MathClasses.theory.ua_subalgebraT
Require Import
RelationClasses
universal_algebra ua_homomorphisms theory.categories abstract_algebra.
Require
categories.algebras.
Section subalgebras.
Context `{Algebra sign A} (P: ∀ s, A s → Type).
Fixpoint op_closed {o: OpType (sorts sign)}: op_type A o → Type :=
match o with
| ne_list.one x ⇒ P x
| ne_list.cons x y ⇒ λ d, ∀ z, P _ z → op_closed (d z)
end.
Definition op_closed_proper:
∀ (Pproper: ∀ s x x', x = x' → iffT (P s x) (P s x')) o,
∀ x x', x = x' → iffT (@op_closed o x) (@op_closed o x').
Proof with intuition.
induction o; simpl; intros x y E.
intuition.
split; intros...
apply (IHo (x z))...
apply E...
apply (IHo (y z))...
symmetry.
apply E...
Qed.
Class ClosedSubset: Type :=
{ subset_proper: ∀ s x x', x = x' → iffT (P s x) (P s x')
; subset_closed: ∀ o, op_closed (algebra_op o) }.
Context `{ClosedSubset}.
Definition carrier s := sigT (P s).
Hint Unfold carrier: typeclass_instances.
Fixpoint close_op {d}: ∀ (o: op_type A d), op_closed o → op_type carrier d :=
match d with
| ne_list.one _ ⇒ λ o c, existT _ o (c)
| ne_list.cons _ _ ⇒ λ o c X, close_op (o (projT1 X)) (c (projT1 X) (projT2 X))
end.
Global Instance impl: AlgebraOps sign carrier := λ o, close_op (algebra_op o) (subset_closed o).
Instance: ∀ d, Equiv (op_type carrier d).
intro.
apply op_type_equiv.
intro.
apply _.
Defined.
Definition close_op_proper d (o0 o1: op_type A d)
(P': op_closed o0) (Q: op_closed o1): o0 = o1 → close_op o0 P' = close_op o1 Q.
Proof with intuition.
induction d; simpl in ×...
intros [x p] [y q] U.
apply (IHd _ _ (P' x p) (Q y q)), H2...
Qed.
Global Instance subalgebra: Algebra sign carrier.
Proof. constructor. apply _. intro. apply close_op_proper, algebra_propers. Qed.
End subalgebras.
Hint Unfold carrier: typeclass_instances.
RelationClasses
universal_algebra ua_homomorphisms theory.categories abstract_algebra.
Require
categories.algebras.
Section subalgebras.
Context `{Algebra sign A} (P: ∀ s, A s → Type).
Fixpoint op_closed {o: OpType (sorts sign)}: op_type A o → Type :=
match o with
| ne_list.one x ⇒ P x
| ne_list.cons x y ⇒ λ d, ∀ z, P _ z → op_closed (d z)
end.
Definition op_closed_proper:
∀ (Pproper: ∀ s x x', x = x' → iffT (P s x) (P s x')) o,
∀ x x', x = x' → iffT (@op_closed o x) (@op_closed o x').
Proof with intuition.
induction o; simpl; intros x y E.
intuition.
split; intros...
apply (IHo (x z))...
apply E...
apply (IHo (y z))...
symmetry.
apply E...
Qed.
Class ClosedSubset: Type :=
{ subset_proper: ∀ s x x', x = x' → iffT (P s x) (P s x')
; subset_closed: ∀ o, op_closed (algebra_op o) }.
Context `{ClosedSubset}.
Definition carrier s := sigT (P s).
Hint Unfold carrier: typeclass_instances.
Fixpoint close_op {d}: ∀ (o: op_type A d), op_closed o → op_type carrier d :=
match d with
| ne_list.one _ ⇒ λ o c, existT _ o (c)
| ne_list.cons _ _ ⇒ λ o c X, close_op (o (projT1 X)) (c (projT1 X) (projT2 X))
end.
Global Instance impl: AlgebraOps sign carrier := λ o, close_op (algebra_op o) (subset_closed o).
Instance: ∀ d, Equiv (op_type carrier d).
intro.
apply op_type_equiv.
intro.
apply _.
Defined.
Definition close_op_proper d (o0 o1: op_type A d)
(P': op_closed o0) (Q: op_closed o1): o0 = o1 → close_op o0 P' = close_op o1 Q.
Proof with intuition.
induction d; simpl in ×...
intros [x p] [y q] U.
apply (IHd _ _ (P' x p) (Q y q)), H2...
Qed.
Global Instance subalgebra: Algebra sign carrier.
Proof. constructor. apply _. intro. apply close_op_proper, algebra_propers. Qed.
End subalgebras.
Hint Unfold carrier: typeclass_instances.