I need to calculate standard deviations across large datasets. I've got about 30 GB of raw data, and I want to calculate standard deviation for about a dozen different fields across about 500 million records. I'd like to stream the data and process it as I go for performance reasons. Looking at other Stack Overflow questions, Welford's online algorithm seems to be the way to go for this. I'm actually using C#, but this question isn't C# specific.

Welford's algorithm is said to be very numerically stable, but I'm a bit concerned about the way it updates the mean as it goes along. Here's the full algorithm as expressed on Wikipedia, in Python:

```
# for a new value newValue, compute the new count, new mean, the new M2.
# mean accumulates the mean of the entire dataset
# M2 aggregates the squared distance from the mean
# count aggregates the number of samples seen so far
def update(existingAggregate, newValue):
(count, mean, M2) = existingAggregate
count += 1
delta = newValue - mean
mean += delta / count
delta2 = newValue - mean
M2 += delta * delta2
return (count, mean, M2)
# retrieve the mean, variance and sample variance from an aggregate
def finalize(existingAggregate):
(count, mean, M2) = existingAggregate
(mean, variance, sampleVariance) = (mean, M2/count, M2/(count - 1))
if count < 2:
return float('nan')
else:
return (mean, variance, sampleVariance)
```

The step I'm concerned about is this:

```
mean += delta / count
```

Once I'm getting up into the 10s or 100s of millions of records being processed, I'm going to be updating the mean by adding a *tiny* increment relative to the existing mean. It seems like the incremental updates to the mean would easily get truncated by limited floating-point precision.

If the updates are being completely truncated, is it possible that a slowly increasing trend in the mean value towards the tail end of the data set might not actually be recorded in the running mean?

Does this algorithm need to use something like Kahan compensated summation when updating the mean, to work correctly on large datasets? Or is there something I'm overlooking in the algorithm which makes it numerically stable for large data sets, even without using compensated summation?