def __init__(self, eventlist=[], timelist=[], sort=False):
"""
Creates a heap for the event times and a dictionary to keep track of
of the corresponding events. The events could for instance be described
by strings. The event times are (of course) floating-point numbers.
The heap and the dict can be filled here but the input lists must be
synchronized but not necessarily created in time order - sort=True will
turn the input time list into a bona fide heap and must be used if the
inputs are not sorted beforehand.
"""
n = len(eventlist)
assert len(timelist) == n, \
"input lists are of unequal length in EventSchedule!"
# First create an eventtype dictionary with the eventtimes as keys:
self.__eventsdict = {}
for k in range(0, n): self.__eventsdict[timelist[k]] = eventlist[k]
# Then create a heap from the time list (sorted if so requested):
self.__timeheap = Heap(timelist)
if sort: self.__timeheap.sort() # sort into a bona fide heap
class EventSchedule:
"""
The class defines a schedule of events in a general discrete-event
simulation. The event times are kept in a heap; the event types are
kept in a corresponding dictionary. Safest is, of course, to assure
there are no ties among the event times.
EventSchedule is notably more efficient (=faster) than EventScheduleStack
despite the crudeness of its implementation (might be better having an
event type list shadowing the event time heap in a specific implementation
of the Heap class that does not use the built-in heapq library, but this
has not been tried). But the two classes are otherwise equivalent in
principle. All the methods of the Stack class are available for handling
the event types via EventScheduleStack, a feature which may be used for
creating subclasses to EventScheduleStack which can handle more complex
types of schedules than the ones handled by the dict-based EventSchedule.
But EventSchedule should normally be preferred!.
NB. TIES are only handled approximately in EventSchedule. The put_event
method looks for ties in the eventtimes/eventtypes dictionary. If a tie
is found, 2*(machine epsilon)*abs(eventtime) + minimum float > 0 will be
added to eventtime before placing it in the dict. If perfect handling of
ties is required, then EventScheduleStack must be used!
"""
# ------------------------------------------------------------------------------
def __init__(self, eventlist=[], timelist=[], sort=False):
"""
Creates a heap for the event times and a dictionary to keep track of
of the corresponding events. The events could for instance be described
by strings. The event times are (of course) floating-point numbers.
The heap and the dict can be filled here but the input lists must be
synchronized but not necessarily created in time order - sort=True will
turn the input time list into a bona fide heap and must be used if the
inputs are not sorted beforehand.
"""
n = len(eventlist)
assert len(timelist) == n, \
"input lists are of unequal length in EventSchedule!"
# First create an eventtype dictionary with the eventtimes as keys:
self.__eventsdict = {}
for k in range(0, n): self.__eventsdict[timelist[k]] = eventlist[k]
# Then create a heap from the time list (sorted if so requested):
self.__timeheap = Heap(timelist)
if sort: self.__timeheap.sort() # sort into a bona fide heap
# end of __init__
# ------------------------------------------------------------------------------
def put_event(self, eventtype, eventtime):
"""
Add an event to the schedule: place it in the eventtype/eventtime
dictionary and heap.
"""
eventtim = eventtime
delta = TWOMACHEPS*abs(eventtim) + MINFLOAT
while True: # Take care of ties!
if (eventtim in self.__eventsdict):
eventtim += delta
else:
break
self.__eventsdict[self.__timeheap.push(eventtim)] = eventtype
# Does it all in this nice construct due to the way the push
# method works (it returns eventtim)
# CF above
#self.__eventsdict[eventtim] = eventtype
#self.__timeheap.push(eventtim)
return eventtim
# end of put_event
# ------------------------------------------------------------------------------
def get_next_event(self):
"""
Get the next event (event type, event time) and remove it from
the schedule.
"""
try:
nexttime = self.__timeheap.shift()
except IndexError:
nexttime = None
try:
nextevent = self.__eventsdict[nexttime]
del self.__eventsdict[nexttime]
except KeyError:
nextevent = None
return nextevent, nexttime
# end of get_next_event
# ------------------------------------------------------------------------------
def show_next_event(self):
"""
Just look at the next event in the schedule (event type, event time)
without touching!
"""
try:
nexttime = self.__timeheap[0]
except IndexError:
nexttime = None
try:
nextevent = self.__eventsdict[nexttime]
except KeyError:
nextevent = None
return nextevent, nexttime
# end of show_next_event
# ------------------------------------------------------------------------------
def zap_events(self):
"""
Empty the schedule to allow for a restart. Return the length of
the heap as it was before zapping.
"""
length = self.__timeheap.zap()
self.__eventsdict = {}
return length
# end of zap_events
# ------------------------------------------------------------------------------
# end of EventSchedule
# ------------------------------------------------------------------------------
