[did the question change? maybe i only read the start. i have updated/edited to give a better reply:]

there is no perfect solution (in constant memory) that i know of, but i can give various approaches.

first, for the basic calculation you only need the sum of all values (`sum_x`

), the sum of their squares (`sum_x2`

), and the total count (`n`

). then:

```
mean = sum_x / n
stdev = sqrt( sum_x2/n - mean^2 )
```

and all these values (`sum_x`

, `sum_x2`

, `n`

) can be updated from a stream.

the problem (as you say) is dealing with overflow and / or limited precision. you can see this if you consider floating point when `sum_x2`

is so large that the internal representation doesn't include values of the magnitude of a single squared value.

a simple way to avoid the problem is to use *exact arithmetic*, but that will be increasingly slow (and also uses O(log(n)) memory).

another way that can help is to normalise values - if you know that values are typically `X`

then you can do calculations on `x - X`

which makes the sums smaller (obviously you then add `X`

to the mean!). that helps postpone the point at which precision is lost (and can/should be combined with any other method here - when binning, for example, you can use the mean of the previous bin). see this algorithm (knuth's method) for how to do this progressively.

if you don't mind a (small constant factor) O(n) memory cost you could *restart* every `N`

values (eg million - smarter still would be to adapt this value by detecting when precision is too low), *storing previous mean and stdev and then combine for the final result* (so your mean is the appropriately weighted value from the recent running total and the old binned values).

the binning approach could probably be generalised to *multiple levels* (you start binning the bins) and would reduce to O(log(n)) memory use, but i haven't worked out the details.

finally, a more practical solution would probably be to do the initial approach for, say, 1000 values, and then start a new sum in parallel. you could display a weighted average of the two and, after another 1000 values, drop the old sums (after gradually decreasing their weight) and start a new set. so you always have two sets of sums, and display a weighted average between them, which gives continuous data that reflect the last 1000 values (only). in some cases that will be good enough, i imagine (it's not an exact value, since it's only for "recent" data, but it's smooth and representative, and uses a fixed amount of memory).

ps, something that occurred to me later - really, doing this "forever" doesn't make much sense anyway, because you'll get to a point where the values are absolutely dominated by the old data. it would be better to use a "running mean" which gives decreased weight to old values. see for example https://en.wikipedia.org/wiki/Moving_average - however, i don't know of a common equivalent to stdev.