The answer is that, although there are no side effects in math, it is possible to mathematically model code that has side effects.

In fact, we can even pull this trick to turn impure code into pure code (without having to go to math in the first place. So, instead of the (psuedocode) function:

```
f(x) = {
y := y + x
return y
}
```

...we could write:

```
f(x, state_before) = {
let old_y = lookup_y(state_before)
let state_after = update_y(state_before, old_y + x)
let new_y = lookup_y(state_after)
return (new_y, state_after)
}
```

...which can accomplish the same thing with no side effects. Of course, the entire program would have to be rewritten to explicitly pass these state values around, and you'd need to write appropriate `lookup_`

and `update_`

functions for all mutable variables, but it's a theoretically straightforward process.

Of course, no one wants to program this way. (Haskell does something similar to simulate side effects without having them be part of the language, but a lot of work went into making it more ergonomic than this.) But because it can be done, we know that side-effects are a well-defined concept.

This means that we can prove things about languages with side-effects, provided that their specifications provide us with enough information to know how to rewrite programs in them into state-passing style.