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PhysLean/HepLean/SpaceTime/LorentzTensor/IndexNotation/WithUniqueDual.lean

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refactor: Lint
2024-08-15 10:16:42 -04:00
/-
Copyright (c) 2024 Joseph Tooby-Smith. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Joseph Tooby-Smith
-/
import HepLean.SpaceTime.LorentzTensor.IndexNotation.WithDual
import Mathlib.Algebra.Order.Ring.Nat
import Mathlib.Data.Finset.Sort
/-!
# With Unique Dual
Finite sets of indices with a unique dual.
-/
namespace IndexNotation
namespace IndexList
variable {X : Type} [IndexNotation X] [Fintype X] [DecidableEq X]
variable (l l2 l3 : IndexList X)
/-!
## Unique duals
-/
/-- The finite set of indices of an index list which have a unique dual in that index list. -/
def withUniqueDual : Finset (Fin l.length) :=
Finset.filter (fun i => i ∈ l.withDual ∧
∀ j, l.AreDualInSelf i j → j = l.getDual? i) Finset.univ
/-- The finite set of indices of an index list which have a unique dual in another, provided, index
list. -/
def withUniqueDualInOther : Finset (Fin l.length) :=
Finset.filter (fun i => i ∉ l.withDual ∧ i ∈ l.withDualInOther l2
∧ (∀ j, l.AreDualInOther l2 i j → j = l.getDualInOther? l2 i)) Finset.univ
/-!
## Basic properties of withUniqueDual
-/
@[simp, nolint simpNF]
lemma mem_withDual_of_mem_withUniqueDual (i : Fin l.length) (h : i ∈ l.withUniqueDual) :
i ∈ l.withDual := by
simp only [withUniqueDual, mem_withDual_iff_isSome, Finset.mem_filter, Finset.mem_univ,
true_and] at h
simpa using h.1
@[simp]
lemma mem_withUniqueDual_isSome (i : Fin l.length) (h : i ∈ l.withUniqueDual) :
(l.getDual? i).isSome := by
simpa using mem_withDual_of_mem_withUniqueDual l i h
lemma mem_withDual_of_withUniqueDual (i : l.withUniqueDual) :
i.1 ∈ l.withDual :=
mem_withDual_of_mem_withUniqueDual l (↑i) i.2
/-!
## Basic properties of withUniqueDualInOther
-/
lemma not_mem_withDual_of_withUniqueDualInOther (i : l.withUniqueDualInOther l2) :
i.1 ∉ l.withDual := by
have hi := i.2
simp only [withUniqueDualInOther, Finset.univ_eq_attach, Finset.mem_filter, Finset.mem_attach,
true_and] at hi
exact hi.2.1
lemma mem_withDualInOther_of_withUniqueDualInOther (i : l.withUniqueDualInOther l2) :
i.1 ∈ l.withDualInOther l2 := by
have hi := i.2
simp only [withUniqueDualInOther, Finset.univ_eq_attach, Finset.mem_filter, Finset.mem_attach,
true_and] at hi
exact hi.2.2.1
@[simp]
lemma mem_withUniqueDualInOther_isSome (i : Fin l.length) (hi : i ∈ l.withUniqueDualInOther l2) :
(l.getDualInOther? l2 i).isSome := by
simp only [withUniqueDualInOther, Finset.mem_filter, Finset.mem_univ, true_and] at hi
exact (mem_withInDualOther_iff_isSome l l2 i).mp hi.2.1
/-!
## Properties of getDual? and withUniqueDual
-/
lemma all_dual_eq_getDual?_of_mem_withUniqueDual (i : Fin l.length) (h : i ∈ l.withUniqueDual) :
∀ j, l.AreDualInSelf i j → j = l.getDual? i := by
simp [withUniqueDual] at h
exact fun j hj => h.2 j hj
lemma some_eq_getDual?_of_withUniqueDual_iff (i j : Fin l.length) (h : i ∈ l.withUniqueDual) :
l.AreDualInSelf i j ↔ some j = l.getDual? i := by
apply Iff.intro
exact fun h' => all_dual_eq_getDual?_of_mem_withUniqueDual l i h j h'
intro h'
have hj : j = (l.getDual? i).get (mem_withUniqueDual_isSome l i h) :=
Eq.symm (Option.get_of_mem (mem_withUniqueDual_isSome l i h) (id (Eq.symm h')))
subst hj
exact (getDual?_get_areDualInSelf l i (mem_withUniqueDual_isSome l i h)).symm
@[simp]
lemma eq_getDual?_get_of_withUniqueDual_iff (i j : Fin l.length) (h : i ∈ l.withUniqueDual) :
l.AreDualInSelf i j ↔ j = (l.getDual? i).get (mem_withUniqueDual_isSome l i h) := by
rw [l.some_eq_getDual?_of_withUniqueDual_iff i j h]
refine Iff.intro (fun h' => ?_) (fun h' => ?_)
exact Eq.symm (Option.get_of_mem (mem_withUniqueDual_isSome l i h) (id (Eq.symm h')))
simp [h']
lemma eq_of_areDualInSelf_withUniqueDual {j k : Fin l.length} (i : l.withUniqueDual)
(hj : l.AreDualInSelf i j) (hk : l.AreDualInSelf i k) : j = k := by
simp at hj hk
exact hj.trans hk.symm
@[simp, nolint simpNF]
lemma getDual?_get_getDual?_get_of_withUniqueDual (i : Fin l.length) (h : i ∈ l.withUniqueDual) :
(l.getDual? ((l.getDual? i).get (mem_withUniqueDual_isSome l i h))).get
(l.getDual?_getDual?_get_isSome i (mem_withUniqueDual_isSome l i h)) = i := by
by_contra hn
have h' : l.AreDualInSelf i ((l.getDual? ((l.getDual? i).get
(mem_withUniqueDual_isSome l i h))).get (
getDual?_getDual?_get_isSome l i (mem_withUniqueDual_isSome l i h))) := by
simp [AreDualInSelf, hn]
exact fun a => hn (id (Eq.symm a))
simp [h] at h'
@[simp, nolint simpNF]
lemma getDual?_getDual?_get_of_withUniqueDual (i : Fin l.length) (h : i ∈ l.withUniqueDual) :
l.getDual? ((l.getDual? i).get (mem_withUniqueDual_isSome l i h)) = some i := by
nth_rewrite 3 [← l.getDual?_get_getDual?_get_of_withUniqueDual i h]
exact Option.eq_some_of_isSome
(getDual?_getDual?_get_isSome l i (mem_withUniqueDual_isSome l i h))
@[simp]
lemma getDual?_getDual?_of_withUniqueDual (i : Fin l.length) (h : i ∈ l.withUniqueDual) :
(l.getDual? i).bind l.getDual? = some i := by
have h1 : (l.getDual? i) = some ((l.getDual? i).get (mem_withUniqueDual_isSome l i h)) :=
Option.eq_some_of_isSome (mem_withUniqueDual_isSome l i h)
nth_rewrite 1 [h1]
rw [Option.some_bind']
exact getDual?_getDual?_get_of_withUniqueDual l i h
@[simp, nolint simpNF]
lemma getDual?_get_of_mem_withUnique_mem (i : Fin l.length) (h : i ∈ l.withUniqueDual) :
(l.getDual? i).get (l.mem_withUniqueDual_isSome i h) ∈ l.withUniqueDual := by
simp only [withUniqueDual, mem_withDual_iff_isSome, Finset.mem_filter, Finset.mem_univ,
getDual?_getDual?_get_isSome, true_and]
intro j hj
have h1 : i = j := by
by_contra hn
have h' : l.AreDualInSelf i j := by
simp only [AreDualInSelf, ne_eq, hn, not_false_eq_true, true_and]
simp_all only [AreDualInSelf, ne_eq, getDual?_get_id]
simp [h] at h'
subst h'
simp_all
subst h1
exact Eq.symm (getDual?_getDual?_get_of_withUniqueDual l i h)
/-!
## Properties of getDualInOther? and withUniqueDualInOther
-/
lemma all_dual_eq_of_withUniqueDualInOther (i : Fin l.length)
(h : i ∈ l.withUniqueDualInOther l2) :
∀ j, l.AreDualInOther l2 i j → j = l.getDualInOther? l2 i := by
simp [withUniqueDualInOther] at h
exact fun j hj => h.2.2 j hj
lemma some_eq_getDualInOther?_of_withUniqueDualInOther_iff (i : Fin l.length) (j : Fin l2.length)
(h : i ∈ l.withUniqueDualInOther l2) :
l.AreDualInOther l2 i j ↔ some j = l.getDualInOther? l2 i := by
apply Iff.intro
exact fun h' => l.all_dual_eq_of_withUniqueDualInOther l2 i h j h'
intro h'
have hj : j = (l.getDualInOther? l2 i).get (mem_withUniqueDualInOther_isSome l l2 i h) :=
Eq.symm (Option.get_of_mem (mem_withUniqueDualInOther_isSome l l2 i h) (id (Eq.symm h')))
subst hj
exact getDualInOther?_areDualInOther_get l l2 i (mem_withUniqueDualInOther_isSome l l2 i h)
@[simp]
lemma eq_getDualInOther?_get_of_withUniqueDualInOther_iff (i : Fin l.length) (j : Fin l2.length)
(h : i ∈ l.withUniqueDualInOther l2) :
l.AreDualInOther l2 i j ↔ j = (l.getDualInOther? l2 i).get
(mem_withUniqueDualInOther_isSome l l2 i h) := by
rw [l.some_eq_getDualInOther?_of_withUniqueDualInOther_iff l2 i j h]
refine Iff.intro (fun h' => ?_) (fun h' => ?_)
exact Eq.symm (Option.get_of_mem (mem_withUniqueDualInOther_isSome l l2 i h) (id (Eq.symm h')))
simp [h']
@[simp, nolint simpNF]
lemma getDualInOther?_get_getDualInOther?_get_of_withUniqueDualInOther
(i : Fin l.length) (h : i ∈ l.withUniqueDualInOther l2) :
(l2.getDualInOther? l ((l.getDualInOther? l2 i).get
(mem_withUniqueDualInOther_isSome l l2 i h))).get
(l.getDualInOther?_getDualInOther?_get_isSome l2 i
(mem_withUniqueDualInOther_isSome l l2 i h)) = i := by
by_contra hn
have h' : l.AreDualInSelf i ((l2.getDualInOther? l ((l.getDualInOther? l2 i).get
(mem_withUniqueDualInOther_isSome l l2 i h))).get
(l.getDualInOther?_getDualInOther?_get_isSome l2 i
(mem_withUniqueDualInOther_isSome l l2 i h))):= by
simp [AreDualInSelf, hn]
exact fun a => hn (id (Eq.symm a))
have h1 := l.not_mem_withDual_of_withUniqueDualInOther l2 ⟨i, h⟩
simp [getDual?] at h1
rw [Fin.find_eq_none_iff] at h1
exact h1 _ h'
@[simp, nolint simpNF]
lemma getDualInOther?_getDualInOther?_get_of_withUniqueDualInOther (i : Fin l.length)
(h : i ∈ l.withUniqueDualInOther l2) :
l2.getDualInOther? l ((l.getDualInOther? l2 i).get (mem_withUniqueDualInOther_isSome l l2 i h))
= some i := by
nth_rewrite 3 [← l.getDualInOther?_get_getDualInOther?_get_of_withUniqueDualInOther l2 i h]
exact Option.eq_some_of_isSome
(getDualInOther?_getDualInOther?_get_isSome l l2 i (mem_withUniqueDualInOther_isSome l l2 i h))
@[simp]
lemma getDualInOther?_getDualInOther?_of_withUniqueDualInOther
(i : Fin l.length) (h : i ∈ l.withUniqueDualInOther l2) :
(l.getDualInOther? l2 i).bind (l2.getDualInOther? l) = some i := by
have h1 : (l.getDualInOther? l2 i) = some ((l.getDualInOther? l2 i).get
(mem_withUniqueDualInOther_isSome l l2 i h)) :=
Option.eq_some_of_isSome (mem_withUniqueDualInOther_isSome l l2 i h)
nth_rewrite 1 [h1]
rw [Option.some_bind']
exact getDualInOther?_getDualInOther?_get_of_withUniqueDualInOther l l2 i h
lemma eq_of_areDualInOther_withUniqueDualInOther {j k : Fin l2.length}
(i : l.withUniqueDualInOther l2)
(hj : l.AreDualInOther l2 i j) (hk : l.AreDualInOther l2 i k) : j = k := by
simp at hj hk
exact hj.trans hk.symm
lemma getDual?_of_getDualInOther?_of_mem_withUniqueInOther_eq_none (i : Fin l.length)
(h : i ∈ l.withUniqueDualInOther l2) : l2.getDual?
((l.getDualInOther? l2 i).get (l.mem_withUniqueDualInOther_isSome l2 i h)) = none := by
by_contra hn
rw [← @Option.not_isSome_iff_eq_none, not_not] at hn
rw [@getDual?_isSome_iff_exists] at hn
obtain ⟨j, hj⟩ := hn
have hx : l.AreDualInOther l2 i j := by
simp [AreDualInOther, hj]
simp [AreDualInSelf] at hj
exact hj.2
have hn := l.eq_of_areDualInOther_withUniqueDualInOther l2 ⟨i, h⟩ hx
(getDualInOther?_areDualInOther_get l l2 i (mem_withUniqueDualInOther_isSome l l2 i h))
subst hn
simp_all
@[simp, nolint simpNF]
lemma getDualInOther?_get_of_mem_withUniqueInOther_mem (i : Fin l.length)
(h : i ∈ l.withUniqueDualInOther l2) :
(l.getDualInOther? l2 i).get
(l.mem_withUniqueDualInOther_isSome l2 i h) ∈ l2.withUniqueDualInOther l := by
simp only [withUniqueDualInOther, mem_withDual_iff_isSome, Bool.not_eq_true, Option.not_isSome,
Option.isNone_iff_eq_none, mem_withInDualOther_iff_isSome, Finset.mem_filter, Finset.mem_univ,
getDualInOther?_getDualInOther?_get_isSome, true_and]
apply And.intro
exact getDual?_of_getDualInOther?_of_mem_withUniqueInOther_eq_none l l2 i h
intro j hj
simp only [h, getDualInOther?_getDualInOther?_get_of_withUniqueDualInOther, Option.some.injEq]
by_contra hn
have hx : l.AreDualInSelf i j := by
simp [AreDualInSelf, hn]
simp [AreDualInOther] at hj
exact ⟨fun a => hn (id (Eq.symm a)), hj⟩
simp only [withUniqueDualInOther, mem_withDual_iff_isSome, getDual?, Bool.not_eq_true,
Option.not_isSome, Option.isNone_iff_eq_none, mem_withInDualOther_iff_isSome, Finset.mem_filter,
Finset.mem_univ, true_and] at h
rw [Fin.find_eq_none_iff] at h
simp_all only
@[simp]
lemma getDualInOther?_self_of_mem_withUniqueInOther (i : Fin l.length)
(h : i ∈ l.withUniqueDualInOther l) :
l.getDualInOther? l i = some i := by
rw [all_dual_eq_of_withUniqueDualInOther l l i h i rfl]
/-!
## Properties of getDual?, withUniqueDual and append
-/
lemma append_inl_not_mem_withDual_of_withDualInOther (i : Fin l.length)
(h : appendEquiv (Sum.inl i) ∈ (l ++ l2).withUniqueDual) :
i ∈ l.withDual ↔ ¬ i ∈ l.withDualInOther l2 := by
refine Iff.intro (fun hs => ?_) (fun ho => ?_)
· by_contra ho
obtain ⟨j, hj⟩ := (l.mem_withDual_iff_exists).mp hs
obtain ⟨k, hk⟩ := (l.mem_withInDualOther_iff_exists l2).mp ho
have h1 : appendEquiv (Sum.inl j) = appendEquiv (Sum.inr k) := by
refine (l ++ l2).eq_of_areDualInSelf_withUniqueDual ⟨appendEquiv (Sum.inl i), h⟩ ?_ ?_
exact AreDualInSelf.append_inl_inl.mpr hj
simpa using hk
simp at h1
· have ht : ((l ++ l2).getDual? (appendEquiv (Sum.inl i))).isSome :=
mem_withUniqueDual_isSome (l ++ l2) (appendEquiv (Sum.inl i)) h
simp only [getDual?_isSome_append_inl_iff] at ht
simp_all
lemma append_inr_not_mem_withDual_of_withDualInOther (i : Fin l2.length)
(h : appendEquiv (Sum.inr i) ∈ (l ++ l2).withUniqueDual) :
i ∈ l2.withDual ↔ ¬ i ∈ l2.withDualInOther l := by
refine Iff.intro (fun hs => ?_) (fun ho => ?_)
· by_contra ho
obtain ⟨j, hj⟩ := (l2.mem_withDual_iff_exists).mp hs
obtain ⟨k, hk⟩ := (l2.mem_withInDualOther_iff_exists l).mp ho
have h1 : appendEquiv (Sum.inr j) = appendEquiv (Sum.inl k) := by
refine (l ++ l2).eq_of_areDualInSelf_withUniqueDual ⟨appendEquiv (Sum.inr i), h⟩ ?_ ?_
exact (AreDualInSelf.append_inr_inr l l2 i j).mpr hj
simpa using hk
simp at h1
· have ht : ((l ++ l2).getDual? (appendEquiv (Sum.inr i))).isSome :=
mem_withUniqueDual_isSome (l ++ l2) (appendEquiv (Sum.inr i)) h
simp only [getDual?_isSome_append_inr_iff] at ht
simp_all
lemma getDual?_append_symm_of_withUniqueDual_of_inl (i : Fin l.length) (k : Fin l2.length)
(h : appendEquiv (Sum.inl i) ∈ (l ++ l2).withUniqueDual) :
(l ++ l2).getDual? (appendEquiv (Sum.inl i)) = some (appendEquiv (Sum.inr k))
↔ (l2 ++ l).getDual? (appendEquiv (Sum.inr i)) = some (appendEquiv (Sum.inl k)) := by
have h := l.append_inl_not_mem_withDual_of_withDualInOther l2 i h
by_cases hs : (l.getDual? i).isSome
<;> by_cases ho : (l.getDualInOther? l2 i).isSome
<;> simp_all [hs, ho]
lemma getDual?_append_symm_of_withUniqueDual_of_inl' (i k : Fin l.length)
(h : appendEquiv (Sum.inl i) ∈ (l ++ l2).withUniqueDual) :
(l ++ l2).getDual? (appendEquiv (Sum.inl i)) = some (appendEquiv (Sum.inl k))
↔ (l2 ++ l).getDual? (appendEquiv (Sum.inr i)) = some (appendEquiv (Sum.inr k)) := by
have h := l.append_inl_not_mem_withDual_of_withDualInOther l2 i h
by_cases hs : (l.getDual? i).isSome
<;> by_cases ho : (l.getDualInOther? l2 i).isSome
<;> simp_all [hs, ho]
lemma getDual?_append_symm_of_withUniqueDual_of_inr (i : Fin l2.length) (k : Fin l.length)
(h : appendEquiv (Sum.inr i) ∈ (l ++ l2).withUniqueDual) :
(l ++ l2).getDual? (appendEquiv (Sum.inr i)) = some (appendEquiv (Sum.inl k))
↔ (l2 ++ l).getDual? (appendEquiv (Sum.inl i)) = some (appendEquiv (Sum.inr k)) := by
have h := l.append_inr_not_mem_withDual_of_withDualInOther l2 i h
by_cases hs : (l2.getDual? i).isSome
<;> by_cases ho : (l2.getDualInOther? l i).isSome
<;> simp_all [hs, ho]
lemma getDual?_append_symm_of_withUniqueDual_of_inr' (i k : Fin l2.length)
(h : appendEquiv (Sum.inr i) ∈ (l ++ l2).withUniqueDual) :
(l ++ l2).getDual? (appendEquiv (Sum.inr i)) = some (appendEquiv (Sum.inr k))
↔ (l2 ++ l).getDual? (appendEquiv (Sum.inl i)) = some (appendEquiv (Sum.inl k)) := by
have h := l.append_inr_not_mem_withDual_of_withDualInOther l2 i h
by_cases hs : (l2.getDual? i).isSome
<;> by_cases ho : (l2.getDualInOther? l i).isSome
<;> simp_all [hs, ho]
lemma mem_withUniqueDual_append_symm (i : Fin l.length) :
appendEquiv (Sum.inl i) ∈ (l ++ l2).withUniqueDual ↔
appendEquiv (Sum.inr i) ∈ (l2 ++ l).withUniqueDual := by
simp only [withUniqueDual, mem_withDual_iff_isSome, Finset.mem_filter, Finset.mem_univ,
getDual?_isSome_append_inl_iff, true_and, getDual?_isSome_append_inr_iff, and_congr_right_iff]
intro h
refine Iff.intro (fun h' j hj => ?_) (fun h' j hj => ?_)
· obtain ⟨k, hk⟩ := appendEquiv.surjective j
subst hk
match k with
| Sum.inl k =>
have hk' := h' (appendEquiv (Sum.inr k))
simp only [AreDualInSelf.append_inl_inr] at hk'
simp only [AreDualInSelf.append_inr_inl] at hj
refine ((l.getDual?_append_symm_of_withUniqueDual_of_inl l2 _ _ ?_).mp (hk' hj).symm).symm
simp_all only [AreDualInSelf.append_inl_inr, imp_self, withUniqueDual,
mem_withDual_iff_isSome, Finset.mem_filter, Finset.mem_univ, getDual?_isSome_append_inl_iff,
implies_true, and_self, mem_withUniqueDual_isSome, eq_getDual?_get_of_withUniqueDual_iff,
getDual?_areDualInSelf_get]
| Sum.inr k =>
have hk' := h' (appendEquiv (Sum.inl k))
simp only [AreDualInSelf.append_inl_inl] at hk'
simp only [AreDualInSelf.append_inr_inr] at hj
refine ((l.getDual?_append_symm_of_withUniqueDual_of_inl' l2 _ _ ?_).mp (hk' hj).symm).symm
simp_all only [AreDualInSelf.append_inl_inl, imp_self, withUniqueDual,
mem_withDual_iff_isSome, Finset.mem_filter, Finset.mem_univ, getDual?_isSome_append_inl_iff,
implies_true, and_self, mem_withUniqueDual_isSome, eq_getDual?_get_of_withUniqueDual_iff,
getDual?_areDualInSelf_get]
· obtain ⟨k, hk⟩ := appendEquiv.surjective j
subst hk
match k with
| Sum.inl k =>
have hk' := h' (appendEquiv (Sum.inr k))
simp only [AreDualInSelf.append_inr_inr] at hk'
simp only [AreDualInSelf.append_inl_inl] at hj
refine ((l2.getDual?_append_symm_of_withUniqueDual_of_inr' l _ _ ?_).mp (hk' hj).symm).symm
simp_all only [AreDualInSelf.append_inr_inr, imp_self, withUniqueDual,
mem_withDual_iff_isSome, Finset.mem_filter, Finset.mem_univ, getDual?_isSome_append_inr_iff,
implies_true, and_self, mem_withUniqueDual_isSome, eq_getDual?_get_of_withUniqueDual_iff,
getDual?_areDualInSelf_get]
| Sum.inr k =>
have hk' := h' (appendEquiv (Sum.inl k))
simp only [AreDualInSelf.append_inr_inl] at hk'
simp only [AreDualInSelf.append_inl_inr] at hj
refine ((l2.getDual?_append_symm_of_withUniqueDual_of_inr l _ _ ?_).mp (hk' hj).symm).symm
simp_all only [AreDualInSelf.append_inr_inl, imp_self, withUniqueDual,
mem_withDual_iff_isSome, Finset.mem_filter, Finset.mem_univ, getDual?_isSome_append_inr_iff,
implies_true, and_self, mem_withUniqueDual_isSome, eq_getDual?_get_of_withUniqueDual_iff,
getDual?_areDualInSelf_get]
@[simp]
lemma not_mem_withDualInOther_of_inl_mem_withUniqueDual (i : Fin l.length)
(h : appendEquiv (Sum.inl i) ∈ (l ++ l2).withUniqueDual) (hs : i ∈ l.withUniqueDual) :
¬ i ∈ l.withUniqueDualInOther l2 := by
have hn := l.append_inl_not_mem_withDual_of_withDualInOther l2 i h
simp_all
by_contra ho
have ho' : (l.getDualInOther? l2 i).isSome := by
exact mem_withUniqueDualInOther_isSome l l2 i ho
simp_all [Option.isSome_none, Bool.false_eq_true]
@[simp]
lemma not_mem_withUniqueDual_of_inl_mem_withUnqieuDual (i : Fin l.length)
(h : appendEquiv (Sum.inl i) ∈ (l ++ l2).withUniqueDual) (hi : i ∈ l.withUniqueDualInOther l2) :
¬ i ∈ l.withUniqueDual := by
by_contra hs
simp_all only [not_mem_withDualInOther_of_inl_mem_withUniqueDual]
@[simp]
lemma mem_withUniqueDual_of_inl (i : Fin l.length)
(h : appendEquiv (Sum.inl i) ∈ (l ++ l2).withUniqueDual) (hi : (l.getDual? i).isSome) :
i ∈ l.withUniqueDual := by
simp only [withUniqueDual, mem_withDual_iff_isSome, Finset.mem_filter, Finset.mem_univ,
getDual?_isSome_append_inl_iff, true_and] at h ⊢
apply And.intro hi
intro j hj
have hj' := h.2 (appendEquiv (Sum.inl j))
simp at hj'
have hj'' := hj' hj
simp [hi] at hj''
simp_all
@[simp]
lemma mem_withUniqueDualInOther_of_inl_withDualInOther (i : Fin l.length)
(h : appendEquiv (Sum.inl i) ∈ (l ++ l2).withUniqueDual)
(hi : (l.getDualInOther? l2 i).isSome) : i ∈ l.withUniqueDualInOther l2 := by
simp only [withUniqueDualInOther, mem_withDual_iff_isSome, Bool.not_eq_true, Option.not_isSome,
Option.isNone_iff_eq_none, mem_withInDualOther_iff_isSome, Finset.mem_filter, Finset.mem_univ,
true_and]
have hn := l.append_inl_not_mem_withDual_of_withDualInOther l2 i h
simp_all only [mem_withDual_iff_isSome, mem_withInDualOther_iff_isSome, not_true_eq_false,
iff_false, Bool.not_eq_true, Option.not_isSome, Option.isNone_iff_eq_none, true_and]
intro j hj
simp only [withUniqueDual, mem_withDual_iff_isSome, Finset.mem_filter, Finset.mem_univ,
getDual?_isSome_append_inl_iff, true_and] at h
have hj' := h.2 (appendEquiv (Sum.inr j))
simp only [AreDualInSelf.append_inl_inr] at hj'
have hj'' := hj' hj
simp only [hn, Option.isNone_none, hi, getDual?_inl_of_getDual?_isNone_getDualInOther?_isSome,
Option.some.injEq, EmbeddingLike.apply_eq_iff_eq, Sum.inr.injEq] at hj''
simp_all only [getDualInOther?_areDualInOther_get, Option.isSome_none, Bool.false_eq_true,
or_true, Option.isNone_none, getDual?_inl_of_getDual?_isNone_getDualInOther?_isSome,
Option.some.injEq, true_and, AreDualInSelf.append_inl_inr, imp_self, Option.some_get]
lemma withUniqueDual_iff_not_withUniqueDualInOther_of_inl_withUniqueDualInOther
(i : Fin l.length) (h : appendEquiv (Sum.inl i) ∈ (l ++ l2).withUniqueDual) :
i ∈ l.withUniqueDual ↔ ¬ i ∈ l.withUniqueDualInOther l2 := by
by_cases h' : (l.getDual? i).isSome
have hn : i ∈ l.withUniqueDual := mem_withUniqueDual_of_inl l l2 i h h'
simp_all
have hn := l.append_inl_not_mem_withDual_of_withDualInOther l2 i h
simp_all
simp [withUniqueDual]
simp_all
exact mem_withUniqueDualInOther_of_inl_withDualInOther l l2 i h (Option.ne_none_iff_isSome.mp hn)
lemma append_inl_mem_withUniqueDual_of_withUniqueDual (i : Fin l.length)
(h : i ∈ l.withUniqueDual) (hn : i ∉ l.withDualInOther l2) :
appendEquiv (Sum.inl i) ∈ (l ++ l2).withUniqueDual := by
simp only [withUniqueDual, mem_withDual_iff_isSome, Finset.mem_filter, Finset.mem_univ,
getDual?_isSome_append_inl_iff, true_and]
apply And.intro
simp_all
intro j hj
obtain ⟨k, hk⟩ := appendEquiv.surjective j
subst hk
match k with
| Sum.inl k => simp_all
| Sum.inr k =>
simp at hj
refine False.elim (hn ?_)
exact (l.mem_withInDualOther_iff_exists _).mpr ⟨k, hj⟩
lemma append_inl_mem_of_withUniqueDualInOther (i : Fin l.length)
(ho : i ∈ l.withUniqueDualInOther l2) :
appendEquiv (Sum.inl i) ∈ (l ++ l2).withUniqueDual := by
simp only [withUniqueDual, mem_withDual_iff_isSome, Finset.mem_filter, Finset.mem_univ,
getDual?_isSome_append_inl_iff, true_and]
apply And.intro
simp_all only [mem_withUniqueDualInOther_isSome, or_true]
intro j hj
obtain ⟨k, hk⟩ := appendEquiv.surjective j
subst hk
have hs := l.not_mem_withDual_of_withUniqueDualInOther l2 ⟨i, ho⟩
match k with
| Sum.inl k =>
refine False.elim (hs ?_)
simp at hj
exact (l.mem_withDual_iff_exists).mpr ⟨k, hj⟩
| Sum.inr k =>
simp_all
@[simp]
lemma append_inl_mem_withUniqueDual_iff (i : Fin l.length) :
appendEquiv (Sum.inl i) ∈ (l ++ l2).withUniqueDual ↔
((i ∈ l.withUniqueDual ∧ i ∉ l.withDualInOther l2) ↔ ¬ i ∈ l.withUniqueDualInOther l2) := by
apply Iff.intro
· intro h
apply Iff.intro
· intro hs
exact (l.withUniqueDual_iff_not_withUniqueDualInOther_of_inl_withUniqueDualInOther l2 i
h).mp hs.1
· intro ho
have hs := ((l.withUniqueDual_iff_not_withUniqueDualInOther_of_inl_withUniqueDualInOther l2 i
h).mpr ho)
apply And.intro hs
refine (l.append_inl_not_mem_withDual_of_withDualInOther l2 i h).mp ?_
exact (l.mem_withDual_of_withUniqueDual ⟨i, hs⟩)
· intro h
by_cases ho : i ∈ l.withUniqueDualInOther l2
· exact append_inl_mem_of_withUniqueDualInOther l l2 i ho
· exact append_inl_mem_withUniqueDual_of_withUniqueDual l l2 i (h.mpr ho).1 (h.mpr ho).2
@[simp]
lemma append_inr_mem_withUniqueDual_iff (i : Fin l2.length) :
appendEquiv (Sum.inr i) ∈ (l ++ l2).withUniqueDual ↔
((i ∈ l2.withUniqueDual ∧ i ∉ l2.withDualInOther l) ↔ ¬ i ∈ l2.withUniqueDualInOther l) := by
rw [← mem_withUniqueDual_append_symm]
exact append_inl_mem_withUniqueDual_iff l2 l i
lemma append_withUniqueDual : (l ++ l2).withUniqueDual =
Finset.map (l.appendInl l2)
((l.withUniqueDual ∩ (l.withDualInOther l2)ᶜ) l.withUniqueDualInOther l2)
Finset.map (l.appendInr l2)
((l2.withUniqueDual ∩ (l2.withDualInOther l)ᶜ) l2.withUniqueDualInOther l) := by
rw [Finset.ext_iff]
intro j
obtain ⟨k, hk⟩ := appendEquiv.surjective j
subst hk
match k with
| Sum.inl k =>
simp only [append_inl_mem_withUniqueDual_iff, Finset.mem_union]
apply Iff.intro
· intro h
apply Or.inl
simp only [Finset.mem_map, Finset.mem_union, Finset.mem_inter, Finset.mem_compl,
mem_withInDualOther_iff_isSome, Bool.not_eq_true, Option.not_isSome,
Option.isNone_iff_eq_none]
use k
simp only [appendInl, Function.Embedding.coeFn_mk, Function.comp_apply, and_true]
by_cases hk : k ∈ l.withUniqueDualInOther l2
exact Or.inr hk
have hk' := h.mpr hk
simp_all only [not_false_eq_true, and_self, mem_withInDualOther_iff_isSome, Bool.not_eq_true,
Option.not_isSome, Option.isNone_iff_eq_none, or_false]
· intro h
simp only [Finset.mem_map, Finset.mem_union, Finset.mem_inter, Finset.mem_compl,
mem_withInDualOther_iff_isSome, Bool.not_eq_true, Option.not_isSome,
Option.isNone_iff_eq_none] at h
cases' h with h h
· obtain ⟨j, hj⟩ := h
have hjk : j = k := by
simp only [appendInl, Function.Embedding.coeFn_mk, Function.comp_apply,
EmbeddingLike.apply_eq_iff_eq, Sum.inl.injEq] at hj
exact hj.2
subst hjk
have hj1 := hj.1
cases' hj1 with hj1 hj1
· simp_all only [and_self, true_or, true_and, mem_withInDualOther_iff_isSome,
Option.isSome_none, Bool.false_eq_true, not_false_eq_true, true_iff]
by_contra hn
have h' := l.mem_withDualInOther_of_withUniqueDualInOther l2 ⟨j, hn⟩
simp_all only [mem_withInDualOther_iff_isSome, Option.isSome_none, Bool.false_eq_true]
· simp_all only [or_true, true_and, mem_withInDualOther_iff_isSome,
mem_withUniqueDualInOther_isSome, not_true_eq_false, and_false]
· obtain ⟨j, hj⟩ := h
simp only [appendInr, Function.Embedding.coeFn_mk, Function.comp_apply,
EmbeddingLike.apply_eq_iff_eq, and_false] at hj
| Sum.inr k =>
simp only [append_inr_mem_withUniqueDual_iff, Finset.mem_union]
apply Iff.intro
· intro h
apply Or.inr
simp only [Finset.mem_map, Finset.mem_union, Finset.mem_inter, Finset.mem_compl,
mem_withInDualOther_iff_isSome, Bool.not_eq_true, Option.not_isSome,
Option.isNone_iff_eq_none]
use k
simp [appendInr]
by_cases hk : k ∈ l2.withUniqueDualInOther l
exact Or.inr hk
have hk' := h.mpr hk
simp_all only [not_false_eq_true, and_self, mem_withInDualOther_iff_isSome, Bool.not_eq_true,
Option.not_isSome, Option.isNone_iff_eq_none, or_false]
· intro h
simp only [Finset.mem_map, Finset.mem_union, Finset.mem_inter, Finset.mem_compl,
mem_withInDualOther_iff_isSome, Bool.not_eq_true, Option.not_isSome,
Option.isNone_iff_eq_none] at h
cases' h with h h
· obtain ⟨j, hj⟩ := h
simp only [appendInl, Function.Embedding.coeFn_mk, Function.comp_apply,
EmbeddingLike.apply_eq_iff_eq, and_false] at hj
· obtain ⟨j, hj⟩ := h
have hjk : j = k := by
simp only [appendInr, Function.Embedding.coeFn_mk, Function.comp_apply,
EmbeddingLike.apply_eq_iff_eq, Sum.inr.injEq] at hj
exact hj.2
subst hjk
have hj1 := hj.1
cases' hj1 with hj1 hj1
· simp_all only [and_self, true_or, true_and, mem_withInDualOther_iff_isSome,
Option.isSome_none, Bool.false_eq_true, not_false_eq_true, true_iff]
by_contra hn
have h' := l2.mem_withDualInOther_of_withUniqueDualInOther l ⟨j, hn⟩
simp_all only [mem_withInDualOther_iff_isSome, Option.isSome_none, Bool.false_eq_true]
· simp_all only [or_true, true_and, mem_withInDualOther_iff_isSome,
mem_withUniqueDualInOther_isSome, not_true_eq_false, and_false]
lemma append_withUniqueDual_disjSum : (l ++ l2).withUniqueDual =
Equiv.finsetCongr appendEquiv
(((l.withUniqueDual ∩ (l.withDualInOther l2)ᶜ) l.withUniqueDualInOther l2).disjSum
((l2.withUniqueDual ∩ (l2.withDualInOther l)ᶜ) l2.withUniqueDualInOther l)) := by
rw [← Equiv.symm_apply_eq]
simp only [Equiv.finsetCongr_symm, append_withUniqueDual, Equiv.finsetCongr_apply]
rw [Finset.map_union]
rw [Finset.map_map, Finset.map_map]
ext1 a
cases a with
| inl val => simp
| inr val_1 => simp
/-!
## Properties of getDualInOther?, withUniqueDualInOther and appendInOther
-/
lemma mem_append_withUniqueDualInOther_symm (i : Fin l.length) :
appendEquiv (Sum.inl i) ∈ (l ++ l2).withUniqueDualInOther l3 ↔
appendEquiv (Sum.inr i) ∈ (l2 ++ l).withUniqueDualInOther l3 := by
simp only [withUniqueDualInOther, mem_withDual_iff_isSome, Bool.not_eq_true, Option.not_isSome,
Option.isNone_iff_eq_none, mem_withInDualOther_iff_isSome, Finset.mem_filter, Finset.mem_univ,
getDual?_eq_none_append_inl_iff, getDualInOther?_append_of_inl, AreDualInOther.append_of_inl,
true_and, getDual?_eq_none_append_inr_iff, getDualInOther?_append_of_inr,
AreDualInOther.append_of_inr]
@[simp]
lemma withUniqueDualInOther_append_not_isSome_snd_of_isSome_fst (i : Fin l.length)
(h1 : i ∈ l.withUniqueDualInOther (l2 ++ l3)) (h2 : (l.getDualInOther? l2 i).isSome) :
(l.getDualInOther? l3 i) = none := by
by_contra hn
simp only [getDualInOther?] at h2 hn
rw [← @Option.not_isSome_iff_eq_none, not_not] at hn
rw [Fin.isSome_find_iff] at h2 hn
obtain ⟨j2, hj2⟩ := h2
obtain ⟨j3, hj3⟩ := hn
have h1' : l.AreDualInOther (l2 ++ l3) i (appendEquiv (Sum.inl j2)) :=
(AreDualInOther.of_append_inl i j2).mpr hj2
have h2 : l.AreDualInOther (l2 ++ l3) i (appendEquiv (Sum.inr j3)) :=
(AreDualInOther.of_append_inr i j3).mpr hj3
have h3 := l.eq_of_areDualInOther_withUniqueDualInOther (l2 ++ l3) ⟨i, h1⟩ h1' h2
simp only [EmbeddingLike.apply_eq_iff_eq] at h3
@[simp]
lemma withUniqueDualInOther_append_not_isSome_fst_of_isSome_snd (i : Fin l.length)
(h1 : i ∈ l.withUniqueDualInOther (l2 ++ l3)) (h2 : (l.getDualInOther? l3 i).isSome) :
(l.getDualInOther? l2 i) = none := by
by_contra hn
simp only [getDualInOther?] at h2 hn
rw [← @Option.not_isSome_iff_eq_none, not_not] at hn
rw [Fin.isSome_find_iff] at h2 hn
obtain ⟨j2, hj2⟩ := h2
obtain ⟨j3, hj3⟩ := hn
have h1' : l.AreDualInOther (l2 ++ l3) i (appendEquiv (Sum.inr j2)) :=
(AreDualInOther.of_append_inr i j2).mpr hj2
have h2 : l.AreDualInOther (l2 ++ l3) i (appendEquiv (Sum.inl j3)) :=
(AreDualInOther.of_append_inl i j3).mpr hj3
have h3 := l.eq_of_areDualInOther_withUniqueDualInOther (l2 ++ l3) ⟨i, h1⟩ h1' h2
simp only [EmbeddingLike.apply_eq_iff_eq] at h3
@[simp]
lemma withUniqueDualInOther_append_isSome_snd_of_not_isSome_fst (i : Fin l.length)
(h1 : i ∈ l.withUniqueDualInOther (l2 ++ l3)) (h2 : ¬ (l.getDualInOther? l2 i).isSome) :
(l.getDualInOther? l3 i).isSome := by
by_contra hn
simp only [withUniqueDualInOther, mem_withDual_iff_isSome, Bool.not_eq_true, Option.not_isSome,
Option.isNone_iff_eq_none, mem_withInDualOther_iff_isSome, getDualInOther?_isSome_of_append_iff,
Finset.mem_filter, Finset.mem_univ, true_and] at h1
simp_all only [Bool.not_eq_true, Option.not_isSome, Option.isNone_iff_eq_none, Option.isSome_none,
Bool.false_eq_true, or_self, false_and, and_false]
lemma withUniqueDualInOther_append_isSome_fst_iff_not_isSome_snd (i : Fin l.length)
(h1 : i ∈ l.withUniqueDualInOther (l2 ++ l3)) :
(l.getDualInOther? l2 i).isSome ↔ (l.getDualInOther? l3 i) = none := by
by_cases hs : (l.getDualInOther? l2 i).isSome
simp [hs, h1]
exact l.withUniqueDualInOther_append_not_isSome_snd_of_isSome_fst l2 l3 i h1 hs
simp [hs]
rw [← @Option.not_isSome_iff_eq_none, not_not]
exact withUniqueDualInOther_append_isSome_snd_of_not_isSome_fst l l2 l3 i h1 hs
lemma getDualInOther?_append_symm_of_withUniqueDual_of_inl (i : Fin l.length)
(k : Fin l2.length) (h : i ∈ l.withUniqueDualInOther (l2 ++ l3)) :
l.getDualInOther? (l2 ++ l3) i = some (appendEquiv (Sum.inl k))
↔ l.getDualInOther? (l3 ++ l2) i = some (appendEquiv (Sum.inr k)) := by
have h := l.withUniqueDualInOther_append_isSome_fst_iff_not_isSome_snd l2 l3 i h
by_cases hs : (l.getDualInOther? l2 i).isSome
<;> by_cases ho : (l.getDualInOther? l3 i).isSome
<;> simp_all [hs]
lemma getDualInOther?_append_symm_of_withUniqueDual_of_inr (i : Fin l.length)
(k : Fin l3.length) (h : i ∈ l.withUniqueDualInOther (l2 ++ l3)) :
l.getDualInOther? (l2 ++ l3) i = some (appendEquiv (Sum.inr k))
↔ l.getDualInOther? (l3 ++ l2) i = some (appendEquiv (Sum.inl k)) := by
have h := l.withUniqueDualInOther_append_isSome_fst_iff_not_isSome_snd l2 l3 i h
by_cases hs : (l.getDualInOther? l2 i).isSome
<;> by_cases ho : (l.getDualInOther? l3 i).isSome
<;> simp_all [hs]
lemma mem_withUniqueDualInOther_symm' (i : Fin l.length)
(h : i ∈ l.withUniqueDualInOther (l2 ++ l3)):
i ∈ l.withUniqueDualInOther (l3 ++ l2) := by
have h' := h
simp only [withUniqueDualInOther, mem_withDual_iff_isSome, Bool.not_eq_true,
Option.not_isSome, Option.isNone_iff_eq_none, mem_withInDualOther_iff_isSome,
getDualInOther?_isSome_of_append_iff, Finset.mem_filter, Finset.mem_univ, true_and,
implies_true, and_self, eq_getDualInOther?_get_of_withUniqueDualInOther_iff,
getDualInOther?_areDualInOther_get] at h ⊢
apply And.intro h.1
have hc := l.withUniqueDualInOther_append_isSome_fst_iff_not_isSome_snd l2 l3 i h'
by_cases h1 : (l.getDualInOther? l2 i).isSome <;>
by_cases h2 : (l.getDualInOther? l3 i).isSome
· simp only [h1, h2, not_true_eq_false, imp_false] at hc
rw [← @Option.not_isSome_iff_eq_none] at hc
simp [h2] at hc
· simp only [h1, or_true, true_and]
intro j
obtain ⟨k, hk⟩ := appendEquiv.surjective j
subst hk
match k with
| Sum.inl k =>
simp only [AreDualInOther.of_append_inl]
have hk'' := h.2.2 (appendEquiv (Sum.inr k))
simp at hk''
exact fun h'' => ((getDualInOther?_append_symm_of_withUniqueDual_of_inr l l2 l3 i k h').mp
(hk'' h'').symm).symm
| Sum.inr k =>
simp only [AreDualInOther.of_append_inr]
have hk'' := h.2.2 (appendEquiv (Sum.inl k))
simp at hk''
exact fun h'' => ((getDualInOther?_append_symm_of_withUniqueDual_of_inl l l2 l3 i k h').mp
(hk'' h'').symm).symm
· simp only [h2, true_or, Option.some.injEq, true_and]
intro j
obtain ⟨k, hk⟩ := appendEquiv.surjective j
subst hk
match k with
| Sum.inl k =>
simp only [AreDualInOther.of_append_inl]
have hk'' := h.2.2 (appendEquiv (Sum.inr k))
simp at hk''
exact fun h'' => ((getDualInOther?_append_symm_of_withUniqueDual_of_inr l l2 l3 i k h').mp
(hk'' h'').symm).symm
| Sum.inr k =>
simp only [AreDualInOther.of_append_inr]
have hk'' := h.2.2 (appendEquiv (Sum.inl k))
simp only [AreDualInOther.of_append_inl] at hk''
exact fun h'' => ((getDualInOther?_append_symm_of_withUniqueDual_of_inl l l2 l3 i k h').mp
(hk'' h'').symm).symm
· simp only [h1, Bool.false_eq_true, false_iff] at hc
simp_all only [Bool.false_eq_true, or_self, eq_getDualInOther?_get_of_withUniqueDualInOther_iff,
Option.some_get, implies_true, and_true, and_false]
lemma mem_withUniqueDualInOther_symm (i : Fin l.length) :
i ∈ l.withUniqueDualInOther (l2 ++ l3) ↔ i ∈ l.withUniqueDualInOther (l3 ++ l2) :=
Iff.intro (l.mem_withUniqueDualInOther_symm' l2 l3 i) (l.mem_withUniqueDualInOther_symm' l3 l2 i)
/-!
## The equivalence defined by getDual?
-/
/-- An equivalence from `l.withUniqueDual` to itself obtained by taking the dual index. -/
def getDualEquiv : l.withUniqueDual ≃ l.withUniqueDual where
toFun x := ⟨(l.getDual? x).get (l.mem_withUniqueDual_isSome x.1 x.2), by
simp only [Finset.coe_mem, getDual?_get_of_mem_withUnique_mem]⟩
invFun x := ⟨(l.getDual? x).get (l.mem_withUniqueDual_isSome x.1 x.2), by simp⟩
left_inv x := SetCoe.ext (by
simp only [Finset.coe_mem, getDual?_getDual?_get_of_withUniqueDual, Option.get_some])
right_inv x := SetCoe.ext (by
simp only [Finset.coe_mem, getDual?_getDual?_get_of_withUniqueDual, Option.get_some])
@[simp]
lemma getDualEquiv_involutive : Function.Involutive l.getDualEquiv := by
intro x
exact (Equiv.apply_eq_iff_eq_symm_apply l.getDualEquiv).mpr rfl
/-!
## Equivalence for withUniqueDualInOther
-/
/-- An equivalence from `l.withUniqueDualInOther l2` to `l2.withUniqueDualInOther l`
obtained by taking the dual index. -/
def getDualInOtherEquiv : l.withUniqueDualInOther l2 ≃ l2.withUniqueDualInOther l where
toFun x := ⟨(l.getDualInOther? l2 x).get (l.mem_withUniqueDualInOther_isSome l2 x.1 x.2),
by simp⟩
invFun x := ⟨(l2.getDualInOther? l x).get (l2.mem_withUniqueDualInOther_isSome l x.1 x.2),
by simp⟩
left_inv x := SetCoe.ext (by simp)
right_inv x := SetCoe.ext (by simp)
@[simp]
lemma getDualInOtherEquiv_self_refl : l.getDualInOtherEquiv l = Equiv.refl _ := by
apply Equiv.ext
intro x
simp [getDualInOtherEquiv]
end IndexList
end IndexNotation
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