litex/migen/sim/generic.py

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# Copyright (C) 2012 Vermeer Manufacturing Co.
# License: GPLv3 with additional permissions (see README).
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from migen.fhdl.structure import *
from migen.fhdl import verilog
from migen.sim.ipc import *
class TopLevel:
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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
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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}
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def get(self, sockaddr):
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template1 = """`timescale 1ns / 1ps
module {top_name}();
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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;
"""
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template2 = """
initial begin
$dumpfile("{vcd_name}");
$dumpvars({vcd_level}, {dut_name});
end
"""
r = template1.format(top_name=self.top_name,
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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,
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sockaddr=sockaddr)
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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
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class Simulator:
def __init__(self, fragment, sim_runner, top_level=None, sockaddr="simsocket", **vopts):
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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,
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name=self.top_level.dut_type,
clock_domains=self.top_level.clock_domains,
return_ns=True,
**vopts)
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self.cycle_counter = -1
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self.interrupt = False
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self.sim_runner = sim_runner
self.sim_runner.start(c_top, c_fragment)
self.ipc.accept()
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reply = self.ipc.recv()
assert(isinstance(reply, MessageTick))
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self.fragment.call_sim(self)
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def run(self, ncycles=-1):
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self.interrupt = False
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counter = 0
while not self.interrupt and (ncycles < 0 or counter < ncycles):
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self.cycle_counter += 1
counter += 1
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self.ipc.send(MessageGo())
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reply = self.ipc.recv()
assert(isinstance(reply, MessageTick))
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self.fragment.call_sim(self)
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def rd(self, item, index=0):
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name = self.top_level.top_name + "." \
+ self.top_level.dut_name + "." \
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+ self.namespace.get_name(item)
self.ipc.send(MessageRead(name, Int32(index)))
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reply = self.ipc.recv()
assert(isinstance(reply, MessageReadReply))
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if isinstance(item, Memory):
signed = False
nbits = item.width
else:
signed = item.bv.signed
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nbits = len(item)
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value = reply.value & (2**nbits - 1)
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if signed and (value & 2**(nbits - 1)):
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value -= 2**nbits
return value
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def wr(self, item, value, index=0):
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name = self.top_level.top_name + "." \
+ self.top_level.dut_name + "." \
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+ self.namespace.get_name(item)
if isinstance(item, Memory):
nbits = item.width
else:
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nbits = len(item)
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if value < 0:
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value += 2**nbits
assert(value >= 0 and value < 2**nbits)
self.ipc.send(MessageWrite(name, Int32(index), value))
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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
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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
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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)
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def __del__(self):
del self.ipc
del self.sim_runner
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# Contrary to multiread/multiwrite, Proxy fetches the necessary signals only and
# immediately forwards writes into the simulation.
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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)
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elif isinstance(item, list):
return [Proxy(self._sim, si) for si in item]
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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)
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class PureSimulable:
def do_simulation(self, s):
raise NotImplementedError("Need to overload do_simulation")
def get_fragment(self):
return Fragment(sim=[self.do_simulation])