Some background for others: when you're computing an expression of the following type directly

```
ln( exp(x_1) + exp(x_2) + ... )
```

you can run into two kinds of problems:

`exp(x_i)`

can overflow (`x_i`

is too big), resulting in numbers that you can't add together
`exp(x_i)`

can underflow (`x_i`

is too small), resulting in a bunch of zeroes

If all the values are big, or all are small, we can divide by some `exp(const)`

and add `const`

to the outside of the `ln`

to get the same value. Thus if we can pick the right `const`

, we can shift the values into some range to prevent overflow/underflow.

The OP's question is, why do we pick `max(x_i)`

for this const instead of any other value? Why don't we recursively do this calculation, picking the max out of each subset and computing the logarithm repeatedly?

The answer: **because it doesn't matter**.

The reason? Let's say `x_1 = 10`

is big, and `x_2 = -10`

is small. (These numbers aren't even very large in magnitude, right?) The expression

```
ln( exp(10) + exp(-10) )
```

will give you a value very close to 10. If you don't believe me, go try it. In fact, in general, `ln( exp(x_1) + exp(x_2) + ... )`

will give be very close to `max(x_i)`

if some particular `x_i`

is much bigger than all the others. (As an aside, this functional form, asymptotically, actually lets you mathematically pick the maximum from a set of numbers.)

Hence, the reason we pick the max instead of any other value is because the smaller values will hardly affect the result. If they underflow, they would have been too small to affect the sum anyway, because it would be dominated by the largest number and anything close to it. In computing terms, the contribution of the small numbers will be less than an ulp after computing the `ln`

. So there's no reason to waste time computing the expression for the smaller values recursively if they will be lost in your final result anyway.

If you wanted to be really persnickety about implementing this, you'd divide by `exp(max(x_i) - some_constant)`

or so to 'center' the resulting values around 1 to avoid both overflow and underflow, and that might give you a few extra digits of precision in the result. But avoiding overflow is much more important about avoiding underflow, because the former determines the result and the latter doesn't, so it's much simpler just to do it this way.