Exemplo n.º 1
0
    def __init__(self, dut, init_val):
        """
        Setup the testbench.

        *init_val* signifies the ``BinaryValue`` which must be captured by the
        output monitor with the first rising clock edge.
        This must match the initial state of the D flip-flop in RTL.
        """
        # Some internal state
        self.dut = dut
        self.stopped = False

        # Create input driver and output monitor
        self.input_drv = BitDriver(signal=dut.d,
                                   clk=dut.c,
                                   generator=input_gen())
        self.output_mon = BitMonitor(name="output", signal=dut.q, clk=dut.c)

        # Create a scoreboard on the outputs
        self.expected_output = [init_val
                                ]  # a list with init_val as the first element
        with warnings.catch_warnings():
            warnings.simplefilter("ignore")
            self.scoreboard = Scoreboard(dut)
        self.scoreboard.add_interface(self.output_mon, self.expected_output)

        # Use the input monitor to reconstruct the transactions from the pins
        # and send them to our 'model' of the design.
        self.input_mon = BitMonitor(name="input",
                                    signal=dut.d,
                                    clk=dut.c,
                                    callback=self.model)
Exemplo n.º 2
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class DFF_TB(object):
    def __init__(self, dut, init_val):
        """
        Setup the testbench.

        *init_val* signifies the ``BinaryValue`` which must be captured by the
        output monitor with the first rising clock edge.
        This must match the initial state of the D flip-flop in RTL.
        """
        # Some internal state
        self.dut = dut
        self.stopped = False

        # Create input driver and output monitor
        self.input_drv = BitDriver(signal=dut.d,
                                   clk=dut.c,
                                   generator=input_gen())
        self.output_mon = BitMonitor(name="output", signal=dut.q, clk=dut.c)

        # Create a scoreboard on the outputs
        self.expected_output = [init_val
                                ]  # a list with init_val as the first element
        with warnings.catch_warnings():
            warnings.simplefilter("ignore")
            self.scoreboard = Scoreboard(dut)
        self.scoreboard.add_interface(self.output_mon, self.expected_output)

        # Use the input monitor to reconstruct the transactions from the pins
        # and send them to our 'model' of the design.
        self.input_mon = BitMonitor(name="input",
                                    signal=dut.d,
                                    clk=dut.c,
                                    callback=self.model)

    def model(self, transaction):
        """Model the DUT based on the input *transaction*.

        For a D flip-flop, what goes in at ``d`` comes out on ``q``,
        so the value on ``d`` (put into *transaction* by our ``input_mon``)
        can be used as expected output without change.
        Thus we can directly append *transaction* to the ``expected_output`` list,
        except for the very last clock cycle of the simulation
        (that is, after ``stop()`` has been called).
        """
        if not self.stopped:
            self.expected_output.append(transaction)

    def start(self):
        """Start generating input data."""
        self.input_drv.start()

    def stop(self):
        """Stop generating input data.

        Also stop generation of expected output transactions.
        One more clock cycle must be executed afterwards so that the output of
        the D flip-flop can be checked.
        """
        self.input_drv.stop()
        self.stopped = True
Exemplo n.º 3
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    def __init__(self, dut, debug=False):
        self.dut = dut
        self.stream_in = AvalonSTDriver(dut, "stream_in", dut.clk)
        self.backpressure = BitDriver(self.dut.stream_out_ready, self.dut.clk)
        self.stream_out = AvalonSTMonitor(
            dut,
            "stream_out",
            dut.clk,
            config={'firstSymbolInHighOrderBits': True})

        self.csr = AvalonMaster(dut, "csr", dut.clk)

        cocotb.fork(
            stream_out_config_setter(dut, self.stream_out, self.stream_in))

        # Create a scoreboard on the stream_out bus
        self.pkts_sent = 0
        self.expected_output = []
        with warnings.catch_warnings():
            warnings.simplefilter("ignore")
            self.scoreboard = Scoreboard(dut)
        self.scoreboard.add_interface(self.stream_out, self.expected_output)

        # Reconstruct the input transactions from the pins
        # and send them to our 'model'
        self.stream_in_recovered = AvalonSTMonitor(dut,
                                                   "stream_in",
                                                   dut.clk,
                                                   callback=self.model)

        # Set verbosity on our various interfaces
        level = logging.DEBUG if debug else logging.WARNING
        self.stream_in.log.setLevel(level)
        self.stream_in_recovered.log.setLevel(level)
Exemplo n.º 4
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    def __init__(self, dut: cocotb.handle.HierarchyObject, num_samples):
        self.dut = dut
        self.dut._log.debug("Building/Connecting Testbench")

        # Sanity checks
        assert (self.CLOCK_FREQ_MHZ * 1e9 / fm_global.fs_rx_c).is_integer(), \
            "Clock rate and fs_rx_c must have an integer relation!"

        self.fir_in_strobe = BitDriver(self.dut.iValDry, self.dut.iClk)
Exemplo n.º 5
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    def __init__(self, dut):
        self.dut = dut

        self.clkedge = RisingEdge(dut.clk)

        self.stream_in = AvalonSTDriver(self.dut, "asi", dut.clk)
        self.stream_out = AvalonSTMonitor(self.dut, "aso", dut.clk)
        with warnings.catch_warnings():
            warnings.simplefilter("ignore")
            self.scoreboard = Scoreboard(self.dut, fail_immediately=True)

        self.expected_output = []
        self.scoreboard.add_interface(self.stream_out, self.expected_output)

        self.backpressure = BitDriver(self.dut.aso_ready, self.dut.clk)
Exemplo n.º 6
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    def __init__(self, dut: cocotb.handle.HierarchyObject, n_sec):
        self.dut = dut

        # Sanity checks
        assert (self.CLOCK_FREQ_MHZ * 1e9 / fm_global.fs_rx_c).is_integer(), \
            "Clock rate and fs_rx_c must have an integer relation!"

        # Instantiate model
        golden_data_directory = "../../../../../sim/matlab/verification_data/"
        self.model = FM_RECEIVER_MODEL(n_sec, golden_data_directory)

        # Connect AXI interface (IP input)
        self.axis_m = Axi4StreamMaster(dut, "s0_axis", dut.clk_i)

        # Backpressure from I2S output
        self.backpressure_i2s = BitDriver(dut.m0_axis_tready, dut.clk_i)

        # AXILite register interface
        self.axil_mm_m = AxiLiteMaster(AxiLiteBus.from_prefix(dut, "s_axi"), dut.clk_i,
                                       dut.rst_n_i, reset_active_level=False)

        # Variables
        self.tb_data_handler = TB_DATA_HANDLER()
        self.tb_analyzer_helper = TB_ANALYZER_HELPER(self.model, self.tb_data_handler, is_cocotb=True)