## Congruence rules

As already noted in the other answers, the `if_weak_cong`

congruence rule prevents the simplifier from simplifying the branches of the if statement. In this answer, I want to elaborate a bit on the use of congruence rules by the simplifier.

For further information, see also the chapter about the Simplifier in the Isabelle/Isar Reference Manual (in particular section 9.3.2).

Congruence rules control how the simplifier descends into terms. They can be used to limit rewriting and to provide additional assumptions. By default, if the simplifier encounters a function application `s t`

it will descend both into `s`

and `t`

to rewrite them to `s'`

and `t'`

, before trying to rewrite the resulting term `s' t'`

.

For each constant (or variable) c one can register a single congruence rule. The rule `if_weak_cong`

is registered by default the constant `If`

(which is underlying the `if ... then ... else ...`

syntax):

```
?b = ?c ⟹ (if ?b then ?x else ?y) = (if ?c then ?x else ?y)
```

This reads as: "If you encounter a term `if ?b then ?x else ?y`

and `?b`

can be simplified to `?c`

, then rewrite `if ?b then ?x else ?y`

to `if ?c then ?x else ?y`

". As congruence rules *replace* the default strategy, this forbids any rewriting of `?x`

and `?y`

.

An alternative to `if_weak_cong`

is the strong congruence rule `if_cong`

:

```
⟦ ?b = ?c; (?c ⟹ ?x = ?u); (¬ ?c ⟹ ?y = ?v) ⟧
⟹ (if ?b then ?x else ?y) = (if ?c then ?u else ?v)
```

Note the two assumptions `(?c ⟹ ?x = ?u)`

and `(¬ ?c ⟹ ?y = ?v)`

: They tell the simplifier that it may assume that the condition holds (or holds not) when simplifying the left (or right) branch of the if.

As an example, consider the behaviour of the simplifier on the goal

```
if foo ∨ False then ¬foo ∨ False else foo ⟹ False
```

and assume that we know nothing about `foo`

. Then,

`apply simp`

: with the rule `if_weak_cong`

, this will be simplified to
`if foo then ¬ foo ∨ False else foo ⟹ False`

, only the condition is rewritten
`apply (simp cong del: if_weak_cong)`

: Without any congruence rule, this will be
simplified to
`if foo then ¬ foo else foo ⟹ False`

, as the condition and the branches are rewritten
`apply (simp cong: if_cong del: if_cancel)`

: With the rule `if_cong`

, this goal will
simplified to
`if foo then False else False ⟹ False`

: The condition `foo ∨ False`

will be
rewritten to `foo`

. For the two branches, the simplifier now rewrites
`foo ⟹ ¬foo ∨ False`

and `¬foo ⟹ foo ∨ False`

, both of which obviously rewrite to
False.

(I removed `if_cancel`

, which would usually solve the remaining goal completely)