# Statistical accumulator in Python

An statistical accumulator allows one to perform incremental calculations. For instance, for computing the arithmetic mean of a stream of numbers given at arbitrary times one could make an object which keeps track of the current number of items given, `n` and their sum, `sum`. When one requests the mean, the object simply returns `sum/n`.

An accumulator like this allows you to compute incrementally in the sense that, when given a new number, you don't need to recompute the entire sum and count.

Similar accumulators can be written for other statistics (cf. boost library for a C++ implementation).

How would you implement accumulators in Python? The code I came up with is:

``````class Accumulator(object):
"""
Used to accumulate the arithmetic mean of a stream of
numbers. This implementation does not allow to remove items
already accumulated, but it could easily be modified to do
so. also, other statistics could be accumulated.
"""
def __init__(self):
# upon initialization, the numnber of items currently
# accumulated (_n) and the total sum of the items acumulated
# (_sum) are set to zero because nothing has been accumulated
# yet.
self._n = 0
self._sum = 0.0

# the 'add' is used to add an item to this accumulator
try:
# try to convert the item to a float. If you are
# successful, add the float to the current sum and
# increase the number of accumulated items
self._sum += float(item)
self._n += 1
except ValueError:
# if you fail to convert the item to a float, simply
# ignore the exception (pass on it and do nothing)
pass

@property
def mean(self):
# the property 'mean' returns the current mean accumulated in
# the object
if self._n > 0:
# if you have more than zero items accumulated, then return
# their artithmetic average
return self._sum / self._n
else:
# if you have no items accumulated, return None (you could
# also raise an exception)
return None

# using the object:

# Create an instance of the object "Accumulator"
my_accumulator = Accumulator()
print my_accumulator.mean
# prints None because there are no items accumulated

print my_accumulator.mean
# prints 1.0

# add two (a string - it will be converted to a float)
print my_accumulator.mean
# prints 1.5

# add a 'NA' (will be ignored because it cannot be converted to float)
print my_accumulator.mean
# prints 1.5 (notice that it ignored the 'NA')
``````

Interesting design questions arise:

1. How to make the accumulator thread-safe?
2. How to safely remove items?
3. How to architect in a way that allows other statistics to be plugged in easily (a factory for statistics)
-
What is the status on an accumulator library for python? I would like to use it with PyTables. –  tlamadon Feb 22 '13 at 12:20

If I were doing this in Python, there are two things I would do differently:

1. Separate out the functionality of each accumulator.
2. Not use @property in any way you did.

For the first one, I would likely want to come up with an API for performing an accumulation, perhaps something like:

``````def add(self, num) # add a number
def compute(self) # compute the value of the accumulator
``````

Then I would create a AccumulatorRegistry that holds onto these accumulators, and allows the user to call actions and add to all of them. The code may look like:

``````class Accumulators(object):
_accumulator_library = {}

def __init__(self):
self.accumulator_library = {}
for key, value in Accumulators._accumulator_library.items():
self.accumulator_library[key] = value()

@staticmethod
def register(name, accumulator):
Accumulators._accumulator_library[name] = accumulator

for accumulator in self.accumulator_library.values():

def compute(self, name):
self.accumulator_library[name].compute()

@staticmethod
def register_decorator(name):
def _inner(cls):
Accumulators.register(name, cls)
return cls

@Accumulators.register_decorator("Mean")
class Mean(object):
def __init__(self):
self.total = 0
self.count = 0

self.count += 1
self.total += num

def compute(self):
return self.total / float(self.count)
``````

I should probably speak to your thread-safe question. Python's GIL protects you from a lot of threading issues. There are a few things you may way to do to protect yourself though:

• If not, you can wrap the operations in a lock, using the with context syntax to deal with holding the lock for you.
-
Great idea about the `register` - I agree that my initial example is too experimental. I look forward to further comments. Thanks. –  Escualo Sep 22 '10 at 23:40
I should also note that I'm making use of python 2.6+ features ;) –  Mike Axiak Sep 22 '10 at 23:44

For a generalized, threadsafe higher-level function, you could use something like the following in combination with the `Queue.Queue` class and some other bits:

``````from Queue import Empty

def Accumulator(f, q, storage):
"""Yields successive values of `f` over the accumulation of `q`.

`f` should take a single iterable as its parameter.

`q` is a Queue.Queue or derivative.

`storage` is a persistent sequence that provides an `append` method.
`collections.deque` may be particularly useful, but a `list` is quite acceptable.

>>> from Queue import Queue
>>> from collections import deque
>>> def mean(it):
...     vals = tuple(it)
...     return sum(it) / len(it)
>>> value_queue = Queue()
>>> LastThreeAverage = Accumulator(mean, value_queue, deque((), 3))
...     for value in it:
...         value_queue.put(value)
...                         args=(range(0, 12, 2), value_queue))
>>> list(LastThreeAverage)
[0, 1, 2, 4, 6, 8]
"""
try:
while True:
storage.append(q.get(timeout=0.1))
yield f(storage)
except Empty:
pass
``````

This generator function evades most of its purported responsibility by delegating it to other entities:

• It relies on `Queue.Queue` to supply its source elements in a thread-safe manner
• A `collections.deque` object can be passed in as the value of the `storage` parameter; this provides, among other things, a convenient way to only use the last `n` (in this case 3) values
• The function itself (in this case `mean`) is passed as a parameter. This will result in less-than-optimally efficient code in some cases, but is readily applied to all sorts of situations.

Note that there is a possibility of the accumulator timing out if your producer thread takes longer than 0.1 seconds per value. This is easily remedied by passing a longer timeout or by removing the timeout parameter entirely. In the latter case the function will block indefinitely at the end of the queue; this usage makes more sense in a case where it's being used in a sub thread (usually a `daemon` thread). Of course you can also parametrize the arguments that are passed to `q.get` as a fourth argument to `Accumulator`.

If you want to communicate end of queue, i.e. that there are no more values to come, from the producer thread (here `putting_thread`), you can pass and check for a sentinel value or use some other method. There is more info in this thread; I opted to write a subclass of Queue.Queue called CloseableQueue that provides a `close` method.

There are various other ways you could customize the behaviour of such a function, for example by limiting the queue size; this is just an example of usage.

### edit

As mentioned above, this loses some efficiency because of the necessity of recalculation and also, I think, doesn't really answer your question.

A generator function can also accept values through its `send` method. So you can write a mean generator function like

``````def meangen():
"""Yields the accumulated mean of sent values.

>>> g = meangen()
>>> g.send(None) # Initialize the generator
>>> g.send(4)
4.0
>>> g.send(10)
7.0
>>> g.send(-2)
4.0
"""
sum = yield(None)
count = 1
while True:
sum += yield(sum / float(count))
count += 1
``````

Here the yield expression is both bringing values —the arguments to `send`— into the function, while simultaneously passing the calculated values out as the return value of `send`.

You can pass the generator returned by a call to that function to a more optimizable accumulator generator function like this one:

``````def EfficientAccumulator(g, q):
"""Similar to Accumulator but sends values to a generator `g`.

>>> from Queue import Queue
>>> value_queue = Queue()
>>> g = meangen()
>>> g.send(None)
>>> mean_accumulator = EfficientAccumulator(g, value_queue)
...     for value in it:
...         value_queue.put(value)