7e52c49dce
Prove that 'is_left_adjoint F' is a mere proposition, although this proof is commented out because it takes ~10 seconds
266 lines
9.9 KiB
Text
266 lines
9.9 KiB
Text
/-
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Copyright (c) 2015 Floris van Doorn. All rights reserved.
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Released under Apache 2.0 license as described in the file LICENSE.
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Author: Floris van Doorn
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Basic theorems about pathovers
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-/
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prelude
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import .path .equiv
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open equiv is_equiv equiv.ops
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variables {A A' : Type} {B B' : A → Type} {C : Π⦃a⦄, B a → Type}
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{a a₂ a₃ a₄ : A} {p p' : a = a₂} {p₂ : a₂ = a₃} {p₃ : a₃ = a₄}
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{b b' : B a} {b₂ b₂' : B a₂} {b₃ : B a₃} {b₄ : B a₄}
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{c : C b} {c₂ : C b₂}
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namespace eq
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inductive pathover.{l} (B : A → Type.{l}) (b : B a) : Π{a₂ : A}, a = a₂ → B a₂ → Type.{l} :=
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idpatho : pathover B b (refl a) b
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notation b `=[`:50 p:0 `]`:0 b₂:50 := pathover _ b p b₂
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definition idpo [reducible] [constructor] : b =[refl a] b :=
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pathover.idpatho b
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/- equivalences with equality using transport -/
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definition pathover_of_tr_eq [unfold 5 8] (r : p ▸ b = b₂) : b =[p] b₂ :=
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by cases p; cases r; exact idpo
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definition pathover_of_eq_tr [unfold 5 8] (r : b = p⁻¹ ▸ b₂) : b =[p] b₂ :=
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by cases p; cases r; exact idpo
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definition tr_eq_of_pathover [unfold 8] (r : b =[p] b₂) : p ▸ b = b₂ :=
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by cases r; exact idp
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definition eq_tr_of_pathover [unfold 8] (r : b =[p] b₂) : b = p⁻¹ ▸ b₂ :=
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by cases r; exact idp
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definition pathover_equiv_tr_eq [constructor] (p : a = a₂) (b : B a) (b₂ : B a₂)
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: (b =[p] b₂) ≃ (p ▸ b = b₂) :=
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begin
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fapply equiv.MK,
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{ exact tr_eq_of_pathover},
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{ exact pathover_of_tr_eq},
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{ intro r, cases p, cases r, apply idp},
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{ intro r, cases r, apply idp},
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end
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definition pathover_equiv_eq_tr [constructor] (p : a = a₂) (b : B a) (b₂ : B a₂)
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: (b =[p] b₂) ≃ (b = p⁻¹ ▸ b₂) :=
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begin
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fapply equiv.MK,
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{ exact eq_tr_of_pathover},
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{ exact pathover_of_eq_tr},
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{ intro r, cases p, cases r, apply idp},
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{ intro r, cases r, apply idp},
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end
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definition pathover_tr [unfold 5] (p : a = a₂) (b : B a) : b =[p] p ▸ b :=
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by cases p;exact idpo
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definition tr_pathover [unfold 5] (p : a = a₂) (b : B a₂) : p⁻¹ ▸ b =[p] b :=
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by cases p;exact idpo
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definition concato [unfold 12] (r : b =[p] b₂) (r₂ : b₂ =[p₂] b₃) : b =[p ⬝ p₂] b₃ :=
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pathover.rec_on r₂ r
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definition inverseo [unfold 8] (r : b =[p] b₂) : b₂ =[p⁻¹] b :=
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pathover.rec_on r idpo
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definition apdo [unfold 6] (f : Πa, B a) (p : a = a₂) : f a =[p] f a₂ :=
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eq.rec_on p idpo
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definition oap [unfold 6] {C : A → Type} (f : Πa, B a → C a) (p : a = a₂) : f a =[p] f a₂ :=
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eq.rec_on p idpo
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definition concato_eq [unfold 10] (r : b =[p] b₂) (q : b₂ = b₂') : b =[p] b₂' :=
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eq.rec_on q r
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definition eq_concato [unfold 9] (q : b = b') (r : b' =[p] b₂) : b =[p] b₂ :=
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by induction q;exact r
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-- infix `⬝` := concato
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infix `⬝o`:75 := concato
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infix `⬝op`:75 := concato_eq
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infix `⬝po`:75 := eq_concato
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-- postfix `⁻¹` := inverseo
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postfix `⁻¹ᵒ`:(max+10) := inverseo
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/- Some of the theorems analogous to theorems for = in init.path -/
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definition cono_idpo (r : b =[p] b₂) : r ⬝o idpo =[con_idp p] r :=
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pathover.rec_on r idpo
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definition idpo_cono (r : b =[p] b₂) : idpo ⬝o r =[idp_con p] r :=
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pathover.rec_on r idpo
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definition cono.assoc' (r : b =[p] b₂) (r₂ : b₂ =[p₂] b₃) (r₃ : b₃ =[p₃] b₄) :
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r ⬝o (r₂ ⬝o r₃) =[!con.assoc'] (r ⬝o r₂) ⬝o r₃ :=
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pathover.rec_on r₃ (pathover.rec_on r₂ (pathover.rec_on r idpo))
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definition cono.assoc (r : b =[p] b₂) (r₂ : b₂ =[p₂] b₃) (r₃ : b₃ =[p₃] b₄) :
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(r ⬝o r₂) ⬝o r₃ =[!con.assoc] r ⬝o (r₂ ⬝o r₃) :=
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pathover.rec_on r₃ (pathover.rec_on r₂ (pathover.rec_on r idpo))
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definition cono.right_inv (r : b =[p] b₂) : r ⬝o r⁻¹ᵒ =[!con.right_inv] idpo :=
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pathover.rec_on r idpo
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definition cono.left_inv (r : b =[p] b₂) : r⁻¹ᵒ ⬝o r =[!con.left_inv] idpo :=
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pathover.rec_on r idpo
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definition eq_of_pathover {a' a₂' : A'} (q : a' =[p] a₂') : a' = a₂' :=
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by cases q;reflexivity
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definition pathover_of_eq {a' a₂' : A'} (q : a' = a₂') : a' =[p] a₂' :=
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by cases p;cases q;exact idpo
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definition pathover_constant [constructor] (p : a = a₂) (a' a₂' : A') : a' =[p] a₂' ≃ a' = a₂' :=
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begin
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fapply equiv.MK,
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{ exact eq_of_pathover},
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{ exact pathover_of_eq},
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{ intro r, cases p, cases r, exact idp},
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{ intro r, cases r, exact idp},
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end
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definition eq_of_pathover_idp [unfold 6] {b' : B a} (q : b =[idpath a] b') : b = b' :=
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tr_eq_of_pathover q
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--should B be explicit in the next two definitions?
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definition pathover_idp_of_eq [unfold 6] {b' : B a} (q : b = b') : b =[idpath a] b' :=
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pathover_of_tr_eq q
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definition pathover_idp [constructor] (b : B a) (b' : B a) : b =[idpath a] b' ≃ b = b' :=
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equiv.MK eq_of_pathover_idp
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(pathover_idp_of_eq)
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(to_right_inv !pathover_equiv_tr_eq)
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(to_left_inv !pathover_equiv_tr_eq)
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-- definition pathover_idp (b : B a) (b' : B a) : b =[idpath a] b' ≃ b = b' :=
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-- pathover_equiv_tr_eq idp b b'
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-- definition eq_of_pathover_idp [reducible] {b' : B a} (q : b =[idpath a] b') : b = b' :=
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-- to_fun !pathover_idp q
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-- definition pathover_idp_of_eq [reducible] {b' : B a} (q : b = b') : b =[idpath a] b' :=
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-- to_inv !pathover_idp q
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definition idp_rec_on [recursor] {P : Π⦃b₂ : B a⦄, b =[idpath a] b₂ → Type}
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{b₂ : B a} (r : b =[idpath a] b₂) (H : P idpo) : P r :=
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have H2 : P (pathover_idp_of_eq (eq_of_pathover_idp r)), from
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eq.rec_on (eq_of_pathover_idp r) H,
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proof left_inv !pathover_idp r ▸ H2 qed
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definition rec_on_right [recursor] {P : Π⦃b₂ : B a₂⦄, b =[p] b₂ → Type}
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{b₂ : B a₂} (r : b =[p] b₂) (H : P !pathover_tr) : P r :=
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by cases r; exact H
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definition rec_on_left [recursor] {P : Π⦃b : B a⦄, b =[p] b₂ → Type}
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{b : B a} (r : b =[p] b₂) (H : P !tr_pathover) : P r :=
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by cases r; exact H
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--pathover with fibration B' ∘ f
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definition pathover_ap [unfold 10] (B' : A' → Type) (f : A → A') {p : a = a₂}
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{b : B' (f a)} {b₂ : B' (f a₂)} (q : b =[p] b₂) : b =[ap f p] b₂ :=
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by cases q; exact idpo
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definition pathover_of_pathover_ap (B' : A' → Type) (f : A → A') {p : a = a₂}
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{b : B' (f a)} {b₂ : B' (f a₂)} (q : b =[ap f p] b₂) : b =[p] b₂ :=
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by cases p; apply (idp_rec_on q); apply idpo
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definition pathover_compose (B' : A' → Type) (f : A → A') (p : a = a₂)
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(b : B' (f a)) (b₂ : B' (f a₂)) : b =[p] b₂ ≃ b =[ap f p] b₂ :=
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begin
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fapply equiv.MK,
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{ apply pathover_ap},
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{ apply pathover_of_pathover_ap},
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{ intro q, cases p, esimp, apply (idp_rec_on q), apply idp},
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{ intro q, cases q, exact idp},
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end
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definition apdo_con (f : Πa, B a) (p : a = a₂) (q : a₂ = a₃)
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: apdo f (p ⬝ q) = apdo f p ⬝o apdo f q :=
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by cases p; cases q; exact idp
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definition apdo_inv (f : Πa, B a) (p : a = a₂) : apdo f p⁻¹ = (apdo f p)⁻¹ᵒ :=
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by cases p; exact idp
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definition apdo_eq_pathover_of_eq_ap (f : A → A') (p : a = a₂) :
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apdo f p = pathover_of_eq (ap f p) :=
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eq.rec_on p idp
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definition pathover_of_pathover_tr (q : b =[p ⬝ p₂] p₂ ▸ b₂) : b =[p] b₂ :=
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by cases p₂;exact q
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definition pathover_tr_of_pathover {p : a = a₃} (q : b =[p ⬝ p₂⁻¹] b₂) : b =[p] p₂ ▸ b₂ :=
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by cases p₂;exact q
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definition pathover_tr_of_eq (q : b = b') : b =[p] p ▸ b' :=
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by cases q;apply pathover_tr
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definition tr_pathover_of_eq (q : b₂ = b₂') : p⁻¹ ▸ b₂ =[p] b₂' :=
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by cases q;apply tr_pathover
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variable (C)
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definition transporto (r : b =[p] b₂) (c : C b) : C b₂ :=
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by induction r;exact c
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infix `▸o`:75 := transporto _
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definition fn_tro_eq_tro_fn (C' : Π ⦃a : A⦄, B a → Type) (q : b =[p] b₂)
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(f : Π(b : B a), C b → C' b) (c : C b) : f b (q ▸o c) = (q ▸o (f b c)) :=
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by induction q;reflexivity
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variable {C}
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definition apo (f : Πa, B a → B' a) {Ha : a = a₂} (Hb : b =[Ha] b₂)
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: f a b =[Ha] f a₂ b₂ :=
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by induction Hb; exact idpo
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definition apo011 (f : Πa, B a → A') (Ha : a = a₂) (Hb : b =[Ha] b₂)
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: f a b = f a₂ b₂ :=
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by cases Hb; exact idp
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definition apo0111 (f : Πa b, C b → A') (Ha : a = a₂) (Hb : b =[Ha] b₂)
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(Hc : c =[apo011 C Ha Hb] c₂) : f a b c = f a₂ b₂ c₂ :=
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by cases Hb; apply (idp_rec_on Hc); apply idp
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definition apo11 {f : Πb, C b} {g : Πb₂, C b₂} (r : f =[p] g)
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{b : B a} {b₂ : B a₂} (q : b =[p] b₂) : f b =[apo011 C p q] g b₂ :=
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by cases r; apply (idp_rec_on q); exact idpo
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definition apdo10 {f : Πb, C b} {g : Πb₂, C b₂} (r : f =[p] g)
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(b : B a) : f b =[apo011 C p !pathover_tr] g (p ▸ b) :=
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by cases r; exact idpo
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definition apo10 {f : B a → B' a} {g : B a₂ → B' a₂} (r : f =[p] g)
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(b : B a) : f b =[p] g (p ▸ b) :=
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by cases r; exact idpo
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definition cono.right_inv_eq (q : b = b')
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: concato_eq (pathover_idp_of_eq q) q⁻¹ = (idpo : b =[refl a] b) :=
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by induction q;constructor
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definition cono.right_inv_eq' (q : b = b')
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: eq_concato q (pathover_idp_of_eq q⁻¹) = (idpo : b =[refl a] b) :=
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by induction q;constructor
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definition cono.left_inv_eq (q : b = b')
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: concato_eq (pathover_idp_of_eq q⁻¹) q = (idpo : b' =[refl a] b') :=
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by induction q;constructor
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definition cono.left_inv_eq' (q : b = b')
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: eq_concato q⁻¹ (pathover_idp_of_eq q) = (idpo : b' =[refl a] b') :=
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by induction q;constructor
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definition change_path [unfold 9] (q : p = p') (r : b =[p] b₂) : b =[p'] b₂ :=
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by induction q;exact r
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definition change_path_equiv (f : Π{a}, B a ≃ B' a) (r : b =[p] b₂) : f b =[p] f b₂ :=
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by induction r;constructor
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definition change_path_equiv' (f : Π{a}, B a ≃ B' a) (r : f b =[p] f b₂) : b =[p] b₂ :=
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(left_inv f b)⁻¹ ⬝po change_path_equiv (λa, f⁻¹ᵉ) r ⬝op left_inv f b₂
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end eq
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