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import Mathlib.GroupTheory.Subgroup.Basic
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import Mathlib.GroupTheory.GroupAction.Basic
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import Mathlib.Topology.Basic
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import Mathlib.Topology.Homeomorph
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import Mathlib.Topology.Algebra.ConstMulAction
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import Mathlib.Data.Set.Basic
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import Rubin.MulActionExt
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namespace Rubin
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-- TODO: give this a notation?
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-- TODO: coe to / extend MulActionHom
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structure EquivariantHomeomorph (G α β : Type _) [Group G] [TopologicalSpace α]
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[TopologicalSpace β] [MulAction G α] [MulAction G β] extends Homeomorph α β where
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equivariant : is_equivariant G toFun
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#align equivariant_homeomorph Rubin.EquivariantHomeomorph
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variable {G α β : Type _}
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variable [Group G]
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variable [TopologicalSpace α] [TopologicalSpace β]
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theorem equivariant_fun [MulAction G α] [MulAction G β]
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(h : EquivariantHomeomorph G α β) :
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is_equivariant G h.toFun :=
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h.equivariant
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#align equivariant_fun Rubin.equivariant_fun
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theorem equivariant_inv [MulAction G α] [MulAction G β]
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(h : EquivariantHomeomorph G α β) :
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is_equivariant G h.invFun :=
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by
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intro g x
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symm
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let e := congr_arg h.invFun (h.equivariant g (h.invFun x))
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rw [h.left_inv _, h.right_inv _] at e
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exact e
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#align equivariant_inv Rubin.equivariant_inv
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open Topology
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-- Note: this sounds like a general enough theorem that it should already be in mathlib
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lemma inter_of_open_subset_of_closure {α : Type _} [TopologicalSpace α] {U V : Set α}
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(U_open : IsOpen U) (U_nonempty : Set.Nonempty U) (V_nonempty : Set.Nonempty V)
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(U_ss_clV : U ⊆ closure V) : Set.Nonempty (U ∩ V) :=
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by
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by_contra empty
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rw [Set.not_nonempty_iff_eq_empty] at empty
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rw [Set.nonempty_iff_ne_empty] at U_nonempty
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apply U_nonempty
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have clV_diff_U_ss_V : V ⊆ closure V \ U := by
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rw [Set.subset_diff]
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constructor
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exact subset_closure
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symm
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rw [Set.disjoint_iff_inter_eq_empty]
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exact empty
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have clV_diff_U_closed : IsClosed (closure V \ U) := by
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apply IsClosed.sdiff
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exact isClosed_closure
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assumption
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unfold closure at U_ss_clV
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simp at U_ss_clV
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specialize U_ss_clV (closure V \ U) clV_diff_U_closed clV_diff_U_ss_V
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rw [Set.subset_diff] at U_ss_clV
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rw [Set.disjoint_iff_inter_eq_empty] at U_ss_clV
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simp at U_ss_clV
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exact U_ss_clV.right
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/--
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Note: `𝓝[≠] x` is notation for `nhdsWithin x {[x]}ᶜ`, ie. the neighborhood of x not containing itself.
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--/
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class HasNoIsolatedPoints (α : Type _) [TopologicalSpace α] :=
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-- TODO: rename to nhdsWithin_ne_bot
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nhbd_ne_bot : ∀ x : α, 𝓝[≠] x ≠ ⊥
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#align has_no_isolated_points Rubin.HasNoIsolatedPoints
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instance has_no_isolated_points_neBot₁ {α : Type _} [TopologicalSpace α] [h_nip: HasNoIsolatedPoints α]
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(x: α) : Filter.NeBot (𝓝[≠] x) where
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ne' := h_nip.nhbd_ne_bot x
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theorem Filter.NeBot.choose {α : Type _} (F : Filter α) [Filter.NeBot F] :
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∃ S : Set α, S ∈ F :=
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by
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have res := (Filter.inhabitedMem (α := α) (f := F)).default
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exact ⟨res.val, res.prop⟩
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theorem TopologicalSpace.IsTopologicalBasis.contains_point {α : Type _} [TopologicalSpace α]
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{B : Set (Set α)} (B_basis : TopologicalSpace.IsTopologicalBasis B) (p : α) :
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∃ S : Set α, S ∈ B ∧ p ∈ S :=
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by
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have nhds_basis := B_basis.nhds_hasBasis (a := p)
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rw [Filter.hasBasis_iff] at nhds_basis
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let ⟨S₁, S₁_in_nhds⟩ := Filter.NeBot.choose (𝓝 p)
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let ⟨S, ⟨⟨S_in_B, p_in_S⟩, _⟩⟩ := (nhds_basis S₁).mp S₁_in_nhds
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exact ⟨S, S_in_B, p_in_S⟩
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-- The collection of all the sets in `B` (a topological basis of `α`), such that `p` is in them.
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def TopologicalBasisContaining {α : Type _} [TopologicalSpace α]
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{B : Set (Set α)} (B_basis : TopologicalSpace.IsTopologicalBasis B) (p : α) : FilterBasis α
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where
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sets := {b ∈ B | p ∈ b}
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nonempty := by
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let ⟨S, S_in_B, p_in_S⟩ := TopologicalSpace.IsTopologicalBasis.contains_point B_basis p
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use S
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simp
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tauto
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inter_sets := by
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intro S T ⟨S_in_B, p_in_S⟩ ⟨T_in_B, p_in_T⟩
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have S_in_nhds := B_basis.mem_nhds_iff.mpr ⟨S, S_in_B, ⟨p_in_S, Eq.subset rfl⟩⟩
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have T_in_nhds := B_basis.mem_nhds_iff.mpr ⟨T, T_in_B, ⟨p_in_T, Eq.subset rfl⟩⟩
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have ST_in_nhds : S ∩ T ∈ 𝓝 p := Filter.inter_mem S_in_nhds T_in_nhds
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rw [B_basis.mem_nhds_iff] at ST_in_nhds
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let ⟨U, props⟩ := ST_in_nhds
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use U
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simp
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simp at props
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tauto
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theorem TopologicalBasisContaining.mem_iff {α : Type _} [TopologicalSpace α]
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{B : Set (Set α)} (B_basis : TopologicalSpace.IsTopologicalBasis B) (p : α) (S : Set α) :
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S ∈ TopologicalBasisContaining B_basis p ↔ S ∈ B ∧ p ∈ S :=
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by
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rw [<-FilterBasis.mem_sets]
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rfl
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theorem TopologicalBasisContaining.mem_nhds {α : Type _} [TopologicalSpace α]
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{B : Set (Set α)} (B_basis : TopologicalSpace.IsTopologicalBasis B) (p : α) (S : Set α) :
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S ∈ TopologicalBasisContaining B_basis p → S ∈ 𝓝 p :=
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by
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rw [TopologicalBasisContaining.mem_iff]
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rw [B_basis.mem_nhds_iff]
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intro ⟨S_in_B, p_in_S⟩
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use S
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instance TopologicalBasisContaining.neBot {α : Type _} [TopologicalSpace α]
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{B : Set (Set α)} (B_basis : TopologicalSpace.IsTopologicalBasis B) (p : α) :
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Filter.NeBot (TopologicalBasisContaining B_basis p).filter where
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ne' := by
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intro empty_in
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rw [<-Filter.empty_mem_iff_bot, FilterBasis.mem_filter_iff] at empty_in
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let ⟨S, ⟨S_in_basis, S_ss_empty⟩⟩ := empty_in
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rw [TopologicalBasisContaining.mem_iff] at S_in_basis
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exact S_ss_empty S_in_basis.right
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-- Note: the definition of "convergence" in the article doesn't quite match with the definition of ClusterPt
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-- Instead, `F ≤ nhds p` should be used.
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-- Note: Filter.HasBasis is a stronger statement than just FilterBasis - it defines a two-way relationship between a filter and a property; if the property is true for a set, then any superset of it is part of the filter, and vice-versa.
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-- With this, it's impossible for there to be a finer filter satisfying the property,
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-- as is evidenced by `filter_eq`: stripping away the `Filter` allows us to uniquely reconstruct it from the property itself.
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-- Proposition 3.3.1 trivially follows from `TopologicalSpace.IsTopologicalBasis.nhds_hasBasis` and `disjoint_nhds_nhds`: if `F.HasBasis (S → S ∈ B ∧ p ∈ S)` and `F.HasBasis (S → S ∈ B ∧ q ∈ S)`,
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-- then one can prove that `F ≤ nhds x` and `F ≤ nhds y` ~> `F = ⊥`
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-- Proposition 3.3.2 becomes simply `TopologicalSpace.IsTopologicalBasis.nhds_hasBasis`
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-- Proposition 3.3.3 is a consequence of the structure of `HasBasis`
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-- Proposition 3.4.1 can maybe be proven with `TopologicalSpace.IsTopologicalBasis.mem_closure_iff`?
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-- The tricky part here though is that "F is an ultra(pre)filter on B" can't easily be expressed.
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-- I should maybe define a Prop for it, and show that "F is an ultrafilter on B" + "F tends to a point p"
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-- is equivalent to `TopologicalSpace.IsTopologicalBasis.nhds_hasBasis`.
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-- The alternative is to only work with `Filter`, and state conditions with `Filter.HasBasis`,
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-- since that will force the filter to be an ultraprefilter on B.
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end Rubin
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