`Ctrl+Click`

on the constant usually takes you to its definition (no matter by what means the constant was defined, be it `definition`

or `inductive`

or `fun`

). This works for types and theorems as well!

However, for things like `div`

that are defined in a type class, this takes you to the declaration instead. There are some other instances (e.g. constants that come out of locale interpretations, like `sum`

) where you also don't end up where you wanted to.

I am not aware of any unified mechanism to access definitions (at least not without diving into Isabelle's ML interfaces).

However, the typical cases are the following (assuming your constant is called `foo`

):

- For ‘normal’ definitions (using the
`definition`

command) the theorem is simply called `foo_def`

. For some other tools like `primrec`

, the `_def`

theorem is also accessible.
- For constants from typeclasses like
`(+)`

, `(*)`

, `(-)`

, `(div)`

, `(mod)`

, `gcd`

, `size`

, the name is `foo_type_def`

, where `type`

is the type in question. See for instance `plus_nat_def`

, `size_list_def`

.
- For functions defined with
`fun`

/`function`

/etc., the `_def`

theorem is hidden because it comes out of a complicated internal construction, would just be confusing to the user, and is pretty useless. I think it internally builds some kind of call graph and then defines the function through that – I am not sure about the details. In any case, for `fun`

, you should see the `foo.simps`

lemmas as definitions (or `foo.psimps`

if the function does not terminate everywhere).
- (Co-)inductive predicates (defined with
`inductive`

/`coinductive`

) are characterised by their `foo.intros`

rules. They also have `foo.simps`

though.
- Some constants (such as datatype constructors) do not have visible definitions at all. I suggest you just treat them like magically they drop out of the sky with the properties that characterise them (injectivity, exhaustiveness, etc). ;)

For functions with fancy syntax like `(+)`

, you can find out the name of the underlying constant either by `Ctrl+hovering`

over it with your mouse, or (in most cases) `Ctrl+clicking`

on it.

If all else fails, you can also look at the internal representation of the constant like this:

```
ML_val ‹@{term "(+)"}›
```

This outputs the following:

```
val it = Const ("Groups.plus_class.plus", "'a ⇒ 'a ⇒ 'a"): term
```

And so you can see that the constant's name is `plus`

(and its full name is `Groups.plus_class.plus`

). And indeed, `plus_nat_def`

gives you the definition of addition on natural numbers.

Lastly, note that sometimes people will define things one way and then add additional ‘alternative’ definitions later on by just showing the equality, e.g. `is_singleton_def`

vs. `is_singleton_altdef`

. In many cases, it is also better to work with derived properties rather than expanding the definitions all the time. Definitions can sometimes contain technical details such as ‘what does the function behave like on bad inputs’ (e.g. division by zero or logarithm of a negative number), and it is usually a good idea to avoid any dependence of your proof on such details whenever possible.