Using a given species of fp numbers, say float16, it is straight forward to construct sums with totally wrong results. For example, using python/numpy:

```
import numpy as np
one = np.float16(1)
ope = np.nextafter(one,one+one)
np.array((ope,one,-one,-one)).cumsum()
# array([1.001, 2. , 1. , 0. ], dtype=float16)
```

Here we have used `cumsum`

to force naive summation. Left to its own devices `numpy`

would have used a different order of summation, yielding a better answer:

```
np.array((ope,one,-one,-one)).sum()
# 0.000977
```

The above is based on cancellation. To rule out this class of examples, let us only allow non negative terms. For naive summation it is still easy to give examples with very wrong sums. The following sums 10^4 identical terms each equal to 10^-4:

```
np.full(10**4,10**-4,np.float16).cumsum()
# array([1.0e-04, 2.0e-04, 3.0e-04, ..., 2.5e-01, 2.5e-01, 2.5e-01],
dtype=float16)
```

The last term is off by a factor of 4.

Again, allowing `numpy`

to use pairwise summation gives a much better result:

```
np.full(10**4,10**-4,np.float16).sum()
# 1.0
```

It is possible to construct sums that beat pairwise summation. Choosing eps below resolution at 1 we can use 1, eps, 0, eps, 3x0, eps, 7x0, eps, 15x0, eps, ..., but this involves an insane number of terms.

My question: Using float16 and only non negative terms, how many terms are required to obtain from pairwise summation a result that is off by at least a factor of 2.

Bonus: Same question with "positive" instead of "non negative". Is it even possible?

possibleto get a result that's off by that amount. Assuming that overflow to infinity is ruled out, I think it may be impossible. (And then the next question would be whether one can put an absolute bound on the ulps error, assuming overflow is avoided.) – Mark Dickinson Sep 15 at 12:14thosesums is at least 2**-22, and so on. My suspicion is that it's going to be hard to engineer a big relative error before hitting overflow. (And everything's going to be exact until we get over 2**-14.) – Mark Dickinson Sep 15 at 12:27