Think of denotation as a mapping from syntax to "meaning". You'll probably see it written in double brackets so that you would read `[[3]] = 3`

as "the denotation of the syntax [the number 3] is the number 3".

A simple example is arithmetic. Usually you have a denotation like

```
[[x + y]] = [[x]] + [[y]]
```

where the `+`

on the left is a syntactic plus and the `+`

on the right the arithmetic plus. To make this more clear, we might change to a lispy syntax.

```
[[(+ x y)]] = [[x]] + [[y]]
```

Now a hugely important question to ask is what is the range (codomain) of this mapping? So far I've been assuming that it's sufficient to see it as "some mathy domain where numbers and addition live", but that is likely insufficient. Importantly, your example will break it quickly.

```
[[do X while True]] = ???
```

As we don't necessarily have a mathy domain which includes a concept of non-termination.

In Haskell, this is solved by calling the mathematical domain a "lifted" domain or a CPO domain which essentially adds non-termination directly. For instance, if your unlifted domain is the integers `I`

then the lifted domain is `⊥ + I`

where `⊥`

is called "bottom" and it *means* non-termination.

That means we might write (in Haskell syntax)

```
[[let omega = 1 + omega in omega]] = ⊥
```

Boom. We have meaning—the meaning of an infinite loop is... nothing at all!

The trick with lifted domains in Haskell is that because Haskell is lazy (non-strict) it's possible to have interesting interactions of datatypes and `⊥`

. For instance, if we have `type IntList = Cons Int IntList | Nil`

then the lifted domain over `IntList`

includes `⊥`

directly (a complete infinite loop) as well as things like `Cons ⊥ ⊥`

which are still not fully resolved, but provide more information than plain old `⊥`

.

And I write "more information" deliberately. CPOs form a partial order (that's the PO) of "definedness". `⊥`

is maximally undefined and so it's `<=`

to anything else in the CPO. Then you get stuff like `Cons ⊥ ⊥ <= Cons 3 ⊥`

which forms a chain in your partial order. You often then say that if `x <= y`

then "`y`

contains more information than `x`

" or "`y`

is more defined than `x`

".

One of the biggest points of this to me is that by defining this CPO structure in our mathy domain of denotation we can talk really precisely about the differences between strict and non-strict evaluation. In a strict language (or really, in strict domains which your language may or may not have some of), your CPOs are all "flat" in that you either have fully-defined results or `⊥`

and nothing else. Laziness occurs exactly when your CPO isn't flat.

Another important point is the notion that "you can't pattern match on bottom"... which, if we think about bottom as an infinite loop (though with this new abstract model it doesn't *have* to mean that... it could be a segfault, for instance) then this adage is nothing more than a different way of expressing the halting problem. It's consequence is that all sensible functions must be "monotonic" in that if `x <= y`

then `f x <= f y`

. If you spend some time with that notion you'll see that it outlaws functions which have different non-bottom behavior whether their arguments are bottom or not. For instance, the halting oracle is non-monotonic

```
halting (⊥) = False -- we can't pattern match on bottom!
halting _ = True
```

But the "broken halting oracle" is

```
hahahalting (⊥) = ⊥ -- we're still pattern matching,
-- but at least the behavior is right
hahahalting _ = True
```

which we write using `seq`

```
hahahalting x = x `seq` True -- valid Haskell
```

This also brings into sharp relief the dangers of non-monotonic functions, like Haskell's `spoon`

. We can write them by taking advantage of denotationally unsound exception catching... but it can cause very wonky behavior if we're not careful.

There are plenty more things you can learn from denotational semantics, so I'll offer Edward Z. Yang's notes on denotational semantics.