from soc.decoder.power_enums import Function, XER_bits
from soc.config.endian import bigendian
+from soc.decoder.power_decoder import create_pdecode
+from soc.decoder.power_decoder2 import PowerDecode2
+
from soc.simple.issuer import TestIssuer
-from soc.experiment.compalu_multi import find_ok # hack
+from soc.experiment.compalu_multi import find_ok # hack
from soc.config.test.test_loadstore import TestMemPspec
from soc.simple.test.test_core import (setup_regs, check_regs,
wait_for_busy_hi)
from soc.fu.compunits.test.test_compunit import (setup_test_memory,
check_sim_memory)
+from soc.debug.dmi import DBGCore, DBGCtrl, DBGStat
# test with ALU data and Logical data
-#from soc.fu.alu.test.test_pipe_caller import ALUTestCase
-#from soc.fu.div.test.test_pipe_caller import DivTestCase
-#from soc.fu.logical.test.test_pipe_caller import LogicalTestCase
+from soc.fu.alu.test.test_pipe_caller import ALUTestCase
+from soc.fu.div.test.test_pipe_caller import DivTestCases
+from soc.fu.logical.test.test_pipe_caller import LogicalTestCase
#from soc.fu.shift_rot.test.test_pipe_caller import ShiftRotTestCase
-#from soc.fu.cr.test.test_pipe_caller import CRTestCase
+from soc.fu.cr.test.test_pipe_caller import CRTestCase
#from soc.fu.branch.test.test_pipe_caller import BranchTestCase
#from soc.fu.spr.test.test_pipe_caller import SPRTestCase
from soc.fu.ldst.test.test_pipe_caller import LDSTTestCase
def setup_i_memory(imem, startaddr, instructions):
mem = imem
- print ("insn before, init mem", mem.depth, mem.width, mem,
- len(instructions))
+ print("insn before, init mem", mem.depth, mem.width, mem,
+ len(instructions))
for i in range(mem.depth):
yield mem._array[i].eq(0)
yield Settle()
- startaddr //= 4 # instructions are 32-bit
- mask = ((1<<64)-1)
+ startaddr //= 4 # instructions are 32-bit
+ if mem.width == 32:
+ mask = ((1 << 32)-1)
+ for ins in instructions:
+ if isinstance(ins, tuple):
+ insn, code = ins
+ else:
+ insn, code = ins, ''
+ insn = insn & 0xffffffff
+ yield mem._array[startaddr].eq(insn)
+ yield Settle()
+ if insn != 0:
+ print("instr: %06x 0x%x %s" % (4*startaddr, insn, code))
+ startaddr += 1
+ startaddr = startaddr & mask
+ return
+
+ # 64 bit
+ mask = ((1 << 64)-1)
for ins in instructions:
if isinstance(ins, tuple):
insn, code = ins
else:
insn, code = ins, ''
insn = insn & 0xffffffff
- msbs = (startaddr>>1) & mask
+ msbs = (startaddr >> 1) & mask
val = yield mem._array[msbs]
if insn != 0:
- print ("before set", hex(4*startaddr),
- hex(msbs), hex(val), hex(insn))
+ print("before set", hex(4*startaddr),
+ hex(msbs), hex(val), hex(insn))
lsb = 1 if (startaddr & 1) else 0
val = (val | (insn << (lsb*32)))
val = val & mask
yield mem._array[msbs].eq(val)
yield Settle()
if insn != 0:
- print ("after set", hex(4*startaddr), hex(msbs), hex(val))
- print ("instr: %06x 0x%x %s %08x" % (4*startaddr, insn, code, val))
+ print("after set", hex(4*startaddr), hex(msbs), hex(val))
+ print("instr: %06x 0x%x %s %08x" % (4*startaddr, insn, code, val))
startaddr += 1
startaddr = startaddr & mask
+def set_dmi(dmi, addr, data):
+ yield dmi.req_i.eq(1)
+ yield dmi.addr_i.eq(addr)
+ yield dmi.din.eq(data)
+ yield dmi.we_i.eq(1)
+ while True:
+ ack = yield dmi.ack_o
+ if ack:
+ break
+ yield
+ yield
+ yield dmi.req_i.eq(0)
+ yield dmi.addr_i.eq(0)
+ yield dmi.din.eq(0)
+ yield dmi.we_i.eq(0)
+ yield
+
+
+def get_dmi(dmi, addr):
+ yield dmi.req_i.eq(1)
+ yield dmi.addr_i.eq(addr)
+ yield dmi.din.eq(0)
+ yield dmi.we_i.eq(0)
+ while True:
+ ack = yield dmi.ack_o
+ if ack:
+ break
+ yield
+ yield # wait one
+ data = yield dmi.dout # get data after ack valid for 1 cycle
+ yield dmi.req_i.eq(0)
+ yield dmi.addr_i.eq(0)
+ yield dmi.we_i.eq(0)
+ yield
+ return data
+
+
class TestRunner(FHDLTestCase):
def __init__(self, tst_data):
super().__init__("run_all")
def run_all(self):
m = Module()
comb = m.d.comb
- go_insn_i = Signal()
pc_i = Signal(32)
pspec = TestMemPspec(ldst_ifacetype='test_bare_wb',
imem_ifacetype='test_bare_wb',
addr_wid=48,
mask_wid=8,
+ imem_reg_wid=64,
+ #wb_data_width=32,
reg_wid=64)
m.submodules.issuer = issuer = TestIssuer(pspec)
imem = issuer.imem._get_memory()
core = issuer.core
- pdecode2 = core.pdecode2
+ dmi = issuer.dbg.dmi
+ pdecode2 = issuer.pdecode2
l0 = core.l0
+ # copy of the decoder for simulator
+ simdec = create_pdecode()
+ simdec2 = PowerDecode2(simdec)
+ m.submodules.simdec2 = simdec2 # pain in the neck
+
comb += issuer.pc_i.data.eq(pc_i)
- comb += issuer.go_insn_i.eq(go_insn_i)
# nmigen Simulation
sim = Simulator(m)
def process():
+ # start in stopped
+ yield from set_dmi(dmi, DBGCore.CTRL, 1<<DBGCtrl.STOP)
+ yield
+ yield
+
for test in self.test_data:
- # get core going
+ # pull a reset
+ #yield from set_dmi(dmi, DBGCore.CTRL, 1<<DBGCtrl.RESET)
+
+ # set up bigendian (TODO: don't do this, use MSR)
yield issuer.core_bigendian_i.eq(bigendian)
- yield issuer.core_start_i.eq(1)
- yield
- yield issuer.core_start_i.eq(0)
yield Settle()
+ yield
+ yield
+ yield
+ yield
+
print(test.name)
program = test.program
self.subTest(test.name)
- print ("regs", test.regs)
- print ("sprs", test.sprs)
- print ("cr", test.cr)
- print ("mem", test.mem)
- print ("msr", test.msr)
- print ("assem", program.assembly)
+ print("regs", test.regs)
+ print("sprs", test.sprs)
+ print("cr", test.cr)
+ print("mem", test.mem)
+ print("msr", test.msr)
+ print("assem", program.assembly)
gen = list(program.generate_instructions())
insncode = program.assembly.splitlines()
instructions = list(zip(gen, insncode))
- sim = ISA(pdecode2, test.regs, test.sprs, test.cr, test.mem,
+ sim = ISA(simdec2, test.regs, test.sprs, test.cr, test.mem,
test.msr,
initial_insns=gen, respect_pc=True,
disassembly=insncode,
bigendian=bigendian)
- pc = 0 # start address
+ pc = 0 # start address
+ counter = 0 # test to pause/start
yield from setup_i_memory(imem, pc, instructions)
yield from setup_test_memory(l0, sim)
- yield from setup_regs(core, test)
+ yield from setup_regs(pdecode2, core, test)
yield pc_i.eq(pc)
yield issuer.pc_i.ok.eq(1)
+ yield
+
+ print("instructions", instructions)
index = sim.pc.CIA.value//4
while index < len(instructions):
print("instruction: 0x{:X}".format(ins & 0xffffffff))
print(index, code)
- # start the instruction
- yield go_insn_i.eq(1)
- yield
- yield issuer.pc_i.ok.eq(0) # don't change PC from now on
- yield go_insn_i.eq(0) # and don't issue a new insn
- yield Settle()
+ if counter == 0:
+ # start the core
+ yield
+ yield from set_dmi(dmi, DBGCore.CTRL, 1<<DBGCtrl.START)
+ yield issuer.pc_i.ok.eq(0) # no change PC after this
+ yield
+ yield
+
+ counter = counter + 1
# wait until executed
yield from wait_for_busy_hi(core)
yield from wait_for_busy_clear(core)
- terminated = yield issuer.halted_o
- print ("terminated", terminated)
+ # set up simulated instruction (in simdec2)
+ try:
+ yield from sim.setup_one()
+ except KeyError: # indicates instruction not in imem: stop
+ break
+ yield Settle()
- print ("sim", code)
# call simulated operation
- opname = code.split(' ')[0]
- yield from sim.call(opname)
+ print("sim", code)
+ yield from sim.execute_one()
yield Settle()
index = sim.pc.CIA.value//4
+ terminated = yield issuer.dbg.terminated_o
+ print("terminated", terminated)
+
+ if index >= len(instructions):
+ print ("index over, send dmi stop")
+ # stop at end
+ yield from set_dmi(dmi, DBGCore.CTRL, 1<<DBGCtrl.STOP)
+ yield
+ yield
+
+ # wait one cycle for registers to settle
+ yield
+
# register check
yield from check_regs(self, sim, core, test, code)
# Memory check
yield from check_sim_memory(self, l0, sim, code)
- terminated = yield issuer.halted_o
+ terminated = yield issuer.dbg.terminated_o
+ print("terminated(2)", terminated)
if terminated:
break
+ # stop at end
+ yield from set_dmi(dmi, DBGCore.CTRL, 1<<DBGCtrl.STOP)
+ yield
+ yield
+
+ # get CR
+ cr = yield from get_dmi(dmi, DBGCore.CR)
+ print ("after test %s cr value %x" % (test.name, cr))
+
+ # test of dmi reg get
+ for int_reg in range(32):
+ yield from set_dmi(dmi, DBGCore.GSPR_IDX, int_reg)
+ value = yield from get_dmi(dmi, DBGCore.GSPR_DATA)
+
+ print ("after test %s reg %2d value %x" % \
+ (test.name, int_reg, value))
+
sim.add_sync_process(process)
with sim.write_vcd("issuer_simulator.vcd",
- traces=[]):
+ traces=[]):
sim.run()
if __name__ == "__main__":
unittest.main(exit=False)
suite = unittest.TestSuite()
- #suite.addTest(TestRunner(HelloTestCases.test_data))
- #suite.addTest(TestRunner(DivTestCase.test_data))
- suite.addTest(TestRunner(AttnTestCase.test_data))
+ # suite.addTest(TestRunner(HelloTestCases.test_data))
+ suite.addTest(TestRunner(DivTestCases().test_data))
+ # suite.addTest(TestRunner(AttnTestCase.test_data))
suite.addTest(TestRunner(GeneralTestCases.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))
- #suite.addTest(TestRunner(SPRTestCase.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))
+ # suite.addTest(TestRunner(SPRTestCase.test_data))
runner = unittest.TextTestRunner()
runner.run(suite)
-