118 lines
5.1 KiB
Text
118 lines
5.1 KiB
Text
/-
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Copyright (c) 2016 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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Authors: Floris van Doorn
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Given a sequence of LES's, we want to splice them together.
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... -> G_{1,k+1} -> G_{1,k} -> ... -> G_{1,1} -> G_{1,0}
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... -> G_{2,k+1} -> G_{2,k} -> ... -> G_{2,1} -> G_{2,0}
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...
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... -> G_{n,k+1} -> G_{n,k} -> ... -> G_{n,1} -> G_{n,0}
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...
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If we have equivalences:
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G_{n,m) = G_{n+1,m+k}
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G_{n,m+1) = G_{n+1,m+k+1}
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such that the evident squares commute, we can obtain a single sequence
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... -> G_{n,m} -> G_{n+1,m+k-1} -> ... -> G_{n+1,m} -> G_{n+2,m+k-1} -> ...
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However, in this formalization, we will only do this for k = 3, because we get more definitional
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equalities in this specific case than in the general case. The reason is that we need to check
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whether a term `x : fin (succ k)` represents `n`. If we do this in general using
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if x = n then ... else ...
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we don't get definitionally that x = n and the successor of x is 0, which means that when defining
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maps G_{n,m} -> G_{n+1,m+k-1} we need to transport along those paths, which is annoying.
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So far, the splicing seems to be only needed for k = 3, so it seems to be sufficient.
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-/
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import homotopy.chain_complex
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open prod prod.ops succ_str fin pointed nat algebra eq is_trunc equiv is_equiv
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/- fin -/
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-- definition cyclic_pred {n : ℕ} (x : fin n) : fin n :=
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-- begin
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-- cases n with n,
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-- { exfalso, apply not_lt_zero _ (is_lt x)},
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-- { cases x with m H, cases m with m,
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-- { exact fin.mk n !self_lt_succ},
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-- { apply fin.mk m, exact lt.trans !self_lt_succ H}}
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-- end
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-- definition stratified_succ2 {N : succ_str} {n : ℕ} (x : stratified_type N n)
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-- : stratified_type N n :=
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-- (nat.cases_on (pr2 x) (S (pr1 x)) (λa, pr1 x), cyclic_pred (pr2 x))
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-- definition stratified2 [reducible] [constructor] (N : succ_str) (n : ℕ) : succ_str :=
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-- succ_str.mk (stratified_type N n) stratified_succ2
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namespace chain_complex
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definition stratified_succ_max {N : succ_str} {n : ℕ} (x : stratified N n) (p : val (pr2 x) = n)
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: S x = (S (pr1 x), 0) :=
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begin
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unfold [stratified, succ_str.S, stratified_succ],
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apply prod_eq,
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{ exact if_pos p},
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{ exact dif_pos p}
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end
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--move
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definition succ_str.add [reducible] {N : succ_str} (n : N) (k : ℕ) : N :=
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iterate S k n
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infix ` +' `:65 := succ_str.add
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definition splice_type [unfold 5] {N M : succ_str} (G : N → chain_complex M) (m : M)
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(x : stratified N 2) : Set* :=
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G x.1 (m +' val x.2)
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definition splice_map {N M : succ_str} (G : N → chain_complex M) (m : M)
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(e0 : Πn, G (S n) m ≃* G n (m +' 3)) :
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Π(x : stratified N 2), splice_type G m (S x) →* splice_type G m x
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| (n, fin.mk 0 H) := proof cc_to_fn (G n) m qed
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| (n, fin.mk 1 H) := proof cc_to_fn (G n) (S m) qed
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| (n, fin.mk 2 H) := proof cc_to_fn (G n) (S (S m)) ∘* e0 n qed
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| (n, fin.mk (k+3) H) := begin exfalso, apply lt_le_antisymm H, apply le_add_left end
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definition is_chain_complex_splice_map {N M : succ_str} (G : N → chain_complex M) (m : M)
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(e0 : Πn, G (S n) m ≃* G n (m +' 3)) (e1 : Πn, G (S n) (S m) ≃* G n (S (m +' 3)))
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(p : Πn, e0 n ∘* cc_to_fn (G (S n)) m ~ cc_to_fn (G n) (m +' 3) ∘* e1 n) :
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Π(x : stratified N 2) (y : splice_type G m (S (S x))),
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splice_map G m e0 x (splice_map G m e0 (S x) y) = pt
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| (n, fin.mk 0 H) y := proof cc_is_chain_complex (G n) m y qed
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| (n, fin.mk 1 H) y := proof cc_is_chain_complex (G n) (S m) (e0 n y) qed
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| (n, fin.mk 2 H) y := proof ap (cc_to_fn (G n) (S (S m))) (p n y) ⬝
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cc_is_chain_complex (G n) (S (S m)) (e1 n y) qed
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| (n, fin.mk (k+3) H) y := begin exfalso, apply lt_le_antisymm H, apply le_add_left end
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definition splice [constructor] {N M : succ_str} (G : N → chain_complex M) (m : M)
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(e0 : Πn, G (S n) m ≃* G n (m +' 3)) (e1 : Πn, G (S n) (S m) ≃* G n (S (m +' 3)))
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(p : Πn, e0 n ∘* cc_to_fn (G (S n)) m ~ cc_to_fn (G n) (m +' 3) ∘* e1 n) :
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chain_complex (stratified N 2) :=
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chain_complex.mk (splice_type G m) (splice_map G m e0) (is_chain_complex_splice_map G m e0 e1 p)
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definition is_exact_splice {N M : succ_str} (G : N → chain_complex M) (m : M)
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(e0 : Πn, G (S n) m ≃* G n (m +' 3)) (e1 : Πn, G (S n) (S m) ≃* G n (S (m +' 3)))
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(p : Πn, e0 n ∘* cc_to_fn (G (S n)) m ~ cc_to_fn (G n) (m +' 3) ∘* e1 n)
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(H2 : Πn, is_exact (G n)) : Π(x : stratified N 2), is_exact_at (splice G m e0 e1 p) x
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| (n, fin.mk 0 H) := proof H2 n m qed
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| (n, fin.mk 1 H) := begin intro y q, induction H2 n (S m) proof y qed proof q qed with x r,
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apply image.mk ((e0 n)⁻¹ᵉ x),
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exact ap (pmap.to_fun (cc_to_fn (G n) (S (S m)))) (to_right_inv (e0 n) x) ⬝ r end
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| (n, fin.mk 2 H) :=
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begin intro y q, induction H2 n (S (S m)) proof e0 n y qed proof q qed with x r,
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apply image.mk ((e1 n)⁻¹ᵉ x),
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refine _ ⬝ to_left_inv (e0 n) y, refine _ ⬝ ap (e0 n)⁻¹ᵉ r, apply @eq_inv_of_eq _ _ (e0 n),
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refine p n ((e1 n)⁻¹ᵉ x) ⬝ _, apply ap (cc_to_fn (G n) (m +' 3)), exact to_right_inv (e1 n) x
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end
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| (n, fin.mk (k+3) H) := begin exfalso, apply lt_le_antisymm H, apply le_add_left end
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end chain_complex
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