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fix(frontends/lean): avoid superfluous local references of the form @-1 (@ f),

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This kind of term also confuses the elaborator
This commit is contained in:
Leonardo de Moura 2014-10-04 07:55:32 -07:00
parent e71d4548de
commit bf01cfeec5
3 changed files with 541 additions and 2 deletions
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9
src/frontends/lean/decl_cmds.cpp
View file

@ -364,8 +364,13 @@ environment definition_cmd_core(parser & p, bool is_theorem, bool is_opaque, boo
remove_section_variables(p, section_ps);
for (expr & param : section_ps)
param = mk_explicit(param);
expr ref = mk_implicit(mk_app(mk_explicit(mk_constant(real_n, section_ls)), section_ps));
p.add_local_expr(n, ref);
if (!section_ps.empty()) {
expr ref = mk_implicit(mk_app(mk_explicit(mk_constant(real_n, section_ls)), section_ps));
p.add_local_expr(n, ref);
} else if (section_ls) {
expr ref = mk_constant(real_n, section_ls);
p.add_local_expr(n, ref);
}
} else {
update_univ_parameters(ls_buffer, collect_univ_params(value, collect_univ_params(type)), p);
ls = to_list(ls_buffer.begin(), ls_buffer.end());

2
src/frontends/lean/inductive_cmd.cpp
View file

@ -430,6 +430,8 @@ struct inductive_cmd_fn {
section parameters \c section_params as arguments.
*/
expr fix_inductive_occs(expr const & type, buffer<inductive_decl> const & decls, buffer<expr> const & section_params) {
if (section_params.empty())
return type;
return replace(type, [&](expr const & e) {
if (!is_constant(e))
return none_expr();

532
tests/lean/slow/cat_sec_var_bug.lean Normal file
View file

@ -0,0 +1,532 @@
-- Copyright (c) 2014 Floris van Doorn. All rights reserved.
-- Released under Apache 2.0 license as described in the file LICENSE.
-- Author: Floris van Doorn
-- category
import logic.core.eq logic.core.connectives
import data.unit data.sigma data.prod
import algebra.function
import logic.axioms.funext
open eq eq.ops
inductive category [class] (ob : Type) : Type :=
mk : Π (hom : ob → ob → Type) (comp : Π⦃a b c : ob⦄, hom b c → hom a b → hom a c)
(id : Π {a : ob}, hom a a),
(Π ⦃a b c d : ob⦄ {h : hom c d} {g : hom b c} {f : hom a b},
comp h (comp g f) = comp (comp h g) f) →
(Π ⦃a b : ob⦄ {f : hom a b}, comp id f = f) →
(Π ⦃a b : ob⦄ {f : hom a b}, comp f id = f) →
category ob
inductive Category : Type := mk : Π (ob : Type), category ob → Category
namespace category
section
parameters {ob : Type} {C : category ob}
variables {a b c d : ob}
definition hom : ob → ob → Type := rec (λ hom compose id assoc idr idl, hom) C
definition compose : Π {a b c : ob}, hom b c → hom a b → hom a c :=
rec (λ hom compose id assoc idr idl, compose) C
definition id : Π {a : ob}, hom a a := rec (λ hom compose id assoc idr idl, id) C
definition ID : Π (a : ob), hom a a := @id
precedence `∘` : 60
infixr `∘` := compose
infixl `=>`:25 := hom
variables {h : hom c d} {g : hom b c} {f : hom a b} {i : hom a a}
theorem assoc : Π ⦃a b c d : ob⦄ (h : hom c d) (g : hom b c) (f : hom a b),
h ∘ (g ∘ f) = (h ∘ g) ∘ f :=
rec (λ hom comp id assoc idr idl, assoc) C
theorem id_left : Π ⦃a b : ob⦄ (f : hom a b), id ∘ f = f :=
rec (λ hom comp id assoc idl idr, idl) C
theorem id_right : Π ⦃a b : ob⦄ (f : hom a b), f ∘ id = f :=
rec (λ hom comp id assoc idl idr, idr) C
theorem id_compose (a : ob) : (ID a) ∘ id = id := !id_left
theorem left_id_unique (H : Π{b} {f : hom b a}, i ∘ f = f) : i = id :=
calc
i = i ∘ id : symm !id_right
... = id : H
theorem right_id_unique (H : Π{b} {f : hom a b}, f ∘ i = f) : i = id :=
calc
i = id ∘ i : eq.symm !id_left
... = id : H
inductive is_section (f : hom a b) : Type := mk : ∀{g}, g ∘ f = id → is_section f
inductive is_retraction (f : hom a b) : Type := mk : ∀{g}, f ∘ g = id → is_retraction f
inductive is_iso (f : hom a b) : Type := mk : ∀{g}, g ∘ f = id → f ∘ g = id → is_iso f
definition retraction_of (f : hom a b) {H : is_section f} : hom b a :=
is_section.rec (λg h, g) H
definition section_of (f : hom a b) {H : is_retraction f} : hom b a :=
is_retraction.rec (λg h, g) H
definition inverse (f : hom a b) {H : is_iso f} : hom b a :=
is_iso.rec (λg h1 h2, g) H
postfix `⁻¹` := inverse
theorem id_is_iso [instance] : is_iso (ID a) :=
is_iso.mk !id_compose !id_compose
theorem inverse_compose (f : hom a b) {H : is_iso f} : f⁻¹ ∘ f = id :=
is_iso.rec (λg h1 h2, h1) H
theorem compose_inverse (f : hom a b) {H : is_iso f} : f ∘ f⁻¹ = id :=
is_iso.rec (λg h1 h2, h2) H
theorem iso_imp_retraction [instance] (f : hom a b) {H : is_iso f} : is_section f :=
is_section.mk !inverse_compose
theorem iso_imp_section [instance] (f : hom a b) {H : is_iso f} : is_retraction f :=
is_retraction.mk !compose_inverse
theorem retraction_compose (f : hom a b) {H : is_section f} : retraction_of f ∘ f = id :=
is_section.rec (λg h, h) H
theorem compose_section (f : hom a b) {H : is_retraction f} : f ∘ section_of f = id :=
is_retraction.rec (λg h, h) H
theorem left_inverse_eq_right_inverse {f : hom a b} {g g' : hom b a}
(Hl : g ∘ f = id) (Hr : f ∘ g' = id) : g = g' :=
calc
g = g ∘ id : symm !id_right
... = g ∘ f ∘ g' : {symm Hr}
... = (g ∘ f) ∘ g' : !assoc
... = id ∘ g' : {Hl}
... = g' : !id_left
theorem section_eq_retraction {Hl : is_section f} {Hr : is_retraction f} :
retraction_of f = section_of f :=
left_inverse_eq_right_inverse !retraction_compose !compose_section
theorem section_retraction_imp_iso {Hl : is_section f} {Hr : is_retraction f} : is_iso f :=
is_iso.mk (subst section_eq_retraction !retraction_compose) !compose_section
theorem inverse_unique (H H' : is_iso f) : @inverse _ _ f H = @inverse _ _ f H' :=
left_inverse_eq_right_inverse !inverse_compose !compose_inverse
theorem retraction_of_id : retraction_of (ID a) = id :=
left_inverse_eq_right_inverse !retraction_compose !id_compose
theorem section_of_id : section_of (ID a) = id :=
symm (left_inverse_eq_right_inverse !id_compose !compose_section)
theorem iso_of_id : ID a⁻¹ = id :=
left_inverse_eq_right_inverse !inverse_compose !id_compose
theorem composition_is_section [instance] {Hf : is_section f} {Hg : is_section g}
: is_section (g ∘ f) :=
is_section.mk
(calc
(retraction_of f ∘ retraction_of g) ∘ g ∘ f
= retraction_of f ∘ retraction_of g ∘ g ∘ f : symm !assoc
... = retraction_of f ∘ (retraction_of g ∘ g) ∘ f : {!assoc}
... = retraction_of f ∘ id ∘ f : {!retraction_compose}
... = retraction_of f ∘ f : {!id_left}
... = id : !retraction_compose)
theorem composition_is_retraction [instance] (Hf : is_retraction f) (Hg : is_retraction g)
: is_retraction (g ∘ f) :=
is_retraction.mk
(calc
(g ∘ f) ∘ section_of f ∘ section_of g = g ∘ f ∘ section_of f ∘ section_of g : symm !assoc
... = g ∘ (f ∘ section_of f) ∘ section_of g : {!assoc}
... = g ∘ id ∘ section_of g : {!compose_section}
... = g ∘ section_of g : {!id_left}
... = id : !compose_section)
theorem composition_is_inverse [instance] (Hf : is_iso f) (Hg : is_iso g) : is_iso (g ∘ f) :=
section_retraction_imp_iso
definition mono (f : hom a b) : Prop := ∀⦃c⦄ {g h : hom c a}, f ∘ g = f ∘ h → g = h
definition epi (f : hom a b) : Prop := ∀⦃c⦄ {g h : hom b c}, g ∘ f = h ∘ f → g = h
theorem section_is_mono (f : hom a b) {H : is_section f} : mono f :=
λ C g h H,
calc
g = id ∘ g : symm !id_left
... = (retraction_of f ∘ f) ∘ g : {symm !retraction_compose}
... = retraction_of f ∘ f ∘ g : symm !assoc
... = retraction_of f ∘ f ∘ h : {H}
... = (retraction_of f ∘ f) ∘ h : !assoc
... = id ∘ h : {!retraction_compose}
... = h : !id_left
theorem retraction_is_epi (f : hom a b) {H : is_retraction f} : epi f :=
λ C g h H,
calc
g = g ∘ id : symm !id_right
... = g ∘ f ∘ section_of f : {symm !compose_section}
... = (g ∘ f) ∘ section_of f : !assoc
... = (h ∘ f) ∘ section_of f : {H}
... = h ∘ f ∘ section_of f : symm !assoc
... = h ∘ id : {!compose_section}
... = h : !id_right
end
section
definition objects [coercion] (C : Category) : Type
:= Category.rec (fun c s, c) C
definition category_instance [instance] (C : Category) : category (objects C)
:= Category.rec (fun c s, s) C
end
end category
open category
inductive functor {obC obD : Type} (C : category obC) (D : category obD) : Type :=
mk : Π (obF : obC → obD) (homF : Π⦃a b : obC⦄, hom a b → hom (obF a) (obF b)),
(Π ⦃a : obC⦄, homF (ID a) = ID (obF a)) →
(Π ⦃a b c : obC⦄ {g : hom b c} {f : hom a b}, homF (g ∘ f) = homF g ∘ homF f) →
functor C D
inductive Functor (C D : Category) : Type :=
mk : functor (category_instance C) (category_instance D) → Functor C D
infixl `⇒`:25 := functor
namespace functor
section basic_functor
variables {obC obD obE : Type} {C : category obC} {D : category obD} {E : category obE}
definition object [coercion] (F : C ⇒ D) : obC → obD := rec (λ obF homF Hid Hcomp, obF) F
definition morphism [coercion] (F : C ⇒ D) : Π{a b : obC}, hom a b → hom (F a) (F b) :=
rec (λ obF homF Hid Hcomp, homF) F
theorem respect_id (F : C ⇒ D) : Π (a : obC), F (ID a) = id :=
rec (λ obF homF Hid Hcomp, Hid) F
variable G : D ⇒ E
check respect_id G
theorem respect_comp (F : C ⇒ D) : Π ⦃a b c : obC⦄ (g : hom b c) (f : hom a b),
F (g ∘ f) = F g ∘ F f :=
rec (λ obF homF Hid Hcomp, Hcomp) F
protected definition compose (G : D ⇒ E) (F : C ⇒ D) : C ⇒ E :=
functor.mk
(λx, G (F x))
(λ a b f, G (F f))
(λ a, calc
G (F (ID a)) = G id : {respect_id F a}
... = id : respect_id G (F a))
(λ a b c g f, calc
G (F (g ∘ f)) = G (F g ∘ F f) : {respect_comp F g f}
... = G (F g) ∘ G (F f) : respect_comp G (F g) (F f))
precedence `∘∘` : 60
infixr `∘∘` := compose
protected theorem assoc {obA obB obC obD : Type} {A : category obA} {B : category obB}
{C : category obC} {D : category obD} (H : C ⇒ D) (G : B ⇒ C) (F : A ⇒ B) :
H ∘∘ (G ∘∘ F) = (H ∘∘ G) ∘∘ F :=
rfl
-- later check whether we want implicit or explicit arguments here. For the moment, define both
protected definition id {ob : Type} {C : category ob} : functor C C :=
mk (λa, a) (λ a b f, f) (λ a, rfl) (λ a b c f g, rfl)
protected definition ID {ob : Type} (C : category ob) : functor C C := id
protected definition Id {C : Category} : Functor C C := Functor.mk id
protected definition iD (C : Category) : Functor C C := Functor.mk id
protected theorem id_left (F : C ⇒ D) : id ∘∘ F = F := rec (λ obF homF idF compF, rfl) F
protected theorem id_right (F : C ⇒ D) : F ∘∘ id = F := rec (λ obF homF idF compF, rfl) F
end basic_functor
section Functor
variables {C₁ C₂ C₃ C₄: Category} --(G : Functor D E) (F : Functor C D)
definition Functor_functor (F : Functor C₁ C₂) :
functor (category_instance C₁) (category_instance C₂) :=
Functor.rec (λ x, x) F
protected definition Compose (G : Functor C₂ C₃) (F : Functor C₁ C₂) : Functor C₁ C₃ :=
Functor.mk (compose (Functor_functor G) (Functor_functor F))
-- namespace Functor
precedence `∘∘` : 60
infixr `∘∘` := Compose
-- end Functor
protected definition Assoc (H : Functor C₃ C₄) (G : Functor C₂ C₃) (F : Functor C₁ C₂)
: H ∘∘ (G ∘∘ F) = (H ∘∘ G) ∘∘ F :=
rfl
protected theorem Id_left (F : Functor C₁ C₂) : Id ∘∘ F = F :=
Functor.rec (λ f, subst !id_left rfl) F
protected theorem Id_right {F : Functor C₁ C₂} : F ∘∘ Id = F :=
Functor.rec (λ f, subst !id_right rfl) F
end Functor
end functor
open functor
inductive natural_transformation {obC obD : Type} {C : category obC} {D : category obD}
(F G : functor C D) : Type :=
mk : Π (η : Π(a : obC), hom (object F a) (object G a)), (Π{a b : obC} (f : hom a b), morphism G f ∘ η a = η b ∘ morphism F f)
→ natural_transformation F G
-- inductive Natural_transformation {C D : Category} (F G : Functor C D) : Type :=
-- mk : natural_transformation (Functor_functor F) (Functor_functor G) → Natural_transformation F G
infixl `==>`:25 := natural_transformation
namespace natural_transformation
section
parameters {obC obD : Type} {C : category obC} {D : category obD} {F G : C ⇒ D}
definition natural_map [coercion] (η : F ==> G) :
Π(a : obC), hom (object F a) (object G a) :=
rec (λ x y, x) η
definition naturality (η : F ==> G) :
Π{a b : obC} (f : hom a b), morphism G f ∘ η a = η b ∘ morphism F f :=
rec (λ x y, y) η
end
section
parameters {obC obD : Type} {C : category obC} {D : category obD} {F G H : C ⇒ D}
protected definition compose (η : G ==> H) (θ : F ==> G) : F ==> H :=
natural_transformation.mk
(λ a, η a ∘ θ a)
(λ a b f,
calc
morphism H f ∘ (η a ∘ θ a) = (morphism H f ∘ η a) ∘ θ a : !assoc
... = (η b ∘ morphism G f) ∘ θ a : {naturality η f}
... = η b ∘ (morphism G f ∘ θ a) : symm !assoc
... = η b ∘ (θ b ∘ morphism F f) : {naturality θ f}
... = (η b ∘ θ b) ∘ morphism F f : !assoc)
end
precedence `∘n` : 60
infixr `∘n` := compose
section
variables {obC obD : Type} {C : category obC} {D : category obD} {F₁ F₂ F₃ F₄ : C ⇒ D}
protected theorem assoc (η₃ : F₃ ==> F₄) (η₂ : F₂ ==> F₃) (η₁ : F₁ ==> F₂) :
η₃ ∘n (η₂ ∘n η₁) = (η₃ ∘n η₂) ∘n η₁ :=
congr_arg2_dep mk (funext (take x, !assoc)) proof_irrel
--TODO: check whether some of the below identities are superfluous
protected definition id {obC obD : Type} {C : category obC} {D : category obD} {F : C ⇒ D}
: natural_transformation F F :=
mk (λa, id) (λa b f, !id_right ⬝ symm !id_left)
protected definition ID {obC obD : Type} {C : category obC} {D : category obD} (F : C ⇒ D)
: natural_transformation F F := id
-- protected definition Id {C D : Category} {F : Functor C D} : Natural_transformation F F :=
-- Natural_transformation.mk id
-- protected definition iD {C D : Category} (F : Functor C D) : Natural_transformation F F :=
-- Natural_transformation.mk id
protected theorem id_left (η : F₁ ==> F₂) : natural_transformation.compose id η = η :=
rec (λf H, congr_arg2_dep mk (funext (take x, !id_left)) proof_irrel) η
protected theorem id_right (η : F₁ ==> F₂) : natural_transformation.compose η id = η :=
rec (λf H, congr_arg2_dep mk (funext (take x, !id_right)) proof_irrel) η
end
end natural_transformation
-- examples of categories / basic constructions (TODO: move to separate file)
open functor
namespace category
section
open unit
definition one [instance] : category unit :=
category.mk (λa b, unit) (λ a b c f g, star) (λ a, star) (λ a b c d f g h, unit.equal _ _)
(λ a b f, unit.equal _ _) (λ a b f, unit.equal _ _)
end
section
open unit
definition big_one_test (A : Type) : category A :=
category.mk (λa b, unit) (λ a b c f g, star) (λ a, star) (λ a b c d f g h, unit.equal _ _)
(λ a b f, unit.equal _ _) (λ a b f, unit.equal _ _)
end
section
parameter {ob : Type}
definition opposite (C : category ob) : category ob :=
category.mk (λa b, hom b a) (λ a b c f g, g ∘ f) (λ a, id) (λ a b c d f g h, symm !assoc)
(λ a b f, !id_right) (λ a b f, !id_left)
precedence `∘op` : 60
infixr `∘op` := @compose _ (opposite _) _ _ _
parameters {C : category ob} {a b c : ob}
theorem compose_op {f : @hom ob C a b} {g : hom b c} : f ∘op g = g ∘ f :=
rfl
theorem op_op {C : category ob} : opposite (opposite C) = C :=
category.rec (λ hom comp id assoc idl idr, refl (mk _ _ _ _ _ _)) C
end
definition Opposite (C : Category) : Category :=
Category.mk (objects C) (opposite (category_instance C))
section
definition type_category : category Type :=
mk (λA B, A → B) (λ a b c, function.compose) (λ a, function.id)
(λ a b c d h g f, symm (function.compose_assoc h g f))
(λ a b f, function.compose_id_left f) (λ a b f, function.compose_id_right f)
end
section cat_C
definition C : category Category :=
mk (λ a b, Functor a b) (λ a b c g f, functor.Compose g f) (λ a, functor.Id)
(λ a b c d h g f, !functor.Assoc) (λ a b f, !functor.Id_left)
(λ a b f, !functor.Id_right)
end cat_C
section functor_category
parameters {obC obD : Type} (C : category obC) (D : category obD)
definition functor_category : category (functor C D) :=
mk (λa b, natural_transformation a b)
(λ a b c g f, natural_transformation.compose g f)
(λ a, natural_transformation.id)
(λ a b c d h g f, !natural_transformation.assoc)
(λ a b f, !natural_transformation.id_left)
(λ a b f, !natural_transformation.id_right)
end functor_category
section slice
open sigma
definition slice {ob : Type} (C : category ob) (c : ob) : category (Σ(b : ob), hom b c) :=
mk (λa b, Σ(g : hom (dpr1 a) (dpr1 b)), dpr2 b ∘ g = dpr2 a)
(λ a b c g f, dpair (dpr1 g ∘ dpr1 f)
(show dpr2 c ∘ (dpr1 g ∘ dpr1 f) = dpr2 a,
proof
calc
dpr2 c ∘ (dpr1 g ∘ dpr1 f) = (dpr2 c ∘ dpr1 g) ∘ dpr1 f : !assoc
... = dpr2 b ∘ dpr1 f : {dpr2 g}
... = dpr2 a : {dpr2 f}
qed))
(λ a, dpair id !id_right)
(λ a b c d h g f, dpair_eq !assoc proof_irrel)
(λ a b f, sigma.equal !id_left proof_irrel)
(λ a b f, sigma.equal !id_right proof_irrel)
-- We give proof_irrel instead of rfl, to give the unifier an easier time
end slice
section coslice
open sigma
definition coslice {ob : Type} (C : category ob) (c : ob) : category (Σ(b : ob), hom c b) :=
mk (λa b, Σ(g : hom (dpr1 a) (dpr1 b)), g ∘ dpr2 a = dpr2 b)
(λ a b c g f, dpair (dpr1 g ∘ dpr1 f)
(show (dpr1 g ∘ dpr1 f) ∘ dpr2 a = dpr2 c,
proof
calc
(dpr1 g ∘ dpr1 f) ∘ dpr2 a = dpr1 g ∘ (dpr1 f ∘ dpr2 a): symm !assoc
... = dpr1 g ∘ dpr2 b : {dpr2 f}
... = dpr2 c : {dpr2 g}
qed))
(λ a, dpair id !id_left)
(λ a b c d h g f, dpair_eq !assoc proof_irrel)
(λ a b f, sigma.equal !id_left proof_irrel)
(λ a b f, sigma.equal !id_right proof_irrel)
-- theorem slice_coslice_opp {ob : Type} (C : category ob) (c : ob) :
-- coslice C c = opposite (slice (opposite C) c) :=
-- sorry
end coslice
section product
open prod
definition product {obC obD : Type} (C : category obC) (D : category obD)
: category (obC × obD) :=
mk (λa b, hom (pr1 a) (pr1 b) × hom (pr2 a) (pr2 b))
(λ a b c g f, (pr1 g ∘ pr1 f , pr2 g ∘ pr2 f) )
(λ a, (id,id))
(λ a b c d h g f, pair_eq !assoc !assoc )
(λ a b f, prod.equal !id_left !id_left )
(λ a b f, prod.equal !id_right !id_right)
end product
section arrow
open sigma eq.ops
-- theorem concat_commutative_squares {ob : Type} {C : category ob} {a1 a2 a3 b1 b2 b3 : ob}
-- {f1 : a1 => b1} {f2 : a2 => b2} {f3 : a3 => b3} {g2 : a2 => a3} {g1 : a1 => a2}
-- {h2 : b2 => b3} {h1 : b1 => b2} (H1 : f2 ∘ g1 = h1 ∘ f1) (H2 : f3 ∘ g2 = h2 ∘ f2)
-- : f3 ∘ (g2 ∘ g1) = (h2 ∘ h1) ∘ f1 :=
-- calc
-- f3 ∘ (g2 ∘ g1) = (f3 ∘ g2) ∘ g1 : assoc
-- ... = (h2 ∘ f2) ∘ g1 : {H2}
-- ... = h2 ∘ (f2 ∘ g1) : symm assoc
-- ... = h2 ∘ (h1 ∘ f1) : {H1}
-- ... = (h2 ∘ h1) ∘ f1 : assoc
-- definition arrow {ob : Type} (C : category ob) : category (Σ(a b : ob), hom a b) :=
-- mk (λa b, Σ(g : hom (dpr1 a) (dpr1 b)) (h : hom (dpr2' a) (dpr2' b)),
-- dpr3 b ∘ g = h ∘ dpr3 a)
-- (λ a b c g f, dpair (dpr1 g ∘ dpr1 f) (dpair (dpr2' g ∘ dpr2' f) (concat_commutative_squares (dpr3 f) (dpr3 g))))
-- (λ a, dpair id (dpair id (id_right ⬝ (symm id_left))))
-- (λ a b c d h g f, dtrip_eq2 assoc assoc proof_irrel)
-- (λ a b f, trip.equal2 id_left id_left proof_irrel)
-- (λ a b f, trip.equal2 id_right id_right proof_irrel)
variables {ob : Type} {C : category ob}
protected definition arrow_obs (ob : Type) (C : category ob) := Σ(a b : ob), hom a b
variables {a b : arrow_obs ob C}
protected definition src (a : arrow_obs ob C) : ob := dpr1 a
protected definition dst (a : arrow_obs ob C) : ob := dpr2' a
protected definition to_hom (a : arrow_obs ob C) : hom (src a) (dst a) := dpr3 a
protected definition arrow_hom (a b : arrow_obs ob C) : Type :=
Σ (g : hom (src a) (src b)) (h : hom (dst a) (dst b)), to_hom b ∘ g = h ∘ to_hom a
protected definition hom_src (m : arrow_hom a b) : hom (src a) (src b) := dpr1 m
protected definition hom_dst (m : arrow_hom a b) : hom (dst a) (dst b) := dpr2' m
protected definition commute (m : arrow_hom a b) : to_hom b ∘ (hom_src m) = (hom_dst m) ∘ to_hom a
:= dpr3 m
definition arrow (ob : Type) (C : category ob) : category (arrow_obs ob C) :=
mk (λa b, arrow_hom a b)
(λ a b c g f, dpair (hom_src g ∘ hom_src f) (dpair (hom_dst g ∘ hom_dst f)
(show to_hom c ∘ (hom_src g ∘ hom_src f) = (hom_dst g ∘ hom_dst f) ∘ to_hom a,
proof
calc
to_hom c ∘ (hom_src g ∘ hom_src f) = (to_hom c ∘ hom_src g) ∘ hom_src f : !assoc
... = (hom_dst g ∘ to_hom b) ∘ hom_src f : {commute g}
... = hom_dst g ∘ (to_hom b ∘ hom_src f) : symm !assoc
... = hom_dst g ∘ (hom_dst f ∘ to_hom a) : {commute f}
... = (hom_dst g ∘ hom_dst f) ∘ to_hom a : !assoc
qed)
))
(λ a, dpair id (dpair id (!id_right ⬝ (symm !id_left))))
(λ a b c d h g f, dtrip_eq_ndep !assoc !assoc proof_irrel)
(λ a b f, trip.equal_ndep !id_left !id_left proof_irrel)
(λ a b f, trip.equal_ndep !id_right !id_right proof_irrel)
end arrow
-- definition foo
-- : category (sorry) :=
-- mk (λa b, sorry)
-- (λ a b c g f, sorry)
-- (λ a, sorry)
-- (λ a b c d h g f, sorry)
-- (λ a b f, sorry)
-- (λ a b f, sorry)
end category