If you have defined your `eval`

function appropriately, you can prove the property you gave in your example like this:

```
lemma Mult_comm: "eval (Mult a b) x = eval (Mult b a) x"
by simp
```

`algebra_simps`

is just a collection of basic simplification rules for groups and rings (such as the integers, in this case). They have nothing to do with this particular example. You can look at the lemmas contained by typing `thm algebra_simps`

.

For this particular proof, you don't actually need `algebra_simps`

, because commutativity of integer multiplication is already a default simplifier rule anyway.

So, to show how to use `algebra_simps`

, consider an example where you actually do need them: right distributivity of multiplication:

```
lemma Mult_distrib_right: "eval (Mult (Add a b) c) x = eval (Add (Mult a c) (Mult b c)) x"
```

If you just try `apply simp`

on this, you will get stuck with the goal

```
(eval a x + eval b x) * eval c x =
eval a x * eval c x + eval b x * eval c x
```

Luckily, the rule `algebra_simps(4)`

is a rule that says just that: `thm algebra_simps(4)`

will show you that this rule is `(?a + ?b) * ?c = ?a * ?c + ?b * ?c`

. Isabelle's simplifier will apply it automatically if you tell it to use the `algebra_simps`

rules, by doing:

```
apply (simp add: algebra_simps)
```

instead of

```
apply simp
```