It's tricky, but important, to decide correctly what **aggregate functions** should do when passed the empty set.

Sometimes it's 'intuitively obvious': What is the SUM of no elements? Zero, I'm sure everyone would readily say.

Sometimes it's less so: What is the PRODUCT of no elements? Those with some mathematical training will quickly say "one", but this is not at all obvious.

Then you get to MIN and MAX and wow! How did we get those infinities?

One way to decide what an aggregate function should do here is consider what behaviours we want to remain consistent, even with empty sets. For example, suppose we have these non-empty sets:

```
A = { 1, 2, 3 }
B = { 4, 5 }
```

Now, it's true here, and indeed for any non-empty sets, that

```
SUM(A ∪ B) = SUM({SUM(A), SUM(B)})
15 = 6 + 9
PRODUCT(A ∪ B) = PRODUCT({ PRODUCT(A), PRODUCT(B) })
120 = 6 * 20
MIN(A ∪ B) = MIN({ MIN(A), MIN(B) })
1 = MIN(1, 4)
```

Wouldn't it be nice, say the mathematicians, if these properties remain true even when one or both of the sets are empty? It surely would.

And it's maintaining *this* behaviour that decides what value we assign to `SOME_AGGREGATE_FUNCTION(∅)`

:

In order for

```
SUM(A ∪ B) = SUM({ SUM(A), SUM(B) })
```

to remain true when `A`

is empty and `B`

is not, we must have `SUM(∅) = 0`

In order for

```
PRODUCT(A ∪ B) = PRODUCT({ PRODUCT(A), PRODUCT(B) })
```

to remain true when `A`

is empty and `B`

is not, we must have `PRODUCT(∅) = 1`

And finally:

In order for

```
MIN(A ∪ B) = MIN({ MIN(A), MIN(B) })
```

to remain true when `A`

is empty and `B`

is not, we need `MIN(∅)`

to be a value which is guaranteed to be greater than any possible value in B, so that it doesn't 'interfere with' the result of `MIN(B)`

. And we get our answer: `MIN(∅) = +∞`

`Math.min/max`

doesn't work on arrays.`-2`

and`6`

? They should be`NaN`

`Math.Min`

or`Math.Max`

without any parameters?8more comments