-from nmigen import Module, Signal
-from nmigen.back.pysim import Simulator, Delay, Settle
-from nmutil.formaltest import FHDLTestCase
-from nmigen.cli import rtlil
+import random
+from soc.fu.shift_rot.pipe_data import ShiftRotPipeSpec
+from soc.fu.shift_rot.pipeline import ShiftRotBasePipe
+from openpower.test.common import TestAccumulatorBase, TestCase, ALUHelpers
+from openpower.endian import bigendian
+from openpower.decoder.isa.all import ISA
+from openpower.simulator.program import Program
+from openpower.decoder.power_enums import (XER_bits, Function, CryIn)
+from openpower.decoder.power_decoder2 import (PowerDecode2)
+from openpower.decoder.power_decoder import (create_pdecode)
import unittest
-from soc.decoder.isa.caller import ISACaller, special_sprs
-from soc.decoder.power_decoder import (create_pdecode)
-from soc.decoder.power_decoder2 import (PowerDecode2)
-from soc.decoder.power_enums import (XER_bits, Function, CryIn)
-from soc.decoder.selectable_int import SelectableInt
-from soc.simulator.program import Program
-from soc.decoder.isa.all import ISA
+from nmigen.cli import rtlil
+from nmigen import Module, Signal
+# 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, Settle
-from soc.fu.test.common import TestCase
-from soc.fu.shift_rot.pipeline import ShiftRotBasePipe
-from soc.fu.alu.alu_input_record import CompALUOpSubset
-from soc.fu.shift_rot.pipe_data import ShiftRotPipeSpec
-import random
+from openpower.test.shift_rot.shift_rot_cases import ShiftRotTestCase
def get_cu_inputs(dec2, sim):
"""
res = {}
- # RA
- reg1_ok = yield dec2.e.read_reg1.ok
- if reg1_ok:
- data1 = yield dec2.e.read_reg1.data
- res['ra'] = sim.gpr(data1).value
-
- # RB
- reg2_ok = yield dec2.e.read_reg2.ok
- if reg2_ok:
- data2 = yield dec2.e.read_reg2.data
- res['rb'] = sim.gpr(data2).value
-
- # RS (RC)
- reg3_ok = yield dec2.e.read_reg3.ok
- if reg3_ok:
- data3 = yield dec2.e.read_reg3.data
- res['rc'] = sim.gpr(data3).value
-
- # XER.ca
- cry_in = yield dec2.e.input_carry
- if cry_in == CryIn.CA.value:
- carry = 1 if sim.spr['XER'][XER_bits['CA']] else 0
- carry32 = 1 if sim.spr['XER'][XER_bits['CA32']] else 0
- res['xer_ca'] = carry | (carry32<<1)
-
- print ("inputs", res)
+ yield from ALUHelpers.get_sim_int_ra(res, sim, dec2) # RA
+ yield from ALUHelpers.get_sim_int_rb(res, sim, dec2) # RB
+ yield from ALUHelpers.get_sim_int_rc(res, sim, dec2) # RC
+ yield from ALUHelpers.get_rd_sim_xer_ca(res, sim, dec2) # XER.ca
+ yield from ALUHelpers.get_sim_xer_so(res, sim, dec2) # XER.so
+
+ print("alu get_cu_inputs", res)
return res
def set_alu_inputs(alu, dec2, sim):
# TODO: see https://bugs.libre-soc.org/show_bug.cgi?id=305#c43
# detect the immediate here (with m.If(self.i.ctx.op.imm_data.imm_ok))
- # and place it into data_i.b
+ # and place it into i_data.b
inp = yield from get_cu_inputs(dec2, sim)
- if 'ra' in inp:
- yield alu.p.data_i.a.eq(inp['ra'])
- else:
- yield alu.p.data_i.a.eq(0)
- if 'rb' in inp:
- yield alu.p.data_i.rb.eq(inp['rb'])
- else:
- yield alu.p.data_i.rb.eq(0)
- if 'rc' in inp:
- yield alu.p.data_i.rs.eq(inp['rc'])
- else:
- yield alu.p.data_i.rs.eq(0)
-
- # If there's an immediate, set the B operand to that
- imm_ok = yield dec2.e.imm_data.imm_ok
- if imm_ok:
- data2 = yield dec2.e.imm_data.imm
- yield alu.p.data_i.rb.eq(data2)
-
- if 'xer_ca' in inp:
- yield alu.p.data_i.xer_ca.eq(inp['xer_ca'])
- print ("extra inputs: CA/32", bin(inp['xer_ca']))
- else:
- yield alu.p.data_i.xer_ca.eq(0)
+ yield from ALUHelpers.set_int_ra(alu, dec2, inp)
+ yield from ALUHelpers.set_int_rb(alu, dec2, inp)
+ yield from ALUHelpers.set_int_rc(alu, dec2, inp)
+ yield from ALUHelpers.set_xer_ca(alu, dec2, inp)
+ yield from ALUHelpers.set_xer_so(alu, dec2, inp)
# This test bench is a bit different than is usual. Initially when I
# takes around 3 seconds
-class ShiftRotTestCase(FHDLTestCase):
- test_data = []
- def __init__(self, name):
- super().__init__(name)
- self.test_name = name
-
- def run_tst_program(self, prog, initial_regs=None, initial_sprs=None):
- tc = TestCase(prog, self.test_name, initial_regs, initial_sprs)
- self.test_data.append(tc)
-
- def test_shift(self):
- insns = ["slw", "sld", "srw", "srd", "sraw", "srad"]
- for i in range(20):
- choice = random.choice(insns)
- lst = [f"{choice} 3, 1, 2"]
- initial_regs = [0] * 32
- initial_regs[1] = random.randint(0, (1<<64)-1)
- initial_regs[2] = random.randint(0, 63)
- print(initial_regs[1], initial_regs[2])
- self.run_tst_program(Program(lst), initial_regs)
-
- def test_shift_arith(self):
- lst = ["sraw 3, 1, 2"]
- initial_regs = [0] * 32
- initial_regs[1] = random.randint(0, (1<<64)-1)
- initial_regs[2] = random.randint(0, 63)
- print(initial_regs[1], initial_regs[2])
- self.run_tst_program(Program(lst), initial_regs)
-
- def test_shift_once(self):
- lst = ["slw 3, 1, 4",
- "slw 3, 1, 2"]
- initial_regs = [0] * 32
- initial_regs[1] = 0x80000000
- initial_regs[2] = 0x40
- initial_regs[4] = 0x00
- self.run_tst_program(Program(lst), initial_regs)
-
- def test_rlwinm(self):
- for i in range(10):
- mb = random.randint(0,31)
- me = random.randint(0,31)
- sh = random.randint(0,31)
- lst = [f"rlwinm 3, 1, {mb}, {me}, {sh}",
- #f"rlwinm. 3, 1, {mb}, {me}, {sh}"
- ]
- initial_regs = [0] * 32
- initial_regs[1] = random.randint(0, (1<<64)-1)
- self.run_tst_program(Program(lst), initial_regs)
-
- def test_rlwimi(self):
- lst = ["rlwimi 3, 1, 5, 20, 6"]
- initial_regs = [0] * 32
- initial_regs[1] = 0xdeadbeef
- initial_regs[3] = 0x12345678
- self.run_tst_program(Program(lst), initial_regs)
-
- def test_rlwnm(self):
- lst = ["rlwnm 3, 1, 2, 20, 6"]
- initial_regs = [0] * 32
- initial_regs[1] = random.randint(0, (1<<64)-1)
- initial_regs[2] = random.randint(0, 63)
- self.run_tst_program(Program(lst), initial_regs)
-
- def test_rldicl(self):
- lst = ["rldicl 3, 1, 5, 20"]
- initial_regs = [0] * 32
- initial_regs[1] = random.randint(0, (1<<64)-1)
- self.run_tst_program(Program(lst), initial_regs)
-
- def test_rldicr(self):
- lst = ["rldicr 3, 1, 5, 20"]
- initial_regs = [0] * 32
- initial_regs[1] = random.randint(0, (1<<64)-1)
- self.run_tst_program(Program(lst), initial_regs)
-
- def test_rlc(self):
- insns = ["rldic", "rldicl", "rldicr"]
- for i in range(20):
- choice = random.choice(insns)
- sh = random.randint(0, 63)
- m = random.randint(0, 63)
- lst = [f"{choice} 3, 1, {sh}, {m}"]
- initial_regs = [0] * 32
- initial_regs[1] = random.randint(0, (1<<64)-1)
- self.run_tst_program(Program(lst), initial_regs)
-
- def test_ilang(self):
+class ShiftRotIlangCase(TestAccumulatorBase):
+
+ def case_ilang(self):
pspec = ShiftRotPipeSpec(id_wid=2)
+ pspec.draft_bitmanip = True
alu = ShiftRotBasePipe(pspec)
vl = rtlil.convert(alu, ports=alu.ports())
- with open("pipeline.il", "w") as f:
+ with open("shift_rot_pipeline.il", "w") as f:
f.write(vl)
-class TestRunner(FHDLTestCase):
+class TestRunner(unittest.TestCase):
def __init__(self, test_data):
super().__init__("run_all")
self.test_data = test_data
+ def execute(self, alu, instruction, pdecode2, test):
+ program = test.program
+ simulator = 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()))
+
+ index = simulator.pc.CIA.value//4
+ while index < len(instructions):
+ ins, code = instructions[index]
+
+ print("0x{:X}".format(ins & 0xffffffff))
+ print(code)
+
+ # ask the decoder to decode this binary data (endian'd)
+ yield pdecode2.dec.bigendian.eq(bigendian) # little / big?
+ yield instruction.eq(ins) # raw binary instr.
+ yield Settle()
+ fn_unit = yield pdecode2.e.do.fn_unit
+ self.assertEqual(fn_unit, Function.SHIFT_ROT.value)
+ yield from set_alu_inputs(alu, pdecode2, simulator)
+
+ # set valid for one cycle, propagate through pipeline...
+ yield alu.p.i_valid.eq(1)
+ yield
+ yield alu.p.i_valid.eq(0)
+
+ opname = code.split(' ')[0]
+ yield from simulator.call(opname)
+ index = simulator.pc.CIA.value//4
+
+ vld = yield alu.n.o_valid
+ while not vld:
+ yield
+ vld = yield alu.n.o_valid
+ yield
+ alu_out = yield alu.n.o_data.o.data
+
+ yield from self.check_alu_outputs(alu, pdecode2,
+ simulator, code)
+ yield Settle()
+
def run_all(self):
m = Module()
comb = m.d.comb
instruction = Signal(32)
- pdecode = create_pdecode()
+ fn_name = "SHIFT_ROT"
+ opkls = ShiftRotPipeSpec.opsubsetkls
- m.submodules.pdecode2 = pdecode2 = PowerDecode2(pdecode)
+ m.submodules.pdecode2 = pdecode2 = PowerDecode2(None, opkls, fn_name)
+ pdecode = pdecode2.dec
pspec = ShiftRotPipeSpec(id_wid=2)
+ pspec.draft_bitmanip = True
m.submodules.alu = alu = ShiftRotBasePipe(pspec)
- comb += alu.p.data_i.ctx.op.eq_from_execute1(pdecode2.e)
- comb += alu.p.valid_i.eq(1)
- comb += alu.n.ready_i.eq(1)
+ comb += alu.p.i_data.ctx.op.eq_from_execute1(pdecode2.do)
+ comb += alu.n.i_ready.eq(1)
comb += pdecode2.dec.raw_opcode_in.eq(instruction)
sim = Simulator(m)
sim.add_clock(1e-6)
+
def process():
for test in self.test_data:
print(test.name)
program = test.program
- self.subTest(test.name)
- simulator = ISA(pdecode2, test.regs, test.sprs, 0)
- gen = program.generate_instructions()
- instructions = list(zip(gen, program.assembly.splitlines()))
-
- index = simulator.pc.CIA.value//4
- while index < len(instructions):
- ins, code = instructions[index]
-
- print("0x{:X}".format(ins & 0xffffffff))
- print(code)
-
- # ask the decoder to decode this binary data (endian'd)
- yield pdecode2.dec.bigendian.eq(0) # little / big?
- yield instruction.eq(ins) # raw binary instr.
- yield Settle()
- fn_unit = yield pdecode2.e.fn_unit
- self.assertEqual(fn_unit, Function.SHIFT_ROT.value)
- yield from set_alu_inputs(alu, pdecode2, simulator)
- yield
- opname = code.split(' ')[0]
- yield from simulator.call(opname)
- index = simulator.pc.CIA.value//4
-
- vld = yield alu.n.valid_o
- while not vld:
- yield
- vld = yield alu.n.valid_o
- yield
- alu_out = yield alu.n.data_o.o.data
- out_reg_valid = yield pdecode2.e.write_reg.ok
- if out_reg_valid:
- write_reg_idx = yield pdecode2.e.write_reg.data
- expected = simulator.gpr(write_reg_idx).value
- msg = f"expected {expected:x}, actual: {alu_out:x}"
- self.assertEqual(expected, alu_out, msg)
- yield from self.check_extra_alu_outputs(alu, pdecode2,
- simulator)
- break
+ with self.subTest(test.name):
+ yield from self.execute(alu, instruction, pdecode2, test)
sim.add_sync_process(process)
- with sim.write_vcd("simulator.vcd", "simulator.gtkw",
- traces=[]):
+ with sim.write_vcd("shift_rot_simulator.vcd"):
sim.run()
- def check_extra_alu_outputs(self, alu, dec2, sim):
- rc = yield dec2.e.rc.data
+ def check_alu_outputs(self, alu, dec2, sim, code):
+
+ rc = yield dec2.e.do.rc.rc
+ cridx_ok = yield dec2.e.write_cr.ok
+ cridx = yield dec2.e.write_cr.data
+
+ print("check extra output", repr(code), cridx_ok, cridx)
if rc:
- cr_expected = sim.crl[0].get_range().value
- cr_actual = yield alu.n.data_o.cr0
- self.assertEqual(cr_expected, cr_actual)
+ self.assertEqual(cridx, 0, code)
+
+ sim_o = {}
+ res = {}
+
+ yield from ALUHelpers.get_cr_a(res, alu, dec2)
+ yield from ALUHelpers.get_xer_ca(res, alu, dec2)
+ yield from ALUHelpers.get_int_o(res, alu, dec2)
+
+ print("hw outputs", res)
+
+ yield from ALUHelpers.get_sim_int_o(sim_o, sim, dec2)
+ yield from ALUHelpers.get_wr_sim_cr_a(sim_o, sim, dec2)
+ yield from ALUHelpers.get_wr_sim_xer_ca(sim_o, sim, dec2)
+
+ print("sim outputs", sim_o)
+
+ ALUHelpers.check_cr_a(self, res, sim_o, "CR%d %s" % (cridx, code))
+ ALUHelpers.check_xer_ca(self, res, sim_o, code)
+ ALUHelpers.check_int_o(self, res, sim_o, code)
if __name__ == "__main__":
unittest.main(exit=False)
suite = unittest.TestSuite()
- suite.addTest(TestRunner(ShiftRotTestCase.test_data))
+ suite.addTest(TestRunner(ShiftRotTestCase().test_data))
+ suite.addTest(TestRunner(ShiftRotIlangCase().test_data))
runner = unittest.TextTestRunner()
runner.run(suite)