to_fast_reg, spr_to_state_reg
+
+from openpower.consts import StateRegsEnum
# list of SPRs that are controlled and managed by the MMU
-mmu_sprs = ["PRTBL", "DSISR", "DAR", "PIDR"]
+mmu_sprs = ["PRTBL", "PIDR"]
+ldst_sprs = ["DAR", "DSISR"]
def set_mmu_spr(name, i, val, core): # important keep pep8 formatting
yield fsm.mmu.l_in.rs.eq(val)
yield
yield fsm.mmu.l_in.mtspr.eq(0)
- print("mmu_spr was updated")
+ while True:
+ done = yield fsm.mmu.l_out.done
+ if done:
+ break
+ yield
+ yield
+ print("mmu_spr %s %d was updated %x" % (name, i, val))
+
+
+def set_ldst_spr(name, i, val, core): # important keep pep8 formatting
+ ldst = core.fus.get_fu("mmu0").alu.ldst # awkward to get at but it works
+ yield ldst.sprval_in.eq(val)
+ yield ldst.mmu_set_spr.eq(1)
+ if name == 'DAR':
+ yield ldst.mmu_set_dar.eq(1)
+ yield
+ yield ldst.mmu_set_dar.eq(0)
+ else:
+ yield ldst.mmu_set_dsisr.eq(1)
+ yield
+ yield ldst.mmu_set_dsisr.eq(0)
+ yield ldst.mmu_set_spr.eq(0)
+ print("ldst_spr %s %d was updated %x" % (name, i, val))
def setup_regs(pdecode2, core, test):
yield intregs.memory._array[i].eq(test.regs[i])
yield Settle()
+ # set up MSR in STATE regfile, "direct" write (bypass rd/write ports)
+ stateregs = core.regs.state
+ yield stateregs.regs[StateRegsEnum.MSR].reg.eq(test.msr)
+
# set up CR regfile, "direct" write across all CRs
cr = test.cr
crregs = core.regs.cr
# setting both fast and slow SPRs from test data
fregs = core.regs.fast
+ stateregs = core.regs.state
sregs = core.regs.spr
for sprname, val in test.sprs.items():
if isinstance(val, SelectableInt):
sprname = spr_dict[sprname].SPR
if sprname == 'XER':
continue
+ print ('set spr %s val %x' % (sprname, val))
+
fast = spr_to_fast_reg(sprname)
- if fast is None:
+ state = spr_to_state_reg(sprname)
+
+ if fast is None and state is None:
# match behaviour of SPRMap in power_decoder2.py
for i, x in enumerate(SPR):
if sprname == x.name:
- print("setting slow SPR %d (%s) to %x" %
- (i, sprname, val))
- if sprname not in mmu_sprs:
- yield sregs.memory._array[i].eq(val)
+ print("setting slow SPR %d (%s/%d) to %x" %
+ (i, sprname, x.value, val))
+ if sprname in mmu_sprs:
+ yield from set_mmu_spr(sprname, x.value, val, core)
+ elif sprname in ldst_sprs:
+ yield from set_ldst_spr(sprname, x.value, val, core)
else:
- yield from set_mmu_spr(sprname, i, val, core)
+ yield sregs.memory._array[i].eq(val)
+ elif state is not None:
+ print("setting state reg %d (%s) to %x" %
+ (state, sprname, val))
+ if stateregs.unary:
+ rval = stateregs.regs[state].reg
+ else:
+ rval = stateregs.memory._array[state]
+ yield rval.eq(val)
else:
print("setting fast reg %d (%s) to %x" %
(fast, sprname, val))
print("oe:", oe, oe_ok)
-def teststate_check_regs(dut, states, test, code):
- """teststate_check_regs: compares a set of Power ISA objects
- to check if they have the same "state" (registers only, at the moment)
- """
- slist = []
- for stype, totest in states.items():
- state = yield from TestState(stype, totest, dut, code)
- slist.append(state)
- for i in range(len(slist)-1):
- state, against = slist[i], slist[i+1]
- state.compare(against)
-
-
def check_regs(dut, sim, core, test, code):
# create the two states and compare
testdic = {'sim': sim, 'hdl': core}
yield from teststate_check_regs(dut, testdic, test, code)
+def check_mem(dut, sim, core, test, code):
+ # create the two states and compare mem
+ testdic = {'sim': sim, 'hdl': core}
+ yield from teststate_check_mem(dut, testdic, test, code)
+
+
def wait_for_busy_hi(cu):
while True:
busy_o = yield cu.busy_o
def wait_for_busy_clear(cu):
while True:
- busy_o = yield cu.busy_o
- terminate_o = yield cu.core_terminate_o
+ busy_o = yield cu.o.busy_o
+ terminate_o = yield cu.o.core_terminate_o
if not busy_o:
print("busy/terminate:", busy_o, terminate_o)
break
m = Module()
comb = m.d.comb
instruction = Signal(32)
- ivalid_i = Signal()
+
+ units = {'alu': 3, 'cr': 1, 'branch': 1, 'trap': 1,
+ 'spr': 1,
+ 'logical': 1,
+ 'mul': 3,
+ 'div': 1, 'shiftrot': 1}
pspec = TestMemPspec(ldst_ifacetype='testpi',
imem_ifacetype='',
addr_wid=48,
mask_wid=8,
+ units=units,
+ allow_overlap=True,
reg_wid=64)
+ cur_state = CoreState("cur") # current state (MSR/PC/SVSTATE)
+ pdecode2 = PowerDecode2(None, state=cur_state,
+ #opkls=IssuerDecode2ToOperand,
+ svp64_en=True, # self.svp64_en,
+ regreduce_en=False, #self.regreduce_en
+ )
+
m.submodules.core = core = NonProductionCore(pspec)
- pdecode2 = core.pdecode2
+ m.submodules.pdecode2 = pdecode2
+ core.pdecode2 = pdecode2
l0 = core.l0
- comb += core.raw_opcode_i.eq(instruction)
- comb += core.ivalid_i.eq(ivalid_i)
+ comb += pdecode2.dec.raw_opcode_in.eq(instruction)
+ comb += pdecode2.dec.bigendian.eq(bigendian) # little / big?
+ comb += core.i.e.eq(pdecode2.e)
+ comb += core.i.state.eq(cur_state)
+ comb += core.i.raw_insn_i.eq(instruction)
+ comb += core.i.bigendian_i.eq(bigendian)
+
+ # set the PC StateRegs read port to always send back the PC
+ stateregs = core.regs.state
+ pc_regnum = StateRegs.PC
+ comb += stateregs.r_ports['cia'].ren.eq(1<<pc_regnum)
# temporary hack: says "go" immediately for both address gen and ST
ldst = core.fus.fus['ldst0']
- m.d.comb += ldst.ad.go.eq(ldst.ad.rel) # link addr-go direct to rel
- m.d.comb += ldst.st.go.eq(ldst.st.rel) # link store-go direct to rel
+ m.d.comb += ldst.ad.go_i.eq(ldst.ad.rel_o) # link addr-go to rel
+ m.d.comb += ldst.st.go_i.eq(ldst.st.rel_o) # link store-go to rel
# nmigen Simulation
sim = Simulator(m)
sim.add_clock(1e-6)
def process():
- yield core.issue_i.eq(0)
yield
for test in self.test_data:
print(test.name)
program = test.program
- self.subTest(test.name)
- sim = ISA(pdecode2, test.regs, test.sprs, test.cr, test.mem,
- test.msr,
- bigendian=bigendian)
- gen = program.generate_instructions()
- instructions = list(zip(gen, program.assembly.splitlines()))
-
- yield from setup_tst_memory(l0, sim)
- yield from setup_regs(core, test)
-
- index = sim.pc.CIA.value // 4
- while index < len(instructions):
- ins, code = instructions[index]
-
- print("instruction: 0x{:X}".format(ins & 0xffffffff))
- print(code)
-
- # ask the decoder to decode this binary data (endian'd)
- yield core.bigendian_i.eq(bigendian) # little / big?
- yield instruction.eq(ins) # raw binary instr.
- yield ivalid_i.eq(1)
- yield Settle()
- # fn_unit = yield pdecode2.e.fn_unit
- #fuval = self.funit.value
- #self.assertEqual(fn_unit & fuval, fuval)
-
- # set operand and get inputs
- yield from set_issue(core, pdecode2, sim)
- yield Settle()
-
- yield from wait_for_busy_clear(core)
- yield ivalid_i.eq(0)
- yield
-
- print("sim", code)
- # call simulated operation
- opname = code.split(' ')[0]
- yield from sim.call(opname)
- index = sim.pc.CIA.value // 4
+ with self.subTest(test.name):
+ sim = ISA(pdecode2, test.regs, test.sprs, test.cr,
+ test.mem,
+ test.msr,
+ bigendian=bigendian)
+ gen = program.generate_instructions()
+ instructions = list(zip(gen, program.assembly.splitlines()))
- # register check
- yield from check_regs(self, sim, core, test, code)
+ yield from setup_tst_memory(l0, test.mem)
+ yield from setup_regs(pdecode2, core, test)
- # Memory check
- yield from check_sim_memory(self, l0, sim, code)
+ index = sim.pc.CIA.value // 4
+ while index < len(instructions):
+ ins, code = instructions[index]
+
+ print("instruction: 0x{:X}".format(ins & 0xffffffff))
+ print(code)
+
+ # ask the decoder to decode this binary data (endian'd)
+ yield instruction.eq(ins) # raw binary instr.
+ yield Settle()
+
+ print("sim", code)
+ # call simulated operation
+ opname = code.split(' ')[0]
+ yield from sim.call(opname)
+ pc = sim.pc.CIA.value
+ nia = sim.pc.NIA.value
+ index = pc // 4
+
+ # set the PC to the same simulated value
+ # (core is not able to do this itself, except
+ # for branch / TRAP)
+ print ("after call, pc nia", pc, nia)
+ yield stateregs.regs[pc_regnum].reg.eq(pc)
+ yield Settle()
+
+ yield core.p.i_valid.eq(1)
+ yield
+ o_ready = yield core.p.o_ready
+ while True:
+ if o_ready:
+ break
+ yield
+ o_ready = yield core.p.o_ready
+ yield core.p.i_valid.eq(0)
+
+ # set operand and get inputs
+ yield from wait_for_busy_clear(core)
+
+ # synchronised (non-overlap) is fine to check
+ if not core.allow_overlap:
+ # register check
+ yield from check_regs(self, sim, core, test, code)
+
+ # Memory check
+ yield from check_mem(self, sim, core, test, code)
+
+ # non-overlap mode is only fine to check right at the end
+ if core.allow_overlap:
+ # wait until all settled
+ # XXX really this should be in DMI, which should in turn
+ # use issuer.any_busy to not send back "stopped" signal
+ while (yield core.o.any_busy_o):
+ yield
+ yield Settle()
+
+ # register check
+ yield from check_regs(self, sim, core, test, code)
+
+ # Memory check
+ yield from check_mem(self, sim, core, test, code)
+
+ # give a couple extra clock cycles for gtkwave display to be happy
+ yield
+ yield
sim.add_sync_process(process)
with sim.write_vcd("core_simulator.vcd", "core_simulator.gtkw",
if __name__ == "__main__":
unittest.main(exit=False)
suite = unittest.TestSuite()
- suite.addTest(TestRunner(LDSTTestCase().test_data))
- suite.addTest(TestRunner(CRTestCase().test_data))
- suite.addTest(TestRunner(ShiftRotTestCase().test_data))
- suite.addTest(TestRunner(LogicalTestCase().test_data))
- suite.addTest(TestRunner(ALUTestCase().test_data))
- suite.addTest(TestRunner(BranchTestCase().test_data))
+ suite.addTest(TestRunner(HazardTestCase().test_data))
+ suite.addTest(TestRunner(RandomHazardTestCase().test_data))
+ #suite.addTest(TestRunner(LDSTTestCase().test_data))
+ #suite.addTest(TestRunner(CRTestCase().test_data))
+ #suite.addTest(TestRunner(ShiftRotTestCase().test_data))
+ #suite.addTest(TestRunner(LogicalTestCase().test_data))
+ #suite.addTest(TestRunner(ALUTestCase().test_data))
+ #suite.addTest(TestRunner(BranchTestCase().test_data))
runner = unittest.TextTestRunner()
runner.run(suite)