# Copyright (C) 2012 Vermeer Manufacturing Co. # License: GPLv3 with additional permissions (see README). from migen.fhdl.structure import * from migen.fhdl import verilog from migen.sim.ipc import * class TopLevel: def __init__(self, vcd_name=None, vcd_level=1, top_name="top", dut_type="dut", dut_name="dut", clk_name="sys_clk", clk_period=10, rst_name="sys_rst"): self.vcd_name = vcd_name self.vcd_level = vcd_level self.top_name = top_name self.dut_type = dut_type self.dut_name = dut_name self._clk_name = clk_name self._clk_period = clk_period self._rst_name = rst_name cd = ClockDomain(self._clk_name, self._rst_name) self.clock_domains = {"sys": cd} self.ios = {cd.clk, cd.rst} def get(self, sockaddr): template1 = """`timescale 1ns / 1ps module {top_name}(); reg {clk_name}; reg {rst_name}; initial begin {rst_name} <= 1'b1; @(posedge {clk_name}); {rst_name} <= 1'b0; end always begin {clk_name} <= 1'b0; #{hclk_period}; {clk_name} <= 1'b1; #{hclk_period}; end {dut_type} {dut_name}( .{rst_name}({rst_name}), .{clk_name}({clk_name}) ); initial $migensim_connect("{sockaddr}"); always @(posedge {clk_name}) $migensim_tick; """ template2 = """ initial begin $dumpfile("{vcd_name}"); $dumpvars({vcd_level}, {dut_name}); end """ r = template1.format(top_name=self.top_name, dut_type=self.dut_type, dut_name=self.dut_name, clk_name=self._clk_name, hclk_period=str(self._clk_period/2), rst_name=self._rst_name, sockaddr=sockaddr) if self.vcd_name is not None: r += template2.format(vcd_name=self.vcd_name, vcd_level=str(self.vcd_level), dut_name=self.dut_name) r += "\nendmodule" return r class Simulator: def __init__(self, fragment, sim_runner, top_level=None, sockaddr="simsocket", **vopts): self.fragment = fragment if top_level is None: self.top_level = TopLevel() else: self.top_level = top_level self.ipc = Initiator(sockaddr) c_top = self.top_level.get(sockaddr) c_fragment, self.namespace = verilog.convert(fragment, ios=self.top_level.ios, name=self.top_level.dut_type, clock_domains=self.top_level.clock_domains, return_ns=True, **vopts) self.cycle_counter = -1 self.interrupt = False self.sim_runner = sim_runner self.sim_runner.start(c_top, c_fragment) self.ipc.accept() reply = self.ipc.recv() assert(isinstance(reply, MessageTick)) self.fragment.call_sim(self) def run(self, ncycles=-1): self.interrupt = False counter = 0 while not self.interrupt and (ncycles < 0 or counter < ncycles): self.cycle_counter += 1 counter += 1 self.ipc.send(MessageGo()) reply = self.ipc.recv() assert(isinstance(reply, MessageTick)) self.fragment.call_sim(self) def rd(self, item, index=0): name = self.top_level.top_name + "." \ + self.top_level.dut_name + "." \ + self.namespace.get_name(item) self.ipc.send(MessageRead(name, Int32(index))) reply = self.ipc.recv() assert(isinstance(reply, MessageReadReply)) if isinstance(item, Memory): signed = False nbits = item.width else: signed = item.bv.signed nbits = len(item) value = reply.value & (2**nbits - 1) if signed and (value & 2**(nbits - 1)): value -= 2**nbits return value def wr(self, item, value, index=0): name = self.top_level.top_name + "." \ + self.top_level.dut_name + "." \ + self.namespace.get_name(item) if isinstance(item, Memory): nbits = item.width else: nbits = len(item) if value < 0: value += 2**nbits assert(value >= 0 and value < 2**nbits) self.ipc.send(MessageWrite(name, Int32(index), value)) def multiread(self, obj): if isinstance(obj, Signal): return self.rd(obj) elif isinstance(obj, list): r = [] for item in obj: rd = self.multiread(item) if isinstance(item, Signal) or rd: r.append(rd) return r elif hasattr(obj, "__dict__"): r = {} for k, v in obj.__dict__.items(): rd = self.multiread(v) if isinstance(v, Signal) or rd: r[k] = rd return r def multiwrite(self, obj, value): if isinstance(obj, Signal): self.wr(obj, value) elif isinstance(obj, list): for target, source in zip(obj, value): self.multiwrite(target, source) else: for k, v in value.items(): self.multiwrite(getattr(obj, k), v) def __del__(self): del self.ipc del self.sim_runner # Contrary to multiread/multiwrite, Proxy fetches the necessary signals only and # immediately forwards writes into the simulation. class Proxy: def __init__(self, sim, obj): self.__dict__["_sim"] = sim self.__dict__["_obj"] = obj def __getattr__(self, name): item = getattr(self._obj, name) if isinstance(item, Signal): return self._sim.rd(item) elif isinstance(item, list): return [Proxy(self._sim, si) for si in item] else: return Proxy(self._sim, item) def __setattr__(self, name, value): item = getattr(self._obj, name) assert(isinstance(item, Signal)) self._sim.wr(item, value) class PureSimulable: def do_simulation(self, s): raise NotImplementedError("Need to overload do_simulation") def get_fragment(self): return Fragment(sim=[self.do_simulation])