While I like Martijn's answer on this, like george, I was wondering if this wouldn't be faster by using a running summation instead of applying the `sum()`

over and over again on mostly the same numbers.

Also the idea of having `None`

values as default during the ramp up phase is interesting. In fact there may be plenty of different scenarios one could conceive for moving averages. Let's split the calculation of averages into three phases:

- Ramp Up: Starting iterations where the current iteration count < window size
- Steady Progress: We have exactly window size number of elements available to calculate a normal
`average := sum(x[iteration_counter-window_size:iteration_counter])/window_size`

- Ramp Down: At the end of the input data, we could return another
`window_size - 1`

"average" numbers.

Here's a function that accepts

- Arbitrary iterables (generators are fine) as input for data
- Arbitrary window sizes >= 1
- Parameters to switch on/off production of values during the phases for Ramp Up/Down
- Callback functions for those phases to control how values are produced. This can be used to constantly provide a default (e.g.
`None`

) or to provide partial averages

Here's the code:

```
from collections import deque
def moving_averages(data, size, rampUp=True, rampDown=True):
"""Slide a window of <size> elements over <data> to calc an average
First and last <size-1> iterations when window is not yet completely
filled with data, or the window empties due to exhausted <data>, the
average is computed with just the available data (but still divided
by <size>).
Set rampUp/rampDown to False in order to not provide any values during
those start and end <size-1> iterations.
Set rampUp/rampDown to functions to provide arbitrary partial average
numbers during those phases. The callback will get the currently
available input data in a deque. Do not modify that data.
"""
d = deque()
running_sum = 0.0
data = iter(data)
# rampUp
for count in range(1, size):
try:
val = next(data)
except StopIteration:
break
running_sum += val
d.append(val)
#print("up: running sum:" + str(running_sum) + " count: " + str(count) + " deque: " + str(d))
if rampUp:
if callable(rampUp):
yield rampUp(d)
else:
yield running_sum / size
# steady
exhausted_early = True
for val in data:
exhausted_early = False
running_sum += val
#print("st: running sum:" + str(running_sum) + " deque: " + str(d))
yield running_sum / size
d.append(val)
running_sum -= d.popleft()
# rampDown
if rampDown:
if exhausted_early:
running_sum -= d.popleft()
for (count) in range(min(len(d), size-1), 0, -1):
#print("dn: running sum:" + str(running_sum) + " deque: " + str(d))
if callable(rampDown):
yield rampDown(d)
else:
yield running_sum / size
running_sum -= d.popleft()
```

It seems to be a bit faster than Martijn's version - which is far more elegant, though. Here's the test code:

```
print("")
print("Timeit")
print("-" * 80)
from itertools import islice
def window(seq, n=2):
"Returns a sliding window (of width n) over data from the iterable"
" s -> (s0,s1,...s[n-1]), (s1,s2,...,sn), ... "
it = iter(seq)
result = tuple(islice(it, n))
if len(result) == n:
yield result
for elem in it:
result = result[1:] + (elem,)
yield result
# Martijn's version:
def moving_averages_SO(values, size):
for selection in window(values, size):
yield sum(selection) / size
import timeit
problems = [int(i) for i in (10, 100, 1000, 10000, 1e5, 1e6, 1e7)]
for problem_size in problems:
print("{:12s}".format(str(problem_size)), end="")
so = timeit.repeat("list(moving_averages_SO(range("+str(problem_size)+"), 5))", number=1*max(problems)//problem_size,
setup="from __main__ import moving_averages_SO")
print("{:12.3f} ".format(min(so)), end="")
my = timeit.repeat("list(moving_averages(range("+str(problem_size)+"), 5, False, False))", number=1*max(problems)//problem_size,
setup="from __main__ import moving_averages")
print("{:12.3f} ".format(min(my)), end="")
print("")
```

And the output:

```
Timeit
--------------------------------------------------------------------------------
10 7.242 7.656
100 5.816 5.500
1000 5.787 5.244
10000 5.782 5.180
100000 5.746 5.137
1000000 5.745 5.198
10000000 5.764 5.186
```

The original question can now be solved with this function call:

```
print(list(moving_averages(range(1,11), 5,
rampUp=lambda _: None,
rampDown=False)))
```

The output:

```
[None, None, None, None, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0]
```