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soil/tests/test_agents.py

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from unittest import TestCase
import pytest
from soil import agents, environment
from soil import time as stime
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class Dead(agents.FSM):
@agents.default_state
@agents.state
def only(self):
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return self.die()
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class TestAgents(TestCase):
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def test_die_returns_infinity(self):
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"""The last step of a dead agent should return time.INFINITY"""
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d = Dead(unique_id=0, model=environment.Environment())
ret = d.step()
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assert ret == stime.NEVER
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def test_die_raises_exception(self):
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"""A dead agent should raise an exception if it is stepped after death"""
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d = Dead(unique_id=0, model=environment.Environment())
d.step()
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with pytest.raises(stime.DeadAgent):
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d.step()
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def test_agent_generator(self):
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"""
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The step function of an agent could be a generator. In that case, the state of the
agent will be resumed after every call to step.
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"""
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a = 0
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class Gen(agents.BaseAgent):
def step(self):
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nonlocal a
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for i in range(5):
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yield
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a += 1
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e = environment.Environment()
g = Gen(model=e, unique_id=e.next_id())
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e.schedule.add(g)
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for i in range(5):
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e.step()
assert a == i
def test_state_decorator(self):
class MyAgent(agents.FSM):
run = 0
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@agents.default_state
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@agents.state("original")
def root(self):
self.run += 1
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return self.other
@agents.state
def other(self):
self.run += 1
e = environment.Environment()
a = MyAgent(model=e, unique_id=e.next_id())
a.step()
assert a.run == 1
a.step()
def test_broadcast(self):
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"""
An agent should be able to broadcast messages to every other agent, AND each receiver should be able
to process it
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"""
class BCast(agents.Evented):
pings_received = 0
def step(self):
print(self.model.broadcast)
try:
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self.model.broadcast("PING")
except Exception as ex:
print(ex)
while True:
self.check_messages()
yield
def on_receive(self, msg, sender=None):
self.pings_received += 1
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e = environment.EventedEnvironment()
for i in range(10):
e.add_agent(agent_class=BCast)
e.step()
pings_received = lambda: [a.pings_received for a in e.agents]
assert sorted(pings_received()) == list(range(1, 11))
e.step()
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assert all(x == 10 for x in pings_received())
def test_ask_messages(self):
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"""
An agent should be able to ask another agent, and wait for a response.
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"""
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# There are two agents, they try to send pings
# This is arguably a very contrived example. In practice, the or
# There should be a delay of one step between agent 0 and 1
# On the first step:
# Agent 0 sends a PING, but blocks before a PONG
# Agent 1 detects the PING, responds with a PONG, and blocks after its own PING
# After that step, every agent can both receive (there are pending messages) and send.
# In each step, for each agent, one message is sent, and another one is received
# (although not necessarily in that order).
# Results depend on ordering (agents are normally shuffled)
# so we force the timedactivation not to be shuffled
pings = []
pongs = []
responses = []
class Ping(agents.EventedAgent):
def step(self):
target_id = (self.unique_id + 1) % self.count_agents()
target = self.model.agents[target_id]
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print("starting")
while True:
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if pongs or not pings: # First agent, or anyone after that
pings.append(self.now)
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response = yield target.ask("PING")
responses.append(response)
else:
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print("NOT sending ping")
print("Checking msgs")
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# Do not block if we have already received a PING
if not self.check_messages():
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yield self.received()
print("done")
def on_receive(self, msg, sender=None):
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if msg == "PING":
pongs.append(self.now)
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return "PONG"
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raise Exception("This should never happen")
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e = environment.EventedEnvironment(schedule_class=stime.OrderedTimedActivation)
for i in range(2):
e.add_agent(agent_class=Ping)
assert e.now == 0
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for i in range(5):
e.step()
time = i + 1
assert e.now == time
assert len(pings) == 2 * time
assert len(pongs) == (2 * time) - 1
# Every step between 0 and t appears twice
assert sum(pings) == sum(range(time)) * 2
# It is the same as pings, without the leading 0
assert sum(pongs) == sum(range(time)) * 2