def run_sim(dut, data, n):
    sim = Simulator(dut, engine=os.getenv('NMIGEN_SIM', 'pysim'))
    sim.add_clock(10e-9, domain='sync')
    sim.add_sync_process(dut.input.send_driver(data))
    sim.add_sync_process(dut.output.recv_driver(n))
    with sim.write_vcd('bla.vcd'):
        sim.run()
Esempio n. 2
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    def sim(cls):
        """A quick simulation of the transparent latch."""
        m = Module()
        m.submodules.latch = latch = TransparentLatch(32)

        sim = Simulator(m)

        def process():
            yield latch.n_oe.eq(1)
            yield latch.le.eq(1)
            yield Delay(1e-6)
            yield latch.data_in.eq(0xAAAA1111)
            yield Delay(1e-6)
            yield latch.data_in.eq(0x1111AAAA)
            yield Delay(1e-6)
            yield latch.le.eq(0)
            yield Delay(1e-6)
            yield latch.data_in.eq(0xAAAA1111)
            yield Delay(1e-6)
            yield latch.le.eq(1)
            yield Delay(1e-6)

        sim.add_process(process)
        with sim.write_vcd("latch.vcd"):
            sim.run_until(10e-6)
Esempio n. 3
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class TestBase(unittest.TestCase):
    """Base class for testing an nMigen module.

    The module can use sync, comb or both.
    """
    def setUp(self):
        self.m = Module()
        self.dut = self.create_dut()
        self.m.submodules['dut'] = self.dut
        self.m.submodules['dummy'] = _DummySyncModule()
        self.sim = Simulator(self.m)

    def create_dut(self):
        """Returns an instance of the device under test"""
        raise NotImplementedError

    def add_process(self, process):
        """Add main test process to the simulator"""
        self.sim.add_sync_process(process)

    def add_sim_clocks(self):
        """Add clocks as required by sim.
        """
        self.sim.add_clock(1, domain='sync')

    def run_sim(self, process, write_trace=False):
        self.add_process(process)
        self.add_sim_clocks()
        if write_trace:
            with self.sim.write_vcd("zz.vcd", "zz.gtkw"):
                self.sim.run()
        else:
            self.sim.run()
Esempio n. 4
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    def sim(self, dut, testbench=None, traces=(), filename=None):
        dut = self.prepare(dut)
        simulator = Simulator(dut)
        for name, frequency in self.clocks.items():
            simulator.add_clock(1 / frequency, domain=name)

        if not filename:
            stack = inspect.stack()
            filename = stack[1].function
        assert isinstance(filename, str)

        if isinstance(testbench, tuple):
            generator, domain = testbench
            self.add_process(generator, domain)
        elif inspect.isgeneratorfunction(testbench):
            self.add_process(testbench, "sync")
        elif testbench is None:
            pass
        else:
            raise TypeError("unknown type for testbench")

        for generator, domain in self.processes:
            simulator.add_sync_process(generator, domain=domain)

        Path(".sim_results/").mkdir(exist_ok=True)
        with simulator.write_vcd(".sim_results/{}.vcd".format(filename),
                                 ".sim_results/{}.gtkw".format(filename),
                                 traces=traces):
            simulator.run()
Esempio n. 5
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    def sim(cls):
        """A quick simulation of the async memory."""
        m = Module()
        m.submodules.mem = mem = AsyncMemory(width=32, addr_lines=5)

        sim = Simulator(m)

        def process():
            yield mem.n_oe.eq(0)
            yield mem.n_wr.eq(1)
            yield mem.data_in.eq(0xFFFFFFFF)
            yield Delay(1e-6)
            yield mem.addr.eq(1)
            yield mem.n_oe.eq(0)
            yield Delay(1e-6)
            yield mem.n_oe.eq(1)
            yield Delay(1e-6)
            yield mem.data_in.eq(0xAAAA1111)
            yield Delay(1e-6)
            yield mem.n_wr.eq(0)
            yield Delay(0.2e-6)
            yield mem.n_wr.eq(1)
            yield Delay(0.2e-6)
            yield mem.data_in.eq(0xFFFFFFFF)
            yield mem.n_oe.eq(0)
            yield Delay(1e-6)
            yield mem.addr.eq(0)
            yield Delay(1e-6)

        sim.add_process(process)
        with sim.write_vcd("async_memory.vcd"):
            sim.run_until(10e-6)
Esempio n. 6
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    def sim(self, dut, testbench=None, traces=(), engine="pysim"):
        dut = self.prepare(dut)
        self.fragment = dut
        simulator = Simulator(dut, engine=engine)
        for name, (frequency, phase) in self.clocks.items():
            simulator.add_clock(1 / frequency, domain=name, phase=phase)

        if isinstance(testbench, tuple):
            generator, domain = testbench
            self.add_process(generator, domain)
        elif inspect.isgeneratorfunction(testbench):
            self.add_process(testbench, "sync")
        elif testbench is None:
            pass
        else:
            raise TypeError("unknown type for testbench")

        for generator, domain in self.processes:
            simulator.add_sync_process(generator, domain=domain)

        print("\nwriting vcd to '{}.vcd'".format(self.output_filename_base))
        with simulator.write_vcd("{}.vcd".format(self.output_filename_base),
                                 "{}.gtkw".format(self.output_filename_base),
                                 traces=traces):
            simulator.run()
Esempio n. 7
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def test_h100_sync():
	from nmigen.sim import Simulator, Delay

	bus = HighSpeedTransmitBus()

	m = Module()
	m.submodules.sync = sync = H100Sync()
	m.submodules.dut = dut = HighSpeedTransmit(bus=bus, sync=sync)

	frame_data_0 = [ord(c) for c in '0_TESTING_T1_DATA_STUFF\xff']
	frame_data_1 = [ord(c) for c in '1_TESTING_T1_DATA_STUFF\x00']
	frame_data_2 = [ord(c) for c in '2_TESTING_T1_DATA_STUFF\xff']
	frame_data_3 = [ord(c) for c in '3_TESTING_T1_DATA_STUFF\x00']

	def process_test():
		yield Delay(100e-9)
		yield sync.enable.eq(1)
		yield dut.enable.eq(1)
		yield dut.data[0].eq(0xaa)
		yield dut.data[1].eq(0x55)
		yield dut.data[2].eq(0xff)
		yield dut.data[3].eq(0x00)

		for _ in range(2500):
			slot_t1 = yield sync.slot_t1
			yield
			yield dut.data[0].eq(frame_data_0[slot_t1])
			yield dut.data[1].eq(frame_data_1[slot_t1])
			yield dut.data[2].eq(frame_data_2[slot_t1])
			yield dut.data[3].eq(frame_data_3[slot_t1])

	sim = Simulator(m)
	sim.add_clock(1.0 / 16.384e6)

	# sim.add_sync_process(process_inclk)
	sim.add_sync_process(process_test)

	traces = [
		# sync.inclk,
		# sync.outclk,

		dut.enable,

		bus.ser.o,
		bus.ser.oe,
		bus.msync.o,
		bus.msync.oe,
		bus.sync.o,
		bus.sync.oe,
	]

	with sim.write_vcd("test_h100_sync.vcd", "test_h100_sync.gtkw", traces=traces):
		sim.run()
Esempio n. 8
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def test_pattern_matching():
    m = Matcher(pattern=[0, 1, 1, 0], interval=1)
    sim = Simulator(m)
    sim.add_clock(1e-6, domain="sync")

    haystack = [0, 0, 1, 0, 0, 1, 1, 1, 0, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 0]

    def process():
        matchcount = 0
        for i in range(len(haystack)):
            yield
            yield m.input.eq(haystack[i])
            matchcount += yield m.match
        assert (matchcount == 1)

    sim.add_sync_process(process)

    with sim.write_vcd("matching.vcd"):
        sim.run()
def test_crc():

    m = GaloisCRC()
    sim = Simulator(m)
    sim.add_clock(1e-6, domain="sync")

    data = [0, 1, 0, 0, 1, 0, 1, 1, 1, 0]

    def process():
        for bit in data:
            yield m.input.eq(bit)
            yield m.en.eq(1)
            yield
        yield
        crc = yield m.crc
        assert (crc == py_crc(np.array(data)))

    sim.add_sync_process(process)

    with sim.write_vcd("crc.vcd"):
        sim.run()
Esempio n. 10
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    def check(self, instruction: int, expected: Dict[str, int]):
        decoder = CPUDecoder()
        sim = Simulator(decoder)

        def input_process():
            yield decoder.instruction_in.eq(instruction)

        def check_process():
            yield Delay(1e-6)
            for k, expected_value in expected.items():
                value = yield getattr(decoder, k)
                if isinstance(expected_value, enum.Enum):
                    value = expected_value.__class__(value)
                else:
                    value = hex(value)
                    expected_value = hex(expected_value)
                with self.subTest(f"decoder.{k}"):
                    self.assertEqual(value, expected_value)

        with sim.write_vcd(f"test_decode_{hex(instruction)}.vcd"):
            sim.add_process(input_process)
            sim.add_process(check_process)
            sim.run()
Esempio n. 11
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def test_frequency_generation():
    """This creates an oscillator with a frequency error that meets a given spec and then
       verifies that it actually loops through everything. Note that below a certain error
       level, we start to get assorted floating point differences that mean that this test
       fails against even the "realized frequency" reference"""
    
    freq = 2.4*1e9
    sample_rate = 5*1e9
    error = 0.0001*1e6 # 50ppm allowable frequency error, not 

    m = OneBitFixedOscillator(sample_rate=sample_rate, frequency=freq, max_error=error, width=20, domain='sync')
    sim = Simulator(m)
    sim.add_clock(1e-6, domain="sync")

    assert np.abs(m.realized_frequency - freq) < error
    samples = m.pattern_words*10

    ref = binarize(make_carrier(sample_rate=sample_rate, freq=m.realized_frequency, samples=samples*20))
    ref = pack_mem(ref, 20)

    output = np.zeros((samples,), dtype=np.uint32)

    def process():
        for i in range(samples):
            yield
            result = yield m.output
            counter = yield m.counter
            output[i] = result
            if bin(result) != bin(ref[i]):
                raise Exception("At {} got {} but expected {}".format(i, bin(result), bin(ref[i])))
        print(json.dumps(list(map(int, output))))

    sim.add_sync_process(process)
    
    with sim.write_vcd("nco.vcd"):
        sim.run()
Esempio n. 12
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    def test_serializer(self):
        clk = 60e6
        m = Serializer(w_width=32, r_width=8)

        sim = Simulator(m)
        sim.add_clock(1 / clk)

        def process():
            data = 0xDDCCBBAA
            yield m.w_data.eq(data)
            yield m.w_en.eq(1)
            yield m.r_en.eq(1)
            yield
            for i in range(10):
                for j in range(4):
                    yield
                    shift = (j * 8)
                    mask = (0xff << shift)
                    expected_r_data = (data & mask) >> shift
                    self.assertEqual((yield m.r_data), expected_r_data)

        sim.add_sync_process(process)
        with sim.write_vcd("serializer.vcd", "serializer.gtkw", traces=[]):
            sim.run()
Esempio n. 13
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    def assertStatement(self, stmt, inputs, output, reset=0):
        inputs = [Value.cast(i) for i in inputs]
        output = Value.cast(output)

        isigs = [Signal(i.shape(), name=n) for i, n in zip(inputs, "abcd")]
        osig = Signal(output.shape(), name="y", reset=reset)

        stmt = stmt(osig, *isigs)
        frag = Fragment()
        frag.add_statements(stmt)
        for signal in flatten(s._lhs_signals() for s in Statement.cast(stmt)):
            frag.add_driver(signal)

        sim = Simulator(frag)

        def process():
            for isig, input in zip(isigs, inputs):
                yield isig.eq(input)
            yield Settle()
            self.assertEqual((yield osig), output.value)

        sim.add_process(process)
        with sim.write_vcd("test.vcd", "test.gtkw", traces=[*isigs, osig]):
            sim.run()
Esempio n. 14
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    yield from jtagPDI((0x4C, 1), (0xEB, 1))
    yield
    yield from jtagPDI((0xCA, 0), (0xEB, 1))
    yield
    yield from jtagPDI((0x01, 1), (0xEB, 1))
    yield
    yield from jtagPDI((0x00, 0), (0xEB, 1))
    yield
    yield from jtagPDI((0x01, 1), (0xEB, 1))
    yield
    yield from jtagPDI((0x00, 0), (0xEB, 1))
    yield
    yield
    yield
    yield


sim = Simulator(subtarget)
# Define the JTAG clock to have a period of 1/4MHz
#sim.add_clock(250e-9, domain = 'jtag')
sim.add_clock(2e-6, domain='jtag')
# Define the system clock to have a period of 1/48MHz
sim.add_clock(20.8e-9)

sim.add_sync_process(benchSync, domain='sync')
sim.add_sync_process(benchJTAG, domain='jtag')

with sim.write_vcd('jtag_pdi-sniffer.vcd'):
    sim.reset()
    sim.run()
Esempio n. 15
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        def transmit_proc():
            assert (yield uart.tx_ack)
            assert not (yield uart.rx_rdy)

            yield uart.tx_data.eq(0x5A)
            yield uart.tx_rdy.eq(1)
            yield
            yield uart.tx_rdy.eq(0)
            yield
            assert not (yield uart.tx_ack)

            for _ in range(uart.divisor * 12): yield

            assert (yield uart.tx_ack)
            assert (yield uart.rx_rdy)
            assert not (yield uart.rx_err)
            assert (yield uart.rx_data) == 0x5A

            yield uart.rx_ack.eq(1)
            yield
        sim.add_sync_process(transmit_proc)

        with sim.write_vcd("uart.vcd", "uart.gtkw"):
            sim.run()

    if args.action == "generate":
        from nmigen.back import verilog

        print(verilog.convert(uart, ports=ports))
Esempio n. 16
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                                        m.next = "FETCH"
                            with m.Case(3):
                                with m.If(bus.done):
                                    m.d.sync += [
                                        self.pc.eq(self.wx),
                                        bus.addr.eq(self.sp),
                                        bus.data_in.eq(self.pc[:8]),
                                        bus.en.eq(1),
                                        cycle.eq(4)
                                    ]
                            with m.Case(4):
                                with m.If(bus.done):
                                    m.next = "FETCH"
                    with m.Default():  # NOP
                        m.d.comb += op.eq(OpBlock.NOP)
                        m.next = "FETCH"
            with m.State("HALT"):
                pass

        return m


if __name__ == "__main__":
    import sys, os
    from nmigen.sim import Simulator
    sys.setrecursionlimit(8192)
    sim = Simulator(I8080())
    sim.add_clock(1e-4)
    with sim.write_vcd("trace.vcd"):
        sim.run_until(1, run_passive=True)
Esempio n. 17
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    def generic_chacha20(self, implementation):
        print("")

        # Encrypt a test message with a known good implementation
        import json
        from base64 import b64encode
        from Crypto.Cipher import ChaCha20
        from Crypto.Random import get_random_bytes
        from struct import pack, unpack
        from binascii import hexlify

        def byte_xor(ba1, ba2):
            """ XOR two byte strings """
            return bytes([_a ^ _b for _a, _b in zip(ba1, ba2)])

        plaintext = b'A' * 64
        # key = get_random_bytes(32)
        key = bytes([i for i in range(32)])

        # nonce = get_random_bytes(12)
        nonce = bytes([(i * 16 + i) for i in range(12)])
        cipher = ChaCha20.new(key=key, nonce=nonce)
        ciphertext = cipher.encrypt(plaintext)

        nonceb64 = b64encode(cipher.nonce).decode('utf-8')
        ciphertextb64 = b64encode(ciphertext).decode('utf-8')
        keystream = byte_xor(plaintext, ciphertext)
        keystream_hex = hexlify(keystream).decode('utf8')
        result = json.dumps({
            'nonce': nonceb64,
            'ciphertext': ciphertextb64,
            'keystream': keystream_hex
        })
        # print(result)

        # cipher = ChaCha20.new(key=key, nonce=nonce)
        # cipher.seek(0)
        # print(cipher.decrypt(ciphertext))

        m = Module()

        m.submodules.chacha20 = chacha20 = ChaCha20Cipher(implementation)

        key_words = unpack("<8I", key)
        m.d.comb += [
            chacha20.i_key[i].eq(key_words[i]) for i in range(len(key_words))
        ]

        nonce_words = unpack("<3I", nonce)
        m.d.comb += [
            chacha20.i_nonce[i].eq(nonce_words[i])
            for i in range(len(nonce_words))
        ]

        sim = Simulator(m)
        sim.add_clock(1e-6, domain="sync")

        def process():
            ks = []
            iterations = 0
            yield chacha20.i_en.eq(1)
            yield
            for i in range(30 * 4):
                # Simulate until it'd finished
                iterations += 1
                if (yield chacha20.o_ready) != 0:
                    yield
                    yield
                    yield
                    break
                yield
            for i in range(16):
                ks.append((yield chacha20.o_stream[i]))
            keystream_hdl = pack("<16I", *ks)
            print(f"Took {iterations} iterations")
            print("Keystream generated by simulation: ",
                  hexlify(keystream_hdl))
            print("Decryption using simulation: ",
                  byte_xor(keystream_hdl, ciphertext))

            self.assertEqual(keystream_hdl, keystream)
            self.assertEqual(plaintext, byte_xor(keystream_hdl, ciphertext))

        sim.add_sync_process(process)
        with sim.write_vcd("test.vcd", "test.gtkw"):
            sim.run()
Esempio n. 18
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def test_base_rate_sync():
	from nmigen.sim import Simulator, Delay

	clock_sclk = 1.544e6
	clock_sync = 16.384e6

	m = Module()
	m.submodules.dut = dut = BaseRateSync()

	sclk = Signal()
	serclk = Signal()
	ser = Signal()

	SERCLK_SKEW = 10e-9
	SER_SKEW = 10e-9

	def process_framer():
		frequency = clock_sclk
		period = 1.0 / frequency

		data = 'THIS_IS_A_TEST_' * 40
		data_bits = ''.join(['{:08b}'.format(ord(v)) for v in data])

		for bit in data_bits:
			yield sclk.eq(1)
			yield Delay(SERCLK_SKEW)
			yield serclk.eq(1)
			yield Delay(SER_SKEW)
			yield ser.eq(int(bit))
			yield Delay(period * 0.5 - SERCLK_SKEW - SER_SKEW)
			yield sclk.eq(0)
			yield Delay(SERCLK_SKEW)
			yield serclk.eq(0)
			yield Delay(period * 0.5 - SERCLK_SKEW)

	def process_strobe():
		last = 0
		for _ in range(int(round(4700 * clock_sync / clock_sclk))):
			serclk_value = yield serclk
			if serclk_value == 0 and last == 1:
				yield dut.strobe_in.eq(1)
			else:
				yield dut.strobe_in.eq(0)
			last = serclk_value
			yield

	def process_test():
		yield Delay(100e-9)

		for _ in range(4700):
			yield

	sim = Simulator(m)
	sim.add_clock(1.0 / clock_sync)

	sim.add_process(process_framer)
	sim.add_sync_process(process_strobe)
	sim.add_sync_process(process_test)

	traces = [
		sclk,
		serclk,
		ser,
	]

	with sim.write_vcd("test_base_rate_sync.vcd", "test_base_rate_sync.gtkw", traces=traces):
		sim.run()
Esempio n. 19
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    fw = FIRM  # use this firmware

    if args.simulate:
        spork = build(fw, mem_size=1024)
        from nmigen.sim import Simulator
        from sim_data import test_rx, str_data

        st = "sphinx of black quartz judge my vow"
        # print(hex(_crc(st.encode("utf-8"))))
        data = str_data(st)
        dut = spork.cpu.pc.devices[0]._phy
        dut.divisor_val = spork.divisor
        sim = Simulator(spork)
        sim.add_clock(1e-3)
        sim.add_sync_process(test_rx(data, dut))
        with sim.write_vcd("sim.vcd"):
            sim.run()

    if args.list:
        spork = build(fw, detail=True)

    if args.program:
        spork = build(fw, detail=True)
        spork.platform.build(spork, do_program=True)

    if args.generate:
        spork = build(fw, mem_size=1024, sim=True)
        from nmigen.back import cxxrtl
        from nmigen.hdl import ir

        # output = rtlil.convert(
Esempio n. 20
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            self.CPU.data_port.r_data.eq(register_file_r.data),
            register_file_w.addr.eq(self.CPU.data_port.addr),
            register_file_w.data.eq(self.CPU.data_port.w_data),
            register_file_w.en.eq(self.CPU.data_port.w_en)
        ]
        
        return m


if __name__ == "__main__":
    with open("infinite_helloworld.bf", "r") as f:
        m = Module()
        m.submodules.DUT = DUT = Sim_top(f, brainfuck_array_size=64)

        sim = Simulator(m)

        def process():
            yield DUT.si_data.eq(ord("A"))
            yield DUT.si_valid.eq(0)
            yield DUT.so_ready.eq(0)
            for _ in range(3210):
                yield 
            yield DUT.si_valid.eq(1)
            yield DUT.so_ready.eq(1)
            yield

        sim.add_clock(0.02083e-6, domain="sync")
        sim.add_sync_process(process)
        with sim.write_vcd("bf_tb.vcd", "bf_tb.gtkw"):
            sim.run_until(500e-5, run_passive=True)
Esempio n. 21
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from nmigen import *
from nmigen.sim import Simulator, Delay, Settle, Passive
from st7789 import *

if __name__ == "__main__":
    m = Module()
    m.submodules.st7789 = st7789 = ST7789(1)

    sim = Simulator(m)
    sim.add_clock(4e-8)

    def process():
        yield st7789.color.eq(0xf800)
        yield Passive()

    sim.add_process(process)
    with sim.write_vcd("test.vcd", "test.gtkw", traces=st7789.ports()):
        sim.run_until(30e-6, run_passive=True)
Esempio n. 22
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from axi_stream_top import AxiStreamTop

dut = AxiStreamTop()


def bench():
    tvalid_last = 0
    tvalid_can_fall = 0
    for i in range(2000):
        yield
        # Check that TVALID never goes low until the transmission completes.
        tvalid = (yield dut.tx.m_axis.tvalid)
        tx_done = (yield dut.tx.m_axis.tx_done())
        # Don't care about no change in tvalid.
        # Don't care if tvalid is high.
        # Only allow tvalid to fall the cycle after a tx_done.
        assert ((tvalid == tvalid_last) or (tvalid) or (tvalid_can_fall))
        tvalid_can_fall = tx_done
        tvalid_last = tvalid


sim = Simulator(dut)
sim.add_clock(1e-6)
sim.add_sync_process(bench)
with sim.write_vcd("axi_stream_top.vcd"):
    sim.run()

with open("axi_stream_top.v", "w") as f:
    f.write(verilog.convert(dut))
Esempio n. 23
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        # with m.If(self.enable):
        m.d.sync += phase_acc.eq(phase_acc + self.phase_step)

        return m

    @staticmethod
    def calculate_phase_step(clk_frequency: float, frequency: float):
        return int(round((2 ** 32) * frequency / clk_frequency))


if __name__ == "__main__":
    # from nmigen_boards.tinyfpga_bx import TinyFPGABXPlatform
    # platform = TinyFPGABXPlatform()
    # products = platform.build(Top(), do_program=True)
    
    from nmigen.sim import Simulator, Tick

    dut = NCO(width=8, samples=1024)
    sim = Simulator(dut)
    sim.add_clock(1 / 1e6)

    def proc():
        yield dut.phase_step.eq(NCO.calculate_phase_step(clk_frequency=1e6, frequency=440))
        for i in range(3000):
            yield Tick()

    sim.add_process(proc)
    with sim.write_vcd("dds.vcd"):
        sim.run()
Esempio n. 24
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from nmigen.back import verilog
from nmigen.sim import Simulator

from lfsr import Lfsr

dut = Lfsr()


def bench():
    yield dut.en.eq(1)
    for _ in range(100):
        yield


sim = Simulator(dut)
sim.add_clock(1e-6)
sim.add_sync_process(bench)
with sim.write_vcd("lfsr.vcd"):
    sim.run()

with open("lfsr.v", "w") as f:
    f.write(verilog.convert(dut, ports=[dut.out]))
Esempio n. 25
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	pdiPerform = True
	yield from jtagPDI((0x24, 0), (0xEB, 1))
	yield from jtagPDI((0x00, 0), (0x1E, 0))
	yield from jtagPDI((0x00, 0), (0x98, 1))
	yield from jtagPDI((0x00, 0), (0x42, 0))
	pdiComplete = True
	yield
	pdiPerform = True
	yield from jtagPDI((0x4C, 1), (0xEB, 1))
	yield from jtagPDI((0xCA, 0), (0xEB, 1))
	yield from jtagPDI((0x01, 1), (0xEB, 1))
	yield from jtagPDI((0x00, 0), (0xEB, 1))
	yield from jtagPDI((0x01, 1), (0xEB, 1))
	yield from jtagPDI((0x00, 0), (0xEB, 1))
	pdiComplete = True
	yield
	yield
	yield
	yield

sim = Simulator(subtarget)
# Define the system clock to have a period of 1/48MHz
sim.add_clock(20.8e-9)

sim.add_sync_process(benchSync, domain = 'sync')
sim.add_sync_process(benchJTAG, domain = 'sync')

with sim.write_vcd('jtag_pdi-interactive.vcd'):
	sim.reset()
	sim.run()
Esempio n. 26
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class LunaGatewareTestCase(unittest.TestCase):

    domain = 'sync'

    # Convenience property: if set, instantiate_dut will automatically create
    # the relevant fragment with FRAGMENT_ARGUMENTS.
    FRAGMENT_UNDER_TEST = None
    FRAGMENT_ARGUMENTS = {}

    # Convenience properties: if not None, a clock with the relevant frequency
    # will automatically be added.
    FAST_CLOCK_FREQUENCY = None
    SYNC_CLOCK_FREQUENCY = 120e6
    USB_CLOCK_FREQUENCY = None
    SS_CLOCK_FREQUENCY = None

    def instantiate_dut(self):
        """ Basic-most function to instantiate a device-under-test.

        By default, instantiates FRAGMENT_UNDER_TEST.
        """
        return self.FRAGMENT_UNDER_TEST(**self.FRAGMENT_ARGUMENTS)

    def get_vcd_name(self):
        """ Return the name to use for any VCDs generated by this class. """
        return "test_{}".format(self.__class__.__name__)

    def setUp(self):
        self.dut = self.instantiate_dut()
        self.sim = Simulator(self.dut)

        if self.USB_CLOCK_FREQUENCY:
            self.sim.add_clock(1 / self.USB_CLOCK_FREQUENCY, domain="usb")
        if self.SYNC_CLOCK_FREQUENCY:
            self.sim.add_clock(1 / self.SYNC_CLOCK_FREQUENCY, domain="sync")
        if self.FAST_CLOCK_FREQUENCY:
            self.sim.add_clock(1 / self.FAST_CLOCK_FREQUENCY, domain="fast")
        if self.SS_CLOCK_FREQUENCY:
            self.sim.add_clock(1 / self.SS_CLOCK_FREQUENCY, domain="ss")

    def initialize_signals(self):
        """ Provide an opportunity for the test apparatus to initialize siganls. """
        yield Signal()

    def traces_of_interest(self):
        """ Returns an interable of traces to include in any generated output. """
        return ()

    def simulate(self, *, vcd_suffix=None):
        """ Runs our core simulation. """

        # If we're generating VCDs, run the test under a VCD writer.
        if os.getenv('GENERATE_VCDS', default=False):

            # Figure out the name of our VCD files...
            vcd_name = self.get_vcd_name()
            if vcd_suffix:
                vcd_name = "{}_{}".format(vcd_name, vcd_suffix)

            # ... and run the simulation while writing them.
            traces = self.traces_of_interest()
            with self.sim.write_vcd(vcd_name + ".vcd",
                                    vcd_name + ".gtkw",
                                    traces=traces):
                self.sim.run()

        else:
            self.sim.run()

    @staticmethod
    def pulse(signal, *, step_after=True):
        """ Helper method that asserts a signal for a cycle. """
        yield signal.eq(1)
        yield
        yield signal.eq(0)

        if step_after:
            yield

    @staticmethod
    def advance_cycles(cycles):
        """ Helper methods that waits for a given number of cycles. """

        for _ in range(cycles):
            yield

    @staticmethod
    def wait_until(strobe, *, timeout=None):
        """ Helper method that advances time until a strobe signal becomes true. """

        cycles_passed = 0

        while not (yield strobe):
            yield

            cycles_passed += 1
            if timeout and cycles_passed > timeout:
                raise RuntimeError(
                    f"Timeout waiting for '{strobe.name}' to go high!")

    def _ensure_clocks_present(self):
        """ Function that validates that a clock is present for our simulation domain. """
        frequencies = {
            'sync': self.SYNC_CLOCK_FREQUENCY,
            'usb': self.USB_CLOCK_FREQUENCY,
            'fast': self.FAST_CLOCK_FREQUENCY,
            'ss': self.SS_CLOCK_FREQUENCY
        }
        self.assertIsNotNone(
            frequencies[self.domain],
            f"no frequency provied for `{self.domain}`-domain clock!")

    def wait(self, time):
        """ Helper method that waits for a given number of seconds in a *_test_case. """

        # Figure out the period of the clock we want to work with...
        if self.domain == 'sync':
            period = 1 / self.SYNC_CLOCK_FREQUENCY
        elif self.domain == 'usb':
            period = 1 / self.USB_CLOCK_FREQUENCY
        elif self.domain == 'fast':
            period = 1 / self.FAST_CLOCK_FREQUENCY

        # ... and, accordingly, how many cycles we want to delay.
        cycles = math.ceil(time / period)
        print(cycles)

        # Finally, wait that many cycles.
        yield from self.advance_cycles(cycles)
Esempio n. 27
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from up_counter import *

dut = UpCounter(25)


def bench():
    # Disabled counter should not overflow.
    yield dut.en.eq(0)
    for _ in range(30):
        yield
        assert not (yield dut.ovf)

    # Once enabled, the counter should overflow in 25 cycles.
    yield dut.en.eq(1)
    for _ in range(25):
        yield
        assert not (yield dut.ovf)
    yield
    assert (yield dut.ovf)

    # The overflow should clear in one cycle.
    yield
    assert not (yield dut.ovf)


sim = Simulator(dut)
sim.add_clock(1e-6)  # 1 MHz
sim.add_sync_process(bench)
with sim.write_vcd("up_counter.vcd"):
    sim.run()
Esempio n. 28
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            #spimem.copi.eq((timer == 0x30) | (timer == 0x10)), # read address 1
            spimem.copi.eq((timer == 0x30)
                           | (timer == 0x40)),  # write address 1, dout = 1
            spimem.csn.eq(timer == 0),
            spimem.din.eq(0x55)
        ]

        return m


if __name__ == "__main__":
    m = Module()
    m.submodules.test = test = TestSPI()

    sim = Simulator(m)
    sim.add_clock(1e-6)

    def process():

        for i in range(67):
            yield

        addr = yield test.spimem.addr
        print("addr:", addr)
        dout = yield test.spimem.dout
        print("dout:", dout)

    sim.add_sync_process(process)
    with sim.write_vcd("test.vcd", "test.gtkw"):
        sim.run()
Esempio n. 29
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def main():
    # parser = main_parser()
    # args = parser.parse_args()

    m = Module()

    m.submodules.ft = ft = FT600()
    m.submodules.wfifo = wfifo = AsyncFIFOBuffered(
        width=16, depth=1024, r_domain="sync", w_domain="sync")
    m.submodules.rfifo = rfifo = AsyncFIFOBuffered(
        width=16, depth=1024, r_domain="sync", w_domain="sync")

    ft_oe = Signal()
    ft_be = Signal()
    ft_txe = Signal()

    # FT control
    m.d.comb += ft_oe.eq(ft.ft_oe)
    m.d.comb += ft_be.eq(ft.ft_be)
    m.d.comb += ft_txe.eq(ft.ft_txe)

    # FT to Write FIFO
    m.d.comb += ft.input_payload.eq(wfifo.r_data)
    m.d.comb += wfifo.r_en.eq(ft.input_ready)
    m.d.comb += ft.input_valid.eq(wfifo.r_rdy)

    # FT to Read FIFO
    m.d.comb += rfifo.w_data.eq(ft.output_payload)
    m.d.comb += rfifo.w_en.eq(ft.output_valid)
    m.d.comb += ft.output_ready.eq(rfifo.w_rdy)

    sim = Simulator(m)
    sim.add_clock(1e-7, domain="sync")      # 10 MHz FPGA clock

    def process():
        yield wfifo.w_en.eq(1)
        yield wfifo.w_data.eq(1)
        yield Tick(domain="sync")
        yield wfifo.w_data.eq(2)
        yield Tick(domain="sync")
        yield wfifo.w_data.eq(3)
        yield Tick(domain="sync")
        yield wfifo.w_data.eq(4)
        yield Tick(domain="sync")
        yield wfifo.w_data.eq(5)
        yield Tick(domain="sync")
        yield wfifo.w_data.eq(6)
        yield Tick(domain="sync")
        yield wfifo.w_data.eq(7)
        yield Tick(domain="sync")
        yield wfifo.w_en.eq(0)
        yield Tick(domain="sync")
        yield Tick(domain="sync")
        yield ft.ft_txe.eq(1)
        yield Tick(domain="sync")
        yield Tick(domain="sync")
        yield Tick(domain="sync")
        yield Tick(domain="sync")
        yield ft.ft_txe.eq(0)
        yield Tick(domain="sync")
        yield Tick(domain="sync")
        yield ft.ft_txe.eq(1)
        yield Tick(domain="sync")
        yield Tick(domain="sync")
        yield Tick(domain="sync")
        yield Tick(domain="sync")
        yield Tick(domain="sync")
        yield Tick(domain="sync")
        yield Tick(domain="sync")
        yield ft.ft_rxf.eq(1)
        yield Tick(domain="sync")
        yield ft.ft_override.eq(1)
        yield Tick(domain="sync")
        yield ft.ft_override.eq(2)
        yield Tick(domain="sync")
        yield ft.ft_override.eq(3)
        yield Tick(domain="sync")
        yield ft.ft_rxf.eq(0)
        yield Tick(domain="sync")
        yield Tick(domain="sync")
        yield Tick(domain="sync")
        yield Tick(domain="sync")

    sim.add_sync_process(process)
    with sim.write_vcd("test.vcd", "test.gtkw", traces=[]):
        sim.run()
Esempio n. 30
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        oper = Operation[args.oper]

    m = Module()
    m.submodules.alu = alu = ALU_big(oper)

    if oper is not None:
        m.d.comb += Assume(~ResetSignal())
        m.d.comb += Assume(alu.oper == oper)
        main_runner(parser, args, m, ports=alu.ports())

    else:
        sim = Simulator(m)

        def process():
            yield
            yield alu.inputa.eq(0x12)
            yield alu.inputb.eq(0x34)
            yield alu.oper.eq(Operation.ADC)
            yield
            yield
            yield alu.inputa.eq(0x7F)
            yield alu.inputb.eq(0x7F)
            yield alu.oper.eq(Operation.ADC)
            yield
            yield

        sim.add_clock(1e-6)  # 1 MHz
        sim.add_sync_process(process)
        with sim.write_vcd("test.vcd", "test.gtkw", traces=alu.ports()):
            sim.run()