/- Copyright (c) 2016 Floris van Doorn. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Floris van Doorn We define the fiber sequence of a pointed map f : X →* Y. We mostly follow the proof in section 8.4 of the book. PART 1: We define a sequence fiber_sequence as in Definition 8.4.3. It has types X(n) : Type* X(0) := Y, X(1) := X, X(n+1) := fiber (f(n)) with functions f(n) : X(n+1) →* X(n) f(0) := f f(n+1) := point (f(n)) [this is the first projection] We prove that this is an exact sequence. Then we prove Lemma 8.4.3, by showing that X(n+3) ≃* Ω(X(n)) and that this equivalence sends the pointed map f(n+3) to -Ω(f(n)), i.e. the composition of Ω(f(n)) with path inversion. Using this equivalence we get a boundary_map : Ω(Y) → pfiber f. PART 2: Now we can define a new fiber sequence X'(n) : Type*, and here we slightly diverge from the book. We define it as X'(0) := Y, X'(1) := X, X'(2) := fiber f X'(n+3) := Ω(X'(n)) with maps f'(n) : X'(n+1) →* X'(n) f'(0) := f f'(1) := point f f'(2) := boundary_map f'(n+3) := Ω(f'(n)) This sequence is not equivalent to the previous sequence. The difference is in the signs. The sequence f has negative signs (i.e. is composed with the inverse maps) for n ≡ 3, 4, 5 mod 6. This sign information is captured by e : X'(n) ≃* X'(n) such that e(k) := 1 for k = 0,1,2,3 e(k+3) := Ω(e(k)) ∘ (-)⁻¹ for k > 0 Now the sequence (X', f' ∘ e) is equivalent to (X, f), Hence (X', f' ∘ e) is an exact sequence. We then prove that (X', f') is an exact sequence by using that there are other equivalences eₗ and eᵣ such that f' = eᵣ ∘ f' ∘ e f' ∘ eₗ = e ∘ f'. (this fact is type_chain_complex_cancel_aut and is_exact_at_t_cancel_aut in the file chain_complex) eₗ and eᵣ are almost the same as e, except that the places where the inverse is taken is slightly shifted: eᵣ = (-)⁻¹ for n ≡ 3, 4, 5 mod 6 and eᵣ = 1 otherwise e = (-)⁻¹ for n ≡ 4, 5, 6 mod 6 (except for n = 0) and e = 1 otherwise eₗ = (-)⁻¹ for n ≡ 5, 6, 7 mod 6 (except for n = 0, 1) and eₗ = 1 otherwise PART 3: We change the type over which the sequence of types and maps are indexed from ℕ to ℕ × 3 (where 3 is the finite type with 3 elements). The reason is that we have that X'(3n) = Ωⁿ(Y), but this equality is not definitionally true. Hence we cannot even state whether f'(3n) = Ωⁿ(f) without using transports. This gets ugly. However, if we use as index type ℕ × 3, we can do this. We can define Y : ℕ × 3 → Type* as Y(n, 0) := Ωⁿ(Y) Y(n, 1) := Ωⁿ(X) Y(n, 2) := Ωⁿ(fiber f) with maps g(n) : Y(S n) →* Y(n) (where the successor is defined in the obvious way) g(n, 0) := Ωⁿ(f) g(n, 1) := Ωⁿ(point f) g(n, 2) := Ωⁿ(boundary_map) ∘ cast Here "cast" is the transport over the equality Ωⁿ⁺¹(Y) = Ωⁿ(Ω(Y)). We show that the sequence (ℕ, X', f') is equivalent to (ℕ × 3, Y, g). PART 4: We get the long exact sequence of homotopy groups by taking the set-truncation of (Y, g). -/ import .chain_complex algebra.homotopy_group open eq pointed sigma fiber equiv is_equiv sigma.ops is_trunc nat trunc algebra function sum section MOVE -- TODO: MOVE open group chain_complex definition pinverse_pinverse (A : Type*) : pinverse ∘* pinverse ~* pid (Ω A) := begin fapply phomotopy.mk, { apply inv_inv}, { reflexivity} end 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 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_pinverse (A : Type*) : Ω A ≃* Ω A := pequiv_of_pmap pinverse !is_equiv_eq_inverse definition tr_mul_tr {A : Type*} (n : ℕ) (p q : Ω[n + 1] A) : tr p *[πg[n+1] A] tr q = tr (p ⬝ q) := by reflexivity definition is_homomorphism_cast_loop_space_succ_eq_in {A : Type*} (n : ℕ) : is_homomorphism (cast (ap (trunc 0 ∘ pointed.carrier) (loop_space_succ_eq_in A (succ n))) : πg[n+1+1] A → πg[n+1] Ω A) := begin intro g h, induction g with g, induction h with h, xrewrite [tr_mul_tr, - + fn_cast_eq_cast_fn _ (λn, tr), tr_mul_tr, ↑cast, -tr_compose, loop_space_succ_eq_in_concat, - + tr_compose], end definition is_homomorphism_inverse (A : Type*) (n : ℕ) : is_homomorphism (λp, p⁻¹ : πag[n+2] A → πag[n+2] A) := begin intro g h, rewrite mul.comm, induction g with g, induction h with h, exact ap tr !con_inv end end MOVE /-------------- PART 1 --------------/ namespace chain_complex definition fiber_sequence_helper [constructor] (v : Σ(X Y : Type*), X →* Y) : Σ(Z X : Type*), Z →* X := ⟨pfiber v.2.2, v.1, ppoint v.2.2⟩ definition fiber_sequence_helpern (v : Σ(X Y : Type*), X →* Y) (n : ℕ) : Σ(Z X : Type*), Z →* X := iterate fiber_sequence_helper n v section universe variable u parameters {X Y : pType.{u}} (f : X →* Y) include f definition fiber_sequence_carrier (n : ℕ) : Type* := (fiber_sequence_helpern ⟨X, Y, f⟩ n).2.1 definition fiber_sequence_fun (n : ℕ) : fiber_sequence_carrier (n + 1) →* fiber_sequence_carrier n := (fiber_sequence_helpern ⟨X, Y, f⟩ n).2.2 /- Definition 8.4.3 -/ definition fiber_sequence : type_chain_complex.{0 u} +ℕ := begin fconstructor, { exact fiber_sequence_carrier}, { exact fiber_sequence_fun}, { intro n x, cases n with n, { exact point_eq x}, { exact point_eq x}} end definition is_exact_fiber_sequence : is_exact_t fiber_sequence := λn x p, fiber.mk (fiber.mk x p) rfl /- (generalization of) Lemma 8.4.4(i)(ii) -/ definition fiber_sequence_carrier_equiv (n : ℕ) : fiber_sequence_carrier (n+3) ≃ Ω(fiber_sequence_carrier n) := calc fiber_sequence_carrier (n+3) ≃ fiber (fiber_sequence_fun (n+1)) pt : erfl ... ≃ Σ(x : fiber_sequence_carrier _), fiber_sequence_fun (n+1) x = pt : fiber.sigma_char ... ≃ Σ(x : fiber (fiber_sequence_fun n) pt), fiber_sequence_fun _ x = pt : erfl ... ≃ Σ(v : Σ(x : fiber_sequence_carrier _), fiber_sequence_fun _ x = pt), fiber_sequence_fun _ (fiber.mk v.1 v.2) = pt : by exact sigma_equiv_sigma !fiber.sigma_char (λa, erfl) ... ≃ Σ(v : Σ(x : fiber_sequence_carrier _), fiber_sequence_fun _ x = pt), v.1 = pt : erfl ... ≃ Σ(v : Σ(x : fiber_sequence_carrier _), x = pt), fiber_sequence_fun _ v.1 = pt : sigma_assoc_comm_equiv ... ≃ fiber_sequence_fun _ !center.1 = pt : @(sigma_equiv_of_is_contr_left _) !is_contr_sigma_eq' ... ≃ fiber_sequence_fun _ pt = pt : erfl ... ≃ pt = pt : by exact !equiv_eq_closed_left !respect_pt ... ≃ Ω(fiber_sequence_carrier n) : erfl /- computation rule -/ definition fiber_sequence_carrier_equiv_eq (n : ℕ) (x : fiber_sequence_carrier (n+1)) (p : fiber_sequence_fun n x = pt) (q : fiber_sequence_fun (n+1) (fiber.mk x p) = pt) : fiber_sequence_carrier_equiv n (fiber.mk (fiber.mk x p) q) = !respect_pt⁻¹ ⬝ ap (fiber_sequence_fun n) q⁻¹ ⬝ p := begin refine _ ⬝ !con.assoc⁻¹, apply whisker_left, refine transport_eq_Fl _ _ ⬝ _, apply whisker_right, refine inverse2 !ap_inv ⬝ !inv_inv ⬝ _, refine ap_compose (fiber_sequence_fun n) pr₁ _ ⬝ ap02 (fiber_sequence_fun n) !ap_pr1_center_eq_sigma_eq', end definition fiber_sequence_carrier_equiv_inv_eq (n : ℕ) (p : Ω(fiber_sequence_carrier n)) : (fiber_sequence_carrier_equiv n)⁻¹ᵉ p = fiber.mk (fiber.mk pt (respect_pt (fiber_sequence_fun n) ⬝ p)) idp := begin apply inv_eq_of_eq, refine _ ⬝ !fiber_sequence_carrier_equiv_eq⁻¹, esimp, exact !inv_con_cancel_left⁻¹ end definition fiber_sequence_carrier_pequiv (n : ℕ) : fiber_sequence_carrier (n+3) ≃* Ω(fiber_sequence_carrier n) := pequiv_of_equiv (fiber_sequence_carrier_equiv n) begin esimp, apply con.left_inv end definition fiber_sequence_carrier_pequiv_eq (n : ℕ) (x : fiber_sequence_carrier (n+1)) (p : fiber_sequence_fun n x = pt) (q : fiber_sequence_fun (n+1) (fiber.mk x p) = pt) : fiber_sequence_carrier_pequiv n (fiber.mk (fiber.mk x p) q) = !respect_pt⁻¹ ⬝ ap (fiber_sequence_fun n) q⁻¹ ⬝ p := fiber_sequence_carrier_equiv_eq n x p q definition fiber_sequence_carrier_pequiv_inv_eq (n : ℕ) (p : Ω(fiber_sequence_carrier n)) : (fiber_sequence_carrier_pequiv n)⁻¹ᵉ* p = fiber.mk (fiber.mk pt (respect_pt (fiber_sequence_fun n) ⬝ p)) idp := by rexact fiber_sequence_carrier_equiv_inv_eq n p /- Lemma 8.4.4(iii) -/ definition fiber_sequence_fun_eq_helper (n : ℕ) (p : Ω(fiber_sequence_carrier (n + 1))) : fiber_sequence_carrier_pequiv n (fiber_sequence_fun (n + 3) ((fiber_sequence_carrier_pequiv (n + 1))⁻¹ᵉ* p)) = ap1 (fiber_sequence_fun n) p⁻¹ := begin refine ap (λx, fiber_sequence_carrier_pequiv n (fiber_sequence_fun (n + 3) x)) (fiber_sequence_carrier_pequiv_inv_eq (n+1) p) ⬝ _, /- the following three lines are rewriting some reflexivities: -/ -- replace (n + 3) with (n + 2 + 1), -- refine ap (fiber_sequence_carrier_pequiv n) -- (fiber_sequence_fun_eq1 (n+2) _ idp) ⬝ _, refine fiber_sequence_carrier_pequiv_eq n pt (respect_pt (fiber_sequence_fun n)) _ ⬝ _, esimp, apply whisker_right, apply whisker_left, apply ap02, apply inverse2, apply idp_con, end theorem fiber_sequence_carrier_pequiv_eq_point_eq_idp (n : ℕ) : fiber_sequence_carrier_pequiv_eq n (Point (fiber_sequence_carrier (n+1))) (respect_pt (fiber_sequence_fun n)) (respect_pt (fiber_sequence_fun (n + 1))) = idp := begin apply con_inv_eq_idp, refine ap (λx, whisker_left _ (_ ⬝ x)) _ ⬝ _, { reflexivity}, { reflexivity}, refine ap (whisker_left _) (transport_eq_Fl_idp_left (fiber_sequence_fun n) (respect_pt (fiber_sequence_fun n))) ⬝ _, apply whisker_left_idp_con_eq_assoc end theorem fiber_sequence_fun_phomotopy_helper (n : ℕ) : (fiber_sequence_carrier_pequiv n ∘* fiber_sequence_fun (n + 3)) ∘* (fiber_sequence_carrier_pequiv (n + 1))⁻¹ᵉ* ~* ap1 (fiber_sequence_fun n) ∘* pinverse := begin fapply phomotopy.mk, { exact chain_complex.fiber_sequence_fun_eq_helper f n}, { esimp, rewrite [idp_con], refine _ ⬝ whisker_left _ !idp_con⁻¹, apply whisker_right, apply whisker_left, exact chain_complex.fiber_sequence_carrier_pequiv_eq_point_eq_idp f n} end theorem fiber_sequence_fun_eq (n : ℕ) : Π(x : fiber_sequence_carrier (n + 4)), fiber_sequence_carrier_pequiv n (fiber_sequence_fun (n + 3) x) = ap1 (fiber_sequence_fun n) (fiber_sequence_carrier_pequiv (n + 1) x)⁻¹ := begin apply homotopy_of_inv_homotopy_pre (fiber_sequence_carrier_pequiv (n + 1)), apply fiber_sequence_fun_eq_helper n end theorem fiber_sequence_fun_phomotopy (n : ℕ) : fiber_sequence_carrier_pequiv n ∘* fiber_sequence_fun (n + 3) ~* (ap1 (fiber_sequence_fun n) ∘* pinverse) ∘* fiber_sequence_carrier_pequiv (n + 1) := begin apply phomotopy_of_pinv_right_phomotopy, apply fiber_sequence_fun_phomotopy_helper end definition boundary_map : Ω Y →* pfiber f := fiber_sequence_fun 2 ∘* (fiber_sequence_carrier_pequiv 0)⁻¹ᵉ* /-------------- PART 2 --------------/ /- Now we are ready to define the long exact sequence of homotopy groups. First we define its carrier -/ definition loop_spaces : ℕ → Type* | 0 := Y | 1 := X | 2 := pfiber f | (k+3) := Ω (loop_spaces k) /- The maps between the homotopy groups -/ definition loop_spaces_fun : Π(n : ℕ), loop_spaces (n+1) →* loop_spaces n | 0 := proof f qed | 1 := proof ppoint f qed | 2 := proof boundary_map qed | (k+3) := proof ap1 (loop_spaces_fun k) qed definition loop_spaces_fun_add3 [unfold_full] (n : ℕ) : loop_spaces_fun (n + 3) = ap1 (loop_spaces_fun n) := proof idp qed definition fiber_sequence_pequiv_loop_spaces : Πn, fiber_sequence_carrier n ≃* loop_spaces n | 0 := by reflexivity | 1 := by reflexivity | 2 := by reflexivity | (k+3) := begin refine fiber_sequence_carrier_pequiv k ⬝e* _, apply loop_pequiv_loop, exact fiber_sequence_pequiv_loop_spaces k end definition fiber_sequence_pequiv_loop_spaces_add3 (n : ℕ) : fiber_sequence_pequiv_loop_spaces (n + 3) = ap1 (fiber_sequence_pequiv_loop_spaces n) ∘* fiber_sequence_carrier_pequiv n := by reflexivity definition fiber_sequence_pequiv_loop_spaces_3_phomotopy : fiber_sequence_pequiv_loop_spaces 3 ~* proof fiber_sequence_carrier_pequiv nat.zero qed := begin refine pwhisker_right _ ap1_id ⬝* _, apply pid_comp end definition pid_or_pinverse : Π(n : ℕ), loop_spaces n ≃* loop_spaces n | 0 := pequiv.rfl | 1 := pequiv.rfl | 2 := pequiv.rfl | 3 := pequiv.rfl | (k+4) := !pequiv_pinverse ⬝e* loop_pequiv_loop (pid_or_pinverse (k+1)) definition pid_or_pinverse_add4 (n : ℕ) : pid_or_pinverse (n + 4) = !pequiv_pinverse ⬝e* loop_pequiv_loop (pid_or_pinverse (n + 1)) := by reflexivity definition pid_or_pinverse_add4_rev : Π(n : ℕ), pid_or_pinverse (n + 4) ~* pinverse ∘* Ω→(pid_or_pinverse (n + 1)) | 0 := begin rewrite [pid_or_pinverse_add4, + to_pmap_pequiv_trans], replace pid_or_pinverse (0 + 1) with pequiv.refl X, rewrite [loop_pequiv_loop_rfl, ▸*], refine !pid_comp ⬝* _, exact !comp_pid⁻¹* ⬝* pwhisker_left _ !ap1_id⁻¹* end | 1 := begin rewrite [pid_or_pinverse_add4, + to_pmap_pequiv_trans], replace pid_or_pinverse (1 + 1) with pequiv.refl (pfiber f), rewrite [loop_pequiv_loop_rfl, ▸*], refine !pid_comp ⬝* _, exact !comp_pid⁻¹* ⬝* pwhisker_left _ !ap1_id⁻¹* end | 2 := begin rewrite [pid_or_pinverse_add4, + to_pmap_pequiv_trans], replace pid_or_pinverse (2 + 1) with pequiv.refl (Ω Y), rewrite [loop_pequiv_loop_rfl, ▸*], refine !pid_comp ⬝* _, exact !comp_pid⁻¹* ⬝* pwhisker_left _ !ap1_id⁻¹* end | (k+3) := begin replace (k + 3 + 1) with (k + 4), rewrite [+ pid_or_pinverse_add4, + to_pmap_pequiv_trans], refine _ ⬝* pwhisker_left _ !ap1_compose⁻¹*, refine _ ⬝* !passoc, apply pconcat2, { refine ap1_phomotopy (pid_or_pinverse_add4_rev k) ⬝* _, refine !ap1_compose ⬝* _, apply pwhisker_right, apply ap1_pinverse}, { refine !ap1_pinverse⁻¹*} end theorem fiber_sequence_phomotopy_loop_spaces : Π(n : ℕ), fiber_sequence_pequiv_loop_spaces n ∘* fiber_sequence_fun n ~* (loop_spaces_fun n ∘* pid_or_pinverse (n + 1)) ∘* fiber_sequence_pequiv_loop_spaces (n + 1) | 0 := proof proof phomotopy.rfl qed ⬝* pwhisker_right _ !comp_pid⁻¹* qed | 1 := by reflexivity | 2 := begin refine !pid_comp ⬝* _, replace loop_spaces_fun 2 with boundary_map, refine _ ⬝* pwhisker_left _ fiber_sequence_pequiv_loop_spaces_3_phomotopy⁻¹*, apply phomotopy_of_pinv_right_phomotopy, exact !pid_comp⁻¹* end | (k+3) := begin replace (k + 3 + 1) with (k + 1 + 3), rewrite [fiber_sequence_pequiv_loop_spaces_add3 k, fiber_sequence_pequiv_loop_spaces_add3 (k+1)], refine !passoc ⬝* _, refine pwhisker_left _ (fiber_sequence_fun_phomotopy k) ⬝* _, refine !passoc⁻¹* ⬝* _ ⬝* !passoc, apply pwhisker_right, replace (k + 1 + 3) with (k + 4), xrewrite [loop_spaces_fun_add3, pid_or_pinverse_add4, to_pmap_pequiv_trans], refine _ ⬝* !passoc⁻¹*, refine _ ⬝* pwhisker_left _ !passoc⁻¹*, refine _ ⬝* pwhisker_left _ (pwhisker_left _ !ap1_compose_pinverse), refine !passoc⁻¹* ⬝* _ ⬝* !passoc ⬝* !passoc, apply pwhisker_right, refine !ap1_compose⁻¹* ⬝* _ ⬝* !ap1_compose ⬝* pwhisker_right _ !ap1_compose, apply ap1_phomotopy, exact fiber_sequence_phomotopy_loop_spaces k end definition pid_or_pinverse_right : Π(n : ℕ), loop_spaces n →* loop_spaces n | 0 := !pid | 1 := !pid | 2 := !pid | (k+3) := Ω→(pid_or_pinverse_right k) ∘* pinverse definition pid_or_pinverse_left : Π(n : ℕ), loop_spaces n →* loop_spaces n | 0 := pequiv.rfl | 1 := pequiv.rfl | 2 := pequiv.rfl | 3 := pequiv.rfl | 4 := pequiv.rfl | (k+5) := Ω→(pid_or_pinverse_left (k+2)) ∘* pinverse definition pid_or_pinverse_right_add3 (n : ℕ) : pid_or_pinverse_right (n + 3) = Ω→(pid_or_pinverse_right n) ∘* pinverse := by reflexivity definition pid_or_pinverse_left_add5 (n : ℕ) : pid_or_pinverse_left (n + 5) = Ω→(pid_or_pinverse_left (n+2)) ∘* pinverse := by reflexivity theorem pid_or_pinverse_commute_right : Π(n : ℕ), loop_spaces_fun n ~* pid_or_pinverse_right n ∘* loop_spaces_fun n ∘* pid_or_pinverse (n + 1) | 0 := proof !comp_pid⁻¹* ⬝* !pid_comp⁻¹* qed | 1 := proof !comp_pid⁻¹* ⬝* !pid_comp⁻¹* qed | 2 := proof !comp_pid⁻¹* ⬝* !pid_comp⁻¹* qed | (k+3) := begin replace (k + 3 + 1) with (k + 4), rewrite [pid_or_pinverse_right_add3, loop_spaces_fun_add3], refine _ ⬝* pwhisker_left _ (pwhisker_left _ !pid_or_pinverse_add4_rev⁻¹*), refine ap1_phomotopy (pid_or_pinverse_commute_right k) ⬝* _, refine !ap1_compose ⬝* _ ⬝* !passoc⁻¹*, apply pwhisker_left, refine !ap1_compose ⬝* _ ⬝* !passoc ⬝* !passoc, apply pwhisker_right, refine _ ⬝* pwhisker_right _ !ap1_compose_pinverse, refine _ ⬝* !passoc⁻¹*, refine !comp_pid⁻¹* ⬝* pwhisker_left _ _, symmetry, apply pinverse_pinverse end theorem pid_or_pinverse_commute_left : Π(n : ℕ), loop_spaces_fun n ∘* pid_or_pinverse_left (n + 1) ~* pid_or_pinverse n ∘* loop_spaces_fun n | 0 := proof !comp_pid ⬝* !pid_comp⁻¹* qed | 1 := proof !comp_pid ⬝* !pid_comp⁻¹* qed | 2 := proof !comp_pid ⬝* !pid_comp⁻¹* qed | 3 := proof !comp_pid ⬝* !pid_comp⁻¹* qed | (k+4) := begin replace (k + 4 + 1) with (k + 5), rewrite [pid_or_pinverse_left_add5, pid_or_pinverse_add4, to_pmap_pequiv_trans], replace (k + 4) with (k + 1 + 3), rewrite [loop_spaces_fun_add3], refine !passoc⁻¹* ⬝* _ ⬝* !passoc⁻¹*, refine _ ⬝* pwhisker_left _ !ap1_compose_pinverse, refine _ ⬝* !passoc, apply pwhisker_right, refine !ap1_compose⁻¹* ⬝* _ ⬝* !ap1_compose, exact ap1_phomotopy (pid_or_pinverse_commute_left (k+1)) end definition LES_of_loop_spaces' [constructor] : type_chain_complex +ℕ := transfer_type_chain_complex fiber_sequence (λn, loop_spaces_fun n ∘* pid_or_pinverse (n + 1)) fiber_sequence_pequiv_loop_spaces fiber_sequence_phomotopy_loop_spaces definition LES_of_loop_spaces [constructor] : type_chain_complex +ℕ := type_chain_complex_cancel_aut LES_of_loop_spaces' loop_spaces_fun pid_or_pinverse pid_or_pinverse_right (λn x, idp) pid_or_pinverse_commute_right definition is_exact_LES_of_loop_spaces : is_exact_t LES_of_loop_spaces := begin intro n, refine is_exact_at_t_cancel_aut n pid_or_pinverse_left _ _ pid_or_pinverse_commute_left _, apply is_exact_at_t_transfer, apply is_exact_fiber_sequence end open prod succ_str fin /-------------- PART 3 --------------/ definition loop_spaces2 [reducible] : +3ℕ → Type* | (n, fin.mk 0 H) := Ω[n] Y | (n, fin.mk 1 H) := Ω[n] X | (n, fin.mk k H) := Ω[n] (pfiber f) definition loop_spaces2_add1 (n : ℕ) : Π(x : fin (nat.succ 2)), loop_spaces2 (n+1, x) = Ω (loop_spaces2 (n, x)) | (fin.mk 0 H) := by reflexivity | (fin.mk 1 H) := by reflexivity | (fin.mk 2 H) := by reflexivity | (fin.mk (k+3) H) := begin exfalso, apply lt_le_antisymm H, apply le_add_left end definition loop_spaces_fun2 : Π(n : +3ℕ), loop_spaces2 (S n) →* loop_spaces2 n | (n, fin.mk 0 H) := proof Ω→[n] f qed | (n, fin.mk 1 H) := proof Ω→[n] (ppoint f) qed | (n, fin.mk 2 H) := proof Ω→[n] boundary_map ∘* pcast (loop_space_succ_eq_in Y n) qed | (n, fin.mk (k+3) H) := begin exfalso, apply lt_le_antisymm H, apply le_add_left end definition loop_spaces_fun2_add1_0 (n : ℕ) (H : 0 < succ 2) : loop_spaces_fun2 (n+1, fin.mk 0 H) ~* cast proof idp qed ap1 (loop_spaces_fun2 (n, fin.mk 0 H)) := by reflexivity definition loop_spaces_fun2_add1_1 (n : ℕ) (H : 1 < succ 2) : loop_spaces_fun2 (n+1, fin.mk 1 H) ~* cast proof idp qed ap1 (loop_spaces_fun2 (n, fin.mk 1 H)) := by reflexivity definition loop_spaces_fun2_add1_2 (n : ℕ) (H : 2 < succ 2) : loop_spaces_fun2 (n+1, fin.mk 2 H) ~* cast proof idp qed ap1 (loop_spaces_fun2 (n, fin.mk 2 H)) := begin esimp, refine _ ⬝* !ap1_compose⁻¹*, apply pwhisker_left, apply pcast_ap_loop_space end definition nat_of_str [unfold 2] [reducible] {n : ℕ} : ℕ × fin (succ n) → ℕ := λx, succ n * pr1 x + val (pr2 x) definition str_of_nat {n : ℕ} : ℕ → ℕ × fin (succ n) := λm, (m / (succ n), mk_mod n m) definition nat_of_str_3S [unfold 2] [reducible] : Π(x : stratified +ℕ 2), nat_of_str x + 1 = nat_of_str (@S (stratified +ℕ 2) x) | (n, fin.mk 0 H) := by reflexivity | (n, fin.mk 1 H) := by reflexivity | (n, fin.mk 2 H) := by reflexivity | (n, fin.mk (k+3) H) := begin exfalso, apply lt_le_antisymm H, apply le_add_left end definition fin_prod_nat_equiv_nat [constructor] (n : ℕ) : ℕ × fin (succ n) ≃ ℕ := equiv.MK nat_of_str str_of_nat abstract begin intro m, unfold [nat_of_str, str_of_nat, mk_mod], refine _ ⬝ (eq_div_mul_add_mod m (succ n))⁻¹, rewrite [mul.comm] end end abstract begin intro x, cases x with m k, cases k with k H, apply prod_eq: esimp [str_of_nat], { rewrite [add.comm, add_mul_div_self_left _ _ (!zero_lt_succ), ▸*, div_eq_zero_of_lt H, zero_add]}, { apply eq_of_veq, esimp [mk_mod], rewrite [add.comm, add_mul_mod_self_left, ▸*, mod_eq_of_lt H]} end end /- note: in the following theorem the (n+1) case is 3 times the same, so maybe this can be simplified -/ definition loop_spaces2_pequiv' : Π(n : ℕ) (x : fin (nat.succ 2)), loop_spaces (nat_of_str (n, x)) ≃* loop_spaces2 (n, x) | 0 (fin.mk 0 H) := by reflexivity | 0 (fin.mk 1 H) := by reflexivity | 0 (fin.mk 2 H) := by reflexivity | (n+1) (fin.mk 0 H) := begin apply loop_pequiv_loop, rexact loop_spaces2_pequiv' n (fin.mk 0 H) end | (n+1) (fin.mk 1 H) := begin apply loop_pequiv_loop, rexact loop_spaces2_pequiv' n (fin.mk 1 H) end | (n+1) (fin.mk 2 H) := begin apply loop_pequiv_loop, rexact loop_spaces2_pequiv' n (fin.mk 2 H) end | n (fin.mk (k+3) H) := begin exfalso, apply lt_le_antisymm H, apply le_add_left end definition loop_spaces2_pequiv : Π(x : +3ℕ), loop_spaces (nat_of_str x) ≃* loop_spaces2 x | (n, x) := loop_spaces2_pequiv' n x local attribute loop_pequiv_loop [reducible] /- all cases where n>0 are basically the same -/ definition loop_spaces_fun2_phomotopy (x : +3ℕ) : loop_spaces2_pequiv x ∘* loop_spaces_fun (nat_of_str x) ~* (loop_spaces_fun2 x ∘* loop_spaces2_pequiv (S x)) ∘* pcast (ap (loop_spaces) (nat_of_str_3S x)) := begin cases x with n x, cases x with k H, do 3 (cases k with k; rotate 1), { /-k≥3-/ exfalso, apply lt_le_antisymm H, apply le_add_left}, { /-k=0-/ induction n with n IH, { refine !pid_comp ⬝* _ ⬝* !comp_pid⁻¹* ⬝* !comp_pid⁻¹*, reflexivity}, { refine _ ⬝* !comp_pid⁻¹*, refine _ ⬝* pwhisker_right _ !loop_spaces_fun2_add1_0⁻¹*, refine !ap1_compose⁻¹* ⬝* _ ⬝* !ap1_compose, apply ap1_phomotopy, exact IH ⬝* !comp_pid}}, { /-k=1-/ induction n with n IH, { refine !pid_comp ⬝* _ ⬝* !comp_pid⁻¹* ⬝* !comp_pid⁻¹*, reflexivity}, { refine _ ⬝* !comp_pid⁻¹*, refine _ ⬝* pwhisker_right _ !loop_spaces_fun2_add1_1⁻¹*, refine !ap1_compose⁻¹* ⬝* _ ⬝* !ap1_compose, apply ap1_phomotopy, exact IH ⬝* !comp_pid}}, { /-k=2-/ induction n with n IH, { refine !pid_comp ⬝* _ ⬝* !comp_pid⁻¹*, refine !comp_pid⁻¹* ⬝* pconcat2 _ _, { exact (comp_pid (chain_complex.boundary_map f))⁻¹*}, { refine cast (ap (λx, _ ~* x) !loop_pequiv_loop_rfl)⁻¹ _, reflexivity}}, { refine _ ⬝* !comp_pid⁻¹*, refine _ ⬝* pwhisker_right _ !loop_spaces_fun2_add1_2⁻¹*, refine !ap1_compose⁻¹* ⬝* _ ⬝* !ap1_compose, apply ap1_phomotopy, exact IH ⬝* !comp_pid}}, end definition LES_of_loop_spaces2 [constructor] : type_chain_complex +3ℕ := transfer_type_chain_complex2 LES_of_loop_spaces !fin_prod_nat_equiv_nat nat_of_str_3S @loop_spaces_fun2 @loop_spaces2_pequiv begin intro m x, refine loop_spaces_fun2_phomotopy m x ⬝ _, apply ap (loop_spaces_fun2 m), apply ap (loop_spaces2_pequiv (S m)), esimp, exact ap010 cast !ap_compose⁻¹ x end definition is_exact_LES_of_loop_spaces2 : is_exact_t LES_of_loop_spaces2 := begin intro n, apply is_exact_at_transfer2, apply is_exact_LES_of_loop_spaces end definition LES_of_homotopy_groups' [constructor] : chain_complex +3ℕ := trunc_chain_complex LES_of_loop_spaces2 /-------------- PART 4 --------------/ definition homotopy_groups [reducible] : +3ℕ → Set* | (n, fin.mk 0 H) := π*[n] Y | (n, fin.mk 1 H) := π*[n] X | (n, fin.mk k H) := π*[n] (pfiber f) definition homotopy_groups_pequiv_loop_spaces2 [reducible] : Π(n : +3ℕ), ptrunc 0 (loop_spaces2 n) ≃* homotopy_groups n | (n, fin.mk 0 H) := by reflexivity | (n, fin.mk 1 H) := by reflexivity | (n, fin.mk 2 H) := by reflexivity | (n, fin.mk (k+3) H) := begin exfalso, apply lt_le_antisymm H, apply le_add_left end definition homotopy_groups_fun : Π(n : +3ℕ), homotopy_groups (S n) →* homotopy_groups n | (n, fin.mk 0 H) := proof π→*[n] f qed | (n, fin.mk 1 H) := proof π→*[n] (ppoint f) qed | (n, fin.mk 2 H) := proof π→*[n] boundary_map ∘* pcast (ap (ptrunc 0) (loop_space_succ_eq_in Y n)) qed | (n, fin.mk (k+3) H) := begin exfalso, apply lt_le_antisymm H, apply le_add_left end definition homotopy_groups_fun_phomotopy_loop_spaces_fun2 [reducible] : Π(n : +3ℕ), homotopy_groups_pequiv_loop_spaces2 n ∘* ptrunc_functor 0 (loop_spaces_fun2 n) ~* homotopy_groups_fun n ∘* homotopy_groups_pequiv_loop_spaces2 (S n) | (n, fin.mk 0 H) := by reflexivity | (n, fin.mk 1 H) := by reflexivity | (n, fin.mk 2 H) := begin refine !pid_comp ⬝* _ ⬝* !comp_pid⁻¹*, refine !ptrunc_functor_pcompose ⬝* _, apply pwhisker_left, apply ptrunc_functor_pcast, end | (n, fin.mk (k+3) H) := begin exfalso, apply lt_le_antisymm H, apply le_add_left end definition LES_of_homotopy_groups [constructor] : chain_complex +3ℕ := transfer_chain_complex LES_of_homotopy_groups' homotopy_groups_fun homotopy_groups_pequiv_loop_spaces2 homotopy_groups_fun_phomotopy_loop_spaces_fun2 definition is_exact_LES_of_homotopy_groups : is_exact LES_of_homotopy_groups := begin intro n, apply is_exact_at_transfer, apply is_exact_at_trunc, apply is_exact_LES_of_loop_spaces2 end variable (n : ℕ) /- the carrier of the fiber sequence is definitionally what we want (as pointed sets) -/ example : LES_of_homotopy_groups (str_of_nat 6) = π*[2] Y :> Set* := by reflexivity example : LES_of_homotopy_groups (str_of_nat 7) = π*[2] X :> Set* := by reflexivity example : LES_of_homotopy_groups (str_of_nat 8) = π*[2] (pfiber f) :> Set* := by reflexivity example : LES_of_homotopy_groups (str_of_nat 9) = π*[3] Y :> Set* := by reflexivity example : LES_of_homotopy_groups (str_of_nat 10) = π*[3] X :> Set* := by reflexivity example : LES_of_homotopy_groups (str_of_nat 11) = π*[3] (pfiber f) :> Set* := by reflexivity definition LES_of_homotopy_groups_0 : LES_of_homotopy_groups (n, 0) = π*[n] Y := by reflexivity definition LES_of_homotopy_groups_1 : LES_of_homotopy_groups (n, 1) = π*[n] X := by reflexivity definition LES_of_homotopy_groups_2 : LES_of_homotopy_groups (n, 2) = π*[n] (pfiber f) := by reflexivity /- the functions of the fiber sequence is definitionally what we want (as pointed function). -/ definition LES_of_homotopy_groups_fun_0 : cc_to_fn LES_of_homotopy_groups (n, 0) = π→*[n] f := by reflexivity definition LES_of_homotopy_groups_fun_1 : cc_to_fn LES_of_homotopy_groups (n, 1) = π→*[n] (ppoint f) := by reflexivity definition LES_of_homotopy_groups_fun_2 : cc_to_fn LES_of_homotopy_groups (n, 2) = π→*[n] boundary_map ∘* pcast (ap (ptrunc 0) (loop_space_succ_eq_in Y n)) := by reflexivity open group definition group_LES_of_homotopy_groups (n : ℕ) : Π(x : fin (succ 2)), group (LES_of_homotopy_groups (n + 1, x)) | (fin.mk 0 H) := begin rexact group_homotopy_group n Y end | (fin.mk 1 H) := begin rexact group_homotopy_group n X end | (fin.mk 2 H) := begin rexact group_homotopy_group n (pfiber f) end | (fin.mk (k+3) H) := begin exfalso, apply lt_le_antisymm H, apply le_add_left end definition comm_group_LES_of_homotopy_groups (n : ℕ) : Π(x : fin (succ 2)), comm_group (LES_of_homotopy_groups (n + 2, x)) | (fin.mk 0 H) := proof comm_group_homotopy_group n Y qed | (fin.mk 1 H) := proof comm_group_homotopy_group n X qed | (fin.mk 2 H) := proof comm_group_homotopy_group n (pfiber f) qed | (fin.mk (k+3) H) := begin exfalso, apply lt_le_antisymm H, apply le_add_left end definition Group_LES_of_homotopy_groups (x : +3ℕ) : Group.{u} := Group.mk (LES_of_homotopy_groups (nat.succ (pr1 x), pr2 x)) (group_LES_of_homotopy_groups (pr1 x) (pr2 x)) definition CommGroup_LES_of_homotopy_groups (n : +3ℕ) : CommGroup.{u} := CommGroup.mk (LES_of_homotopy_groups (pr1 n + 2, pr2 n)) (comm_group_LES_of_homotopy_groups (pr1 n) (pr2 n)) definition homomorphism_LES_of_homotopy_groups_fun : Π(k : +3ℕ), Group_LES_of_homotopy_groups (S k) →g Group_LES_of_homotopy_groups k | (k, fin.mk 0 H) := proof homomorphism.mk (cc_to_fn LES_of_homotopy_groups (k + 1, 0)) (phomotopy_group_functor_mul _ _) qed | (k, fin.mk 1 H) := proof homomorphism.mk (cc_to_fn LES_of_homotopy_groups (k + 1, 1)) (phomotopy_group_functor_mul _ _) qed | (k, fin.mk 2 H) := begin apply homomorphism.mk (cc_to_fn LES_of_homotopy_groups (k + 1, 2)), exact abstract begin rewrite [LES_of_homotopy_groups_fun_2], refine @is_homomorphism_compose _ _ _ _ _ _ (π→*[k + 1] boundary_map) _ _ _, { apply group_homotopy_group k}, { apply phomotopy_group_functor_mul}, { rewrite [▸*, -ap_compose', ▸*], apply is_homomorphism_cast_loop_space_succ_eq_in} end end end | (k, fin.mk (l+3) H) := begin exfalso, apply lt_le_antisymm H, apply le_add_left end end end chain_complex