lean2/hott/types/pointed.hlean
Floris van Doorn 52dd6cf90b feat(hott): Port files from other repositories to the HoTT library.
This commit adds truncated 2-quotients, groupoid quotients, Eilenberg MacLane spaces, chain complexes, the long exact sequence of homotopy groups, the Freudenthal Suspension Theorem, Whitehead's principle, and the computation of homotopy groups of almost all spheres which are known in HoTT.
2016-05-06 14:27:27 -07:00

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/-
Copyright (c) 2014-2016 Jakob von Raumer. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jakob von Raumer, Floris van Doorn
Ported from Coq HoTT
The basic definitions are in init.pointed
-/
import .equiv .nat.basic
open is_trunc eq prod sigma nat equiv option is_equiv bool unit algebra sigma.ops sum
namespace pointed
variables {A B : Type}
definition pointed_loop [instance] [constructor] (a : A) : pointed (a = a) :=
pointed.mk idp
definition pointed_fun_closed [constructor] (f : A → B) [H : pointed A] : pointed B :=
pointed.mk (f pt)
definition ploop_space [reducible] [constructor] (A : Type*) : Type* :=
pointed.mk' (point A = point A)
definition iterated_ploop_space [reducible] : → Type* → Type*
| iterated_ploop_space 0 X := X
| iterated_ploop_space (n+1) X := ploop_space (iterated_ploop_space n X)
notation `Ω` := ploop_space
notation `Ω[`:95 n:0 `] `:0 A:95 := iterated_ploop_space n A
definition is_trunc_loop [instance] [priority 1100] (A : Type*)
(n : ℕ₋₂) [H : is_trunc (n.+1) A] : is_trunc n (Ω A) :=
!is_trunc_eq
definition iterated_ploop_space_zero [unfold_full] (A : Type*)
: Ω[0] A = A := rfl
definition iterated_ploop_space_succ [unfold_full] (k : ) (A : Type*)
: Ω[succ k] A = Ω Ω[k] A := rfl
definition rfln [constructor] [reducible] {n : } {A : Type*} : Ω[n] A := pt
definition refln [constructor] [reducible] (n : ) (A : Type*) : Ω[n] A := pt
definition refln_eq_refl [unfold_full] (A : Type*) (n : ) : rfln = rfl :> Ω[succ n] A := rfl
definition iterated_loop_space [unfold 3] (A : Type) [H : pointed A] (n : ) : Type :=
Ω[n] (pointed.mk' A)
definition loop_mul {k : } {A : Type*} (mul : A → A → A) : Ω[k] A → Ω[k] A → Ω[k] A :=
begin cases k with k, exact mul, exact concat end
definition pType_eq {A B : Type*} (f : A ≃ B) (p : f pt = pt) : A = B :=
begin
cases A with A a, cases B with B b, esimp at *,
fapply apd011 @pType.mk,
{ apply ua f},
{ rewrite [cast_ua,p]},
end
definition pType_eq_elim {A B : Type*} (p : A = B :> Type*)
: Σ(p : carrier A = carrier B :> Type), Point A =[p] Point B :=
by induction p; exact ⟨idp, idpo⟩
protected definition pType.sigma_char.{u} : pType.{u} ≃ Σ(X : Type.{u}), X :=
begin
fapply equiv.MK,
{ intro x, induction x with X x, exact ⟨X, x⟩},
{ intro x, induction x with X x, exact pointed.MK X x},
{ intro x, induction x with X x, reflexivity},
{ intro x, induction x with X x, reflexivity},
end
definition add_point [constructor] (A : Type) : Type* :=
pointed.Mk (none : option A)
postfix `₊`:(max+1) := add_point
-- the inclusion A → A₊ is called "some", the extra point "pt" or "none" ("@none A")
end pointed
namespace pointed
/- truncated pointed types -/
definition ptrunctype_eq {n : ℕ₋₂} {A B : n-Type*}
(p : A = B :> Type) (q : Point A =[p] Point B) : A = B :=
begin
induction A with A HA a, induction B with B HB b, esimp at *,
induction q, esimp,
refine ap010 (ptrunctype.mk A) _ a,
exact !is_prop.elim
end
definition ptrunctype_eq_of_pType_eq {n : ℕ₋₂} {A B : n-Type*} (p : A = B :> Type*)
: A = B :=
begin
cases pType_eq_elim p with q r,
exact ptrunctype_eq q r
end
definition is_trunc_ptrunctype [instance] {n : ℕ₋₂} (A : n-Type*) : is_trunc n A :=
trunctype.struct A
/- properties of iterated loop space -/
variable (A : Type*)
definition loop_space_succ_eq_in (n : ) : Ω[succ n] A = Ω[n] (Ω A) :=
begin
induction n with n IH,
{ reflexivity},
{ exact ap ploop_space IH}
end
definition loop_space_add (n m : ) : Ω[n] (Ω[m] A) = Ω[m+n] (A) :=
begin
induction n with n IH,
{ reflexivity},
{ exact ap ploop_space IH}
end
definition loop_space_succ_eq_out (n : ) : Ω[succ n] A = Ω(Ω[n] A) :=
idp
variable {A}
/- the equality [loop_space_succ_eq_in] preserves concatenation -/
theorem loop_space_succ_eq_in_concat {n : } (p q : Ω[succ (succ n)] A) :
transport carrier (ap ploop_space (loop_space_succ_eq_in A n)) (p ⬝ q)
= transport carrier (ap ploop_space (loop_space_succ_eq_in A n)) p
⬝ transport carrier (ap ploop_space (loop_space_succ_eq_in A n)) q :=
begin
rewrite [-+tr_compose, ↑function.compose],
rewrite [+@transport_eq_FlFr_D _ _ _ _ Point Point, +con.assoc], apply whisker_left,
rewrite [-+con.assoc], apply whisker_right, rewrite [con_inv_cancel_right, ▸*, -ap_con]
end
definition loop_space_loop_irrel (p : point A = point A) : Ω(pointed.Mk p) = Ω[2] A :=
begin
intros, fapply pType_eq,
{ esimp, transitivity _,
apply eq_equiv_fn_eq_of_equiv (equiv_eq_closed_right _ p⁻¹),
esimp, apply eq_equiv_eq_closed, apply con.right_inv, apply con.right_inv},
{ esimp, apply con.left_inv}
end
definition iterated_loop_space_loop_irrel (n : ) (p : point A = point A)
: Ω[succ n](pointed.Mk p) = Ω[succ (succ n)] A :> pType :=
calc
Ω[succ n](pointed.Mk p) = Ω[n](Ω (pointed.Mk p)) : loop_space_succ_eq_in
... = Ω[n] (Ω[2] A) : loop_space_loop_irrel
... = Ω[2+n] A : loop_space_add
... = Ω[n+2] A : by rewrite [algebra.add.comm]
end pointed open pointed
namespace pointed
variables {A B C D : Type*} {f g h : A →* B}
/- categorical properties of pointed maps -/
definition pmap_of_map [constructor] {A B : Type} (f : A → B) (a : A) :
pointed.MK A a →* pointed.MK B (f a) :=
pmap.mk f idp
definition pid [constructor] [refl] (A : Type*) : A →* A :=
pmap.mk id idp
definition pcompose [constructor] [trans] (g : B →* C) (f : A →* B) : A →* C :=
pmap.mk (λa, g (f a)) (ap g (respect_pt f) ⬝ respect_pt g)
infixr ` ∘* `:60 := pcompose
definition passoc (h : C →* D) (g : B →* C) (f : A →* B) : (h ∘* g) ∘* f ~* h ∘* (g ∘* f) :=
begin
fconstructor, intro a, reflexivity,
cases A, cases B, cases C, cases D, cases f with f pf, cases g with g pg, cases h with h ph,
esimp at *,
induction pf, induction pg, induction ph, reflexivity
end
definition pid_comp [constructor] (f : A →* B) : pid B ∘* f ~* f :=
begin
fconstructor,
{ intro a, reflexivity},
{ reflexivity}
end
definition comp_pid [constructor] (f : A →* B) : f ∘* pid A ~* f :=
begin
fconstructor,
{ intro a, reflexivity},
{ reflexivity}
end
/- equivalences and equalities -/
definition pmap_eq (r : Πa, f a = g a) (s : respect_pt f = (r pt) ⬝ respect_pt g) : f = g :=
begin
cases f with f p, cases g with g q,
esimp at *,
fapply apo011 pmap.mk,
{ exact eq_of_homotopy r},
{ apply concato_eq, apply pathover_eq_Fl, apply inv_con_eq_of_eq_con,
rewrite [ap_eq_ap10,↑ap10,apd10_eq_of_homotopy,s]}
end
definition pmap_equiv_left (A : Type) (B : Type*) : A₊ →* B ≃ (A → B) :=
begin
fapply equiv.MK,
{ intro f a, cases f with f p, exact f (some a)},
{ intro f, fconstructor,
intro a, cases a, exact pt, exact f a,
reflexivity},
{ intro f, reflexivity},
{ intro f, cases f with f p, esimp, fapply pmap_eq,
{ intro a, cases a; all_goals (esimp at *), exact p⁻¹},
{ esimp, exact !con.left_inv⁻¹}},
end
definition pmap_equiv_right (A : Type*) (B : Type)
: (Σ(b : B), A →* (pointed.Mk b)) ≃ (A → B) :=
begin
fapply equiv.MK,
{ intro u a, exact pmap.to_fun u.2 a},
{ intro f, refine ⟨f pt, _⟩, fapply pmap.mk,
intro a, esimp, exact f a,
reflexivity},
{ intro f, reflexivity},
{ intro u, cases u with b f, cases f with f p, esimp at *, induction p,
reflexivity}
end
definition pmap_bool_equiv (B : Type*) : (pbool →* B) ≃ B :=
begin
fapply equiv.MK,
{ intro f, cases f with f p, exact f tt},
{ intro b, fconstructor,
intro u, cases u, exact pt, exact b,
reflexivity},
{ intro b, reflexivity},
{ intro f, cases f with f p, esimp, fapply pmap_eq,
{ intro a, cases a; all_goals (esimp at *), exact p⁻¹},
{ esimp, exact !con.left_inv⁻¹}},
end
-- The constant pointed map between any two types
definition pconst [constructor] (A B : Type*) : A →* B :=
pmap.mk (λ a, Point B) idp
-- the pointed type of pointed maps
definition ppmap [constructor] (A B : Type*) : Type* :=
pType.mk (A →* B) (pconst A B)
/- instances of pointed maps -/
definition pcast [constructor] {A B : Type*} (p : A = B) : A →* B :=
pmap.mk (cast (ap pType.carrier p)) (by induction p; reflexivity)
definition pinverse [constructor] {X : Type*} : Ω X →* Ω X :=
pmap.mk eq.inverse idp
definition ap1 [constructor] (f : A →* B) : Ω A →* Ω B :=
begin
fconstructor,
{ intro p, exact !respect_pt⁻¹ ⬝ ap f p ⬝ !respect_pt},
{ esimp, apply con.left_inv}
end
definition apn (n : ) (f : A →* B) : Ω[n] A →* Ω[n] B :=
begin
induction n with n IH,
{ exact f},
{ esimp [iterated_ploop_space], exact ap1 IH}
end
prefix `Ω→`:(max+5) := ap1
notation `Ω→[`:95 n:0 `] `:0 f:95 := apn n f
/- categorical properties of pointed homotopies -/
protected definition phomotopy.refl [constructor] [refl] (f : A →* B) : f ~* f :=
begin
fconstructor,
{ intro a, exact idp},
{ apply idp_con}
end
protected definition phomotopy.rfl [constructor] {f : A →* B} : f ~* f :=
phomotopy.refl f
protected definition phomotopy.trans [constructor] [trans] (p : f ~* g) (q : g ~* h)
: f ~* h :=
phomotopy.mk (λa, p a ⬝ q a)
abstract begin
induction f, induction g, induction p with p p', induction q with q q', esimp at *,
induction p', induction q', esimp, apply con.assoc
end end
protected definition phomotopy.symm [constructor] [symm] (p : f ~* g) : g ~* f :=
phomotopy.mk (λa, (p a)⁻¹)
abstract begin
induction f, induction p with p p', esimp at *,
induction p', esimp, apply inv_con_cancel_left
end end
infix ` ⬝* `:75 := phomotopy.trans
postfix `⁻¹*`:(max+1) := phomotopy.symm
/- properties about the given pointed maps -/
definition is_equiv_ap1 (f : A →* B) [is_equiv f] : is_equiv (ap1 f) :=
begin
induction B with B b, induction f with f pf, esimp at *, cases pf, esimp,
apply is_equiv.homotopy_closed (ap f),
intro p, exact !idp_con⁻¹
end
definition is_equiv_apn (n : ) (f : A →* B) [H : is_equiv f]
: is_equiv (apn n f) :=
begin
induction n with n IH,
{ exact H},
{ exact is_equiv_ap1 (apn n f)}
end
definition is_equiv_pcast [instance] {A B : Type*} (p : A = B) : is_equiv (pcast p) :=
!is_equiv_cast
definition ap1_id [constructor] {A : Type*} : ap1 (pid A) ~* pid (Ω A) :=
begin
fapply phomotopy.mk,
{ intro p, esimp, refine !idp_con ⬝ !ap_id},
{ reflexivity}
end
definition ap1_pinverse {A : Type*} : ap1 (@pinverse A) ~* @pinverse (Ω A) :=
begin
fapply phomotopy.mk,
{ intro p, esimp, refine !idp_con ⬝ _, exact !inv_eq_inv2⁻¹ },
{ reflexivity}
end
definition ap1_compose (g : B →* C) (f : A →* B) : ap1 (g ∘* f) ~* ap1 g ∘* ap1 f :=
begin
induction B, induction C, induction g with g pg, induction f with f pf, esimp at *,
induction pg, induction pf,
fconstructor,
{ intro p, esimp, apply whisker_left, exact ap_compose g f p ⬝ ap (ap g) !idp_con⁻¹},
{ reflexivity}
end
definition ap1_compose_pinverse (f : A →* B) : ap1 f ∘* pinverse ~* pinverse ∘* ap1 f :=
begin
fconstructor,
{ intro p, esimp, refine !con.assoc ⬝ _ ⬝ !con_inv⁻¹, apply whisker_left,
refine whisker_right !ap_inv _ ⬝ _ ⬝ !con_inv⁻¹, apply whisker_left,
exact !inv_inv⁻¹},
{ induction B with B b, induction f with f pf, esimp at *, induction pf, reflexivity},
end
theorem ap1_con (f : A →* B) (p q : Ω A) : ap1 f (p ⬝ q) = ap1 f p ⬝ ap1 f q :=
begin
rewrite [▸*,ap_con, +con.assoc, con_inv_cancel_left], repeat apply whisker_left
end
theorem ap1_inv (f : A →* B) (p : Ω A) : ap1 f p⁻¹ = (ap1 f p)⁻¹ :=
begin
rewrite [▸*,ap_inv, +con_inv, inv_inv, +con.assoc], repeat apply whisker_left
end
definition pcast_ap_loop_space {A B : Type*} (p : A = B)
: pcast (ap ploop_space p) ~* Ω→ (pcast p) :=
begin
induction p, exact !ap1_id⁻¹*
end
definition pinverse_con [constructor] {X : Type*} (p q : Ω X)
: pinverse (p ⬝ q) = pinverse q ⬝ pinverse p :=
!con_inv
definition pinverse_inv [constructor] {X : Type*} (p : Ω X)
: pinverse p⁻¹ = (pinverse p)⁻¹ :=
idp
definition pcast_idp [constructor] {A : Type*} : pcast (idpath A) ~* pid A :=
by reflexivity
definition apn_zero [unfold_full] (f : A →* B) : Ω→[0] f = f := idp
definition apn_succ [unfold_full] (n : ) (f : A →* B) : Ω→[n + 1] f = Ω→ (Ω→[n] f) := idp
/- more on pointed homotopies -/
definition phomotopy_of_eq [constructor] {A B : Type*} {f g : A →* B} (p : f = g) : f ~* g :=
phomotopy.mk (ap010 pmap.to_fun p) begin induction p, apply idp_con end
definition pconcat_eq [constructor] {A B : Type*} {f g h : A →* B} (p : f ~* g) (q : g = h)
: f ~* h :=
p ⬝* phomotopy_of_eq q
definition eq_pconcat [constructor] {A B : Type*} {f g h : A →* B} (p : f = g) (q : g ~* h)
: f ~* h :=
phomotopy_of_eq p ⬝* q
infix ` ⬝*p `:75 := pconcat_eq
infix ` ⬝p* `:75 := eq_pconcat
definition pwhisker_left [constructor] (h : B →* C) (p : f ~* g) : h ∘* f ~* h ∘* g :=
phomotopy.mk (λa, ap h (p a))
abstract begin
induction A, induction B, induction C,
induction f with f pf, induction g with g pg, induction h with h ph,
induction p with p p', esimp at *, induction ph, induction pg, induction p', reflexivity
end end
definition pwhisker_right [constructor] (h : C →* A) (p : f ~* g) : f ∘* h ~* g ∘* h :=
phomotopy.mk (λa, p (h a))
abstract begin
induction A, induction B, induction C,
induction f with f pf, induction g with g pg, induction h with h ph,
induction p with p p', esimp at *, induction ph, induction pg, induction p', esimp,
exact !idp_con⁻¹
end end
definition pconcat2 [constructor] {A B C : Type*} {h i : B →* C} {f g : A →* B}
(q : h ~* i) (p : f ~* g) : h ∘* f ~* i ∘* g :=
pwhisker_left _ p ⬝* pwhisker_right _ q
definition eq_of_phomotopy (p : f ~* g) : f = g :=
begin
fapply pmap_eq,
{ intro a, exact p a},
{ exact !to_homotopy_pt⁻¹}
end
/-
In general we need function extensionality for pap,
but for particular F we can do it without function extensionality.
-/
definition pap (F : (A →* B) → (C →* D)) {f g : A →* B} (p : f ~* g) : F f ~* F g :=
phomotopy.mk (ap010 F (eq_of_phomotopy p)) begin cases eq_of_phomotopy p, apply idp_con end
definition ap1_phomotopy {f g : A →* B} (p : f ~* g)
: ap1 f ~* ap1 g :=
begin
induction p with p q, induction f with f pf, induction g with g pg, induction B with B b,
esimp at *, induction q, induction pg,
fapply phomotopy.mk,
{ intro l, esimp, refine _ ⬝ !idp_con⁻¹, refine !con.assoc ⬝ _, apply inv_con_eq_of_eq_con,
apply ap_con_eq_con_ap},
{ unfold [ap_con_eq_con_ap], generalize p (Point A), generalize g (Point A), intro b q,
induction q, reflexivity}
end
definition apn_phomotopy {f g : A →* B} (n : ) (p : f ~* g) : apn n f ~* apn n g :=
begin
induction n with n IH,
{ exact p},
{ exact ap1_phomotopy IH}
end
definition apn_compose (n : ) (g : B →* C) (f : A →* B) : apn n (g ∘* f) ~* apn n g ∘* apn n f :=
begin
induction n with n IH,
{ reflexivity},
{ refine ap1_phomotopy IH ⬝* _, apply ap1_compose}
end
definition apn_pid [constructor] {A : Type*} (n : ) : apn n (pid A) ~* pid (Ω[n] A) :=
begin
induction n with n IH,
{ reflexivity},
{ exact ap1_phomotopy IH ⬝* ap1_id}
end
theorem apn_con (n : ) (f : A →* B) (p q : Ω[n+1] A)
: apn (n+1) f (p ⬝ q) = apn (n+1) f p ⬝ apn (n+1) f q :=
by rewrite [+apn_succ, ap1_con]
theorem apn_inv (n : ) (f : A →* B) (p : Ω[n+1] A) : apn (n+1) f p⁻¹ = (apn (n+1) f p)⁻¹ :=
by rewrite [+apn_succ, ap1_inv]
definition pinverse_pinverse (A : Type*) : pinverse ∘* pinverse ~* pid (Ω A) :=
begin
fapply phomotopy.mk,
{ apply inv_inv},
{ reflexivity}
end
definition pcast_loop_space [constructor] {A B : Type*} (p : A = B) :
pcast (ap Ω p) ~* ap1 (pcast p) :=
begin
fapply phomotopy.mk,
{ intro a, induction p, esimp, exact (!idp_con ⬝ !ap_id)⁻¹},
{ induction p, reflexivity}
end
definition apn_succ_phomotopy_in (n : ) (f : A →* B) :
pcast (loop_space_succ_eq_in B n) ∘* Ω→[n + 1] f ~*
Ω→[n] (Ω→ f) ∘* pcast (loop_space_succ_eq_in A n) :=
begin
induction n with n IH,
{ reflexivity},
{ refine pwhisker_right _ (pcast_loop_space (loop_space_succ_eq_in B n)) ⬝* _,
refine _ ⬝* pwhisker_left _ (pcast_loop_space (loop_space_succ_eq_in A n))⁻¹*,
refine (ap1_compose _ (Ω→[n + 1] f))⁻¹* ⬝* _ ⬝* ap1_compose (Ω→[n] (Ω→ f)) _,
exact ap1_phomotopy IH}
end
definition ap1_pmap_of_map [constructor] {A B : Type} (f : A → B) (a : A) :
ap1 (pmap_of_map f a) ~* pmap_of_map (ap f) (idpath a) :=
begin
fapply phomotopy.mk,
{ intro a, esimp, apply idp_con},
{ reflexivity}
end
definition pmap_of_eq_pt [constructor] {A : Type} {a a' : A} (p : a = a') :
pointed.MK A a →* pointed.MK A a' :=
pmap.mk id p
/- pointed equivalences -/
definition pequiv_of_pmap [constructor] (f : A →* B) (H : is_equiv f) : A ≃* B :=
pequiv.mk f _ (respect_pt f)
definition pequiv_of_equiv [constructor] (f : A ≃ B) (H : f pt = pt) : A ≃* B :=
pequiv.mk f _ H
protected definition pequiv.MK [constructor] (f : A →* B) (g : B → A)
(gf : Πa, g (f a) = a) (fg : Πb, f (g b) = b) : A ≃* B :=
pequiv.mk f (adjointify f g fg gf) (respect_pt f)
definition equiv_of_pequiv [constructor] (f : A ≃* B) : A ≃ B :=
equiv.mk f _
definition to_pinv [constructor] (f : A ≃* B) : B →* A :=
pmap.mk f⁻¹ ((ap f⁻¹ (respect_pt f))⁻¹ ⬝ left_inv f pt)
definition to_pmap_pequiv_of_pmap {A B : Type*} (f : A →* B) (H : is_equiv f)
: pequiv.to_pmap (pequiv_of_pmap f H) = f :=
by cases f; reflexivity
/-
A version of pequiv.MK with stronger conditions.
The advantage of defining a pointed equivalence with this definition is that there is a
pointed homotopy between the inverse of the resulting equivalence and the given pointed map g.
This is not the case when using `pequiv.MK` (if g is a pointed map),
that will only give an ordinary homotopy.
-/
protected definition pequiv.MK2 [constructor] (f : A →* B) (g : B →* A)
(gf : g ∘* f ~* !pid) (fg : f ∘* g ~* !pid) : A ≃* B :=
pequiv.MK f g gf fg
definition to_pmap_pequiv_MK2 [constructor] (f : A →* B) (g : B →* A)
(gf : g ∘* f ~* !pid) (fg : f ∘* g ~* !pid) : pequiv.MK2 f g gf fg ~* f :=
phomotopy.mk (λb, idp) !idp_con
definition to_pinv_pequiv_MK2 [constructor] (f : A →* B) (g : B →* A)
(gf : g ∘* f ~* !pid) (fg : f ∘* g ~* !pid) : to_pinv (pequiv.MK2 f g gf fg) ~* g :=
phomotopy.mk (λb, idp)
abstract [irreducible] begin
esimp, unfold [adjointify_left_inv'],
note H := to_homotopy_pt gf, note H2 := to_homotopy_pt fg,
note H3 := eq_top_of_square (natural_square_tr (to_homotopy fg) (respect_pt f)),
rewrite [▸* at *, H, H3, H2, ap_id, - +con.assoc, ap_compose' f g, con_inv,
- ap_inv, - +ap_con g],
apply whisker_right, apply ap02 g,
rewrite [ap_con, - + con.assoc, +ap_inv, +inv_con_cancel_right, con.left_inv],
end end
definition pua {A B : Type*} (f : A ≃* B) : A = B :=
pType_eq (equiv_of_pequiv f) !respect_pt
protected definition pequiv.refl [refl] [constructor] (A : Type*) : A ≃* A :=
pequiv_of_pmap !pid !is_equiv_id
protected definition pequiv.rfl [constructor] : A ≃* A :=
pequiv.refl A
protected definition pequiv.symm [symm] (f : A ≃* B) : B ≃* A :=
pequiv_of_pmap (to_pinv f) !is_equiv_inv
protected definition pequiv.trans [trans] (f : A ≃* B) (g : B ≃* C) : A ≃* C :=
pequiv_of_pmap (g ∘* f) !is_equiv_compose
postfix `⁻¹ᵉ*`:(max + 1) := pequiv.symm
infix ` ⬝e* `:75 := pequiv.trans
definition to_pmap_pequiv_trans {A B C : Type*} (f : A ≃* B) (g : B ≃* C)
: pequiv.to_pmap (f ⬝e* g) = g ∘* f :=
!to_pmap_pequiv_of_pmap
definition pequiv_change_fun [constructor] (f : A ≃* B) (f' : A →* B) (Heq : f ~ f') : A ≃* B :=
pequiv_of_pmap f' (is_equiv.homotopy_closed f Heq)
definition pequiv_change_inv [constructor] (f : A ≃* B) (f' : B →* A) (Heq : to_pinv f ~ f')
: A ≃* B :=
pequiv.MK f f' (to_left_inv (equiv_change_inv f Heq)) (to_right_inv (equiv_change_inv f Heq))
definition pequiv_rect' (f : A ≃* B) (P : A → B → Type)
(g : Πb, P (f⁻¹ b) b) (a : A) : P a (f a) :=
left_inv f a ▸ g (f a)
definition pequiv_of_eq [constructor] {A B : Type*} (p : A = B) : A ≃* B :=
pequiv_of_pmap (pcast p) !is_equiv_tr
definition peconcat_eq {A B C : Type*} (p : A ≃* B) (q : B = C) : A ≃* C :=
p ⬝e* pequiv_of_eq q
definition eq_peconcat {A B C : Type*} (p : A = B) (q : B ≃* C) : A ≃* C :=
pequiv_of_eq p ⬝e* q
definition eq_of_pequiv {A B : Type*} (p : A ≃* B) : A = B :=
pType_eq (equiv_of_pequiv p) !respect_pt
definition peap {A B : Type*} (F : Type* → Type*) (p : A ≃* B) : F A ≃* F B :=
pequiv_of_pmap (pcast (ap F (eq_of_pequiv p))) begin cases eq_of_pequiv p, apply is_equiv_id end
definition pequiv_eq {p q : A ≃* B} (H : p = q :> (A →* B)) : p = q :=
begin
cases p with f Hf, cases q with g Hg, esimp at *,
exact apd011 pequiv_of_pmap H !is_prop.elim
end
infix ` ⬝e*p `:75 := peconcat_eq
infix ` ⬝pe* `:75 := eq_peconcat
local attribute pequiv.symm [constructor]
definition pleft_inv (f : A ≃* B) : f⁻¹ᵉ* ∘* f ~* pid A :=
phomotopy.mk (left_inv f)
abstract begin
esimp, symmetry, apply con_inv_cancel_left
end end
definition pright_inv (f : A ≃* B) : f ∘* f⁻¹ᵉ* ~* pid B :=
phomotopy.mk (right_inv f)
abstract begin
induction f with f H p, esimp,
rewrite [ap_con, +ap_inv, -adj f, -ap_compose],
note q := natural_square (right_inv f) p,
rewrite [ap_id at q],
apply eq_bot_of_square,
exact transpose q
end end
definition pcancel_left (f : B ≃* C) {g h : A →* B} (p : f ∘* g ~* f ∘* h) : g ~* h :=
begin
refine _⁻¹* ⬝* pwhisker_left f⁻¹ᵉ* p ⬝* _:
refine !passoc⁻¹* ⬝* _:
refine pwhisker_right _ (pleft_inv f) ⬝* _:
apply pid_comp
end
definition pcancel_right (f : A ≃* B) {g h : B →* C} (p : g ∘* f ~* h ∘* f) : g ~* h :=
begin
refine _⁻¹* ⬝* pwhisker_right f⁻¹ᵉ* p ⬝* _:
refine !passoc ⬝* _:
refine pwhisker_left _ (pright_inv f) ⬝* _:
apply comp_pid
end
definition phomotopy_pinv_right_of_phomotopy {f : A ≃* B} {g : B →* C} {h : A →* C}
(p : g ∘* f ~* h) : g ~* h ∘* f⁻¹ᵉ* :=
begin
refine _ ⬝* pwhisker_right _ p, symmetry,
refine !passoc ⬝* _,
refine pwhisker_left _ (pright_inv f) ⬝* _,
apply comp_pid
end
definition phomotopy_of_pinv_right_phomotopy {f : B ≃* A} {g : B →* C} {h : A →* C}
(p : g ∘* f⁻¹ᵉ* ~* h) : g ~* h ∘* f :=
begin
refine _ ⬝* pwhisker_right _ p, symmetry,
refine !passoc ⬝* _,
refine pwhisker_left _ (pleft_inv f) ⬝* _,
apply comp_pid
end
definition pinv_right_phomotopy_of_phomotopy {f : A ≃* B} {g : B →* C} {h : A →* C}
(p : h ~* g ∘* f) : h ∘* f⁻¹ᵉ* ~* g :=
(phomotopy_pinv_right_of_phomotopy p⁻¹*)⁻¹*
definition phomotopy_of_phomotopy_pinv_right {f : B ≃* A} {g : B →* C} {h : A →* C}
(p : h ~* g ∘* f⁻¹ᵉ*) : h ∘* f ~* g :=
(phomotopy_of_pinv_right_phomotopy p⁻¹*)⁻¹*
definition phomotopy_pinv_left_of_phomotopy {f : B ≃* C} {g : A →* B} {h : A →* C}
(p : f ∘* g ~* h) : g ~* f⁻¹ᵉ* ∘* h :=
begin
refine _ ⬝* pwhisker_left _ p, symmetry,
refine !passoc⁻¹* ⬝* _,
refine pwhisker_right _ (pleft_inv f) ⬝* _,
apply pid_comp
end
definition phomotopy_of_pinv_left_phomotopy {f : C ≃* B} {g : A →* B} {h : A →* C}
(p : f⁻¹ᵉ* ∘* g ~* h) : g ~* f ∘* h :=
begin
refine _ ⬝* pwhisker_left _ p, symmetry,
refine !passoc⁻¹* ⬝* _,
refine pwhisker_right _ (pright_inv f) ⬝* _,
apply pid_comp
end
definition pinv_left_phomotopy_of_phomotopy {f : B ≃* C} {g : A →* B} {h : A →* C}
(p : h ~* f ∘* g) : f⁻¹ᵉ* ∘* h ~* g :=
(phomotopy_pinv_left_of_phomotopy p⁻¹*)⁻¹*
definition phomotopy_of_phomotopy_pinv_left {f : C ≃* B} {g : A →* B} {h : A →* C}
(p : h ~* f⁻¹ᵉ* ∘* g) : f ∘* h ~* g :=
(phomotopy_of_pinv_left_phomotopy p⁻¹*)⁻¹*
/- pointed equivalences between particular pointed types -/
definition loopn_pequiv_loopn [constructor] (n : ) (f : A ≃* B) : Ω[n] A ≃* Ω[n] B :=
pequiv.MK2 (apn n f) (apn n f⁻¹ᵉ*)
abstract begin
induction n with n IH,
{ apply pleft_inv},
{ replace nat.succ n with n + 1,
rewrite [+apn_succ],
refine !ap1_compose⁻¹* ⬝* _,
refine ap1_phomotopy IH ⬝* _,
apply ap1_id}
end end
abstract begin
induction n with n IH,
{ apply pright_inv},
{ replace nat.succ n with n + 1,
rewrite [+apn_succ],
refine !ap1_compose⁻¹* ⬝* _,
refine ap1_phomotopy IH ⬝* _,
apply ap1_id}
end end
definition loop_pequiv_loop [constructor] (f : A ≃* B) : Ω A ≃* Ω B :=
loopn_pequiv_loopn 1 f
definition to_pmap_loopn_pequiv_loopn [constructor] (n : ) (f : A ≃* B)
: loopn_pequiv_loopn n f ~* apn n f :=
!to_pmap_pequiv_MK2
definition to_pinv_loopn_pequiv_loopn [constructor] (n : ) (f : A ≃* B)
: (loopn_pequiv_loopn n f)⁻¹ᵉ* ~* apn n f⁻¹ᵉ* :=
!to_pinv_pequiv_MK2
definition loopn_pequiv_loopn_con (n : ) (f : A ≃* B) (p q : Ω[n+1] A)
: loopn_pequiv_loopn (n+1) f (p ⬝ q) =
loopn_pequiv_loopn (n+1) f p ⬝ loopn_pequiv_loopn (n+1) f q :=
ap1_con (loopn_pequiv_loopn n f) p q
definition loop_pequiv_loop_con {A B : Type*} (f : A ≃* B) (p q : Ω A)
: loop_pequiv_loop f (p ⬝ q) = loop_pequiv_loop f p ⬝ loop_pequiv_loop f q :=
loopn_pequiv_loopn_con 0 f p q
definition loopn_pequiv_loopn_rfl (n : ) (A : Type*) :
loopn_pequiv_loopn n (pequiv.refl A) = pequiv.refl (Ω[n] A) :=
begin
apply pequiv_eq, apply eq_of_phomotopy,
exact !to_pmap_loopn_pequiv_loopn ⬝* apn_pid n,
end
definition loop_pequiv_loop_rfl (A : Type*) :
loop_pequiv_loop (pequiv.refl A) = pequiv.refl (Ω A) :=
loopn_pequiv_loopn_rfl 1 A
definition pmap_functor [constructor] {A A' B B' : Type*} (f : A' →* A) (g : B →* B') :
ppmap A B →* ppmap A' B' :=
pmap.mk (λh, g ∘* h ∘* f)
abstract begin
fapply pmap_eq,
{ esimp, intro a, exact respect_pt g},
{ rewrite [▸*, ap_constant], apply idp_con}
end end
definition pequiv_pinverse (A : Type*) : Ω A ≃* Ω A :=
pequiv_of_pmap pinverse !is_equiv_eq_inverse
definition pequiv_of_eq_pt [constructor] {A : Type} {a a' : A} (p : a = a') :
pointed.MK A a ≃* pointed.MK A a' :=
pequiv_of_pmap (pmap_of_eq_pt p) !is_equiv_id
/- -- TODO
definition pmap_pequiv_pmap {A A' B B' : Type*} (f : A ≃* A') (g : B ≃* B') :
ppmap A B ≃* ppmap A' B' :=
pequiv.MK (pmap_functor f⁻¹ᵉ* g) (pmap_functor f g⁻¹ᵉ*)
abstract begin
intro a, esimp, apply pmap_eq,
{ esimp, },
{ }
end end
abstract begin
end end
-/
end pointed