From an expression f ≫ g, extract the expression representing the category instance.

(internals for @[reassoc]) Given a lemma of the form ∀ ..., f ≫ g = h, proves a new lemma of the form h : ∀ ... {W} (k), f ≫ (g ≫ k) = h ≫ k, and returns the type and proof of this lemma.

(implementation for @[reassoc]) Given a declaration named n of the form ∀ ..., f ≫ g = h, proves a new lemma named n' of the form ∀ ... {W} (k), f ≫ (g ≫ k) = h ≫ k.

The reassoc attribute can be applied to a lemma

@[reassoc]
lemma some_lemma : foo ≫ bar = baz := ...

to produce

lemma some_lemma_assoc {Y : C} (f : X ⟶ Y) : foo ≫ bar ≫ f = baz ≫ f := ...

The name of the produced lemma can be specified with @[reassoc other_lemma_name]. If simp is added first, the generated lemma will also have the simp attribute.

When declaring a class of categories, the axioms can be reformulated to be more amenable to manipulation in right associated expressions:

class some_class (C : Type) [category C] :=
(foo : Π X : C, X ⟶ X)
(bar : ∀ {X Y : C} (f : X ⟶ Y), foo X ≫ f = f ≫ foo Y)

reassoc_axiom some_class.bar

The above will produce:

lemma some_class.bar_assoc {Z : C} (g : Y ⟶ Z) :
  foo X ≫ f ≫ g = f ≫ foo Y ≫ g := ...

Here too, the reassoc attribute can be used instead. It works well when combined with simp:

attribute [simp, reassoc] some_class.bar

reassoc h, for assumption h : x ≫ y = z, creates a new assumption h : ∀ {W} (f : Z ⟶ W), x ≫ y ≫ f = z ≫ f. reassoc! h, does the same but deletes the initial h assumption. (You can also add the attribute @[reassoc] to lemmas to generate new declarations generalized in this way.)