/usr/lib/python3/dist-packages/SimPy/Simulation.py is in python3-simpy 2.3.1-1.
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"""
Simulation implements SimPy Processes, Resources, Buffers, and the backbone simulation
scheduling by coroutine calls. Provides data collection through classes
Monitor and Tally.
Based on generators
"""
import random
import sys
import types
from heapq import heappush, heappop
from SimPy.Lister import Lister
from SimPy.Recording import Monitor, Tally
from SimPy.Lib import Process, SimEvent, PriorityQ, Resource, Level, \
Store, Simerror, FatalSimerror, FIFO
# Required for backward compatibility
import SimPy
import SimPy.Globals as Globals
from SimPy.Globals import initialize, simulate, now, stopSimulation, \
allEventNotices, allEventTimes, startCollection,\
_startWUStepping, _stopWUStepping, activate, reactivate
# yield keywords
hold = 1
passivate = 2
request = 3
release = 4
waitevent = 5
queueevent = 6
waituntil = 7
get = 8
put = 9
class Infinity(object):
def __cmp__(self, other):
return 1
infinity = Infinity()
def holdfunc(a):
a[0][1]._hold(a)
def requestfunc(a):
"""Handles 'yield request, self, res' and
'yield (request, self, res),(<code>,self, par)'.
<code > can be 'hold' or 'waitevent'.
"""
if type(a[0][0]) == tuple:
## Compound yield request statement
## first tuple in ((request, self, res),(xx, self, yy))
b = a[0][0]
## b[2] == res (the resource requested)
##process the first part of the compound yield statement
##a[1] is the Process instance
b[2]._request(arg = (b, a[1]))
##deal with add - on condition to command
##Trigger processes for reneging
class _Holder(Process):
"""Provides timeout process"""
def __init__(self,name,sim=None):
Process.__init__(self,name=name,sim=sim)
def trigger(self, delay):
yield hold, self, delay
if not proc in b[2].activeQ:
proc.sim.reactivate(proc)
class _EventWait(Process):
"""Provides event waiting process"""
def __init__(self,name,sim=None):
Process.__init__(self,name=name,sim=sim)
def trigger(self, event):
yield waitevent, self, event
if not proc in b[2].activeQ:
proc.eventsFired = self.eventsFired
proc.sim.reactivate(proc)
#activate it
proc = a[0][0][1] # the process to be woken up
actCode = a[0][1][0]
if actCode == hold:
proc._holder = _Holder(name = 'RENEGE - hold for %s'%proc.name,
sim=proc.sim)
## the timeout delay
proc.sim.activate(proc._holder, proc._holder.trigger(a[0][1][2]))
elif actCode == waituntil:
raise FatalSimerror('Illegal code for reneging: waituntil')
elif actCode == waitevent:
proc._holder = _EventWait(name = 'RENEGE - waitevent for %s'\
%proc.name,sim=proc.sim)
## the event
proc.sim.activate(proc._holder, proc._holder.trigger(a[0][1][2]))
elif actCode == queueevent:
raise FatalSimerror('Illegal code for reneging: queueevent')
else:
raise FatalSimerror('Illegal code for reneging %s'%actCode)
else:
## Simple yield request command
a[0][2]._request(a)
def releasefunc(a):
a[0][2]._release(a)
def passivatefunc(a):
a[0][1]._passivate(a)
def waitevfunc(a):
#if waiting for one event only (not a tuple or list)
evtpar = a[0][2]
if isinstance(evtpar, SimEvent):
a[0][2]._wait(a)
# else, if waiting for an OR of events (list / tuple):
else: #it should be a list / tuple of events
# call _waitOR for first event
evtpar[0]._waitOR(a)
def queueevfunc(a):
#if queueing for one event only (not a tuple or list)
evtpar = a[0][2]
if isinstance(evtpar, SimEvent):
a[0][2]._queue(a)
#else, if queueing for an OR of events (list / tuple):
else: #it should be a list / tuple of events
# call _queueOR for first event
evtpar[0]._queueOR(a)
def waituntilfunc(par):
par[0][1].sim._waitUntilFunc(par[0][1], par[0][2])
def getfunc(a):
"""Handles 'yield get, self, buffer, what, priority' and
'yield (get, self, buffer, what, priority),(<code>,self, par)'.
<code > can be 'hold' or 'waitevent'.
"""
if type(a[0][0]) == tuple:
## Compound yield request statement
## first tuple in ((request, self, res),(xx, self, yy))
b = a[0][0]
## b[2] == res (the resource requested)
##process the first part of the compound yield statement
##a[1] is the Process instance
b[2]._get(arg = (b, a[1]))
##deal with add - on condition to command
##Trigger processes for reneging
class _Holder(Process):
"""Provides timeout process"""
def __init__(self,**par):
Process.__init__(self,**par)
def trigger(self, delay):
yield hold, self, delay
#if not proc in b[2].activeQ:
if proc in b[2].getQ:
a[1].sim.reactivate(proc)
class _EventWait(Process):
"""Provides event waiting process"""
def __init__(self,**par):
Process.__init__(self,**par)
def trigger(self, event):
yield waitevent, self, event
if proc in b[2].getQ:
a[1].eventsFired = self.eventsFired
a[1].sim.reactivate(proc)
#activate it
proc = a[0][0][1] # the process to be woken up
actCode = a[0][1][0]
if actCode == hold:
proc._holder = _Holder(name='RENEGE - hold for %s'%proc.name,
sim=proc.sim)
## the timeout delay
a[1].sim.activate(proc._holder, proc._holder.trigger(a[0][1][2]))
elif actCode == waituntil:
raise FatalSimerror('waituntil: Illegal code for reneging: waituntil')
elif actCode == waitevent:
proc._holder = _EventWait(name="RENEGE - waitevent for%s"\
%proc.name,sim=proc.sim)
## the event
a[1].sim.activate(proc._holder, proc._holder.trigger(a[0][1][2]))
elif actCode == queueevent:
raise FatalSimerror('Illegal code for reneging: queueevent')
else:
raise FatalSimerror('Illegal code for reneging %s'%actCode)
else:
## Simple yield request command
a[0][2]._get(a)
def putfunc(a):
"""Handles 'yield put' (simple and compound hold / waitevent)
"""
if type(a[0][0]) == tuple:
## Compound yield request statement
## first tuple in ((request, self, res),(xx, self, yy))
b = a[0][0]
## b[2] == res (the resource requested)
##process the first part of the compound yield statement
##a[1] is the Process instance
b[2]._put(arg = (b, a[1]))
##deal with add - on condition to command
##Trigger processes for reneging
class _Holder(Process):
"""Provides timeout process"""
def __init__(self,**par):
Process.__init__(self,**par)
def trigger(self, delay):
yield hold, self, delay
#if not proc in b[2].activeQ:
if proc in b[2].putQ:
a[1].sim.reactivate(proc)
class _EventWait(Process):
"""Provides event waiting process"""
def __init__(self,**par):
Process.__init__(self,**par)
def trigger(self, event):
yield waitevent, self, event
if proc in b[2].putQ:
a[1].eventsFired = self.eventsFired
a[1].sim.reactivate(proc)
#activate it
proc = a[0][0][1] # the process to be woken up
actCode = a[0][1][0]
if actCode == hold:
proc._holder = _Holder(name='RENEGE - hold for %s'%proc.name,
sim=proc.sim)
## the timeout delay
a[1].sim.activate(proc._holder, proc._holder.trigger(a[0][1][2]))
elif actCode == waituntil:
raise FatalSimerror('Illegal code for reneging: waituntil')
elif actCode == waitevent:
proc._holder = _EventWait(name='RENEGE - waitevent for %s'\
%proc.name,sim=proc.sim)
## the event
a[1].sim.activate(proc._holder, proc._holder.trigger(a[0][1][2]))
elif actCode == queueevent:
raise FatalSimerror('Illegal code for reneging: queueevent')
else:
raise FatalSimerror('Illegal code for reneging %s'%actCode)
else:
## Simple yield request command
a[0][2]._put(a)
class Simulation(object):
_dispatch = {
hold: holdfunc, request: requestfunc, release: releasefunc,
passivate: passivatefunc, waitevent: waitevfunc,
queueevent: queueevfunc, waituntil: waituntilfunc, get: getfunc,
put: putfunc,
}
_commandcodes = list(_dispatch.keys())
_commandwords = {
hold: 'hold', request: 'request', release: 'release',
passivate: 'passivate', waitevent: 'waitevent',
queueevent: 'queueevent', waituntil: 'waituntil', get: 'get',
put: 'put'
}
def __init__(self):
self.initialize()
def initialize(self):
self._t = 0
self.next_time = 0
# Eventqueue stuff.
self._timestamps = []
self._sortpr = 0
self._start = False
self._stop = False
self.condQ = []
self.allMonitors = []
self.allTallies = []
def now(self):
return self._t
def stopSimulation(self):
"""Application function to stop simulation run"""
self._stop = True
def _post(self, what, at, prior = False):
"""Post an event notice for process what for time at"""
# event notices are Process instances
if at < self._t:
raise FatalSimerror('Attempt to schedule event in the past')
what._nextTime = at
self._sortpr -= 1
if prior:
# before all other event notices at this time
# heappush with highest priority value so far (negative of
# monotonely decreasing number)
# store event notice in process instance
what._rec = [at, self._sortpr, what, False]
# make event list refer to it
heappush(self._timestamps, what._rec)
else:
# heappush with lowest priority
# store event notice in process instance
what._rec = [at,-self._sortpr, what, False]
# make event list refer to it
heappush(self._timestamps, what._rec)
def _unpost(self, whom):
"""
Mark event notice for whom as cancelled if whom is a suspended process
"""
if whom._nextTime is not None: # check if whom was actually active
whom._rec[3] = True ## Mark as cancelled
whom._nextTime = None
def allEventNotices(self):
"""Returns string with eventlist as;
t1: processname, processname2
t2: processname4, processname5, . . .
. . . .
"""
ret = ''
tempList = []
tempList[:] = self._timestamps
tempList.sort()
# return only event notices which are not cancelled
tempList = [[x[0],x[2].name] for x in tempList if not x[3]]
tprev = -1
for t in tempList:
# if new time, new line
if t[0] == tprev:
# continue line
ret += ', %s'%t[1]
else:
# new time
if tprev == -1:
ret = '%s: %s' % (t[0],t[1])
else:
ret += '\n%s: %s' % (t[0],t[1])
tprev = t[0]
return ret + '\n'
def allEventTimes(self):
"""Returns list of all times for which events are scheduled.
"""
r = []
r[:] = self._timestamps
r.sort()
# return only event times of not cancelled event notices
r1 = [x[0] for x in r if not x[3]]
tprev = -1
ret = []
for t in r1:
if t == tprev:
#skip time, already in list
pass
else:
ret.append(t)
tprev = t
return ret
def activate(self, obj, process, at = 'undefined', delay = 'undefined',
prior = False):
"""Application function to activate passive process."""
if __debug__:
if not (obj.sim == self):
raise FatalSimerror('activate: Process %s not in activating '
'Simulation instance' % obj.name)
if not (type(process) == types.GeneratorType):
raise FatalSimerror('Activating function which'+
' is not a generator (contains no \'yield\')')
if not obj._terminated and not obj._nextTime:
#store generator reference in object; needed for reactivation
obj._nextpoint = process
if at == 'undefined':
at = self._t
if delay == 'undefined':
zeit = max(self._t, at)
else:
zeit = max(self._t, self._t + delay)
self._post(obj, at = zeit, prior = prior)
def reactivate(self, obj, at = 'undefined', delay = 'undefined',
prior = False):
"""Application function to reactivate a process which is active,
suspended or passive."""
# Object may be active, suspended or passive
if not obj._terminated:
a = Process('SimPysystem',sim=self)
a.cancel(obj)
# object now passive
if at == 'undefined':
at = self._t
if delay == 'undefined':
zeit = max(self._t, at)
else:
zeit = max(self._t, self._t + delay)
self._post(obj, at = zeit, prior = prior)
def startCollection(self, when = 0.0, monitors = None, tallies = None):
"""Starts data collection of all designated Monitor and Tally objects
(default = all) at time 'when'.
"""
class Starter(Process):
def collect(self, monitors, tallies):
for m in monitors:
m.reset()
for t in tallies:
t.reset()
yield hold, self
if monitors is None:
monitors = self.allMonitors
if tallies is None:
tallies = self.allTallies
if when == 0.0:
for m in monitors:
try:
ylast = m[-1][1]
empty = False
except IndexError:
empty = True
m.reset()
if not empty:
m.observe(t = now(), y = ylast)
for t in tallies:
t.reset()
else:
s = Starter(sim = self)
self.activate(s, s.collect(monitors = monitors, tallies = tallies),\
at = when, prior = True)
def _waitUntilFunc(self, proc, cond):
"""
Puts a process 'proc' waiting for a condition into a waiting queue.
'cond' is a predicate function which returns True if the condition is
satisfied.
"""
if not cond():
self.condQ.append(proc)
proc.cond = cond
# passivate calling process
proc._nextTime = None
else:
#schedule continuation of calling process
self._post(proc, at = self._t, prior = 1)
def _terminate(self, process):
"""Marks a process as terminated."""
process._nextpoint = None
process._terminated = True
process._nextTime = None
def has_events(self):
"""
Checks if there are events which can be processed. Returns ``True`` if
there are events and the simulation has not been stopped.
"""
return not self._stop and self._timestamps
def peek(self):
"""
Returns the time of the next event or infinity, if no
more events are scheduled.
"""
if not self._timestamps:
return infinity
else:
return self._timestamps[0][0]
def step(self):
"""
Executes the next uncancelled event in the eventqueue.
"""
# Fetch next process and advance its process execution method.
noActiveNotice = True
# Get an uncancelled event
while noActiveNotice:
if self._timestamps:
_tnotice, p, proc, cancelled = heappop(self._timestamps)
noActiveNotice = cancelled
else:
return None
# Advance simulation time.
proc._rec = None
self._t = _tnotice
# Execute the event. This will advance the process execution method.
try:
resultTuple = next(proc._nextpoint)
# Process the command function which has been yielded by the
# process.
if type(resultTuple[0]) == tuple:
# allowing for reneges, e.g.:
# >>> yield (request, self, res),(waituntil, self, cond)
command = resultTuple[0][0]
else:
command = resultTuple[0]
if __debug__:
if not command in self._commandcodes:
raise FatalSimerror('Illegal command: yield %s'%command)
self._dispatch[command]((resultTuple, proc))
except StopIteration:
# Process execution method has terminated.
self._terminate(proc)
# Test the conditions for all waiting processes if there are any at
# all. Where condition are satisfied, reactivate that process
# immediately and remove it from queue.
# Always test the wait conditions. They might be triggered by on a
# terminating process execution method (e.g. the above next() call
# raises the StopIteration exception)
if self.condQ:
i = 0
while i < len(self.condQ):
proc = self.condQ[i]
if proc.cond():
self.condQ.pop(i)
self.reactivate(proc)
else:
i += 1
# Return time of the next scheduled event.
#return self._timestamps[0][0] if self._timestamps else None
if self._timestamps:
return self._timestamps[0][0]
else:
return None
def simulate(self, until=0):
"""
Start the simulation and run its loop until the timeout ``until`` is
reached, stopSimulation is called, or no more events are scheduled.
"""
try:
if not self._timestamps:
return 'SimPy: No activities scheduled'
# Some speedups. Storing these values in local variables prevents
# the self-lookup. Note that this can't be done for _stop because
# this variable will get overwritten, bools are immutable.
step = self.step
timestamps = self._timestamps
while not self._stop and timestamps and timestamps[0][0] <= until:
step()
if not self._stop and timestamps:
# Timestamps left, simulation not stopped
self._t = until
return 'SimPy: Normal exit at time %s' % self._t
elif not timestamps:
# No more timestamps
return 'SimPy: No more events at time %s' % self._t
else:
# Stopped by call of stopSimulation
return 'SimPy: Run stopped at time %s' % self._t
# Delete the excepts?
except FatalSimerror as error:
raise FatalSimerror('SimPy: ' + error.value)
except Simerror as error:
return 'SimPy: ' + error.value
finally:
self._stop = True
# For backward compatibility
Globals.sim = Simulation()
peek = Globals.sim.peek
step = Globals.sim.step
allMonitors = Globals.sim.allMonitors
allTallies = Globals.sim.allTallies
# End backward compatibility
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