**This is perfectly accurate:**

Consider each element in `x[1:] + x[:-1]`

. So consider `x₀`

and `x₁`

, the first and second elements.

`x₀ + x₁`

is calculated to perfect precision and *then* rounded, in accordance to IEEE. It would therefore be the correct answer if that was all that was needed.

`(x₀ + x₁) / 2`

is just half of that value. This can almost always be done by reducing the exponent by one, except in two cases:

`x₀ + x₁`

overflows. This will result in an infinity (of either sign). That's not what is wanted, so the calculation will be **wrong**.

`x₀ + x₁`

underflows. As the size is *reduced*, rounding will be perfect and thus the calculation will be **correct**.

In all other cases, the calculation will be **correct**.

Now consider `x[:-1] + numpy.diff(x) / 2`

. This, by inspection of the source, evaluates directly to

```
x[:-1] + (x[1:] - x[:-1]) / 2
```

and so consider again `x₀`

and `x₁`

.

`x₁ - x₀`

will have severe "problems" with *underflow* for many values. This will also lose precision with large cancellations. It's not immediately clear that this doesn't matter if the signs are the same, though, as the error effectively cancels out on addition. What does matter is that *rounding occurs*.

`(x₁ - x₀) / 2`

will be no less rounded, but then `x₀ + (x₁ - x₀) / 2`

involves *another* rounding. This means that errors *will* creep in. Proof:

```
import numpy
wins = draws = losses = 0
for _ in range(100000):
a = numpy.random.random()
b = numpy.random.random() / 0.146
x = (a+b)/2
y = a + (b-a)/2
error_mine = (a-x) - (x-b)
error_theirs = (a-y) - (y-b)
if x != y:
if abs(error_mine) < abs(error_theirs):
wins += 1
elif abs(error_mine) == abs(error_theirs):
draws += 1
else:
losses += 1
else:
draws += 1
wins / 1000
#>>> 12.44
draws / 1000
#>>> 87.56
losses / 1000
#>>> 0.0
```

This shows that for the carefully chosen constant of `1.46`

, a full 12-13% of answers are wrong with the `diff`

variant! As expected, my version is always right.

Now consider *underflow*. Although my variant has overflow problems, these are much less big a deal than cancellation problems. It should be obvious why the double-rounding from the above logic is very problematic. Proof:

```
...
a = numpy.random.random()
b = -numpy.random.random()
...
wins / 1000
#>>> 25.149
draws / 1000
#>>> 74.851
losses / 1000
#>>> 0.0
```

Yeah, it gets 25% wrong!

In fact, it doesn't take much pruning to get this up to 50%:

```
...
a = numpy.random.random()
b = -a + numpy.random.random()/256
...
wins / 1000
#>>> 49.188
draws / 1000
#>>> 50.812
losses / 1000
#>>> 0.0
```

Well, it's not that bad. It's only ever 1 least-significant-bit off *as long as the signs are the same*, I think.