In the interactive theorem prover Coq, any interactive proof or definition can be terminated with either `Qed`

or `Defined`

. There is some concept of "opacity" which `Qed`

enforces but `Defined`

does not. For instance, the book *Certified Programming with Dependent Types*, by Adam Chlipala, states:

We end the "proof" with

`Defined`

instead of`Qed`

, so that the definition we constructed remains visible. This contrasts to the case of ending a proof with`Qed`

, where the details of the proof are hidden afterward. (More formally,`Defined`

marks an identifier astransparent, allowing it to be unfolded; while`Qed`

marks an identifier asopaque, preventing unfolding.)

However, I'm not quite sure what this means in practice. There is a later example in which it is necessary to use `Defined`

due to the need for `Fix`

to inspect the structure of a certain proof, but I don't understand exactly what this "inspection" entails, or why it would fail if `Qed`

were used instead. (Looking at the definition of `Fix`

wasn't exactly enlightening either).

Superficially, it's hard to tell what `Qed`

is actually doing. For instance, if I write:

```
Definition x : bool.
exact false.
Qed.
```

I can still see the value of `x`

by executing the command `Print x.`

In addition, I'm allowed later to pattern-match on the "opaque" value of `x`

:

```
Definition not_x : bool :=
match x with
| true => false
| false => true
end.
```

Therefore it seems like I'm able to use the value of `x`

just fine. What does Prof. Chlipala mean by "unfolding" here? What exactly is the difference between an opaque and a transparent difference? Most importantly, what is special about `Fix`

that makes this matter?

`x`

is transparent,`not_x`

evaluates to`true`

. If`x`

is opaque,`not_x`

evaluates to`if x then false else true`

. Use the command`Eval lazy in not_x`

.