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/- Copyright (c) 2022 Apurva Nakade. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Apurva Nakade -/ import Mathlib.Analysis.Convex.Cone.Closure import Mathlib.Analysis.InnerProductSpace.Adjoint /-! # Proper cones We define a proper cone as a closed, pointed cone. Proper cones are used in defining conic programs which generalize linear programs. A linear program is a conic program for the positive cone. We then prove Farkas' lemma for conic programs following the proof in the reference below. Farkas' lemma is equivalent to strong duality. So, once we have the definitions of conic and linear programs, the results from this file can be used to prove duality theorems. ## TODO The next steps are: - Add convex_cone_class that extends set_like and replace the below instance - Define primal and dual cone programs and prove weak duality. - Prove regular and strong duality for cone programs using Farkas' lemma (see reference). - Define linear programs and prove LP duality as a special case of cone duality. - Find a better reference (textbook instead of lecture notes). ## References - [B. Gartner and J. Matousek, Cone Programming][gartnerMatousek] -/ open ContinuousLinearMap Filter Set /-- A proper cone is a pointed cone `K` that is closed. Proper cones have the nice property that they are equal to their double dual, see `ProperCone.dual_dual`. This makes them useful for defining cone programs and proving duality theorems. -/ structure ProperCone (𝕜 : Type) (E : Type) [Semiring 𝕜] [PartialOrder 𝕜] [IsOrderedRing 𝕜] [AddCommMonoid E] [TopologicalSpace E] [Module 𝕜 E] extends Submodule {c : 𝕜 // 0 ≤ c} E where isClosed' : IsClosed (carrier : Set E) namespace ProperCone section Module variable {𝕜 : Type} [Semiring 𝕜] [PartialOrder 𝕜] [IsOrderedRing 𝕜] variable {E : Type} [AddCommMonoid E] [TopologicalSpace E] [Module 𝕜 E] /-- A `PointedCone` is defined as an alias of submodule. We replicate the abbreviation here and define `toPointedCone` as an alias of `toSubmodule`. -/ abbrev toPointedCone (C : ProperCone 𝕜 E) := C.toSubmodule attribute [coe] toPointedCone instance : Coe (ProperCone 𝕜 E) (PointedCone 𝕜 E) := ⟨toPointedCone⟩ theorem toPointedCone_injective : Function.Injective ((↑) : ProperCone 𝕜 E → PointedCone 𝕜 E) := fun S T h => by cases S; cases T; congr -- TODO: add `ConvexConeClass` that extends `SetLike` and replace the below instance instance : SetLike (ProperCone 𝕜 E) E where coe K := K.carrier coe_injective' _ _ h := ProperCone.toPointedCone_injective (SetLike.coe_injective h) @[ext] theorem ext {S T : ProperCone 𝕜 E} (h : ∀ x, x ∈ S ↔ x ∈ T) : S = T := SetLike.ext h @[simp] theorem mem_coe {x : E} {K : ProperCone 𝕜 E} : x ∈ (K : PointedCone 𝕜 E) ↔ x ∈ K := Iff.rfl instance instZero (K : ProperCone 𝕜 E) : Zero K := PointedCone.instZero (K.toSubmodule) protected theorem nonempty (K : ProperCone 𝕜 E) : (K : Set E).Nonempty := ⟨0, by { simp_rw [SetLike.mem_coe, ← ProperCone.mem_coe, Submodule.zero_mem] }⟩ protected theorem isClosed (K : ProperCone 𝕜 E) : IsClosed (K : Set E) := K.isClosed' end Module section PositiveCone variable (𝕜 E) variable [Semiring 𝕜] [PartialOrder 𝕜] [IsOrderedRing 𝕜] [AddCommGroup E] [PartialOrder E] [IsOrderedAddMonoid E] [Module 𝕜 E] [OrderedSMul 𝕜 E] [TopologicalSpace E] [OrderClosedTopology E] /-- The positive cone is the proper cone formed by the set of nonnegative elements in an ordered module. -/ def positive : ProperCone 𝕜 E where toSubmodule := PointedCone.positive 𝕜 E isClosed' := isClosed_Ici @[simp] theorem mem_positive {x : E} : x ∈ positive 𝕜 E ↔ 0 ≤ x := Iff.rfl @[simp] theorem coe_positive : ↑(positive 𝕜 E) = ConvexCone.positive 𝕜 E := rfl end PositiveCone section Module variable {𝕜 : Type} [Semiring 𝕜] [PartialOrder 𝕜] [IsOrderedRing 𝕜] variable {E : Type} [AddCommMonoid E] [TopologicalSpace E] [T1Space E] [Module 𝕜 E] instance : Zero (ProperCone 𝕜 E) := ⟨{ toSubmodule := 0 isClosed' := isClosed_singleton }⟩ instance : Inhabited (ProperCone 𝕜 E) := ⟨0⟩ @[simp] theorem mem_zero (x : E) : x ∈ (0 : ProperCone 𝕜 E) ↔ x = 0 := Iff.rfl @[simp, norm_cast] theorem coe_zero : ↑(0 : ProperCone 𝕜 E) = (0 : ConvexCone 𝕜 E) := rfl theorem pointed_zero : ((0 : ProperCone 𝕜 E) : ConvexCone 𝕜 E).Pointed := by simp [ConvexCone.pointed_zero] end Module section InnerProductSpace variable {E : Type} [NormedAddCommGroup E] [InnerProductSpace ℝ E] variable {F : Type} [NormedAddCommGroup F] [InnerProductSpace ℝ F] variable {G : Type*} [NormedAddCommGroup G] [InnerProductSpace ℝ G] protected theorem pointed (K : ProperCone ℝ E) : (K : ConvexCone ℝ E).Pointed := (K : ConvexCone ℝ E).pointed_of_nonempty_of_isClosed K.nonempty K.isClosed /-- The closure of image of a proper cone under a continuous `ℝ`-linear map is a proper cone. We use continuous maps here so that the comap of f is also a map between proper cones. -/ noncomputable def map (f : E →L[ℝ] F) (K : ProperCone ℝ E) : ProperCone ℝ F where toSubmodule := PointedCone.closure (PointedCone.map (f : E →ₗ[ℝ] F) ↑K) isClosed' := isClosed_closure @[simp, norm_cast] theorem coe_map (f : E →L[ℝ] F) (K : ProperCone ℝ E) : ↑(K.map f) = (PointedCone.map (f : E →ₗ[ℝ] F) ↑K).closure := rfl @[simp] theorem mem_map {f : E →L[ℝ] F} {K : ProperCone ℝ E} {y : F} : y ∈ K.map f ↔ y ∈ (PointedCone.map (f : E →ₗ[ℝ] F) ↑K).closure := Iff.rfl @[simp] theorem map_id (K : ProperCone ℝ E) : K.map (ContinuousLinearMap.id ℝ E) = K := ProperCone.toPointedCone_injective <\| by simpa using IsClosed.closure_eq K.isClosed /-- The inner dual cone of a proper cone is a proper cone. -/ def dual (K : ProperCone ℝ E) : ProperCone ℝ E where toSubmodule := PointedCone.dual (K : PointedCone ℝ E) isClosed' := isClosed_innerDualCone _ @[simp, norm_cast] theorem coe_dual (K : ProperCone ℝ E) : K.dual = (K : Set E).innerDualCone := rfl open scoped InnerProductSpace in @[simp] theorem mem_dual {K : ProperCone ℝ E} {y : E} : y ∈ dual K ↔ ∀ ⦃x⦄, x ∈ K → 0 ≤ ⟪x, y⟫_ℝ := by aesop /-- The preimage of a proper cone under a continuous `ℝ`-linear map is a proper cone. -/ noncomputable def comap (f : E →L[ℝ] F) (S : ProperCone ℝ F) : ProperCone ℝ E where toSubmodule := PointedCone.comap (f : E →ₗ[ℝ] F) S isClosed' := by rw [PointedCone.comap] apply IsClosed.preimage f.2 S.isClosed @[simp] theorem coe_comap (f : E →L[ℝ] F) (S : ProperCone ℝ F) : (S.comap f : Set E) = f ⁻¹' S := rfl @[simp] theorem comap_id (S : ConvexCone ℝ E) : S.comap LinearMap.id = S := SetLike.coe_injective preimage_id theorem comap_comap (g : F →L[ℝ] G) (f : E →L[ℝ] F) (S : ProperCone ℝ G) : (S.comap g).comap f = S.comap (g.comp f) := SetLike.coe_injective <\| by congr	@[simp]	Mathlib/Analysis/Convex/Cone/Proper.lean	193	194
/- Copyright (c) 2022 Joseph Myers. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Joseph Myers -/ import Mathlib.Analysis.Convex.Side import Mathlib.Geometry.Euclidean.Angle.Oriented.Rotation import Mathlib.Geometry.Euclidean.Angle.Unoriented.Affine /-! # Oriented angles. This file defines oriented angles in Euclidean affine spaces. ## Main definitions * `EuclideanGeometry.oangle`, with notation `∡`, is the oriented angle determined by three points. -/ noncomputable section open Module Complex open scoped Affine EuclideanGeometry Real RealInnerProductSpace ComplexConjugate namespace EuclideanGeometry variable {V : Type} {P : Type} [NormedAddCommGroup V] [InnerProductSpace ℝ V] [MetricSpace P] [NormedAddTorsor V P] [hd2 : Fact (finrank ℝ V = 2)] [Module.Oriented ℝ V (Fin 2)] /-- A fixed choice of positive orientation of Euclidean space `ℝ²` -/ abbrev o := @Module.Oriented.positiveOrientation /-- The oriented angle at `p₂` between the line segments to `p₁` and `p₃`, modulo `2 * π`. If either of those points equals `p₂`, this is 0. See `EuclideanGeometry.angle` for the corresponding unoriented angle definition. -/ def oangle (p₁ p₂ p₃ : P) : Real.Angle := o.oangle (p₁ -ᵥ p₂) (p₃ -ᵥ p₂) @[inherit_doc] scoped notation "∡" => EuclideanGeometry.oangle /-- Oriented angles are continuous when neither end point equals the middle point. -/ theorem continuousAt_oangle {x : P × P × P} (hx12 : x.1 ≠ x.2.1) (hx32 : x.2.2 ≠ x.2.1) : ContinuousAt (fun y : P × P × P => ∡ y.1 y.2.1 y.2.2) x := by unfold oangle fun_prop (disch := simp [*]) /-- The angle ∡AAB at a point. -/ @[simp] theorem oangle_self_left (p₁ p₂ : P) : ∡ p₁ p₁ p₂ = 0 := by simp [oangle] /-- The angle ∡ABB at a point. -/ @[simp] theorem oangle_self_right (p₁ p₂ : P) : ∡ p₁ p₂ p₂ = 0 := by simp [oangle] /-- The angle ∡ABA at a point. -/ @[simp] theorem oangle_self_left_right (p₁ p₂ : P) : ∡ p₁ p₂ p₁ = 0 := o.oangle_self _ /-- If the angle between three points is nonzero, the first two points are not equal. -/ theorem left_ne_of_oangle_ne_zero {p₁ p₂ p₃ : P} (h : ∡ p₁ p₂ p₃ ≠ 0) : p₁ ≠ p₂ := by rw [← @vsub_ne_zero V]; exact o.left_ne_zero_of_oangle_ne_zero h /-- If the angle between three points is nonzero, the last two points are not equal. -/ theorem right_ne_of_oangle_ne_zero {p₁ p₂ p₃ : P} (h : ∡ p₁ p₂ p₃ ≠ 0) : p₃ ≠ p₂ := by rw [← @vsub_ne_zero V]; exact o.right_ne_zero_of_oangle_ne_zero h /-- If the angle between three points is nonzero, the first and third points are not equal. -/ theorem left_ne_right_of_oangle_ne_zero {p₁ p₂ p₃ : P} (h : ∡ p₁ p₂ p₃ ≠ 0) : p₁ ≠ p₃ := by rw [← (vsub_left_injective p₂).ne_iff]; exact o.ne_of_oangle_ne_zero h /-- If the angle between three points is `π`, the first two points are not equal. -/ theorem left_ne_of_oangle_eq_pi {p₁ p₂ p₃ : P} (h : ∡ p₁ p₂ p₃ = π) : p₁ ≠ p₂ := left_ne_of_oangle_ne_zero (h.symm ▸ Real.Angle.pi_ne_zero : ∡ p₁ p₂ p₃ ≠ 0) /-- If the angle between three points is `π`, the last two points are not equal. -/ theorem right_ne_of_oangle_eq_pi {p₁ p₂ p₃ : P} (h : ∡ p₁ p₂ p₃ = π) : p₃ ≠ p₂ := right_ne_of_oangle_ne_zero (h.symm ▸ Real.Angle.pi_ne_zero : ∡ p₁ p₂ p₃ ≠ 0) /-- If the angle between three points is `π`, the first and third points are not equal. -/ theorem left_ne_right_of_oangle_eq_pi {p₁ p₂ p₃ : P} (h : ∡ p₁ p₂ p₃ = π) : p₁ ≠ p₃ := left_ne_right_of_oangle_ne_zero (h.symm ▸ Real.Angle.pi_ne_zero : ∡ p₁ p₂ p₃ ≠ 0) /-- If the angle between three points is `π / 2`, the first two points are not equal. -/ theorem left_ne_of_oangle_eq_pi_div_two {p₁ p₂ p₃ : P} (h : ∡ p₁ p₂ p₃ = (π / 2 : ℝ)) : p₁ ≠ p₂ := left_ne_of_oangle_ne_zero (h.symm ▸ Real.Angle.pi_div_two_ne_zero : ∡ p₁ p₂ p₃ ≠ 0) /-- If the angle between three points is `π / 2`, the last two points are not equal. -/ theorem right_ne_of_oangle_eq_pi_div_two {p₁ p₂ p₃ : P} (h : ∡ p₁ p₂ p₃ = (π / 2 : ℝ)) : p₃ ≠ p₂ := right_ne_of_oangle_ne_zero (h.symm ▸ Real.Angle.pi_div_two_ne_zero : ∡ p₁ p₂ p₃ ≠ 0) /-- If the angle between three points is `π / 2`, the first and third points are not equal. -/ theorem left_ne_right_of_oangle_eq_pi_div_two {p₁ p₂ p₃ : P} (h : ∡ p₁ p₂ p₃ = (π / 2 : ℝ)) : p₁ ≠ p₃ := left_ne_right_of_oangle_ne_zero (h.symm ▸ Real.Angle.pi_div_two_ne_zero : ∡ p₁ p₂ p₃ ≠ 0) /-- If the angle between three points is `-π / 2`, the first two points are not equal. -/ theorem left_ne_of_oangle_eq_neg_pi_div_two {p₁ p₂ p₃ : P} (h : ∡ p₁ p₂ p₃ = (-π / 2 : ℝ)) : p₁ ≠ p₂ := left_ne_of_oangle_ne_zero (h.symm ▸ Real.Angle.neg_pi_div_two_ne_zero : ∡ p₁ p₂ p₃ ≠ 0) /-- If the angle between three points is `-π / 2`, the last two points are not equal. -/ theorem right_ne_of_oangle_eq_neg_pi_div_two {p₁ p₂ p₃ : P} (h : ∡ p₁ p₂ p₃ = (-π / 2 : ℝ)) : p₃ ≠ p₂ := right_ne_of_oangle_ne_zero (h.symm ▸ Real.Angle.neg_pi_div_two_ne_zero : ∡ p₁ p₂ p₃ ≠ 0) /-- If the angle between three points is `-π / 2`, the first and third points are not equal. -/ theorem left_ne_right_of_oangle_eq_neg_pi_div_two {p₁ p₂ p₃ : P} (h : ∡ p₁ p₂ p₃ = (-π / 2 : ℝ)) : p₁ ≠ p₃ := left_ne_right_of_oangle_ne_zero (h.symm ▸ Real.Angle.neg_pi_div_two_ne_zero : ∡ p₁ p₂ p₃ ≠ 0) /-- If the sign of the angle between three points is nonzero, the first two points are not equal. -/ theorem left_ne_of_oangle_sign_ne_zero {p₁ p₂ p₃ : P} (h : (∡ p₁ p₂ p₃).sign ≠ 0) : p₁ ≠ p₂ := left_ne_of_oangle_ne_zero (Real.Angle.sign_ne_zero_iff.1 h).1 /-- If the sign of the angle between three points is nonzero, the last two points are not equal. -/ theorem right_ne_of_oangle_sign_ne_zero {p₁ p₂ p₃ : P} (h : (∡ p₁ p₂ p₃).sign ≠ 0) : p₃ ≠ p₂ := right_ne_of_oangle_ne_zero (Real.Angle.sign_ne_zero_iff.1 h).1 /-- If the sign of the angle between three points is nonzero, the first and third points are not equal. -/ theorem left_ne_right_of_oangle_sign_ne_zero {p₁ p₂ p₃ : P} (h : (∡ p₁ p₂ p₃).sign ≠ 0) : p₁ ≠ p₃ := left_ne_right_of_oangle_ne_zero (Real.Angle.sign_ne_zero_iff.1 h).1 /-- If the sign of the angle between three points is positive, the first two points are not equal. -/ theorem left_ne_of_oangle_sign_eq_one {p₁ p₂ p₃ : P} (h : (∡ p₁ p₂ p₃).sign = 1) : p₁ ≠ p₂ := left_ne_of_oangle_sign_ne_zero (h.symm ▸ by decide : (∡ p₁ p₂ p₃).sign ≠ 0) /-- If the sign of the angle between three points is positive, the last two points are not equal. -/ theorem right_ne_of_oangle_sign_eq_one {p₁ p₂ p₃ : P} (h : (∡ p₁ p₂ p₃).sign = 1) : p₃ ≠ p₂ := right_ne_of_oangle_sign_ne_zero (h.symm ▸ by decide : (∡ p₁ p₂ p₃).sign ≠ 0) /-- If the sign of the angle between three points is positive, the first and third points are not equal. -/ theorem left_ne_right_of_oangle_sign_eq_one {p₁ p₂ p₃ : P} (h : (∡ p₁ p₂ p₃).sign = 1) : p₁ ≠ p₃ := left_ne_right_of_oangle_sign_ne_zero (h.symm ▸ by decide : (∡ p₁ p₂ p₃).sign ≠ 0) /-- If the sign of the angle between three points is negative, the first two points are not equal. -/ theorem left_ne_of_oangle_sign_eq_neg_one {p₁ p₂ p₃ : P} (h : (∡ p₁ p₂ p₃).sign = -1) : p₁ ≠ p₂ := left_ne_of_oangle_sign_ne_zero (h.symm ▸ by decide : (∡ p₁ p₂ p₃).sign ≠ 0) /-- If the sign of the angle between three points is negative, the last two points are not equal. -/ theorem right_ne_of_oangle_sign_eq_neg_one {p₁ p₂ p₃ : P} (h : (∡ p₁ p₂ p₃).sign = -1) : p₃ ≠ p₂ := right_ne_of_oangle_sign_ne_zero (h.symm ▸ by decide : (∡ p₁ p₂ p₃).sign ≠ 0) /-- If the sign of the angle between three points is negative, the first and third points are not equal. -/ theorem left_ne_right_of_oangle_sign_eq_neg_one {p₁ p₂ p₃ : P} (h : (∡ p₁ p₂ p₃).sign = -1) : p₁ ≠ p₃ := left_ne_right_of_oangle_sign_ne_zero (h.symm ▸ by decide : (∡ p₁ p₂ p₃).sign ≠ 0) /-- Reversing the order of the points passed to `oangle` negates the angle. -/ theorem oangle_rev (p₁ p₂ p₃ : P) : ∡ p₃ p₂ p₁ = -∡ p₁ p₂ p₃ := o.oangle_rev _ _ /-- Adding an angle to that with the order of the points reversed results in 0. -/ @[simp] theorem oangle_add_oangle_rev (p₁ p₂ p₃ : P) : ∡ p₁ p₂ p₃ + ∡ p₃ p₂ p₁ = 0 := o.oangle_add_oangle_rev _ _ /-- An oriented angle is zero if and only if the angle with the order of the points reversed is zero. -/ theorem oangle_eq_zero_iff_oangle_rev_eq_zero {p₁ p₂ p₃ : P} : ∡ p₁ p₂ p₃ = 0 ↔ ∡ p₃ p₂ p₁ = 0 := o.oangle_eq_zero_iff_oangle_rev_eq_zero /-- An oriented angle is `π` if and only if the angle with the order of the points reversed is `π`. -/ theorem oangle_eq_pi_iff_oangle_rev_eq_pi {p₁ p₂ p₃ : P} : ∡ p₁ p₂ p₃ = π ↔ ∡ p₃ p₂ p₁ = π := o.oangle_eq_pi_iff_oangle_rev_eq_pi /-- An oriented angle is not zero or `π` if and only if the three points are affinely independent. -/ theorem oangle_ne_zero_and_ne_pi_iff_affineIndependent {p₁ p₂ p₃ : P} : ∡ p₁ p₂ p₃ ≠ 0 ∧ ∡ p₁ p₂ p₃ ≠ π ↔ AffineIndependent ℝ ![p₁, p₂, p₃] := by rw [oangle, o.oangle_ne_zero_and_ne_pi_iff_linearIndependent, affineIndependent_iff_linearIndependent_vsub ℝ _ (1 : Fin 3), ← linearIndependent_equiv (finSuccAboveEquiv (1 : Fin 3))] convert Iff.rfl ext i fin_cases i <;> rfl /-- An oriented angle is zero or `π` if and only if the three points are collinear. -/ theorem oangle_eq_zero_or_eq_pi_iff_collinear {p₁ p₂ p₃ : P} : ∡ p₁ p₂ p₃ = 0 ∨ ∡ p₁ p₂ p₃ = π ↔ Collinear ℝ ({p₁, p₂, p₃} : Set P) := by rw [← not_iff_not, not_or, oangle_ne_zero_and_ne_pi_iff_affineIndependent, affineIndependent_iff_not_collinear_set] /-- An oriented angle has a sign zero if and only if the three points are collinear. -/ theorem oangle_sign_eq_zero_iff_collinear {p₁ p₂ p₃ : P} : (∡ p₁ p₂ p₃).sign = 0 ↔ Collinear ℝ ({p₁, p₂, p₃} : Set P) := by rw [Real.Angle.sign_eq_zero_iff, oangle_eq_zero_or_eq_pi_iff_collinear] /-- If twice the oriented angles between two triples of points are equal, one triple is affinely independent if and only if the other is. -/ theorem affineIndependent_iff_of_two_zsmul_oangle_eq {p₁ p₂ p₃ p₄ p₅ p₆ : P} (h : (2 : ℤ) • ∡ p₁ p₂ p₃ = (2 : ℤ) • ∡ p₄ p₅ p₆) : AffineIndependent ℝ ![p₁, p₂, p₃] ↔ AffineIndependent ℝ ![p₄, p₅, p₆] := by simp_rw [← oangle_ne_zero_and_ne_pi_iff_affineIndependent, ← Real.Angle.two_zsmul_ne_zero_iff, h] /-- If twice the oriented angles between two triples of points are equal, one triple is collinear if and only if the other is. -/ theorem collinear_iff_of_two_zsmul_oangle_eq {p₁ p₂ p₃ p₄ p₅ p₆ : P} (h : (2 : ℤ) • ∡ p₁ p₂ p₃ = (2 : ℤ) • ∡ p₄ p₅ p₆) : Collinear ℝ ({p₁, p₂, p₃} : Set P) ↔ Collinear ℝ ({p₄, p₅, p₆} : Set P) := by simp_rw [← oangle_eq_zero_or_eq_pi_iff_collinear, ← Real.Angle.two_zsmul_eq_zero_iff, h] /-- If corresponding pairs of points in two angles have the same vector span, twice those angles are equal. -/ theorem two_zsmul_oangle_of_vectorSpan_eq {p₁ p₂ p₃ p₄ p₅ p₆ : P} (h₁₂₄₅ : vectorSpan ℝ ({p₁, p₂} : Set P) = vectorSpan ℝ ({p₄, p₅} : Set P)) (h₃₂₆₅ : vectorSpan ℝ ({p₃, p₂} : Set P) = vectorSpan ℝ ({p₆, p₅} : Set P)) : (2 : ℤ) • ∡ p₁ p₂ p₃ = (2 : ℤ) • ∡ p₄ p₅ p₆ := by simp_rw [vectorSpan_pair] at h₁₂₄₅ h₃₂₆₅ exact o.two_zsmul_oangle_of_span_eq_of_span_eq h₁₂₄₅ h₃₂₆₅ /-- If the lines determined by corresponding pairs of points in two angles are parallel, twice those angles are equal. -/ theorem two_zsmul_oangle_of_parallel {p₁ p₂ p₃ p₄ p₅ p₆ : P} (h₁₂₄₅ : line[ℝ, p₁, p₂] ∥ line[ℝ, p₄, p₅]) (h₃₂₆₅ : line[ℝ, p₃, p₂] ∥ line[ℝ, p₆, p₅]) : (2 : ℤ) • ∡ p₁ p₂ p₃ = (2 : ℤ) • ∡ p₄ p₅ p₆ := by rw [AffineSubspace.affineSpan_pair_parallel_iff_vectorSpan_eq] at h₁₂₄₅ h₃₂₆₅ exact two_zsmul_oangle_of_vectorSpan_eq h₁₂₄₅ h₃₂₆₅ /-- Given three points not equal to `p`, the angle between the first and the second at `p` plus the angle between the second and the third equals the angle between the first and the third. -/ @[simp] theorem oangle_add {p p₁ p₂ p₃ : P} (hp₁ : p₁ ≠ p) (hp₂ : p₂ ≠ p) (hp₃ : p₃ ≠ p) : ∡ p₁ p p₂ + ∡ p₂ p p₃ = ∡ p₁ p p₃ := o.oangle_add (vsub_ne_zero.2 hp₁) (vsub_ne_zero.2 hp₂) (vsub_ne_zero.2 hp₃) /-- Given three points not equal to `p`, the angle between the second and the third at `p` plus the angle between the first and the second equals the angle between the first and the third. -/ @[simp] theorem oangle_add_swap {p p₁ p₂ p₃ : P} (hp₁ : p₁ ≠ p) (hp₂ : p₂ ≠ p) (hp₃ : p₃ ≠ p) : ∡ p₂ p p₃ + ∡ p₁ p p₂ = ∡ p₁ p p₃ := o.oangle_add_swap (vsub_ne_zero.2 hp₁) (vsub_ne_zero.2 hp₂) (vsub_ne_zero.2 hp₃) /-- Given three points not equal to `p`, the angle between the first and the third at `p` minus the angle between the first and the second equals the angle between the second and the third. -/ @[simp] theorem oangle_sub_left {p p₁ p₂ p₃ : P} (hp₁ : p₁ ≠ p) (hp₂ : p₂ ≠ p) (hp₃ : p₃ ≠ p) : ∡ p₁ p p₃ - ∡ p₁ p p₂ = ∡ p₂ p p₃ := o.oangle_sub_left (vsub_ne_zero.2 hp₁) (vsub_ne_zero.2 hp₂) (vsub_ne_zero.2 hp₃) /-- Given three points not equal to `p`, the angle between the first and the third at `p` minus the angle between the second and the third equals the angle between the first and the second. -/ @[simp] theorem oangle_sub_right {p p₁ p₂ p₃ : P} (hp₁ : p₁ ≠ p) (hp₂ : p₂ ≠ p) (hp₃ : p₃ ≠ p) : ∡ p₁ p p₃ - ∡ p₂ p p₃ = ∡ p₁ p p₂ := o.oangle_sub_right (vsub_ne_zero.2 hp₁) (vsub_ne_zero.2 hp₂) (vsub_ne_zero.2 hp₃) /-- Given three points not equal to `p`, adding the angles between them at `p` in cyclic order results in 0. -/ @[simp] theorem oangle_add_cyc3 {p p₁ p₂ p₃ : P} (hp₁ : p₁ ≠ p) (hp₂ : p₂ ≠ p) (hp₃ : p₃ ≠ p) : ∡ p₁ p p₂ + ∡ p₂ p p₃ + ∡ p₃ p p₁ = 0 := o.oangle_add_cyc3 (vsub_ne_zero.2 hp₁) (vsub_ne_zero.2 hp₂) (vsub_ne_zero.2 hp₃) /-- Pons asinorum, oriented angle-at-point form. -/ theorem oangle_eq_oangle_of_dist_eq {p₁ p₂ p₃ : P} (h : dist p₁ p₂ = dist p₁ p₃) : ∡ p₁ p₂ p₃ = ∡ p₂ p₃ p₁ := by simp_rw [dist_eq_norm_vsub V] at h rw [oangle, oangle, ← vsub_sub_vsub_cancel_left p₃ p₂ p₁, ← vsub_sub_vsub_cancel_left p₂ p₃ p₁, o.oangle_sub_eq_oangle_sub_rev_of_norm_eq h] /-- The angle at the apex of an isosceles triangle is `π` minus twice a base angle, oriented angle-at-point form. -/ theorem oangle_eq_pi_sub_two_zsmul_oangle_of_dist_eq {p₁ p₂ p₃ : P} (hn : p₂ ≠ p₃) (h : dist p₁ p₂ = dist p₁ p₃) : ∡ p₃ p₁ p₂ = π - (2 : ℤ) • ∡ p₁ p₂ p₃ := by simp_rw [dist_eq_norm_vsub V] at h rw [oangle, oangle] convert o.oangle_eq_pi_sub_two_zsmul_oangle_sub_of_norm_eq _ h using 1 · rw [← neg_vsub_eq_vsub_rev p₁ p₃, ← neg_vsub_eq_vsub_rev p₁ p₂, o.oangle_neg_neg] · rw [← o.oangle_sub_eq_oangle_sub_rev_of_norm_eq h]; simp · simpa using hn /-- A base angle of an isosceles triangle is acute, oriented angle-at-point form. -/ theorem abs_oangle_right_toReal_lt_pi_div_two_of_dist_eq {p₁ p₂ p₃ : P} (h : dist p₁ p₂ = dist p₁ p₃) : \|(∡ p₁ p₂ p₃).toReal\| < π / 2 := by simp_rw [dist_eq_norm_vsub V] at h rw [oangle, ← vsub_sub_vsub_cancel_left p₃ p₂ p₁] exact o.abs_oangle_sub_right_toReal_lt_pi_div_two h /-- A base angle of an isosceles triangle is acute, oriented angle-at-point form. -/ theorem abs_oangle_left_toReal_lt_pi_div_two_of_dist_eq {p₁ p₂ p₃ : P} (h : dist p₁ p₂ = dist p₁ p₃) : \|(∡ p₂ p₃ p₁).toReal\| < π / 2 := oangle_eq_oangle_of_dist_eq h ▸ abs_oangle_right_toReal_lt_pi_div_two_of_dist_eq h /-- The cosine of the oriented angle at `p` between two points not equal to `p` equals that of the unoriented angle. -/ theorem cos_oangle_eq_cos_angle {p p₁ p₂ : P} (hp₁ : p₁ ≠ p) (hp₂ : p₂ ≠ p) : Real.Angle.cos (∡ p₁ p p₂) = Real.cos (∠ p₁ p p₂) := o.cos_oangle_eq_cos_angle (vsub_ne_zero.2 hp₁) (vsub_ne_zero.2 hp₂) /-- The oriented angle at `p` between two points not equal to `p` is plus or minus the unoriented angle. -/ theorem oangle_eq_angle_or_eq_neg_angle {p p₁ p₂ : P} (hp₁ : p₁ ≠ p) (hp₂ : p₂ ≠ p) : ∡ p₁ p p₂ = ∠ p₁ p p₂ ∨ ∡ p₁ p p₂ = -∠ p₁ p p₂ := o.oangle_eq_angle_or_eq_neg_angle (vsub_ne_zero.2 hp₁) (vsub_ne_zero.2 hp₂) /-- The unoriented angle at `p` between two points not equal to `p` is the absolute value of the oriented angle. -/ theorem angle_eq_abs_oangle_toReal {p p₁ p₂ : P} (hp₁ : p₁ ≠ p) (hp₂ : p₂ ≠ p) : ∠ p₁ p p₂ = \|(∡ p₁ p p₂).toReal\| := o.angle_eq_abs_oangle_toReal (vsub_ne_zero.2 hp₁) (vsub_ne_zero.2 hp₂) /-- If the sign of the oriented angle at `p` between two points is zero, either one of the points equals `p` or the unoriented angle is 0 or π. -/ theorem eq_zero_or_angle_eq_zero_or_pi_of_sign_oangle_eq_zero {p p₁ p₂ : P} (h : (∡ p₁ p p₂).sign = 0) : p₁ = p ∨ p₂ = p ∨ ∠ p₁ p p₂ = 0 ∨ ∠ p₁ p p₂ = π := by convert o.eq_zero_or_angle_eq_zero_or_pi_of_sign_oangle_eq_zero h <;> simp /-- If two unoriented angles are equal, and the signs of the corresponding oriented angles are equal, then the oriented angles are equal (even in degenerate cases). -/ theorem oangle_eq_of_angle_eq_of_sign_eq {p₁ p₂ p₃ p₄ p₅ p₆ : P} (h : ∠ p₁ p₂ p₃ = ∠ p₄ p₅ p₆) (hs : (∡ p₁ p₂ p₃).sign = (∡ p₄ p₅ p₆).sign) : ∡ p₁ p₂ p₃ = ∡ p₄ p₅ p₆ := o.oangle_eq_of_angle_eq_of_sign_eq h hs /-- If the signs of two nondegenerate oriented angles between points are equal, the oriented angles are equal if and only if the unoriented angles are equal. -/ theorem angle_eq_iff_oangle_eq_of_sign_eq {p₁ p₂ p₃ p₄ p₅ p₆ : P} (hp₁ : p₁ ≠ p₂) (hp₃ : p₃ ≠ p₂) (hp₄ : p₄ ≠ p₅) (hp₆ : p₆ ≠ p₅) (hs : (∡ p₁ p₂ p₃).sign = (∡ p₄ p₅ p₆).sign) : ∠ p₁ p₂ p₃ = ∠ p₄ p₅ p₆ ↔ ∡ p₁ p₂ p₃ = ∡ p₄ p₅ p₆ := o.angle_eq_iff_oangle_eq_of_sign_eq (vsub_ne_zero.2 hp₁) (vsub_ne_zero.2 hp₃) (vsub_ne_zero.2 hp₄) (vsub_ne_zero.2 hp₆) hs /-- The oriented angle between three points equals the unoriented angle if the sign is positive. -/ theorem oangle_eq_angle_of_sign_eq_one {p₁ p₂ p₃ : P} (h : (∡ p₁ p₂ p₃).sign = 1) : ∡ p₁ p₂ p₃ = ∠ p₁ p₂ p₃ := o.oangle_eq_angle_of_sign_eq_one h /-- The oriented angle between three points equals minus the unoriented angle if the sign is negative. -/ theorem oangle_eq_neg_angle_of_sign_eq_neg_one {p₁ p₂ p₃ : P} (h : (∡ p₁ p₂ p₃).sign = -1) : ∡ p₁ p₂ p₃ = -∠ p₁ p₂ p₃ := o.oangle_eq_neg_angle_of_sign_eq_neg_one h /-- The unoriented angle at `p` between two points not equal to `p` is zero if and only if the unoriented angle is zero. -/ theorem oangle_eq_zero_iff_angle_eq_zero {p p₁ p₂ : P} (hp₁ : p₁ ≠ p) (hp₂ : p₂ ≠ p) : ∡ p₁ p p₂ = 0 ↔ ∠ p₁ p p₂ = 0 := o.oangle_eq_zero_iff_angle_eq_zero (vsub_ne_zero.2 hp₁) (vsub_ne_zero.2 hp₂) /-- The oriented angle between three points is `π` if and only if the unoriented angle is `π`. -/ theorem oangle_eq_pi_iff_angle_eq_pi {p₁ p₂ p₃ : P} : ∡ p₁ p₂ p₃ = π ↔ ∠ p₁ p₂ p₃ = π := o.oangle_eq_pi_iff_angle_eq_pi /-- If the oriented angle between three points is `π / 2`, so is the unoriented angle. -/ theorem angle_eq_pi_div_two_of_oangle_eq_pi_div_two {p₁ p₂ p₃ : P} (h : ∡ p₁ p₂ p₃ = ↑(π / 2)) : ∠ p₁ p₂ p₃ = π / 2 := by rw [angle, ← InnerProductGeometry.inner_eq_zero_iff_angle_eq_pi_div_two] exact o.inner_eq_zero_of_oangle_eq_pi_div_two h /-- If the oriented angle between three points is `π / 2`, so is the unoriented angle (reversed). -/ theorem angle_rev_eq_pi_div_two_of_oangle_eq_pi_div_two {p₁ p₂ p₃ : P} (h : ∡ p₁ p₂ p₃ = ↑(π / 2)) : ∠ p₃ p₂ p₁ = π / 2 := by rw [angle_comm] exact angle_eq_pi_div_two_of_oangle_eq_pi_div_two h /-- If the oriented angle between three points is `-π / 2`, the unoriented angle is `π / 2`. -/ theorem angle_eq_pi_div_two_of_oangle_eq_neg_pi_div_two {p₁ p₂ p₃ : P} (h : ∡ p₁ p₂ p₃ = ↑(-π / 2)) : ∠ p₁ p₂ p₃ = π / 2 := by rw [angle, ← InnerProductGeometry.inner_eq_zero_iff_angle_eq_pi_div_two] exact o.inner_eq_zero_of_oangle_eq_neg_pi_div_two h /-- If the oriented angle between three points is `-π / 2`, the unoriented angle (reversed) is `π / 2`. -/ theorem angle_rev_eq_pi_div_two_of_oangle_eq_neg_pi_div_two {p₁ p₂ p₃ : P} (h : ∡ p₁ p₂ p₃ = ↑(-π / 2)) : ∠ p₃ p₂ p₁ = π / 2 := by rw [angle_comm] exact angle_eq_pi_div_two_of_oangle_eq_neg_pi_div_two h /-- Swapping the first and second points in an oriented angle negates the sign of that angle. -/ theorem oangle_swap₁₂_sign (p₁ p₂ p₃ : P) : -(∡ p₁ p₂ p₃).sign = (∡ p₂ p₁ p₃).sign := by rw [eq_comm, oangle, oangle, ← o.oangle_neg_neg, neg_vsub_eq_vsub_rev, neg_vsub_eq_vsub_rev, ← vsub_sub_vsub_cancel_left p₁ p₃ p₂, ← neg_vsub_eq_vsub_rev p₃ p₂, sub_eq_add_neg, neg_vsub_eq_vsub_rev p₂ p₁, add_comm, ← @neg_one_smul ℝ] nth_rw 2 [← one_smul ℝ (p₁ -ᵥ p₂)] rw [o.oangle_sign_smul_add_smul_right] simp /-- Swapping the first and third points in an oriented angle negates the sign of that angle. -/ theorem oangle_swap₁₃_sign (p₁ p₂ p₃ : P) : -(∡ p₁ p₂ p₃).sign = (∡ p₃ p₂ p₁).sign := by rw [oangle_rev, Real.Angle.sign_neg, neg_neg] /-- Swapping the second and third points in an oriented angle negates the sign of that angle. -/ theorem oangle_swap₂₃_sign (p₁ p₂ p₃ : P) : -(∡ p₁ p₂ p₃).sign = (∡ p₁ p₃ p₂).sign := by rw [oangle_swap₁₃_sign, ← oangle_swap₁₂_sign, oangle_swap₁₃_sign] /-- Rotating the points in an oriented angle does not change the sign of that angle. -/ theorem oangle_rotate_sign (p₁ p₂ p₃ : P) : (∡ p₂ p₃ p₁).sign = (∡ p₁ p₂ p₃).sign := by rw [← oangle_swap₁₂_sign, oangle_swap₁₃_sign] /-- The oriented angle between three points is π if and only if the second point is strictly between the other two. -/ theorem oangle_eq_pi_iff_sbtw {p₁ p₂ p₃ : P} : ∡ p₁ p₂ p₃ = π ↔ Sbtw ℝ p₁ p₂ p₃ := by rw [oangle_eq_pi_iff_angle_eq_pi, angle_eq_pi_iff_sbtw] /-- If the second of three points is strictly between the other two, the oriented angle at that point is π. -/ theorem _root_.Sbtw.oangle₁₂₃_eq_pi {p₁ p₂ p₃ : P} (h : Sbtw ℝ p₁ p₂ p₃) : ∡ p₁ p₂ p₃ = π := oangle_eq_pi_iff_sbtw.2 h /-- If the second of three points is strictly between the other two, the oriented angle at that point (reversed) is π. -/ theorem _root_.Sbtw.oangle₃₂₁_eq_pi {p₁ p₂ p₃ : P} (h : Sbtw ℝ p₁ p₂ p₃) : ∡ p₃ p₂ p₁ = π := by rw [oangle_eq_pi_iff_oangle_rev_eq_pi, ← h.oangle₁₂₃_eq_pi] /-- If the second of three points is weakly between the other two, the oriented angle at the first point is zero. -/ theorem _root_.Wbtw.oangle₂₁₃_eq_zero {p₁ p₂ p₃ : P} (h : Wbtw ℝ p₁ p₂ p₃) : ∡ p₂ p₁ p₃ = 0 := by by_cases hp₂p₁ : p₂ = p₁; · simp [hp₂p₁] by_cases hp₃p₁ : p₃ = p₁; · simp [hp₃p₁] rw [oangle_eq_zero_iff_angle_eq_zero hp₂p₁ hp₃p₁] exact h.angle₂₁₃_eq_zero_of_ne hp₂p₁ /-- If the second of three points is strictly between the other two, the oriented angle at the first point is zero. -/ theorem _root_.Sbtw.oangle₂₁₃_eq_zero {p₁ p₂ p₃ : P} (h : Sbtw ℝ p₁ p₂ p₃) : ∡ p₂ p₁ p₃ = 0 := h.wbtw.oangle₂₁₃_eq_zero /-- If the second of three points is weakly between the other two, the oriented angle at the first point (reversed) is zero. -/ theorem _root_.Wbtw.oangle₃₁₂_eq_zero {p₁ p₂ p₃ : P} (h : Wbtw ℝ p₁ p₂ p₃) : ∡ p₃ p₁ p₂ = 0 := by rw [oangle_eq_zero_iff_oangle_rev_eq_zero, h.oangle₂₁₃_eq_zero] /-- If the second of three points is strictly between the other two, the oriented angle at the first point (reversed) is zero. -/ theorem _root_.Sbtw.oangle₃₁₂_eq_zero {p₁ p₂ p₃ : P} (h : Sbtw ℝ p₁ p₂ p₃) : ∡ p₃ p₁ p₂ = 0 := h.wbtw.oangle₃₁₂_eq_zero /-- If the second of three points is weakly between the other two, the oriented angle at the third point is zero. -/ theorem _root_.Wbtw.oangle₂₃₁_eq_zero {p₁ p₂ p₃ : P} (h : Wbtw ℝ p₁ p₂ p₃) : ∡ p₂ p₃ p₁ = 0 := h.symm.oangle₂₁₃_eq_zero /-- If the second of three points is strictly between the other two, the oriented angle at the third point is zero. -/ theorem _root_.Sbtw.oangle₂₃₁_eq_zero {p₁ p₂ p₃ : P} (h : Sbtw ℝ p₁ p₂ p₃) : ∡ p₂ p₃ p₁ = 0 := h.wbtw.oangle₂₃₁_eq_zero /-- If the second of three points is weakly between the other two, the oriented angle at the third point (reversed) is zero. -/ theorem _root_.Wbtw.oangle₁₃₂_eq_zero {p₁ p₂ p₃ : P} (h : Wbtw ℝ p₁ p₂ p₃) : ∡ p₁ p₃ p₂ = 0 := h.symm.oangle₃₁₂_eq_zero /-- If the second of three points is strictly between the other two, the oriented angle at the third point (reversed) is zero. -/ theorem _root_.Sbtw.oangle₁₃₂_eq_zero {p₁ p₂ p₃ : P} (h : Sbtw ℝ p₁ p₂ p₃) : ∡ p₁ p₃ p₂ = 0 := h.wbtw.oangle₁₃₂_eq_zero /-- The oriented angle between three points is zero if and only if one of the first and third points is weakly between the other two. -/ theorem oangle_eq_zero_iff_wbtw {p₁ p₂ p₃ : P} : ∡ p₁ p₂ p₃ = 0 ↔ Wbtw ℝ p₂ p₁ p₃ ∨ Wbtw ℝ p₂ p₃ p₁ := by by_cases hp₁p₂ : p₁ = p₂; · simp [hp₁p₂] by_cases hp₃p₂ : p₃ = p₂; · simp [hp₃p₂] rw [oangle_eq_zero_iff_angle_eq_zero hp₁p₂ hp₃p₂, angle_eq_zero_iff_ne_and_wbtw] simp [hp₁p₂, hp₃p₂] /-- An oriented angle is unchanged by replacing the first point by one weakly further away on the same ray. -/ theorem _root_.Wbtw.oangle_eq_left {p₁ p₁' p₂ p₃ : P} (h : Wbtw ℝ p₂ p₁ p₁') (hp₁p₂ : p₁ ≠ p₂) : ∡ p₁ p₂ p₃ = ∡ p₁' p₂ p₃ := by by_cases hp₃p₂ : p₃ = p₂; · simp [hp₃p₂] by_cases hp₁'p₂ : p₁' = p₂; · rw [hp₁'p₂, wbtw_self_iff] at h; exact False.elim (hp₁p₂ h) rw [← oangle_add hp₁'p₂ hp₁p₂ hp₃p₂, h.oangle₃₁₂_eq_zero, zero_add] /-- An oriented angle is unchanged by replacing the first point by one strictly further away on the same ray. -/ theorem _root_.Sbtw.oangle_eq_left {p₁ p₁' p₂ p₃ : P} (h : Sbtw ℝ p₂ p₁ p₁') : ∡ p₁ p₂ p₃ = ∡ p₁' p₂ p₃ := h.wbtw.oangle_eq_left h.ne_left /-- An oriented angle is unchanged by replacing the third point by one weakly further away on the same ray. -/ theorem _root_.Wbtw.oangle_eq_right {p₁ p₂ p₃ p₃' : P} (h : Wbtw ℝ p₂ p₃ p₃') (hp₃p₂ : p₃ ≠ p₂) : ∡ p₁ p₂ p₃ = ∡ p₁ p₂ p₃' := by rw [oangle_rev, h.oangle_eq_left hp₃p₂, ← oangle_rev] /-- An oriented angle is unchanged by replacing the third point by one strictly further away on the same ray. -/ theorem _root_.Sbtw.oangle_eq_right {p₁ p₂ p₃ p₃' : P} (h : Sbtw ℝ p₂ p₃ p₃') : ∡ p₁ p₂ p₃ = ∡ p₁ p₂ p₃' := h.wbtw.oangle_eq_right h.ne_left /-- An oriented angle is unchanged by replacing the first point with the midpoint of the segment between it and the second point. -/ @[simp] theorem oangle_midpoint_left (p₁ p₂ p₃ : P) : ∡ (midpoint ℝ p₁ p₂) p₂ p₃ = ∡ p₁ p₂ p₃ := by by_cases h : p₁ = p₂; · simp [h] exact (sbtw_midpoint_of_ne ℝ h).symm.oangle_eq_left /-- An oriented angle is unchanged by replacing the first point with the midpoint of the segment between the second point and that point. -/ @[simp] theorem oangle_midpoint_rev_left (p₁ p₂ p₃ : P) : ∡ (midpoint ℝ p₂ p₁) p₂ p₃ = ∡ p₁ p₂ p₃ := by rw [midpoint_comm, oangle_midpoint_left] /-- An oriented angle is unchanged by replacing the third point with the midpoint of the segment between it and the second point. -/ @[simp] theorem oangle_midpoint_right (p₁ p₂ p₃ : P) : ∡ p₁ p₂ (midpoint ℝ p₃ p₂) = ∡ p₁ p₂ p₃ := by by_cases h : p₃ = p₂; · simp [h] exact (sbtw_midpoint_of_ne ℝ h).symm.oangle_eq_right /-- An oriented angle is unchanged by replacing the third point with the midpoint of the segment between the second point and that point. -/ @[simp] theorem oangle_midpoint_rev_right (p₁ p₂ p₃ : P) : ∡ p₁ p₂ (midpoint ℝ p₂ p₃) = ∡ p₁ p₂ p₃ := by rw [midpoint_comm, oangle_midpoint_right] /-- Replacing the first point by one on the same line but the opposite ray adds π to the oriented angle. -/ theorem _root_.Sbtw.oangle_eq_add_pi_left {p₁ p₁' p₂ p₃ : P} (h : Sbtw ℝ p₁ p₂ p₁') (hp₃p₂ : p₃ ≠ p₂) : ∡ p₁ p₂ p₃ = ∡ p₁' p₂ p₃ + π := by rw [← h.oangle₁₂₃_eq_pi, oangle_add_swap h.left_ne h.right_ne hp₃p₂] /-- Replacing the third point by one on the same line but the opposite ray adds π to the oriented angle. -/ theorem _root_.Sbtw.oangle_eq_add_pi_right {p₁ p₂ p₃ p₃' : P} (h : Sbtw ℝ p₃ p₂ p₃') (hp₁p₂ : p₁ ≠ p₂) : ∡ p₁ p₂ p₃ = ∡ p₁ p₂ p₃' + π := by rw [← h.oangle₃₂₁_eq_pi, oangle_add hp₁p₂ h.right_ne h.left_ne] /-- Replacing both the first and third points by ones on the same lines but the opposite rays does not change the oriented angle (vertically opposite angles). -/ theorem _root_.Sbtw.oangle_eq_left_right {p₁ p₁' p₂ p₃ p₃' : P} (h₁ : Sbtw ℝ p₁ p₂ p₁') (h₃ : Sbtw ℝ p₃ p₂ p₃') : ∡ p₁ p₂ p₃ = ∡ p₁' p₂ p₃' := by rw [h₁.oangle_eq_add_pi_left h₃.left_ne, h₃.oangle_eq_add_pi_right h₁.right_ne, add_assoc, Real.Angle.coe_pi_add_coe_pi, add_zero] /-- Replacing the first point by one on the same line does not change twice the oriented angle. -/ theorem _root_.Collinear.two_zsmul_oangle_eq_left {p₁ p₁' p₂ p₃ : P} (h : Collinear ℝ ({p₁, p₂, p₁'} : Set P)) (hp₁p₂ : p₁ ≠ p₂) (hp₁'p₂ : p₁' ≠ p₂) : (2 : ℤ) • ∡ p₁ p₂ p₃ = (2 : ℤ) • ∡ p₁' p₂ p₃ := by by_cases hp₃p₂ : p₃ = p₂; · simp [hp₃p₂] rcases h.wbtw_or_wbtw_or_wbtw with (hw \| hw \| hw) · have hw' : Sbtw ℝ p₁ p₂ p₁' := ⟨hw, hp₁p₂.symm, hp₁'p₂.symm⟩ rw [hw'.oangle_eq_add_pi_left hp₃p₂, smul_add, Real.Angle.two_zsmul_coe_pi, add_zero] · rw [hw.oangle_eq_left hp₁'p₂] · rw [hw.symm.oangle_eq_left hp₁p₂] /-- Replacing the third point by one on the same line does not change twice the oriented angle. -/ theorem _root_.Collinear.two_zsmul_oangle_eq_right {p₁ p₂ p₃ p₃' : P} (h : Collinear ℝ ({p₃, p₂, p₃'} : Set P)) (hp₃p₂ : p₃ ≠ p₂) (hp₃'p₂ : p₃' ≠ p₂) : (2 : ℤ) • ∡ p₁ p₂ p₃ = (2 : ℤ) • ∡ p₁ p₂ p₃' := by rw [oangle_rev, smul_neg, h.two_zsmul_oangle_eq_left hp₃p₂ hp₃'p₂, ← smul_neg, ← oangle_rev] /-- Two different points are equidistant from a third point if and only if that third point equals some multiple of a `π / 2` rotation of the vector between those points, plus the midpoint of those points. -/ theorem dist_eq_iff_eq_smul_rotation_pi_div_two_vadd_midpoint {p₁ p₂ p : P} (h : p₁ ≠ p₂) : dist p₁ p = dist p₂ p ↔ ∃ r : ℝ, r • o.rotation (π / 2 : ℝ) (p₂ -ᵥ p₁) +ᵥ midpoint ℝ p₁ p₂ = p := by refine ⟨fun hd => ?_, fun hr => ?_⟩ · have hi : ⟪p₂ -ᵥ p₁, p -ᵥ midpoint ℝ p₁ p₂⟫ = 0 := by rw [@dist_eq_norm_vsub' V, @dist_eq_norm_vsub' V, ← mul_self_inj (norm_nonneg _) (norm_nonneg _), ← real_inner_self_eq_norm_mul_norm, ← real_inner_self_eq_norm_mul_norm] at hd simp_rw [vsub_midpoint, ← vsub_sub_vsub_cancel_left p₂ p₁ p, inner_sub_left, inner_add_right, inner_smul_right, hd, real_inner_comm (p -ᵥ p₁)] abel rw [@Orientation.inner_eq_zero_iff_eq_zero_or_eq_smul_rotation_pi_div_two V _ _ _ o, or_iff_right (vsub_ne_zero.2 h.symm)] at hi rcases hi with ⟨r, hr⟩ rw [eq_comm, ← eq_vadd_iff_vsub_eq] at hr exact ⟨r, hr.symm⟩ · rcases hr with ⟨r, rfl⟩ simp_rw [@dist_eq_norm_vsub V, vsub_vadd_eq_vsub_sub, left_vsub_midpoint, right_vsub_midpoint, invOf_eq_inv, ← neg_vsub_eq_vsub_rev p₂ p₁, ← mul_self_inj (norm_nonneg _) (norm_nonneg _), ← real_inner_self_eq_norm_mul_norm, inner_sub_sub_self] simp [-neg_vsub_eq_vsub_rev] open AffineSubspace /-- Given two pairs of distinct points on the same line, such that the vectors between those pairs of points are on the same ray (oriented in the same direction on that line), and a fifth point, the angles at the fifth point between each of those two pairs of points have the same sign. -/ theorem _root_.Collinear.oangle_sign_of_sameRay_vsub {p₁ p₂ p₃ p₄ : P} (p₅ : P) (hp₁p₂ : p₁ ≠ p₂) (hp₃p₄ : p₃ ≠ p₄) (hc : Collinear ℝ ({p₁, p₂, p₃, p₄} : Set P)) (hr : SameRay ℝ (p₂ -ᵥ p₁) (p₄ -ᵥ p₃)) : (∡ p₁ p₅ p₂).sign = (∡ p₃ p₅ p₄).sign := by by_cases hc₅₁₂ : Collinear ℝ ({p₅, p₁, p₂} : Set P) · have hc₅₁₂₃₄ : Collinear ℝ ({p₅, p₁, p₂, p₃, p₄} : Set P) := (hc.collinear_insert_iff_of_ne (Set.mem_insert _ _) (Set.mem_insert_of_mem _ (Set.mem_insert _ _)) hp₁p₂).2 hc₅₁₂ have hc₅₃₄ : Collinear ℝ ({p₅, p₃, p₄} : Set P) := (hc.collinear_insert_iff_of_ne (Set.mem_insert_of_mem _ (Set.mem_insert_of_mem _ (Set.mem_insert _ _))) (Set.mem_insert_of_mem _ (Set.mem_insert_of_mem _ (Set.mem_insert_of_mem _ (Set.mem_singleton _)))) hp₃p₄).1 hc₅₁₂₃₄ rw [Set.insert_comm] at hc₅₁₂ hc₅₃₄ have hs₁₅₂ := oangle_eq_zero_or_eq_pi_iff_collinear.2 hc₅₁₂ have hs₃₅₄ := oangle_eq_zero_or_eq_pi_iff_collinear.2 hc₅₃₄	rw [← Real.Angle.sign_eq_zero_iff] at hs₁₅₂ hs₃₅₄ rw [hs₁₅₂, hs₃₅₄]	Mathlib/Geometry/Euclidean/Angle/Oriented/Affine.lean	608	609
/- Copyright (c) 2020 Joseph Myers. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Joseph Myers -/ import Mathlib.Algebra.Order.Group.Pointwise.Interval import Mathlib.LinearAlgebra.BilinearMap import Mathlib.LinearAlgebra.Pi import Mathlib.LinearAlgebra.Prod import Mathlib.Tactic.Abel import Mathlib.Algebra.AddTorsor.Basic import Mathlib.LinearAlgebra.AffineSpace.Defs /-! # Affine maps This file defines affine maps. ## Main definitions * `AffineMap` is the type of affine maps between two affine spaces with the same ring `k`. Various basic examples of affine maps are defined, including `const`, `id`, `lineMap` and `homothety`. ## Notations * `P1 →ᵃ[k] P2` is a notation for `AffineMap k P1 P2`; * `AffineSpace V P`: a localized notation for `AddTorsor V P` defined in `LinearAlgebra.AffineSpace.Basic`. ## Implementation notes `outParam` is used in the definition of `[AddTorsor V P]` to make `V` an implicit argument (deduced from `P`) in most cases. As for modules, `k` is an explicit argument rather than implied by `P` or `V`. This file only provides purely algebraic definitions and results. Those depending on analysis or topology are defined elsewhere; see `Analysis.Normed.Affine.AddTorsor` and `Topology.Algebra.Affine`. ## References * https://en.wikipedia.org/wiki/Affine_space * https://en.wikipedia.org/wiki/Principal_homogeneous_space -/ open Affine /-- An `AffineMap k P1 P2` (notation: `P1 →ᵃ[k] P2`) is a map from `P1` to `P2` that induces a corresponding linear map from `V1` to `V2`. -/ structure AffineMap (k : Type) {V1 : Type} (P1 : Type) {V2 : Type} (P2 : Type) [Ring k] [AddCommGroup V1] [Module k V1] [AffineSpace V1 P1] [AddCommGroup V2] [Module k V2] [AffineSpace V2 P2] where toFun : P1 → P2 linear : V1 →ₗ[k] V2 map_vadd' : ∀ (p : P1) (v : V1), toFun (v +ᵥ p) = linear v +ᵥ toFun p /-- An `AffineMap k P1 P2` (notation: `P1 →ᵃ[k] P2`) is a map from `P1` to `P2` that induces a corresponding linear map from `V1` to `V2`. -/ notation:25 P1 " →ᵃ[" k:25 "] " P2:0 => AffineMap k P1 P2 instance AffineMap.instFunLike (k : Type) {V1 : Type} (P1 : Type) {V2 : Type} (P2 : Type) [Ring k] [AddCommGroup V1] [Module k V1] [AffineSpace V1 P1] [AddCommGroup V2] [Module k V2] [AffineSpace V2 P2] : FunLike (P1 →ᵃ[k] P2) P1 P2 where coe := AffineMap.toFun coe_injective' := fun ⟨f, f_linear, f_add⟩ ⟨g, g_linear, g_add⟩ => fun (h : f = g) => by obtain ⟨p⟩ := (AddTorsor.nonempty : Nonempty P1) congr with v apply vadd_right_cancel (f p) rw [← f_add, h, ← g_add] namespace LinearMap variable {k : Type} {V₁ : Type} {V₂ : Type} [Ring k] [AddCommGroup V₁] [Module k V₁] [AddCommGroup V₂] [Module k V₂] (f : V₁ →ₗ[k] V₂) /-- Reinterpret a linear map as an affine map. -/ def toAffineMap : V₁ →ᵃ[k] V₂ where toFun := f linear := f map_vadd' p v := f.map_add v p @[simp] theorem coe_toAffineMap : ⇑f.toAffineMap = f := rfl @[simp] theorem toAffineMap_linear : f.toAffineMap.linear = f := rfl end LinearMap namespace AffineMap variable {k : Type} {V1 : Type} {P1 : Type} {V2 : Type} {P2 : Type} {V3 : Type} {P3 : Type} {V4 : Type} {P4 : Type} [Ring k] [AddCommGroup V1] [Module k V1] [AffineSpace V1 P1] [AddCommGroup V2] [Module k V2] [AffineSpace V2 P2] [AddCommGroup V3] [Module k V3] [AffineSpace V3 P3] [AddCommGroup V4] [Module k V4] [AffineSpace V4 P4] /-- Constructing an affine map and coercing back to a function produces the same map. -/ @[simp] theorem coe_mk (f : P1 → P2) (linear add) : ((mk f linear add : P1 →ᵃ[k] P2) : P1 → P2) = f := rfl /-- `toFun` is the same as the result of coercing to a function. -/ @[simp] theorem toFun_eq_coe (f : P1 →ᵃ[k] P2) : f.toFun = ⇑f := rfl /-- An affine map on the result of adding a vector to a point produces the same result as the linear map applied to that vector, added to the affine map applied to that point. -/ @[simp] theorem map_vadd (f : P1 →ᵃ[k] P2) (p : P1) (v : V1) : f (v +ᵥ p) = f.linear v +ᵥ f p := f.map_vadd' p v /-- The linear map on the result of subtracting two points is the result of subtracting the result of the affine map on those two points. -/ @[simp] theorem linearMap_vsub (f : P1 →ᵃ[k] P2) (p1 p2 : P1) : f.linear (p1 -ᵥ p2) = f p1 -ᵥ f p2 := by conv_rhs => rw [← vsub_vadd p1 p2, map_vadd, vadd_vsub] /-- Two affine maps are equal if they coerce to the same function. -/ @[ext] theorem ext {f g : P1 →ᵃ[k] P2} (h : ∀ p, f p = g p) : f = g := DFunLike.ext _ _ h theorem coeFn_injective : @Function.Injective (P1 →ᵃ[k] P2) (P1 → P2) (⇑) := DFunLike.coe_injective protected theorem congr_arg (f : P1 →ᵃ[k] P2) {x y : P1} (h : x = y) : f x = f y := congr_arg _ h protected theorem congr_fun {f g : P1 →ᵃ[k] P2} (h : f = g) (x : P1) : f x = g x := h ▸ rfl /-- Two affine maps are equal if they have equal linear maps and are equal at some point. -/ theorem ext_linear {f g : P1 →ᵃ[k] P2} (h₁ : f.linear = g.linear) {p : P1} (h₂ : f p = g p) : f = g := by ext q have hgl : g.linear (q -ᵥ p) = toFun g ((q -ᵥ p) +ᵥ q) -ᵥ toFun g q := by simp have := f.map_vadd' q (q -ᵥ p) rw [h₁, hgl, toFun_eq_coe, map_vadd, linearMap_vsub, h₂] at this simpa /-- Two affine maps are equal if they have equal linear maps and are equal at some point. -/ theorem ext_linear_iff {f g : P1 →ᵃ[k] P2} : f = g ↔ (f.linear = g.linear) ∧ (∃ p, f p = g p) := ⟨fun h ↦ ⟨congrArg _ h, by inhabit P1; exact default, by rw [h]⟩, fun h ↦ Exists.casesOn h.2 fun _ hp ↦ ext_linear h.1 hp⟩ variable (k P1) /-- The constant function as an `AffineMap`. -/ def const (p : P2) : P1 →ᵃ[k] P2 where toFun := Function.const P1 p linear := 0 map_vadd' _ _ := letI : AddAction V2 P2 := inferInstance by simp @[simp] theorem coe_const (p : P2) : ⇑(const k P1 p) = Function.const P1 p := rfl @[simp] theorem const_apply (p : P2) (q : P1) : (const k P1 p) q = p := rfl @[simp] theorem const_linear (p : P2) : (const k P1 p).linear = 0 := rfl variable {k P1} theorem linear_eq_zero_iff_exists_const (f : P1 →ᵃ[k] P2) : f.linear = 0 ↔ ∃ q, f = const k P1 q := by refine ⟨fun h => ?_, fun h => ?_⟩ · use f (Classical.arbitrary P1) ext rw [coe_const, Function.const_apply, ← @vsub_eq_zero_iff_eq V2, ← f.linearMap_vsub, h, LinearMap.zero_apply] · rcases h with ⟨q, rfl⟩ exact const_linear k P1 q instance nonempty : Nonempty (P1 →ᵃ[k] P2) := (AddTorsor.nonempty : Nonempty P2).map <\| const k P1 /-- Construct an affine map by verifying the relation between the map and its linear part at one base point. Namely, this function takes a map `f : P₁ → P₂`, a linear map `f' : V₁ →ₗ[k] V₂`, and a point `p` such that for any other point `p'` we have `f p' = f' (p' -ᵥ p) +ᵥ f p`. -/ def mk' (f : P1 → P2) (f' : V1 →ₗ[k] V2) (p : P1) (h : ∀ p' : P1, f p' = f' (p' -ᵥ p) +ᵥ f p) : P1 →ᵃ[k] P2 where toFun := f linear := f' map_vadd' p' v := by rw [h, h p', vadd_vsub_assoc, f'.map_add, vadd_vadd] @[simp] theorem coe_mk' (f : P1 → P2) (f' : V1 →ₗ[k] V2) (p h) : ⇑(mk' f f' p h) = f := rfl @[simp] theorem mk'_linear (f : P1 → P2) (f' : V1 →ₗ[k] V2) (p h) : (mk' f f' p h).linear = f' := rfl section SMul variable {R : Type} [Monoid R] [DistribMulAction R V2] [SMulCommClass k R V2] /-- The space of affine maps to a module inherits an `R`-action from the action on its codomain. -/ instance mulAction : MulAction R (P1 →ᵃ[k] V2) where smul c f := ⟨c • ⇑f, c • f.linear, fun p v => by simp [smul_add]⟩ one_smul _ := ext fun _ => one_smul _ _ mul_smul _ _ _ := ext fun _ => mul_smul _ _ _ @[simp, norm_cast] theorem coe_smul (c : R) (f : P1 →ᵃ[k] V2) : ⇑(c • f) = c • ⇑f := rfl @[simp] theorem smul_linear (t : R) (f : P1 →ᵃ[k] V2) : (t • f).linear = t • f.linear := rfl instance isCentralScalar [DistribMulAction Rᵐᵒᵖ V2] [IsCentralScalar R V2] : IsCentralScalar R (P1 →ᵃ[k] V2) where op_smul_eq_smul _r _x := ext fun _ => op_smul_eq_smul _ _ end SMul instance : Zero (P1 →ᵃ[k] V2) where zero := ⟨0, 0, fun _ _ => (zero_vadd _ _).symm⟩ instance : Add (P1 →ᵃ[k] V2) where add f g := ⟨f + g, f.linear + g.linear, fun p v => by simp [add_add_add_comm]⟩ instance : Sub (P1 →ᵃ[k] V2) where sub f g := ⟨f - g, f.linear - g.linear, fun p v => by simp [sub_add_sub_comm]⟩ instance : Neg (P1 →ᵃ[k] V2) where neg f := ⟨-f, -f.linear, fun p v => by simp [add_comm, map_vadd f]⟩ @[simp, norm_cast] theorem coe_zero : ⇑(0 : P1 →ᵃ[k] V2) = 0 := rfl @[simp, norm_cast] theorem coe_add (f g : P1 →ᵃ[k] V2) : ⇑(f + g) = f + g := rfl @[simp, norm_cast] theorem coe_neg (f : P1 →ᵃ[k] V2) : ⇑(-f) = -f := rfl @[simp, norm_cast] theorem coe_sub (f g : P1 →ᵃ[k] V2) : ⇑(f - g) = f - g := rfl @[simp] theorem zero_linear : (0 : P1 →ᵃ[k] V2).linear = 0 := rfl @[simp] theorem add_linear (f g : P1 →ᵃ[k] V2) : (f + g).linear = f.linear + g.linear := rfl @[simp] theorem sub_linear (f g : P1 →ᵃ[k] V2) : (f - g).linear = f.linear - g.linear := rfl @[simp] theorem neg_linear (f : P1 →ᵃ[k] V2) : (-f).linear = -f.linear := rfl /-- The set of affine maps to a vector space is an additive commutative group. -/ instance : AddCommGroup (P1 →ᵃ[k] V2) := coeFn_injective.addCommGroup _ coe_zero coe_add coe_neg coe_sub (fun _ _ => coe_smul _ _) fun _ _ => coe_smul _ _ /-- The space of affine maps from `P1` to `P2` is an affine space over the space of affine maps from `P1` to the vector space `V2` corresponding to `P2`. -/ instance : AffineSpace (P1 →ᵃ[k] V2) (P1 →ᵃ[k] P2) where vadd f g := ⟨fun p => f p +ᵥ g p, f.linear + g.linear, fun p v => by simp [vadd_vadd, add_right_comm]⟩ zero_vadd f := ext fun p => zero_vadd _ (f p) add_vadd f₁ f₂ f₃ := ext fun p => add_vadd (f₁ p) (f₂ p) (f₃ p) vsub f g := ⟨fun p => f p -ᵥ g p, f.linear - g.linear, fun p v => by simp [vsub_vadd_eq_vsub_sub, vadd_vsub_assoc, add_sub, sub_add_eq_add_sub]⟩ vsub_vadd' f g := ext fun p => vsub_vadd (f p) (g p) vadd_vsub' f g := ext fun p => vadd_vsub (f p) (g p) @[simp] theorem vadd_apply (f : P1 →ᵃ[k] V2) (g : P1 →ᵃ[k] P2) (p : P1) : (f +ᵥ g) p = f p +ᵥ g p := rfl @[simp] theorem vsub_apply (f g : P1 →ᵃ[k] P2) (p : P1) : (f -ᵥ g : P1 →ᵃ[k] V2) p = f p -ᵥ g p := rfl /-- `Prod.fst` as an `AffineMap`. -/ def fst : P1 × P2 →ᵃ[k] P1 where toFun := Prod.fst linear := LinearMap.fst k V1 V2 map_vadd' _ _ := rfl @[simp] theorem coe_fst : ⇑(fst : P1 × P2 →ᵃ[k] P1) = Prod.fst := rfl @[simp] theorem fst_linear : (fst : P1 × P2 →ᵃ[k] P1).linear = LinearMap.fst k V1 V2 := rfl /-- `Prod.snd` as an `AffineMap`. -/ def snd : P1 × P2 →ᵃ[k] P2 where toFun := Prod.snd linear := LinearMap.snd k V1 V2 map_vadd' _ _ := rfl @[simp] theorem coe_snd : ⇑(snd : P1 × P2 →ᵃ[k] P2) = Prod.snd := rfl @[simp] theorem snd_linear : (snd : P1 × P2 →ᵃ[k] P2).linear = LinearMap.snd k V1 V2 := rfl variable (k P1) /-- Identity map as an affine map. -/ nonrec def id : P1 →ᵃ[k] P1 where toFun := id linear := LinearMap.id map_vadd' _ _ := rfl /-- The identity affine map acts as the identity. -/ @[simp, norm_cast] theorem coe_id : ⇑(id k P1) = _root_.id := rfl @[simp] theorem id_linear : (id k P1).linear = LinearMap.id := rfl variable {P1} /-- The identity affine map acts as the identity. -/ theorem id_apply (p : P1) : id k P1 p = p := rfl variable {k} instance : Inhabited (P1 →ᵃ[k] P1) := ⟨id k P1⟩ /-- Composition of affine maps. -/ def comp (f : P2 →ᵃ[k] P3) (g : P1 →ᵃ[k] P2) : P1 →ᵃ[k] P3 where toFun := f ∘ g linear := f.linear.comp g.linear map_vadd' := by intro p v rw [Function.comp_apply, g.map_vadd, f.map_vadd] rfl /-- Composition of affine maps acts as applying the two functions. -/ @[simp] theorem coe_comp (f : P2 →ᵃ[k] P3) (g : P1 →ᵃ[k] P2) : ⇑(f.comp g) = f ∘ g := rfl /-- Composition of affine maps acts as applying the two functions. -/ theorem comp_apply (f : P2 →ᵃ[k] P3) (g : P1 →ᵃ[k] P2) (p : P1) : f.comp g p = f (g p) := rfl @[simp] theorem comp_id (f : P1 →ᵃ[k] P2) : f.comp (id k P1) = f := ext fun _ => rfl @[simp] theorem id_comp (f : P1 →ᵃ[k] P2) : (id k P2).comp f = f := ext fun _ => rfl theorem comp_assoc (f₃₄ : P3 →ᵃ[k] P4) (f₂₃ : P2 →ᵃ[k] P3) (f₁₂ : P1 →ᵃ[k] P2) : (f₃₄.comp f₂₃).comp f₁₂ = f₃₄.comp (f₂₃.comp f₁₂) := rfl instance : Monoid (P1 →ᵃ[k] P1) where one := id k P1 mul := comp one_mul := id_comp mul_one := comp_id mul_assoc := comp_assoc @[simp] theorem coe_mul (f g : P1 →ᵃ[k] P1) : ⇑(f g) = f ∘ g := rfl @[simp] theorem coe_one : ⇑(1 : P1 →ᵃ[k] P1) = _root_.id := rfl /-- `AffineMap.linear` on endomorphisms is a `MonoidHom`. -/ @[simps] def linearHom : (P1 →ᵃ[k] P1) →* V1 →ₗ[k] V1 where toFun := linear map_one' := rfl map_mul' _ _ := rfl @[simp] theorem linear_injective_iff (f : P1 →ᵃ[k] P2) : Function.Injective f.linear ↔ Function.Injective f := by obtain ⟨p⟩ := (inferInstance : Nonempty P1) have h : ⇑f.linear = (Equiv.vaddConst (f p)).symm ∘ f ∘ Equiv.vaddConst p := by ext v simp [f.map_vadd, vadd_vsub_assoc] rw [h, Equiv.comp_injective, Equiv.injective_comp] @[simp] theorem linear_surjective_iff (f : P1 →ᵃ[k] P2) : Function.Surjective f.linear ↔ Function.Surjective f := by obtain ⟨p⟩ := (inferInstance : Nonempty P1) have h : ⇑f.linear = (Equiv.vaddConst (f p)).symm ∘ f ∘ Equiv.vaddConst p := by ext v simp [f.map_vadd, vadd_vsub_assoc] rw [h, Equiv.comp_surjective, Equiv.surjective_comp] @[simp] theorem linear_bijective_iff (f : P1 →ᵃ[k] P2) : Function.Bijective f.linear ↔ Function.Bijective f := and_congr f.linear_injective_iff f.linear_surjective_iff theorem image_vsub_image {s t : Set P1} (f : P1 →ᵃ[k] P2) : f '' s -ᵥ f '' t = f.linear '' (s -ᵥ t) := by ext v simp only [Set.mem_vsub, Set.mem_image, exists_exists_and_eq_and, exists_and_left, ← f.linearMap_vsub] constructor · rintro ⟨x, hx, y, hy, hv⟩ exact ⟨x -ᵥ y, ⟨x, hx, y, hy, rfl⟩, hv⟩ · rintro ⟨-, ⟨x, hx, y, hy, rfl⟩, rfl⟩ exact ⟨x, hx, y, hy, rfl⟩ /-! ### Definition of `AffineMap.lineMap` and lemmas about it -/ /-- The affine map from `k` to `P1` sending `0` to `p₀` and `1` to `p₁`. -/ def lineMap (p₀ p₁ : P1) : k →ᵃ[k] P1 := ((LinearMap.id : k →ₗ[k] k).smulRight (p₁ -ᵥ p₀)).toAffineMap +ᵥ const k k p₀ theorem coe_lineMap (p₀ p₁ : P1) : (lineMap p₀ p₁ : k → P1) = fun c => c • (p₁ -ᵥ p₀) +ᵥ p₀ := rfl theorem lineMap_apply (p₀ p₁ : P1) (c : k) : lineMap p₀ p₁ c = c • (p₁ -ᵥ p₀) +ᵥ p₀ := rfl theorem lineMap_apply_module' (p₀ p₁ : V1) (c : k) : lineMap p₀ p₁ c = c • (p₁ - p₀) + p₀ := rfl theorem lineMap_apply_module (p₀ p₁ : V1) (c : k) : lineMap p₀ p₁ c = (1 - c) • p₀ + c • p₁ := by simp [lineMap_apply_module', smul_sub, sub_smul]; abel theorem lineMap_apply_ring' (a b c : k) : lineMap a b c = c * (b - a) + a := rfl theorem lineMap_apply_ring (a b c : k) : lineMap a b c = (1 - c) * a + c * b := lineMap_apply_module a b c theorem lineMap_vadd_apply (p : P1) (v : V1) (c : k) : lineMap p (v +ᵥ p) c = c • v +ᵥ p := by rw [lineMap_apply, vadd_vsub] @[simp] theorem lineMap_linear (p₀ p₁ : P1) : (lineMap p₀ p₁ : k →ᵃ[k] P1).linear = LinearMap.id.smulRight (p₁ -ᵥ p₀) := add_zero _ theorem lineMap_same_apply (p : P1) (c : k) : lineMap p p c = p := by simp [lineMap_apply] @[simp] theorem lineMap_same (p : P1) : lineMap p p = const k k p := ext <\| lineMap_same_apply p @[simp] theorem lineMap_apply_zero (p₀ p₁ : P1) : lineMap p₀ p₁ (0 : k) = p₀ := by simp [lineMap_apply] @[simp] theorem lineMap_apply_one (p₀ p₁ : P1) : lineMap p₀ p₁ (1 : k) = p₁ := by simp [lineMap_apply] @[simp] theorem lineMap_eq_lineMap_iff [NoZeroSMulDivisors k V1] {p₀ p₁ : P1} {c₁ c₂ : k} : lineMap p₀ p₁ c₁ = lineMap p₀ p₁ c₂ ↔ p₀ = p₁ ∨ c₁ = c₂ := by rw [lineMap_apply, lineMap_apply, ← @vsub_eq_zero_iff_eq V1, vadd_vsub_vadd_cancel_right, ← sub_smul, smul_eq_zero, sub_eq_zero, vsub_eq_zero_iff_eq, or_comm, eq_comm] @[simp] theorem lineMap_eq_left_iff [NoZeroSMulDivisors k V1] {p₀ p₁ : P1} {c : k} : lineMap p₀ p₁ c = p₀ ↔ p₀ = p₁ ∨ c = 0 := by rw [← @lineMap_eq_lineMap_iff k V1, lineMap_apply_zero] @[simp] theorem lineMap_eq_right_iff [NoZeroSMulDivisors k V1] {p₀ p₁ : P1} {c : k} : lineMap p₀ p₁ c = p₁ ↔ p₀ = p₁ ∨ c = 1 := by rw [← @lineMap_eq_lineMap_iff k V1, lineMap_apply_one] variable (k) in theorem lineMap_injective [NoZeroSMulDivisors k V1] {p₀ p₁ : P1} (h : p₀ ≠ p₁) : Function.Injective (lineMap p₀ p₁ : k → P1) := fun _c₁ _c₂ hc => (lineMap_eq_lineMap_iff.mp hc).resolve_left h @[simp] theorem apply_lineMap (f : P1 →ᵃ[k] P2) (p₀ p₁ : P1) (c : k) : f (lineMap p₀ p₁ c) = lineMap (f p₀) (f p₁) c := by simp [lineMap_apply] @[simp] theorem comp_lineMap (f : P1 →ᵃ[k] P2) (p₀ p₁ : P1) : f.comp (lineMap p₀ p₁) = lineMap (f p₀) (f p₁) := ext <\| f.apply_lineMap p₀ p₁ @[simp] theorem fst_lineMap (p₀ p₁ : P1 × P2) (c : k) : (lineMap p₀ p₁ c).1 = lineMap p₀.1 p₁.1 c := fst.apply_lineMap p₀ p₁ c @[simp] theorem snd_lineMap (p₀ p₁ : P1 × P2) (c : k) : (lineMap p₀ p₁ c).2 = lineMap p₀.2 p₁.2 c := snd.apply_lineMap p₀ p₁ c theorem lineMap_symm (p₀ p₁ : P1) : lineMap p₀ p₁ = (lineMap p₁ p₀).comp (lineMap (1 : k) (0 : k)) := by rw [comp_lineMap] simp theorem lineMap_apply_one_sub (p₀ p₁ : P1) (c : k) : lineMap p₀ p₁ (1 - c) = lineMap p₁ p₀ c := by rw [lineMap_symm p₀, comp_apply] congr simp [lineMap_apply] @[simp] theorem lineMap_vsub_left (p₀ p₁ : P1) (c : k) : lineMap p₀ p₁ c -ᵥ p₀ = c • (p₁ -ᵥ p₀) := vadd_vsub _ _ @[simp] theorem left_vsub_lineMap (p₀ p₁ : P1) (c : k) : p₀ -ᵥ lineMap p₀ p₁ c = c • (p₀ -ᵥ p₁) := by rw [← neg_vsub_eq_vsub_rev, lineMap_vsub_left, ← smul_neg, neg_vsub_eq_vsub_rev] @[simp] theorem lineMap_vsub_right (p₀ p₁ : P1) (c : k) : lineMap p₀ p₁ c -ᵥ p₁ = (1 - c) • (p₀ -ᵥ p₁) := by rw [← lineMap_apply_one_sub, lineMap_vsub_left] @[simp] theorem right_vsub_lineMap (p₀ p₁ : P1) (c : k) : p₁ -ᵥ lineMap p₀ p₁ c = (1 - c) • (p₁ -ᵥ p₀) := by rw [← lineMap_apply_one_sub, left_vsub_lineMap] theorem lineMap_vadd_lineMap (v₁ v₂ : V1) (p₁ p₂ : P1) (c : k) : lineMap v₁ v₂ c +ᵥ lineMap p₁ p₂ c = lineMap (v₁ +ᵥ p₁) (v₂ +ᵥ p₂) c := ((fst : V1 × P1 →ᵃ[k] V1) +ᵥ (snd : V1 × P1 →ᵃ[k] P1)).apply_lineMap (v₁, p₁) (v₂, p₂) c theorem lineMap_vsub_lineMap (p₁ p₂ p₃ p₄ : P1) (c : k) : lineMap p₁ p₂ c -ᵥ lineMap p₃ p₄ c = lineMap (p₁ -ᵥ p₃) (p₂ -ᵥ p₄) c := ((fst : P1 × P1 →ᵃ[k] P1) -ᵥ (snd : P1 × P1 →ᵃ[k] P1)).apply_lineMap (_, _) (_, _) c @[simp] lemma lineMap_lineMap_right (p₀ p₁ : P1) (c d : k) : lineMap p₀ (lineMap p₀ p₁ c) d = lineMap p₀ p₁ (d * c) := by simp [lineMap_apply, mul_smul] @[simp] lemma lineMap_lineMap_left (p₀ p₁ : P1) (c d : k) : lineMap (lineMap p₀ p₁ c) p₁ d = lineMap p₀ p₁ (1 - (1 - d) * (1 - c)) := by simp_rw [lineMap_apply_one_sub, ← lineMap_apply_one_sub p₁, lineMap_lineMap_right] /-- Decomposition of an affine map in the special case when the point space and vector space are the same. -/ theorem decomp (f : V1 →ᵃ[k] V2) : (f : V1 → V2) = ⇑f.linear + fun _ => f 0 := by ext x calc f x = f.linear x +ᵥ f 0 := by rw [← f.map_vadd, vadd_eq_add, add_zero] _ = (f.linear + fun _ : V1 => f 0) x := rfl /-- Decomposition of an affine map in the special case when the point space and vector space are the same. -/ theorem decomp' (f : V1 →ᵃ[k] V2) : (f.linear : V1 → V2) = ⇑f - fun _ => f 0 := by rw [decomp] simp only [LinearMap.map_zero, Pi.add_apply, add_sub_cancel_right, zero_add] theorem image_uIcc {k : Type} [Field k] [LinearOrder k] [IsStrictOrderedRing k] (f : k →ᵃ[k] k) (a b : k) : f '' Set.uIcc a b = Set.uIcc (f a) (f b) := by have : ⇑f = (fun x => x + f 0) ∘ fun x => x (f 1 - f 0) := by ext x change f x = x • (f 1 -ᵥ f 0) +ᵥ f 0 rw [← f.linearMap_vsub, ← f.linear.map_smul, ← f.map_vadd] simp only [vsub_eq_sub, add_zero, mul_one, vadd_eq_add, sub_zero, smul_eq_mul] rw [this, Set.image_comp] simp only [Set.image_add_const_uIcc, Set.image_mul_const_uIcc, Function.comp_apply] section variable {ι : Type} {V : ι → Type} {P : ι → Type} [∀ i, AddCommGroup (V i)] [∀ i, Module k (V i)] [∀ i, AddTorsor (V i) (P i)] /-- Evaluation at a point as an affine map. -/ def proj (i : ι) : (∀ i : ι, P i) →ᵃ[k] P i where toFun f := f i linear := @LinearMap.proj k ι _ V _ _ i map_vadd' _ _ := rfl @[simp] theorem proj_apply (i : ι) (f : ∀ i, P i) : @proj k _ ι V P _ _ _ i f = f i := rfl @[simp] theorem proj_linear (i : ι) : (@proj k _ ι V P _ _ _ i).linear = @LinearMap.proj k ι _ V _ _ i := rfl theorem pi_lineMap_apply (f g : ∀ i, P i) (c : k) (i : ι) : lineMap f g c i = lineMap (f i) (g i) c := (proj i : (∀ i, P i) →ᵃ[k] P i).apply_lineMap f g c end end AffineMap namespace AffineMap variable {R k V1 P1 V2 P2 V3 P3 : Type} section Ring variable [Ring k] [AddCommGroup V1] [AffineSpace V1 P1] [AddCommGroup V2] [AffineSpace V2 P2] variable [AddCommGroup V3] [AffineSpace V3 P3] [Module k V1] [Module k V2] [Module k V3] section DistribMulAction variable [Monoid R] [DistribMulAction R V2] [SMulCommClass k R V2] /-- The space of affine maps to a module inherits an `R`-action from the action on its codomain. -/ instance distribMulAction : DistribMulAction R (P1 →ᵃ[k] V2) where smul_add _ _ _ := ext fun _ => smul_add _ _ _ smul_zero _ := ext fun _ => smul_zero _ end DistribMulAction section Module variable [Semiring R] [Module R V2] [SMulCommClass k R V2] /-- The space of affine maps taking values in an `R`-module is an `R`-module. -/ instance : Module R (P1 →ᵃ[k] V2) := { AffineMap.distribMulAction with add_smul := fun _ _ _ => ext fun _ => add_smul _ _ _ zero_smul := fun _ => ext fun _ => zero_smul _ _ }	variable (R)	Mathlib/LinearAlgebra/AffineSpace/AffineMap.lean	646	647
/- Copyright (c) 2021 Aaron Anderson, Jesse Michael Han, Floris van Doorn. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Aaron Anderson, Jesse Michael Han, Floris van Doorn -/ import Mathlib.Data.Finset.Basic import Mathlib.ModelTheory.Syntax import Mathlib.Data.List.ProdSigma /-! # Basics on First-Order Semantics This file defines the interpretations of first-order terms, formulas, sentences, and theories in a style inspired by the [Flypitch project](https://flypitch.github.io/). ## Main Definitions - `FirstOrder.Language.Term.realize` is defined so that `t.realize v` is the term `t` evaluated at variables `v`. - `FirstOrder.Language.BoundedFormula.Realize` is defined so that `φ.Realize v xs` is the bounded formula `φ` evaluated at tuples of variables `v` and `xs`. - `FirstOrder.Language.Formula.Realize` is defined so that `φ.Realize v` is the formula `φ` evaluated at variables `v`. - `FirstOrder.Language.Sentence.Realize` is defined so that `φ.Realize M` is the sentence `φ` evaluated in the structure `M`. Also denoted `M ⊨ φ`. - `FirstOrder.Language.Theory.Model` is defined so that `T.Model M` is true if and only if every sentence of `T` is realized in `M`. Also denoted `T ⊨ φ`. ## Main Results - Several results in this file show that syntactic constructions such as `relabel`, `castLE`, `liftAt`, `subst`, and the actions of language maps commute with realization of terms, formulas, sentences, and theories. ## Implementation Notes - Formulas use a modified version of de Bruijn variables. Specifically, a `L.BoundedFormula α n` is a formula with some variables indexed by a type `α`, which cannot be quantified over, and some indexed by `Fin n`, which can. For any `φ : L.BoundedFormula α (n + 1)`, we define the formula `∀' φ : L.BoundedFormula α n` by universally quantifying over the variable indexed by `n : Fin (n + 1)`. ## References For the Flypitch project: - [J. Han, F. van Doorn, A formal proof of the independence of the continuum hypothesis] [flypitch_cpp] - [J. Han, F. van Doorn, A formalization of forcing and the unprovability of the continuum hypothesis][flypitch_itp] -/ universe u v w u' v' namespace FirstOrder namespace Language variable {L : Language.{u, v}} {L' : Language} variable {M : Type w} {N P : Type} [L.Structure M] [L.Structure N] [L.Structure P] variable {α : Type u'} {β : Type v'} {γ : Type} open FirstOrder Cardinal open Structure Cardinal Fin namespace Term /-- A term `t` with variables indexed by `α` can be evaluated by giving a value to each variable. -/ def realize (v : α → M) : ∀ _t : L.Term α, M \| var k => v k \| func f ts => funMap f fun i => (ts i).realize v @[simp] theorem realize_var (v : α → M) (k) : realize v (var k : L.Term α) = v k := rfl @[simp] theorem realize_func (v : α → M) {n} (f : L.Functions n) (ts) : realize v (func f ts : L.Term α) = funMap f fun i => (ts i).realize v := rfl @[simp] theorem realize_relabel {t : L.Term α} {g : α → β} {v : β → M} : (t.relabel g).realize v = t.realize (v ∘ g) := by induction t with \| var => rfl \| func f ts ih => simp [ih] @[simp] theorem realize_liftAt {n n' m : ℕ} {t : L.Term (α ⊕ (Fin n))} {v : α ⊕ (Fin (n + n')) → M} : (t.liftAt n' m).realize v = t.realize (v ∘ Sum.map id fun i : Fin _ => if ↑i < m then Fin.castAdd n' i else Fin.addNat i n') := realize_relabel @[simp] theorem realize_constants {c : L.Constants} {v : α → M} : c.term.realize v = c := funMap_eq_coe_constants @[simp] theorem realize_functions_apply₁ {f : L.Functions 1} {t : L.Term α} {v : α → M} : (f.apply₁ t).realize v = funMap f ![t.realize v] := by rw [Functions.apply₁, Term.realize] refine congr rfl (funext fun i => ?_) simp only [Matrix.cons_val_fin_one] @[simp] theorem realize_functions_apply₂ {f : L.Functions 2} {t₁ t₂ : L.Term α} {v : α → M} : (f.apply₂ t₁ t₂).realize v = funMap f ![t₁.realize v, t₂.realize v] := by rw [Functions.apply₂, Term.realize] refine congr rfl (funext (Fin.cases ?_ ?_)) · simp only [Matrix.cons_val_zero] · simp only [Matrix.cons_val_succ, Matrix.cons_val_fin_one, forall_const] theorem realize_con {A : Set M} {a : A} {v : α → M} : (L.con a).term.realize v = a := rfl @[simp] theorem realize_subst {t : L.Term α} {tf : α → L.Term β} {v : β → M} : (t.subst tf).realize v = t.realize fun a => (tf a).realize v := by induction t with \| var => rfl \| func _ _ ih => simp [ih] theorem realize_restrictVar [DecidableEq α] {t : L.Term α} {f : t.varFinset → β} {v : β → M} (v' : α → M) (hv' : ∀ a, v (f a) = v' a) : (t.restrictVar f).realize v = t.realize v' := by induction t with \| var => simp [restrictVar, hv'] \| func _ _ ih => exact congr rfl (funext fun i => ih i ((by simp [Function.comp_apply, hv']))) /-- A special case of `realize_restrictVar`, included because we can add the `simp` attribute to it -/ @[simp] theorem realize_restrictVar' [DecidableEq α] {t : L.Term α} {s : Set α} (h : ↑t.varFinset ⊆ s) {v : α → M} : (t.restrictVar (Set.inclusion h)).realize (v ∘ (↑)) = t.realize v := realize_restrictVar _ (by simp) theorem realize_restrictVarLeft [DecidableEq α] {γ : Type} {t : L.Term (α ⊕ γ)} {f : t.varFinsetLeft → β} {xs : β ⊕ γ → M} (xs' : α → M) (hxs' : ∀ a, xs (Sum.inl (f a)) = xs' a) : (t.restrictVarLeft f).realize xs = t.realize (Sum.elim xs' (xs ∘ Sum.inr)) := by induction t with \| var a => cases a <;> simp [restrictVarLeft, hxs'] \| func _ _ ih => exact congr rfl (funext fun i => ih i (by simp [hxs'])) /-- A special case of `realize_restrictVarLeft`, included because we can add the `simp` attribute to it -/ @[simp] theorem realize_restrictVarLeft' [DecidableEq α] {γ : Type} {t : L.Term (α ⊕ γ)} {s : Set α} (h : ↑t.varFinsetLeft ⊆ s) {v : α → M} {xs : γ → M} : (t.restrictVarLeft (Set.inclusion h)).realize (Sum.elim (v ∘ (↑)) xs) = t.realize (Sum.elim v xs) := realize_restrictVarLeft _ (by simp) @[simp] theorem realize_constantsToVars [L[[α]].Structure M] [(lhomWithConstants L α).IsExpansionOn M] {t : L[[α]].Term β} {v : β → M} : t.constantsToVars.realize (Sum.elim (fun a => ↑(L.con a)) v) = t.realize v := by induction t with \| var => simp \| @func n f ts ih => cases n · cases f · simp only [realize, ih, constantsOn, constantsOnFunc, constantsToVars] -- Porting note: below lemma does not work with simp for some reason rw [withConstants_funMap_sumInl] · simp only [realize, constantsToVars, Sum.elim_inl, funMap_eq_coe_constants] rfl · obtain - \| f := f · simp only [realize, ih, constantsOn, constantsOnFunc, constantsToVars] -- Porting note: below lemma does not work with simp for some reason rw [withConstants_funMap_sumInl] · exact isEmptyElim f @[simp] theorem realize_varsToConstants [L[[α]].Structure M] [(lhomWithConstants L α).IsExpansionOn M] {t : L.Term (α ⊕ β)} {v : β → M} : t.varsToConstants.realize v = t.realize (Sum.elim (fun a => ↑(L.con a)) v) := by induction t with \| var ab => rcases ab with a \| b <;> simp [Language.con] \| func f ts ih => simp only [realize, constantsOn, constantsOnFunc, ih, varsToConstants] -- Porting note: below lemma does not work with simp for some reason rw [withConstants_funMap_sumInl] theorem realize_constantsVarsEquivLeft [L[[α]].Structure M] [(lhomWithConstants L α).IsExpansionOn M] {n} {t : L[[α]].Term (β ⊕ (Fin n))} {v : β → M} {xs : Fin n → M} : (constantsVarsEquivLeft t).realize (Sum.elim (Sum.elim (fun a => ↑(L.con a)) v) xs) = t.realize (Sum.elim v xs) := by simp only [constantsVarsEquivLeft, realize_relabel, Equiv.coe_trans, Function.comp_apply, constantsVarsEquiv_apply, relabelEquiv_symm_apply] refine _root_.trans ?_ realize_constantsToVars rcongr x rcases x with (a \| (b \| i)) <;> simp end Term namespace LHom @[simp] theorem realize_onTerm [L'.Structure M] (φ : L →ᴸ L') [φ.IsExpansionOn M] (t : L.Term α) (v : α → M) : (φ.onTerm t).realize v = t.realize v := by induction t with \| var => rfl \| func f ts ih => simp only [Term.realize, LHom.onTerm, LHom.map_onFunction, ih] end LHom @[simp] theorem HomClass.realize_term {F : Type} [FunLike F M N] [HomClass L F M N] (g : F) {t : L.Term α} {v : α → M} : t.realize (g ∘ v) = g (t.realize v) := by induction t · rfl · rw [Term.realize, Term.realize, HomClass.map_fun] refine congr rfl ?_ ext x simp [] variable {n : ℕ} namespace BoundedFormula open Term /-- A bounded formula can be evaluated as true or false by giving values to each free variable. -/ def Realize : ∀ {l} (_f : L.BoundedFormula α l) (_v : α → M) (_xs : Fin l → M), Prop \| _, falsum, _v, _xs => False \| _, equal t₁ t₂, v, xs => t₁.realize (Sum.elim v xs) = t₂.realize (Sum.elim v xs) \| _, rel R ts, v, xs => RelMap R fun i => (ts i).realize (Sum.elim v xs) \| _, imp f₁ f₂, v, xs => Realize f₁ v xs → Realize f₂ v xs \| _, all f, v, xs => ∀ x : M, Realize f v (snoc xs x) variable {l : ℕ} {φ ψ : L.BoundedFormula α l} {θ : L.BoundedFormula α l.succ} variable {v : α → M} {xs : Fin l → M} @[simp] theorem realize_bot : (⊥ : L.BoundedFormula α l).Realize v xs ↔ False := Iff.rfl @[simp] theorem realize_not : φ.not.Realize v xs ↔ ¬φ.Realize v xs := Iff.rfl @[simp] theorem realize_bdEqual (t₁ t₂ : L.Term (α ⊕ (Fin l))) : (t₁.bdEqual t₂).Realize v xs ↔ t₁.realize (Sum.elim v xs) = t₂.realize (Sum.elim v xs) := Iff.rfl @[simp] theorem realize_top : (⊤ : L.BoundedFormula α l).Realize v xs ↔ True := by simp [Top.top] @[simp] theorem realize_inf : (φ ⊓ ψ).Realize v xs ↔ φ.Realize v xs ∧ ψ.Realize v xs := by simp [Inf.inf, Realize] @[simp] theorem realize_foldr_inf (l : List (L.BoundedFormula α n)) (v : α → M) (xs : Fin n → M) : (l.foldr (· ⊓ ·) ⊤).Realize v xs ↔ ∀ φ ∈ l, BoundedFormula.Realize φ v xs := by induction' l with φ l ih · simp · simp [ih] @[simp] theorem realize_imp : (φ.imp ψ).Realize v xs ↔ φ.Realize v xs → ψ.Realize v xs := by simp only [Realize] @[simp] theorem realize_rel {k : ℕ} {R : L.Relations k} {ts : Fin k → L.Term _} : (R.boundedFormula ts).Realize v xs ↔ RelMap R fun i => (ts i).realize (Sum.elim v xs) := Iff.rfl @[simp] theorem realize_rel₁ {R : L.Relations 1} {t : L.Term _} : (R.boundedFormula₁ t).Realize v xs ↔ RelMap R ![t.realize (Sum.elim v xs)] := by rw [Relations.boundedFormula₁, realize_rel, iff_eq_eq] refine congr rfl (funext fun _ => ?_) simp only [Matrix.cons_val_fin_one] @[simp] theorem realize_rel₂ {R : L.Relations 2} {t₁ t₂ : L.Term _} : (R.boundedFormula₂ t₁ t₂).Realize v xs ↔ RelMap R ![t₁.realize (Sum.elim v xs), t₂.realize (Sum.elim v xs)] := by rw [Relations.boundedFormula₂, realize_rel, iff_eq_eq] refine congr rfl (funext (Fin.cases ?_ ?_)) · simp only [Matrix.cons_val_zero] · simp only [Matrix.cons_val_succ, Matrix.cons_val_fin_one, forall_const] @[simp] theorem realize_sup : (φ ⊔ ψ).Realize v xs ↔ φ.Realize v xs ∨ ψ.Realize v xs := by simp only [realize, max, realize_not, eq_iff_iff] tauto @[simp] theorem realize_foldr_sup (l : List (L.BoundedFormula α n)) (v : α → M) (xs : Fin n → M) : (l.foldr (· ⊔ ·) ⊥).Realize v xs ↔ ∃ φ ∈ l, BoundedFormula.Realize φ v xs := by induction' l with φ l ih · simp · simp_rw [List.foldr_cons, realize_sup, ih, List.mem_cons, or_and_right, exists_or, exists_eq_left] @[simp] theorem realize_all : (all θ).Realize v xs ↔ ∀ a : M, θ.Realize v (Fin.snoc xs a) := Iff.rfl @[simp] theorem realize_ex : θ.ex.Realize v xs ↔ ∃ a : M, θ.Realize v (Fin.snoc xs a) := by rw [BoundedFormula.ex, realize_not, realize_all, not_forall] simp_rw [realize_not, Classical.not_not] @[simp] theorem realize_iff : (φ.iff ψ).Realize v xs ↔ (φ.Realize v xs ↔ ψ.Realize v xs) := by simp only [BoundedFormula.iff, realize_inf, realize_imp, and_imp, ← iff_def] theorem realize_castLE_of_eq {m n : ℕ} (h : m = n) {h' : m ≤ n} {φ : L.BoundedFormula α m} {v : α → M} {xs : Fin n → M} : (φ.castLE h').Realize v xs ↔ φ.Realize v (xs ∘ Fin.cast h) := by subst h simp only [castLE_rfl, cast_refl, OrderIso.coe_refl, Function.comp_id] theorem realize_mapTermRel_id [L'.Structure M] {ft : ∀ n, L.Term (α ⊕ (Fin n)) → L'.Term (β ⊕ (Fin n))} {fr : ∀ n, L.Relations n → L'.Relations n} {n} {φ : L.BoundedFormula α n} {v : α → M} {v' : β → M} {xs : Fin n → M} (h1 : ∀ (n) (t : L.Term (α ⊕ (Fin n))) (xs : Fin n → M), (ft n t).realize (Sum.elim v' xs) = t.realize (Sum.elim v xs)) (h2 : ∀ (n) (R : L.Relations n) (x : Fin n → M), RelMap (fr n R) x = RelMap R x) : (φ.mapTermRel ft fr fun _ => id).Realize v' xs ↔ φ.Realize v xs := by induction φ with \| falsum => rfl \| equal => simp [mapTermRel, Realize, h1] \| rel => simp [mapTermRel, Realize, h1, h2] \| imp _ _ ih1 ih2 => simp [mapTermRel, Realize, ih1, ih2] \| all _ ih => simp only [mapTermRel, Realize, ih, id] theorem realize_mapTermRel_add_castLe [L'.Structure M] {k : ℕ} {ft : ∀ n, L.Term (α ⊕ (Fin n)) → L'.Term (β ⊕ (Fin (k + n)))} {fr : ∀ n, L.Relations n → L'.Relations n} {n} {φ : L.BoundedFormula α n} (v : ∀ {n}, (Fin (k + n) → M) → α → M) {v' : β → M} (xs : Fin (k + n) → M) (h1 : ∀ (n) (t : L.Term (α ⊕ (Fin n))) (xs' : Fin (k + n) → M), (ft n t).realize (Sum.elim v' xs') = t.realize (Sum.elim (v xs') (xs' ∘ Fin.natAdd _))) (h2 : ∀ (n) (R : L.Relations n) (x : Fin n → M), RelMap (fr n R) x = RelMap R x) (hv : ∀ (n) (xs : Fin (k + n) → M) (x : M), @v (n + 1) (snoc xs x : Fin _ → M) = v xs) : (φ.mapTermRel ft fr fun _ => castLE (add_assoc _ _ _).symm.le).Realize v' xs ↔ φ.Realize (v xs) (xs ∘ Fin.natAdd _) := by induction φ with \| falsum => rfl \| equal => simp [mapTermRel, Realize, h1] \| rel => simp [mapTermRel, Realize, h1, h2] \| imp _ _ ih1 ih2 => simp [mapTermRel, Realize, ih1, ih2] \| all _ ih => simp [mapTermRel, Realize, ih, hv] @[simp] theorem realize_relabel {m n : ℕ} {φ : L.BoundedFormula α n} {g : α → β ⊕ (Fin m)} {v : β → M} {xs : Fin (m + n) → M} : (φ.relabel g).Realize v xs ↔ φ.Realize (Sum.elim v (xs ∘ Fin.castAdd n) ∘ g) (xs ∘ Fin.natAdd m) := by apply realize_mapTermRel_add_castLe <;> simp theorem realize_liftAt {n n' m : ℕ} {φ : L.BoundedFormula α n} {v : α → M} {xs : Fin (n + n') → M} (hmn : m + n' ≤ n + 1) : (φ.liftAt n' m).Realize v xs ↔ φ.Realize v (xs ∘ fun i => if ↑i < m then Fin.castAdd n' i else Fin.addNat i n') := by rw [liftAt] induction φ with \| falsum => simp [mapTermRel, Realize] \| equal => simp [mapTermRel, Realize, realize_rel, realize_liftAt, Sum.elim_comp_map] \| rel => simp [mapTermRel, Realize, realize_rel, realize_liftAt, Sum.elim_comp_map] \| imp _ _ ih1 ih2 => simp only [mapTermRel, Realize, ih1 hmn, ih2 hmn] \| @all k _ ih3 => have h : k + 1 + n' = k + n' + 1 := by rw [add_assoc, add_comm 1 n', ← add_assoc] simp only [mapTermRel, Realize, realize_castLE_of_eq h, ih3 (hmn.trans k.succ.le_succ)] refine forall_congr' fun x => iff_eq_eq.mpr (congr rfl (funext (Fin.lastCases ?_ fun i => ?_))) · simp only [Function.comp_apply, val_last, snoc_last] refine (congr rfl (Fin.ext ?_)).trans (snoc_last _ _) split_ifs <;> dsimp; omega · simp only [Function.comp_apply, Fin.snoc_castSucc] refine (congr rfl (Fin.ext ?_)).trans (snoc_castSucc _ _ _) simp only [coe_castSucc, coe_cast] split_ifs <;> simp theorem realize_liftAt_one {n m : ℕ} {φ : L.BoundedFormula α n} {v : α → M} {xs : Fin (n + 1) → M} (hmn : m ≤ n) : (φ.liftAt 1 m).Realize v xs ↔ φ.Realize v (xs ∘ fun i => if ↑i < m then castSucc i else i.succ) := by simp [realize_liftAt (add_le_add_right hmn 1), castSucc] @[simp] theorem realize_liftAt_one_self {n : ℕ} {φ : L.BoundedFormula α n} {v : α → M} {xs : Fin (n + 1) → M} : (φ.liftAt 1 n).Realize v xs ↔ φ.Realize v (xs ∘ castSucc) := by rw [realize_liftAt_one (refl n), iff_eq_eq] refine congr rfl (congr rfl (funext fun i => ?_)) rw [if_pos i.is_lt] @[simp] theorem realize_subst {φ : L.BoundedFormula α n} {tf : α → L.Term β} {v : β → M} {xs : Fin n → M} : (φ.subst tf).Realize v xs ↔ φ.Realize (fun a => (tf a).realize v) xs := realize_mapTermRel_id (fun n t x => by rw [Term.realize_subst] rcongr a cases a · simp only [Sum.elim_inl, Function.comp_apply, Term.realize_relabel, Sum.elim_comp_inl] · rfl) (by simp) theorem realize_restrictFreeVar [DecidableEq α] {n : ℕ} {φ : L.BoundedFormula α n} {f : φ.freeVarFinset → β} {v : β → M} {xs : Fin n → M} (v' : α → M) (hv' : ∀ a, v (f a) = v' a) : (φ.restrictFreeVar f).Realize v xs ↔ φ.Realize v' xs := by induction φ with \| falsum => rfl \| equal => simp only [Realize, restrictFreeVar, freeVarFinset.eq_2] rw [realize_restrictVarLeft v' (by simp [hv']), realize_restrictVarLeft v' (by simp [hv'])] simp [Function.comp_apply] \| rel => simp only [Realize, freeVarFinset.eq_3, Finset.biUnion_val, restrictFreeVar] congr! rw [realize_restrictVarLeft v' (by simp [hv'])] simp [Function.comp_apply] \| imp _ _ ih1 ih2 => simp only [Realize, restrictFreeVar, freeVarFinset.eq_4] rw [ih1, ih2] <;> simp [hv'] \| all _ ih3 => simp only [restrictFreeVar, Realize] refine forall_congr' (fun _ => ?_) rw [ih3]; simp [hv'] /-- A special case of `realize_restrictFreeVar`, included because we can add the `simp` attribute to it -/ @[simp] theorem realize_restrictFreeVar' [DecidableEq α] {n : ℕ} {φ : L.BoundedFormula α n} {s : Set α} (h : ↑φ.freeVarFinset ⊆ s) {v : α → M} {xs : Fin n → M} : (φ.restrictFreeVar (Set.inclusion h)).Realize (v ∘ (↑)) xs ↔ φ.Realize v xs := realize_restrictFreeVar _ (by simp) theorem realize_constantsVarsEquiv [L[[α]].Structure M] [(lhomWithConstants L α).IsExpansionOn M] {n} {φ : L[[α]].BoundedFormula β n} {v : β → M} {xs : Fin n → M} : (constantsVarsEquiv φ).Realize (Sum.elim (fun a => ↑(L.con a)) v) xs ↔ φ.Realize v xs := by refine realize_mapTermRel_id (fun n t xs => realize_constantsVarsEquivLeft) fun n R xs => ?_ -- This used to be `rw`, but we need `erw` after https://github.com/leanprover/lean4/pull/2644 erw [← (lhomWithConstants L α).map_onRelation (Equiv.sumEmpty (L.Relations n) ((constantsOn α).Relations n) R) xs] rcongr obtain - \| R := R · simp · exact isEmptyElim R @[simp] theorem realize_relabelEquiv {g : α ≃ β} {k} {φ : L.BoundedFormula α k} {v : β → M} {xs : Fin k → M} : (relabelEquiv g φ).Realize v xs ↔ φ.Realize (v ∘ g) xs := by simp only [relabelEquiv, mapTermRelEquiv_apply, Equiv.coe_refl] refine realize_mapTermRel_id (fun n t xs => ?_) fun _ _ _ => rfl simp only [relabelEquiv_apply, Term.realize_relabel] refine congr (congr rfl ?_) rfl ext (i \| i) <;> rfl variable [Nonempty M] theorem realize_all_liftAt_one_self {n : ℕ} {φ : L.BoundedFormula α n} {v : α → M} {xs : Fin n → M} : (φ.liftAt 1 n).all.Realize v xs ↔ φ.Realize v xs := by inhabit M simp only [realize_all, realize_liftAt_one_self] refine ⟨fun h => ?_, fun h a => ?_⟩ · refine (congr rfl (funext fun i => ?_)).mp (h default) simp · refine (congr rfl (funext fun i => ?_)).mp h simp end BoundedFormula namespace LHom open BoundedFormula @[simp] theorem realize_onBoundedFormula [L'.Structure M] (φ : L →ᴸ L') [φ.IsExpansionOn M] {n : ℕ} (ψ : L.BoundedFormula α n) {v : α → M} {xs : Fin n → M} : (φ.onBoundedFormula ψ).Realize v xs ↔ ψ.Realize v xs := by induction ψ with \| falsum => rfl \| equal => simp only [onBoundedFormula, realize_bdEqual, realize_onTerm]; rfl \| rel => simp only [onBoundedFormula, realize_rel, LHom.map_onRelation, Function.comp_apply, realize_onTerm] rfl \| imp _ _ ih1 ih2 => simp only [onBoundedFormula, ih1, ih2, realize_imp] \| all _ ih3 => simp only [onBoundedFormula, ih3, realize_all] end LHom namespace Formula /-- A formula can be evaluated as true or false by giving values to each free variable. -/ nonrec def Realize (φ : L.Formula α) (v : α → M) : Prop := φ.Realize v default variable {φ ψ : L.Formula α} {v : α → M} @[simp] theorem realize_not : φ.not.Realize v ↔ ¬φ.Realize v := Iff.rfl @[simp] theorem realize_bot : (⊥ : L.Formula α).Realize v ↔ False := Iff.rfl @[simp] theorem realize_top : (⊤ : L.Formula α).Realize v ↔ True := BoundedFormula.realize_top @[simp] theorem realize_inf : (φ ⊓ ψ).Realize v ↔ φ.Realize v ∧ ψ.Realize v := BoundedFormula.realize_inf @[simp] theorem realize_imp : (φ.imp ψ).Realize v ↔ φ.Realize v → ψ.Realize v := BoundedFormula.realize_imp @[simp] theorem realize_rel {k : ℕ} {R : L.Relations k} {ts : Fin k → L.Term α} : (R.formula ts).Realize v ↔ RelMap R fun i => (ts i).realize v := BoundedFormula.realize_rel.trans (by simp) @[simp] theorem realize_rel₁ {R : L.Relations 1} {t : L.Term _} : (R.formula₁ t).Realize v ↔ RelMap R ![t.realize v] := by rw [Relations.formula₁, realize_rel, iff_eq_eq] refine congr rfl (funext fun _ => ?_) simp only [Matrix.cons_val_fin_one] @[simp] theorem realize_rel₂ {R : L.Relations 2} {t₁ t₂ : L.Term _} : (R.formula₂ t₁ t₂).Realize v ↔ RelMap R ![t₁.realize v, t₂.realize v] := by rw [Relations.formula₂, realize_rel, iff_eq_eq] refine congr rfl (funext (Fin.cases ?_ ?_)) · simp only [Matrix.cons_val_zero] · simp only [Matrix.cons_val_succ, Matrix.cons_val_fin_one, forall_const] @[simp] theorem realize_sup : (φ ⊔ ψ).Realize v ↔ φ.Realize v ∨ ψ.Realize v := BoundedFormula.realize_sup @[simp] theorem realize_iff : (φ.iff ψ).Realize v ↔ (φ.Realize v ↔ ψ.Realize v) := BoundedFormula.realize_iff @[simp] theorem realize_relabel {φ : L.Formula α} {g : α → β} {v : β → M} : (φ.relabel g).Realize v ↔ φ.Realize (v ∘ g) := by rw [Realize, Realize, relabel, BoundedFormula.realize_relabel, iff_eq_eq, Fin.castAdd_zero] exact congr rfl (funext finZeroElim) theorem realize_relabel_sumInr (φ : L.Formula (Fin n)) {v : Empty → M} {x : Fin n → M} : (BoundedFormula.relabel Sum.inr φ).Realize v x ↔ φ.Realize x := by rw [BoundedFormula.realize_relabel, Formula.Realize, Sum.elim_comp_inr, Fin.castAdd_zero, cast_refl, Function.comp_id, Subsingleton.elim (x ∘ (natAdd n : Fin 0 → Fin n)) default] @[deprecated (since := "2025-02-21")] alias realize_relabel_sum_inr := realize_relabel_sumInr @[simp] theorem realize_equal {t₁ t₂ : L.Term α} {x : α → M} : (t₁.equal t₂).Realize x ↔ t₁.realize x = t₂.realize x := by simp [Term.equal, Realize] @[simp] theorem realize_graph {f : L.Functions n} {x : Fin n → M} {y : M} : (Formula.graph f).Realize (Fin.cons y x : _ → M) ↔ funMap f x = y := by simp only [Formula.graph, Term.realize, realize_equal, Fin.cons_zero, Fin.cons_succ] rw [eq_comm] theorem boundedFormula_realize_eq_realize (φ : L.Formula α) (x : α → M) (y : Fin 0 → M) : BoundedFormula.Realize φ x y ↔ φ.Realize x := by rw [Formula.Realize, iff_iff_eq] congr ext i; exact Fin.elim0 i end Formula @[simp] theorem LHom.realize_onFormula [L'.Structure M] (φ : L →ᴸ L') [φ.IsExpansionOn M] (ψ : L.Formula α) {v : α → M} : (φ.onFormula ψ).Realize v ↔ ψ.Realize v := φ.realize_onBoundedFormula ψ @[simp] theorem LHom.setOf_realize_onFormula [L'.Structure M] (φ : L →ᴸ L') [φ.IsExpansionOn M] (ψ : L.Formula α) : (setOf (φ.onFormula ψ).Realize : Set (α → M)) = setOf ψ.Realize := by ext simp variable (M) /-- A sentence can be evaluated as true or false in a structure. -/ nonrec def Sentence.Realize (φ : L.Sentence) : Prop := φ.Realize (default : _ → M) -- input using \\|= or \vDash, but not using \models @[inherit_doc Sentence.Realize] infixl:51 " ⊨ " => Sentence.Realize @[simp] theorem Sentence.realize_not {φ : L.Sentence} : M ⊨ φ.not ↔ ¬M ⊨ φ := Iff.rfl namespace Formula @[simp] theorem realize_equivSentence_symm_con [L[[α]].Structure M] [(L.lhomWithConstants α).IsExpansionOn M] (φ : L[[α]].Sentence) : ((equivSentence.symm φ).Realize fun a => (L.con a : M)) ↔ φ.Realize M := by simp only [equivSentence, _root_.Equiv.symm_symm, Equiv.coe_trans, Realize, BoundedFormula.realize_relabelEquiv, Function.comp] refine _root_.trans ?_ BoundedFormula.realize_constantsVarsEquiv rw [iff_iff_eq] congr with (_ \| a) · simp · cases a @[simp] theorem realize_equivSentence [L[[α]].Structure M] [(L.lhomWithConstants α).IsExpansionOn M] (φ : L.Formula α) : (equivSentence φ).Realize M ↔ φ.Realize fun a => (L.con a : M) := by rw [← realize_equivSentence_symm_con M (equivSentence φ), _root_.Equiv.symm_apply_apply] theorem realize_equivSentence_symm (φ : L[[α]].Sentence) (v : α → M) : (equivSentence.symm φ).Realize v ↔ @Sentence.Realize _ M (@Language.withConstantsStructure L M _ α (constantsOn.structure v)) φ := letI := constantsOn.structure v realize_equivSentence_symm_con M φ end Formula @[simp] theorem LHom.realize_onSentence [L'.Structure M] (φ : L →ᴸ L') [φ.IsExpansionOn M] (ψ : L.Sentence) : M ⊨ φ.onSentence ψ ↔ M ⊨ ψ := φ.realize_onFormula ψ variable (L) /-- The complete theory of a structure `M` is the set of all sentences `M` satisfies. -/ def completeTheory : L.Theory := { φ \| M ⊨ φ } variable (N) /-- Two structures are elementarily equivalent when they satisfy the same sentences. -/ def ElementarilyEquivalent : Prop := L.completeTheory M = L.completeTheory N @[inherit_doc FirstOrder.Language.ElementarilyEquivalent] scoped[FirstOrder] notation:25 A " ≅[" L "] " B:50 => FirstOrder.Language.ElementarilyEquivalent L A B variable {L} {M} {N} @[simp] theorem mem_completeTheory {φ : Sentence L} : φ ∈ L.completeTheory M ↔ M ⊨ φ := Iff.rfl theorem elementarilyEquivalent_iff : M ≅[L] N ↔ ∀ φ : L.Sentence, M ⊨ φ ↔ N ⊨ φ := by simp only [ElementarilyEquivalent, Set.ext_iff, completeTheory, Set.mem_setOf_eq] variable (M) /-- A model of a theory is a structure in which every sentence is realized as true. -/ class Theory.Model (T : L.Theory) : Prop where realize_of_mem : ∀ φ ∈ T, M ⊨ φ -- input using \\|= or \vDash, but not using \models @[inherit_doc Theory.Model] infixl:51 " ⊨ " => Theory.Model variable {M} (T : L.Theory) @[simp default - 10] theorem Theory.model_iff : M ⊨ T ↔ ∀ φ ∈ T, M ⊨ φ := ⟨fun h => h.realize_of_mem, fun h => ⟨h⟩⟩ theorem Theory.realize_sentence_of_mem [M ⊨ T] {φ : L.Sentence} (h : φ ∈ T) : M ⊨ φ := Theory.Model.realize_of_mem φ h @[simp] theorem LHom.onTheory_model [L'.Structure M] (φ : L →ᴸ L') [φ.IsExpansionOn M] (T : L.Theory) : M ⊨ φ.onTheory T ↔ M ⊨ T := by simp [Theory.model_iff, LHom.onTheory]	variable {T} instance model_empty : M ⊨ (∅ : L.Theory) :=	Mathlib/ModelTheory/Semantics.lean	690	693
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Mario Carneiro, Patrick Massot -/ import Mathlib.Algebra.Group.TypeTags.Basic import Mathlib.Data.Fin.VecNotation import Mathlib.Data.Finset.Piecewise import Mathlib.Order.Filter.Cofinite import Mathlib.Order.Filter.Curry import Mathlib.Topology.Constructions.SumProd import Mathlib.Topology.NhdsSet /-! # Constructions of new topological spaces from old ones This file constructs pi types, subtypes and quotients of topological spaces and sets up their basic theory, such as criteria for maps into or out of these constructions to be continuous; descriptions of the open sets, neighborhood filters, and generators of these constructions; and their behavior with respect to embeddings and other specific classes of maps. ## Implementation note The constructed topologies are defined using induced and coinduced topologies along with the complete lattice structure on topologies. Their universal properties (for example, a map `X → Y × Z` is continuous if and only if both projections `X → Y`, `X → Z` are) follow easily using order-theoretic descriptions of continuity. With more work we can also extract descriptions of the open sets, neighborhood filters and so on. ## Tags product, subspace, quotient space -/ noncomputable section open Topology TopologicalSpace Set Filter Function open scoped Set.Notation universe u v u' v' variable {X : Type u} {Y : Type v} {Z W ε ζ : Type} section Constructions instance {r : X → X → Prop} [t : TopologicalSpace X] : TopologicalSpace (Quot r) := coinduced (Quot.mk r) t instance instTopologicalSpaceQuotient {s : Setoid X} [t : TopologicalSpace X] : TopologicalSpace (Quotient s) := coinduced Quotient.mk' t instance instTopologicalSpaceSigma {ι : Type} {X : ι → Type v} [t₂ : ∀ i, TopologicalSpace (X i)] : TopologicalSpace (Sigma X) := ⨆ i, coinduced (Sigma.mk i) (t₂ i) instance Pi.topologicalSpace {ι : Type} {Y : ι → Type v} [t₂ : (i : ι) → TopologicalSpace (Y i)] : TopologicalSpace ((i : ι) → Y i) := ⨅ i, induced (fun f => f i) (t₂ i) instance ULift.topologicalSpace [t : TopologicalSpace X] : TopologicalSpace (ULift.{v, u} X) := t.induced ULift.down /-! ### `Additive`, `Multiplicative` The topology on those type synonyms is inherited without change. -/ section variable [TopologicalSpace X] open Additive Multiplicative instance : TopologicalSpace (Additive X) := ‹TopologicalSpace X› instance : TopologicalSpace (Multiplicative X) := ‹TopologicalSpace X› instance [DiscreteTopology X] : DiscreteTopology (Additive X) := ‹DiscreteTopology X› instance [DiscreteTopology X] : DiscreteTopology (Multiplicative X) := ‹DiscreteTopology X› theorem continuous_ofMul : Continuous (ofMul : X → Additive X) := continuous_id theorem continuous_toMul : Continuous (toMul : Additive X → X) := continuous_id theorem continuous_ofAdd : Continuous (ofAdd : X → Multiplicative X) := continuous_id theorem continuous_toAdd : Continuous (toAdd : Multiplicative X → X) := continuous_id theorem isOpenMap_ofMul : IsOpenMap (ofMul : X → Additive X) := IsOpenMap.id theorem isOpenMap_toMul : IsOpenMap (toMul : Additive X → X) := IsOpenMap.id theorem isOpenMap_ofAdd : IsOpenMap (ofAdd : X → Multiplicative X) := IsOpenMap.id theorem isOpenMap_toAdd : IsOpenMap (toAdd : Multiplicative X → X) := IsOpenMap.id theorem isClosedMap_ofMul : IsClosedMap (ofMul : X → Additive X) := IsClosedMap.id theorem isClosedMap_toMul : IsClosedMap (toMul : Additive X → X) := IsClosedMap.id theorem isClosedMap_ofAdd : IsClosedMap (ofAdd : X → Multiplicative X) := IsClosedMap.id theorem isClosedMap_toAdd : IsClosedMap (toAdd : Multiplicative X → X) := IsClosedMap.id theorem nhds_ofMul (x : X) : 𝓝 (ofMul x) = map ofMul (𝓝 x) := rfl theorem nhds_ofAdd (x : X) : 𝓝 (ofAdd x) = map ofAdd (𝓝 x) := rfl theorem nhds_toMul (x : Additive X) : 𝓝 x.toMul = map toMul (𝓝 x) := rfl theorem nhds_toAdd (x : Multiplicative X) : 𝓝 x.toAdd = map toAdd (𝓝 x) := rfl end /-! ### Order dual The topology on this type synonym is inherited without change. -/ section variable [TopologicalSpace X] open OrderDual instance OrderDual.instTopologicalSpace : TopologicalSpace Xᵒᵈ := ‹_› instance OrderDual.instDiscreteTopology [DiscreteTopology X] : DiscreteTopology Xᵒᵈ := ‹_› theorem continuous_toDual : Continuous (toDual : X → Xᵒᵈ) := continuous_id theorem continuous_ofDual : Continuous (ofDual : Xᵒᵈ → X) := continuous_id theorem isOpenMap_toDual : IsOpenMap (toDual : X → Xᵒᵈ) := IsOpenMap.id theorem isOpenMap_ofDual : IsOpenMap (ofDual : Xᵒᵈ → X) := IsOpenMap.id theorem isClosedMap_toDual : IsClosedMap (toDual : X → Xᵒᵈ) := IsClosedMap.id theorem isClosedMap_ofDual : IsClosedMap (ofDual : Xᵒᵈ → X) := IsClosedMap.id theorem nhds_toDual (x : X) : 𝓝 (toDual x) = map toDual (𝓝 x) := rfl theorem nhds_ofDual (x : X) : 𝓝 (ofDual x) = map ofDual (𝓝 x) := rfl variable [Preorder X] {x : X} instance OrderDual.instNeBotNhdsWithinIoi [(𝓝[<] x).NeBot] : (𝓝[>] toDual x).NeBot := ‹_› instance OrderDual.instNeBotNhdsWithinIio [(𝓝[>] x).NeBot] : (𝓝[<] toDual x).NeBot := ‹_› end theorem Quotient.preimage_mem_nhds [TopologicalSpace X] [s : Setoid X] {V : Set <\| Quotient s} {x : X} (hs : V ∈ 𝓝 (Quotient.mk' x)) : Quotient.mk' ⁻¹' V ∈ 𝓝 x := preimage_nhds_coinduced hs /-- The image of a dense set under `Quotient.mk'` is a dense set. -/ theorem Dense.quotient [Setoid X] [TopologicalSpace X] {s : Set X} (H : Dense s) : Dense (Quotient.mk' '' s) := Quotient.mk''_surjective.denseRange.dense_image continuous_coinduced_rng H /-- The composition of `Quotient.mk'` and a function with dense range has dense range. -/ theorem DenseRange.quotient [Setoid X] [TopologicalSpace X] {f : Y → X} (hf : DenseRange f) : DenseRange (Quotient.mk' ∘ f) := Quotient.mk''_surjective.denseRange.comp hf continuous_coinduced_rng theorem continuous_map_of_le {α : Type} [TopologicalSpace α] {s t : Setoid α} (h : s ≤ t) : Continuous (Setoid.map_of_le h) := continuous_coinduced_rng theorem continuous_map_sInf {α : Type} [TopologicalSpace α] {S : Set (Setoid α)} {s : Setoid α} (h : s ∈ S) : Continuous (Setoid.map_sInf h) := continuous_coinduced_rng instance {p : X → Prop} [TopologicalSpace X] [DiscreteTopology X] : DiscreteTopology (Subtype p) := ⟨bot_unique fun s _ => ⟨(↑) '' s, isOpen_discrete _, preimage_image_eq _ Subtype.val_injective⟩⟩ instance Sum.discreteTopology [TopologicalSpace X] [TopologicalSpace Y] [h : DiscreteTopology X] [hY : DiscreteTopology Y] : DiscreteTopology (X ⊕ Y) := ⟨sup_eq_bot_iff.2 <\| by simp [h.eq_bot, hY.eq_bot]⟩ instance Sigma.discreteTopology {ι : Type} {Y : ι → Type v} [∀ i, TopologicalSpace (Y i)] [h : ∀ i, DiscreteTopology (Y i)] : DiscreteTopology (Sigma Y) := ⟨iSup_eq_bot.2 fun _ => by simp only [(h _).eq_bot, coinduced_bot]⟩ @[simp] lemma comap_nhdsWithin_range {α β} [TopologicalSpace β] (f : α → β) (y : β) : comap f (𝓝[range f] y) = comap f (𝓝 y) := comap_inf_principal_range section Top variable [TopologicalSpace X] /- The 𝓝 filter and the subspace topology. -/ theorem mem_nhds_subtype (s : Set X) (x : { x // x ∈ s }) (t : Set { x // x ∈ s }) : t ∈ 𝓝 x ↔ ∃ u ∈ 𝓝 (x : X), Subtype.val ⁻¹' u ⊆ t := mem_nhds_induced _ x t theorem nhds_subtype (s : Set X) (x : { x // x ∈ s }) : 𝓝 x = comap (↑) (𝓝 (x : X)) := nhds_induced _ x lemma nhds_subtype_eq_comap_nhdsWithin (s : Set X) (x : { x // x ∈ s }) : 𝓝 x = comap (↑) (𝓝[s] (x : X)) := by rw [nhds_subtype, ← comap_nhdsWithin_range, Subtype.range_val] theorem nhdsWithin_subtype_eq_bot_iff {s t : Set X} {x : s} : 𝓝[((↑) : s → X) ⁻¹' t] x = ⊥ ↔ 𝓝[t] (x : X) ⊓ 𝓟 s = ⊥ := by rw [inf_principal_eq_bot_iff_comap, nhdsWithin, nhdsWithin, comap_inf, comap_principal, nhds_induced] theorem nhds_ne_subtype_eq_bot_iff {S : Set X} {x : S} : 𝓝[≠] x = ⊥ ↔ 𝓝[≠] (x : X) ⊓ 𝓟 S = ⊥ := by rw [← nhdsWithin_subtype_eq_bot_iff, preimage_compl, ← image_singleton, Subtype.coe_injective.preimage_image] theorem nhds_ne_subtype_neBot_iff {S : Set X} {x : S} : (𝓝[≠] x).NeBot ↔ (𝓝[≠] (x : X) ⊓ 𝓟 S).NeBot := by rw [neBot_iff, neBot_iff, not_iff_not, nhds_ne_subtype_eq_bot_iff] theorem discreteTopology_subtype_iff {S : Set X} : DiscreteTopology S ↔ ∀ x ∈ S, 𝓝[≠] x ⊓ 𝓟 S = ⊥ := by simp_rw [discreteTopology_iff_nhds_ne, SetCoe.forall', nhds_ne_subtype_eq_bot_iff] end Top /-- A type synonym equipped with the topology whose open sets are the empty set and the sets with finite complements. -/ def CofiniteTopology (X : Type) := X namespace CofiniteTopology /-- The identity equivalence between `` and `CofiniteTopology `. -/ def of : X ≃ CofiniteTopology X := Equiv.refl X instance [Inhabited X] : Inhabited (CofiniteTopology X) where default := of default instance : TopologicalSpace (CofiniteTopology X) where IsOpen s := s.Nonempty → Set.Finite sᶜ isOpen_univ := by simp isOpen_inter s t := by rintro hs ht ⟨x, hxs, hxt⟩ rw [compl_inter] exact (hs ⟨x, hxs⟩).union (ht ⟨x, hxt⟩) isOpen_sUnion := by rintro s h ⟨x, t, hts, hzt⟩ rw [compl_sUnion] exact Finite.sInter (mem_image_of_mem _ hts) (h t hts ⟨x, hzt⟩) theorem isOpen_iff {s : Set (CofiniteTopology X)} : IsOpen s ↔ s.Nonempty → sᶜ.Finite := Iff.rfl theorem isOpen_iff' {s : Set (CofiniteTopology X)} : IsOpen s ↔ s = ∅ ∨ sᶜ.Finite := by simp only [isOpen_iff, nonempty_iff_ne_empty, or_iff_not_imp_left] theorem isClosed_iff {s : Set (CofiniteTopology X)} : IsClosed s ↔ s = univ ∨ s.Finite := by simp only [← isOpen_compl_iff, isOpen_iff', compl_compl, compl_empty_iff] theorem nhds_eq (x : CofiniteTopology X) : 𝓝 x = pure x ⊔ cofinite := by ext U rw [mem_nhds_iff] constructor · rintro ⟨V, hVU, V_op, haV⟩ exact mem_sup.mpr ⟨hVU haV, mem_of_superset (V_op ⟨_, haV⟩) hVU⟩ · rintro ⟨hU : x ∈ U, hU' : Uᶜ.Finite⟩ exact ⟨U, Subset.rfl, fun _ => hU', hU⟩ theorem mem_nhds_iff {x : CofiniteTopology X} {s : Set (CofiniteTopology X)} : s ∈ 𝓝 x ↔ x ∈ s ∧ sᶜ.Finite := by simp [nhds_eq] end CofiniteTopology end Constructions section Prod variable [TopologicalSpace X] [TopologicalSpace Y] theorem MapClusterPt.curry_prodMap {α β : Type} {f : α → X} {g : β → Y} {la : Filter α} {lb : Filter β} {x : X} {y : Y} (hf : MapClusterPt x la f) (hg : MapClusterPt y lb g) : MapClusterPt (x, y) (la.curry lb) (.map f g) := by rw [mapClusterPt_iff_frequently] at hf hg rw [((𝓝 x).basis_sets.prod_nhds (𝓝 y).basis_sets).mapClusterPt_iff_frequently] rintro ⟨s, t⟩ ⟨hs, ht⟩ rw [frequently_curry_iff] exact (hf s hs).mono fun x hx ↦ (hg t ht).mono fun y hy ↦ ⟨hx, hy⟩ theorem MapClusterPt.prodMap {α β : Type} {f : α → X} {g : β → Y} {la : Filter α} {lb : Filter β} {x : X} {y : Y} (hf : MapClusterPt x la f) (hg : MapClusterPt y lb g) : MapClusterPt (x, y) (la ×ˢ lb) (.map f g) := (hf.curry_prodMap hg).mono <\| map_mono curry_le_prod end Prod section Bool lemma continuous_bool_rng [TopologicalSpace X] {f : X → Bool} (b : Bool) : Continuous f ↔ IsClopen (f ⁻¹' {b}) := by rw [continuous_discrete_rng, Bool.forall_bool' b, IsClopen, ← isOpen_compl_iff, ← preimage_compl, Bool.compl_singleton, and_comm] end Bool section Subtype variable [TopologicalSpace X] [TopologicalSpace Y] {p : X → Prop} lemma Topology.IsInducing.subtypeVal {t : Set Y} : IsInducing ((↑) : t → Y) := ⟨rfl⟩ @[deprecated (since := "2024-10-28")] alias inducing_subtype_val := IsInducing.subtypeVal lemma Topology.IsInducing.of_codRestrict {f : X → Y} {t : Set Y} (ht : ∀ x, f x ∈ t) (h : IsInducing (t.codRestrict f ht)) : IsInducing f := subtypeVal.comp h @[deprecated (since := "2024-10-28")] alias Inducing.of_codRestrict := IsInducing.of_codRestrict lemma Topology.IsEmbedding.subtypeVal : IsEmbedding ((↑) : Subtype p → X) := ⟨.subtypeVal, Subtype.coe_injective⟩ @[deprecated (since := "2024-10-26")] alias embedding_subtype_val := IsEmbedding.subtypeVal theorem Topology.IsClosedEmbedding.subtypeVal (h : IsClosed {a \| p a}) : IsClosedEmbedding ((↑) : Subtype p → X) := ⟨.subtypeVal, by rwa [Subtype.range_coe_subtype]⟩ @[continuity, fun_prop] theorem continuous_subtype_val : Continuous (@Subtype.val X p) := continuous_induced_dom theorem Continuous.subtype_val {f : Y → Subtype p} (hf : Continuous f) : Continuous fun x => (f x : X) := continuous_subtype_val.comp hf theorem IsOpen.isOpenEmbedding_subtypeVal {s : Set X} (hs : IsOpen s) : IsOpenEmbedding ((↑) : s → X) := ⟨.subtypeVal, (@Subtype.range_coe _ s).symm ▸ hs⟩ theorem IsOpen.isOpenMap_subtype_val {s : Set X} (hs : IsOpen s) : IsOpenMap ((↑) : s → X) := hs.isOpenEmbedding_subtypeVal.isOpenMap theorem IsOpenMap.restrict {f : X → Y} (hf : IsOpenMap f) {s : Set X} (hs : IsOpen s) : IsOpenMap (s.restrict f) := hf.comp hs.isOpenMap_subtype_val lemma IsClosed.isClosedEmbedding_subtypeVal {s : Set X} (hs : IsClosed s) : IsClosedEmbedding ((↑) : s → X) := .subtypeVal hs theorem IsClosed.isClosedMap_subtype_val {s : Set X} (hs : IsClosed s) : IsClosedMap ((↑) : s → X) := hs.isClosedEmbedding_subtypeVal.isClosedMap @[continuity, fun_prop] theorem Continuous.subtype_mk {f : Y → X} (h : Continuous f) (hp : ∀ x, p (f x)) : Continuous fun x => (⟨f x, hp x⟩ : Subtype p) := continuous_induced_rng.2 h theorem Continuous.subtype_map {f : X → Y} (h : Continuous f) {q : Y → Prop} (hpq : ∀ x, p x → q (f x)) : Continuous (Subtype.map f hpq) := (h.comp continuous_subtype_val).subtype_mk _ theorem continuous_inclusion {s t : Set X} (h : s ⊆ t) : Continuous (inclusion h) := continuous_id.subtype_map h theorem continuousAt_subtype_val {p : X → Prop} {x : Subtype p} : ContinuousAt ((↑) : Subtype p → X) x := continuous_subtype_val.continuousAt theorem Subtype.dense_iff {s : Set X} {t : Set s} : Dense t ↔ s ⊆ closure ((↑) '' t) := by rw [IsInducing.subtypeVal.dense_iff, SetCoe.forall] rfl theorem map_nhds_subtype_val {s : Set X} (x : s) : map ((↑) : s → X) (𝓝 x) = 𝓝[s] ↑x := by rw [IsInducing.subtypeVal.map_nhds_eq, Subtype.range_val] theorem map_nhds_subtype_coe_eq_nhds {x : X} (hx : p x) (h : ∀ᶠ x in 𝓝 x, p x) : map ((↑) : Subtype p → X) (𝓝 ⟨x, hx⟩) = 𝓝 x := map_nhds_induced_of_mem <\| by rw [Subtype.range_val]; exact h theorem nhds_subtype_eq_comap {x : X} {h : p x} : 𝓝 (⟨x, h⟩ : Subtype p) = comap (↑) (𝓝 x) := nhds_induced _ _ theorem tendsto_subtype_rng {Y : Type} {p : X → Prop} {l : Filter Y} {f : Y → Subtype p} : ∀ {x : Subtype p}, Tendsto f l (𝓝 x) ↔ Tendsto (fun x => (f x : X)) l (𝓝 (x : X)) \| ⟨a, ha⟩ => by rw [nhds_subtype_eq_comap, tendsto_comap_iff]; rfl theorem closure_subtype {x : { a // p a }} {s : Set { a // p a }} : x ∈ closure s ↔ (x : X) ∈ closure (((↑) : _ → X) '' s) := closure_induced @[simp] theorem continuousAt_codRestrict_iff {f : X → Y} {t : Set Y} (h1 : ∀ x, f x ∈ t) {x : X} : ContinuousAt (codRestrict f t h1) x ↔ ContinuousAt f x := IsInducing.subtypeVal.continuousAt_iff alias ⟨_, ContinuousAt.codRestrict⟩ := continuousAt_codRestrict_iff theorem ContinuousAt.restrict {f : X → Y} {s : Set X} {t : Set Y} (h1 : MapsTo f s t) {x : s} (h2 : ContinuousAt f x) : ContinuousAt (h1.restrict f s t) x := (h2.comp continuousAt_subtype_val).codRestrict _ theorem ContinuousAt.restrictPreimage {f : X → Y} {s : Set Y} {x : f ⁻¹' s} (h : ContinuousAt f x) : ContinuousAt (s.restrictPreimage f) x := h.restrict _ @[continuity, fun_prop] theorem Continuous.codRestrict {f : X → Y} {s : Set Y} (hf : Continuous f) (hs : ∀ a, f a ∈ s) : Continuous (s.codRestrict f hs) := hf.subtype_mk hs @[continuity, fun_prop] theorem Continuous.restrict {f : X → Y} {s : Set X} {t : Set Y} (h1 : MapsTo f s t) (h2 : Continuous f) : Continuous (h1.restrict f s t) := (h2.comp continuous_subtype_val).codRestrict _ @[continuity, fun_prop] theorem Continuous.restrictPreimage {f : X → Y} {s : Set Y} (h : Continuous f) : Continuous (s.restrictPreimage f) := h.restrict _ lemma Topology.IsEmbedding.restrict {f : X → Y} (hf : IsEmbedding f) {s : Set X} {t : Set Y} (H : s.MapsTo f t) : IsEmbedding H.restrict := .of_comp (hf.continuous.restrict H) continuous_subtype_val (hf.comp .subtypeVal) lemma Topology.IsOpenEmbedding.restrict {f : X → Y} (hf : IsOpenEmbedding f) {s : Set X} {t : Set Y} (H : s.MapsTo f t) (hs : IsOpen s) : IsOpenEmbedding H.restrict := ⟨hf.isEmbedding.restrict H, (by rw [MapsTo.range_restrict] exact continuous_subtype_val.1 _ (hf.isOpenMap _ hs))⟩ theorem Topology.IsInducing.codRestrict {e : X → Y} (he : IsInducing e) {s : Set Y} (hs : ∀ x, e x ∈ s) : IsInducing (codRestrict e s hs) := he.of_comp (he.continuous.codRestrict hs) continuous_subtype_val @[deprecated (since := "2024-10-28")] alias Inducing.codRestrict := IsInducing.codRestrict protected lemma Topology.IsEmbedding.codRestrict {e : X → Y} (he : IsEmbedding e) (s : Set Y) (hs : ∀ x, e x ∈ s) : IsEmbedding (codRestrict e s hs) := he.of_comp (he.continuous.codRestrict hs) continuous_subtype_val @[deprecated (since := "2024-10-26")] alias Embedding.codRestrict := IsEmbedding.codRestrict variable {s t : Set X} protected lemma Topology.IsEmbedding.inclusion (h : s ⊆ t) : IsEmbedding (inclusion h) := IsEmbedding.subtypeVal.codRestrict _ _ protected lemma Topology.IsOpenEmbedding.inclusion (hst : s ⊆ t) (hs : IsOpen (t ↓∩ s)) : IsOpenEmbedding (inclusion hst) where toIsEmbedding := .inclusion _ isOpen_range := by rwa [range_inclusion] protected lemma Topology.IsClosedEmbedding.inclusion (hst : s ⊆ t) (hs : IsClosed (t ↓∩ s)) : IsClosedEmbedding (inclusion hst) where toIsEmbedding := .inclusion _ isClosed_range := by rwa [range_inclusion] @[deprecated (since := "2024-10-26")] alias embedding_inclusion := IsEmbedding.inclusion /-- Let `s, t ⊆ X` be two subsets of a topological space `X`. If `t ⊆ s` and the topology induced by `X`on `s` is discrete, then also the topology induces on `t` is discrete. -/ theorem DiscreteTopology.of_subset {X : Type} [TopologicalSpace X] {s t : Set X} (_ : DiscreteTopology s) (ts : t ⊆ s) : DiscreteTopology t := (IsEmbedding.inclusion ts).discreteTopology /-- Let `s` be a discrete subset of a topological space. Then the preimage of `s` by a continuous injective map is also discrete. -/ theorem DiscreteTopology.preimage_of_continuous_injective {X Y : Type} [TopologicalSpace X] [TopologicalSpace Y] (s : Set Y) [DiscreteTopology s] {f : X → Y} (hc : Continuous f) (hinj : Function.Injective f) : DiscreteTopology (f ⁻¹' s) := DiscreteTopology.of_continuous_injective (β := s) (Continuous.restrict (by exact fun _ x ↦ x) hc) ((MapsTo.restrict_inj _).mpr hinj.injOn) /-- If `f : X → Y` is a quotient map, then its restriction to the preimage of an open set is a quotient map too. -/ theorem Topology.IsQuotientMap.restrictPreimage_isOpen {f : X → Y} (hf : IsQuotientMap f) {s : Set Y} (hs : IsOpen s) : IsQuotientMap (s.restrictPreimage f) := by refine isQuotientMap_iff.2 ⟨hf.surjective.restrictPreimage _, fun U ↦ ?_⟩ rw [hs.isOpenEmbedding_subtypeVal.isOpen_iff_image_isOpen, ← hf.isOpen_preimage, (hs.preimage hf.continuous).isOpenEmbedding_subtypeVal.isOpen_iff_image_isOpen,	image_val_preimage_restrictPreimage] @[deprecated (since := "2024-10-22")] alias QuotientMap.restrictPreimage_isOpen := IsQuotientMap.restrictPreimage_isOpen open scoped Set.Notation in lemma isClosed_preimage_val {s t : Set X} : IsClosed (s ↓∩ t) ↔ s ∩ closure (s ∩ t) ⊆ t := by rw [← closure_eq_iff_isClosed, IsEmbedding.subtypeVal.closure_eq_preimage_closure_image, ← Subtype.val_injective.image_injective.eq_iff, Subtype.image_preimage_coe, Subtype.image_preimage_coe, subset_antisymm_iff, and_iff_left, Set.subset_inter_iff,	Mathlib/Topology/Constructions.lean	492	501
/- Copyright (c) 2020 Nicolò Cavalleri. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Nicolò Cavalleri, Yury Kudryashov -/ import Mathlib.Geometry.Manifold.ContMDiffMap import Mathlib.Geometry.Manifold.MFDeriv.UniqueDifferential /-! # Diffeomorphisms This file implements diffeomorphisms. ## Definitions * `Diffeomorph I I' M M' n`: `n`-times continuously differentiable diffeomorphism between `M` and `M'` with respect to I and I'; we do not introduce a separate definition for the case `n = ∞`; we use notation instead. * `Diffeomorph.toHomeomorph`: reinterpret a diffeomorphism as a homeomorphism. * `ContinuousLinearEquiv.toDiffeomorph`: reinterpret a continuous equivalence as a diffeomorphism. * `ModelWithCorners.transDiffeomorph`: compose a given `ModelWithCorners` with a diffeomorphism between the old and the new target spaces. Useful, e.g, to turn any finite dimensional manifold into a manifold modelled on a Euclidean space. * `Diffeomorph.toTransDiffeomorph`: the identity diffeomorphism between `M` with model `I` and `M` with model `I.trans_diffeomorph e`. This file also provides diffeomorphisms related to products and disjoint unions. * `Diffeomorph.prodCongr`: the product of two diffeomorphisms * `Diffeomorph.prodComm`: `M × N` is diffeomorphic to `N × M` * `Diffeomorph.prodAssoc`: `(M × N) × N'` is diffeomorphic to `M × (N × N')` * `Diffeomorph.sumCongr`: the disjoint union of two diffeomorphisms * `Diffeomorph.sumComm`: `M ⊕ M'` is diffeomorphic to `M' × M` * `Diffeomorph.sumAssoc`: `(M ⊕ N) ⊕ P` is diffeomorphic to `M ⊕ (N ⊕ P)` * `Diffeomorph.sumEmpty`: `M ⊕ ∅` is diffeomorphic to `M` ## Notations * `M ≃ₘ^n⟮I, I'⟯ M'` := `Diffeomorph I J M N n` * `M ≃ₘ⟮I, I'⟯ M'` := `Diffeomorph I J M N ∞` * `E ≃ₘ^n[𝕜] E'` := `E ≃ₘ^n⟮𝓘(𝕜, E), 𝓘(𝕜, E')⟯ E'` * `E ≃ₘ[𝕜] E'` := `E ≃ₘ⟮𝓘(𝕜, E), 𝓘(𝕜, E')⟯ E'` ## Implementation notes This notion of diffeomorphism is needed although there is already a notion of structomorphism because structomorphisms do not allow the model spaces `H` and `H'` of the two manifolds to be different, i.e. for a structomorphism one has to impose `H = H'` which is often not the case in practice. ## Keywords diffeomorphism, manifold -/ open scoped Manifold Topology ContDiff open Function Set variable {𝕜 : Type} [NontriviallyNormedField 𝕜] {E : Type} [NormedAddCommGroup E] [NormedSpace 𝕜 E] {E' : Type} [NormedAddCommGroup E'] [NormedSpace 𝕜 E'] {F : Type} [NormedAddCommGroup F] [NormedSpace 𝕜 F] {H : Type} [TopologicalSpace H] {H' : Type} [TopologicalSpace H'] {G : Type} [TopologicalSpace G] {G' : Type} [TopologicalSpace G'] {I : ModelWithCorners 𝕜 E H} {I' : ModelWithCorners 𝕜 E' H'} {J : ModelWithCorners 𝕜 F G} {J' : ModelWithCorners 𝕜 F G'} variable {M : Type} [TopologicalSpace M] [ChartedSpace H M] {M' : Type} [TopologicalSpace M'] [ChartedSpace H' M'] {N : Type} [TopologicalSpace N] [ChartedSpace G N] {N' : Type} [TopologicalSpace N'] [ChartedSpace G' N'] {n : WithTop ℕ∞} section Defs variable (I I' M M' n) /-- `n`-times continuously differentiable diffeomorphism between `M` and `M'` with respect to `I` and `I'`, denoted as `M ≃ₘ^n⟮I, I'⟯ M'` (in the `Manifold` namespace). -/ structure Diffeomorph extends M ≃ M' where protected contMDiff_toFun : ContMDiff I I' n toEquiv protected contMDiff_invFun : ContMDiff I' I n toEquiv.symm end Defs @[inherit_doc] scoped[Manifold] notation M " ≃ₘ^" n:1000 "⟮" I ", " J "⟯ " N => Diffeomorph I J M N n /-- Infinitely differentiable diffeomorphism between `M` and `M'` with respect to `I` and `I'`. -/ scoped[Manifold] notation M " ≃ₘ⟮" I ", " J "⟯ " N => Diffeomorph I J M N ∞ /-- `n`-times continuously differentiable diffeomorphism between `E` and `E'`. -/ scoped[Manifold] notation E " ≃ₘ^" n:1000 "[" 𝕜 "] " E' => Diffeomorph 𝓘(𝕜, E) 𝓘(𝕜, E') E E' n /-- Infinitely differentiable diffeomorphism between `E` and `E'`. -/ scoped[Manifold] notation3 E " ≃ₘ[" 𝕜 "] " E' => Diffeomorph 𝓘(𝕜, E) 𝓘(𝕜, E') E E' ∞ namespace Diffeomorph theorem toEquiv_injective : Injective (Diffeomorph.toEquiv : (M ≃ₘ^n⟮I, I'⟯ M') → M ≃ M') \| ⟨_, _, _⟩, ⟨_, _, _⟩, rfl => rfl instance : EquivLike (M ≃ₘ^n⟮I, I'⟯ M') M M' where coe Φ := Φ.toEquiv inv Φ := Φ.toEquiv.symm left_inv Φ := Φ.left_inv right_inv Φ := Φ.right_inv coe_injective' _ _ h _ := toEquiv_injective <\| DFunLike.ext' h /-- Interpret a diffeomorphism as a `ContMDiffMap`. -/ @[coe] def toContMDiffMap (Φ : M ≃ₘ^n⟮I, I'⟯ M') : C^n⟮I, M; I', M'⟯ := ⟨Φ, Φ.contMDiff_toFun⟩ instance : Coe (M ≃ₘ^n⟮I, I'⟯ M') C^n⟮I, M; I', M'⟯ := ⟨toContMDiffMap⟩ @[continuity] protected theorem continuous (h : M ≃ₘ^n⟮I, I'⟯ M') : Continuous h := h.contMDiff_toFun.continuous protected theorem contMDiff (h : M ≃ₘ^n⟮I, I'⟯ M') : ContMDiff I I' n h := h.contMDiff_toFun protected theorem contMDiffAt (h : M ≃ₘ^n⟮I, I'⟯ M') {x} : ContMDiffAt I I' n h x := h.contMDiff.contMDiffAt protected theorem contMDiffWithinAt (h : M ≃ₘ^n⟮I, I'⟯ M') {s x} : ContMDiffWithinAt I I' n h s x := h.contMDiffAt.contMDiffWithinAt -- Porting note (https://github.com/leanprover-community/mathlib4/issues/11215): TODO: should use `E ≃ₘ^n[𝕜] F` notation protected theorem contDiff (h : E ≃ₘ^n⟮𝓘(𝕜, E), 𝓘(𝕜, E')⟯ E') : ContDiff 𝕜 n h := h.contMDiff.contDiff @[deprecated (since := "2024-11-21")] alias smooth := Diffeomorph.contDiff protected theorem mdifferentiable (h : M ≃ₘ^n⟮I, I'⟯ M') (hn : 1 ≤ n) : MDifferentiable I I' h := h.contMDiff.mdifferentiable hn protected theorem mdifferentiableOn (h : M ≃ₘ^n⟮I, I'⟯ M') (s : Set M) (hn : 1 ≤ n) : MDifferentiableOn I I' h s := (h.mdifferentiable hn).mdifferentiableOn @[simp] theorem coe_toEquiv (h : M ≃ₘ^n⟮I, I'⟯ M') : ⇑h.toEquiv = h := rfl @[simp, norm_cast] theorem coe_coe (h : M ≃ₘ^n⟮I, I'⟯ M') : ⇑(h : C^n⟮I, M; I', M'⟯) = h := rfl @[simp] theorem toEquiv_inj {h h' : M ≃ₘ^n⟮I, I'⟯ M'} : h.toEquiv = h'.toEquiv ↔ h = h' := toEquiv_injective.eq_iff /-- Coercion to function `fun h : M ≃ₘ^n⟮I, I'⟯ M' ↦ (h : M → M')` is injective. -/ theorem coeFn_injective : Injective ((↑) : (M ≃ₘ^n⟮I, I'⟯ M') → (M → M')) := DFunLike.coe_injective @[ext] theorem ext {h h' : M ≃ₘ^n⟮I, I'⟯ M'} (Heq : ∀ x, h x = h' x) : h = h' := coeFn_injective <\| funext Heq instance : ContinuousMapClass (M ≃ₘ⟮I, J⟯ N) M N where map_continuous f := f.continuous section variable (M I n) /-- Identity map as a diffeomorphism. -/ protected def refl : M ≃ₘ^n⟮I, I⟯ M where contMDiff_toFun := contMDiff_id contMDiff_invFun := contMDiff_id toEquiv := Equiv.refl M @[simp] theorem refl_toEquiv : (Diffeomorph.refl I M n).toEquiv = Equiv.refl _ := rfl @[simp] theorem coe_refl : ⇑(Diffeomorph.refl I M n) = id := rfl end /-- Composition of two diffeomorphisms. -/ @[trans] protected def trans (h₁ : M ≃ₘ^n⟮I, I'⟯ M') (h₂ : M' ≃ₘ^n⟮I', J⟯ N) : M ≃ₘ^n⟮I, J⟯ N where contMDiff_toFun := h₂.contMDiff.comp h₁.contMDiff contMDiff_invFun := h₁.contMDiff_invFun.comp h₂.contMDiff_invFun toEquiv := h₁.toEquiv.trans h₂.toEquiv @[simp] theorem trans_refl (h : M ≃ₘ^n⟮I, I'⟯ M') : h.trans (Diffeomorph.refl I' M' n) = h := ext fun _ => rfl @[simp] theorem refl_trans (h : M ≃ₘ^n⟮I, I'⟯ M') : (Diffeomorph.refl I M n).trans h = h := ext fun _ => rfl @[simp] theorem coe_trans (h₁ : M ≃ₘ^n⟮I, I'⟯ M') (h₂ : M' ≃ₘ^n⟮I', J⟯ N) : ⇑(h₁.trans h₂) = h₂ ∘ h₁ := rfl /-- Inverse of a diffeomorphism. -/ @[symm] protected def symm (h : M ≃ₘ^n⟮I, J⟯ N) : N ≃ₘ^n⟮J, I⟯ M where contMDiff_toFun := h.contMDiff_invFun contMDiff_invFun := h.contMDiff_toFun toEquiv := h.toEquiv.symm @[simp] theorem apply_symm_apply (h : M ≃ₘ^n⟮I, J⟯ N) (x : N) : h (h.symm x) = x := h.toEquiv.apply_symm_apply x @[simp] theorem symm_apply_apply (h : M ≃ₘ^n⟮I, J⟯ N) (x : M) : h.symm (h x) = x := h.toEquiv.symm_apply_apply x @[simp] theorem symm_refl : (Diffeomorph.refl I M n).symm = Diffeomorph.refl I M n := ext fun _ => rfl @[simp] theorem self_trans_symm (h : M ≃ₘ^n⟮I, J⟯ N) : h.trans h.symm = Diffeomorph.refl I M n := ext h.symm_apply_apply @[simp] theorem symm_trans_self (h : M ≃ₘ^n⟮I, J⟯ N) : h.symm.trans h = Diffeomorph.refl J N n := ext h.apply_symm_apply @[simp] theorem symm_trans' (h₁ : M ≃ₘ^n⟮I, I'⟯ M') (h₂ : M' ≃ₘ^n⟮I', J⟯ N) : (h₁.trans h₂).symm = h₂.symm.trans h₁.symm := rfl @[simp] theorem symm_toEquiv (h : M ≃ₘ^n⟮I, J⟯ N) : h.symm.toEquiv = h.toEquiv.symm := rfl @[simp, mfld_simps] theorem toEquiv_coe_symm (h : M ≃ₘ^n⟮I, J⟯ N) : ⇑h.toEquiv.symm = h.symm := rfl theorem image_eq_preimage (h : M ≃ₘ^n⟮I, J⟯ N) (s : Set M) : h '' s = h.symm ⁻¹' s := h.toEquiv.image_eq_preimage s theorem symm_image_eq_preimage (h : M ≃ₘ^n⟮I, J⟯ N) (s : Set N) : h.symm '' s = h ⁻¹' s := h.symm.image_eq_preimage s @[simp, mfld_simps] nonrec theorem range_comp {α} (h : M ≃ₘ^n⟮I, J⟯ N) (f : α → M) : range (h ∘ f) = h.symm ⁻¹' range f := by rw [range_comp, image_eq_preimage] @[simp] theorem image_symm_image (h : M ≃ₘ^n⟮I, J⟯ N) (s : Set N) : h '' (h.symm '' s) = s := h.toEquiv.image_symm_image s @[simp] theorem symm_image_image (h : M ≃ₘ^n⟮I, J⟯ N) (s : Set M) : h.symm '' (h '' s) = s := h.toEquiv.symm_image_image s /-- A diffeomorphism is a homeomorphism. -/ def toHomeomorph (h : M ≃ₘ^n⟮I, J⟯ N) : M ≃ₜ N := ⟨h.toEquiv, h.continuous, h.symm.continuous⟩ @[simp] theorem toHomeomorph_toEquiv (h : M ≃ₘ^n⟮I, J⟯ N) : h.toHomeomorph.toEquiv = h.toEquiv := rfl @[simp] theorem symm_toHomeomorph (h : M ≃ₘ^n⟮I, J⟯ N) : h.symm.toHomeomorph = h.toHomeomorph.symm := rfl @[simp] theorem coe_toHomeomorph (h : M ≃ₘ^n⟮I, J⟯ N) : ⇑h.toHomeomorph = h := rfl @[simp] theorem coe_toHomeomorph_symm (h : M ≃ₘ^n⟮I, J⟯ N) : ⇑h.toHomeomorph.symm = h.symm := rfl @[simp] theorem contMDiffWithinAt_comp_diffeomorph_iff {m} (h : M ≃ₘ^n⟮I, J⟯ N) {f : N → M'} {s x} (hm : m ≤ n) : ContMDiffWithinAt I I' m (f ∘ h) s x ↔ ContMDiffWithinAt J I' m f (h.symm ⁻¹' s) (h x) := by constructor · intro Hfh rw [← h.symm_apply_apply x] at Hfh simpa only [Function.comp_def, h.apply_symm_apply] using Hfh.comp (h x) (h.symm.contMDiffWithinAt.of_le hm) (mapsTo_preimage _ _) · rw [← h.image_eq_preimage] exact fun hf => hf.comp x (h.contMDiffWithinAt.of_le hm) (mapsTo_image _ _) @[simp] theorem contMDiffOn_comp_diffeomorph_iff {m} (h : M ≃ₘ^n⟮I, J⟯ N) {f : N → M'} {s} (hm : m ≤ n) : ContMDiffOn I I' m (f ∘ h) s ↔ ContMDiffOn J I' m f (h.symm ⁻¹' s) := h.toEquiv.forall_congr fun {_} => by simp only [hm, coe_toEquiv, h.symm_apply_apply, contMDiffWithinAt_comp_diffeomorph_iff, mem_preimage] @[simp] theorem contMDiffAt_comp_diffeomorph_iff {m} (h : M ≃ₘ^n⟮I, J⟯ N) {f : N → M'} {x} (hm : m ≤ n) : ContMDiffAt I I' m (f ∘ h) x ↔ ContMDiffAt J I' m f (h x) := h.contMDiffWithinAt_comp_diffeomorph_iff hm @[simp] theorem contMDiff_comp_diffeomorph_iff {m} (h : M ≃ₘ^n⟮I, J⟯ N) {f : N → M'} (hm : m ≤ n) : ContMDiff I I' m (f ∘ h) ↔ ContMDiff J I' m f := h.toEquiv.forall_congr fun _ ↦ h.contMDiffAt_comp_diffeomorph_iff hm @[simp] theorem contMDiffWithinAt_diffeomorph_comp_iff {m} (h : M ≃ₘ^n⟮I, J⟯ N) {f : M' → M} (hm : m ≤ n) {s x} : ContMDiffWithinAt I' J m (h ∘ f) s x ↔ ContMDiffWithinAt I' I m f s x := ⟨fun Hhf => by simpa only [Function.comp_def, h.symm_apply_apply] using (h.symm.contMDiffAt.of_le hm).comp_contMDiffWithinAt _ Hhf, fun Hf => (h.contMDiffAt.of_le hm).comp_contMDiffWithinAt _ Hf⟩ @[simp] theorem contMDiffAt_diffeomorph_comp_iff {m} (h : M ≃ₘ^n⟮I, J⟯ N) {f : M' → M} (hm : m ≤ n) {x} : ContMDiffAt I' J m (h ∘ f) x ↔ ContMDiffAt I' I m f x := h.contMDiffWithinAt_diffeomorph_comp_iff hm @[simp] theorem contMDiffOn_diffeomorph_comp_iff {m} (h : M ≃ₘ^n⟮I, J⟯ N) {f : M' → M} (hm : m ≤ n) {s} : ContMDiffOn I' J m (h ∘ f) s ↔ ContMDiffOn I' I m f s := forall₂_congr fun _ _ => h.contMDiffWithinAt_diffeomorph_comp_iff hm @[simp] theorem contMDiff_diffeomorph_comp_iff {m} (h : M ≃ₘ^n⟮I, J⟯ N) {f : M' → M} (hm : m ≤ n) : ContMDiff I' J m (h ∘ f) ↔ ContMDiff I' I m f := forall_congr' fun _ => h.contMDiffWithinAt_diffeomorph_comp_iff hm theorem toPartialHomeomorph_mdifferentiable (h : M ≃ₘ^n⟮I, J⟯ N) (hn : 1 ≤ n) : h.toHomeomorph.toPartialHomeomorph.MDifferentiable I J := ⟨h.mdifferentiableOn _ hn, h.symm.mdifferentiableOn _ hn⟩ theorem uniqueMDiffOn_image_aux (h : M ≃ₘ^n⟮I, J⟯ N) (hn : 1 ≤ n) {s : Set M} (hs : UniqueMDiffOn I s) : UniqueMDiffOn J (h '' s) := by convert hs.uniqueMDiffOn_preimage (h.toPartialHomeomorph_mdifferentiable hn) simp [h.image_eq_preimage] @[simp] theorem uniqueMDiffOn_image (h : M ≃ₘ^n⟮I, J⟯ N) (hn : 1 ≤ n) {s : Set M} : UniqueMDiffOn J (h '' s) ↔ UniqueMDiffOn I s := ⟨fun hs => h.symm_image_image s ▸ h.symm.uniqueMDiffOn_image_aux hn hs, h.uniqueMDiffOn_image_aux hn⟩ @[simp] theorem uniqueMDiffOn_preimage (h : M ≃ₘ^n⟮I, J⟯ N) (hn : 1 ≤ n) {s : Set N} : UniqueMDiffOn I (h ⁻¹' s) ↔ UniqueMDiffOn J s := h.symm_image_eq_preimage s ▸ h.symm.uniqueMDiffOn_image hn -- Porting note (https://github.com/leanprover-community/mathlib4/issues/11215): TODO: should use `E ≃ₘ^n[𝕜] F` notation @[simp] theorem uniqueDiffOn_image (h : E ≃ₘ^n⟮𝓘(𝕜, E), 𝓘(𝕜, F)⟯ F) (hn : 1 ≤ n) {s : Set E} : UniqueDiffOn 𝕜 (h '' s) ↔ UniqueDiffOn 𝕜 s := by simp only [← uniqueMDiffOn_iff_uniqueDiffOn, uniqueMDiffOn_image, hn] @[simp] -- Porting note (https://github.com/leanprover-community/mathlib4/issues/11215): TODO: should use `E ≃ₘ^n[𝕜] F` notation theorem uniqueDiffOn_preimage (h : E ≃ₘ^n⟮𝓘(𝕜, E), 𝓘(𝕜, F)⟯ F) (hn : 1 ≤ n) {s : Set F} : UniqueDiffOn 𝕜 (h ⁻¹' s) ↔ UniqueDiffOn 𝕜 s := h.symm_image_eq_preimage s ▸ h.symm.uniqueDiffOn_image hn end Diffeomorph namespace ContinuousLinearEquiv variable (e : E ≃L[𝕜] E') /-- A continuous linear equivalence between normed spaces is a diffeomorphism. -/ def toDiffeomorph : E ≃ₘ[𝕜] E' where contMDiff_toFun := e.contDiff.contMDiff contMDiff_invFun := e.symm.contDiff.contMDiff toEquiv := e.toLinearEquiv.toEquiv @[simp] theorem coe_toDiffeomorph : ⇑e.toDiffeomorph = e := rfl @[simp] theorem symm_toDiffeomorph : e.symm.toDiffeomorph = e.toDiffeomorph.symm := rfl @[simp] theorem coe_toDiffeomorph_symm : ⇑e.toDiffeomorph.symm = e.symm := rfl end ContinuousLinearEquiv namespace ModelWithCorners variable (I) (e : E ≃ₘ^n⟮𝓘(𝕜, E), 𝓘(𝕜, E')⟯ E') [NeZero n] /-- Apply a diffeomorphism (e.g., a continuous linear equivalence) to the model vector space. -/ def transDiffeomorph : ModelWithCorners 𝕜 E' H where toPartialEquiv := I.toPartialEquiv.trans e.toEquiv.toPartialEquiv source_eq := by simp uniqueDiffOn' := by have hn : 1 ≤ n := ENat.one_le_iff_ne_zero_withTop.mpr (NeZero.ne n) simp [I.uniqueDiffOn, hn] target_subset_closure_interior := by simp only [PartialEquiv.trans_target, Equiv.toPartialEquiv_target, Equiv.toPartialEquiv_symm_apply, Diffeomorph.toEquiv_coe_symm, target_eq, univ_inter] change e.toHomeomorph.symm ⁻¹' _ ⊆ closure (interior (e.toHomeomorph.symm ⁻¹' (range I))) rw [← e.toHomeomorph.symm.isOpenMap.preimage_interior_eq_interior_preimage e.toHomeomorph.continuous_symm, ← e.toHomeomorph.symm.isOpenMap.preimage_closure_eq_closure_preimage e.toHomeomorph.continuous_symm] exact preimage_mono I.range_subset_closure_interior continuous_toFun := e.continuous.comp I.continuous continuous_invFun := I.continuous_symm.comp e.symm.continuous @[simp, mfld_simps] theorem coe_transDiffeomorph : ⇑(I.transDiffeomorph e) = e ∘ I := rfl @[simp, mfld_simps] theorem coe_transDiffeomorph_symm : ⇑(I.transDiffeomorph e).symm = I.symm ∘ e.symm := rfl theorem transDiffeomorph_range : range (I.transDiffeomorph e) = e '' range I := range_comp e I theorem coe_extChartAt_transDiffeomorph (x : M) : ⇑(extChartAt (I.transDiffeomorph e) x) = e ∘ extChartAt I x := rfl theorem coe_extChartAt_transDiffeomorph_symm (x : M) : ⇑(extChartAt (I.transDiffeomorph e) x).symm = (extChartAt I x).symm ∘ e.symm := rfl theorem extChartAt_transDiffeomorph_target (x : M) : (extChartAt (I.transDiffeomorph e) x).target = e.symm ⁻¹' (extChartAt I x).target := by simp only [e.range_comp, preimage_preimage, mfld_simps]; rfl end ModelWithCorners namespace Diffeomorph section variable [NeZero n] (e : E ≃ₘ^n⟮𝓘(𝕜, E), 𝓘(𝕜, F)⟯ F) instance instIsManifoldTransDiffeomorph [IsManifold I n M] : IsManifold (I.transDiffeomorph e) n M := by refine isManifold_of_contDiffOn (I.transDiffeomorph e) n M fun e₁ e₂ h₁ h₂ => ?_ refine e.contDiff.comp_contDiffOn (((contDiffGroupoid n I).compatible h₁ h₂).1.comp e.symm.contDiff.contDiffOn ?_) simp only [mapsTo_iff_subset_preimage] mfld_set_tac variable (I M) /-- The identity diffeomorphism between a manifold with model `I` and the same manifold with model `I.trans_diffeomorph e`. -/ def toTransDiffeomorph (e : E ≃ₘ^n⟮𝓘(𝕜, E), 𝓘(𝕜, F)⟯ F) : M ≃ₘ^n⟮I, I.transDiffeomorph e⟯ M where toEquiv := Equiv.refl M contMDiff_toFun x := by refine contMDiffWithinAt_iff'.2 ⟨continuousWithinAt_id, ?_⟩ refine e.contDiff.contDiffWithinAt.congr_of_mem (fun y hy ↦ ?_) ?_ · simp only [Equiv.coe_refl, id, (· ∘ ·), I.coe_extChartAt_transDiffeomorph, (extChartAt I x).right_inv hy.1] · exact ⟨(extChartAt I x).map_source (mem_extChartAt_source x), trivial, by simp only [mfld_simps]⟩ contMDiff_invFun x := by	refine contMDiffWithinAt_iff'.2 ⟨continuousWithinAt_id, ?_⟩ refine e.symm.contDiff.contDiffWithinAt.congr_of_mem (fun y hy => ?_) ?_ · simp only [mem_inter_iff, I.extChartAt_transDiffeomorph_target] at hy	Mathlib/Geometry/Manifold/Diffeomorph.lean	468	470
/- Copyright (c) 2018 Chris Hughes. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Chris Hughes, Abhimanyu Pallavi Sudhir, Jean Lo, Calle Sönne, Benjamin Davidson -/ import Mathlib.Algebra.Field.NegOnePow import Mathlib.Algebra.Field.Periodic import Mathlib.Algebra.QuadraticDiscriminant import Mathlib.Analysis.SpecialFunctions.Exp /-! # Trigonometric functions ## Main definitions This file contains the definition of `π`. See also `Analysis.SpecialFunctions.Trigonometric.Inverse` and `Analysis.SpecialFunctions.Trigonometric.Arctan` for the inverse trigonometric functions. See also `Analysis.SpecialFunctions.Complex.Arg` and `Analysis.SpecialFunctions.Complex.Log` for the complex argument function and the complex logarithm. ## Main statements Many basic inequalities on the real trigonometric functions are established. The continuity of the usual trigonometric functions is proved. Several facts about the real trigonometric functions have the proofs deferred to `Analysis.SpecialFunctions.Trigonometric.Complex`, as they are most easily proved by appealing to the corresponding fact for complex trigonometric functions. See also `Analysis.SpecialFunctions.Trigonometric.Chebyshev` for the multiple angle formulas in terms of Chebyshev polynomials. ## Tags sin, cos, tan, angle -/ noncomputable section open Topology Filter Set namespace Complex @[continuity, fun_prop] theorem continuous_sin : Continuous sin := by change Continuous fun z => (exp (-z * I) - exp (z * I)) * I / 2 fun_prop @[fun_prop] theorem continuousOn_sin {s : Set ℂ} : ContinuousOn sin s := continuous_sin.continuousOn @[continuity, fun_prop] theorem continuous_cos : Continuous cos := by change Continuous fun z => (exp (z * I) + exp (-z * I)) / 2 fun_prop @[fun_prop] theorem continuousOn_cos {s : Set ℂ} : ContinuousOn cos s := continuous_cos.continuousOn @[continuity, fun_prop] theorem continuous_sinh : Continuous sinh := by change Continuous fun z => (exp z - exp (-z)) / 2 fun_prop @[continuity, fun_prop] theorem continuous_cosh : Continuous cosh := by change Continuous fun z => (exp z + exp (-z)) / 2 fun_prop end Complex namespace Real variable {x y z : ℝ} @[continuity, fun_prop] theorem continuous_sin : Continuous sin := Complex.continuous_re.comp (Complex.continuous_sin.comp Complex.continuous_ofReal) @[fun_prop] theorem continuousOn_sin {s} : ContinuousOn sin s := continuous_sin.continuousOn @[continuity, fun_prop] theorem continuous_cos : Continuous cos := Complex.continuous_re.comp (Complex.continuous_cos.comp Complex.continuous_ofReal) @[fun_prop] theorem continuousOn_cos {s} : ContinuousOn cos s := continuous_cos.continuousOn @[continuity, fun_prop] theorem continuous_sinh : Continuous sinh := Complex.continuous_re.comp (Complex.continuous_sinh.comp Complex.continuous_ofReal) @[continuity, fun_prop] theorem continuous_cosh : Continuous cosh := Complex.continuous_re.comp (Complex.continuous_cosh.comp Complex.continuous_ofReal) end Real namespace Real theorem exists_cos_eq_zero : 0 ∈ cos '' Icc (1 : ℝ) 2 := intermediate_value_Icc' (by norm_num) continuousOn_cos ⟨le_of_lt cos_two_neg, le_of_lt cos_one_pos⟩ /-- The number π = 3.14159265... Defined here using choice as twice a zero of cos in [1,2], from which one can derive all its properties. For explicit bounds on π, see `Data.Real.Pi.Bounds`. Denoted `π`, once the `Real` namespace is opened. -/ protected noncomputable def pi : ℝ := 2 * Classical.choose exists_cos_eq_zero @[inherit_doc] scoped notation "π" => Real.pi @[simp] theorem cos_pi_div_two : cos (π / 2) = 0 := by rw [Real.pi, mul_div_cancel_left₀ _ (two_ne_zero' ℝ)] exact (Classical.choose_spec exists_cos_eq_zero).2 theorem one_le_pi_div_two : (1 : ℝ) ≤ π / 2 := by rw [Real.pi, mul_div_cancel_left₀ _ (two_ne_zero' ℝ)] exact (Classical.choose_spec exists_cos_eq_zero).1.1 theorem pi_div_two_le_two : π / 2 ≤ 2 := by rw [Real.pi, mul_div_cancel_left₀ _ (two_ne_zero' ℝ)] exact (Classical.choose_spec exists_cos_eq_zero).1.2 theorem two_le_pi : (2 : ℝ) ≤ π := (div_le_div_iff_of_pos_right (show (0 : ℝ) < 2 by norm_num)).1 (by rw [div_self (two_ne_zero' ℝ)]; exact one_le_pi_div_two) theorem pi_le_four : π ≤ 4 := (div_le_div_iff_of_pos_right (show (0 : ℝ) < 2 by norm_num)).1 (calc π / 2 ≤ 2 := pi_div_two_le_two _ = 4 / 2 := by norm_num) @[bound] theorem pi_pos : 0 < π := lt_of_lt_of_le (by norm_num) two_le_pi @[bound] theorem pi_nonneg : 0 ≤ π := pi_pos.le theorem pi_ne_zero : π ≠ 0 := pi_pos.ne' theorem pi_div_two_pos : 0 < π / 2 := half_pos pi_pos theorem two_pi_pos : 0 < 2 * π := by linarith [pi_pos] end Real namespace Mathlib.Meta.Positivity open Lean.Meta Qq /-- Extension for the `positivity` tactic: `π` is always positive. -/ @[positivity Real.pi] def evalRealPi : PositivityExt where eval {u α} _zα _pα e := do match u, α, e with \| 0, ~q(ℝ), ~q(Real.pi) => assertInstancesCommute pure (.positive q(Real.pi_pos)) \| _, _, _ => throwError "not Real.pi" end Mathlib.Meta.Positivity namespace NNReal open Real open Real NNReal /-- `π` considered as a nonnegative real. -/ noncomputable def pi : ℝ≥0 := ⟨π, Real.pi_pos.le⟩ @[simp] theorem coe_real_pi : (pi : ℝ) = π := rfl theorem pi_pos : 0 < pi := mod_cast Real.pi_pos theorem pi_ne_zero : pi ≠ 0 := pi_pos.ne' end NNReal namespace Real @[simp] theorem sin_pi : sin π = 0 := by rw [← mul_div_cancel_left₀ π (two_ne_zero' ℝ), two_mul, add_div, sin_add, cos_pi_div_two]; simp @[simp] theorem cos_pi : cos π = -1 := by rw [← mul_div_cancel_left₀ π (two_ne_zero' ℝ), mul_div_assoc, cos_two_mul, cos_pi_div_two] norm_num @[simp] theorem sin_two_pi : sin (2 * π) = 0 := by simp [two_mul, sin_add] @[simp] theorem cos_two_pi : cos (2 * π) = 1 := by simp [two_mul, cos_add] theorem sin_antiperiodic : Function.Antiperiodic sin π := by simp [sin_add] theorem sin_periodic : Function.Periodic sin (2 * π) := sin_antiperiodic.periodic_two_mul @[simp] theorem sin_add_pi (x : ℝ) : sin (x + π) = -sin x := sin_antiperiodic x @[simp] theorem sin_add_two_pi (x : ℝ) : sin (x + 2 * π) = sin x := sin_periodic x @[simp] theorem sin_sub_pi (x : ℝ) : sin (x - π) = -sin x := sin_antiperiodic.sub_eq x @[simp] theorem sin_sub_two_pi (x : ℝ) : sin (x - 2 * π) = sin x := sin_periodic.sub_eq x @[simp] theorem sin_pi_sub (x : ℝ) : sin (π - x) = sin x := neg_neg (sin x) ▸ sin_neg x ▸ sin_antiperiodic.sub_eq' @[simp] theorem sin_two_pi_sub (x : ℝ) : sin (2 * π - x) = -sin x := sin_neg x ▸ sin_periodic.sub_eq' @[simp] theorem sin_nat_mul_pi (n : ℕ) : sin (n * π) = 0 := sin_antiperiodic.nat_mul_eq_of_eq_zero sin_zero n @[simp] theorem sin_int_mul_pi (n : ℤ) : sin (n * π) = 0 := sin_antiperiodic.int_mul_eq_of_eq_zero sin_zero n @[simp] theorem sin_add_nat_mul_two_pi (x : ℝ) (n : ℕ) : sin (x + n * (2 * π)) = sin x := sin_periodic.nat_mul n x @[simp] theorem sin_add_int_mul_two_pi (x : ℝ) (n : ℤ) : sin (x + n * (2 * π)) = sin x := sin_periodic.int_mul n x @[simp] theorem sin_sub_nat_mul_two_pi (x : ℝ) (n : ℕ) : sin (x - n * (2 * π)) = sin x := sin_periodic.sub_nat_mul_eq n @[simp] theorem sin_sub_int_mul_two_pi (x : ℝ) (n : ℤ) : sin (x - n * (2 * π)) = sin x := sin_periodic.sub_int_mul_eq n @[simp] theorem sin_nat_mul_two_pi_sub (x : ℝ) (n : ℕ) : sin (n * (2 * π) - x) = -sin x := sin_neg x ▸ sin_periodic.nat_mul_sub_eq n @[simp] theorem sin_int_mul_two_pi_sub (x : ℝ) (n : ℤ) : sin (n * (2 * π) - x) = -sin x := sin_neg x ▸ sin_periodic.int_mul_sub_eq n theorem sin_add_int_mul_pi (x : ℝ) (n : ℤ) : sin (x + n * π) = (-1) ^ n * sin x := n.cast_negOnePow ℝ ▸ sin_antiperiodic.add_int_mul_eq n theorem sin_add_nat_mul_pi (x : ℝ) (n : ℕ) : sin (x + n * π) = (-1) ^ n * sin x := sin_antiperiodic.add_nat_mul_eq n theorem sin_sub_int_mul_pi (x : ℝ) (n : ℤ) : sin (x - n * π) = (-1) ^ n * sin x := n.cast_negOnePow ℝ ▸ sin_antiperiodic.sub_int_mul_eq n theorem sin_sub_nat_mul_pi (x : ℝ) (n : ℕ) : sin (x - n * π) = (-1) ^ n * sin x := sin_antiperiodic.sub_nat_mul_eq n theorem sin_int_mul_pi_sub (x : ℝ) (n : ℤ) : sin (n * π - x) = -((-1) ^ n * sin x) := by simpa only [sin_neg, mul_neg, Int.cast_negOnePow] using sin_antiperiodic.int_mul_sub_eq n theorem sin_nat_mul_pi_sub (x : ℝ) (n : ℕ) : sin (n * π - x) = -((-1) ^ n * sin x) := by simpa only [sin_neg, mul_neg] using sin_antiperiodic.nat_mul_sub_eq n theorem cos_antiperiodic : Function.Antiperiodic cos π := by simp [cos_add] theorem cos_periodic : Function.Periodic cos (2 * π) := cos_antiperiodic.periodic_two_mul @[simp] theorem abs_cos_int_mul_pi (k : ℤ) : \|cos (k * π)\| = 1 := by simp [abs_cos_eq_sqrt_one_sub_sin_sq] @[simp] theorem cos_add_pi (x : ℝ) : cos (x + π) = -cos x := cos_antiperiodic x @[simp] theorem cos_add_two_pi (x : ℝ) : cos (x + 2 * π) = cos x := cos_periodic x @[simp] theorem cos_sub_pi (x : ℝ) : cos (x - π) = -cos x := cos_antiperiodic.sub_eq x @[simp] theorem cos_sub_two_pi (x : ℝ) : cos (x - 2 * π) = cos x := cos_periodic.sub_eq x @[simp] theorem cos_pi_sub (x : ℝ) : cos (π - x) = -cos x := cos_neg x ▸ cos_antiperiodic.sub_eq' @[simp] theorem cos_two_pi_sub (x : ℝ) : cos (2 * π - x) = cos x := cos_neg x ▸ cos_periodic.sub_eq' @[simp] theorem cos_nat_mul_two_pi (n : ℕ) : cos (n * (2 * π)) = 1 := (cos_periodic.nat_mul_eq n).trans cos_zero @[simp] theorem cos_int_mul_two_pi (n : ℤ) : cos (n * (2 * π)) = 1 := (cos_periodic.int_mul_eq n).trans cos_zero @[simp] theorem cos_add_nat_mul_two_pi (x : ℝ) (n : ℕ) : cos (x + n * (2 * π)) = cos x := cos_periodic.nat_mul n x @[simp] theorem cos_add_int_mul_two_pi (x : ℝ) (n : ℤ) : cos (x + n * (2 * π)) = cos x := cos_periodic.int_mul n x @[simp] theorem cos_sub_nat_mul_two_pi (x : ℝ) (n : ℕ) : cos (x - n * (2 * π)) = cos x := cos_periodic.sub_nat_mul_eq n @[simp] theorem cos_sub_int_mul_two_pi (x : ℝ) (n : ℤ) : cos (x - n * (2 * π)) = cos x := cos_periodic.sub_int_mul_eq n @[simp] theorem cos_nat_mul_two_pi_sub (x : ℝ) (n : ℕ) : cos (n * (2 * π) - x) = cos x := cos_neg x ▸ cos_periodic.nat_mul_sub_eq n @[simp] theorem cos_int_mul_two_pi_sub (x : ℝ) (n : ℤ) : cos (n * (2 * π) - x) = cos x := cos_neg x ▸ cos_periodic.int_mul_sub_eq n theorem cos_add_int_mul_pi (x : ℝ) (n : ℤ) : cos (x + n * π) = (-1) ^ n * cos x := n.cast_negOnePow ℝ ▸ cos_antiperiodic.add_int_mul_eq n theorem cos_add_nat_mul_pi (x : ℝ) (n : ℕ) : cos (x + n * π) = (-1) ^ n * cos x := cos_antiperiodic.add_nat_mul_eq n theorem cos_sub_int_mul_pi (x : ℝ) (n : ℤ) : cos (x - n * π) = (-1) ^ n * cos x := n.cast_negOnePow ℝ ▸ cos_antiperiodic.sub_int_mul_eq n theorem cos_sub_nat_mul_pi (x : ℝ) (n : ℕ) : cos (x - n * π) = (-1) ^ n * cos x := cos_antiperiodic.sub_nat_mul_eq n theorem cos_int_mul_pi_sub (x : ℝ) (n : ℤ) : cos (n * π - x) = (-1) ^ n * cos x := n.cast_negOnePow ℝ ▸ cos_neg x ▸ cos_antiperiodic.int_mul_sub_eq n theorem cos_nat_mul_pi_sub (x : ℝ) (n : ℕ) : cos (n * π - x) = (-1) ^ n * cos x := cos_neg x ▸ cos_antiperiodic.nat_mul_sub_eq n theorem cos_nat_mul_two_pi_add_pi (n : ℕ) : cos (n * (2 * π) + π) = -1 := by simpa only [cos_zero] using (cos_periodic.nat_mul n).add_antiperiod_eq cos_antiperiodic theorem cos_int_mul_two_pi_add_pi (n : ℤ) : cos (n * (2 * π) + π) = -1 := by simpa only [cos_zero] using (cos_periodic.int_mul n).add_antiperiod_eq cos_antiperiodic theorem cos_nat_mul_two_pi_sub_pi (n : ℕ) : cos (n * (2 * π) - π) = -1 := by simpa only [cos_zero] using (cos_periodic.nat_mul n).sub_antiperiod_eq cos_antiperiodic theorem cos_int_mul_two_pi_sub_pi (n : ℤ) : cos (n * (2 * π) - π) = -1 := by simpa only [cos_zero] using (cos_periodic.int_mul n).sub_antiperiod_eq cos_antiperiodic theorem sin_pos_of_pos_of_lt_pi {x : ℝ} (h0x : 0 < x) (hxp : x < π) : 0 < sin x := if hx2 : x ≤ 2 then sin_pos_of_pos_of_le_two h0x hx2 else have : (2 : ℝ) + 2 = 4 := by norm_num have : π - x ≤ 2 := sub_le_iff_le_add.2 (le_trans pi_le_four (this ▸ add_le_add_left (le_of_not_ge hx2) _)) sin_pi_sub x ▸ sin_pos_of_pos_of_le_two (sub_pos.2 hxp) this theorem sin_pos_of_mem_Ioo {x : ℝ} (hx : x ∈ Ioo 0 π) : 0 < sin x := sin_pos_of_pos_of_lt_pi hx.1 hx.2 theorem sin_nonneg_of_mem_Icc {x : ℝ} (hx : x ∈ Icc 0 π) : 0 ≤ sin x := by rw [← closure_Ioo pi_ne_zero.symm] at hx exact closure_lt_subset_le continuous_const continuous_sin (closure_mono (fun y => sin_pos_of_mem_Ioo) hx) theorem sin_nonneg_of_nonneg_of_le_pi {x : ℝ} (h0x : 0 ≤ x) (hxp : x ≤ π) : 0 ≤ sin x := sin_nonneg_of_mem_Icc ⟨h0x, hxp⟩ theorem sin_neg_of_neg_of_neg_pi_lt {x : ℝ} (hx0 : x < 0) (hpx : -π < x) : sin x < 0 := neg_pos.1 <\| sin_neg x ▸ sin_pos_of_pos_of_lt_pi (neg_pos.2 hx0) (neg_lt.1 hpx) theorem sin_nonpos_of_nonnpos_of_neg_pi_le {x : ℝ} (hx0 : x ≤ 0) (hpx : -π ≤ x) : sin x ≤ 0 := neg_nonneg.1 <\| sin_neg x ▸ sin_nonneg_of_nonneg_of_le_pi (neg_nonneg.2 hx0) (neg_le.1 hpx) @[simp] theorem sin_pi_div_two : sin (π / 2) = 1 := have : sin (π / 2) = 1 ∨ sin (π / 2) = -1 := by simpa [sq, mul_self_eq_one_iff] using sin_sq_add_cos_sq (π / 2) this.resolve_right fun h => show ¬(0 : ℝ) < -1 by norm_num <\| h ▸ sin_pos_of_pos_of_lt_pi pi_div_two_pos (half_lt_self pi_pos) theorem sin_add_pi_div_two (x : ℝ) : sin (x + π / 2) = cos x := by simp [sin_add] theorem sin_sub_pi_div_two (x : ℝ) : sin (x - π / 2) = -cos x := by simp [sub_eq_add_neg, sin_add] theorem sin_pi_div_two_sub (x : ℝ) : sin (π / 2 - x) = cos x := by simp [sub_eq_add_neg, sin_add] theorem cos_add_pi_div_two (x : ℝ) : cos (x + π / 2) = -sin x := by simp [cos_add] theorem cos_sub_pi_div_two (x : ℝ) : cos (x - π / 2) = sin x := by simp [sub_eq_add_neg, cos_add] theorem cos_pi_div_two_sub (x : ℝ) : cos (π / 2 - x) = sin x := by rw [← cos_neg, neg_sub, cos_sub_pi_div_two] theorem cos_pos_of_mem_Ioo {x : ℝ} (hx : x ∈ Ioo (-(π / 2)) (π / 2)) : 0 < cos x := sin_add_pi_div_two x ▸ sin_pos_of_mem_Ioo ⟨by linarith [hx.1], by linarith [hx.2]⟩ theorem cos_nonneg_of_mem_Icc {x : ℝ} (hx : x ∈ Icc (-(π / 2)) (π / 2)) : 0 ≤ cos x := sin_add_pi_div_two x ▸ sin_nonneg_of_mem_Icc ⟨by linarith [hx.1], by linarith [hx.2]⟩ theorem cos_nonneg_of_neg_pi_div_two_le_of_le {x : ℝ} (hl : -(π / 2) ≤ x) (hu : x ≤ π / 2) : 0 ≤ cos x := cos_nonneg_of_mem_Icc ⟨hl, hu⟩ theorem cos_neg_of_pi_div_two_lt_of_lt {x : ℝ} (hx₁ : π / 2 < x) (hx₂ : x < π + π / 2) : cos x < 0 := neg_pos.1 <\| cos_pi_sub x ▸ cos_pos_of_mem_Ioo ⟨by linarith, by linarith⟩ theorem cos_nonpos_of_pi_div_two_le_of_le {x : ℝ} (hx₁ : π / 2 ≤ x) (hx₂ : x ≤ π + π / 2) : cos x ≤ 0 := neg_nonneg.1 <\| cos_pi_sub x ▸ cos_nonneg_of_mem_Icc ⟨by linarith, by linarith⟩ theorem sin_eq_sqrt_one_sub_cos_sq {x : ℝ} (hl : 0 ≤ x) (hu : x ≤ π) : sin x = √(1 - cos x ^ 2) := by rw [← abs_sin_eq_sqrt_one_sub_cos_sq, abs_of_nonneg (sin_nonneg_of_nonneg_of_le_pi hl hu)] theorem cos_eq_sqrt_one_sub_sin_sq {x : ℝ} (hl : -(π / 2) ≤ x) (hu : x ≤ π / 2) : cos x = √(1 - sin x ^ 2) := by rw [← abs_cos_eq_sqrt_one_sub_sin_sq, abs_of_nonneg (cos_nonneg_of_mem_Icc ⟨hl, hu⟩)] lemma cos_half {x : ℝ} (hl : -π ≤ x) (hr : x ≤ π) : cos (x / 2) = sqrt ((1 + cos x) / 2) := by have : 0 ≤ cos (x / 2) := cos_nonneg_of_mem_Icc <\| by constructor <;> linarith rw [← sqrt_sq this, cos_sq, add_div, two_mul, add_halves] lemma abs_sin_half (x : ℝ) : \|sin (x / 2)\| = sqrt ((1 - cos x) / 2) := by rw [← sqrt_sq_eq_abs, sin_sq_eq_half_sub, two_mul, add_halves, sub_div] lemma sin_half_eq_sqrt {x : ℝ} (hl : 0 ≤ x) (hr : x ≤ 2 * π) : sin (x / 2) = sqrt ((1 - cos x) / 2) := by rw [← abs_sin_half, abs_of_nonneg] apply sin_nonneg_of_nonneg_of_le_pi <;> linarith lemma sin_half_eq_neg_sqrt {x : ℝ} (hl : -(2 * π) ≤ x) (hr : x ≤ 0) : sin (x / 2) = -sqrt ((1 - cos x) / 2) := by rw [← abs_sin_half, abs_of_nonpos, neg_neg] apply sin_nonpos_of_nonnpos_of_neg_pi_le <;> linarith theorem sin_eq_zero_iff_of_lt_of_lt {x : ℝ} (hx₁ : -π < x) (hx₂ : x < π) : sin x = 0 ↔ x = 0 := ⟨fun h => by contrapose! h cases h.lt_or_lt with \| inl h0 => exact (sin_neg_of_neg_of_neg_pi_lt h0 hx₁).ne \| inr h0 => exact (sin_pos_of_pos_of_lt_pi h0 hx₂).ne', fun h => by simp [h]⟩ theorem sin_eq_zero_iff {x : ℝ} : sin x = 0 ↔ ∃ n : ℤ, (n : ℝ) * π = x := ⟨fun h => ⟨⌊x / π⌋, le_antisymm (sub_nonneg.1 (Int.sub_floor_div_mul_nonneg _ pi_pos)) (sub_nonpos.1 <\| le_of_not_gt fun h₃ => (sin_pos_of_pos_of_lt_pi h₃ (Int.sub_floor_div_mul_lt _ pi_pos)).ne (by simp [sub_eq_add_neg, sin_add, h, sin_int_mul_pi]))⟩, fun ⟨_, hn⟩ => hn ▸ sin_int_mul_pi _⟩ theorem sin_ne_zero_iff {x : ℝ} : sin x ≠ 0 ↔ ∀ n : ℤ, (n : ℝ) * π ≠ x := by rw [← not_exists, not_iff_not, sin_eq_zero_iff] theorem sin_eq_zero_iff_cos_eq {x : ℝ} : sin x = 0 ↔ cos x = 1 ∨ cos x = -1 := by rw [← mul_self_eq_one_iff, ← sin_sq_add_cos_sq x, sq, sq, ← sub_eq_iff_eq_add, sub_self] exact ⟨fun h => by rw [h, mul_zero], eq_zero_of_mul_self_eq_zero ∘ Eq.symm⟩ theorem cos_eq_one_iff (x : ℝ) : cos x = 1 ↔ ∃ n : ℤ, (n : ℝ) * (2 * π) = x := ⟨fun h => let ⟨n, hn⟩ := sin_eq_zero_iff.1 (sin_eq_zero_iff_cos_eq.2 (Or.inl h)) ⟨n / 2, (Int.emod_two_eq_zero_or_one n).elim (fun hn0 => by rwa [← mul_assoc, ← @Int.cast_two ℝ, ← Int.cast_mul, Int.ediv_mul_cancel (Int.dvd_iff_emod_eq_zero.2 hn0)]) fun hn1 => by rw [← Int.emod_add_ediv n 2, hn1, Int.cast_add, Int.cast_one, add_mul, one_mul, add_comm, mul_comm (2 : ℤ), Int.cast_mul, mul_assoc, Int.cast_two] at hn rw [← hn, cos_int_mul_two_pi_add_pi] at h exact absurd h (by norm_num)⟩, fun ⟨_, hn⟩ => hn ▸ cos_int_mul_two_pi _⟩ theorem cos_eq_one_iff_of_lt_of_lt {x : ℝ} (hx₁ : -(2 * π) < x) (hx₂ : x < 2 * π) : cos x = 1 ↔ x = 0 := ⟨fun h => by rcases (cos_eq_one_iff _).1 h with ⟨n, rfl⟩ rw [mul_lt_iff_lt_one_left two_pi_pos] at hx₂ rw [neg_lt, neg_mul_eq_neg_mul, mul_lt_iff_lt_one_left two_pi_pos] at hx₁ norm_cast at hx₁ hx₂ obtain rfl : n = 0 := le_antisymm (by omega) (by omega) simp, fun h => by simp [h]⟩ theorem sin_lt_sin_of_lt_of_le_pi_div_two {x y : ℝ} (hx₁ : -(π / 2) ≤ x) (hy₂ : y ≤ π / 2) (hxy : x < y) : sin x < sin y := by rw [← sub_pos, sin_sub_sin] have : 0 < sin ((y - x) / 2) := by apply sin_pos_of_pos_of_lt_pi <;> linarith have : 0 < cos ((y + x) / 2) := by refine cos_pos_of_mem_Ioo ⟨?_, ?_⟩ <;> linarith positivity theorem strictMonoOn_sin : StrictMonoOn sin (Icc (-(π / 2)) (π / 2)) := fun _ hx _ hy hxy => sin_lt_sin_of_lt_of_le_pi_div_two hx.1 hy.2 hxy theorem cos_lt_cos_of_nonneg_of_le_pi {x y : ℝ} (hx₁ : 0 ≤ x) (hy₂ : y ≤ π) (hxy : x < y) : cos y < cos x := by rw [← sin_pi_div_two_sub, ← sin_pi_div_two_sub] apply sin_lt_sin_of_lt_of_le_pi_div_two <;> linarith theorem cos_lt_cos_of_nonneg_of_le_pi_div_two {x y : ℝ} (hx₁ : 0 ≤ x) (hy₂ : y ≤ π / 2) (hxy : x < y) : cos y < cos x := cos_lt_cos_of_nonneg_of_le_pi hx₁ (hy₂.trans (by linarith)) hxy theorem strictAntiOn_cos : StrictAntiOn cos (Icc 0 π) := fun _ hx _ hy hxy => cos_lt_cos_of_nonneg_of_le_pi hx.1 hy.2 hxy theorem cos_le_cos_of_nonneg_of_le_pi {x y : ℝ} (hx₁ : 0 ≤ x) (hy₂ : y ≤ π) (hxy : x ≤ y) : cos y ≤ cos x := (strictAntiOn_cos.le_iff_le ⟨hx₁.trans hxy, hy₂⟩ ⟨hx₁, hxy.trans hy₂⟩).2 hxy theorem sin_le_sin_of_le_of_le_pi_div_two {x y : ℝ} (hx₁ : -(π / 2) ≤ x) (hy₂ : y ≤ π / 2) (hxy : x ≤ y) : sin x ≤ sin y := (strictMonoOn_sin.le_iff_le ⟨hx₁, hxy.trans hy₂⟩ ⟨hx₁.trans hxy, hy₂⟩).2 hxy theorem injOn_sin : InjOn sin (Icc (-(π / 2)) (π / 2)) := strictMonoOn_sin.injOn theorem injOn_cos : InjOn cos (Icc 0 π) := strictAntiOn_cos.injOn theorem surjOn_sin : SurjOn sin (Icc (-(π / 2)) (π / 2)) (Icc (-1) 1) := by simpa only [sin_neg, sin_pi_div_two] using intermediate_value_Icc (neg_le_self pi_div_two_pos.le) continuous_sin.continuousOn theorem surjOn_cos : SurjOn cos (Icc 0 π) (Icc (-1) 1) := by simpa only [cos_zero, cos_pi] using intermediate_value_Icc' pi_pos.le continuous_cos.continuousOn theorem sin_mem_Icc (x : ℝ) : sin x ∈ Icc (-1 : ℝ) 1 := ⟨neg_one_le_sin x, sin_le_one x⟩ theorem cos_mem_Icc (x : ℝ) : cos x ∈ Icc (-1 : ℝ) 1 := ⟨neg_one_le_cos x, cos_le_one x⟩ theorem mapsTo_sin (s : Set ℝ) : MapsTo sin s (Icc (-1 : ℝ) 1) := fun x _ => sin_mem_Icc x theorem mapsTo_cos (s : Set ℝ) : MapsTo cos s (Icc (-1 : ℝ) 1) := fun x _ => cos_mem_Icc x theorem bijOn_sin : BijOn sin (Icc (-(π / 2)) (π / 2)) (Icc (-1) 1) := ⟨mapsTo_sin _, injOn_sin, surjOn_sin⟩ theorem bijOn_cos : BijOn cos (Icc 0 π) (Icc (-1) 1) := ⟨mapsTo_cos _, injOn_cos, surjOn_cos⟩ @[simp] theorem range_cos : range cos = (Icc (-1) 1 : Set ℝ) := Subset.antisymm (range_subset_iff.2 cos_mem_Icc) surjOn_cos.subset_range @[simp] theorem range_sin : range sin = (Icc (-1) 1 : Set ℝ) := Subset.antisymm (range_subset_iff.2 sin_mem_Icc) surjOn_sin.subset_range theorem range_cos_infinite : (range Real.cos).Infinite := by rw [Real.range_cos] exact Icc_infinite (by norm_num) theorem range_sin_infinite : (range Real.sin).Infinite := by rw [Real.range_sin] exact Icc_infinite (by norm_num) section CosDivSq variable (x : ℝ) /-- the series `sqrtTwoAddSeries x n` is `sqrt(2 + sqrt(2 + ... ))` with `n` square roots, starting with `x`. We define it here because `cos (pi / 2 ^ (n+1)) = sqrtTwoAddSeries 0 n / 2` -/ @[simp] noncomputable def sqrtTwoAddSeries (x : ℝ) : ℕ → ℝ \| 0 => x \| n + 1 => √(2 + sqrtTwoAddSeries x n) theorem sqrtTwoAddSeries_zero : sqrtTwoAddSeries x 0 = x := by simp theorem sqrtTwoAddSeries_one : sqrtTwoAddSeries 0 1 = √2 := by simp theorem sqrtTwoAddSeries_two : sqrtTwoAddSeries 0 2 = √(2 + √2) := by simp theorem sqrtTwoAddSeries_zero_nonneg : ∀ n : ℕ, 0 ≤ sqrtTwoAddSeries 0 n \| 0 => le_refl 0 \| _ + 1 => sqrt_nonneg _ theorem sqrtTwoAddSeries_nonneg {x : ℝ} (h : 0 ≤ x) : ∀ n : ℕ, 0 ≤ sqrtTwoAddSeries x n \| 0 => h \| _ + 1 => sqrt_nonneg _ theorem sqrtTwoAddSeries_lt_two : ∀ n : ℕ, sqrtTwoAddSeries 0 n < 2 \| 0 => by norm_num \| n + 1 => by refine lt_of_lt_of_le ?_ (sqrt_sq zero_lt_two.le).le rw [sqrtTwoAddSeries, sqrt_lt_sqrt_iff, ← lt_sub_iff_add_lt'] · refine (sqrtTwoAddSeries_lt_two n).trans_le ?_ norm_num · exact add_nonneg zero_le_two (sqrtTwoAddSeries_zero_nonneg n) theorem sqrtTwoAddSeries_succ (x : ℝ) : ∀ n : ℕ, sqrtTwoAddSeries x (n + 1) = sqrtTwoAddSeries (√(2 + x)) n \| 0 => rfl \| n + 1 => by rw [sqrtTwoAddSeries, sqrtTwoAddSeries_succ _ _, sqrtTwoAddSeries] theorem sqrtTwoAddSeries_monotone_left {x y : ℝ} (h : x ≤ y) : ∀ n : ℕ, sqrtTwoAddSeries x n ≤ sqrtTwoAddSeries y n \| 0 => h \| n + 1 => by rw [sqrtTwoAddSeries, sqrtTwoAddSeries] exact sqrt_le_sqrt (add_le_add_left (sqrtTwoAddSeries_monotone_left h _) _) @[simp] theorem cos_pi_over_two_pow : ∀ n : ℕ, cos (π / 2 ^ (n + 1)) = sqrtTwoAddSeries 0 n / 2 \| 0 => by simp \| n + 1 => by have A : (1 : ℝ) < 2 ^ (n + 1) := one_lt_pow₀ one_lt_two n.succ_ne_zero have B : π / 2 ^ (n + 1) < π := div_lt_self pi_pos A have C : 0 < π / 2 ^ (n + 1) := by positivity rw [pow_succ, div_mul_eq_div_div, cos_half, cos_pi_over_two_pow n, sqrtTwoAddSeries, add_div_eq_mul_add_div, one_mul, ← div_mul_eq_div_div, sqrt_div, sqrt_mul_self] <;> linarith [sqrtTwoAddSeries_nonneg le_rfl n] theorem sin_sq_pi_over_two_pow (n : ℕ) : sin (π / 2 ^ (n + 1)) ^ 2 = 1 - (sqrtTwoAddSeries 0 n / 2) ^ 2 := by rw [sin_sq, cos_pi_over_two_pow] theorem sin_sq_pi_over_two_pow_succ (n : ℕ) : sin (π / 2 ^ (n + 2)) ^ 2 = 1 / 2 - sqrtTwoAddSeries 0 n / 4 := by rw [sin_sq_pi_over_two_pow, sqrtTwoAddSeries, div_pow, sq_sqrt, add_div, ← sub_sub] · congr · norm_num · norm_num · exact add_nonneg two_pos.le (sqrtTwoAddSeries_zero_nonneg _) @[simp] theorem sin_pi_over_two_pow_succ (n : ℕ) : sin (π / 2 ^ (n + 2)) = √(2 - sqrtTwoAddSeries 0 n) / 2 := by rw [eq_div_iff_mul_eq two_ne_zero, eq_comm, sqrt_eq_iff_eq_sq, mul_pow, sin_sq_pi_over_two_pow_succ, sub_mul] · congr <;> norm_num · rw [sub_nonneg] exact (sqrtTwoAddSeries_lt_two _).le refine mul_nonneg (sin_nonneg_of_nonneg_of_le_pi ?_ ?_) zero_le_two · positivity · exact div_le_self pi_pos.le <\| one_le_pow₀ one_le_two @[simp] theorem cos_pi_div_four : cos (π / 4) = √2 / 2 := by trans cos (π / 2 ^ 2) · congr norm_num · simp @[simp] theorem sin_pi_div_four : sin (π / 4) = √2 / 2 := by trans sin (π / 2 ^ 2) · congr norm_num · simp @[simp] theorem cos_pi_div_eight : cos (π / 8) = √(2 + √2) / 2 := by trans cos (π / 2 ^ 3) · congr norm_num · simp @[simp] theorem sin_pi_div_eight : sin (π / 8) = √(2 - √2) / 2 := by trans sin (π / 2 ^ 3) · congr norm_num · simp @[simp] theorem cos_pi_div_sixteen : cos (π / 16) = √(2 + √(2 + √2)) / 2 := by trans cos (π / 2 ^ 4) · congr norm_num · simp @[simp] theorem sin_pi_div_sixteen : sin (π / 16) = √(2 - √(2 + √2)) / 2 := by trans sin (π / 2 ^ 4) · congr norm_num · simp @[simp] theorem cos_pi_div_thirty_two : cos (π / 32) = √(2 + √(2 + √(2 + √2))) / 2 := by trans cos (π / 2 ^ 5) · congr norm_num · simp @[simp] theorem sin_pi_div_thirty_two : sin (π / 32) = √(2 - √(2 + √(2 + √2))) / 2 := by trans sin (π / 2 ^ 5) · congr norm_num · simp -- This section is also a convenient location for other explicit values of `sin` and `cos`. /-- The cosine of `π / 3` is `1 / 2`. -/ @[simp] theorem cos_pi_div_three : cos (π / 3) = 1 / 2 := by have h₁ : (2 * cos (π / 3) - 1) ^ 2 * (2 * cos (π / 3) + 2) = 0 := by have : cos (3 * (π / 3)) = cos π := by congr 1 ring linarith [cos_pi, cos_three_mul (π / 3)] rcases mul_eq_zero.mp h₁ with h \| h · linarith [pow_eq_zero h] · have : cos π < cos (π / 3) := by refine cos_lt_cos_of_nonneg_of_le_pi ?_ le_rfl ?_ <;> linarith [pi_pos] linarith [cos_pi] /-- The cosine of `π / 6` is `√3 / 2`. -/ @[simp] theorem cos_pi_div_six : cos (π / 6) = √3 / 2 := by rw [show (6 : ℝ) = 3 * 2 by norm_num, div_mul_eq_div_div, cos_half, cos_pi_div_three, one_add_div, ← div_mul_eq_div_div, two_add_one_eq_three, sqrt_div, sqrt_mul_self] <;> linarith [pi_pos] /-- The square of the cosine of `π / 6` is `3 / 4` (this is sometimes more convenient than the result for cosine itself). -/ theorem sq_cos_pi_div_six : cos (π / 6) ^ 2 = 3 / 4 := by rw [cos_pi_div_six, div_pow, sq_sqrt] <;> norm_num /-- The sine of `π / 6` is `1 / 2`. -/ @[simp] theorem sin_pi_div_six : sin (π / 6) = 1 / 2 := by rw [← cos_pi_div_two_sub, ← cos_pi_div_three] congr ring /-- The square of the sine of `π / 3` is `3 / 4` (this is sometimes more convenient than the result for cosine itself). -/ theorem sq_sin_pi_div_three : sin (π / 3) ^ 2 = 3 / 4 := by rw [← cos_pi_div_two_sub, ← sq_cos_pi_div_six] congr ring /-- The sine of `π / 3` is `√3 / 2`. -/ @[simp] theorem sin_pi_div_three : sin (π / 3) = √3 / 2 := by rw [← cos_pi_div_two_sub, ← cos_pi_div_six] congr ring theorem quadratic_root_cos_pi_div_five : letI c := cos (π / 5) 4 * c ^ 2 - 2 * c - 1 = 0 := by set θ := π / 5 with hθ set c := cos θ set s := sin θ suffices 2 * c = 4 * c ^ 2 - 1 by simp [this] have hs : s ≠ 0 := by rw [ne_eq, sin_eq_zero_iff, hθ] push_neg intro n hn replace hn : n * 5 = 1 := by field_simp [mul_comm _ π, mul_assoc] at hn; norm_cast at hn omega suffices s * (2 * c) = s * (4 * c ^ 2 - 1) from mul_left_cancel₀ hs this calc s * (2 * c) = 2 * s * c := by rw [← mul_assoc, mul_comm 2] _ = sin (2 * θ) := by rw [sin_two_mul] _ = sin (π - 2 * θ) := by rw [sin_pi_sub] _ = sin (2 * θ + θ) := by congr; field_simp [hθ]; linarith _ = sin (2 * θ) * c + cos (2 * θ) * s := sin_add (2 * θ) θ _ = 2 * s * c * c + cos (2 * θ) * s := by rw [sin_two_mul] _ = 2 * s * c * c + (2 * c ^ 2 - 1) * s := by rw [cos_two_mul] _ = s * (2 * c * c) + s * (2 * c ^ 2 - 1) := by linarith _ = s * (4 * c ^ 2 - 1) := by linarith open Polynomial in theorem Polynomial.isRoot_cos_pi_div_five : (4 • X ^ 2 - 2 • X - C 1 : ℝ[X]).IsRoot (cos (π / 5)) := by simpa using quadratic_root_cos_pi_div_five /-- The cosine of `π / 5` is `(1 + √5) / 4`. -/ @[simp] theorem cos_pi_div_five : cos (π / 5) = (1 + √5) / 4 := by set c := cos (π / 5) have : 4 * (c * c) + (-2) * c + (-1) = 0 := by rw [← sq, neg_mul, ← sub_eq_add_neg, ← sub_eq_add_neg] exact quadratic_root_cos_pi_div_five have hd : discrim 4 (-2) (-1) = (2 * √5) * (2 * √5) := by norm_num [discrim, mul_mul_mul_comm] rcases (quadratic_eq_zero_iff (by norm_num) hd c).mp this with h \| h · field_simp [h]; linarith · absurd (show 0 ≤ c from cos_nonneg_of_mem_Icc <\| by constructor <;> linarith [pi_pos.le]) rw [not_le, h] exact div_neg_of_neg_of_pos (by norm_num [lt_sqrt]) (by positivity) end CosDivSq /-- `Real.sin` as an `OrderIso` between `[-(π / 2), π / 2]` and `[-1, 1]`. -/ def sinOrderIso : Icc (-(π / 2)) (π / 2) ≃o Icc (-1 : ℝ) 1 := (strictMonoOn_sin.orderIso _ _).trans <\| OrderIso.setCongr _ _ bijOn_sin.image_eq @[simp] theorem coe_sinOrderIso_apply (x : Icc (-(π / 2)) (π / 2)) : (sinOrderIso x : ℝ) = sin x := rfl theorem sinOrderIso_apply (x : Icc (-(π / 2)) (π / 2)) : sinOrderIso x = ⟨sin x, sin_mem_Icc x⟩ := rfl @[simp]	theorem tan_pi_div_four : tan (π / 4) = 1 := by rw [tan_eq_sin_div_cos, cos_pi_div_four, sin_pi_div_four] have h : √2 / 2 > 0 := by positivity exact div_self (ne_of_gt h)	Mathlib/Analysis/SpecialFunctions/Trigonometric/Basic.lean	851	855
/- Copyright (c) 2022 Joël Riou. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Joël Riou -/ import Mathlib.AlgebraicTopology.DoldKan.GammaCompN import Mathlib.AlgebraicTopology.DoldKan.NReflectsIso /-! The unit isomorphism of the Dold-Kan equivalence In order to construct the unit isomorphism of the Dold-Kan equivalence, we first construct natural transformations `Γ₂N₁.natTrans : N₁ ⋙ Γ₂ ⟶ toKaroubi (SimplicialObject C)` and `Γ₂N₂.natTrans : N₂ ⋙ Γ₂ ⟶ 𝟭 (SimplicialObject C)`. It is then shown that `Γ₂N₂.natTrans` is an isomorphism by using that it becomes an isomorphism after the application of the functor `N₂ : Karoubi (SimplicialObject C) ⥤ Karoubi (ChainComplex C ℕ)` which reflects isomorphisms. (See `Equivalence.lean` for the general strategy of proof of the Dold-Kan equivalence.) -/ noncomputable section open CategoryTheory CategoryTheory.Category CategoryTheory.Limits CategoryTheory.Idempotents SimplexCategory Opposite SimplicialObject Simplicial DoldKan namespace AlgebraicTopology namespace DoldKan variable {C : Type*} [Category C] [Preadditive C] theorem PInfty_comp_map_mono_eq_zero (X : SimplicialObject C) {n : ℕ} {Δ' : SimplexCategory} (i : Δ' ⟶ ⦋n⦌) [hi : Mono i] (h₁ : Δ'.len ≠ n) (h₂ : ¬Isδ₀ i) : PInfty.f n ≫ X.map i.op = 0 := by induction' Δ' using SimplexCategory.rec with m obtain ⟨k, hk⟩ := Nat.exists_eq_add_of_lt (len_lt_of_mono i fun h => by rw [← h] at h₁ exact h₁ rfl) simp only [len_mk] at hk rcases k with _\|k · change n = m + 1 at hk subst hk obtain ⟨j, rfl⟩ := eq_δ_of_mono i rw [Isδ₀.iff] at h₂ have h₃ : 1 ≤ (j : ℕ) := by by_contra h exact h₂ (by simpa only [Fin.ext_iff, not_le, Nat.lt_one_iff] using h) exact (HigherFacesVanish.of_P (m + 1) m).comp_δ_eq_zero j h₂ (by omega) · simp only [Nat.succ_eq_add_one, ← add_assoc] at hk clear h₂ hi subst hk obtain ⟨j₁ : Fin (_ + 1), i, rfl⟩ := eq_comp_δ_of_not_surjective i fun h => by have h' := len_le_of_epi (SimplexCategory.epi_iff_surjective.2 h) dsimp at h' omega obtain ⟨j₂, i, rfl⟩ := eq_comp_δ_of_not_surjective i fun h => by have h' := len_le_of_epi (SimplexCategory.epi_iff_surjective.2 h) dsimp at h' omega by_cases hj₁ : j₁ = 0 · subst hj₁ rw [assoc, ← SimplexCategory.δ_comp_δ'' (Fin.zero_le _)] simp only [op_comp, X.map_comp, assoc, PInfty_f] erw [(HigherFacesVanish.of_P _ _).comp_δ_eq_zero_assoc _ j₂.succ_ne_zero, zero_comp] simp only [Nat.succ_eq_add_one, Nat.add, Fin.succ] omega · simp only [op_comp, X.map_comp, assoc, PInfty_f] erw [(HigherFacesVanish.of_P _ _).comp_δ_eq_zero_assoc _ hj₁, zero_comp] by_contra exact hj₁ (by simp only [Fin.ext_iff, Fin.val_zero]; omega) @[reassoc] theorem Γ₀_obj_termwise_mapMono_comp_PInfty (X : SimplicialObject C) {Δ Δ' : SimplexCategory} (i : Δ ⟶ Δ') [Mono i] : Γ₀.Obj.Termwise.mapMono (AlternatingFaceMapComplex.obj X) i ≫ PInfty.f Δ.len = PInfty.f Δ'.len ≫ X.map i.op := by induction' Δ using SimplexCategory.rec with n induction' Δ' using SimplexCategory.rec with n' dsimp -- We start with the case `i` is an identity by_cases h : n = n' · subst h simp only [SimplexCategory.eq_id_of_mono i, Γ₀.Obj.Termwise.mapMono_id, op_id, X.map_id] dsimp simp only [id_comp, comp_id] by_cases hi : Isδ₀ i -- The case `i = δ 0` · have h' : n' = n + 1 := hi.left subst h' simp only [Γ₀.Obj.Termwise.mapMono_δ₀' _ i hi] dsimp rw [← PInfty.comm _ n, AlternatingFaceMapComplex.obj_d_eq] simp only [eq_self_iff_true, id_comp, if_true, Preadditive.comp_sum] rw [Finset.sum_eq_single (0 : Fin (n + 2))] rotate_left · intro b _ hb rw [Preadditive.comp_zsmul, SimplicialObject.δ, PInfty_comp_map_mono_eq_zero X (SimplexCategory.δ b) h (by rw [Isδ₀.iff] exact hb), zsmul_zero] · simp only [Finset.mem_univ, not_true, IsEmpty.forall_iff] · simp only [hi.eq_δ₀, Fin.val_zero, pow_zero, one_zsmul] rfl -- The case `i ≠ δ 0` · rw [Γ₀.Obj.Termwise.mapMono_eq_zero _ i _ hi, zero_comp] swap · by_contra h' exact h (congr_arg SimplexCategory.len h'.symm) rw [PInfty_comp_map_mono_eq_zero] · exact h · by_contra h' exact hi h' variable [HasFiniteCoproducts C] namespace Γ₂N₁ /-- The natural transformation `N₁ ⋙ Γ₂ ⟶ toKaroubi (SimplicialObject C)`. -/ @[simps] def natTrans : (N₁ : SimplicialObject C ⥤ _) ⋙ Γ₂ ⟶ toKaroubi _ where app X := { f := { app := fun Δ => (Γ₀.splitting K[X]).desc Δ fun A => PInfty.f A.1.unop.len ≫ X.map A.e.op naturality := fun Δ Δ' θ => by apply (Γ₀.splitting K[X]).hom_ext' intro A change _ ≫ (Γ₀.obj K[X]).map θ ≫ _ = _ simp only [Splitting.ι_desc_assoc, assoc, Γ₀.Obj.map_on_summand'_assoc, Splitting.ι_desc] erw [Γ₀_obj_termwise_mapMono_comp_PInfty_assoc X (image.ι (θ.unop ≫ A.e))] dsimp only [toKaroubi] simp only [← X.map_comp] congr 2 simp only [eqToHom_refl, id_comp, comp_id, ← op_comp] exact Quiver.Hom.unop_inj (A.fac_pull θ) } comm := by apply (Γ₀.splitting K[X]).hom_ext intro n dsimp [N₁] simp only [← Splitting.cofan_inj_id, Splitting.ι_desc, comp_id, Splitting.ι_desc_assoc, assoc, PInfty_f_idem_assoc] } naturality {X Y} f := by ext1 apply (Γ₀.splitting K[X]).hom_ext intro n dsimp [N₁, toKaroubi] simp only [← Splitting.cofan_inj_id, Splitting.ι_desc, Splitting.ι_desc_assoc, assoc, PInfty_f_idem_assoc, Karoubi.comp_f, NatTrans.comp_app, Γ₂_map_f_app, HomologicalComplex.comp_f, AlternatingFaceMapComplex.map_f, PInfty_f_naturality_assoc, NatTrans.naturality, Splitting.IndexSet.id_fst, unop_op, len_mk] end Γ₂N₁ /-- The compatibility isomorphism relating `N₂ ⋙ Γ₂` and `N₁ ⋙ Γ₂`. -/ @[simps! hom_app inv_app] def Γ₂N₂ToKaroubiIso : toKaroubi (SimplicialObject C) ⋙ N₂ ⋙ Γ₂ ≅ N₁ ⋙ Γ₂ := (Functor.associator _ _ _).symm ≪≫ isoWhiskerRight toKaroubiCompN₂IsoN₁ Γ₂ namespace Γ₂N₂ /-- The natural transformation `N₂ ⋙ Γ₂ ⟶ 𝟭 (SimplicialObject C)`. -/ def natTrans : (N₂ : Karoubi (SimplicialObject C) ⥤ _) ⋙ Γ₂ ⟶ 𝟭 _ := ((whiskeringLeft _ _ _).obj (toKaroubi (SimplicialObject C))).preimage (Γ₂N₂ToKaroubiIso.hom ≫ Γ₂N₁.natTrans) theorem natTrans_app_f_app (P : Karoubi (SimplicialObject C)) : Γ₂N₂.natTrans.app P = (N₂ ⋙ Γ₂).map P.decompId_i ≫ (Γ₂N₂ToKaroubiIso.hom ≫ Γ₂N₁.natTrans).app P.X ≫ P.decompId_p := by dsimp only [natTrans] simp only [whiskeringLeft_obj_preimage_app, Functor.id_map, assoc] end Γ₂N₂ theorem compatibility_Γ₂N₁_Γ₂N₂_natTrans (X : SimplicialObject C) : Γ₂N₁.natTrans.app X = (Γ₂N₂ToKaroubiIso.app X).inv ≫ Γ₂N₂.natTrans.app ((toKaroubi (SimplicialObject C)).obj X) := by rw [Γ₂N₂.natTrans_app_f_app] dsimp only [Karoubi.decompId_i_toKaroubi, Karoubi.decompId_p_toKaroubi, Functor.comp_map, NatTrans.comp_app] rw [N₂.map_id, Γ₂.map_id, Iso.app_inv] dsimp only [toKaroubi] erw [id_comp] rw [comp_id, Iso.inv_hom_id_app_assoc] theorem identity_N₂_objectwise (P : Karoubi (SimplicialObject C)) : (N₂Γ₂.inv.app (N₂.obj P) : N₂.obj P ⟶ N₂.obj (Γ₂.obj (N₂.obj P))) ≫ N₂.map (Γ₂N₂.natTrans.app P) = 𝟙 (N₂.obj P) := by ext n have eq₁ : (N₂Γ₂.inv.app (N₂.obj P)).f.f n = PInfty.f n ≫ P.p.app (op ⦋n⦌) ≫ ((Γ₀.splitting (N₂.obj P).X).cofan _).inj (Splitting.IndexSet.id (op ⦋n⦌)) := by simp only [N₂Γ₂_inv_app_f_f, N₂_obj_p_f, assoc] have eq₂ : ((Γ₀.splitting (N₂.obj P).X).cofan _).inj (Splitting.IndexSet.id (op ⦋n⦌)) ≫ (N₂.map (Γ₂N₂.natTrans.app P)).f.f n = PInfty.f n ≫ P.p.app (op ⦋n⦌) := by dsimp rw [PInfty_on_Γ₀_splitting_summand_eq_self_assoc, Γ₂N₂.natTrans_app_f_app] dsimp rw [Γ₂N₂ToKaroubiIso_hom_app, assoc, Splitting.ι_desc_assoc, assoc, assoc] dsimp [toKaroubi] rw [Splitting.ι_desc_assoc] simp [Splitting.IndexSet.e] simp only [Karoubi.comp_f, HomologicalComplex.comp_f, Karoubi.id_f, N₂_obj_p_f, assoc, eq₁, eq₂, PInfty_f_naturality_assoc, app_idem, PInfty_f_idem_assoc] theorem identity_N₂ : (𝟙 (N₂ : Karoubi (SimplicialObject C) ⥤ _) ◫ N₂Γ₂.inv) ≫ (Functor.associator _ _ _).inv ≫ Γ₂N₂.natTrans ◫ 𝟙 (@N₂ C _ _) = 𝟙 N₂ := by ext P : 2 dsimp only [NatTrans.comp_app, NatTrans.hcomp_app, Functor.comp_map, Functor.associator, NatTrans.id_app, Functor.comp_obj] rw [Γ₂.map_id, N₂.map_id, comp_id, id_comp, id_comp, identity_N₂_objectwise P] instance : IsIso (Γ₂N₂.natTrans : (N₂ : Karoubi (SimplicialObject C) ⥤ _) ⋙ _ ⟶ _) := by have : ∀ P : Karoubi (SimplicialObject C), IsIso (Γ₂N₂.natTrans.app P) := by intro P have : IsIso (N₂.map (Γ₂N₂.natTrans.app P)) := by have h := identity_N₂_objectwise P dsimp only [Functor.id_obj, Functor.comp_obj] at h rw [hom_comp_eq_id] at h rw [h] infer_instance exact isIso_of_reflects_iso _ N₂ apply NatIso.isIso_of_isIso_app instance : IsIso (Γ₂N₁.natTrans : (N₁ : SimplicialObject C ⥤ _) ⋙ _ ⟶ _) := by have : ∀ X : SimplicialObject C, IsIso (Γ₂N₁.natTrans.app X) := by intro X rw [compatibility_Γ₂N₁_Γ₂N₂_natTrans] infer_instance apply NatIso.isIso_of_isIso_app /-- The unit isomorphism of the Dold-Kan equivalence. -/ @[simps! inv] def Γ₂N₂ : 𝟭 _ ≅ (N₂ : Karoubi (SimplicialObject C) ⥤ _) ⋙ Γ₂ := (asIso Γ₂N₂.natTrans).symm /-- The natural isomorphism `toKaroubi (SimplicialObject C) ≅ N₁ ⋙ Γ₂`. -/ @[simps! inv] def Γ₂N₁ : toKaroubi _ ≅ (N₁ : SimplicialObject C ⥤ _) ⋙ Γ₂ := (asIso Γ₂N₁.natTrans).symm end DoldKan end AlgebraicTopology		Mathlib/AlgebraicTopology/DoldKan/NCompGamma.lean	254	260
/- Copyright (c) 2023 Yaël Dillies. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yaël Dillies -/ import Mathlib.Algebra.Group.Action.Pointwise.Finset import Mathlib.Algebra.Ring.Nat /-! # e-transforms e-transforms are a family of transformations of pairs of finite sets that aim to reduce the size of the sumset while keeping some invariant the same. This file defines a few of them, to be used as internals of other proofs. ## Main declarations * `Finset.mulDysonETransform`: The Dyson e-transform. Replaces `(s, t)` by `(s ∪ e • t, t ∩ e⁻¹ • s)`. The additive version preserves `\|s ∩ [1, m]\| + \|t ∩ [1, m - e]\|`. * `Finset.mulETransformLeft`/`Finset.mulETransformRight`: Replace `(s, t)` by `(s ∩ s • e, t ∪ e⁻¹ • t)` and `(s ∪ s • e, t ∩ e⁻¹ • t)`. Preserve (together) the sum of the cardinalities (see `Finset.MulETransform.card`). In particular, one of the two transforms increases the sum of the cardinalities and the other one decreases it. See `le_or_lt_of_add_le_add` and around. ## TODO Prove the invariance property of the Dyson e-transform. -/ open MulOpposite open Pointwise variable {α : Type} [DecidableEq α] namespace Finset /-! ### Dyson e-transform -/ section CommGroup variable [CommGroup α] (e : α) (x : Finset α × Finset α) /-- The Dyson e-transform. Turns `(s, t)` into `(s ∪ e • t, t ∩ e⁻¹ • s)`. This reduces the product of the two sets. -/ @[to_additive (attr := simps) "The Dyson e-transform. Turns `(s, t)` into `(s ∪ e +ᵥ t, t ∩ -e +ᵥ s)`. This reduces the sum of the two sets."] def mulDysonETransform : Finset α × Finset α := (x.1 ∪ e • x.2, x.2 ∩ e⁻¹ • x.1) @[to_additive] theorem mulDysonETransform.subset : (mulDysonETransform e x).1 (mulDysonETransform e x).2 ⊆ x.1 * x.2 := by refine union_mul_inter_subset_union.trans (union_subset Subset.rfl ?_) rw [mul_smul_comm, smul_mul_assoc, inv_smul_smul, mul_comm] @[to_additive] theorem mulDysonETransform.card : (mulDysonETransform e x).1.card + (mulDysonETransform e x).2.card = x.1.card + x.2.card := by dsimp rw [← card_smul_finset e (_ ∩ _), smul_finset_inter, smul_inv_smul, inter_comm, card_union_add_card_inter, card_smul_finset] @[to_additive (attr := simp)] theorem mulDysonETransform_idem : mulDysonETransform e (mulDysonETransform e x) = mulDysonETransform e x := by ext : 1 <;> dsimp · rw [smul_finset_inter, smul_inv_smul, inter_comm, union_eq_left] exact inter_subset_union · rw [smul_finset_union, inv_smul_smul, union_comm, inter_eq_left] exact inter_subset_union variable {e x} @[to_additive] theorem mulDysonETransform.smul_finset_snd_subset_fst : e • (mulDysonETransform e x).2 ⊆ (mulDysonETransform e x).1 := by dsimp rw [smul_finset_inter, smul_inv_smul, inter_comm] exact inter_subset_union end CommGroup /-! ### Two unnamed e-transforms The following two transforms both reduce the product/sum of the two sets. Further, one of them must decrease the sum of the size of the sets (and then the other increases it). This pair of transforms doesn't seem to be named in the literature. It is used by Sanders in his bound on Roth numbers, and by DeVos in his proof of Cauchy-Davenport. -/ section Group variable [Group α] (e : α) (x : Finset α × Finset α) /-- An e-transform. Turns `(s, t)` into `(s ∩ s • e, t ∪ e⁻¹ • t)`. This reduces the product of the two sets. -/ @[to_additive (attr := simps) "An e-transform. Turns `(s, t)` into `(s ∩ s +ᵥ e, t ∪ -e +ᵥ t)`. This reduces the sum of the two sets."] def mulETransformLeft : Finset α × Finset α := (x.1 ∩ op e • x.1, x.2 ∪ e⁻¹ • x.2) /-- An e-transform. Turns `(s, t)` into `(s ∪ s • e, t ∩ e⁻¹ • t)`. This reduces the product of the two sets. -/ @[to_additive (attr := simps) "An e-transform. Turns `(s, t)` into `(s ∪ s +ᵥ e, t ∩ -e +ᵥ t)`. This reduces the sum of the two sets."] def mulETransformRight : Finset α × Finset α := (x.1 ∪ op e • x.1, x.2 ∩ e⁻¹ • x.2) @[to_additive (attr := simp)] theorem mulETransformLeft_one : mulETransformLeft 1 x = x := by simp [mulETransformLeft] @[to_additive (attr := simp)] theorem mulETransformRight_one : mulETransformRight 1 x = x := by simp [mulETransformRight] @[to_additive] theorem mulETransformLeft.fst_mul_snd_subset : (mulETransformLeft e x).1 * (mulETransformLeft e x).2 ⊆ x.1 * x.2 := by refine inter_mul_union_subset_union.trans (union_subset Subset.rfl ?_) rw [op_smul_finset_mul_eq_mul_smul_finset, smul_inv_smul] @[to_additive] theorem mulETransformRight.fst_mul_snd_subset : (mulETransformRight e x).1 * (mulETransformRight e x).2 ⊆ x.1 * x.2 := by refine union_mul_inter_subset_union.trans (union_subset Subset.rfl ?_)	rw [op_smul_finset_mul_eq_mul_smul_finset, smul_inv_smul]	Mathlib/Combinatorics/Additive/ETransform.lean	132	132
/- Copyright (c) 2021 Kim Morrison. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Riccardo Brasca, Johan Commelin, Kim Morrison -/ import Mathlib.Analysis.Normed.Group.SemiNormedGrp import Mathlib.Analysis.Normed.Group.Quotient import Mathlib.CategoryTheory.Limits.Shapes.Kernels /-! # Kernels and cokernels in SemiNormedGrp₁ and SemiNormedGrp We show that `SemiNormedGrp₁` has cokernels (for which of course the `cokernel.π f` maps are norm non-increasing), as well as the easier result that `SemiNormedGrp` has cokernels. We also show that `SemiNormedGrp` has kernels. So far, I don't see a way to state nicely what we really want: `SemiNormedGrp` has cokernels, and `cokernel.π f` is norm non-increasing. The problem is that the limits API doesn't promise you any particular model of the cokernel, and in `SemiNormedGrp` one can always take a cokernel and rescale its norm (and hence making `cokernel.π f` arbitrarily large in norm), obtaining another categorical cokernel. -/ open CategoryTheory CategoryTheory.Limits universe u namespace SemiNormedGrp₁ noncomputable section /-- Auxiliary definition for `HasCokernels SemiNormedGrp₁`. -/ def cokernelCocone {X Y : SemiNormedGrp₁.{u}} (f : X ⟶ Y) : Cofork f 0 := Cofork.ofπ (@SemiNormedGrp₁.mkHom _ (Y ⧸ NormedAddGroupHom.range f.1) _ _ f.hom.1.range.normedMk (NormedAddGroupHom.isQuotientQuotient _).norm_le) (by ext x -- Porting note(https://github.com/leanprover-community/mathlib4/issues/5026): was -- simp only [ConcreteCategory.comp_apply, Limits.zero_comp, NormedAddGroupHom.zero_apply, -- SemiNormedGrp₁.mkHom_apply, SemiNormedGrp₁.zero_apply, -- ← NormedAddGroupHom.mem_ker, f.1.range.ker_normedMk, f.1.mem_range] rw [Limits.zero_comp, comp_apply, SemiNormedGrp₁.mkHom_apply, SemiNormedGrp₁.zero_apply, ← NormedAddGroupHom.mem_ker, f.hom.1.range.ker_normedMk, f.hom.1.mem_range] use x) /-- Auxiliary definition for `HasCokernels SemiNormedGrp₁`. -/ def cokernelLift {X Y : SemiNormedGrp₁.{u}} (f : X ⟶ Y) (s : CokernelCofork f) : (cokernelCocone f).pt ⟶ s.pt := by fconstructor -- The lift itself: · apply NormedAddGroupHom.lift _ s.π.1 rintro _ ⟨b, rfl⟩ change (f ≫ s.π) b = 0 simp -- The lift has norm at most one: exact NormedAddGroupHom.lift_normNoninc _ _ _ s.π.2 instance : HasCokernels SemiNormedGrp₁.{u} where has_colimit f := HasColimit.mk { cocone := cokernelCocone f isColimit := isColimitAux _ (cokernelLift f) (fun s => by ext apply NormedAddGroupHom.lift_mk f.1.range rintro _ ⟨b, rfl⟩ change (f ≫ s.π) b = 0 simp) fun _ _ w => SemiNormedGrp₁.hom_ext <\| Subtype.eq (NormedAddGroupHom.lift_unique f.1.range _ _ _ (congr_arg Subtype.val (congr_arg Hom.hom w))) } -- Sanity check example : HasCokernels SemiNormedGrp₁ := by infer_instance end end SemiNormedGrp₁ namespace SemiNormedGrp section EqualizersAndKernels noncomputable instance {V W : SemiNormedGrp.{u}} : Norm (V ⟶ W) where norm f := norm f.hom noncomputable instance {V W : SemiNormedGrp.{u}} : NNNorm (V ⟶ W) where nnnorm f := nnnorm f.hom /-- The equalizer cone for a parallel pair of morphisms of seminormed groups. -/ def fork {V W : SemiNormedGrp.{u}} (f g : V ⟶ W) : Fork f g := @Fork.ofι _ _ _ _ _ _ (of (f - g).hom.ker) (ofHom (NormedAddGroupHom.incl (f - g).hom.ker)) <\| by ext v have : v.1 ∈ (f - g).hom.ker := v.2 simpa [-SetLike.coe_mem, NormedAddGroupHom.mem_ker, sub_eq_zero] using this instance hasLimit_parallelPair {V W : SemiNormedGrp.{u}} (f g : V ⟶ W) : HasLimit (parallelPair f g) where exists_limit := Nonempty.intro { cone := fork f g isLimit := have this := fun (c : Fork f g) => show NormedAddGroupHom.compHom (f - g).hom c.ι.hom = 0 by rw [hom_sub, AddMonoidHom.map_sub, AddMonoidHom.sub_apply, sub_eq_zero] exact congr_arg Hom.hom c.condition Fork.IsLimit.mk _ (fun c => ofHom <\| NormedAddGroupHom.ker.lift (Fork.ι c).hom _ <\| this c) (fun _ => SemiNormedGrp.hom_ext <\| NormedAddGroupHom.ker.incl_comp_lift _ _ (this _)) fun c g h => by ext x; dsimp; simp_rw [← h]; rfl} instance : Limits.HasEqualizers.{u, u + 1} SemiNormedGrp := @hasEqualizers_of_hasLimit_parallelPair SemiNormedGrp _ fun {_ _ f g} => SemiNormedGrp.hasLimit_parallelPair f g end EqualizersAndKernels section Cokernel -- PROJECT: can we reuse the work to construct cokernels in `SemiNormedGrp₁` here? -- I don't see a way to do this that is less work than just repeating the relevant parts. /-- Auxiliary definition for `HasCokernels SemiNormedGrp`. -/ noncomputable def cokernelCocone {X Y : SemiNormedGrp.{u}} (f : X ⟶ Y) : Cofork f 0 := Cofork.ofπ (P := SemiNormedGrp.of (Y ⧸ NormedAddGroupHom.range f.hom)) (ofHom f.hom.range.normedMk) (by aesop) /-- Auxiliary definition for `HasCokernels SemiNormedGrp`. -/ noncomputable def cokernelLift {X Y : SemiNormedGrp.{u}} (f : X ⟶ Y) (s : CokernelCofork f) : (cokernelCocone f).pt ⟶ s.pt := ofHom <\| NormedAddGroupHom.lift _ s.π.hom (by rintro _ ⟨b, rfl⟩ change (f ≫ s.π) b = 0 simp) /-- Auxiliary definition for `HasCokernels SemiNormedGrp`. -/ noncomputable def isColimitCokernelCocone {X Y : SemiNormedGrp.{u}} (f : X ⟶ Y) : IsColimit (cokernelCocone f) := isColimitAux _ (cokernelLift f) (fun s => by ext apply NormedAddGroupHom.lift_mk f.hom.range rintro _ ⟨b, rfl⟩ change (f ≫ s.π) b = 0 simp) fun _ _ w => SemiNormedGrp.hom_ext <\| NormedAddGroupHom.lift_unique f.hom.range _ _ _ <\| congr_arg Hom.hom w instance : HasCokernels SemiNormedGrp.{u} where has_colimit f := HasColimit.mk { cocone := cokernelCocone f isColimit := isColimitCokernelCocone f } -- Sanity check example : HasCokernels SemiNormedGrp := by infer_instance section ExplicitCokernel /-- An explicit choice of cokernel, which has good properties with respect to the norm. -/ noncomputable def explicitCokernel {X Y : SemiNormedGrp.{u}} (f : X ⟶ Y) : SemiNormedGrp.{u} := (cokernelCocone f).pt /-- Descend to the explicit cokernel. -/ noncomputable def explicitCokernelDesc {X Y Z : SemiNormedGrp.{u}} {f : X ⟶ Y} {g : Y ⟶ Z} (w : f ≫ g = 0) : explicitCokernel f ⟶ Z := (isColimitCokernelCocone f).desc (Cofork.ofπ g (by simp [w])) /-- The projection from `Y` to the explicit cokernel of `X ⟶ Y`. -/ noncomputable def explicitCokernelπ {X Y : SemiNormedGrp.{u}} (f : X ⟶ Y) : Y ⟶ explicitCokernel f := (cokernelCocone f).ι.app WalkingParallelPair.one theorem explicitCokernelπ_surjective {X Y : SemiNormedGrp.{u}} {f : X ⟶ Y} : Function.Surjective (explicitCokernelπ f) := Quot.mk_surjective @[reassoc (attr := simp)] theorem comp_explicitCokernelπ {X Y : SemiNormedGrp.{u}} (f : X ⟶ Y) : f ≫ explicitCokernelπ f = 0 := by convert (cokernelCocone f).w WalkingParallelPairHom.left simp @[simp] theorem explicitCokernelπ_apply_dom_eq_zero {X Y : SemiNormedGrp.{u}} {f : X ⟶ Y} (x : X) : (explicitCokernelπ f) (f x) = 0 := show (f ≫ explicitCokernelπ f) x = 0 by rw [comp_explicitCokernelπ]; rfl @[simp, reassoc] theorem explicitCokernelπ_desc {X Y Z : SemiNormedGrp.{u}} {f : X ⟶ Y} {g : Y ⟶ Z} (w : f ≫ g = 0) : explicitCokernelπ f ≫ explicitCokernelDesc w = g := (isColimitCokernelCocone f).fac _ _ @[simp] theorem explicitCokernelπ_desc_apply {X Y Z : SemiNormedGrp.{u}} {f : X ⟶ Y} {g : Y ⟶ Z} {cond : f ≫ g = 0} (x : Y) : explicitCokernelDesc cond (explicitCokernelπ f x) = g x := show (explicitCokernelπ f ≫ explicitCokernelDesc cond) x = g x by rw [explicitCokernelπ_desc] theorem explicitCokernelDesc_unique {X Y Z : SemiNormedGrp.{u}} {f : X ⟶ Y} {g : Y ⟶ Z} (w : f ≫ g = 0) (e : explicitCokernel f ⟶ Z) (he : explicitCokernelπ f ≫ e = g) : e = explicitCokernelDesc w := by apply (isColimitCokernelCocone f).uniq (Cofork.ofπ g (by simp [w])) rintro (_ \| _) · convert w.symm simp · exact he theorem explicitCokernelDesc_comp_eq_desc {X Y Z W : SemiNormedGrp.{u}} {f : X ⟶ Y} {g : Y ⟶ Z} {h : Z ⟶ W} {cond : f ≫ g = 0} : explicitCokernelDesc cond ≫ h = explicitCokernelDesc (show f ≫ g ≫ h = 0 by rw [← CategoryTheory.Category.assoc, cond, Limits.zero_comp]) := by refine explicitCokernelDesc_unique _ _ ?_ rw [← CategoryTheory.Category.assoc, explicitCokernelπ_desc] @[simp] theorem explicitCokernelDesc_zero {X Y Z : SemiNormedGrp.{u}} {f : X ⟶ Y} : explicitCokernelDesc (show f ≫ (0 : Y ⟶ Z) = 0 from CategoryTheory.Limits.comp_zero) = 0 := Eq.symm <\| explicitCokernelDesc_unique _ _ CategoryTheory.Limits.comp_zero @[ext] theorem explicitCokernel_hom_ext {X Y Z : SemiNormedGrp.{u}} {f : X ⟶ Y} (e₁ e₂ : explicitCokernel f ⟶ Z) (h : explicitCokernelπ f ≫ e₁ = explicitCokernelπ f ≫ e₂) : e₁ = e₂ := by let g : Y ⟶ Z := explicitCokernelπ f ≫ e₂ have w : f ≫ g = 0 := by simp [g] have : e₂ = explicitCokernelDesc w := by apply explicitCokernelDesc_unique; rfl rw [this] apply explicitCokernelDesc_unique exact h instance explicitCokernelπ.epi {X Y : SemiNormedGrp.{u}} {f : X ⟶ Y} : Epi (explicitCokernelπ f) := by constructor intro Z g h H ext x rw [H] theorem isQuotient_explicitCokernelπ {X Y : SemiNormedGrp.{u}} (f : X ⟶ Y) : NormedAddGroupHom.IsQuotient (explicitCokernelπ f).hom := NormedAddGroupHom.isQuotientQuotient _ theorem normNoninc_explicitCokernelπ {X Y : SemiNormedGrp.{u}} (f : X ⟶ Y) : (explicitCokernelπ f).hom.NormNoninc := (isQuotient_explicitCokernelπ f).norm_le open scoped NNReal theorem explicitCokernelDesc_norm_le_of_norm_le {X Y Z : SemiNormedGrp.{u}} {f : X ⟶ Y} {g : Y ⟶ Z} (w : f ≫ g = 0) (c : ℝ≥0) (h : ‖g‖ ≤ c) : ‖explicitCokernelDesc w‖ ≤ c := NormedAddGroupHom.lift_norm_le _ _ _ h theorem explicitCokernelDesc_normNoninc {X Y Z : SemiNormedGrp.{u}} {f : X ⟶ Y} {g : Y ⟶ Z} {cond : f ≫ g = 0} (hg : g.hom.NormNoninc) : (explicitCokernelDesc cond).hom.NormNoninc := by refine NormedAddGroupHom.NormNoninc.normNoninc_iff_norm_le_one.2 ?_ rw [← NNReal.coe_one] exact explicitCokernelDesc_norm_le_of_norm_le cond 1 (NormedAddGroupHom.NormNoninc.normNoninc_iff_norm_le_one.1 hg) theorem explicitCokernelDesc_comp_eq_zero {X Y Z W : SemiNormedGrp.{u}} {f : X ⟶ Y} {g : Y ⟶ Z} {h : Z ⟶ W} (cond : f ≫ g = 0) (cond2 : g ≫ h = 0) : explicitCokernelDesc cond ≫ h = 0 := by rw [← cancel_epi (explicitCokernelπ f), ← Category.assoc, explicitCokernelπ_desc] simp [cond2] theorem explicitCokernelDesc_norm_le {X Y Z : SemiNormedGrp.{u}} {f : X ⟶ Y} {g : Y ⟶ Z} (w : f ≫ g = 0) : ‖explicitCokernelDesc w‖ ≤ ‖g‖ := explicitCokernelDesc_norm_le_of_norm_le w ‖g‖₊ le_rfl /-- The explicit cokernel is isomorphic to the usual cokernel. -/ noncomputable def explicitCokernelIso {X Y : SemiNormedGrp.{u}} (f : X ⟶ Y) : explicitCokernel f ≅ cokernel f := (isColimitCokernelCocone f).coconePointUniqueUpToIso (colimit.isColimit _) @[simp] theorem explicitCokernelIso_hom_π {X Y : SemiNormedGrp.{u}} (f : X ⟶ Y) : explicitCokernelπ f ≫ (explicitCokernelIso f).hom = cokernel.π _ := by simp [explicitCokernelπ, explicitCokernelIso, IsColimit.coconePointUniqueUpToIso] @[simp] theorem explicitCokernelIso_inv_π {X Y : SemiNormedGrp.{u}} (f : X ⟶ Y) : cokernel.π f ≫ (explicitCokernelIso f).inv = explicitCokernelπ f := by simp [explicitCokernelπ, explicitCokernelIso] @[simp] theorem explicitCokernelIso_hom_desc {X Y Z : SemiNormedGrp.{u}} {f : X ⟶ Y} {g : Y ⟶ Z} (w : f ≫ g = 0) : (explicitCokernelIso f).hom ≫ cokernel.desc f g w = explicitCokernelDesc w := by	ext1 simp [explicitCokernelDesc, explicitCokernelπ, explicitCokernelIso, IsColimit.coconePointUniqueUpToIso] /-- A special case of `CategoryTheory.Limits.cokernel.map` adapted to `explicitCokernel`. -/ noncomputable def explicitCokernel.map {A B C D : SemiNormedGrp.{u}} {fab : A ⟶ B} {fbd : B ⟶ D} {fac : A ⟶ C} {fcd : C ⟶ D} (h : fab ≫ fbd = fac ≫ fcd) : explicitCokernel fab ⟶ explicitCokernel fcd := @explicitCokernelDesc _ _ _ fab (fbd ≫ explicitCokernelπ _) <\| by simp [reassoc_of% h]	Mathlib/Analysis/Normed/Group/SemiNormedGrp/Kernels.lean	304	312
/- Copyright (c) 2019 Sébastien Gouëzel. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Sébastien Gouëzel -/ import Mathlib.Analysis.NormedSpace.Multilinear.Curry /-! # Formal multilinear series In this file we define `FormalMultilinearSeries 𝕜 E F` to be a family of `n`-multilinear maps for all `n`, designed to model the sequence of derivatives of a function. In other files we use this notion to define `C^n` functions (called `contDiff` in `mathlib`) and analytic functions. ## Notations We use the notation `E [×n]→L[𝕜] F` for the space of continuous multilinear maps on `E^n` with values in `F`. This is the space in which the `n`-th derivative of a function from `E` to `F` lives. ## Tags multilinear, formal series -/ noncomputable section open Set Fin Topology universe u u' v w x variable {𝕜 : Type u} {𝕜' : Type u'} {E : Type v} {F : Type w} {G : Type x} section variable [Semiring 𝕜] [AddCommMonoid E] [Module 𝕜 E] [TopologicalSpace E] [ContinuousAdd E] [ContinuousConstSMul 𝕜 E] [AddCommMonoid F] [Module 𝕜 F] [TopologicalSpace F] [ContinuousAdd F] [ContinuousConstSMul 𝕜 F] [AddCommMonoid G] [Module 𝕜 G] [TopologicalSpace G] [ContinuousAdd G] [ContinuousConstSMul 𝕜 G] /-- A formal multilinear series over a field `𝕜`, from `E` to `F`, is given by a family of multilinear maps from `E^n` to `F` for all `n`. -/ @[nolint unusedArguments] def FormalMultilinearSeries (𝕜 : Type) (E : Type) (F : Type) [Semiring 𝕜] [AddCommMonoid E] [Module 𝕜 E] [TopologicalSpace E] [ContinuousAdd E] [ContinuousConstSMul 𝕜 E] [AddCommMonoid F] [Module 𝕜 F] [TopologicalSpace F] [ContinuousAdd F] [ContinuousConstSMul 𝕜 F] := ∀ n : ℕ, E[×n]→L[𝕜] F -- The `AddCommMonoid` instance should be constructed by a deriving handler. -- https://github.com/leanprover-community/mathlib4/issues/380 instance : AddCommMonoid (FormalMultilinearSeries 𝕜 E F) := inferInstanceAs <\| AddCommMonoid <\| ∀ n : ℕ, E[×n]→L[𝕜] F instance : Inhabited (FormalMultilinearSeries 𝕜 E F) := ⟨0⟩ section Module instance (𝕜') [Semiring 𝕜'] [Module 𝕜' F] [ContinuousConstSMul 𝕜' F] [SMulCommClass 𝕜 𝕜' F] : Module 𝕜' (FormalMultilinearSeries 𝕜 E F) := inferInstanceAs <\| Module 𝕜' <\| ∀ n : ℕ, E[×n]→L[𝕜] F end Module namespace FormalMultilinearSeries @[simp] theorem zero_apply (n : ℕ) : (0 : FormalMultilinearSeries 𝕜 E F) n = 0 := rfl @[simp] theorem add_apply (p q : FormalMultilinearSeries 𝕜 E F) (n : ℕ) : (p + q) n = p n + q n := rfl @[simp] theorem smul_apply [Semiring 𝕜'] [Module 𝕜' F] [ContinuousConstSMul 𝕜' F] [SMulCommClass 𝕜 𝕜' F] (f : FormalMultilinearSeries 𝕜 E F) (n : ℕ) (a : 𝕜') : (a • f) n = a • f n := rfl @[ext] protected theorem ext {p q : FormalMultilinearSeries 𝕜 E F} (h : ∀ n, p n = q n) : p = q := funext h protected theorem ne_iff {p q : FormalMultilinearSeries 𝕜 E F} : p ≠ q ↔ ∃ n, p n ≠ q n := Function.ne_iff /-- Cartesian product of two formal multilinear series (with the same field `𝕜` and the same source space, but possibly different target spaces). -/ def prod (p : FormalMultilinearSeries 𝕜 E F) (q : FormalMultilinearSeries 𝕜 E G) : FormalMultilinearSeries 𝕜 E (F × G) \| n => (p n).prod (q n) /-- Product of formal multilinear series (with the same field `𝕜` and the same source space, but possibly different target spaces). -/ @[simp] def pi {ι : Type} {F : ι → Type} [∀ i, AddCommGroup (F i)] [∀ i, Module 𝕜 (F i)] [∀ i, TopologicalSpace (F i)] [∀ i, IsTopologicalAddGroup (F i)] [∀ i, ContinuousConstSMul 𝕜 (F i)] (p : Π i, FormalMultilinearSeries 𝕜 E (F i)) : FormalMultilinearSeries 𝕜 E (Π i, F i) \| n => ContinuousMultilinearMap.pi (fun i ↦ p i n) /-- Killing the zeroth coefficient in a formal multilinear series -/ def removeZero (p : FormalMultilinearSeries 𝕜 E F) : FormalMultilinearSeries 𝕜 E F \| 0 => 0 \| n + 1 => p (n + 1) @[simp] theorem removeZero_coeff_zero (p : FormalMultilinearSeries 𝕜 E F) : p.removeZero 0 = 0 := rfl @[simp] theorem removeZero_coeff_succ (p : FormalMultilinearSeries 𝕜 E F) (n : ℕ) : p.removeZero (n + 1) = p (n + 1) := rfl theorem removeZero_of_pos (p : FormalMultilinearSeries 𝕜 E F) {n : ℕ} (h : 0 < n) : p.removeZero n = p n := by rw [← Nat.succ_pred_eq_of_pos h] rfl /-- Convenience congruence lemma stating in a dependent setting that, if the arguments to a formal multilinear series are equal, then the values are also equal. -/ theorem congr (p : FormalMultilinearSeries 𝕜 E F) {m n : ℕ} {v : Fin m → E} {w : Fin n → E} (h1 : m = n) (h2 : ∀ (i : ℕ) (him : i < m) (hin : i < n), v ⟨i, him⟩ = w ⟨i, hin⟩) : p m v = p n w := by subst n congr with ⟨i, hi⟩ exact h2 i hi hi lemma congr_zero (p : FormalMultilinearSeries 𝕜 E F) {k l : ℕ} (h : k = l) (h' : p k = 0) : p l = 0 := by subst h; exact h' /-- Composing each term `pₙ` in a formal multilinear series with `(u, ..., u)` where `u` is a fixed continuous linear map, gives a new formal multilinear series `p.compContinuousLinearMap u`. -/ def compContinuousLinearMap (p : FormalMultilinearSeries 𝕜 F G) (u : E →L[𝕜] F) : FormalMultilinearSeries 𝕜 E G := fun n => (p n).compContinuousLinearMap fun _ : Fin n => u @[simp] theorem compContinuousLinearMap_apply (p : FormalMultilinearSeries 𝕜 F G) (u : E →L[𝕜] F) (n : ℕ) (v : Fin n → E) : (p.compContinuousLinearMap u) n v = p n (u ∘ v) := rfl variable (𝕜) [Semiring 𝕜'] [SMul 𝕜 𝕜'] variable [Module 𝕜' E] [ContinuousConstSMul 𝕜' E] [IsScalarTower 𝕜 𝕜' E] variable [Module 𝕜' F] [ContinuousConstSMul 𝕜' F] [IsScalarTower 𝕜 𝕜' F] /-- Reinterpret a formal `𝕜'`-multilinear series as a formal `𝕜`-multilinear series. -/ @[simp] protected def restrictScalars (p : FormalMultilinearSeries 𝕜' E F) : FormalMultilinearSeries 𝕜 E F := fun n => (p n).restrictScalars 𝕜 end FormalMultilinearSeries end namespace FormalMultilinearSeries variable [Ring 𝕜] [AddCommGroup E] [Module 𝕜 E] [TopologicalSpace E] [IsTopologicalAddGroup E] [ContinuousConstSMul 𝕜 E] [AddCommGroup F] [Module 𝕜 F] [TopologicalSpace F] [IsTopologicalAddGroup F] [ContinuousConstSMul 𝕜 F] instance : AddCommGroup (FormalMultilinearSeries 𝕜 E F) := inferInstanceAs <\| AddCommGroup <\| ∀ n : ℕ, E[×n]→L[𝕜] F @[simp] theorem neg_apply (f : FormalMultilinearSeries 𝕜 E F) (n : ℕ) : (-f) n = - f n := rfl @[simp] theorem sub_apply (f g : FormalMultilinearSeries 𝕜 E F) (n : ℕ) : (f - g) n = f n - g n := rfl end FormalMultilinearSeries namespace FormalMultilinearSeries variable [NontriviallyNormedField 𝕜] [NormedAddCommGroup E] [NormedSpace 𝕜 E] [NormedAddCommGroup F] [NormedSpace 𝕜 F] variable (p : FormalMultilinearSeries 𝕜 E F) /-- Forgetting the zeroth term in a formal multilinear series, and interpreting the following terms as multilinear maps into `E →L[𝕜] F`. If `p` is the Taylor series (`HasFTaylorSeriesUpTo`) of a function, then `p.shift` is the Taylor series of the derivative of the function. Note that the `p.sum` of a Taylor series `p` does not give the original function; for a formal multilinear series that sums to the derivative of `p.sum`, see `HasFPowerSeriesOnBall.fderiv`. -/ def shift : FormalMultilinearSeries 𝕜 E (E →L[𝕜] F) := fun n => (p n.succ).curryRight /-- Adding a zeroth term to a formal multilinear series taking values in `E →L[𝕜] F`. This corresponds to starting from a Taylor series (`HasFTaylorSeriesUpTo`) for the derivative of a function, and building a Taylor series for the function itself. -/ def unshift (q : FormalMultilinearSeries 𝕜 E (E →L[𝕜] F)) (z : F) : FormalMultilinearSeries 𝕜 E F \| 0 => (continuousMultilinearCurryFin0 𝕜 E F).symm z \| n + 1 => (continuousMultilinearCurryRightEquiv' 𝕜 n E F).symm (q n) theorem unshift_shift {p : FormalMultilinearSeries 𝕜 E (E →L[𝕜] F)} {z : F} : (p.unshift z).shift = p := by ext1 n simp [shift, unshift] exact LinearIsometryEquiv.apply_symm_apply (continuousMultilinearCurryRightEquiv' 𝕜 n E F) (p n) end FormalMultilinearSeries section variable [Semiring 𝕜] [AddCommMonoid E] [Module 𝕜 E] [TopologicalSpace E] [ContinuousAdd E] [ContinuousConstSMul 𝕜 E] [AddCommMonoid F] [Module 𝕜 F] [TopologicalSpace F] [ContinuousAdd F] [ContinuousConstSMul 𝕜 F] [AddCommMonoid G] [Module 𝕜 G] [TopologicalSpace G] [ContinuousAdd G] [ContinuousConstSMul 𝕜 G] namespace ContinuousLinearMap /-- Composing each term `pₙ` in a formal multilinear series with a continuous linear map `f` on the left gives a new formal multilinear series `f.compFormalMultilinearSeries p` whose general term is `f ∘ pₙ`. -/ def compFormalMultilinearSeries (f : F →L[𝕜] G) (p : FormalMultilinearSeries 𝕜 E F) : FormalMultilinearSeries 𝕜 E G := fun n => f.compContinuousMultilinearMap (p n) @[simp] theorem compFormalMultilinearSeries_apply (f : F →L[𝕜] G) (p : FormalMultilinearSeries 𝕜 E F) (n : ℕ) : (f.compFormalMultilinearSeries p) n = f.compContinuousMultilinearMap (p n) := rfl theorem compFormalMultilinearSeries_apply' (f : F →L[𝕜] G) (p : FormalMultilinearSeries 𝕜 E F) (n : ℕ) (v : Fin n → E) : (f.compFormalMultilinearSeries p) n v = f (p n v) := rfl end ContinuousLinearMap namespace ContinuousMultilinearMap variable {ι : Type} {E : ι → Type*} [∀ i, AddCommGroup (E i)] [∀ i, Module 𝕜 (E i)] [∀ i, TopologicalSpace (E i)] [∀ i, IsTopologicalAddGroup (E i)] [∀ i, ContinuousConstSMul 𝕜 (E i)] [Fintype ι] (f : ContinuousMultilinearMap 𝕜 E F) /-- Realize a ContinuousMultilinearMap on `∀ i : ι, E i` as the evaluation of a FormalMultilinearSeries by choosing an arbitrary identification `ι ≃ Fin (Fintype.card ι)`. -/ noncomputable def toFormalMultilinearSeries : FormalMultilinearSeries 𝕜 (∀ i, E i) F := fun n ↦ if h : Fintype.card ι = n then (f.compContinuousLinearMap .proj).domDomCongr (Fintype.equivFinOfCardEq h) else 0 end ContinuousMultilinearMap end namespace FormalMultilinearSeries section Order variable [Semiring 𝕜] {n : ℕ} [AddCommMonoid E] [Module 𝕜 E] [TopologicalSpace E] [ContinuousAdd E] [ContinuousConstSMul 𝕜 E] [AddCommMonoid F] [Module 𝕜 F] [TopologicalSpace F] [ContinuousAdd F] [ContinuousConstSMul 𝕜 F] {p : FormalMultilinearSeries 𝕜 E F} /-- The index of the first non-zero coefficient in `p` (or `0` if all coefficients are zero). This is the order of the isolated zero of an analytic function `f` at a point if `p` is the Taylor series of `f` at that point. -/ noncomputable def order (p : FormalMultilinearSeries 𝕜 E F) : ℕ := sInf { n \| p n ≠ 0 } @[simp] theorem order_zero : (0 : FormalMultilinearSeries 𝕜 E F).order = 0 := by simp [order] theorem ne_zero_of_order_ne_zero (hp : p.order ≠ 0) : p ≠ 0 := fun h => by simp [h] at hp theorem order_eq_find [DecidablePred fun n => p n ≠ 0] (hp : ∃ n, p n ≠ 0) : p.order = Nat.find hp := by convert Nat.sInf_def hp theorem order_eq_find' [DecidablePred fun n => p n ≠ 0] (hp : p ≠ 0) : p.order = Nat.find (FormalMultilinearSeries.ne_iff.mp hp) := order_eq_find _ theorem order_eq_zero_iff' : p.order = 0 ↔ p = 0 ∨ p 0 ≠ 0 := by simpa [order, Nat.sInf_eq_zero, FormalMultilinearSeries.ext_iff, eq_empty_iff_forall_not_mem] using or_comm theorem order_eq_zero_iff (hp : p ≠ 0) : p.order = 0 ↔ p 0 ≠ 0 := by simp [order_eq_zero_iff', hp] theorem apply_order_ne_zero (hp : p ≠ 0) : p p.order ≠ 0 := Nat.sInf_mem (FormalMultilinearSeries.ne_iff.1 hp) theorem apply_order_ne_zero' (hp : p.order ≠ 0) : p p.order ≠ 0 := apply_order_ne_zero (ne_zero_of_order_ne_zero hp) theorem apply_eq_zero_of_lt_order (hp : n < p.order) : p n = 0 := by_contra <\| Nat.not_mem_of_lt_sInf hp end Order section Coef variable [NontriviallyNormedField 𝕜] [NormedAddCommGroup E] [NormedSpace 𝕜 E] {p : FormalMultilinearSeries 𝕜 𝕜 E} {f : 𝕜 → E} {n : ℕ} {z : 𝕜} {y : Fin n → 𝕜} /-- The `n`th coefficient of `p` when seen as a power series. -/ def coeff (p : FormalMultilinearSeries 𝕜 𝕜 E) (n : ℕ) : E := p n 1 theorem mkPiRing_coeff_eq (p : FormalMultilinearSeries 𝕜 𝕜 E) (n : ℕ) : ContinuousMultilinearMap.mkPiRing 𝕜 (Fin n) (p.coeff n) = p n := (p n).mkPiRing_apply_one_eq_self @[simp] theorem apply_eq_prod_smul_coeff : p n y = (∏ i, y i) • p.coeff n := by	convert (p n).toMultilinearMap.map_smul_univ y 1 simp only [Pi.one_apply, Algebra.id.smul_eq_mul, mul_one]	Mathlib/Analysis/Calculus/FormalMultilinearSeries.lean	302	304
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Mario Carneiro -/ import Mathlib.Data.Set.Constructions import Mathlib.Order.Filter.AtTopBot.CountablyGenerated import Mathlib.Topology.Constructions import Mathlib.Topology.ContinuousOn /-! # Bases of topologies. Countability axioms. A topological basis on a topological space `t` is a collection of sets, such that all open sets can be generated as unions of these sets, without the need to take finite intersections of them. This file introduces a framework for dealing with these collections, and also what more we can say under certain countability conditions on bases, which are referred to as first- and second-countable. We also briefly cover the theory of separable spaces, which are those with a countable, dense subset. If a space is second-countable, and also has a countably generated uniformity filter (for example, if `t` is a metric space), it will automatically be separable (and indeed, these conditions are equivalent in this case). ## Main definitions * `TopologicalSpace.IsTopologicalBasis s`: The topological space `t` has basis `s`. * `TopologicalSpace.SeparableSpace α`: The topological space `t` has a countable, dense subset. * `TopologicalSpace.IsSeparable s`: The set `s` is contained in the closure of a countable set. * `FirstCountableTopology α`: A topology in which `𝓝 x` is countably generated for every `x`. * `SecondCountableTopology α`: A topology which has a topological basis which is countable. ## Main results * `TopologicalSpace.FirstCountableTopology.tendsto_subseq`: In a first-countable space, cluster points are limits of subsequences. * `TopologicalSpace.SecondCountableTopology.isOpen_iUnion_countable`: In a second-countable space, the union of arbitrarily-many open sets is equal to a sub-union of only countably many of these sets. * `TopologicalSpace.SecondCountableTopology.countable_cover_nhds`: Consider `f : α → Set α` with the property that `f x ∈ 𝓝 x` for all `x`. Then there is some countable set `s` whose image covers the space. ## Implementation Notes For our applications we are interested that there exists a countable basis, but we do not need the concrete basis itself. This allows us to declare these type classes as `Prop` to use them as mixins. ## TODO More fine grained instances for `FirstCountableTopology`, `TopologicalSpace.SeparableSpace`, and more. -/ open Set Filter Function Topology noncomputable section namespace TopologicalSpace universe u variable {α : Type u} {β : Type} [t : TopologicalSpace α] {B : Set (Set α)} {s : Set α} /-- A topological basis is one that satisfies the necessary conditions so that it suffices to take unions of the basis sets to get a topology (without taking finite intersections as well). -/ structure IsTopologicalBasis (s : Set (Set α)) : Prop where /-- For every point `x`, the set of `t ∈ s` such that `x ∈ t` is directed downwards. -/ exists_subset_inter : ∀ t₁ ∈ s, ∀ t₂ ∈ s, ∀ x ∈ t₁ ∩ t₂, ∃ t₃ ∈ s, x ∈ t₃ ∧ t₃ ⊆ t₁ ∩ t₂ /-- The sets from `s` cover the whole space. -/ sUnion_eq : ⋃₀ s = univ /-- The topology is generated by sets from `s`. -/ eq_generateFrom : t = generateFrom s /-- If a family of sets `s` generates the topology, then intersections of finite subcollections of `s` form a topological basis. -/ theorem isTopologicalBasis_of_subbasis {s : Set (Set α)} (hs : t = generateFrom s) : IsTopologicalBasis ((fun f => ⋂₀ f) '' { f : Set (Set α) \| f.Finite ∧ f ⊆ s }) := by subst t; letI := generateFrom s refine ⟨?_, ?_, le_antisymm (le_generateFrom ?_) <\| generateFrom_anti fun t ht => ?_⟩ · rintro _ ⟨t₁, ⟨hft₁, ht₁b⟩, rfl⟩ _ ⟨t₂, ⟨hft₂, ht₂b⟩, rfl⟩ x h exact ⟨_, ⟨_, ⟨hft₁.union hft₂, union_subset ht₁b ht₂b⟩, sInter_union t₁ t₂⟩, h, Subset.rfl⟩ · rw [sUnion_image, iUnion₂_eq_univ_iff] exact fun x => ⟨∅, ⟨finite_empty, empty_subset _⟩, sInter_empty.substr <\| mem_univ x⟩ · rintro _ ⟨t, ⟨hft, htb⟩, rfl⟩ exact hft.isOpen_sInter fun s hs ↦ GenerateOpen.basic _ <\| htb hs · rw [← sInter_singleton t] exact ⟨{t}, ⟨finite_singleton t, singleton_subset_iff.2 ht⟩, rfl⟩ theorem isTopologicalBasis_of_subbasis_of_finiteInter {s : Set (Set α)} (hsg : t = generateFrom s) (hsi : FiniteInter s) : IsTopologicalBasis s := by convert isTopologicalBasis_of_subbasis hsg refine le_antisymm (fun t ht ↦ ⟨{t}, by simpa using ht⟩) ?_ rintro _ ⟨g, ⟨hg, hgs⟩, rfl⟩ lift g to Finset (Set α) using hg exact hsi.finiteInter_mem g hgs theorem isTopologicalBasis_of_subbasis_of_inter {r : Set (Set α)} (hsg : t = generateFrom r) (hsi : ∀ ⦃s⦄, s ∈ r → ∀ ⦃t⦄, t ∈ r → s ∩ t ∈ r) : IsTopologicalBasis (insert univ r) := isTopologicalBasis_of_subbasis_of_finiteInter (by simpa using hsg) (FiniteInter.mk₂ hsi) theorem IsTopologicalBasis.of_hasBasis_nhds {s : Set (Set α)} (h_nhds : ∀ a, (𝓝 a).HasBasis (fun t ↦ t ∈ s ∧ a ∈ t) id) : IsTopologicalBasis s where exists_subset_inter t₁ ht₁ t₂ ht₂ x hx := by simpa only [and_assoc, (h_nhds x).mem_iff] using (inter_mem ((h_nhds _).mem_of_mem ⟨ht₁, hx.1⟩) ((h_nhds _).mem_of_mem ⟨ht₂, hx.2⟩)) sUnion_eq := sUnion_eq_univ_iff.2 fun x ↦ (h_nhds x).ex_mem eq_generateFrom := ext_nhds fun x ↦ by simpa only [nhds_generateFrom, and_comm] using (h_nhds x).eq_biInf /-- If a family of open sets `s` is such that every open neighbourhood contains some member of `s`, then `s` is a topological basis. -/ theorem isTopologicalBasis_of_isOpen_of_nhds {s : Set (Set α)} (h_open : ∀ u ∈ s, IsOpen u) (h_nhds : ∀ (a : α) (u : Set α), a ∈ u → IsOpen u → ∃ v ∈ s, a ∈ v ∧ v ⊆ u) : IsTopologicalBasis s := .of_hasBasis_nhds <\| fun a ↦ (nhds_basis_opens a).to_hasBasis' (by simpa [and_assoc] using h_nhds a) fun _ ⟨hts, hat⟩ ↦ (h_open _ hts).mem_nhds hat /-- A set `s` is in the neighbourhood of `a` iff there is some basis set `t`, which contains `a` and is itself contained in `s`. -/ theorem IsTopologicalBasis.mem_nhds_iff {a : α} {s : Set α} {b : Set (Set α)} (hb : IsTopologicalBasis b) : s ∈ 𝓝 a ↔ ∃ t ∈ b, a ∈ t ∧ t ⊆ s := by change s ∈ (𝓝 a).sets ↔ ∃ t ∈ b, a ∈ t ∧ t ⊆ s rw [hb.eq_generateFrom, nhds_generateFrom, biInf_sets_eq] · simp [and_assoc, and_left_comm] · rintro s ⟨hs₁, hs₂⟩ t ⟨ht₁, ht₂⟩ let ⟨u, hu₁, hu₂, hu₃⟩ := hb.1 _ hs₂ _ ht₂ _ ⟨hs₁, ht₁⟩ exact ⟨u, ⟨hu₂, hu₁⟩, le_principal_iff.2 (hu₃.trans inter_subset_left), le_principal_iff.2 (hu₃.trans inter_subset_right)⟩ · rcases eq_univ_iff_forall.1 hb.sUnion_eq a with ⟨i, h1, h2⟩ exact ⟨i, h2, h1⟩ theorem IsTopologicalBasis.isOpen_iff {s : Set α} {b : Set (Set α)} (hb : IsTopologicalBasis b) : IsOpen s ↔ ∀ a ∈ s, ∃ t ∈ b, a ∈ t ∧ t ⊆ s := by simp [isOpen_iff_mem_nhds, hb.mem_nhds_iff] theorem IsTopologicalBasis.of_isOpen_of_subset {s s' : Set (Set α)} (h_open : ∀ u ∈ s', IsOpen u) (hs : IsTopologicalBasis s) (hss' : s ⊆ s') : IsTopologicalBasis s' := isTopologicalBasis_of_isOpen_of_nhds h_open fun a _ ha u_open ↦ have ⟨t, hts, ht⟩ := hs.isOpen_iff.mp u_open a ha; ⟨t, hss' hts, ht⟩ theorem IsTopologicalBasis.nhds_hasBasis {b : Set (Set α)} (hb : IsTopologicalBasis b) {a : α} : (𝓝 a).HasBasis (fun t : Set α => t ∈ b ∧ a ∈ t) fun t => t := ⟨fun s => hb.mem_nhds_iff.trans <\| by simp only [and_assoc]⟩ protected theorem IsTopologicalBasis.isOpen {s : Set α} {b : Set (Set α)} (hb : IsTopologicalBasis b) (hs : s ∈ b) : IsOpen s := by rw [hb.eq_generateFrom] exact .basic s hs theorem IsTopologicalBasis.insert_empty {s : Set (Set α)} (h : IsTopologicalBasis s) : IsTopologicalBasis (insert ∅ s) := h.of_isOpen_of_subset (by rintro _ (rfl \| hu); exacts [isOpen_empty, h.isOpen hu]) (subset_insert ..) theorem IsTopologicalBasis.diff_empty {s : Set (Set α)} (h : IsTopologicalBasis s) : IsTopologicalBasis (s \ {∅}) := isTopologicalBasis_of_isOpen_of_nhds (fun _ hu ↦ h.isOpen hu.1) fun a _ ha hu ↦ have ⟨t, hts, ht⟩ := h.isOpen_iff.mp hu a ha ⟨t, ⟨hts, ne_of_mem_of_not_mem' ht.1 <\| not_mem_empty _⟩, ht⟩ protected theorem IsTopologicalBasis.mem_nhds {a : α} {s : Set α} {b : Set (Set α)} (hb : IsTopologicalBasis b) (hs : s ∈ b) (ha : a ∈ s) : s ∈ 𝓝 a := (hb.isOpen hs).mem_nhds ha theorem IsTopologicalBasis.exists_subset_of_mem_open {b : Set (Set α)} (hb : IsTopologicalBasis b) {a : α} {u : Set α} (au : a ∈ u) (ou : IsOpen u) : ∃ v ∈ b, a ∈ v ∧ v ⊆ u := hb.mem_nhds_iff.1 <\| IsOpen.mem_nhds ou au /-- Any open set is the union of the basis sets contained in it. -/ theorem IsTopologicalBasis.open_eq_sUnion' {B : Set (Set α)} (hB : IsTopologicalBasis B) {u : Set α} (ou : IsOpen u) : u = ⋃₀ { s ∈ B \| s ⊆ u } := ext fun _a => ⟨fun ha => let ⟨b, hb, ab, bu⟩ := hB.exists_subset_of_mem_open ha ou ⟨b, ⟨hb, bu⟩, ab⟩, fun ⟨_b, ⟨_, bu⟩, ab⟩ => bu ab⟩ theorem IsTopologicalBasis.open_eq_sUnion {B : Set (Set α)} (hB : IsTopologicalBasis B) {u : Set α} (ou : IsOpen u) : ∃ S ⊆ B, u = ⋃₀ S := ⟨{ s ∈ B \| s ⊆ u }, fun _ h => h.1, hB.open_eq_sUnion' ou⟩ theorem IsTopologicalBasis.open_iff_eq_sUnion {B : Set (Set α)} (hB : IsTopologicalBasis B) {u : Set α} : IsOpen u ↔ ∃ S ⊆ B, u = ⋃₀ S := ⟨hB.open_eq_sUnion, fun ⟨_S, hSB, hu⟩ => hu.symm ▸ isOpen_sUnion fun _s hs => hB.isOpen (hSB hs)⟩ theorem IsTopologicalBasis.open_eq_iUnion {B : Set (Set α)} (hB : IsTopologicalBasis B) {u : Set α} (ou : IsOpen u) : ∃ (β : Type u) (f : β → Set α), (u = ⋃ i, f i) ∧ ∀ i, f i ∈ B := ⟨↥({ s ∈ B \| s ⊆ u }), (↑), by rw [← sUnion_eq_iUnion] apply hB.open_eq_sUnion' ou, fun s => And.left s.2⟩ lemma IsTopologicalBasis.subset_of_forall_subset {t : Set α} (hB : IsTopologicalBasis B) (hs : IsOpen s) (h : ∀ U ∈ B, U ⊆ s → U ⊆ t) : s ⊆ t := by rw [hB.open_eq_sUnion' hs]; simpa [sUnion_subset_iff] lemma IsTopologicalBasis.eq_of_forall_subset_iff {t : Set α} (hB : IsTopologicalBasis B) (hs : IsOpen s) (ht : IsOpen t) (h : ∀ U ∈ B, U ⊆ s ↔ U ⊆ t) : s = t := by rw [hB.open_eq_sUnion' hs, hB.open_eq_sUnion' ht] exact congr_arg _ (Set.ext fun U ↦ and_congr_right <\| h _) /-- A point `a` is in the closure of `s` iff all basis sets containing `a` intersect `s`. -/ theorem IsTopologicalBasis.mem_closure_iff {b : Set (Set α)} (hb : IsTopologicalBasis b) {s : Set α} {a : α} : a ∈ closure s ↔ ∀ o ∈ b, a ∈ o → (o ∩ s).Nonempty := (mem_closure_iff_nhds_basis' hb.nhds_hasBasis).trans <\| by simp only [and_imp] /-- A set is dense iff it has non-trivial intersection with all basis sets. -/ theorem IsTopologicalBasis.dense_iff {b : Set (Set α)} (hb : IsTopologicalBasis b) {s : Set α} : Dense s ↔ ∀ o ∈ b, Set.Nonempty o → (o ∩ s).Nonempty := by simp only [Dense, hb.mem_closure_iff] exact ⟨fun h o hb ⟨a, ha⟩ => h a o hb ha, fun h a o hb ha => h o hb ⟨a, ha⟩⟩ theorem IsTopologicalBasis.isOpenMap_iff {β} [TopologicalSpace β] {B : Set (Set α)} (hB : IsTopologicalBasis B) {f : α → β} : IsOpenMap f ↔ ∀ s ∈ B, IsOpen (f '' s) := by refine ⟨fun H o ho => H _ (hB.isOpen ho), fun hf o ho => ?_⟩ rw [hB.open_eq_sUnion' ho, sUnion_eq_iUnion, image_iUnion] exact isOpen_iUnion fun s => hf s s.2.1 theorem IsTopologicalBasis.exists_nonempty_subset {B : Set (Set α)} (hb : IsTopologicalBasis B) {u : Set α} (hu : u.Nonempty) (ou : IsOpen u) : ∃ v ∈ B, Set.Nonempty v ∧ v ⊆ u := let ⟨x, hx⟩ := hu let ⟨v, vB, xv, vu⟩ := hb.exists_subset_of_mem_open hx ou ⟨v, vB, ⟨x, xv⟩, vu⟩ theorem isTopologicalBasis_opens : IsTopologicalBasis { U : Set α \| IsOpen U } := isTopologicalBasis_of_isOpen_of_nhds (by tauto) (by tauto) protected lemma IsTopologicalBasis.isInducing {β} [TopologicalSpace β] {f : α → β} {T : Set (Set β)} (hf : IsInducing f) (h : IsTopologicalBasis T) : IsTopologicalBasis ((preimage f) '' T) := .of_hasBasis_nhds fun a ↦ by convert (hf.basis_nhds (h.nhds_hasBasis (a := f a))).to_image_id with s aesop @[deprecated (since := "2024-10-28")] alias IsTopologicalBasis.inducing := IsTopologicalBasis.isInducing protected theorem IsTopologicalBasis.induced {α} [s : TopologicalSpace β] (f : α → β) {T : Set (Set β)} (h : IsTopologicalBasis T) : IsTopologicalBasis (t := induced f s) ((preimage f) '' T) := h.isInducing (t := induced f s) (.induced f) protected theorem IsTopologicalBasis.inf {t₁ t₂ : TopologicalSpace β} {B₁ B₂ : Set (Set β)} (h₁ : IsTopologicalBasis (t := t₁) B₁) (h₂ : IsTopologicalBasis (t := t₂) B₂) : IsTopologicalBasis (t := t₁ ⊓ t₂) (image2 (· ∩ ·) B₁ B₂) := by refine .of_hasBasis_nhds (t := ?_) fun a ↦ ?_ rw [nhds_inf (t₁ := t₁)] convert ((h₁.nhds_hasBasis (t := t₁)).inf (h₂.nhds_hasBasis (t := t₂))).to_image_id aesop theorem IsTopologicalBasis.inf_induced {γ} [s : TopologicalSpace β] {B₁ : Set (Set α)} {B₂ : Set (Set β)} (h₁ : IsTopologicalBasis B₁) (h₂ : IsTopologicalBasis B₂) (f₁ : γ → α) (f₂ : γ → β) : IsTopologicalBasis (t := induced f₁ t ⊓ induced f₂ s) (image2 (f₁ ⁻¹' · ∩ f₂ ⁻¹' ·) B₁ B₂) := by simpa only [image2_image_left, image2_image_right] using (h₁.induced f₁).inf (h₂.induced f₂) protected theorem IsTopologicalBasis.prod {β} [TopologicalSpace β] {B₁ : Set (Set α)} {B₂ : Set (Set β)} (h₁ : IsTopologicalBasis B₁) (h₂ : IsTopologicalBasis B₂) : IsTopologicalBasis (image2 (· ×ˢ ·) B₁ B₂) := h₁.inf_induced h₂ Prod.fst Prod.snd theorem isTopologicalBasis_of_cover {ι} {U : ι → Set α} (Uo : ∀ i, IsOpen (U i)) (Uc : ⋃ i, U i = univ) {b : ∀ i, Set (Set (U i))} (hb : ∀ i, IsTopologicalBasis (b i)) : IsTopologicalBasis (⋃ i : ι, image ((↑) : U i → α) '' b i) := by refine isTopologicalBasis_of_isOpen_of_nhds (fun u hu => ?_) ?_ · simp only [mem_iUnion, mem_image] at hu rcases hu with ⟨i, s, sb, rfl⟩ exact (Uo i).isOpenMap_subtype_val _ ((hb i).isOpen sb) · intro a u ha uo rcases iUnion_eq_univ_iff.1 Uc a with ⟨i, hi⟩ lift a to ↥(U i) using hi rcases (hb i).exists_subset_of_mem_open ha (uo.preimage continuous_subtype_val) with ⟨v, hvb, hav, hvu⟩ exact ⟨(↑) '' v, mem_iUnion.2 ⟨i, mem_image_of_mem _ hvb⟩, mem_image_of_mem _ hav, image_subset_iff.2 hvu⟩ protected theorem IsTopologicalBasis.continuous_iff {β : Type} [TopologicalSpace β] {B : Set (Set β)} (hB : IsTopologicalBasis B) {f : α → β} : Continuous f ↔ ∀ s ∈ B, IsOpen (f ⁻¹' s) := by rw [hB.eq_generateFrom, continuous_generateFrom_iff] @[simp] lemma isTopologicalBasis_empty : IsTopologicalBasis (∅ : Set (Set α)) ↔ IsEmpty α where mp h := by simpa using h.sUnion_eq.symm mpr h := ⟨by simp, by simp [Set.univ_eq_empty_iff.2], Subsingleton.elim ..⟩ variable (α) /-- A separable space is one with a countable dense subset, available through `TopologicalSpace.exists_countable_dense`. If `α` is also known to be nonempty, then `TopologicalSpace.denseSeq` provides a sequence `ℕ → α` with dense range, see `TopologicalSpace.denseRange_denseSeq`. If `α` is a uniform space with countably generated uniformity filter (e.g., an `EMetricSpace`), then this condition is equivalent to `SecondCountableTopology α`. In this case the latter should be used as a typeclass argument in theorems because Lean can automatically deduce `TopologicalSpace.SeparableSpace` from `SecondCountableTopology` but it can't deduce `SecondCountableTopology` from `TopologicalSpace.SeparableSpace`. Porting note (https://github.com/leanprover-community/mathlib4/issues/11215): TODO: the previous paragraph describes the state of the art in Lean 3. We can have instance cycles in Lean 4 but we might want to postpone adding them till after the port. -/ @[mk_iff] class SeparableSpace : Prop where /-- There exists a countable dense set. -/ exists_countable_dense : ∃ s : Set α, s.Countable ∧ Dense s theorem exists_countable_dense [SeparableSpace α] : ∃ s : Set α, s.Countable ∧ Dense s := SeparableSpace.exists_countable_dense /-- A nonempty separable space admits a sequence with dense range. Instead of running `cases` on the conclusion of this lemma, you might want to use `TopologicalSpace.denseSeq` and `TopologicalSpace.denseRange_denseSeq`. If `α` might be empty, then `TopologicalSpace.exists_countable_dense` is the main way to use separability of `α`. -/ theorem exists_dense_seq [SeparableSpace α] [Nonempty α] : ∃ u : ℕ → α, DenseRange u := by obtain ⟨s : Set α, hs, s_dense⟩ := exists_countable_dense α obtain ⟨u, hu⟩ := Set.countable_iff_exists_subset_range.mp hs exact ⟨u, s_dense.mono hu⟩ /-- A dense sequence in a non-empty separable topological space. If `α` might be empty, then `TopologicalSpace.exists_countable_dense` is the main way to use separability of `α`. -/ def denseSeq [SeparableSpace α] [Nonempty α] : ℕ → α := Classical.choose (exists_dense_seq α) /-- The sequence `TopologicalSpace.denseSeq α` has dense range. -/ @[simp] theorem denseRange_denseSeq [SeparableSpace α] [Nonempty α] : DenseRange (denseSeq α) := Classical.choose_spec (exists_dense_seq α) variable {α} instance (priority := 100) Countable.to_separableSpace [Countable α] : SeparableSpace α where exists_countable_dense := ⟨Set.univ, Set.countable_univ, dense_univ⟩ /-- If `f` has a dense range and its domain is countable, then its codomain is a separable space. See also `DenseRange.separableSpace`. -/ theorem SeparableSpace.of_denseRange {ι : Sort _} [Countable ι] (u : ι → α) (hu : DenseRange u) : SeparableSpace α := ⟨⟨range u, countable_range u, hu⟩⟩ alias _root_.DenseRange.separableSpace' := SeparableSpace.of_denseRange /-- If `α` is a separable space and `f : α → β` is a continuous map with dense range, then `β` is a separable space as well. E.g., the completion of a separable uniform space is separable. -/ protected theorem _root_.DenseRange.separableSpace [SeparableSpace α] [TopologicalSpace β] {f : α → β} (h : DenseRange f) (h' : Continuous f) : SeparableSpace β := let ⟨s, s_cnt, s_dense⟩ := exists_countable_dense α ⟨⟨f '' s, Countable.image s_cnt f, h.dense_image h' s_dense⟩⟩ theorem _root_.Topology.IsQuotientMap.separableSpace [SeparableSpace α] [TopologicalSpace β] {f : α → β} (hf : IsQuotientMap f) : SeparableSpace β := hf.surjective.denseRange.separableSpace hf.continuous @[deprecated (since := "2024-10-22")] alias _root_.QuotientMap.separableSpace := Topology.IsQuotientMap.separableSpace /-- The product of two separable spaces is a separable space. -/ instance [TopologicalSpace β] [SeparableSpace α] [SeparableSpace β] : SeparableSpace (α × β) := by rcases exists_countable_dense α with ⟨s, hsc, hsd⟩ rcases exists_countable_dense β with ⟨t, htc, htd⟩ exact ⟨⟨s ×ˢ t, hsc.prod htc, hsd.prod htd⟩⟩ /-- The product of a countable family of separable spaces is a separable space. -/ instance {ι : Type} {X : ι → Type} [∀ i, TopologicalSpace (X i)] [∀ i, SeparableSpace (X i)] [Countable ι] : SeparableSpace (∀ i, X i) := by choose t htc htd using (exists_countable_dense <\| X ·) haveI := fun i ↦ (htc i).to_subtype nontriviality ∀ i, X i; inhabit ∀ i, X i classical set f : (Σ I : Finset ι, ∀ i : I, t i) → ∀ i, X i := fun ⟨I, g⟩ i ↦ if hi : i ∈ I then g ⟨i, hi⟩ else (default : ∀ i, X i) i refine ⟨⟨range f, countable_range f, dense_iff_inter_open.2 fun U hU ⟨g, hg⟩ ↦ ?_⟩⟩ rcases isOpen_pi_iff.1 hU g hg with ⟨I, u, huo, huU⟩ have : ∀ i : I, ∃ y ∈ t i, y ∈ u i := fun i ↦ (htd i).exists_mem_open (huo i i.2).1 ⟨_, (huo i i.2).2⟩ choose y hyt hyu using this lift y to ∀ i : I, t i using hyt refine ⟨f ⟨I, y⟩, huU fun i (hi : i ∈ I) ↦ ?_, mem_range_self (f := f) ⟨I, y⟩⟩ simp only [f, dif_pos hi] exact hyu ⟨i, _⟩ instance [SeparableSpace α] {r : α → α → Prop} : SeparableSpace (Quot r) := isQuotientMap_quot_mk.separableSpace instance [SeparableSpace α] {s : Setoid α} : SeparableSpace (Quotient s) := isQuotientMap_quot_mk.separableSpace /-- A topological space with discrete topology is separable iff it is countable. -/ theorem separableSpace_iff_countable [DiscreteTopology α] : SeparableSpace α ↔ Countable α := by simp [separableSpace_iff, countable_univ_iff] /-- In a separable space, a family of nonempty disjoint open sets is countable. -/ theorem _root_.Pairwise.countable_of_isOpen_disjoint [SeparableSpace α] {ι : Type} {s : ι → Set α} (hd : Pairwise (Disjoint on s)) (ho : ∀ i, IsOpen (s i)) (hne : ∀ i, (s i).Nonempty) : Countable ι := by rcases exists_countable_dense α with ⟨u, u_countable, u_dense⟩ choose f hfu hfs using fun i ↦ u_dense.exists_mem_open (ho i) (hne i) have f_inj : Injective f := fun i j hij ↦ hd.eq <\| not_disjoint_iff.2 ⟨f i, hfs i, hij.symm ▸ hfs j⟩ have := u_countable.to_subtype exact (f_inj.codRestrict hfu).countable /-- In a separable space, a family of nonempty disjoint open sets is countable. -/ theorem _root_.Set.PairwiseDisjoint.countable_of_isOpen [SeparableSpace α] {ι : Type} {s : ι → Set α} {a : Set ι} (h : a.PairwiseDisjoint s) (ho : ∀ i ∈ a, IsOpen (s i)) (hne : ∀ i ∈ a, (s i).Nonempty) : a.Countable := (h.subtype _ _).countable_of_isOpen_disjoint (Subtype.forall.2 ho) (Subtype.forall.2 hne) /-- In a separable space, a family of disjoint sets with nonempty interiors is countable. -/ theorem _root_.Set.PairwiseDisjoint.countable_of_nonempty_interior [SeparableSpace α] {ι : Type} {s : ι → Set α} {a : Set ι} (h : a.PairwiseDisjoint s) (ha : ∀ i ∈ a, (interior (s i)).Nonempty) : a.Countable := (h.mono fun _ => interior_subset).countable_of_isOpen (fun _ _ => isOpen_interior) ha /-- A set `s` in a topological space is separable if it is contained in the closure of a countable set `c`. Beware that this definition does not require that `c` is contained in `s` (to express the latter, use `TopologicalSpace.SeparableSpace s` or `TopologicalSpace.IsSeparable (univ : Set s))`. In metric spaces, the two definitions are equivalent, see `TopologicalSpace.IsSeparable.separableSpace`. -/ def IsSeparable (s : Set α) := ∃ c : Set α, c.Countable ∧ s ⊆ closure c theorem IsSeparable.mono {s u : Set α} (hs : IsSeparable s) (hu : u ⊆ s) : IsSeparable u := by rcases hs with ⟨c, c_count, hs⟩ exact ⟨c, c_count, hu.trans hs⟩ theorem IsSeparable.iUnion {ι : Sort} [Countable ι] {s : ι → Set α} (hs : ∀ i, IsSeparable (s i)) : IsSeparable (⋃ i, s i) := by choose c hc h'c using hs refine ⟨⋃ i, c i, countable_iUnion hc, iUnion_subset_iff.2 fun i => ?_⟩ exact (h'c i).trans (closure_mono (subset_iUnion _ i)) @[simp] theorem isSeparable_iUnion {ι : Sort} [Countable ι] {s : ι → Set α} : IsSeparable (⋃ i, s i) ↔ ∀ i, IsSeparable (s i) := ⟨fun h i ↦ h.mono <\| subset_iUnion s i, .iUnion⟩ @[simp] theorem isSeparable_union {s t : Set α} : IsSeparable (s ∪ t) ↔ IsSeparable s ∧ IsSeparable t := by simp [union_eq_iUnion, and_comm] theorem IsSeparable.union {s u : Set α} (hs : IsSeparable s) (hu : IsSeparable u) : IsSeparable (s ∪ u) := isSeparable_union.2 ⟨hs, hu⟩ @[simp] theorem isSeparable_closure : IsSeparable (closure s) ↔ IsSeparable s := by simp only [IsSeparable, isClosed_closure.closure_subset_iff] protected alias ⟨_, IsSeparable.closure⟩ := isSeparable_closure theorem _root_.Set.Countable.isSeparable {s : Set α} (hs : s.Countable) : IsSeparable s := ⟨s, hs, subset_closure⟩ theorem _root_.Set.Finite.isSeparable {s : Set α} (hs : s.Finite) : IsSeparable s := hs.countable.isSeparable theorem IsSeparable.univ_pi {ι : Type} [Countable ι] {X : ι → Type} {s : ∀ i, Set (X i)} [∀ i, TopologicalSpace (X i)] (h : ∀ i, IsSeparable (s i)) : IsSeparable (univ.pi s) := by classical rcases eq_empty_or_nonempty (univ.pi s) with he \| ⟨f₀, -⟩ · rw [he] exact countable_empty.isSeparable · choose c c_count hc using h haveI := fun i ↦ (c_count i).to_subtype set g : (I : Finset ι) × ((i : I) → c i) → (i : ι) → X i := fun ⟨I, f⟩ i ↦ if hi : i ∈ I then f ⟨i, hi⟩ else f₀ i refine ⟨range g, countable_range g, fun f hf ↦ mem_closure_iff.2 fun o ho hfo ↦ ?_⟩ rcases isOpen_pi_iff.1 ho f hfo with ⟨I, u, huo, hI⟩ rsuffices ⟨f, hf⟩ : ∃ f : (i : I) → c i, g ⟨I, f⟩ ∈ Set.pi I u · exact ⟨g ⟨I, f⟩, hI hf, mem_range_self (f := g) ⟨I, f⟩⟩ suffices H : ∀ i ∈ I, (u i ∩ c i).Nonempty by choose f hfu hfc using H refine ⟨fun i ↦ ⟨f i i.2, hfc i i.2⟩, fun i (hi : i ∈ I) ↦ ?_⟩ simpa only [g, dif_pos hi] using hfu i hi intro i hi exact mem_closure_iff.1 (hc i <\| hf _ trivial) _ (huo i hi).1 (huo i hi).2 lemma isSeparable_pi {ι : Type} [Countable ι] {α : ι → Type} {s : ∀ i, Set (α i)} [∀ i, TopologicalSpace (α i)] (h : ∀ i, IsSeparable (s i)) : IsSeparable {f : ∀ i, α i \| ∀ i, f i ∈ s i} := by simpa only [← mem_univ_pi] using IsSeparable.univ_pi h lemma IsSeparable.prod {β : Type} [TopologicalSpace β] {s : Set α} {t : Set β} (hs : IsSeparable s) (ht : IsSeparable t) : IsSeparable (s ×ˢ t) := by rcases hs with ⟨cs, cs_count, hcs⟩ rcases ht with ⟨ct, ct_count, hct⟩ refine ⟨cs ×ˢ ct, cs_count.prod ct_count, ?_⟩ rw [closure_prod_eq] gcongr theorem IsSeparable.image {β : Type} [TopologicalSpace β] {s : Set α} (hs : IsSeparable s) {f : α → β} (hf : Continuous f) : IsSeparable (f '' s) := by rcases hs with ⟨c, c_count, hc⟩ refine ⟨f '' c, c_count.image _, ?_⟩ rw [image_subset_iff] exact hc.trans (closure_subset_preimage_closure_image hf) theorem _root_.Dense.isSeparable_iff (hs : Dense s) : IsSeparable s ↔ SeparableSpace α := by simp_rw [IsSeparable, separableSpace_iff, dense_iff_closure_eq, ← univ_subset_iff, ← hs.closure_eq, isClosed_closure.closure_subset_iff] theorem isSeparable_univ_iff : IsSeparable (univ : Set α) ↔ SeparableSpace α := dense_univ.isSeparable_iff theorem isSeparable_range [TopologicalSpace β] [SeparableSpace α] {f : α → β} (hf : Continuous f) : IsSeparable (range f) := image_univ (f := f) ▸ (isSeparable_univ_iff.2 ‹_›).image hf theorem IsSeparable.of_subtype (s : Set α) [SeparableSpace s] : IsSeparable s := by simpa using isSeparable_range (continuous_subtype_val (p := (· ∈ s))) theorem IsSeparable.of_separableSpace [h : SeparableSpace α] (s : Set α) : IsSeparable s := IsSeparable.mono (isSeparable_univ_iff.2 h) (subset_univ _) end TopologicalSpace open TopologicalSpace protected theorem IsTopologicalBasis.iInf {β : Type} {ι : Type} {t : ι → TopologicalSpace β} {T : ι → Set (Set β)} (h_basis : ∀ i, IsTopologicalBasis (t := t i) (T i)) : IsTopologicalBasis (t := ⨅ i, t i) { S \| ∃ (U : ι → Set β) (F : Finset ι), (∀ i, i ∈ F → U i ∈ T i) ∧ S = ⋂ i ∈ F, U i } := by let _ := ⨅ i, t i refine isTopologicalBasis_of_isOpen_of_nhds ?_ ?_ · rintro - ⟨U, F, hU, rfl⟩ refine isOpen_biInter_finset fun i hi ↦ (h_basis i).isOpen (t := t i) (hU i hi) \|>.mono (iInf_le _ _) · intro a u ha hu rcases (nhds_iInf (t := t) (a := a)).symm ▸ hasBasis_iInf' (fun i ↦ (h_basis i).nhds_hasBasis (t := t i)) \|>.mem_iff.1 (hu.mem_nhds ha) with ⟨⟨F, U⟩, ⟨hF, hU⟩, hUu⟩ refine ⟨_, ⟨U, hF.toFinset, ?_, rfl⟩, ?_, ?_⟩ <;> simp only [Finite.mem_toFinset, mem_iInter] · exact fun i hi ↦ (hU i hi).1 · exact fun i hi ↦ (hU i hi).2 · exact hUu theorem IsTopologicalBasis.iInf_induced {β : Type} {ι : Type} {X : ι → Type} [t : Π i, TopologicalSpace (X i)] {T : Π i, Set (Set (X i))} (cond : ∀ i, IsTopologicalBasis (T i)) (f : Π i, β → X i) : IsTopologicalBasis (t := ⨅ i, induced (f i) (t i)) { S \| ∃ (U : ∀ i, Set (X i)) (F : Finset ι), (∀ i, i ∈ F → U i ∈ T i) ∧ S = ⋂ (i) (_ : i ∈ F), f i ⁻¹' U i } := by convert IsTopologicalBasis.iInf (fun i ↦ (cond i).induced (f i)) with S constructor <;> rintro ⟨U, F, hUT, hSU⟩ · exact ⟨fun i ↦ (f i) ⁻¹' (U i), F, fun i hi ↦ mem_image_of_mem _ (hUT i hi), hSU⟩ · choose! U' hU' hUU' using hUT exact ⟨U', F, hU', hSU ▸ (.symm <\| iInter₂_congr hUU')⟩ theorem isTopologicalBasis_pi {ι : Type} {X : ι → Type} [∀ i, TopologicalSpace (X i)] {T : ∀ i, Set (Set (X i))} (cond : ∀ i, IsTopologicalBasis (T i)) : IsTopologicalBasis { S \| ∃ (U : ∀ i, Set (X i)) (F : Finset ι), (∀ i, i ∈ F → U i ∈ T i) ∧ S = (F : Set ι).pi U } := by simpa only [Set.pi_def] using IsTopologicalBasis.iInf_induced cond eval theorem isTopologicalBasis_singletons (α : Type) [TopologicalSpace α] [DiscreteTopology α] : IsTopologicalBasis { s \| ∃ x : α, (s : Set α) = {x} } := isTopologicalBasis_of_isOpen_of_nhds (fun _ _ => isOpen_discrete _) fun x _ hx _ => ⟨{x}, ⟨x, rfl⟩, mem_singleton x, singleton_subset_iff.2 hx⟩ theorem isTopologicalBasis_subtype {α : Type} [TopologicalSpace α] {B : Set (Set α)} (h : TopologicalSpace.IsTopologicalBasis B) (p : α → Prop) : IsTopologicalBasis (Set.preimage (Subtype.val (p := p)) '' B) := h.isInducing ⟨rfl⟩ section variable {ι : Type} {π : ι → Type} [∀ i, TopologicalSpace (π i)] lemma isOpenMap_eval (i : ι) : IsOpenMap (Function.eval i : (∀ i, π i) → π i) := by classical refine (isTopologicalBasis_pi fun _ ↦ isTopologicalBasis_opens).isOpenMap_iff.2 ?_ rintro _ ⟨U, s, hU, rfl⟩ obtain h \| h := ((s : Set ι).pi U).eq_empty_or_nonempty · simp [h] by_cases hi : i ∈ s · rw [eval_image_pi (mod_cast hi) h] exact hU _ hi · rw [eval_image_pi_of_not_mem (mod_cast hi), if_pos h] exact isOpen_univ end theorem Dense.exists_countable_dense_subset {α : Type} [TopologicalSpace α] {s : Set α} [SeparableSpace s] (hs : Dense s) : ∃ t ⊆ s, t.Countable ∧ Dense t := let ⟨t, htc, htd⟩ := exists_countable_dense s ⟨(↑) '' t, Subtype.coe_image_subset s t, htc.image Subtype.val, hs.denseRange_val.dense_image continuous_subtype_val htd⟩ /-- Let `s` be a dense set in a topological space `α` with partial order structure. If `s` is a separable space (e.g., if `α` has a second countable topology), then there exists a countable dense subset `t ⊆ s` such that `t` contains bottom/top element of `α` when they exist and belong to `s`. For a dense subset containing neither bot nor top elements, see `Dense.exists_countable_dense_subset_no_bot_top`. -/ theorem Dense.exists_countable_dense_subset_bot_top {α : Type} [TopologicalSpace α] [PartialOrder α] {s : Set α} [SeparableSpace s] (hs : Dense s) : ∃ t ⊆ s, t.Countable ∧ Dense t ∧ (∀ x, IsBot x → x ∈ s → x ∈ t) ∧ ∀ x, IsTop x → x ∈ s → x ∈ t := by rcases hs.exists_countable_dense_subset with ⟨t, hts, htc, htd⟩ refine ⟨(t ∪ ({ x \| IsBot x } ∪ { x \| IsTop x })) ∩ s, ?_, ?_, ?_, ?_, ?_⟩ exacts [inter_subset_right, (htc.union ((countable_isBot α).union (countable_isTop α))).mono inter_subset_left, htd.mono (subset_inter subset_union_left hts), fun x hx hxs => ⟨Or.inr <\| Or.inl hx, hxs⟩, fun x hx hxs => ⟨Or.inr <\| Or.inr hx, hxs⟩] instance separableSpace_univ {α : Type} [TopologicalSpace α] [SeparableSpace α] : SeparableSpace (univ : Set α) := (Equiv.Set.univ α).symm.surjective.denseRange.separableSpace (continuous_id.subtype_mk _) /-- If `α` is a separable topological space with a partial order, then there exists a countable dense set `s : Set α` that contains those of both bottom and top elements of `α` that actually exist. For a dense set containing neither bot nor top elements, see `exists_countable_dense_no_bot_top`. -/ theorem exists_countable_dense_bot_top (α : Type) [TopologicalSpace α] [SeparableSpace α] [PartialOrder α] : ∃ s : Set α, s.Countable ∧ Dense s ∧ (∀ x, IsBot x → x ∈ s) ∧ ∀ x, IsTop x → x ∈ s := by simpa using dense_univ.exists_countable_dense_subset_bot_top namespace TopologicalSpace universe u variable (α : Type u) [t : TopologicalSpace α] /-- A first-countable space is one in which every point has a countable neighborhood basis. -/ class _root_.FirstCountableTopology : Prop where /-- The filter `𝓝 a` is countably generated for all points `a`. -/ nhds_generated_countable : ∀ a : α, (𝓝 a).IsCountablyGenerated attribute [instance] FirstCountableTopology.nhds_generated_countable /-- If `β` is a first-countable space, then its induced topology via `f` on `α` is also first-countable. -/ theorem firstCountableTopology_induced (α β : Type) [t : TopologicalSpace β] [FirstCountableTopology β] (f : α → β) : @FirstCountableTopology α (t.induced f) := let _ := t.induced f ⟨fun x ↦ nhds_induced f x ▸ inferInstance⟩ variable {α} instance Subtype.firstCountableTopology (s : Set α) [FirstCountableTopology α] : FirstCountableTopology s := firstCountableTopology_induced s α (↑) protected theorem _root_.Topology.IsInducing.firstCountableTopology {β : Type} [TopologicalSpace β] [FirstCountableTopology β] {f : α → β} (hf : IsInducing f) : FirstCountableTopology α := by rw [hf.1] exact firstCountableTopology_induced α β f @[deprecated (since := "2024-10-28")] alias _root_.Inducing.firstCountableTopology := IsInducing.firstCountableTopology protected theorem _root_.Topology.IsEmbedding.firstCountableTopology {β : Type} [TopologicalSpace β] [FirstCountableTopology β] {f : α → β} (hf : IsEmbedding f) : FirstCountableTopology α := hf.1.firstCountableTopology @[deprecated (since := "2024-10-26")] alias _root_.Embedding.firstCountableTopology := IsEmbedding.firstCountableTopology namespace FirstCountableTopology /-- In a first-countable space, a cluster point `x` of a sequence is the limit of some subsequence. -/ theorem tendsto_subseq [FirstCountableTopology α] {u : ℕ → α} {x : α} (hx : MapClusterPt x atTop u) : ∃ ψ : ℕ → ℕ, StrictMono ψ ∧ Tendsto (u ∘ ψ) atTop (𝓝 x) := subseq_tendsto_of_neBot hx end FirstCountableTopology instance {β} [TopologicalSpace β] [FirstCountableTopology α] [FirstCountableTopology β] : FirstCountableTopology (α × β) := ⟨fun ⟨x, y⟩ => by rw [nhds_prod_eq]; infer_instance⟩ section Pi instance {ι : Type} {π : ι → Type} [Countable ι] [∀ i, TopologicalSpace (π i)] [∀ i, FirstCountableTopology (π i)] : FirstCountableTopology (∀ i, π i) := ⟨fun f => by rw [nhds_pi]; infer_instance⟩ end Pi instance isCountablyGenerated_nhdsWithin (x : α) [IsCountablyGenerated (𝓝 x)] (s : Set α) : IsCountablyGenerated (𝓝[s] x) := Inf.isCountablyGenerated _ _ variable (α) in /-- A second-countable space is one with a countable basis. -/ class _root_.SecondCountableTopology : Prop where /-- There exists a countable set of sets that generates the topology. -/ is_open_generated_countable : ∃ b : Set (Set α), b.Countable ∧ t = TopologicalSpace.generateFrom b protected theorem IsTopologicalBasis.secondCountableTopology {b : Set (Set α)} (hb : IsTopologicalBasis b) (hc : b.Countable) : SecondCountableTopology α := ⟨⟨b, hc, hb.eq_generateFrom⟩⟩ lemma SecondCountableTopology.mk' {α} {b : Set (Set α)} (hc : b.Countable) : @SecondCountableTopology α (generateFrom b) := @SecondCountableTopology.mk α (generateFrom b) ⟨b, hc, rfl⟩ instance _root_.Finite.toSecondCountableTopology [Finite α] : SecondCountableTopology α where is_open_generated_countable := ⟨_, {U \| IsOpen U}.to_countable, TopologicalSpace.isTopologicalBasis_opens.eq_generateFrom⟩ variable (α) theorem exists_countable_basis [SecondCountableTopology α] : ∃ b : Set (Set α), b.Countable ∧ ∅ ∉ b ∧ IsTopologicalBasis b := by obtain ⟨b, hb₁, hb₂⟩ := @SecondCountableTopology.is_open_generated_countable α _ _ refine ⟨_, ?_, not_mem_diff_of_mem ?_, (isTopologicalBasis_of_subbasis hb₂).diff_empty⟩ exacts [((countable_setOf_finite_subset hb₁).image _).mono diff_subset, rfl] /-- A countable topological basis of `α`. -/ def countableBasis [SecondCountableTopology α] : Set (Set α) := (exists_countable_basis α).choose theorem countable_countableBasis [SecondCountableTopology α] : (countableBasis α).Countable := (exists_countable_basis α).choose_spec.1 instance encodableCountableBasis [SecondCountableTopology α] : Encodable (countableBasis α) := (countable_countableBasis α).toEncodable theorem empty_nmem_countableBasis [SecondCountableTopology α] : ∅ ∉ countableBasis α := (exists_countable_basis α).choose_spec.2.1 theorem isBasis_countableBasis [SecondCountableTopology α] : IsTopologicalBasis (countableBasis α) := (exists_countable_basis α).choose_spec.2.2 theorem eq_generateFrom_countableBasis [SecondCountableTopology α] : ‹TopologicalSpace α› = generateFrom (countableBasis α) := (isBasis_countableBasis α).eq_generateFrom variable {α} theorem isOpen_of_mem_countableBasis [SecondCountableTopology α] {s : Set α} (hs : s ∈ countableBasis α) : IsOpen s := (isBasis_countableBasis α).isOpen hs theorem nonempty_of_mem_countableBasis [SecondCountableTopology α] {s : Set α} (hs : s ∈ countableBasis α) : s.Nonempty := nonempty_iff_ne_empty.2 <\| ne_of_mem_of_not_mem hs <\| empty_nmem_countableBasis α variable (α) -- see Note [lower instance priority] instance (priority := 100) SecondCountableTopology.to_firstCountableTopology [SecondCountableTopology α] : FirstCountableTopology α := ⟨fun _ => HasCountableBasis.isCountablyGenerated <\| ⟨(isBasis_countableBasis α).nhds_hasBasis, (countable_countableBasis α).mono inter_subset_left⟩⟩ /-- If `β` is a second-countable space, then its induced topology via `f` on `α` is also second-countable. -/ theorem secondCountableTopology_induced (α β) [t : TopologicalSpace β] [SecondCountableTopology β] (f : α → β) : @SecondCountableTopology α (t.induced f) := by rcases @SecondCountableTopology.is_open_generated_countable β _ _ with ⟨b, hb, eq⟩ letI := t.induced f refine { is_open_generated_countable := ⟨preimage f '' b, hb.image _, ?_⟩ } rw [eq, induced_generateFrom_eq] variable {α} instance Subtype.secondCountableTopology (s : Set α) [SecondCountableTopology α] : SecondCountableTopology s := secondCountableTopology_induced s α (↑) lemma secondCountableTopology_iInf {α ι} [Countable ι] {t : ι → TopologicalSpace α} (ht : ∀ i, @SecondCountableTopology α (t i)) : @SecondCountableTopology α (⨅ i, t i) := by rw [funext fun i => @eq_generateFrom_countableBasis α (t i) (ht i), ← generateFrom_iUnion] exact SecondCountableTopology.mk' <\| countable_iUnion fun i => @countable_countableBasis _ (t i) (ht i) -- TODO: more fine grained instances for `FirstCountableTopology`, `SeparableSpace`, `T2Space`, ... instance {β : Type} [TopologicalSpace β] [SecondCountableTopology α] [SecondCountableTopology β] : SecondCountableTopology (α × β) := ((isBasis_countableBasis α).prod (isBasis_countableBasis β)).secondCountableTopology <\| (countable_countableBasis α).image2 (countable_countableBasis β) _ instance {ι : Type} {π : ι → Type} [Countable ι] [∀ a, TopologicalSpace (π a)] [∀ a, SecondCountableTopology (π a)] : SecondCountableTopology (∀ a, π a) := secondCountableTopology_iInf fun _ => secondCountableTopology_induced _ _ _ -- see Note [lower instance priority] instance (priority := 100) SecondCountableTopology.to_separableSpace [SecondCountableTopology α] : SeparableSpace α := by choose p hp using fun s : countableBasis α => nonempty_of_mem_countableBasis s.2 exact ⟨⟨range p, countable_range _, (isBasis_countableBasis α).dense_iff.2 fun o ho _ => ⟨p ⟨o, ho⟩, hp ⟨o, _⟩, mem_range_self _⟩⟩⟩ /-- A countable open cover induces a second-countable topology if all open covers are themselves second countable. -/ theorem secondCountableTopology_of_countable_cover {ι} [Countable ι] {U : ι → Set α} [∀ i, SecondCountableTopology (U i)] (Uo : ∀ i, IsOpen (U i)) (hc : ⋃ i, U i = univ) : SecondCountableTopology α := haveI : IsTopologicalBasis (⋃ i, image ((↑) : U i → α) '' countableBasis (U i)) := isTopologicalBasis_of_cover Uo hc fun i => isBasis_countableBasis (U i) this.secondCountableTopology (countable_iUnion fun _ => (countable_countableBasis _).image _) /-- In a second-countable space, an open set, given as a union of open sets, is equal to the union of countably many of those sets. In particular, any open covering of `α` has a countable subcover: α is a Lindelöf space. -/ theorem isOpen_iUnion_countable [SecondCountableTopology α] {ι} (s : ι → Set α) (H : ∀ i, IsOpen (s i)) : ∃ T : Set ι, T.Countable ∧ ⋃ i ∈ T, s i = ⋃ i, s i := by let B := { b ∈ countableBasis α \| ∃ i, b ⊆ s i } choose f hf using fun b : B => b.2.2 haveI : Countable B := ((countable_countableBasis α).mono (sep_subset _ _)).to_subtype refine ⟨_, countable_range f, (iUnion₂_subset_iUnion _ _).antisymm (sUnion_subset ?_)⟩ rintro _ ⟨i, rfl⟩ x xs rcases (isBasis_countableBasis α).exists_subset_of_mem_open xs (H _) with ⟨b, hb, xb, bs⟩ exact ⟨_, ⟨_, rfl⟩, _, ⟨⟨⟨_, hb, _, bs⟩, rfl⟩, rfl⟩, hf _ xb⟩ theorem isOpen_biUnion_countable [SecondCountableTopology α] {ι : Type} (I : Set ι) (s : ι → Set α) (H : ∀ i ∈ I, IsOpen (s i)) : ∃ T ⊆ I, T.Countable ∧ ⋃ i ∈ T, s i = ⋃ i ∈ I, s i := by simp_rw [← Subtype.exists_set_subtype, biUnion_image] rcases isOpen_iUnion_countable (fun i : I ↦ s i) fun i ↦ H i i.2 with ⟨T, hTc, hU⟩ exact ⟨T, hTc.image _, hU.trans <\| iUnion_subtype ..⟩ theorem isOpen_sUnion_countable [SecondCountableTopology α] (S : Set (Set α)) (H : ∀ s ∈ S, IsOpen s) : ∃ T : Set (Set α), T.Countable ∧ T ⊆ S ∧ ⋃₀ T = ⋃₀ S := by simpa only [and_left_comm, sUnion_eq_biUnion] using isOpen_biUnion_countable S id H /-- In a topological space with second countable topology, if `f` is a function that sends each point `x` to a neighborhood of `x`, then for some countable set `s`, the neighborhoods `f x`, `x ∈ s`, cover the whole space. -/ theorem countable_cover_nhds [SecondCountableTopology α] {f : α → Set α} (hf : ∀ x, f x ∈ 𝓝 x) : ∃ s : Set α, s.Countable ∧ ⋃ x ∈ s, f x = univ := by rcases isOpen_iUnion_countable (fun x => interior (f x)) fun x => isOpen_interior with ⟨s, hsc, hsU⟩ suffices ⋃ x ∈ s, interior (f x) = univ from ⟨s, hsc, flip eq_univ_of_subset this <\| iUnion₂_mono fun _ _ => interior_subset⟩ simp only [hsU, eq_univ_iff_forall, mem_iUnion] exact fun x => ⟨x, mem_interior_iff_mem_nhds.2 (hf x)⟩ theorem countable_cover_nhdsWithin [SecondCountableTopology α] {f : α → Set α} {s : Set α} (hf : ∀ x ∈ s, f x ∈ 𝓝[s] x) : ∃ t ⊆ s, t.Countable ∧ s ⊆ ⋃ x ∈ t, f x := by have : ∀ x : s, (↑) ⁻¹' f x ∈ 𝓝 x := fun x => preimage_coe_mem_nhds_subtype.2 (hf x x.2) rcases countable_cover_nhds this with ⟨t, htc, htU⟩ refine ⟨(↑) '' t, Subtype.coe_image_subset _ _, htc.image _, fun x hx => ?_⟩ simp only [biUnion_image, eq_univ_iff_forall, ← preimage_iUnion, mem_preimage] at htU ⊢ exact htU ⟨x, hx⟩ section Sigma variable {ι : Type} {E : ι → Type} [∀ i, TopologicalSpace (E i)] /-- In a disjoint union space `Σ i, E i`, one can form a topological basis by taking the union of topological bases on each of the parts of the space. -/ theorem IsTopologicalBasis.sigma {s : ∀ i : ι, Set (Set (E i))} (hs : ∀ i, IsTopologicalBasis (s i)) : IsTopologicalBasis (⋃ i : ι, (fun u => (Sigma.mk i '' u : Set (Σi, E i))) '' s i) := by refine .of_hasBasis_nhds fun a ↦ ?_ rw [Sigma.nhds_eq] convert (((hs a.1).nhds_hasBasis).map _).to_image_id aesop /-- A countable disjoint union of second countable spaces is second countable. -/ instance [Countable ι] [∀ i, SecondCountableTopology (E i)] : SecondCountableTopology (Σi, E i) := by let b := ⋃ i : ι, (fun u => (Sigma.mk i '' u : Set (Σi, E i))) '' countableBasis (E i) have A : IsTopologicalBasis b := IsTopologicalBasis.sigma fun i => isBasis_countableBasis _ have B : b.Countable := countable_iUnion fun i => (countable_countableBasis _).image _ exact A.secondCountableTopology B end Sigma section Sum variable {β : Type} [TopologicalSpace β] /-- In a sum space `α ⊕ β`, one can form a topological basis by taking the union of topological bases on each of the two components. -/ theorem IsTopologicalBasis.sum {s : Set (Set α)} (hs : IsTopologicalBasis s) {t : Set (Set β)}	(ht : IsTopologicalBasis t) : IsTopologicalBasis ((fun u => Sum.inl '' u) '' s ∪ (fun u => Sum.inr '' u) '' t) := by apply isTopologicalBasis_of_isOpen_of_nhds · rintro u (⟨w, hw, rfl⟩ \| ⟨w, hw, rfl⟩) · exact IsOpenEmbedding.inl.isOpenMap w (hs.isOpen hw) · exact IsOpenEmbedding.inr.isOpenMap w (ht.isOpen hw) · rintro (x \| x) u hxu u_open · obtain ⟨v, vs, xv, vu⟩ : ∃ v ∈ s, x ∈ v ∧ v ⊆ Sum.inl ⁻¹' u := hs.exists_subset_of_mem_open hxu (isOpen_sum_iff.1 u_open).1	Mathlib/Topology/Bases.lean	881	889
/- Copyright (c) 2024 Peter Nelson. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Peter Nelson -/ import Mathlib.Data.Matroid.Minor.Restrict /-! # Some constructions of matroids This file defines some very elementary examples of matroids, namely those with at most one base. ## Main definitions * `emptyOn α` is the matroid on `α` with empty ground set. For `E : Set α`, ... * `loopyOn E` is the matroid on `E` whose elements are all loops, or equivalently in which `∅` is the only base. * `freeOn E` is the 'free matroid' whose ground set `E` is the only base. * For `I ⊆ E`, `uniqueBaseOn I E` is the matroid with ground set `E` in which `I` is the only base. ## Implementation details To avoid the tedious process of certifying the matroid axioms for each of these easy examples, we bootstrap the definitions starting with `emptyOn α` (which `simp` can prove is a matroid) and then construct the other examples using duality and restriction. -/ assert_not_exists Field variable {α : Type} {M : Matroid α} {E B I X R J : Set α} namespace Matroid open Set section EmptyOn /-- The `Matroid α` with empty ground set. -/ def emptyOn (α : Type) : Matroid α where E := ∅ IsBase := (· = ∅) Indep := (· = ∅) indep_iff' := by simp [subset_empty_iff] exists_isBase := ⟨∅, rfl⟩ isBase_exchange := by rintro _ _ rfl; simp maximality := by rintro _ _ _ rfl -; exact ⟨∅, by simp [Maximal]⟩ subset_ground := by simp @[simp] theorem emptyOn_ground : (emptyOn α).E = ∅ := rfl @[simp] theorem emptyOn_isBase_iff : (emptyOn α).IsBase B ↔ B = ∅ := Iff.rfl @[simp] theorem emptyOn_indep_iff : (emptyOn α).Indep I ↔ I = ∅ := Iff.rfl theorem ground_eq_empty_iff : (M.E = ∅) ↔ M = emptyOn α := by simp only [emptyOn, ext_iff_indep, iff_self_and]	exact fun h ↦ by simp [h, subset_empty_iff]	Mathlib/Data/Matroid/Constructions.lean	61	62
/- Copyright (c) 2022 Daniel Roca González. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Daniel Roca González -/ import Mathlib.Analysis.InnerProductSpace.Dual /-! # The Lax-Milgram Theorem We consider a Hilbert space `V` over `ℝ` equipped with a bounded bilinear form `B : V →L[ℝ] V →L[ℝ] ℝ`. Recall that a bilinear form `B : V →L[ℝ] V →L[ℝ] ℝ` is coercive iff `∃ C, (0 < C) ∧ ∀ u, C * ‖u‖ * ‖u‖ ≤ B u u`. Under the hypothesis that `B` is coercive we prove the Lax-Milgram theorem: that is, the map `InnerProductSpace.continuousLinearMapOfBilin` from `Analysis.InnerProductSpace.Dual` can be upgraded to a continuous equivalence `IsCoercive.continuousLinearEquivOfBilin : V ≃L[ℝ] V`. ## References * We follow the notes of Peter Howard's Spring 2020 M612: Partial Differential Equations lecture, see[howard] ## Tags dual, Lax-Milgram -/ noncomputable section open RCLike LinearMap ContinuousLinearMap InnerProductSpace open LinearMap (ker range) open RealInnerProductSpace NNReal universe u namespace IsCoercive variable {V : Type u} [NormedAddCommGroup V] [InnerProductSpace ℝ V] [CompleteSpace V] variable {B : V →L[ℝ] V →L[ℝ] ℝ} local postfix:1024 "♯" => continuousLinearMapOfBilin (𝕜 := ℝ) theorem bounded_below (coercive : IsCoercive B) : ∃ C, 0 < C ∧ ∀ v, C * ‖v‖ ≤ ‖B♯ v‖ := by rcases coercive with ⟨C, C_ge_0, coercivity⟩ refine ⟨C, C_ge_0, ?_⟩ intro v by_cases h : 0 < ‖v‖ · refine (mul_le_mul_right h).mp ?_ calc C * ‖v‖ * ‖v‖ ≤ B v v := coercivity v _ = ⟪B♯ v, v⟫_ℝ := (continuousLinearMapOfBilin_apply B v v).symm _ ≤ ‖B♯ v‖ * ‖v‖ := real_inner_le_norm (B♯ v) v · have : v = 0 := by simpa using h simp [this] theorem antilipschitz (coercive : IsCoercive B) : ∃ C : ℝ≥0, 0 < C ∧ AntilipschitzWith C B♯ := by rcases coercive.bounded_below with ⟨C, C_pos, below_bound⟩ refine ⟨C⁻¹.toNNReal, Real.toNNReal_pos.mpr (inv_pos.mpr C_pos), ?_⟩ refine ContinuousLinearMap.antilipschitz_of_bound B♯ ?_ simp_rw [Real.coe_toNNReal', max_eq_left_of_lt (inv_pos.mpr C_pos), ← inv_mul_le_iff₀ (inv_pos.mpr C_pos)] simpa using below_bound theorem ker_eq_bot (coercive : IsCoercive B) : ker B♯ = ⊥ := by rw [LinearMapClass.ker_eq_bot] rcases coercive.antilipschitz with ⟨_, _, antilipschitz⟩ exact antilipschitz.injective theorem isClosed_range (coercive : IsCoercive B) : IsClosed (range B♯ : Set V) := by rcases coercive.antilipschitz with ⟨_, _, antilipschitz⟩ exact antilipschitz.isClosed_range B♯.uniformContinuous theorem range_eq_top (coercive : IsCoercive B) : range B♯ = ⊤ := by haveI := coercive.isClosed_range.completeSpace_coe rw [← (range B♯).orthogonal_orthogonal] rw [Submodule.eq_top_iff'] intro v w mem_w_orthogonal rcases coercive with ⟨C, C_pos, coercivity⟩ obtain rfl : w = 0 := by	rw [← norm_eq_zero, ← mul_self_eq_zero, ← mul_right_inj' C_pos.ne', mul_zero, ← mul_assoc] apply le_antisymm · calc C * ‖w‖ * ‖w‖ ≤ B w w := coercivity w _ = ⟪B♯ w, w⟫_ℝ := (continuousLinearMapOfBilin_apply B w w).symm _ = 0 := mem_w_orthogonal _ ⟨w, rfl⟩ · positivity exact inner_zero_left _ /-- The Lax-Milgram equivalence of a coercive bounded bilinear operator: for all `v : V`, `continuousLinearEquivOfBilin B v` is the unique element `V` such that `continuousLinearEquivOfBilin B v, w⟫ = B v w`. The Lax-Milgram theorem states that this is a continuous equivalence. -/ def continuousLinearEquivOfBilin (coercive : IsCoercive B) : V ≃L[ℝ] V :=	Mathlib/Analysis/InnerProductSpace/LaxMilgram.lean	87	102
/- Copyright (c) 2023 Joël Riou. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Joël Riou -/ import Mathlib.Algebra.Homology.ShortComplex.PreservesHomology import Mathlib.Algebra.Homology.ShortComplex.Abelian import Mathlib.Algebra.Homology.ShortComplex.QuasiIso import Mathlib.CategoryTheory.Abelian.Opposite import Mathlib.CategoryTheory.Preadditive.AdditiveFunctor import Mathlib.CategoryTheory.Preadditive.Injective.Basic /-! # Exact short complexes When `S : ShortComplex C`, this file defines a structure `S.Exact` which expresses the exactness of `S`, i.e. there exists a homology data `h : S.HomologyData` such that `h.left.H` is zero. When `[S.HasHomology]`, it is equivalent to the assertion `IsZero S.homology`. Almost by construction, this notion of exactness is self dual, see `Exact.op` and `Exact.unop`. -/ namespace CategoryTheory open Category Limits ZeroObject Preadditive variable {C D : Type*} [Category C] [Category D] namespace ShortComplex section variable [HasZeroMorphisms C] [HasZeroMorphisms D] (S : ShortComplex C) {S₁ S₂ : ShortComplex C} /-- The assertion that the short complex `S : ShortComplex C` is exact. -/ structure Exact : Prop where /-- the condition that there exists an homology data whose `left.H` field is zero -/ condition : ∃ (h : S.HomologyData), IsZero h.left.H variable {S} lemma Exact.hasHomology (h : S.Exact) : S.HasHomology := HasHomology.mk' h.condition.choose lemma Exact.hasZeroObject (h : S.Exact) : HasZeroObject C := ⟨h.condition.choose.left.H, h.condition.choose_spec⟩ variable (S) lemma exact_iff_isZero_homology [S.HasHomology] : S.Exact ↔ IsZero S.homology := by constructor · rintro ⟨⟨h', z⟩⟩ exact IsZero.of_iso z h'.left.homologyIso · intro h exact ⟨⟨_, h⟩⟩ variable {S} lemma LeftHomologyData.exact_iff [S.HasHomology] (h : S.LeftHomologyData) : S.Exact ↔ IsZero h.H := by rw [S.exact_iff_isZero_homology] exact Iso.isZero_iff h.homologyIso lemma RightHomologyData.exact_iff [S.HasHomology] (h : S.RightHomologyData) : S.Exact ↔ IsZero h.H := by rw [S.exact_iff_isZero_homology] exact Iso.isZero_iff h.homologyIso variable (S) lemma exact_iff_isZero_leftHomology [S.HasHomology] : S.Exact ↔ IsZero S.leftHomology := LeftHomologyData.exact_iff _ lemma exact_iff_isZero_rightHomology [S.HasHomology] : S.Exact ↔ IsZero S.rightHomology := RightHomologyData.exact_iff _ variable {S}	lemma HomologyData.exact_iff (h : S.HomologyData) : S.Exact ↔ IsZero h.left.H := by haveI := HasHomology.mk' h	Mathlib/Algebra/Homology/ShortComplex/Exact.lean	88	91
/- Copyright (c) 2019 Kim Morrison. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kim Morrison, Bhavik Mehta -/ import Mathlib.CategoryTheory.Comma.Over.Basic import Mathlib.CategoryTheory.Discrete.Basic import Mathlib.CategoryTheory.EpiMono import Mathlib.CategoryTheory.Limits.Shapes.Terminal /-! # Binary (co)products We define a category `WalkingPair`, which is the index category for a binary (co)product diagram. A convenience method `pair X Y` constructs the functor from the walking pair, hitting the given objects. We define `prod X Y` and `coprod X Y` as limits and colimits of such functors. Typeclasses `HasBinaryProducts` and `HasBinaryCoproducts` assert the existence of (co)limits shaped as walking pairs. We include lemmas for simplifying equations involving projections and coprojections, and define braiding and associating isomorphisms, and the product comparison morphism. ## References * [Stacks: Products of pairs](https://stacks.math.columbia.edu/tag/001R) * [Stacks: coproducts of pairs](https://stacks.math.columbia.edu/tag/04AN) -/ universe v v₁ u u₁ u₂ open CategoryTheory namespace CategoryTheory.Limits /-- The type of objects for the diagram indexing a binary (co)product. -/ inductive WalkingPair : Type \| left \| right deriving DecidableEq, Inhabited open WalkingPair /-- The equivalence swapping left and right. -/ def WalkingPair.swap : WalkingPair ≃ WalkingPair where toFun \| left => right \| right => left invFun \| left => right \| right => left left_inv j := by cases j <;> rfl right_inv j := by cases j <;> rfl @[simp] theorem WalkingPair.swap_apply_left : WalkingPair.swap left = right := rfl @[simp] theorem WalkingPair.swap_apply_right : WalkingPair.swap right = left := rfl @[simp] theorem WalkingPair.swap_symm_apply_tt : WalkingPair.swap.symm left = right := rfl @[simp] theorem WalkingPair.swap_symm_apply_ff : WalkingPair.swap.symm right = left := rfl /-- An equivalence from `WalkingPair` to `Bool`, sometimes useful when reindexing limits. -/ def WalkingPair.equivBool : WalkingPair ≃ Bool where toFun \| left => true \| right => false -- to match equiv.sum_equiv_sigma_bool invFun b := Bool.recOn b right left left_inv j := by cases j <;> rfl right_inv b := by cases b <;> rfl @[simp] theorem WalkingPair.equivBool_apply_left : WalkingPair.equivBool left = true := rfl @[simp] theorem WalkingPair.equivBool_apply_right : WalkingPair.equivBool right = false := rfl @[simp] theorem WalkingPair.equivBool_symm_apply_true : WalkingPair.equivBool.symm true = left := rfl @[simp] theorem WalkingPair.equivBool_symm_apply_false : WalkingPair.equivBool.symm false = right := rfl variable {C : Type u} /-- The function on the walking pair, sending the two points to `X` and `Y`. -/ def pairFunction (X Y : C) : WalkingPair → C := fun j => WalkingPair.casesOn j X Y @[simp] theorem pairFunction_left (X Y : C) : pairFunction X Y left = X := rfl @[simp] theorem pairFunction_right (X Y : C) : pairFunction X Y right = Y := rfl variable [Category.{v} C] /-- The diagram on the walking pair, sending the two points to `X` and `Y`. -/ def pair (X Y : C) : Discrete WalkingPair ⥤ C := Discrete.functor fun j => WalkingPair.casesOn j X Y @[simp] theorem pair_obj_left (X Y : C) : (pair X Y).obj ⟨left⟩ = X := rfl @[simp] theorem pair_obj_right (X Y : C) : (pair X Y).obj ⟨right⟩ = Y := rfl section variable {F G : Discrete WalkingPair ⥤ C} (f : F.obj ⟨left⟩ ⟶ G.obj ⟨left⟩) (g : F.obj ⟨right⟩ ⟶ G.obj ⟨right⟩) attribute [local aesop safe tactic (rule_sets := [CategoryTheory])] CategoryTheory.Discrete.discreteCases /-- The natural transformation between two functors out of the walking pair, specified by its components. -/ def mapPair : F ⟶ G where app \| ⟨left⟩ => f \| ⟨right⟩ => g naturality := fun ⟨X⟩ ⟨Y⟩ ⟨⟨u⟩⟩ => by aesop_cat @[simp] theorem mapPair_left : (mapPair f g).app ⟨left⟩ = f := rfl @[simp] theorem mapPair_right : (mapPair f g).app ⟨right⟩ = g := rfl /-- The natural isomorphism between two functors out of the walking pair, specified by its components. -/ @[simps!] def mapPairIso (f : F.obj ⟨left⟩ ≅ G.obj ⟨left⟩) (g : F.obj ⟨right⟩ ≅ G.obj ⟨right⟩) : F ≅ G := NatIso.ofComponents (fun j ↦ match j with \| ⟨left⟩ => f \| ⟨right⟩ => g) (fun ⟨⟨u⟩⟩ => by aesop_cat) end /-- Every functor out of the walking pair is naturally isomorphic (actually, equal) to a `pair` -/ @[simps!] def diagramIsoPair (F : Discrete WalkingPair ⥤ C) : F ≅ pair (F.obj ⟨WalkingPair.left⟩) (F.obj ⟨WalkingPair.right⟩) := mapPairIso (Iso.refl _) (Iso.refl _) section variable {D : Type u₁} [Category.{v₁} D] /-- The natural isomorphism between `pair X Y ⋙ F` and `pair (F.obj X) (F.obj Y)`. -/ def pairComp (X Y : C) (F : C ⥤ D) : pair X Y ⋙ F ≅ pair (F.obj X) (F.obj Y) := diagramIsoPair _ end /-- A binary fan is just a cone on a diagram indexing a product. -/ abbrev BinaryFan (X Y : C) := Cone (pair X Y) /-- The first projection of a binary fan. -/ abbrev BinaryFan.fst {X Y : C} (s : BinaryFan X Y) := s.π.app ⟨WalkingPair.left⟩ /-- The second projection of a binary fan. -/ abbrev BinaryFan.snd {X Y : C} (s : BinaryFan X Y) := s.π.app ⟨WalkingPair.right⟩ @[simp] theorem BinaryFan.π_app_left {X Y : C} (s : BinaryFan X Y) : s.π.app ⟨WalkingPair.left⟩ = s.fst := rfl @[simp] theorem BinaryFan.π_app_right {X Y : C} (s : BinaryFan X Y) : s.π.app ⟨WalkingPair.right⟩ = s.snd := rfl /-- Constructs an isomorphism of `BinaryFan`s out of an isomorphism of the tips that commutes with the projections. -/ def BinaryFan.ext {A B : C} {c c' : BinaryFan A B} (e : c.pt ≅ c'.pt) (h₁ : c.fst = e.hom ≫ c'.fst) (h₂ : c.snd = e.hom ≫ c'.snd) : c ≅ c' := Cones.ext e (fun j => by rcases j with ⟨⟨⟩⟩ <;> assumption) @[simp] lemma BinaryFan.ext_hom_hom {A B : C} {c c' : BinaryFan A B} (e : c.pt ≅ c'.pt) (h₁ : c.fst = e.hom ≫ c'.fst) (h₂ : c.snd = e.hom ≫ c'.snd) : (ext e h₁ h₂).hom.hom = e.hom := rfl /-- A convenient way to show that a binary fan is a limit. -/ def BinaryFan.IsLimit.mk {X Y : C} (s : BinaryFan X Y) (lift : ∀ {T : C} (_ : T ⟶ X) (_ : T ⟶ Y), T ⟶ s.pt) (hl₁ : ∀ {T : C} (f : T ⟶ X) (g : T ⟶ Y), lift f g ≫ s.fst = f) (hl₂ : ∀ {T : C} (f : T ⟶ X) (g : T ⟶ Y), lift f g ≫ s.snd = g) (uniq : ∀ {T : C} (f : T ⟶ X) (g : T ⟶ Y) (m : T ⟶ s.pt) (_ : m ≫ s.fst = f) (_ : m ≫ s.snd = g), m = lift f g) : IsLimit s := Limits.IsLimit.mk (fun t => lift (BinaryFan.fst t) (BinaryFan.snd t)) (by rintro t (rfl \| rfl) · exact hl₁ _ _ · exact hl₂ _ _) fun _ _ h => uniq _ _ _ (h ⟨WalkingPair.left⟩) (h ⟨WalkingPair.right⟩) theorem BinaryFan.IsLimit.hom_ext {W X Y : C} {s : BinaryFan X Y} (h : IsLimit s) {f g : W ⟶ s.pt} (h₁ : f ≫ s.fst = g ≫ s.fst) (h₂ : f ≫ s.snd = g ≫ s.snd) : f = g := h.hom_ext fun j => Discrete.recOn j fun j => WalkingPair.casesOn j h₁ h₂ /-- A binary cofan is just a cocone on a diagram indexing a coproduct. -/ abbrev BinaryCofan (X Y : C) := Cocone (pair X Y) /-- The first inclusion of a binary cofan. -/ abbrev BinaryCofan.inl {X Y : C} (s : BinaryCofan X Y) := s.ι.app ⟨WalkingPair.left⟩ /-- The second inclusion of a binary cofan. -/ abbrev BinaryCofan.inr {X Y : C} (s : BinaryCofan X Y) := s.ι.app ⟨WalkingPair.right⟩ /-- Constructs an isomorphism of `BinaryCofan`s out of an isomorphism of the tips that commutes with the injections. -/ def BinaryCofan.ext {A B : C} {c c' : BinaryCofan A B} (e : c.pt ≅ c'.pt) (h₁ : c.inl ≫ e.hom = c'.inl) (h₂ : c.inr ≫ e.hom = c'.inr) : c ≅ c' := Cocones.ext e (fun j => by rcases j with ⟨⟨⟩⟩ <;> assumption) @[simp] lemma BinaryCofan.ext_hom_hom {A B : C} {c c' : BinaryCofan A B} (e : c.pt ≅ c'.pt) (h₁ : c.inl ≫ e.hom = c'.inl) (h₂ : c.inr ≫ e.hom = c'.inr) : (ext e h₁ h₂).hom.hom = e.hom := rfl @[simp] theorem BinaryCofan.ι_app_left {X Y : C} (s : BinaryCofan X Y) : s.ι.app ⟨WalkingPair.left⟩ = s.inl := rfl @[simp] theorem BinaryCofan.ι_app_right {X Y : C} (s : BinaryCofan X Y) : s.ι.app ⟨WalkingPair.right⟩ = s.inr := rfl /-- A convenient way to show that a binary cofan is a colimit. -/ def BinaryCofan.IsColimit.mk {X Y : C} (s : BinaryCofan X Y) (desc : ∀ {T : C} (_ : X ⟶ T) (_ : Y ⟶ T), s.pt ⟶ T) (hd₁ : ∀ {T : C} (f : X ⟶ T) (g : Y ⟶ T), s.inl ≫ desc f g = f) (hd₂ : ∀ {T : C} (f : X ⟶ T) (g : Y ⟶ T), s.inr ≫ desc f g = g) (uniq : ∀ {T : C} (f : X ⟶ T) (g : Y ⟶ T) (m : s.pt ⟶ T) (_ : s.inl ≫ m = f) (_ : s.inr ≫ m = g), m = desc f g) : IsColimit s := Limits.IsColimit.mk (fun t => desc (BinaryCofan.inl t) (BinaryCofan.inr t)) (by rintro t (rfl \| rfl) · exact hd₁ _ _ · exact hd₂ _ _) fun _ _ h => uniq _ _ _ (h ⟨WalkingPair.left⟩) (h ⟨WalkingPair.right⟩) theorem BinaryCofan.IsColimit.hom_ext {W X Y : C} {s : BinaryCofan X Y} (h : IsColimit s) {f g : s.pt ⟶ W} (h₁ : s.inl ≫ f = s.inl ≫ g) (h₂ : s.inr ≫ f = s.inr ≫ g) : f = g := h.hom_ext fun j => Discrete.recOn j fun j => WalkingPair.casesOn j h₁ h₂ variable {X Y : C} section attribute [local aesop safe tactic (rule_sets := [CategoryTheory])] CategoryTheory.Discrete.discreteCases -- Porting note: would it be okay to use this more generally? attribute [local aesop safe cases (rule_sets := [CategoryTheory])] Eq /-- A binary fan with vertex `P` consists of the two projections `π₁ : P ⟶ X` and `π₂ : P ⟶ Y`. -/ @[simps pt] def BinaryFan.mk {P : C} (π₁ : P ⟶ X) (π₂ : P ⟶ Y) : BinaryFan X Y where pt := P π := { app := fun \| { as := j } => match j with \| left => π₁ \| right => π₂ } /-- A binary cofan with vertex `P` consists of the two inclusions `ι₁ : X ⟶ P` and `ι₂ : Y ⟶ P`. -/ @[simps pt] def BinaryCofan.mk {P : C} (ι₁ : X ⟶ P) (ι₂ : Y ⟶ P) : BinaryCofan X Y where pt := P ι := { app := fun \| { as := j } => match j with \| left => ι₁ \| right => ι₂ } end @[simp] theorem BinaryFan.mk_fst {P : C} (π₁ : P ⟶ X) (π₂ : P ⟶ Y) : (BinaryFan.mk π₁ π₂).fst = π₁ := rfl @[simp] theorem BinaryFan.mk_snd {P : C} (π₁ : P ⟶ X) (π₂ : P ⟶ Y) : (BinaryFan.mk π₁ π₂).snd = π₂ := rfl @[simp] theorem BinaryCofan.mk_inl {P : C} (ι₁ : X ⟶ P) (ι₂ : Y ⟶ P) : (BinaryCofan.mk ι₁ ι₂).inl = ι₁ := rfl @[simp] theorem BinaryCofan.mk_inr {P : C} (ι₁ : X ⟶ P) (ι₂ : Y ⟶ P) : (BinaryCofan.mk ι₁ ι₂).inr = ι₂ := rfl /-- Every `BinaryFan` is isomorphic to an application of `BinaryFan.mk`. -/ def isoBinaryFanMk {X Y : C} (c : BinaryFan X Y) : c ≅ BinaryFan.mk c.fst c.snd := Cones.ext (Iso.refl _) fun ⟨l⟩ => by cases l; repeat simp /-- Every `BinaryFan` is isomorphic to an application of `BinaryFan.mk`. -/ def isoBinaryCofanMk {X Y : C} (c : BinaryCofan X Y) : c ≅ BinaryCofan.mk c.inl c.inr := Cocones.ext (Iso.refl _) fun ⟨l⟩ => by cases l; repeat simp /-- This is a more convenient formulation to show that a `BinaryFan` constructed using `BinaryFan.mk` is a limit cone. -/ def BinaryFan.isLimitMk {W : C} {fst : W ⟶ X} {snd : W ⟶ Y} (lift : ∀ s : BinaryFan X Y, s.pt ⟶ W) (fac_left : ∀ s : BinaryFan X Y, lift s ≫ fst = s.fst) (fac_right : ∀ s : BinaryFan X Y, lift s ≫ snd = s.snd) (uniq : ∀ (s : BinaryFan X Y) (m : s.pt ⟶ W) (_ : m ≫ fst = s.fst) (_ : m ≫ snd = s.snd), m = lift s) : IsLimit (BinaryFan.mk fst snd) := { lift := lift fac := fun s j => by rcases j with ⟨⟨⟩⟩ exacts [fac_left s, fac_right s] uniq := fun s m w => uniq s m (w ⟨WalkingPair.left⟩) (w ⟨WalkingPair.right⟩) } /-- This is a more convenient formulation to show that a `BinaryCofan` constructed using `BinaryCofan.mk` is a colimit cocone. -/ def BinaryCofan.isColimitMk {W : C} {inl : X ⟶ W} {inr : Y ⟶ W} (desc : ∀ s : BinaryCofan X Y, W ⟶ s.pt) (fac_left : ∀ s : BinaryCofan X Y, inl ≫ desc s = s.inl) (fac_right : ∀ s : BinaryCofan X Y, inr ≫ desc s = s.inr) (uniq : ∀ (s : BinaryCofan X Y) (m : W ⟶ s.pt) (_ : inl ≫ m = s.inl) (_ : inr ≫ m = s.inr), m = desc s) : IsColimit (BinaryCofan.mk inl inr) := { desc := desc fac := fun s j => by rcases j with ⟨⟨⟩⟩ exacts [fac_left s, fac_right s] uniq := fun s m w => uniq s m (w ⟨WalkingPair.left⟩) (w ⟨WalkingPair.right⟩) } /-- If `s` is a limit binary fan over `X` and `Y`, then every pair of morphisms `f : W ⟶ X` and `g : W ⟶ Y` induces a morphism `l : W ⟶ s.pt` satisfying `l ≫ s.fst = f` and `l ≫ s.snd = g`. -/ @[simps] def BinaryFan.IsLimit.lift' {W X Y : C} {s : BinaryFan X Y} (h : IsLimit s) (f : W ⟶ X) (g : W ⟶ Y) : { l : W ⟶ s.pt // l ≫ s.fst = f ∧ l ≫ s.snd = g } := ⟨h.lift <\| BinaryFan.mk f g, h.fac _ _, h.fac _ _⟩ /-- If `s` is a colimit binary cofan over `X` and `Y`,, then every pair of morphisms `f : X ⟶ W` and `g : Y ⟶ W` induces a morphism `l : s.pt ⟶ W` satisfying `s.inl ≫ l = f` and `s.inr ≫ l = g`. -/ @[simps] def BinaryCofan.IsColimit.desc' {W X Y : C} {s : BinaryCofan X Y} (h : IsColimit s) (f : X ⟶ W) (g : Y ⟶ W) : { l : s.pt ⟶ W // s.inl ≫ l = f ∧ s.inr ≫ l = g } := ⟨h.desc <\| BinaryCofan.mk f g, h.fac _ _, h.fac _ _⟩ /-- Binary products are symmetric. -/ def BinaryFan.isLimitFlip {X Y : C} {c : BinaryFan X Y} (hc : IsLimit c) : IsLimit (BinaryFan.mk c.snd c.fst) := BinaryFan.isLimitMk (fun s => hc.lift (BinaryFan.mk s.snd s.fst)) (fun _ => hc.fac _ _) (fun _ => hc.fac _ _) fun s _ e₁ e₂ => BinaryFan.IsLimit.hom_ext hc (e₂.trans (hc.fac (BinaryFan.mk s.snd s.fst) ⟨WalkingPair.left⟩).symm) (e₁.trans (hc.fac (BinaryFan.mk s.snd s.fst) ⟨WalkingPair.right⟩).symm) theorem BinaryFan.isLimit_iff_isIso_fst {X Y : C} (h : IsTerminal Y) (c : BinaryFan X Y) : Nonempty (IsLimit c) ↔ IsIso c.fst := by constructor · rintro ⟨H⟩ obtain ⟨l, hl, -⟩ := BinaryFan.IsLimit.lift' H (𝟙 X) (h.from X) exact ⟨⟨l, BinaryFan.IsLimit.hom_ext H (by simpa [hl, -Category.comp_id] using Category.comp_id _) (h.hom_ext _ _), hl⟩⟩ · intro exact ⟨BinaryFan.IsLimit.mk _ (fun f _ => f ≫ inv c.fst) (fun _ _ => by simp) (fun _ _ => h.hom_ext _ _) fun _ _ _ e _ => by simp [← e]⟩ theorem BinaryFan.isLimit_iff_isIso_snd {X Y : C} (h : IsTerminal X) (c : BinaryFan X Y) : Nonempty (IsLimit c) ↔ IsIso c.snd := by refine Iff.trans ?_ (BinaryFan.isLimit_iff_isIso_fst h (BinaryFan.mk c.snd c.fst)) exact ⟨fun h => ⟨BinaryFan.isLimitFlip h.some⟩, fun h => ⟨(BinaryFan.isLimitFlip h.some).ofIsoLimit (isoBinaryFanMk c).symm⟩⟩ /-- If `X' ≅ X`, then `X × Y` also is the product of `X'` and `Y`. -/ noncomputable def BinaryFan.isLimitCompLeftIso {X Y X' : C} (c : BinaryFan X Y) (f : X ⟶ X') [IsIso f] (h : IsLimit c) : IsLimit (BinaryFan.mk (c.fst ≫ f) c.snd) := by fapply BinaryFan.isLimitMk · exact fun s => h.lift (BinaryFan.mk (s.fst ≫ inv f) s.snd) · intro s -- Porting note: simp timed out here simp only [Category.comp_id,BinaryFan.π_app_left,IsIso.inv_hom_id, BinaryFan.mk_fst,IsLimit.fac_assoc,eq_self_iff_true,Category.assoc] · intro s -- Porting note: simp timed out here simp only [BinaryFan.π_app_right,BinaryFan.mk_snd,eq_self_iff_true,IsLimit.fac] · intro s m e₁ e₂ -- Porting note: simpa timed out here also apply BinaryFan.IsLimit.hom_ext h · simpa only [BinaryFan.π_app_left,BinaryFan.mk_fst,Category.assoc,IsLimit.fac,IsIso.eq_comp_inv] · simpa only [BinaryFan.π_app_right,BinaryFan.mk_snd,IsLimit.fac] /-- If `Y' ≅ Y`, then `X x Y` also is the product of `X` and `Y'`. -/ noncomputable def BinaryFan.isLimitCompRightIso {X Y Y' : C} (c : BinaryFan X Y) (f : Y ⟶ Y') [IsIso f] (h : IsLimit c) : IsLimit (BinaryFan.mk c.fst (c.snd ≫ f)) := BinaryFan.isLimitFlip <\| BinaryFan.isLimitCompLeftIso _ f (BinaryFan.isLimitFlip h) /-- Binary coproducts are symmetric. -/ def BinaryCofan.isColimitFlip {X Y : C} {c : BinaryCofan X Y} (hc : IsColimit c) : IsColimit (BinaryCofan.mk c.inr c.inl) := BinaryCofan.isColimitMk (fun s => hc.desc (BinaryCofan.mk s.inr s.inl)) (fun _ => hc.fac _ _) (fun _ => hc.fac _ _) fun s _ e₁ e₂ => BinaryCofan.IsColimit.hom_ext hc (e₂.trans (hc.fac (BinaryCofan.mk s.inr s.inl) ⟨WalkingPair.left⟩).symm) (e₁.trans (hc.fac (BinaryCofan.mk s.inr s.inl) ⟨WalkingPair.right⟩).symm) theorem BinaryCofan.isColimit_iff_isIso_inl {X Y : C} (h : IsInitial Y) (c : BinaryCofan X Y) : Nonempty (IsColimit c) ↔ IsIso c.inl := by constructor · rintro ⟨H⟩ obtain ⟨l, hl, -⟩ := BinaryCofan.IsColimit.desc' H (𝟙 X) (h.to X) refine ⟨⟨l, hl, BinaryCofan.IsColimit.hom_ext H (?_) (h.hom_ext _ _)⟩⟩ rw [Category.comp_id] have e : (inl c ≫ l) ≫ inl c = 𝟙 X ≫ inl c := congrArg (·≫inl c) hl rwa [Category.assoc,Category.id_comp] at e · intro exact ⟨BinaryCofan.IsColimit.mk _ (fun f _ => inv c.inl ≫ f) (fun _ _ => IsIso.hom_inv_id_assoc _ _) (fun _ _ => h.hom_ext _ _) fun _ _ _ e _ => (IsIso.eq_inv_comp _).mpr e⟩ theorem BinaryCofan.isColimit_iff_isIso_inr {X Y : C} (h : IsInitial X) (c : BinaryCofan X Y) : Nonempty (IsColimit c) ↔ IsIso c.inr := by refine Iff.trans ?_ (BinaryCofan.isColimit_iff_isIso_inl h (BinaryCofan.mk c.inr c.inl)) exact ⟨fun h => ⟨BinaryCofan.isColimitFlip h.some⟩, fun h => ⟨(BinaryCofan.isColimitFlip h.some).ofIsoColimit (isoBinaryCofanMk c).symm⟩⟩ /-- If `X' ≅ X`, then `X ⨿ Y` also is the coproduct of `X'` and `Y`. -/ noncomputable def BinaryCofan.isColimitCompLeftIso {X Y X' : C} (c : BinaryCofan X Y) (f : X' ⟶ X) [IsIso f] (h : IsColimit c) : IsColimit (BinaryCofan.mk (f ≫ c.inl) c.inr) := by fapply BinaryCofan.isColimitMk · exact fun s => h.desc (BinaryCofan.mk (inv f ≫ s.inl) s.inr) · intro s -- Porting note: simp timed out here too simp only [IsColimit.fac,BinaryCofan.ι_app_left,eq_self_iff_true, Category.assoc,BinaryCofan.mk_inl,IsIso.hom_inv_id_assoc] · intro s -- Porting note: simp timed out here too simp only [IsColimit.fac,BinaryCofan.ι_app_right,eq_self_iff_true,BinaryCofan.mk_inr] · intro s m e₁ e₂ apply BinaryCofan.IsColimit.hom_ext h · rw [← cancel_epi f] -- Porting note: simp timed out here too simpa only [IsColimit.fac,BinaryCofan.ι_app_left,eq_self_iff_true, Category.assoc,BinaryCofan.mk_inl,IsIso.hom_inv_id_assoc] using e₁ -- Porting note: simp timed out here too · simpa only [IsColimit.fac,BinaryCofan.ι_app_right,eq_self_iff_true,BinaryCofan.mk_inr] /-- If `Y' ≅ Y`, then `X ⨿ Y` also is the coproduct of `X` and `Y'`. -/ noncomputable def BinaryCofan.isColimitCompRightIso {X Y Y' : C} (c : BinaryCofan X Y) (f : Y' ⟶ Y) [IsIso f] (h : IsColimit c) : IsColimit (BinaryCofan.mk c.inl (f ≫ c.inr)) := BinaryCofan.isColimitFlip <\| BinaryCofan.isColimitCompLeftIso _ f (BinaryCofan.isColimitFlip h) /-- An abbreviation for `HasLimit (pair X Y)`. -/ abbrev HasBinaryProduct (X Y : C) := HasLimit (pair X Y) /-- An abbreviation for `HasColimit (pair X Y)`. -/ abbrev HasBinaryCoproduct (X Y : C) := HasColimit (pair X Y) /-- If we have a product of `X` and `Y`, we can access it using `prod X Y` or `X ⨯ Y`. -/ noncomputable abbrev prod (X Y : C) [HasBinaryProduct X Y] := limit (pair X Y) /-- If we have a coproduct of `X` and `Y`, we can access it using `coprod X Y` or `X ⨿ Y`. -/ noncomputable abbrev coprod (X Y : C) [HasBinaryCoproduct X Y] := colimit (pair X Y) /-- Notation for the product -/ notation:20 X " ⨯ " Y:20 => prod X Y /-- Notation for the coproduct -/ notation:20 X " ⨿ " Y:20 => coprod X Y /-- The projection map to the first component of the product. -/ noncomputable abbrev prod.fst {X Y : C} [HasBinaryProduct X Y] : X ⨯ Y ⟶ X := limit.π (pair X Y) ⟨WalkingPair.left⟩ /-- The projection map to the second component of the product. -/ noncomputable abbrev prod.snd {X Y : C} [HasBinaryProduct X Y] : X ⨯ Y ⟶ Y := limit.π (pair X Y) ⟨WalkingPair.right⟩ /-- The inclusion map from the first component of the coproduct. -/ noncomputable abbrev coprod.inl {X Y : C} [HasBinaryCoproduct X Y] : X ⟶ X ⨿ Y := colimit.ι (pair X Y) ⟨WalkingPair.left⟩ /-- The inclusion map from the second component of the coproduct. -/ noncomputable abbrev coprod.inr {X Y : C} [HasBinaryCoproduct X Y] : Y ⟶ X ⨿ Y := colimit.ι (pair X Y) ⟨WalkingPair.right⟩ /-- The binary fan constructed from the projection maps is a limit. -/ noncomputable def prodIsProd (X Y : C) [HasBinaryProduct X Y] : IsLimit (BinaryFan.mk (prod.fst : X ⨯ Y ⟶ X) prod.snd) := (limit.isLimit _).ofIsoLimit (Cones.ext (Iso.refl _) (fun ⟨u⟩ => by cases u · dsimp; simp only [Category.id_comp]; rfl · dsimp; simp only [Category.id_comp]; rfl )) /-- The binary cofan constructed from the coprojection maps is a colimit. -/ noncomputable def coprodIsCoprod (X Y : C) [HasBinaryCoproduct X Y] : IsColimit (BinaryCofan.mk (coprod.inl : X ⟶ X ⨿ Y) coprod.inr) := (colimit.isColimit _).ofIsoColimit (Cocones.ext (Iso.refl _) (fun ⟨u⟩ => by cases u · dsimp; simp only [Category.comp_id] · dsimp; simp only [Category.comp_id] )) @[ext 1100] theorem prod.hom_ext {W X Y : C} [HasBinaryProduct X Y] {f g : W ⟶ X ⨯ Y} (h₁ : f ≫ prod.fst = g ≫ prod.fst) (h₂ : f ≫ prod.snd = g ≫ prod.snd) : f = g := BinaryFan.IsLimit.hom_ext (limit.isLimit _) h₁ h₂ @[ext 1100] theorem coprod.hom_ext {W X Y : C} [HasBinaryCoproduct X Y] {f g : X ⨿ Y ⟶ W} (h₁ : coprod.inl ≫ f = coprod.inl ≫ g) (h₂ : coprod.inr ≫ f = coprod.inr ≫ g) : f = g := BinaryCofan.IsColimit.hom_ext (colimit.isColimit _) h₁ h₂ /-- If the product of `X` and `Y` exists, then every pair of morphisms `f : W ⟶ X` and `g : W ⟶ Y` induces a morphism `prod.lift f g : W ⟶ X ⨯ Y`. -/ noncomputable abbrev prod.lift {W X Y : C} [HasBinaryProduct X Y] (f : W ⟶ X) (g : W ⟶ Y) : W ⟶ X ⨯ Y := limit.lift _ (BinaryFan.mk f g) /-- diagonal arrow of the binary product in the category `fam I` -/ noncomputable abbrev diag (X : C) [HasBinaryProduct X X] : X ⟶ X ⨯ X := prod.lift (𝟙 _) (𝟙 _) /-- If the coproduct of `X` and `Y` exists, then every pair of morphisms `f : X ⟶ W` and `g : Y ⟶ W` induces a morphism `coprod.desc f g : X ⨿ Y ⟶ W`. -/ noncomputable abbrev coprod.desc {W X Y : C} [HasBinaryCoproduct X Y] (f : X ⟶ W) (g : Y ⟶ W) : X ⨿ Y ⟶ W := colimit.desc _ (BinaryCofan.mk f g) /-- codiagonal arrow of the binary coproduct -/ noncomputable abbrev codiag (X : C) [HasBinaryCoproduct X X] : X ⨿ X ⟶ X := coprod.desc (𝟙 _) (𝟙 _) @[reassoc] theorem prod.lift_fst {W X Y : C} [HasBinaryProduct X Y] (f : W ⟶ X) (g : W ⟶ Y) : prod.lift f g ≫ prod.fst = f := limit.lift_π _ _ @[reassoc] theorem prod.lift_snd {W X Y : C} [HasBinaryProduct X Y] (f : W ⟶ X) (g : W ⟶ Y) : prod.lift f g ≫ prod.snd = g := limit.lift_π _ _ @[reassoc] theorem coprod.inl_desc {W X Y : C} [HasBinaryCoproduct X Y] (f : X ⟶ W) (g : Y ⟶ W) : coprod.inl ≫ coprod.desc f g = f := colimit.ι_desc _ _ @[reassoc] theorem coprod.inr_desc {W X Y : C} [HasBinaryCoproduct X Y] (f : X ⟶ W) (g : Y ⟶ W) : coprod.inr ≫ coprod.desc f g = g := colimit.ι_desc _ _ instance prod.mono_lift_of_mono_left {W X Y : C} [HasBinaryProduct X Y] (f : W ⟶ X) (g : W ⟶ Y) [Mono f] : Mono (prod.lift f g) := mono_of_mono_fac <\| prod.lift_fst _ _ instance prod.mono_lift_of_mono_right {W X Y : C} [HasBinaryProduct X Y] (f : W ⟶ X) (g : W ⟶ Y) [Mono g] : Mono (prod.lift f g) := mono_of_mono_fac <\| prod.lift_snd _ _ instance coprod.epi_desc_of_epi_left {W X Y : C} [HasBinaryCoproduct X Y] (f : X ⟶ W) (g : Y ⟶ W) [Epi f] : Epi (coprod.desc f g) := epi_of_epi_fac <\| coprod.inl_desc _ _ instance coprod.epi_desc_of_epi_right {W X Y : C} [HasBinaryCoproduct X Y] (f : X ⟶ W) (g : Y ⟶ W) [Epi g] : Epi (coprod.desc f g) := epi_of_epi_fac <\| coprod.inr_desc _ _ /-- If the product of `X` and `Y` exists, then every pair of morphisms `f : W ⟶ X` and `g : W ⟶ Y` induces a morphism `l : W ⟶ X ⨯ Y` satisfying `l ≫ Prod.fst = f` and `l ≫ Prod.snd = g`. -/ noncomputable def prod.lift' {W X Y : C} [HasBinaryProduct X Y] (f : W ⟶ X) (g : W ⟶ Y) : { l : W ⟶ X ⨯ Y // l ≫ prod.fst = f ∧ l ≫ prod.snd = g } := ⟨prod.lift f g, prod.lift_fst _ _, prod.lift_snd _ _⟩ /-- If the coproduct of `X` and `Y` exists, then every pair of morphisms `f : X ⟶ W` and `g : Y ⟶ W` induces a morphism `l : X ⨿ Y ⟶ W` satisfying `coprod.inl ≫ l = f` and `coprod.inr ≫ l = g`. -/ noncomputable def coprod.desc' {W X Y : C} [HasBinaryCoproduct X Y] (f : X ⟶ W) (g : Y ⟶ W) : { l : X ⨿ Y ⟶ W // coprod.inl ≫ l = f ∧ coprod.inr ≫ l = g } := ⟨coprod.desc f g, coprod.inl_desc _ _, coprod.inr_desc _ _⟩ /-- If the products `W ⨯ X` and `Y ⨯ Z` exist, then every pair of morphisms `f : W ⟶ Y` and `g : X ⟶ Z` induces a morphism `prod.map f g : W ⨯ X ⟶ Y ⨯ Z`. -/ noncomputable def prod.map {W X Y Z : C} [HasBinaryProduct W X] [HasBinaryProduct Y Z] (f : W ⟶ Y) (g : X ⟶ Z) : W ⨯ X ⟶ Y ⨯ Z := limMap (mapPair f g) /-- If the coproducts `W ⨿ X` and `Y ⨿ Z` exist, then every pair of morphisms `f : W ⟶ Y` and `g : W ⟶ Z` induces a morphism `coprod.map f g : W ⨿ X ⟶ Y ⨿ Z`. -/ noncomputable def coprod.map {W X Y Z : C} [HasBinaryCoproduct W X] [HasBinaryCoproduct Y Z] (f : W ⟶ Y) (g : X ⟶ Z) : W ⨿ X ⟶ Y ⨿ Z := colimMap (mapPair f g) noncomputable section ProdLemmas -- Making the reassoc version of this a simp lemma seems to be more harmful than helpful. @[reassoc, simp] theorem prod.comp_lift {V W X Y : C} [HasBinaryProduct X Y] (f : V ⟶ W) (g : W ⟶ X) (h : W ⟶ Y) : f ≫ prod.lift g h = prod.lift (f ≫ g) (f ≫ h) := by ext <;> simp theorem prod.comp_diag {X Y : C} [HasBinaryProduct Y Y] (f : X ⟶ Y) : f ≫ diag Y = prod.lift f f := by simp @[reassoc (attr := simp)] theorem prod.map_fst {W X Y Z : C} [HasBinaryProduct W X] [HasBinaryProduct Y Z] (f : W ⟶ Y) (g : X ⟶ Z) : prod.map f g ≫ prod.fst = prod.fst ≫ f := limMap_π _ _ @[reassoc (attr := simp)] theorem prod.map_snd {W X Y Z : C} [HasBinaryProduct W X] [HasBinaryProduct Y Z] (f : W ⟶ Y) (g : X ⟶ Z) : prod.map f g ≫ prod.snd = prod.snd ≫ g := limMap_π _ _ @[simp] theorem prod.map_id_id {X Y : C} [HasBinaryProduct X Y] : prod.map (𝟙 X) (𝟙 Y) = 𝟙 _ := by ext <;> simp @[simp] theorem prod.lift_fst_snd {X Y : C} [HasBinaryProduct X Y] : prod.lift prod.fst prod.snd = 𝟙 (X ⨯ Y) := by ext <;> simp @[reassoc (attr := simp)] theorem prod.lift_map {V W X Y Z : C} [HasBinaryProduct W X] [HasBinaryProduct Y Z] (f : V ⟶ W) (g : V ⟶ X) (h : W ⟶ Y) (k : X ⟶ Z) : prod.lift f g ≫ prod.map h k = prod.lift (f ≫ h) (g ≫ k) := by ext <;> simp @[simp] theorem prod.lift_fst_comp_snd_comp {W X Y Z : C} [HasBinaryProduct W Y] [HasBinaryProduct X Z] (g : W ⟶ X) (g' : Y ⟶ Z) : prod.lift (prod.fst ≫ g) (prod.snd ≫ g') = prod.map g g' := by rw [← prod.lift_map] simp -- We take the right hand side here to be simp normal form, as this way composition lemmas for -- `f ≫ h` and `g ≫ k` can fire (eg `id_comp`) , while `map_fst` and `map_snd` can still work just -- as well. @[reassoc (attr := simp)] theorem prod.map_map {A₁ A₂ A₃ B₁ B₂ B₃ : C} [HasBinaryProduct A₁ B₁] [HasBinaryProduct A₂ B₂] [HasBinaryProduct A₃ B₃] (f : A₁ ⟶ A₂) (g : B₁ ⟶ B₂) (h : A₂ ⟶ A₃) (k : B₂ ⟶ B₃) : prod.map f g ≫ prod.map h k = prod.map (f ≫ h) (g ≫ k) := by ext <;> simp -- TODO: is it necessary to weaken the assumption here? @[reassoc] theorem prod.map_swap {A B X Y : C} (f : A ⟶ B) (g : X ⟶ Y) [HasLimitsOfShape (Discrete WalkingPair) C] : prod.map (𝟙 X) f ≫ prod.map g (𝟙 B) = prod.map g (𝟙 A) ≫ prod.map (𝟙 Y) f := by simp @[reassoc] theorem prod.map_comp_id {X Y Z W : C} (f : X ⟶ Y) (g : Y ⟶ Z) [HasBinaryProduct X W] [HasBinaryProduct Z W] [HasBinaryProduct Y W] : prod.map (f ≫ g) (𝟙 W) = prod.map f (𝟙 W) ≫ prod.map g (𝟙 W) := by simp @[reassoc] theorem prod.map_id_comp {X Y Z W : C} (f : X ⟶ Y) (g : Y ⟶ Z) [HasBinaryProduct W X] [HasBinaryProduct W Y] [HasBinaryProduct W Z] : prod.map (𝟙 W) (f ≫ g) = prod.map (𝟙 W) f ≫ prod.map (𝟙 W) g := by simp /-- If the products `W ⨯ X` and `Y ⨯ Z` exist, then every pair of isomorphisms `f : W ≅ Y` and `g : X ≅ Z` induces an isomorphism `prod.mapIso f g : W ⨯ X ≅ Y ⨯ Z`. -/ @[simps] def prod.mapIso {W X Y Z : C} [HasBinaryProduct W X] [HasBinaryProduct Y Z] (f : W ≅ Y) (g : X ≅ Z) : W ⨯ X ≅ Y ⨯ Z where hom := prod.map f.hom g.hom inv := prod.map f.inv g.inv instance isIso_prod {W X Y Z : C} [HasBinaryProduct W X] [HasBinaryProduct Y Z] (f : W ⟶ Y) (g : X ⟶ Z) [IsIso f] [IsIso g] : IsIso (prod.map f g) := (prod.mapIso (asIso f) (asIso g)).isIso_hom instance prod.map_mono {C : Type*} [Category C] {W X Y Z : C} (f : W ⟶ Y) (g : X ⟶ Z) [Mono f] [Mono g] [HasBinaryProduct W X] [HasBinaryProduct Y Z] : Mono (prod.map f g) := ⟨fun i₁ i₂ h => by ext · rw [← cancel_mono f] simpa using congr_arg (fun f => f ≫ prod.fst) h · rw [← cancel_mono g] simpa using congr_arg (fun f => f ≫ prod.snd) h⟩ @[reassoc] theorem prod.diag_map {X Y : C} (f : X ⟶ Y) [HasBinaryProduct X X] [HasBinaryProduct Y Y] : diag X ≫ prod.map f f = f ≫ diag Y := by simp @[reassoc] theorem prod.diag_map_fst_snd {X Y : C} [HasBinaryProduct X Y] [HasBinaryProduct (X ⨯ Y) (X ⨯ Y)] : diag (X ⨯ Y) ≫ prod.map prod.fst prod.snd = 𝟙 (X ⨯ Y) := by simp @[reassoc] theorem prod.diag_map_fst_snd_comp [HasLimitsOfShape (Discrete WalkingPair) C] {X X' Y Y' : C} (g : X ⟶ Y) (g' : X' ⟶ Y') : diag (X ⨯ X') ≫ prod.map (prod.fst ≫ g) (prod.snd ≫ g') = prod.map g g' := by simp instance {X : C} [HasBinaryProduct X X] : IsSplitMono (diag X) := IsSplitMono.mk' { retraction := prod.fst } end ProdLemmas noncomputable section CoprodLemmas @[reassoc, simp] theorem coprod.desc_comp {V W X Y : C} [HasBinaryCoproduct X Y] (f : V ⟶ W) (g : X ⟶ V) (h : Y ⟶ V) : coprod.desc g h ≫ f = coprod.desc (g ≫ f) (h ≫ f) := by ext <;> simp theorem coprod.diag_comp {X Y : C} [HasBinaryCoproduct X X] (f : X ⟶ Y) : codiag X ≫ f = coprod.desc f f := by simp @[reassoc (attr := simp)] theorem coprod.inl_map {W X Y Z : C} [HasBinaryCoproduct W X] [HasBinaryCoproduct Y Z] (f : W ⟶ Y) (g : X ⟶ Z) : coprod.inl ≫ coprod.map f g = f ≫ coprod.inl := ι_colimMap _ _ @[reassoc (attr := simp)] theorem coprod.inr_map {W X Y Z : C} [HasBinaryCoproduct W X] [HasBinaryCoproduct Y Z] (f : W ⟶ Y) (g : X ⟶ Z) : coprod.inr ≫ coprod.map f g = g ≫ coprod.inr := ι_colimMap _ _ @[simp] theorem coprod.map_id_id {X Y : C} [HasBinaryCoproduct X Y] : coprod.map (𝟙 X) (𝟙 Y) = 𝟙 _ := by ext <;> simp @[simp] theorem coprod.desc_inl_inr {X Y : C} [HasBinaryCoproduct X Y] : coprod.desc coprod.inl coprod.inr = 𝟙 (X ⨿ Y) := by ext <;> simp -- The simp linter says simp can prove the reassoc version of this lemma. @[reassoc, simp] theorem coprod.map_desc {S T U V W : C} [HasBinaryCoproduct U W] [HasBinaryCoproduct T V] (f : U ⟶ S) (g : W ⟶ S) (h : T ⟶ U) (k : V ⟶ W) : coprod.map h k ≫ coprod.desc f g = coprod.desc (h ≫ f) (k ≫ g) := by ext <;> simp @[simp] theorem coprod.desc_comp_inl_comp_inr {W X Y Z : C} [HasBinaryCoproduct W Y]	[HasBinaryCoproduct X Z] (g : W ⟶ X) (g' : Y ⟶ Z) : coprod.desc (g ≫ coprod.inl) (g' ≫ coprod.inr) = coprod.map g g' := by rw [← coprod.map_desc]; simp	Mathlib/CategoryTheory/Limits/Shapes/BinaryProducts.lean	772	774
/- Copyright (c) 2022 Violeta Hernández Palacios. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Violeta Hernández Palacios -/ import Mathlib.Order.GameAdd import Mathlib.Order.RelIso.Set import Mathlib.SetTheory.ZFC.Basic /-! # Von Neumann ordinals This file works towards the development of von Neumann ordinals, i.e. transitive sets, well-ordered under `∈`. ## Definitions - `ZFSet.IsTransitive` means that every element of a set is a subset. - `ZFSet.IsOrdinal` means that the set is transitive and well-ordered under `∈`. We show multiple equivalences to this definition. ## TODO - Define the von Neumann hierarchy. - Build correspondences between these set notions and those of the standard `Ordinal` type. -/ universe u variable {x y z w : ZFSet.{u}} namespace ZFSet /-! ### Transitive sets -/ /-- A transitive set is one where every element is a subset. This is equivalent to being an infinite-open interval in the transitive closure of membership. -/ def IsTransitive (x : ZFSet) : Prop := ∀ y ∈ x, y ⊆ x @[simp] theorem isTransitive_empty : IsTransitive ∅ := fun y hy => (not_mem_empty y hy).elim theorem IsTransitive.subset_of_mem (h : x.IsTransitive) : y ∈ x → y ⊆ x := h y theorem isTransitive_iff_mem_trans : z.IsTransitive ↔ ∀ {x y : ZFSet}, x ∈ y → y ∈ z → x ∈ z := ⟨fun h _ _ hx hy => h.subset_of_mem hy hx, fun H _ hx _ hy => H hy hx⟩ alias ⟨IsTransitive.mem_trans, _⟩ := isTransitive_iff_mem_trans protected theorem IsTransitive.inter (hx : x.IsTransitive) (hy : y.IsTransitive) : (x ∩ y).IsTransitive := fun z hz w hw => by rw [mem_inter] at hz ⊢ exact ⟨hx.mem_trans hw hz.1, hy.mem_trans hw hz.2⟩ /-- The union of a transitive set is transitive. -/ protected theorem IsTransitive.sUnion (h : x.IsTransitive) : (⋃₀ x : ZFSet).IsTransitive := fun y hy z hz => by rcases mem_sUnion.1 hy with ⟨w, hw, hw'⟩ exact mem_sUnion_of_mem hz (h.mem_trans hw' hw) /-- The union of transitive sets is transitive. -/ theorem IsTransitive.sUnion' (H : ∀ y ∈ x, IsTransitive y) : (⋃₀ x : ZFSet).IsTransitive := fun y hy z hz => by rcases mem_sUnion.1 hy with ⟨w, hw, hw'⟩ exact mem_sUnion_of_mem ((H w hw).mem_trans hz hw') hw protected theorem IsTransitive.union (hx : x.IsTransitive) (hy : y.IsTransitive) : (x ∪ y).IsTransitive := by rw [← sUnion_pair] apply IsTransitive.sUnion' intro rw [mem_pair] rintro (rfl \| rfl) assumption' protected theorem IsTransitive.powerset (h : x.IsTransitive) : (powerset x).IsTransitive := fun y hy z hz => by rw [mem_powerset] at hy ⊢ exact h.subset_of_mem (hy hz) theorem isTransitive_iff_sUnion_subset : x.IsTransitive ↔ (⋃₀ x : ZFSet) ⊆ x := by constructor <;> intro h y hy · obtain ⟨z, hz, hz'⟩ := mem_sUnion.1 hy exact h.mem_trans hz' hz · exact fun z hz ↦ h <\| mem_sUnion_of_mem hz hy alias ⟨IsTransitive.sUnion_subset, _⟩ := isTransitive_iff_sUnion_subset theorem isTransitive_iff_subset_powerset : x.IsTransitive ↔ x ⊆ powerset x :=	⟨fun h _ hy => mem_powerset.2 <\| h.subset_of_mem hy, fun H _ hy _ hz => mem_powerset.1 (H hy) hz⟩ alias ⟨IsTransitive.subset_powerset, _⟩ := isTransitive_iff_subset_powerset	Mathlib/SetTheory/ZFC/Ordinal.lean	93	96
/- Copyright (c) 2024 Joël Riou. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Joël Riou -/ import Mathlib.CategoryTheory.Comma.StructuredArrow.Basic import Mathlib.CategoryTheory.Limits.Shapes.Equivalence import Mathlib.CategoryTheory.Limits.Preserves.Shapes.Terminal /-! # Kan extensions The basic definitions for Kan extensions of functors is introduced in this file. Part of API is parallel to the definitions for bicategories (see `CategoryTheory.Bicategory.Kan.IsKan`). (The bicategory API cannot be used directly here because it would not allow the universe polymorphism which is necessary for some applications.) Given a natural transformation `α : L ⋙ F' ⟶ F`, we define the property `F'.IsRightKanExtension α` which expresses that `(F', α)` is a right Kan extension of `F` along `L`, i.e. that it is a terminal object in a category `RightExtension L F` of costructured arrows. The condition `F'.IsLeftKanExtension α` for `α : F ⟶ L ⋙ F'` is defined similarly. We also introduce typeclasses `HasRightKanExtension L F` and `HasLeftKanExtension L F` which assert the existence of a right or left Kan extension, and chosen Kan extensions are obtained as `leftKanExtension L F` and `rightKanExtension L F`. ## References * https://ncatlab.org/nlab/show/Kan+extension -/ namespace CategoryTheory open Category Limits namespace Functor variable {C C' H D D' : Type*} [Category C] [Category C'] [Category H] [Category D] [Category D'] /-- Given two functors `L : C ⥤ D` and `F : C ⥤ H`, this is the category of functors `F' : H ⥤ D` equipped with a natural transformation `L ⋙ F' ⟶ F`. -/ abbrev RightExtension (L : C ⥤ D) (F : C ⥤ H) := CostructuredArrow ((whiskeringLeft C D H).obj L) F /-- Given two functors `L : C ⥤ D` and `F : C ⥤ H`, this is the category of functors `F' : H ⥤ D` equipped with a natural transformation `F ⟶ L ⋙ F'`. -/ abbrev LeftExtension (L : C ⥤ D) (F : C ⥤ H) := StructuredArrow F ((whiskeringLeft C D H).obj L) /-- Constructor for objects of the category `Functor.RightExtension L F`. -/ @[simps!] def RightExtension.mk (F' : D ⥤ H) {L : C ⥤ D} {F : C ⥤ H} (α : L ⋙ F' ⟶ F) : RightExtension L F := CostructuredArrow.mk α /-- Constructor for objects of the category `Functor.LeftExtension L F`. -/ @[simps!] def LeftExtension.mk (F' : D ⥤ H) {L : C ⥤ D} {F : C ⥤ H} (α : F ⟶ L ⋙ F') : LeftExtension L F := StructuredArrow.mk α section variable (F' : D ⥤ H) {L : C ⥤ D} {F : C ⥤ H} (α : L ⋙ F' ⟶ F) /-- Given `α : L ⋙ F' ⟶ F`, the property `F'.IsRightKanExtension α` asserts that `(F', α)` is a terminal object in the category `RightExtension L F`, i.e. that `(F', α)` is a right Kan extension of `F` along `L`. -/ class IsRightKanExtension : Prop where nonempty_isUniversal : Nonempty (RightExtension.mk F' α).IsUniversal variable [F'.IsRightKanExtension α] /-- If `(F', α)` is a right Kan extension of `F` along `L`, then `(F', α)` is a terminal object in the category `RightExtension L F`. -/ noncomputable def isUniversalOfIsRightKanExtension : (RightExtension.mk F' α).IsUniversal := IsRightKanExtension.nonempty_isUniversal.some /-- If `(F', α)` is a right Kan extension of `F` along `L` and `β : L ⋙ G ⟶ F` is a natural transformation, this is the induced morphism `G ⟶ F'`. -/ noncomputable def liftOfIsRightKanExtension (G : D ⥤ H) (β : L ⋙ G ⟶ F) : G ⟶ F' := (F'.isUniversalOfIsRightKanExtension α).lift (RightExtension.mk G β) @[reassoc (attr := simp)] lemma liftOfIsRightKanExtension_fac (G : D ⥤ H) (β : L ⋙ G ⟶ F) : whiskerLeft L (F'.liftOfIsRightKanExtension α G β) ≫ α = β := (F'.isUniversalOfIsRightKanExtension α).fac (RightExtension.mk G β) @[reassoc (attr := simp)] lemma liftOfIsRightKanExtension_fac_app (G : D ⥤ H) (β : L ⋙ G ⟶ F) (X : C) : (F'.liftOfIsRightKanExtension α G β).app (L.obj X) ≫ α.app X = β.app X := NatTrans.congr_app (F'.liftOfIsRightKanExtension_fac α G β) X lemma hom_ext_of_isRightKanExtension {G : D ⥤ H} (γ₁ γ₂ : G ⟶ F') (hγ : whiskerLeft L γ₁ ≫ α = whiskerLeft L γ₂ ≫ α) : γ₁ = γ₂ := (F'.isUniversalOfIsRightKanExtension α).hom_ext hγ /-- If `(F', α)` is a right Kan extension of `F` along `L`, then this is the induced bijection `(G ⟶ F') ≃ (L ⋙ G ⟶ F)` for all `G`. -/ noncomputable def homEquivOfIsRightKanExtension (G : D ⥤ H) : (G ⟶ F') ≃ (L ⋙ G ⟶ F) where toFun β := whiskerLeft _ β ≫ α invFun β := liftOfIsRightKanExtension _ α _ β left_inv β := Functor.hom_ext_of_isRightKanExtension _ α _ _ (by simp) right_inv := by aesop_cat lemma isRightKanExtension_of_iso {F' F'' : D ⥤ H} (e : F' ≅ F'') {L : C ⥤ D} {F : C ⥤ H} (α : L ⋙ F' ⟶ F) (α' : L ⋙ F'' ⟶ F) (comm : whiskerLeft L e.hom ≫ α' = α) [F'.IsRightKanExtension α] : F''.IsRightKanExtension α' where nonempty_isUniversal := ⟨IsTerminal.ofIso (F'.isUniversalOfIsRightKanExtension α) (CostructuredArrow.isoMk e comm)⟩ lemma isRightKanExtension_iff_of_iso {F' F'' : D ⥤ H} (e : F' ≅ F'') {L : C ⥤ D} {F : C ⥤ H} (α : L ⋙ F' ⟶ F) (α' : L ⋙ F'' ⟶ F) (comm : whiskerLeft L e.hom ≫ α' = α) : F'.IsRightKanExtension α ↔ F''.IsRightKanExtension α' := by constructor · intro exact isRightKanExtension_of_iso e α α' comm · intro refine isRightKanExtension_of_iso e.symm α' α ?_ rw [← comm, ← whiskerLeft_comp_assoc, Iso.symm_hom, e.inv_hom_id, whiskerLeft_id', id_comp] /-- Right Kan extensions of isomorphic functors are isomorphic. -/ @[simps] noncomputable def rightKanExtensionUniqueOfIso {G : C ⥤ H} (i : F ≅ G) (G' : D ⥤ H) (β : L ⋙ G' ⟶ G) [G'.IsRightKanExtension β] : F' ≅ G' where hom := liftOfIsRightKanExtension _ β F' (α ≫ i.hom) inv := liftOfIsRightKanExtension _ α G' (β ≫ i.inv) hom_inv_id := F'.hom_ext_of_isRightKanExtension α _ _ (by simp) inv_hom_id := G'.hom_ext_of_isRightKanExtension β _ _ (by simp) /-- Two right Kan extensions are (canonically) isomorphic. -/ @[simps!] noncomputable def rightKanExtensionUnique (F'' : D ⥤ H) (α' : L ⋙ F'' ⟶ F) [F''.IsRightKanExtension α'] : F' ≅ F'' := rightKanExtensionUniqueOfIso F' α (Iso.refl _) F'' α' lemma isRightKanExtension_iff_isIso {F' : D ⥤ H} {F'' : D ⥤ H} (φ : F'' ⟶ F') {L : C ⥤ D} {F : C ⥤ H} (α : L ⋙ F' ⟶ F) (α' : L ⋙ F'' ⟶ F) (comm : whiskerLeft L φ ≫ α = α') [F'.IsRightKanExtension α] : F''.IsRightKanExtension α' ↔ IsIso φ := by constructor · intro rw [F'.hom_ext_of_isRightKanExtension α φ (rightKanExtensionUnique _ α' _ α).hom (by simp [comm])] infer_instance · intro rw [isRightKanExtension_iff_of_iso (asIso φ) α' α comm] infer_instance end section variable (F' : D ⥤ H) {L : C ⥤ D} {F : C ⥤ H} (α : F ⟶ L ⋙ F') /-- Given `α : F ⟶ L ⋙ F'`, the property `F'.IsLeftKanExtension α` asserts that `(F', α)` is an initial object in the category `LeftExtension L F`, i.e. that `(F', α)` is a left Kan extension of `F` along `L`. -/ class IsLeftKanExtension : Prop where nonempty_isUniversal : Nonempty (LeftExtension.mk F' α).IsUniversal variable [F'.IsLeftKanExtension α] /-- If `(F', α)` is a left Kan extension of `F` along `L`, then `(F', α)` is an initial object in the category `LeftExtension L F`. -/ noncomputable def isUniversalOfIsLeftKanExtension : (LeftExtension.mk F' α).IsUniversal := IsLeftKanExtension.nonempty_isUniversal.some /-- If `(F', α)` is a left Kan extension of `F` along `L` and `β : F ⟶ L ⋙ G` is a natural transformation, this is the induced morphism `F' ⟶ G`. -/ noncomputable def descOfIsLeftKanExtension (G : D ⥤ H) (β : F ⟶ L ⋙ G) : F' ⟶ G := (F'.isUniversalOfIsLeftKanExtension α).desc (LeftExtension.mk G β) @[reassoc (attr := simp)] lemma descOfIsLeftKanExtension_fac (G : D ⥤ H) (β : F ⟶ L ⋙ G) : α ≫ whiskerLeft L (F'.descOfIsLeftKanExtension α G β) = β := (F'.isUniversalOfIsLeftKanExtension α).fac (LeftExtension.mk G β) @[reassoc (attr := simp)] lemma descOfIsLeftKanExtension_fac_app (G : D ⥤ H) (β : F ⟶ L ⋙ G) (X : C) : α.app X ≫ (F'.descOfIsLeftKanExtension α G β).app (L.obj X) = β.app X := NatTrans.congr_app (F'.descOfIsLeftKanExtension_fac α G β) X lemma hom_ext_of_isLeftKanExtension {G : D ⥤ H} (γ₁ γ₂ : F' ⟶ G) (hγ : α ≫ whiskerLeft L γ₁ = α ≫ whiskerLeft L γ₂) : γ₁ = γ₂ := (F'.isUniversalOfIsLeftKanExtension α).hom_ext hγ /-- If `(F', α)` is a left Kan extension of `F` along `L`, then this is the induced bijection `(F' ⟶ G) ≃ (F ⟶ L ⋙ G)` for all `G`. -/ noncomputable def homEquivOfIsLeftKanExtension (G : D ⥤ H) : (F' ⟶ G) ≃ (F ⟶ L ⋙ G) where toFun β := α ≫ whiskerLeft _ β invFun β := descOfIsLeftKanExtension _ α _ β left_inv β := Functor.hom_ext_of_isLeftKanExtension _ α _ _ (by simp) right_inv := by aesop_cat lemma isLeftKanExtension_of_iso {F' : D ⥤ H} {F'' : D ⥤ H} (e : F' ≅ F'') {L : C ⥤ D} {F : C ⥤ H} (α : F ⟶ L ⋙ F') (α' : F ⟶ L ⋙ F'') (comm : α ≫ whiskerLeft L e.hom = α') [F'.IsLeftKanExtension α] : F''.IsLeftKanExtension α' where nonempty_isUniversal := ⟨IsInitial.ofIso (F'.isUniversalOfIsLeftKanExtension α) (StructuredArrow.isoMk e comm)⟩ lemma isLeftKanExtension_iff_of_iso {F' F'' : D ⥤ H} (e : F' ≅ F'') {L : C ⥤ D} {F : C ⥤ H} (α : F ⟶ L ⋙ F') (α' : F ⟶ L ⋙ F'') (comm : α ≫ whiskerLeft L e.hom = α') : F'.IsLeftKanExtension α ↔ F''.IsLeftKanExtension α' := by constructor · intro exact isLeftKanExtension_of_iso e α α' comm · intro refine isLeftKanExtension_of_iso e.symm α' α ?_ rw [← comm, assoc, ← whiskerLeft_comp, Iso.symm_hom, e.hom_inv_id, whiskerLeft_id', comp_id] /-- Left Kan extensions of isomorphic functors are isomorphic. -/ @[simps] noncomputable def leftKanExtensionUniqueOfIso {G : C ⥤ H} (i : F ≅ G) (G' : D ⥤ H) (β : G ⟶ L ⋙ G') [G'.IsLeftKanExtension β] : F' ≅ G' where hom := descOfIsLeftKanExtension _ α G' (i.hom ≫ β) inv := descOfIsLeftKanExtension _ β F' (i.inv ≫ α) hom_inv_id := F'.hom_ext_of_isLeftKanExtension α _ _ (by simp) inv_hom_id := G'.hom_ext_of_isLeftKanExtension β _ _ (by simp) /-- Two left Kan extensions are (canonically) isomorphic. -/ @[simps!] noncomputable def leftKanExtensionUnique (F'' : D ⥤ H) (α' : F ⟶ L ⋙ F'') [F''.IsLeftKanExtension α'] : F' ≅ F'' := leftKanExtensionUniqueOfIso F' α (Iso.refl _) F'' α' lemma isLeftKanExtension_iff_isIso {F' : D ⥤ H} {F'' : D ⥤ H} (φ : F' ⟶ F'') {L : C ⥤ D} {F : C ⥤ H} (α : F ⟶ L ⋙ F') (α' : F ⟶ L ⋙ F'') (comm : α ≫ whiskerLeft L φ = α') [F'.IsLeftKanExtension α] : F''.IsLeftKanExtension α' ↔ IsIso φ := by constructor · intro rw [F'.hom_ext_of_isLeftKanExtension α φ (leftKanExtensionUnique _ α _ α').hom (by simp [comm])] infer_instance · intro exact isLeftKanExtension_of_iso (asIso φ) α α' comm end /-- This property `HasRightKanExtension L F` holds when the functor `F` has a right Kan extension along `L`. -/ abbrev HasRightKanExtension (L : C ⥤ D) (F : C ⥤ H) := HasTerminal (RightExtension L F) lemma HasRightKanExtension.mk (F' : D ⥤ H) {L : C ⥤ D} {F : C ⥤ H} (α : L ⋙ F' ⟶ F) [F'.IsRightKanExtension α] : HasRightKanExtension L F := (F'.isUniversalOfIsRightKanExtension α).hasTerminal /-- This property `HasLeftKanExtension L F` holds when the functor `F` has a left Kan extension along `L`. -/ abbrev HasLeftKanExtension (L : C ⥤ D) (F : C ⥤ H) := HasInitial (LeftExtension L F) lemma HasLeftKanExtension.mk (F' : D ⥤ H) {L : C ⥤ D} {F : C ⥤ H} (α : F ⟶ L ⋙ F') [F'.IsLeftKanExtension α] : HasLeftKanExtension L F := (F'.isUniversalOfIsLeftKanExtension α).hasInitial section variable (L : C ⥤ D) (F : C ⥤ H) [HasRightKanExtension L F] /-- A chosen right Kan extension when `[HasRightKanExtension L F]` holds. -/ noncomputable def rightKanExtension : D ⥤ H := (⊤_ _ : RightExtension L F).left /-- The counit of the chosen right Kan extension `rightKanExtension L F`. -/ noncomputable def rightKanExtensionCounit : L ⋙ rightKanExtension L F ⟶ F := (⊤_ _ : RightExtension L F).hom instance : (L.rightKanExtension F).IsRightKanExtension (L.rightKanExtensionCounit F) where nonempty_isUniversal := ⟨terminalIsTerminal⟩ @[ext] lemma rightKanExtension_hom_ext {G : D ⥤ H} (γ₁ γ₂ : G ⟶ rightKanExtension L F) (hγ : whiskerLeft L γ₁ ≫ rightKanExtensionCounit L F = whiskerLeft L γ₂ ≫ rightKanExtensionCounit L F) : γ₁ = γ₂ := hom_ext_of_isRightKanExtension _ _ _ _ hγ end section variable (L : C ⥤ D) (F : C ⥤ H) [HasLeftKanExtension L F] /-- A chosen left Kan extension when `[HasLeftKanExtension L F]` holds. -/ noncomputable def leftKanExtension : D ⥤ H := (⊥_ _ : LeftExtension L F).right /-- The unit of the chosen left Kan extension `leftKanExtension L F`. -/ noncomputable def leftKanExtensionUnit : F ⟶ L ⋙ leftKanExtension L F := (⊥_ _ : LeftExtension L F).hom instance : (L.leftKanExtension F).IsLeftKanExtension (L.leftKanExtensionUnit F) where nonempty_isUniversal := ⟨initialIsInitial⟩ @[ext] lemma leftKanExtension_hom_ext {G : D ⥤ H} (γ₁ γ₂ : leftKanExtension L F ⟶ G) (hγ : leftKanExtensionUnit L F ≫ whiskerLeft L γ₁ = leftKanExtensionUnit L F ≫ whiskerLeft L γ₂) : γ₁ = γ₂ := hom_ext_of_isLeftKanExtension _ _ _ _ hγ end section variable {L : C ⥤ D} {L' : C ⥤ D'} (G : D ⥤ D') /-- The functor `LeftExtension L' F ⥤ LeftExtension L F` induced by a natural transformation `L' ⟶ L ⋙ G'`. -/ @[simps!] def LeftExtension.postcomp₁ (f : L' ⟶ L ⋙ G) (F : C ⥤ H) : LeftExtension L' F ⥤ LeftExtension L F := StructuredArrow.map₂ (F := (whiskeringLeft D D' H).obj G) (G := 𝟭 _) (𝟙 _) ((whiskeringLeft C D' H).map f) /-- The functor `RightExtension L' F ⥤ RightExtension L F` induced by a natural transformation `L ⋙ G ⟶ L'`. -/ @[simps!] def RightExtension.postcomp₁ (f : L ⋙ G ⟶ L') (F : C ⥤ H) : RightExtension L' F ⥤ RightExtension L F := CostructuredArrow.map₂ (F := (whiskeringLeft D D' H).obj G) (G := 𝟭 _) ((whiskeringLeft C D' H).map f) (𝟙 _) variable [IsEquivalence G] noncomputable instance (f : L' ⟶ L ⋙ G) [IsIso f] (F : C ⥤ H) : IsEquivalence (LeftExtension.postcomp₁ G f F) := by apply StructuredArrow.isEquivalenceMap₂ noncomputable instance (f : L ⋙ G ⟶ L') [IsIso f] (F : C ⥤ H) : IsEquivalence (RightExtension.postcomp₁ G f F) := by apply CostructuredArrow.isEquivalenceMap₂ variable {G} in lemma hasLeftExtension_iff_postcomp₁ (e : L ⋙ G ≅ L') (F : C ⥤ H) : HasLeftKanExtension L' F ↔ HasLeftKanExtension L F := (LeftExtension.postcomp₁ G e.inv F).asEquivalence.hasInitial_iff variable {G} in lemma hasRightExtension_iff_postcomp₁ (e : L ⋙ G ≅ L') (F : C ⥤ H) : HasRightKanExtension L' F ↔ HasRightKanExtension L F := (RightExtension.postcomp₁ G e.hom F).asEquivalence.hasTerminal_iff variable (e : L ⋙ G ≅ L') (F : C ⥤ H) /-- Given an isomorphism `e : L ⋙ G ≅ L'`, a left extension of `F` along `L'` is universal iff the corresponding left extension of `L` along `L` is. -/ noncomputable def LeftExtension.isUniversalPostcomp₁Equiv (ex : LeftExtension L' F) : ex.IsUniversal ≃ ((LeftExtension.postcomp₁ G e.inv F).obj ex).IsUniversal := by apply IsInitial.isInitialIffObj (LeftExtension.postcomp₁ G e.inv F) /-- Given an isomorphism `e : L ⋙ G ≅ L'`, a right extension of `F` along `L'` is universal iff the corresponding right extension of `L` along `L` is. -/ noncomputable def RightExtension.isUniversalPostcomp₁Equiv (ex : RightExtension L' F) : ex.IsUniversal ≃ ((RightExtension.postcomp₁ G e.hom F).obj ex).IsUniversal := by apply IsTerminal.isTerminalIffObj (RightExtension.postcomp₁ G e.hom F) variable {F F'} lemma isLeftKanExtension_iff_postcomp₁ (α : F ⟶ L' ⋙ F') : F'.IsLeftKanExtension α ↔ (G ⋙ F').IsLeftKanExtension (α ≫ whiskerRight e.inv _ ≫ (Functor.associator _ _ _).hom) := by let eq : (LeftExtension.mk _ α).IsUniversal ≃ (LeftExtension.mk _ (α ≫ whiskerRight e.inv _ ≫ (Functor.associator _ _ _).hom)).IsUniversal := (LeftExtension.isUniversalPostcomp₁Equiv G e F _).trans (IsInitial.equivOfIso (StructuredArrow.isoMk (Iso.refl _))) constructor · exact fun _ => ⟨⟨eq (isUniversalOfIsLeftKanExtension _ _)⟩⟩ · exact fun _ => ⟨⟨eq.symm (isUniversalOfIsLeftKanExtension _ _)⟩⟩ lemma isRightKanExtension_iff_postcomp₁ (α : L' ⋙ F' ⟶ F) : F'.IsRightKanExtension α ↔ (G ⋙ F').IsRightKanExtension ((Functor.associator _ _ _).inv ≫ whiskerRight e.hom F' ≫ α) := by let eq : (RightExtension.mk _ α).IsUniversal ≃ (RightExtension.mk _ ((Functor.associator _ _ _).inv ≫ whiskerRight e.hom F' ≫ α)).IsUniversal := (RightExtension.isUniversalPostcomp₁Equiv G e F _).trans (IsTerminal.equivOfIso (CostructuredArrow.isoMk (Iso.refl _))) constructor · exact fun _ => ⟨⟨eq (isUniversalOfIsRightKanExtension _ _)⟩⟩ · exact fun _ => ⟨⟨eq.symm (isUniversalOfIsRightKanExtension _ _)⟩⟩ end section variable (L : C ⥤ D) (F : C ⥤ H) (F' : D ⥤ H) (G : C' ⥤ C) /-- The functor `LeftExtension L F ⥤ LeftExtension (G ⋙ L) (G ⋙ F)` obtained by precomposition. -/ @[simps!] def LeftExtension.precomp : LeftExtension L F ⥤ LeftExtension (G ⋙ L) (G ⋙ F) := StructuredArrow.map₂ (F := 𝟭 _) (G := (whiskeringLeft C' C H).obj G) (𝟙 _) (𝟙 _) /-- The functor `RightExtension L F ⥤ RightExtension (G ⋙ L) (G ⋙ F)` obtained by precomposition. -/ @[simps!] def RightExtension.precomp : RightExtension L F ⥤ RightExtension (G ⋙ L) (G ⋙ F) := CostructuredArrow.map₂ (F := 𝟭 _) (G := (whiskeringLeft C' C H).obj G) (𝟙 _) (𝟙 _) variable [IsEquivalence G] noncomputable instance : IsEquivalence (LeftExtension.precomp L F G) := by apply StructuredArrow.isEquivalenceMap₂ noncomputable instance : IsEquivalence (RightExtension.precomp L F G) := by apply CostructuredArrow.isEquivalenceMap₂ /-- If `G` is an equivalence, then a left extension of `F` along `L` is universal iff the corresponding left extension of `G ⋙ F` along `G ⋙ L` is. -/ noncomputable def LeftExtension.isUniversalPrecompEquiv (e : LeftExtension L F) : e.IsUniversal ≃ ((LeftExtension.precomp L F G).obj e).IsUniversal := by apply IsInitial.isInitialIffObj (LeftExtension.precomp L F G) /-- If `G` is an equivalence, then a right extension of `F` along `L` is universal iff the corresponding left extension of `G ⋙ F` along `G ⋙ L` is. -/ noncomputable def RightExtension.isUniversalPrecompEquiv (e : RightExtension L F) : e.IsUniversal ≃ ((RightExtension.precomp L F G).obj e).IsUniversal := by apply IsTerminal.isTerminalIffObj (RightExtension.precomp L F G) variable {F L}	lemma isLeftKanExtension_iff_precomp (α : F ⟶ L ⋙ F') : F'.IsLeftKanExtension α ↔ F'.IsLeftKanExtension (whiskerLeft G α ≫ (Functor.associator _ _ _).inv) := by let eq : (LeftExtension.mk _ α).IsUniversal ≃ (LeftExtension.mk _ (whiskerLeft G α ≫ (Functor.associator _ _ _).inv)).IsUniversal := (LeftExtension.isUniversalPrecompEquiv L F G _).trans (IsInitial.equivOfIso (StructuredArrow.isoMk (Iso.refl _))) constructor · exact fun _ => ⟨⟨eq (isUniversalOfIsLeftKanExtension _ _)⟩⟩	Mathlib/CategoryTheory/Functor/KanExtension/Basic.lean	426	435
/- Copyright (c) 2023 Joël Riou. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Joël Riou -/ import Mathlib.Algebra.Homology.HomotopyCategory.HomComplex import Mathlib.Algebra.Homology.HomotopyCofiber /-! # The mapping cone of a morphism of cochain complexes In this file, we study the homotopy cofiber `HomologicalComplex.homotopyCofiber` of a morphism `φ : F ⟶ G` of cochain complexes indexed by `ℤ`. In this case, we redefine it as `CochainComplex.mappingCone φ`. The API involves definitions - `mappingCone.inl φ : Cochain F (mappingCone φ) (-1)`, - `mappingCone.inr φ : G ⟶ mappingCone φ`, - `mappingCone.fst φ : Cocycle (mappingCone φ) F 1` and - `mappingCone.snd φ : Cochain (mappingCone φ) G 0`. -/ assert_not_exists TwoSidedIdeal open CategoryTheory Limits variable {C D : Type} [Category C] [Category D] [Preadditive C] [Preadditive D] namespace CochainComplex open HomologicalComplex section variable {ι : Type} [AddRightCancelSemigroup ι] [One ι] {F G : CochainComplex C ι} (φ : F ⟶ G) instance [∀ p, HasBinaryBiproduct (F.X (p + 1)) (G.X p)] : HasHomotopyCofiber φ where hasBinaryBiproduct := by rintro i _ rfl infer_instance end variable {F G : CochainComplex C ℤ} (φ : F ⟶ G) variable [HasHomotopyCofiber φ] /-- The mapping cone of a morphism of cochain complexes indexed by `ℤ`. -/ noncomputable def mappingCone := homotopyCofiber φ namespace mappingCone open HomComplex /-- The left inclusion in the mapping cone, as a cochain of degree `-1`. -/ noncomputable def inl : Cochain F (mappingCone φ) (-1) := Cochain.mk (fun p q hpq => homotopyCofiber.inlX φ p q (by dsimp; omega)) /-- The right inclusion in the mapping cone. -/ noncomputable def inr : G ⟶ mappingCone φ := homotopyCofiber.inr φ /-- The first projection from the mapping cone, as a cocyle of degree `1`. -/ noncomputable def fst : Cocycle (mappingCone φ) F 1 := Cocycle.mk (Cochain.mk (fun p q hpq => homotopyCofiber.fstX φ p q hpq)) 2 (by omega) (by ext p _ rfl simp [δ_v 1 2 (by omega) _ p (p + 2) (by omega) (p + 1) (p + 1) (by omega) rfl, homotopyCofiber.d_fstX φ p (p + 1) (p + 2) rfl, mappingCone, show Int.negOnePow 2 = 1 by rfl]) /-- The second projection from the mapping cone, as a cochain of degree `0`. -/ noncomputable def snd : Cochain (mappingCone φ) G 0 := Cochain.ofHoms (homotopyCofiber.sndX φ) @[reassoc (attr := simp)] lemma inl_v_fst_v (p q : ℤ) (hpq : q + 1 = p) : (inl φ).v p q (by rw [← hpq, add_neg_cancel_right]) ≫ (fst φ : Cochain (mappingCone φ) F 1).v q p hpq = 𝟙 _ := by simp [inl, fst] @[reassoc (attr := simp)] lemma inl_v_snd_v (p q : ℤ) (hpq : p + (-1) = q) : (inl φ).v p q hpq ≫ (snd φ).v q q (add_zero q) = 0 := by simp [inl, snd] @[reassoc (attr := simp)] lemma inr_f_fst_v (p q : ℤ) (hpq : p + 1 = q) : (inr φ).f p ≫ (fst φ).1.v p q hpq = 0 := by simp [inr, fst] @[reassoc (attr := simp)] lemma inr_f_snd_v (p : ℤ) : (inr φ).f p ≫ (snd φ).v p p (add_zero p) = 𝟙 _ := by simp [inr, snd] @[simp] lemma inl_fst : (inl φ).comp (fst φ).1 (neg_add_cancel 1) = Cochain.ofHom (𝟙 F) := by ext p simp [Cochain.comp_v _ _ (neg_add_cancel 1) p (p-1) p rfl (by omega)] @[simp] lemma inl_snd : (inl φ).comp (snd φ) (add_zero (-1)) = 0 := by ext p q hpq simp [Cochain.comp_v _ _ (add_zero (-1)) p q q (by omega) (by omega)] @[simp] lemma inr_fst : (Cochain.ofHom (inr φ)).comp (fst φ).1 (zero_add 1) = 0 := by ext p q hpq simp [Cochain.comp_v _ _ (zero_add 1) p p q (by omega) (by omega)] @[simp] lemma inr_snd : (Cochain.ofHom (inr φ)).comp (snd φ) (zero_add 0) = Cochain.ofHom (𝟙 G) := by aesop_cat /-! In order to obtain identities of cochains involving `inl`, `inr`, `fst` and `snd`, it is often convenient to use an `ext` lemma, and use simp lemmas like `inl_v_f_fst_v`, but it is sometimes possible to get identities of cochains by using rewrites of identities of cochains like `inl_fst`. Then, similarly as in category theory, if we associate the compositions of cochains to the right as much as possible, it is also interesting to have `reassoc` variants of lemmas, like `inl_fst_assoc`. -/ @[simp] lemma inl_fst_assoc {K : CochainComplex C ℤ} {d e : ℤ} (γ : Cochain F K d) (he : 1 + d = e) : (inl φ).comp ((fst φ).1.comp γ he) (by rw [← he, neg_add_cancel_left]) = γ := by rw [← Cochain.comp_assoc _ _ _ (neg_add_cancel 1) (by omega) (by omega), inl_fst, Cochain.id_comp] @[simp] lemma inl_snd_assoc {K : CochainComplex C ℤ} {d e f : ℤ} (γ : Cochain G K d) (he : 0 + d = e) (hf : -1 + e = f) : (inl φ).comp ((snd φ).comp γ he) hf = 0 := by obtain rfl : e = d := by omega rw [← Cochain.comp_assoc_of_second_is_zero_cochain, inl_snd, Cochain.zero_comp] @[simp] lemma inr_fst_assoc {K : CochainComplex C ℤ} {d e f : ℤ} (γ : Cochain F K d) (he : 1 + d = e) (hf : 0 + e = f) : (Cochain.ofHom (inr φ)).comp ((fst φ).1.comp γ he) hf = 0 := by obtain rfl : e = f := by omega rw [← Cochain.comp_assoc_of_first_is_zero_cochain, inr_fst, Cochain.zero_comp] @[simp] lemma inr_snd_assoc {K : CochainComplex C ℤ} {d e : ℤ} (γ : Cochain G K d) (he : 0 + d = e) : (Cochain.ofHom (inr φ)).comp ((snd φ).comp γ he) (by simp only [← he, zero_add]) = γ := by obtain rfl : d = e := by omega rw [← Cochain.comp_assoc_of_first_is_zero_cochain, inr_snd, Cochain.id_comp] lemma ext_to (i j : ℤ) (hij : i + 1 = j) {A : C} {f g : A ⟶ (mappingCone φ).X i} (h₁ : f ≫ (fst φ).1.v i j hij = g ≫ (fst φ).1.v i j hij) (h₂ : f ≫ (snd φ).v i i (add_zero i) = g ≫ (snd φ).v i i (add_zero i)) : f = g := homotopyCofiber.ext_to_X φ i j hij h₁ (by simpa [snd] using h₂) lemma ext_to_iff (i j : ℤ) (hij : i + 1 = j) {A : C} (f g : A ⟶ (mappingCone φ).X i) : f = g ↔ f ≫ (fst φ).1.v i j hij = g ≫ (fst φ).1.v i j hij ∧ f ≫ (snd φ).v i i (add_zero i) = g ≫ (snd φ).v i i (add_zero i) := by constructor · rintro rfl tauto · rintro ⟨h₁, h₂⟩ exact ext_to φ i j hij h₁ h₂ lemma ext_from (i j : ℤ) (hij : j + 1 = i) {A : C} {f g : (mappingCone φ).X j ⟶ A} (h₁ : (inl φ).v i j (by omega) ≫ f = (inl φ).v i j (by omega) ≫ g) (h₂ : (inr φ).f j ≫ f = (inr φ).f j ≫ g) : f = g := homotopyCofiber.ext_from_X φ i j hij h₁ h₂ lemma ext_from_iff (i j : ℤ) (hij : j + 1 = i) {A : C} (f g : (mappingCone φ).X j ⟶ A) : f = g ↔ (inl φ).v i j (by omega) ≫ f = (inl φ).v i j (by omega) ≫ g ∧ (inr φ).f j ≫ f = (inr φ).f j ≫ g := by constructor · rintro rfl tauto · rintro ⟨h₁, h₂⟩ exact ext_from φ i j hij h₁ h₂ lemma decomp_to {i : ℤ} {A : C} (f : A ⟶ (mappingCone φ).X i) (j : ℤ) (hij : i + 1 = j) : ∃ (a : A ⟶ F.X j) (b : A ⟶ G.X i), f = a ≫ (inl φ).v j i (by omega) + b ≫ (inr φ).f i := ⟨f ≫ (fst φ).1.v i j hij, f ≫ (snd φ).v i i (add_zero i), by apply ext_to φ i j hij <;> simp⟩ lemma decomp_from {j : ℤ} {A : C} (f : (mappingCone φ).X j ⟶ A) (i : ℤ) (hij : j + 1 = i) : ∃ (a : F.X i ⟶ A) (b : G.X j ⟶ A), f = (fst φ).1.v j i hij ≫ a + (snd φ).v j j (add_zero j) ≫ b := ⟨(inl φ).v i j (by omega) ≫ f, (inr φ).f j ≫ f, by apply ext_from φ i j hij <;> simp⟩ lemma ext_cochain_to_iff (i j : ℤ) (hij : i + 1 = j) {K : CochainComplex C ℤ} {γ₁ γ₂ : Cochain K (mappingCone φ) i} : γ₁ = γ₂ ↔ γ₁.comp (fst φ).1 hij = γ₂.comp (fst φ).1 hij ∧ γ₁.comp (snd φ) (add_zero i) = γ₂.comp (snd φ) (add_zero i) := by constructor · rintro rfl tauto · rintro ⟨h₁, h₂⟩ ext p q hpq rw [ext_to_iff φ q (q + 1) rfl] replace h₁ := Cochain.congr_v h₁ p (q + 1) (by omega) replace h₂ := Cochain.congr_v h₂ p q hpq simp only [Cochain.comp_v _ _ _ p q (q + 1) hpq rfl] at h₁ simp only [Cochain.comp_zero_cochain_v] at h₂ exact ⟨h₁, h₂⟩ lemma ext_cochain_from_iff (i j : ℤ) (hij : i + 1 = j) {K : CochainComplex C ℤ} {γ₁ γ₂ : Cochain (mappingCone φ) K j} : γ₁ = γ₂ ↔ (inl φ).comp γ₁ (show _ = i by omega) = (inl φ).comp γ₂ (by omega) ∧ (Cochain.ofHom (inr φ)).comp γ₁ (zero_add j) = (Cochain.ofHom (inr φ)).comp γ₂ (zero_add j) := by constructor · rintro rfl tauto · rintro ⟨h₁, h₂⟩ ext p q hpq rw [ext_from_iff φ (p + 1) p rfl] replace h₁ := Cochain.congr_v h₁ (p + 1) q (by omega) replace h₂ := Cochain.congr_v h₂ p q (by omega) simp only [Cochain.comp_v (inl φ) _ _ (p + 1) p q (by omega) hpq] at h₁ simp only [Cochain.zero_cochain_comp_v, Cochain.ofHom_v] at h₂ exact ⟨h₁, h₂⟩ lemma id : (fst φ).1.comp (inl φ) (add_neg_cancel 1) + (snd φ).comp (Cochain.ofHom (inr φ)) (add_zero 0) = Cochain.ofHom (𝟙 _) := by simp [ext_cochain_from_iff φ (-1) 0 (neg_add_cancel 1)] lemma id_X (p q : ℤ) (hpq : p + 1 = q) : (fst φ).1.v p q hpq ≫ (inl φ).v q p (by omega) + (snd φ).v p p (add_zero p) ≫ (inr φ).f p = 𝟙 ((mappingCone φ).X p) := by simpa only [Cochain.add_v, Cochain.comp_zero_cochain_v, Cochain.ofHom_v, id_f, Cochain.comp_v _ _ (add_neg_cancel 1) p q p hpq (by omega)] using Cochain.congr_v (id φ) p p (add_zero p) @[reassoc] lemma inl_v_d (i j k : ℤ) (hij : i + (-1) = j) (hik : k + (-1) = i) : (inl φ).v i j hij ≫ (mappingCone φ).d j i = φ.f i ≫ (inr φ).f i - F.d i k ≫ (inl φ).v _ _ hik := by dsimp [mappingCone, inl, inr] rw [homotopyCofiber.inlX_d φ j i k (by dsimp; omega) (by dsimp; omega)] abel @[reassoc] lemma inr_f_d (n₁ n₂ : ℤ) : (inr φ).f n₁ ≫ (mappingCone φ).d n₁ n₂ = G.d n₁ n₂ ≫ (inr φ).f n₂ := by simp @[reassoc] lemma d_fst_v (i j k : ℤ) (hij : i + 1 = j) (hjk : j + 1 = k) : (mappingCone φ).d i j ≫ (fst φ).1.v j k hjk = -(fst φ).1.v i j hij ≫ F.d j k := by apply homotopyCofiber.d_fstX @[reassoc (attr := simp)] lemma d_fst_v' (i j : ℤ) (hij : i + 1 = j) : (mappingCone φ).d (i - 1) i ≫ (fst φ).1.v i j hij = -(fst φ).1.v (i - 1) i (by omega) ≫ F.d i j := d_fst_v φ (i - 1) i j (by omega) hij @[reassoc] lemma d_snd_v (i j : ℤ) (hij : i + 1 = j) : (mappingCone φ).d i j ≫ (snd φ).v j j (add_zero _) = (fst φ).1.v i j hij ≫ φ.f j + (snd φ).v i i (add_zero i) ≫ G.d i j := by dsimp [mappingCone, snd, fst] simp only [Cochain.ofHoms_v] apply homotopyCofiber.d_sndX @[reassoc (attr := simp)] lemma d_snd_v' (n : ℤ) : (mappingCone φ).d (n - 1) n ≫ (snd φ).v n n (add_zero n) = (fst φ : Cochain (mappingCone φ) F 1).v (n - 1) n (by omega) ≫ φ.f n + (snd φ).v (n - 1) (n - 1) (add_zero _) ≫ G.d (n - 1) n := by apply d_snd_v @[simp] lemma δ_inl : δ (-1) 0 (inl φ) = Cochain.ofHom (φ ≫ inr φ) := by ext p simp [δ_v (-1) 0 (neg_add_cancel 1) (inl φ) p p (add_zero p) _ _ rfl rfl, inl_v_d φ p (p - 1) (p + 1) (by omega) (by omega)] @[simp] lemma δ_snd : δ 0 1 (snd φ) = -(fst φ).1.comp (Cochain.ofHom φ) (add_zero 1) := by ext p q hpq simp [d_snd_v φ p q hpq] section variable {K : CochainComplex C ℤ} {n m : ℤ} /-- Given `φ : F ⟶ G`, this is the cochain in `Cochain (mappingCone φ) K n` that is constructed from two cochains `α : Cochain F K m` (with `m + 1 = n`) and `β : Cochain F K n`. -/ noncomputable def descCochain (α : Cochain F K m) (β : Cochain G K n) (h : m + 1 = n) : Cochain (mappingCone φ) K n := (fst φ).1.comp α (by rw [← h, add_comm]) + (snd φ).comp β (zero_add n) variable (α : Cochain F K m) (β : Cochain G K n) (h : m + 1 = n) @[simp] lemma inl_descCochain : (inl φ).comp (descCochain φ α β h) (by omega) = α := by simp [descCochain] @[simp] lemma inr_descCochain : (Cochain.ofHom (inr φ)).comp (descCochain φ α β h) (zero_add n) = β := by simp [descCochain] @[reassoc (attr := simp)] lemma inl_v_descCochain_v (p₁ p₂ p₃ : ℤ) (h₁₂ : p₁ + (-1) = p₂) (h₂₃ : p₂ + n = p₃) : (inl φ).v p₁ p₂ h₁₂ ≫ (descCochain φ α β h).v p₂ p₃ h₂₃ = α.v p₁ p₃ (by rw [← h₂₃, ← h₁₂, ← h, add_comm m, add_assoc, neg_add_cancel_left]) := by simpa only [Cochain.comp_v _ _ (show -1 + n = m by omega) p₁ p₂ p₃ (by omega) (by omega)] using Cochain.congr_v (inl_descCochain φ α β h) p₁ p₃ (by omega) @[reassoc (attr := simp)] lemma inr_f_descCochain_v (p₁ p₂ : ℤ) (h₁₂ : p₁ + n = p₂) : (inr φ).f p₁ ≫ (descCochain φ α β h).v p₁ p₂ h₁₂ = β.v p₁ p₂ h₁₂ := by simpa only [Cochain.comp_v _ _ (zero_add n) p₁ p₁ p₂ (add_zero p₁) h₁₂, Cochain.ofHom_v] using Cochain.congr_v (inr_descCochain φ α β h) p₁ p₂ (by omega) lemma δ_descCochain (n' : ℤ) (hn' : n + 1 = n') : δ n n' (descCochain φ α β h) = (fst φ).1.comp (δ m n α + n'.negOnePow • (Cochain.ofHom φ).comp β (zero_add n)) (by omega) + (snd φ).comp (δ n n' β) (zero_add n') := by dsimp only [descCochain] simp only [δ_add, Cochain.comp_add, δ_comp (fst φ).1 α _ 2 n n' hn' (by omega) (by omega), Cocycle.δ_eq_zero, Cochain.zero_comp, smul_zero, add_zero, δ_comp (snd φ) β (zero_add n) 1 n' n' hn' (zero_add 1) hn', δ_snd, Cochain.neg_comp, smul_neg, Cochain.comp_assoc_of_second_is_zero_cochain, Cochain.comp_units_smul, ← hn', Int.negOnePow_succ, Units.neg_smul, Cochain.comp_neg] abel end /-- Given `φ : F ⟶ G`, this is the cocycle in `Cocycle (mappingCone φ) K n` that is constructed from `α : Cochain F K m` (with `m + 1 = n`) and `β : Cocycle F K n`, when a suitable cocycle relation is satisfied. -/ @[simps!] noncomputable def descCocycle {K : CochainComplex C ℤ} {n m : ℤ} (α : Cochain F K m) (β : Cocycle G K n) (h : m + 1 = n) (eq : δ m n α = n.negOnePow • (Cochain.ofHom φ).comp β.1 (zero_add n)) : Cocycle (mappingCone φ) K n := Cocycle.mk (descCochain φ α β.1 h) (n + 1) rfl (by simp [δ_descCochain _ _ _ _ _ rfl, eq, Int.negOnePow_succ]) section variable {K : CochainComplex C ℤ} /-- Given `φ : F ⟶ G`, this is the morphism `mappingCone φ ⟶ K` that is constructed from a cochain `α : Cochain F K (-1)` and a morphism `β : G ⟶ K` such that `δ (-1) 0 α = Cochain.ofHom (φ ≫ β)`. -/ noncomputable def desc (α : Cochain F K (-1)) (β : G ⟶ K) (eq : δ (-1) 0 α = Cochain.ofHom (φ ≫ β)) : mappingCone φ ⟶ K := Cocycle.homOf (descCocycle φ α (Cocycle.ofHom β) (neg_add_cancel 1) (by simp [eq])) variable (α : Cochain F K (-1)) (β : G ⟶ K) (eq : δ (-1) 0 α = Cochain.ofHom (φ ≫ β)) @[simp] lemma ofHom_desc : Cochain.ofHom (desc φ α β eq) = descCochain φ α (Cochain.ofHom β) (neg_add_cancel 1) := by simp [desc] @[reassoc (attr := simp)] lemma inl_v_desc_f (p q : ℤ) (h : p + (-1) = q) : (inl φ).v p q h ≫ (desc φ α β eq).f q = α.v p q h := by simp [desc] lemma inl_desc : (inl φ).comp (Cochain.ofHom (desc φ α β eq)) (add_zero _) = α := by simp @[reassoc (attr := simp)] lemma inr_f_desc_f (p : ℤ) : (inr φ).f p ≫ (desc φ α β eq).f p = β.f p := by simp [desc] @[reassoc (attr := simp)] lemma inr_desc : inr φ ≫ desc φ α β eq = β := by aesop_cat lemma desc_f (p q : ℤ) (hpq : p + 1 = q) : (desc φ α β eq).f p = (fst φ).1.v p q hpq ≫ α.v q p (by omega) + (snd φ).v p p (add_zero p) ≫ β.f p := by simp [ext_from_iff _ _ _ hpq] end /-- Constructor for homotopies between morphisms from a mapping cone. -/ noncomputable def descHomotopy {K : CochainComplex C ℤ} (f₁ f₂ : mappingCone φ ⟶ K) (γ₁ : Cochain F K (-2)) (γ₂ : Cochain G K (-1)) (h₁ : (inl φ).comp (Cochain.ofHom f₁) (add_zero (-1)) = δ (-2) (-1) γ₁ + (Cochain.ofHom φ).comp γ₂ (zero_add (-1)) + (inl φ).comp (Cochain.ofHom f₂) (add_zero (-1))) (h₂ : Cochain.ofHom (inr φ ≫ f₁) = δ (-1) 0 γ₂ + Cochain.ofHom (inr φ ≫ f₂)) : Homotopy f₁ f₂ := (Cochain.equivHomotopy f₁ f₂).symm ⟨descCochain φ γ₁ γ₂ (by norm_num), by simp only [Cochain.ofHom_comp] at h₂ simp [ext_cochain_from_iff _ _ _ (neg_add_cancel 1), δ_descCochain _ _ _ _ _ (neg_add_cancel 1), h₁, h₂]⟩ section variable {K : CochainComplex C ℤ} {n m : ℤ} /-- Given `φ : F ⟶ G`, this is the cochain in `Cochain (mappingCone φ) K n` that is constructed from two cochains `α : Cochain F K m` (with `m + 1 = n`) and `β : Cochain F K n`. -/ noncomputable def liftCochain (α : Cochain K F m) (β : Cochain K G n) (h : n + 1 = m) : Cochain K (mappingCone φ) n := α.comp (inl φ) (by omega) + β.comp (Cochain.ofHom (inr φ)) (add_zero n) variable (α : Cochain K F m) (β : Cochain K G n) (h : n + 1 = m) @[simp] lemma liftCochain_fst : (liftCochain φ α β h).comp (fst φ).1 h = α := by simp [liftCochain] @[simp] lemma liftCochain_snd : (liftCochain φ α β h).comp (snd φ) (add_zero n) = β := by simp [liftCochain] @[reassoc (attr := simp)] lemma liftCochain_v_fst_v (p₁ p₂ p₃ : ℤ) (h₁₂ : p₁ + n = p₂) (h₂₃ : p₂ + 1 = p₃) : (liftCochain φ α β h).v p₁ p₂ h₁₂ ≫ (fst φ).1.v p₂ p₃ h₂₃ = α.v p₁ p₃ (by omega) := by simpa only [Cochain.comp_v _ _ h p₁ p₂ p₃ h₁₂ h₂₃] using Cochain.congr_v (liftCochain_fst φ α β h) p₁ p₃ (by omega) @[reassoc (attr := simp)] lemma liftCochain_v_snd_v (p₁ p₂ : ℤ) (h₁₂ : p₁ + n = p₂) : (liftCochain φ α β h).v p₁ p₂ h₁₂ ≫ (snd φ).v p₂ p₂ (add_zero p₂) = β.v p₁ p₂ h₁₂ := by simpa only [Cochain.comp_v _ _ (add_zero n) p₁ p₂ p₂ h₁₂ (add_zero p₂)] using Cochain.congr_v (liftCochain_snd φ α β h) p₁ p₂ (by omega) lemma δ_liftCochain (m' : ℤ) (hm' : m + 1 = m') : δ n m (liftCochain φ α β h) = -(δ m m' α).comp (inl φ) (by omega) + (δ n m β + α.comp (Cochain.ofHom φ) (add_zero m)).comp (Cochain.ofHom (inr φ)) (add_zero m) := by dsimp only [liftCochain] simp only [δ_add, δ_comp α (inl φ) _ m' _ _ h hm' (neg_add_cancel 1), δ_comp_zero_cochain _ _ _ h, δ_inl, Cochain.ofHom_comp, Int.negOnePow_neg, Int.negOnePow_one, Units.neg_smul, one_smul, δ_ofHom, Cochain.comp_zero, zero_add, Cochain.add_comp, Cochain.comp_assoc_of_second_is_zero_cochain] abel end /-- Given `φ : F ⟶ G`, this is the cocycle in `Cocycle K (mappingCone φ) n` that is constructed from `α : Cochain K F m` (with `n + 1 = m`) and `β : Cocycle K G n`, when a suitable cocycle relation is satisfied. -/ @[simps!] noncomputable def liftCocycle {K : CochainComplex C ℤ} {n m : ℤ} (α : Cocycle K F m) (β : Cochain K G n) (h : n + 1 = m) (eq : δ n m β + α.1.comp (Cochain.ofHom φ) (add_zero m) = 0) : Cocycle K (mappingCone φ) n := Cocycle.mk (liftCochain φ α β h) m h (by simp only [δ_liftCochain φ α β h (m+1) rfl, eq, Cocycle.δ_eq_zero, Cochain.zero_comp, neg_zero, add_zero]) section variable {K : CochainComplex C ℤ} (α : Cocycle K F 1) (β : Cochain K G 0) (eq : δ 0 1 β + α.1.comp (Cochain.ofHom φ) (add_zero 1) = 0) /-- Given `φ : F ⟶ G`, this is the morphism `K ⟶ mappingCone φ` that is constructed from a cocycle `α : Cochain K F 1` and a cochain `β : Cochain K G 0` when a suitable cocycle relation is satisfied. -/ noncomputable def lift : K ⟶ mappingCone φ := Cocycle.homOf (liftCocycle φ α β (zero_add 1) eq) @[simp] lemma ofHom_lift : Cochain.ofHom (lift φ α β eq) = liftCochain φ α β (zero_add 1) := by simp only [lift, Cocycle.cochain_ofHom_homOf_eq_coe, liftCocycle_coe] @[reassoc (attr := simp)] lemma lift_f_fst_v (p q : ℤ) (hpq : p + 1 = q) : (lift φ α β eq).f p ≫ (fst φ).1.v p q hpq = α.1.v p q hpq := by simp [lift] lemma lift_fst : (Cochain.ofHom (lift φ α β eq)).comp (fst φ).1 (zero_add 1) = α.1 := by simp @[reassoc (attr := simp)]	lemma lift_f_snd_v (p q : ℤ) (hpq : p + 0 = q) : (lift φ α β eq).f p ≫ (snd φ).v p q hpq = β.v p q hpq := by obtain rfl : q = p := by omega simp [lift]	Mathlib/Algebra/Homology/HomotopyCategory/MappingCone.lean	492	495
/- Copyright (c) 2021 Riccardo Brasca. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Riccardo Brasca -/ import Mathlib.RingTheory.IntegralClosure.IntegrallyClosed import Mathlib.RingTheory.Trace.Basic import Mathlib.RingTheory.Norm.Basic /-! # Discriminant of a family of vectors Given an `A`-algebra `B` and `b`, an `ι`-indexed family of elements of `B`, we define the discriminant of `b` as the determinant of the matrix whose `(i j)`-th element is the trace of `b i * b j`. ## Main definition * `Algebra.discr A b` : the discriminant of `b : ι → B`. ## Main results * `Algebra.discr_zero_of_not_linearIndependent` : if `b` is not linear independent, then `Algebra.discr A b = 0`. * `Algebra.discr_of_matrix_vecMul` and `Algebra.discr_of_matrix_mulVec` : formulas relating `Algebra.discr A ι b` with `Algebra.discr A (b ᵥ* P.map (algebraMap A B))` and `Algebra.discr A (P.map (algebraMap A B) ᵥ b)`. `Algebra.discr_not_zero_of_basis` : over a field, if `b` is a basis, then `Algebra.discr K b ≠ 0`. * `Algebra.discr_eq_det_embeddingsMatrixReindex_pow_two` : if `L/K` is a field extension and `b : ι → L`, then `discr K b` is the square of the determinant of the matrix whose `(i, j)` coefficient is `σⱼ (b i)`, where `σⱼ : L →ₐ[K] E` is the embedding in an algebraically closed field `E` corresponding to `j : ι` via a bijection `e : ι ≃ (L →ₐ[K] E)`. * `Algebra.discr_powerBasis_eq_prod` : the discriminant of a power basis. * `Algebra.discr_isIntegral` : if `K` and `L` are fields and `IsScalarTower R K L`, if `b : ι → L` satisfies `∀ i, IsIntegral R (b i)`, then `IsIntegral R (discr K b)`. * `Algebra.discr_mul_isIntegral_mem_adjoin` : let `K` be the fraction field of an integrally closed domain `R` and let `L` be a finite separable extension of `K`. Let `B : PowerBasis K L` be such that `IsIntegral R B.gen`. Then for all, `z : L` we have `(discr K B.basis) • z ∈ adjoin R ({B.gen} : Set L)`. ## Implementation details Our definition works for any `A`-algebra `B`, but note that if `B` is not free as an `A`-module, then `trace A B = 0` by definition, so `discr A b = 0` for any `b`. -/ universe u v w z open scoped Matrix open Matrix Module Fintype Polynomial Finset IntermediateField namespace Algebra variable (A : Type u) {B : Type v} (C : Type z) {ι : Type w} [DecidableEq ι] variable [CommRing A] [CommRing B] [Algebra A B] [CommRing C] [Algebra A C] section Discr /-- Given an `A`-algebra `B` and `b`, an `ι`-indexed family of elements of `B`, we define `discr A ι b` as the determinant of `traceMatrix A ι b`. -/ -- Porting note: using `[DecidableEq ι]` instead of `by classical...` did not work in -- mathlib3. noncomputable def discr (A : Type u) {B : Type v} [CommRing A] [CommRing B] [Algebra A B] [Fintype ι] (b : ι → B) := (traceMatrix A b).det theorem discr_def [Fintype ι] (b : ι → B) : discr A b = (traceMatrix A b).det := rfl variable {A C} in /-- Mapping a family of vectors along an `AlgEquiv` preserves the discriminant. -/ theorem discr_eq_discr_of_algEquiv [Fintype ι] (b : ι → B) (f : B ≃ₐ[A] C) : Algebra.discr A b = Algebra.discr A (f ∘ b) := by rw [discr_def]; congr; ext simp_rw [traceMatrix_apply, traceForm_apply, Function.comp, ← map_mul f, trace_eq_of_algEquiv] variable {ι' : Type} [Fintype ι'] [Fintype ι] [DecidableEq ι'] section Basic @[simp] theorem discr_reindex (b : Basis ι A B) (f : ι ≃ ι') : discr A (b ∘ ⇑f.symm) = discr A b := by classical rw [← Basis.coe_reindex, discr_def, traceMatrix_reindex, det_reindex_self, ← discr_def] /-- If `b` is not linear independent, then `Algebra.discr A b = 0`. -/ theorem discr_zero_of_not_linearIndependent [IsDomain A] {b : ι → B} (hli : ¬LinearIndependent A b) : discr A b = 0 := by classical obtain ⟨g, hg, i, hi⟩ := Fintype.not_linearIndependent_iff.1 hli have : (traceMatrix A b) ᵥ g = 0 := by ext i have : ∀ j, (trace A B) (b i * b j) * g j = (trace A B) (g j • b j * b i) := by intro j simp [mul_comm] simp only [mulVec, dotProduct, traceMatrix_apply, Pi.zero_apply, traceForm_apply, fun j => this j, ← map_sum, ← sum_mul, hg, zero_mul, LinearMap.map_zero] by_contra h rw [discr_def] at h simp [Matrix.eq_zero_of_mulVec_eq_zero h this] at hi variable {A} /-- Relation between `Algebra.discr A ι b` and `Algebra.discr A (b ᵥ* P.map (algebraMap A B))`. -/ theorem discr_of_matrix_vecMul (b : ι → B) (P : Matrix ι ι A) : discr A (b ᵥ* P.map (algebraMap A B)) = P.det ^ 2 * discr A b := by rw [discr_def, traceMatrix_of_matrix_vecMul, det_mul, det_mul, det_transpose, mul_comm, ← mul_assoc, discr_def, pow_two] /-- Relation between `Algebra.discr A ι b` and `Algebra.discr A ((P.map (algebraMap A B)) ᵥ b)`. -/ theorem discr_of_matrix_mulVec (b : ι → B) (P : Matrix ι ι A) : discr A (P.map (algebraMap A B) ᵥ b) = P.det ^ 2 * discr A b := by rw [discr_def, traceMatrix_of_matrix_mulVec, det_mul, det_mul, det_transpose, mul_comm, ← mul_assoc, discr_def, pow_two] end Basic section Field variable (K : Type u) {L : Type v} (E : Type z) [Field K] [Field L] [Field E] variable [Algebra K L] [Algebra K E] variable [Module.Finite K L] [IsAlgClosed E] /-- If `b` is a basis of a finite separable field extension `L/K`, then `Algebra.discr K b ≠ 0`. -/ theorem discr_not_zero_of_basis [Algebra.IsSeparable K L] (b : Basis ι K L) : discr K b ≠ 0 := by rw [discr_def, traceMatrix_of_basis, ← LinearMap.BilinForm.nondegenerate_iff_det_ne_zero] exact traceForm_nondegenerate _ _ /-- If `b` is a basis of a finite separable field extension `L/K`, then `Algebra.discr K b` is a unit. -/ theorem discr_isUnit_of_basis [Algebra.IsSeparable K L] (b : Basis ι K L) : IsUnit (discr K b) := IsUnit.mk0 _ (discr_not_zero_of_basis _ _) variable (b : ι → L) (pb : PowerBasis K L) /-- If `L/K` is a field extension and `b : ι → L`, then `discr K b` is the square of the determinant of the matrix whose `(i, j)` coefficient is `σⱼ (b i)`, where `σⱼ : L →ₐ[K] E` is the embedding in an algebraically closed field `E` corresponding to `j : ι` via a bijection `e : ι ≃ (L →ₐ[K] E)`. -/ theorem discr_eq_det_embeddingsMatrixReindex_pow_two [Algebra.IsSeparable K L] (e : ι ≃ (L →ₐ[K] E)) : algebraMap K E (discr K b) = (embeddingsMatrixReindex K E b e).det ^ 2 := by rw [discr_def, RingHom.map_det, RingHom.mapMatrix_apply, traceMatrix_eq_embeddingsMatrixReindex_mul_trans, det_mul, det_transpose, pow_two] /-- The discriminant of a power basis. -/ theorem discr_powerBasis_eq_prod (e : Fin pb.dim ≃ (L →ₐ[K] E)) [Algebra.IsSeparable K L] : algebraMap K E (discr K pb.basis) = ∏ i : Fin pb.dim, ∏ j ∈ Ioi i, (e j pb.gen - e i pb.gen) ^ 2 := by rw [discr_eq_det_embeddingsMatrixReindex_pow_two K E pb.basis e,	embeddingsMatrixReindex_eq_vandermonde, det_transpose, det_vandermonde, ← prod_pow] congr; ext i rw [← prod_pow]	Mathlib/RingTheory/Discriminant.lean	154	157
/- Copyright (c) 2022 Riccardo Brasca. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Riccardo Brasca -/ import Mathlib.RingTheory.Polynomial.Eisenstein.Criterion import Mathlib.RingTheory.Polynomial.ScaleRoots /-! # Eisenstein polynomials Given an ideal `𝓟` of a commutative semiring `R`, we say that a polynomial `f : R[X]` is Eisenstein at `𝓟` if `f.leadingCoeff ∉ 𝓟`, `∀ n, n < f.natDegree → f.coeff n ∈ 𝓟` and `f.coeff 0 ∉ 𝓟 ^ 2`. In this file we gather miscellaneous results about Eisenstein polynomials. ## Main definitions * `Polynomial.IsEisensteinAt f 𝓟`: the property of being Eisenstein at `𝓟`. ## Main results * `Polynomial.IsEisensteinAt.irreducible`: if a primitive `f` satisfies `f.IsEisensteinAt 𝓟`, where `𝓟.IsPrime`, then `f` is irreducible. ## Implementation details We also define a notion `IsWeaklyEisensteinAt` requiring only that `∀ n < f.natDegree → f.coeff n ∈ 𝓟`. This makes certain results slightly more general and it is useful since it is sometimes better behaved (for example it is stable under `Polynomial.map`). -/ universe u v w z variable {R : Type u} open Ideal Algebra Finset open Polynomial namespace Polynomial /-- Given an ideal `𝓟` of a commutative semiring `R`, we say that a polynomial `f : R[X]` is weakly Eisenstein at `𝓟` if `∀ n, n < f.natDegree → f.coeff n ∈ 𝓟`. -/ @[mk_iff] structure IsWeaklyEisensteinAt [CommSemiring R] (f : R[X]) (𝓟 : Ideal R) : Prop where mem : ∀ {n}, n < f.natDegree → f.coeff n ∈ 𝓟 /-- Given an ideal `𝓟` of a commutative semiring `R`, we say that a polynomial `f : R[X]` is Eisenstein at `𝓟` if `f.leadingCoeff ∉ 𝓟`, `∀ n, n < f.natDegree → f.coeff n ∈ 𝓟` and `f.coeff 0 ∉ 𝓟 ^ 2`. -/ @[mk_iff] structure IsEisensteinAt [CommSemiring R] (f : R[X]) (𝓟 : Ideal R) : Prop where leading : f.leadingCoeff ∉ 𝓟 mem : ∀ {n}, n < f.natDegree → f.coeff n ∈ 𝓟 not_mem : f.coeff 0 ∉ 𝓟 ^ 2 namespace IsWeaklyEisensteinAt section CommSemiring variable [CommSemiring R] {𝓟 : Ideal R} {f : R[X]} theorem map (hf : f.IsWeaklyEisensteinAt 𝓟) {A : Type v} [CommSemiring A] (φ : R →+* A) : (f.map φ).IsWeaklyEisensteinAt (𝓟.map φ) := by refine (isWeaklyEisensteinAt_iff _ _).2 fun hn => ?_ rw [coeff_map] exact mem_map_of_mem _ (hf.mem (lt_of_lt_of_le hn natDegree_map_le)) end CommSemiring section CommRing variable [CommRing R] {𝓟 : Ideal R} {f : R[X]} variable {S : Type v} [CommRing S] [Algebra R S] section Principal variable {p : R} theorem exists_mem_adjoin_mul_eq_pow_natDegree {x : S} (hx : aeval x f = 0) (hmo : f.Monic) (hf : f.IsWeaklyEisensteinAt (Submodule.span R {p})) : ∃ y ∈ adjoin R ({x} : Set S), (algebraMap R S) p * y = x ^ (f.map (algebraMap R S)).natDegree := by rw [aeval_def, Polynomial.eval₂_eq_eval_map, eval_eq_sum_range, range_add_one, sum_insert not_mem_range_self, sum_range, (hmo.map (algebraMap R S)).coeff_natDegree, one_mul] at hx replace hx := eq_neg_of_add_eq_zero_left hx have : ∀ n < f.natDegree, p ∣ f.coeff n := by intro n hn exact mem_span_singleton.1 (by simpa using hf.mem hn) choose! φ hφ using this conv_rhs at hx => congr congr · skip ext i rw [coeff_map, hφ i.1 (lt_of_lt_of_le i.2 natDegree_map_le), RingHom.map_mul, mul_assoc] rw [hx, ← mul_sum, neg_eq_neg_one_mul, ← mul_assoc (-1 : S), mul_comm (-1 : S), mul_assoc] refine ⟨-1 * ∑ i : Fin (f.map (algebraMap R S)).natDegree, (algebraMap R S) (φ i.1) * x ^ i.1, ?_, rfl⟩ exact Subalgebra.mul_mem _ (Subalgebra.neg_mem _ (Subalgebra.one_mem _)) (Subalgebra.sum_mem _ fun i _ => Subalgebra.mul_mem _ (Subalgebra.algebraMap_mem _ _) (Subalgebra.pow_mem _ (subset_adjoin (Set.mem_singleton x)) _)) theorem exists_mem_adjoin_mul_eq_pow_natDegree_le {x : S} (hx : aeval x f = 0) (hmo : f.Monic) (hf : f.IsWeaklyEisensteinAt (Submodule.span R {p})) : ∀ i, (f.map (algebraMap R S)).natDegree ≤ i → ∃ y ∈ adjoin R ({x} : Set S), (algebraMap R S) p * y = x ^ i := by intro i hi obtain ⟨k, hk⟩ := exists_add_of_le hi rw [hk, pow_add] obtain ⟨y, hy, H⟩ := exists_mem_adjoin_mul_eq_pow_natDegree hx hmo hf refine ⟨y * x ^ k, ?_, ?_⟩ · exact Subalgebra.mul_mem _ hy (Subalgebra.pow_mem _ (subset_adjoin (Set.mem_singleton x)) _) · rw [← mul_assoc _ y, H] end Principal -- Porting note: `Ideal.neg_mem_iff` was `neg_mem_iff` on line 142 but Lean was not able to find -- NegMemClass theorem pow_natDegree_le_of_root_of_monic_mem (hf : f.IsWeaklyEisensteinAt 𝓟) {x : R} (hroot : IsRoot f x) (hmo : f.Monic) : ∀ i, f.natDegree ≤ i → x ^ i ∈ 𝓟 := by intro i hi obtain ⟨k, hk⟩ := exists_add_of_le hi rw [hk, pow_add] suffices x ^ f.natDegree ∈ 𝓟 by exact mul_mem_right (x ^ k) 𝓟 this rw [IsRoot.def, eval_eq_sum_range, Finset.range_add_one, Finset.sum_insert Finset.not_mem_range_self, Finset.sum_range, hmo.coeff_natDegree, one_mul] at * rw [eq_neg_of_add_eq_zero_left hroot, Ideal.neg_mem_iff] exact Submodule.sum_mem _ fun i _ => mul_mem_right _ _ (hf.mem (Fin.is_lt i)) theorem pow_natDegree_le_of_aeval_zero_of_monic_mem_map (hf : f.IsWeaklyEisensteinAt 𝓟) {x : S} (hx : aeval x f = 0) (hmo : f.Monic) : ∀ i, (f.map (algebraMap R S)).natDegree ≤ i → x ^ i ∈ 𝓟.map (algebraMap R S) := by suffices x ^ (f.map (algebraMap R S)).natDegree ∈ 𝓟.map (algebraMap R S) by intro i hi obtain ⟨k, hk⟩ := exists_add_of_le hi rw [hk, pow_add] exact mul_mem_right _ _ this rw [aeval_def, eval₂_eq_eval_map, ← IsRoot.def] at hx exact pow_natDegree_le_of_root_of_monic_mem (hf.map _) hx (hmo.map _) _ rfl.le end CommRing end IsWeaklyEisensteinAt section ScaleRoots variable {A : Type} [CommRing R] [CommRing A] theorem scaleRoots.isWeaklyEisensteinAt (p : R[X]) {x : R} {P : Ideal R} (hP : x ∈ P) : (scaleRoots p x).IsWeaklyEisensteinAt P := by refine ⟨fun i => ?_⟩ rw [coeff_scaleRoots] rw [natDegree_scaleRoots, ← tsub_pos_iff_lt] at i exact Ideal.mul_mem_left _ _ (Ideal.pow_mem_of_mem P hP _ i) theorem dvd_pow_natDegree_of_eval₂_eq_zero {f : R →+ A} (hf : Function.Injective f) {p : R[X]} (hp : p.Monic) (x y : R) (z : A) (h : p.eval₂ f z = 0) (hz : f x * z = f y) : x ∣ y ^ p.natDegree := by rw [← natDegree_scaleRoots p x, ← Ideal.mem_span_singleton] refine (scaleRoots.isWeaklyEisensteinAt _ (Ideal.mem_span_singleton.mpr <\| dvd_refl x)).pow_natDegree_le_of_root_of_monic_mem ?_ ((monic_scaleRoots_iff x).mpr hp) _ le_rfl rw [injective_iff_map_eq_zero'] at hf have : eval₂ f _ (p.scaleRoots x) = 0 := scaleRoots_eval₂_eq_zero f h rwa [hz, Polynomial.eval₂_at_apply, hf] at this theorem dvd_pow_natDegree_of_aeval_eq_zero [Algebra R A] [Nontrivial A] [NoZeroSMulDivisors R A] {p : R[X]} (hp : p.Monic) (x y : R) (z : A) (h : Polynomial.aeval z p = 0) (hz : z * algebraMap R A x = algebraMap R A y) : x ∣ y ^ p.natDegree := dvd_pow_natDegree_of_eval₂_eq_zero (FaithfulSMul.algebraMap_injective R A) hp x y z h ((mul_comm _ _).trans hz) end ScaleRoots namespace IsEisensteinAt section CommSemiring variable [CommSemiring R] {𝓟 : Ideal R} {f : R[X]} theorem _root_.Polynomial.Monic.leadingCoeff_not_mem (hf : f.Monic) (h : 𝓟 ≠ ⊤) : ¬f.leadingCoeff ∈ 𝓟 := hf.leadingCoeff.symm ▸ (Ideal.ne_top_iff_one _).1 h theorem _root_.Polynomial.Monic.isEisensteinAt_of_mem_of_not_mem (hf : f.Monic) (h : 𝓟 ≠ ⊤) (hmem : ∀ {n}, n < f.natDegree → f.coeff n ∈ 𝓟) (hnot_mem : f.coeff 0 ∉ 𝓟 ^ 2) : f.IsEisensteinAt 𝓟 := { leading := Polynomial.Monic.leadingCoeff_not_mem hf h mem := fun hn => hmem hn not_mem := hnot_mem } theorem isWeaklyEisensteinAt (hf : f.IsEisensteinAt 𝓟) : IsWeaklyEisensteinAt f 𝓟 := ⟨fun h => hf.mem h⟩ theorem coeff_mem (hf : f.IsEisensteinAt 𝓟) {n : ℕ} (hn : n ≠ f.natDegree) : f.coeff n ∈ 𝓟 := by rcases ne_iff_lt_or_gt.1 hn with h₁ \| h₂ · exact hf.mem h₁ · rw [coeff_eq_zero_of_natDegree_lt h₂] exact Ideal.zero_mem _ end CommSemiring section IsDomain variable [CommRing R] [IsDomain R] {𝓟 : Ideal R} {f : R[X]} /-- If a primitive `f` satisfies `f.IsEisensteinAt 𝓟`, where `𝓟.IsPrime`, then `f` is irreducible. -/	theorem irreducible (hf : f.IsEisensteinAt 𝓟) (hprime : 𝓟.IsPrime) (hu : f.IsPrimitive) (hfd0 : 0 < f.natDegree) : Irreducible f := irreducible_of_eisenstein_criterion hprime hf.leading (fun _ hn => hf.mem (coe_lt_degree.1 hn)) (natDegree_pos_iff_degree_pos.1 hfd0) hf.not_mem hu	Mathlib/RingTheory/Polynomial/Eisenstein/Basic.lean	213	217
/- Copyright (c) 2018 Chris Hughes. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Chris Hughes, Abhimanyu Pallavi Sudhir, Jean Lo, Calle Sönne, Sébastien Gouëzel, Rémy Degenne, David Loeffler -/ import Mathlib.Analysis.SpecialFunctions.Pow.Complex import Qq /-! # Power function on `ℝ` We construct the power functions `x ^ y`, where `x` and `y` are real numbers. -/ noncomputable section open Real ComplexConjugate Finset Set /- ## Definitions -/ namespace Real variable {x y z : ℝ} /-- The real power function `x ^ y`, defined as the real part of the complex power function. For `x > 0`, it is equal to `exp (y log x)`. For `x = 0`, one sets `0 ^ 0=1` and `0 ^ y=0` for `y ≠ 0`. For `x < 0`, the definition is somewhat arbitrary as it depends on the choice of a complex determination of the logarithm. With our conventions, it is equal to `exp (y log x) cos (π y)`. -/ noncomputable def rpow (x y : ℝ) := ((x : ℂ) ^ (y : ℂ)).re noncomputable instance : Pow ℝ ℝ := ⟨rpow⟩ @[simp] theorem rpow_eq_pow (x y : ℝ) : rpow x y = x ^ y := rfl theorem rpow_def (x y : ℝ) : x ^ y = ((x : ℂ) ^ (y : ℂ)).re := rfl theorem rpow_def_of_nonneg {x : ℝ} (hx : 0 ≤ x) (y : ℝ) : x ^ y = if x = 0 then if y = 0 then 1 else 0 else exp (log x * y) := by simp only [rpow_def, Complex.cpow_def]; split_ifs <;> simp_all [(Complex.ofReal_log hx).symm, -Complex.ofReal_mul, (Complex.ofReal_mul _ _).symm, Complex.exp_ofReal_re, Complex.ofReal_eq_zero] theorem rpow_def_of_pos {x : ℝ} (hx : 0 < x) (y : ℝ) : x ^ y = exp (log x * y) := by rw [rpow_def_of_nonneg (le_of_lt hx), if_neg (ne_of_gt hx)] theorem exp_mul (x y : ℝ) : exp (x * y) = exp x ^ y := by rw [rpow_def_of_pos (exp_pos _), log_exp] @[simp, norm_cast] theorem rpow_intCast (x : ℝ) (n : ℤ) : x ^ (n : ℝ) = x ^ n := by simp only [rpow_def, ← Complex.ofReal_zpow, Complex.cpow_intCast, Complex.ofReal_intCast, Complex.ofReal_re] @[simp, norm_cast] theorem rpow_natCast (x : ℝ) (n : ℕ) : x ^ (n : ℝ) = x ^ n := by simpa using rpow_intCast x n @[simp] theorem exp_one_rpow (x : ℝ) : exp 1 ^ x = exp x := by rw [← exp_mul, one_mul] @[simp] lemma exp_one_pow (n : ℕ) : exp 1 ^ n = exp n := by rw [← rpow_natCast, exp_one_rpow] theorem rpow_eq_zero_iff_of_nonneg (hx : 0 ≤ x) : x ^ y = 0 ↔ x = 0 ∧ y ≠ 0 := by simp only [rpow_def_of_nonneg hx] split_ifs <;> simp [, exp_ne_zero] @[simp] lemma rpow_eq_zero (hx : 0 ≤ x) (hy : y ≠ 0) : x ^ y = 0 ↔ x = 0 := by simp [rpow_eq_zero_iff_of_nonneg, ] @[simp] lemma rpow_ne_zero (hx : 0 ≤ x) (hy : y ≠ 0) : x ^ y ≠ 0 ↔ x ≠ 0 := Real.rpow_eq_zero hx hy \|>.not open Real theorem rpow_def_of_neg {x : ℝ} (hx : x < 0) (y : ℝ) : x ^ y = exp (log x * y) * cos (y * π) := by rw [rpow_def, Complex.cpow_def, if_neg] · have : Complex.log x * y = ↑(log (-x) * y) + ↑(y * π) * Complex.I := by simp only [Complex.log, Complex.norm_real, norm_eq_abs, abs_of_neg hx, log_neg_eq_log, Complex.arg_ofReal_of_neg hx, Complex.ofReal_mul] ring rw [this, Complex.exp_add_mul_I, ← Complex.ofReal_exp, ← Complex.ofReal_cos, ← Complex.ofReal_sin, mul_add, ← Complex.ofReal_mul, ← mul_assoc, ← Complex.ofReal_mul, Complex.add_re, Complex.ofReal_re, Complex.mul_re, Complex.I_re, Complex.ofReal_im, Real.log_neg_eq_log] ring · rw [Complex.ofReal_eq_zero] exact ne_of_lt hx theorem rpow_def_of_nonpos {x : ℝ} (hx : x ≤ 0) (y : ℝ) : x ^ y = if x = 0 then if y = 0 then 1 else 0 else exp (log x * y) * cos (y * π) := by split_ifs with h <;> simp [rpow_def, ]; exact rpow_def_of_neg (lt_of_le_of_ne hx h) _ @[bound] theorem rpow_pos_of_pos {x : ℝ} (hx : 0 < x) (y : ℝ) : 0 < x ^ y := by rw [rpow_def_of_pos hx]; apply exp_pos @[simp] theorem rpow_zero (x : ℝ) : x ^ (0 : ℝ) = 1 := by simp [rpow_def] theorem rpow_zero_pos (x : ℝ) : 0 < x ^ (0 : ℝ) := by simp @[simp] theorem zero_rpow {x : ℝ} (h : x ≠ 0) : (0 : ℝ) ^ x = 0 := by simp [rpow_def, ] theorem zero_rpow_eq_iff {x : ℝ} {a : ℝ} : 0 ^ x = a ↔ x ≠ 0 ∧ a = 0 ∨ x = 0 ∧ a = 1 := by constructor · intro hyp simp only [rpow_def, Complex.ofReal_zero] at hyp by_cases h : x = 0 · subst h simp only [Complex.one_re, Complex.ofReal_zero, Complex.cpow_zero] at hyp exact Or.inr ⟨rfl, hyp.symm⟩ · rw [Complex.zero_cpow (Complex.ofReal_ne_zero.mpr h)] at hyp exact Or.inl ⟨h, hyp.symm⟩ · rintro (⟨h, rfl⟩ \| ⟨rfl, rfl⟩) · exact zero_rpow h · exact rpow_zero _ theorem eq_zero_rpow_iff {x : ℝ} {a : ℝ} : a = 0 ^ x ↔ x ≠ 0 ∧ a = 0 ∨ x = 0 ∧ a = 1 := by rw [← zero_rpow_eq_iff, eq_comm] @[simp] theorem rpow_one (x : ℝ) : x ^ (1 : ℝ) = x := by simp [rpow_def] @[simp] theorem one_rpow (x : ℝ) : (1 : ℝ) ^ x = 1 := by simp [rpow_def] theorem zero_rpow_le_one (x : ℝ) : (0 : ℝ) ^ x ≤ 1 := by by_cases h : x = 0 <;> simp [h, zero_le_one] theorem zero_rpow_nonneg (x : ℝ) : 0 ≤ (0 : ℝ) ^ x := by by_cases h : x = 0 <;> simp [h, zero_le_one] @[bound] theorem rpow_nonneg {x : ℝ} (hx : 0 ≤ x) (y : ℝ) : 0 ≤ x ^ y := by rw [rpow_def_of_nonneg hx]; split_ifs <;> simp only [zero_le_one, le_refl, le_of_lt (exp_pos _)] theorem abs_rpow_of_nonneg {x y : ℝ} (hx_nonneg : 0 ≤ x) : \|x ^ y\| = \|x\| ^ y := by have h_rpow_nonneg : 0 ≤ x ^ y := Real.rpow_nonneg hx_nonneg _ rw [abs_eq_self.mpr hx_nonneg, abs_eq_self.mpr h_rpow_nonneg] @[bound] theorem abs_rpow_le_abs_rpow (x y : ℝ) : \|x ^ y\| ≤ \|x\| ^ y := by rcases le_or_lt 0 x with hx \| hx · rw [abs_rpow_of_nonneg hx] · rw [abs_of_neg hx, rpow_def_of_neg hx, rpow_def_of_pos (neg_pos.2 hx), log_neg_eq_log, abs_mul, abs_of_pos (exp_pos _)] exact mul_le_of_le_one_right (exp_pos _).le (abs_cos_le_one _) theorem abs_rpow_le_exp_log_mul (x y : ℝ) : \|x ^ y\| ≤ exp (log x * y) := by refine (abs_rpow_le_abs_rpow x y).trans ?_ by_cases hx : x = 0 · by_cases hy : y = 0 <;> simp [hx, hy, zero_le_one] · rw [rpow_def_of_pos (abs_pos.2 hx), log_abs] lemma rpow_inv_log (hx₀ : 0 < x) (hx₁ : x ≠ 1) : x ^ (log x)⁻¹ = exp 1 := by rw [rpow_def_of_pos hx₀, mul_inv_cancel₀] exact log_ne_zero.2 ⟨hx₀.ne', hx₁, (hx₀.trans' <\| by norm_num).ne'⟩ /-- See `Real.rpow_inv_log` for the equality when `x ≠ 1` is strictly positive. -/ lemma rpow_inv_log_le_exp_one : x ^ (log x)⁻¹ ≤ exp 1 := by calc _ ≤ \|x ^ (log x)⁻¹\| := le_abs_self _ _ ≤ \|x\| ^ (log x)⁻¹ := abs_rpow_le_abs_rpow .. rw [← log_abs] obtain hx \| hx := (abs_nonneg x).eq_or_gt · simp [hx] · rw [rpow_def_of_pos hx] gcongr exact mul_inv_le_one theorem norm_rpow_of_nonneg {x y : ℝ} (hx_nonneg : 0 ≤ x) : ‖x ^ y‖ = ‖x‖ ^ y := by simp_rw [Real.norm_eq_abs] exact abs_rpow_of_nonneg hx_nonneg variable {w x y z : ℝ} theorem rpow_add (hx : 0 < x) (y z : ℝ) : x ^ (y + z) = x ^ y * x ^ z := by simp only [rpow_def_of_pos hx, mul_add, exp_add] theorem rpow_add' (hx : 0 ≤ x) (h : y + z ≠ 0) : x ^ (y + z) = x ^ y * x ^ z := by rcases hx.eq_or_lt with (rfl \| pos) · rw [zero_rpow h, zero_eq_mul] have : y ≠ 0 ∨ z ≠ 0 := not_and_or.1 fun ⟨hy, hz⟩ => h <\| hy.symm ▸ hz.symm ▸ zero_add 0 exact this.imp zero_rpow zero_rpow · exact rpow_add pos _ _ /-- Variant of `Real.rpow_add'` that avoids having to prove `y + z = w` twice. -/ lemma rpow_of_add_eq (hx : 0 ≤ x) (hw : w ≠ 0) (h : y + z = w) : x ^ w = x ^ y * x ^ z := by rw [← h, rpow_add' hx]; rwa [h] theorem rpow_add_of_nonneg (hx : 0 ≤ x) (hy : 0 ≤ y) (hz : 0 ≤ z) : x ^ (y + z) = x ^ y * x ^ z := by rcases hy.eq_or_lt with (rfl \| hy) · rw [zero_add, rpow_zero, one_mul] exact rpow_add' hx (ne_of_gt <\| add_pos_of_pos_of_nonneg hy hz) /-- For `0 ≤ x`, the only problematic case in the equality `x ^ y * x ^ z = x ^ (y + z)` is for `x = 0` and `y + z = 0`, where the right hand side is `1` while the left hand side can vanish. The inequality is always true, though, and given in this lemma. -/ theorem le_rpow_add {x : ℝ} (hx : 0 ≤ x) (y z : ℝ) : x ^ y * x ^ z ≤ x ^ (y + z) := by rcases le_iff_eq_or_lt.1 hx with (H \| pos) · by_cases h : y + z = 0 · simp only [H.symm, h, rpow_zero] calc (0 : ℝ) ^ y * 0 ^ z ≤ 1 * 1 := mul_le_mul (zero_rpow_le_one y) (zero_rpow_le_one z) (zero_rpow_nonneg z) zero_le_one _ = 1 := by simp · simp [rpow_add', ← H, h] · simp [rpow_add pos] theorem rpow_sum_of_pos {ι : Type} {a : ℝ} (ha : 0 < a) (f : ι → ℝ) (s : Finset ι) : (a ^ ∑ x ∈ s, f x) = ∏ x ∈ s, a ^ f x := map_sum (⟨⟨fun (x : ℝ) => (a ^ x : ℝ), rpow_zero a⟩, rpow_add ha⟩ : ℝ →+ (Additive ℝ)) f s theorem rpow_sum_of_nonneg {ι : Type} {a : ℝ} (ha : 0 ≤ a) {s : Finset ι} {f : ι → ℝ} (h : ∀ x ∈ s, 0 ≤ f x) : (a ^ ∑ x ∈ s, f x) = ∏ x ∈ s, a ^ f x := by induction' s using Finset.cons_induction with i s hi ihs · rw [sum_empty, Finset.prod_empty, rpow_zero] · rw [forall_mem_cons] at h rw [sum_cons, prod_cons, ← ihs h.2, rpow_add_of_nonneg ha h.1 (sum_nonneg h.2)] theorem rpow_neg {x : ℝ} (hx : 0 ≤ x) (y : ℝ) : x ^ (-y) = (x ^ y)⁻¹ := by simp only [rpow_def_of_nonneg hx]; split_ifs <;> simp_all [exp_neg] theorem rpow_sub {x : ℝ} (hx : 0 < x) (y z : ℝ) : x ^ (y - z) = x ^ y / x ^ z := by simp only [sub_eq_add_neg, rpow_add hx, rpow_neg (le_of_lt hx), div_eq_mul_inv] theorem rpow_sub' {x : ℝ} (hx : 0 ≤ x) {y z : ℝ} (h : y - z ≠ 0) : x ^ (y - z) = x ^ y / x ^ z := by simp only [sub_eq_add_neg] at h ⊢ simp only [rpow_add' hx h, rpow_neg hx, div_eq_mul_inv] protected theorem _root_.HasCompactSupport.rpow_const {α : Type} [TopologicalSpace α] {f : α → ℝ} (hf : HasCompactSupport f) {r : ℝ} (hr : r ≠ 0) : HasCompactSupport (fun x ↦ f x ^ r) := hf.comp_left (g := (· ^ r)) (Real.zero_rpow hr) end Real /-! ## Comparing real and complex powers -/ namespace Complex theorem ofReal_cpow {x : ℝ} (hx : 0 ≤ x) (y : ℝ) : ((x ^ y : ℝ) : ℂ) = (x : ℂ) ^ (y : ℂ) := by simp only [Real.rpow_def_of_nonneg hx, Complex.cpow_def, ofReal_eq_zero]; split_ifs <;> simp [Complex.ofReal_log hx] theorem ofReal_cpow_of_nonpos {x : ℝ} (hx : x ≤ 0) (y : ℂ) : (x : ℂ) ^ y = (-x : ℂ) ^ y exp (π * I * y) := by rcases hx.eq_or_lt with (rfl \| hlt) · rcases eq_or_ne y 0 with (rfl \| hy) <;> simp [] have hne : (x : ℂ) ≠ 0 := ofReal_ne_zero.mpr hlt.ne rw [cpow_def_of_ne_zero hne, cpow_def_of_ne_zero (neg_ne_zero.2 hne), ← exp_add, ← add_mul, log, log, norm_neg, arg_ofReal_of_neg hlt, ← ofReal_neg, arg_ofReal_of_nonneg (neg_nonneg.2 hx), ofReal_zero, zero_mul, add_zero] lemma cpow_ofReal (x : ℂ) (y : ℝ) : x ^ (y : ℂ) = ↑(‖x‖ ^ y) (Real.cos (arg x * y) + Real.sin (arg x * y) * I) := by rcases eq_or_ne x 0 with rfl \| hx · simp [ofReal_cpow le_rfl] · rw [cpow_def_of_ne_zero hx, exp_eq_exp_re_mul_sin_add_cos, mul_comm (log x)] norm_cast rw [re_ofReal_mul, im_ofReal_mul, log_re, log_im, mul_comm y, mul_comm y, Real.exp_mul, Real.exp_log] rwa [norm_pos_iff] lemma cpow_ofReal_re (x : ℂ) (y : ℝ) : (x ^ (y : ℂ)).re = ‖x‖ ^ y * Real.cos (arg x * y) := by rw [cpow_ofReal]; generalize arg x * y = z; simp [Real.cos] lemma cpow_ofReal_im (x : ℂ) (y : ℝ) : (x ^ (y : ℂ)).im = ‖x‖ ^ y * Real.sin (arg x * y) := by rw [cpow_ofReal]; generalize arg x * y = z; simp [Real.sin] theorem norm_cpow_of_ne_zero {z : ℂ} (hz : z ≠ 0) (w : ℂ) : ‖z ^ w‖ = ‖z‖ ^ w.re / Real.exp (arg z * im w) := by rw [cpow_def_of_ne_zero hz, norm_exp, mul_re, log_re, log_im, Real.exp_sub, Real.rpow_def_of_pos (norm_pos_iff.mpr hz)] theorem norm_cpow_of_imp {z w : ℂ} (h : z = 0 → w.re = 0 → w = 0) : ‖z ^ w‖ = ‖z‖ ^ w.re / Real.exp (arg z * im w) := by rcases ne_or_eq z 0 with (hz \| rfl) <;> [exact norm_cpow_of_ne_zero hz w; rw [norm_zero]] rcases eq_or_ne w.re 0 with hw \| hw · simp [hw, h rfl hw] · rw [Real.zero_rpow hw, zero_div, zero_cpow, norm_zero] exact ne_of_apply_ne re hw theorem norm_cpow_le (z w : ℂ) : ‖z ^ w‖ ≤ ‖z‖ ^ w.re / Real.exp (arg z * im w) := by by_cases h : z = 0 → w.re = 0 → w = 0 · exact (norm_cpow_of_imp h).le · push_neg at h simp [h] @[simp] theorem norm_cpow_real (x : ℂ) (y : ℝ) : ‖x ^ (y : ℂ)‖ = ‖x‖ ^ y := by rw [norm_cpow_of_imp] <;> simp @[simp] theorem norm_cpow_inv_nat (x : ℂ) (n : ℕ) : ‖x ^ (n⁻¹ : ℂ)‖ = ‖x‖ ^ (n⁻¹ : ℝ) := by rw [← norm_cpow_real]; simp theorem norm_cpow_eq_rpow_re_of_pos {x : ℝ} (hx : 0 < x) (y : ℂ) : ‖(x : ℂ) ^ y‖ = x ^ y.re := by rw [norm_cpow_of_ne_zero (ofReal_ne_zero.mpr hx.ne'), arg_ofReal_of_nonneg hx.le, zero_mul, Real.exp_zero, div_one, Complex.norm_of_nonneg hx.le] theorem norm_cpow_eq_rpow_re_of_nonneg {x : ℝ} (hx : 0 ≤ x) {y : ℂ} (hy : re y ≠ 0) : ‖(x : ℂ) ^ y‖ = x ^ re y := by rw [norm_cpow_of_imp] <;> simp [*, arg_ofReal_of_nonneg, abs_of_nonneg] @[deprecated (since := "2025-02-17")] alias abs_cpow_of_ne_zero := norm_cpow_of_ne_zero @[deprecated (since := "2025-02-17")] alias abs_cpow_of_imp := norm_cpow_of_imp @[deprecated (since := "2025-02-17")] alias abs_cpow_le := norm_cpow_le @[deprecated (since := "2025-02-17")] alias abs_cpow_real := norm_cpow_real @[deprecated (since := "2025-02-17")] alias abs_cpow_inv_nat := norm_cpow_inv_nat @[deprecated (since := "2025-02-17")] alias abs_cpow_eq_rpow_re_of_pos := norm_cpow_eq_rpow_re_of_pos @[deprecated (since := "2025-02-17")] alias abs_cpow_eq_rpow_re_of_nonneg := norm_cpow_eq_rpow_re_of_nonneg	open Filter in lemma norm_ofReal_cpow_eventually_eq_atTop (c : ℂ) : (fun t : ℝ ↦ ‖(t : ℂ) ^ c‖) =ᶠ[atTop] fun t ↦ t ^ c.re := by filter_upwards [eventually_gt_atTop 0] with t ht	Mathlib/Analysis/SpecialFunctions/Pow/Real.lean	325	329
/- Copyright (c) 2021 Damiano Testa. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Damiano Testa -/ import Mathlib.Algebra.Group.Commute.Defs import Mathlib.Algebra.Group.Units.Defs import Mathlib.Algebra.GroupWithZero.Defs import Mathlib.Algebra.Order.Monoid.Unbundled.Basic import Mathlib.Tactic.NthRewrite /-! # Regular elements We introduce left-regular, right-regular and regular elements, along with their `to_additive` analogues add-left-regular, add-right-regular and add-regular elements. By definition, a regular element in a commutative ring is a non-zero divisor. Lemma `isRegular_of_ne_zero` implies that every non-zero element of an integral domain is regular. Since it assumes that the ring is a `CancelMonoidWithZero` it applies also, for instance, to `ℕ`. The lemmas in Section `MulZeroClass` show that the `0` element is (left/right-)regular if and only if the `MulZeroClass` is trivial. This is useful when figuring out stopping conditions for regular sequences: if `0` is ever an element of a regular sequence, then we can extend the sequence by adding one further `0`. The final goal is to develop part of the API to prove, eventually, results about non-zero-divisors. -/ variable {R : Type} section Mul variable [Mul R] /-- A left-regular element is an element `c` such that multiplication on the left by `c` is injective. -/ @[to_additive "An add-left-regular element is an element `c` such that addition on the left by `c` is injective."] def IsLeftRegular (c : R) := (c ·).Injective /-- A right-regular element is an element `c` such that multiplication on the right by `c` is injective. -/ @[to_additive "An add-right-regular element is an element `c` such that addition on the right by `c` is injective."] def IsRightRegular (c : R) := (· * c).Injective /-- An add-regular element is an element `c` such that addition by `c` both on the left and on the right is injective. -/ structure IsAddRegular {R : Type} [Add R] (c : R) : Prop where /-- An add-regular element `c` is left-regular -/ left : IsAddLeftRegular c -- Porting note: It seems like to_additive is misbehaving /-- An add-regular element `c` is right-regular -/ right : IsAddRightRegular c /-- A regular element is an element `c` such that multiplication by `c` both on the left and on the right is injective. -/ structure IsRegular (c : R) : Prop where /-- A regular element `c` is left-regular -/ left : IsLeftRegular c /-- A regular element `c` is right-regular -/ right : IsRightRegular c attribute [simp] IsRegular.left IsRegular.right attribute [to_additive] IsRegular @[to_additive] theorem isRegular_iff {c : R} : IsRegular c ↔ IsLeftRegular c ∧ IsRightRegular c := ⟨fun ⟨h1, h2⟩ => ⟨h1, h2⟩, fun ⟨h1, h2⟩ => ⟨h1, h2⟩⟩ @[to_additive] protected theorem MulLECancellable.isLeftRegular [PartialOrder R] {a : R} (ha : MulLECancellable a) : IsLeftRegular a := ha.Injective theorem IsLeftRegular.right_of_commute {a : R} (ca : ∀ b, Commute a b) (h : IsLeftRegular a) : IsRightRegular a := fun x y xy => h <\| (ca x).trans <\| xy.trans <\| (ca y).symm theorem IsRightRegular.left_of_commute {a : R} (ca : ∀ b, Commute a b) (h : IsRightRegular a) : IsLeftRegular a := by simp_rw [@Commute.symm_iff R _ a] at ca exact fun x y xy => h <\| (ca x).trans <\| xy.trans <\| (ca y).symm theorem Commute.isRightRegular_iff {a : R} (ca : ∀ b, Commute a b) : IsRightRegular a ↔ IsLeftRegular a := ⟨IsRightRegular.left_of_commute ca, IsLeftRegular.right_of_commute ca⟩ theorem Commute.isRegular_iff {a : R} (ca : ∀ b, Commute a b) : IsRegular a ↔ IsLeftRegular a := ⟨fun h => h.left, fun h => ⟨h, h.right_of_commute ca⟩⟩ end Mul section Semigroup variable [Semigroup R] {a b : R} /-- In a semigroup, the product of left-regular elements is left-regular. -/ @[to_additive "In an additive semigroup, the sum of add-left-regular elements is add-left.regular."] theorem IsLeftRegular.mul (lra : IsLeftRegular a) (lrb : IsLeftRegular b) : IsLeftRegular (a b) := show Function.Injective (((a * b) * ·)) from comp_mul_left a b ▸ lra.comp lrb /-- In a semigroup, the product of right-regular elements is right-regular. -/ @[to_additive "In an additive semigroup, the sum of add-right-regular elements is add-right-regular."] theorem IsRightRegular.mul (rra : IsRightRegular a) (rrb : IsRightRegular b) : IsRightRegular (a * b) := show Function.Injective (· * (a * b)) from comp_mul_right b a ▸ rrb.comp rra /-- In a semigroup, the product of regular elements is regular. -/ @[to_additive "In an additive semigroup, the sum of add-regular elements is add-regular."] theorem IsRegular.mul (rra : IsRegular a) (rrb : IsRegular b) : IsRegular (a * b) := ⟨rra.left.mul rrb.left, rra.right.mul rrb.right⟩ /-- If an element `b` becomes left-regular after multiplying it on the left by a left-regular element, then `b` is left-regular. -/ @[to_additive "If an element `b` becomes add-left-regular after adding to it on the left an add-left-regular element, then `b` is add-left-regular."] theorem IsLeftRegular.of_mul (ab : IsLeftRegular (a * b)) : IsLeftRegular b := Function.Injective.of_comp (f := (a * ·)) (by rwa [comp_mul_left a b]) /-- An element is left-regular if and only if multiplying it on the left by a left-regular element is left-regular. -/ @[to_additive (attr := simp) "An element is add-left-regular if and only if adding to it on the left an add-left-regular element is add-left-regular."] theorem mul_isLeftRegular_iff (b : R) (ha : IsLeftRegular a) : IsLeftRegular (a * b) ↔ IsLeftRegular b := ⟨fun ab => IsLeftRegular.of_mul ab, fun ab => IsLeftRegular.mul ha ab⟩ /-- If an element `b` becomes right-regular after multiplying it on the right by a right-regular element, then `b` is right-regular. -/ @[to_additive "If an element `b` becomes add-right-regular after adding to it on the right an add-right-regular element, then `b` is add-right-regular."] theorem IsRightRegular.of_mul (ab : IsRightRegular (b * a)) : IsRightRegular b := by refine fun x y xy => ab (?_ : x * (b * a) = y * (b * a)) rw [← mul_assoc, ← mul_assoc] exact congr_arg (· * a) xy /-- An element is right-regular if and only if multiplying it on the right with a right-regular element is right-regular. -/ @[to_additive (attr := simp) "An element is add-right-regular if and only if adding it on the right to an add-right-regular element is add-right-regular."] theorem mul_isRightRegular_iff (b : R) (ha : IsRightRegular a) : IsRightRegular (b * a) ↔ IsRightRegular b := ⟨fun ab => IsRightRegular.of_mul ab, fun ab => IsRightRegular.mul ab ha⟩ /-- Two elements `a` and `b` are regular if and only if both products `a * b` and `b * a` are regular. -/ @[to_additive "Two elements `a` and `b` are add-regular if and only if both sums `a + b` and `b + a` are add-regular."] theorem isRegular_mul_and_mul_iff : IsRegular (a * b) ∧ IsRegular (b * a) ↔ IsRegular a ∧ IsRegular b := by refine ⟨?_, ?_⟩ · rintro ⟨ab, ba⟩ exact ⟨⟨IsLeftRegular.of_mul ba.left, IsRightRegular.of_mul ab.right⟩, ⟨IsLeftRegular.of_mul ab.left, IsRightRegular.of_mul ba.right⟩⟩ · rintro ⟨ha, hb⟩ exact ⟨ha.mul hb, hb.mul ha⟩ /-- The "most used" implication of `mul_and_mul_iff`, with split hypotheses, instead of `∧`. -/ @[to_additive "The \"most used\" implication of `add_and_add_iff`, with split hypotheses, instead of `∧`."] theorem IsRegular.and_of_mul_of_mul (ab : IsRegular (a * b)) (ba : IsRegular (b * a)) : IsRegular a ∧ IsRegular b := isRegular_mul_and_mul_iff.mp ⟨ab, ba⟩ end Semigroup section MulZeroClass variable [MulZeroClass R] {a b : R} /-- The element `0` is left-regular if and only if `R` is trivial. -/ theorem IsLeftRegular.subsingleton (h : IsLeftRegular (0 : R)) : Subsingleton R := ⟨fun a b => h <\| Eq.trans (zero_mul a) (zero_mul b).symm⟩ /-- The element `0` is right-regular if and only if `R` is trivial. -/ theorem IsRightRegular.subsingleton (h : IsRightRegular (0 : R)) : Subsingleton R := ⟨fun a b => h <\| Eq.trans (mul_zero a) (mul_zero b).symm⟩ /-- The element `0` is regular if and only if `R` is trivial. -/ theorem IsRegular.subsingleton (h : IsRegular (0 : R)) : Subsingleton R := h.left.subsingleton /-- The element `0` is left-regular if and only if `R` is trivial. -/ theorem isLeftRegular_zero_iff_subsingleton : IsLeftRegular (0 : R) ↔ Subsingleton R := ⟨fun h => h.subsingleton, fun H a b _ => @Subsingleton.elim _ H a b⟩ /-- In a non-trivial `MulZeroClass`, the `0` element is not left-regular. -/ theorem not_isLeftRegular_zero_iff : ¬IsLeftRegular (0 : R) ↔ Nontrivial R := by rw [nontrivial_iff, not_iff_comm, isLeftRegular_zero_iff_subsingleton, subsingleton_iff] push_neg exact Iff.rfl /-- The element `0` is right-regular if and only if `R` is trivial. -/ theorem isRightRegular_zero_iff_subsingleton : IsRightRegular (0 : R) ↔ Subsingleton R := ⟨fun h => h.subsingleton, fun H a b _ => @Subsingleton.elim _ H a b⟩ /-- In a non-trivial `MulZeroClass`, the `0` element is not right-regular. -/ theorem not_isRightRegular_zero_iff : ¬IsRightRegular (0 : R) ↔ Nontrivial R := by rw [nontrivial_iff, not_iff_comm, isRightRegular_zero_iff_subsingleton, subsingleton_iff] push_neg exact Iff.rfl /-- The element `0` is regular if and only if `R` is trivial. -/ theorem isRegular_iff_subsingleton : IsRegular (0 : R) ↔ Subsingleton R := ⟨fun h => h.left.subsingleton, fun h => ⟨isLeftRegular_zero_iff_subsingleton.mpr h, isRightRegular_zero_iff_subsingleton.mpr h⟩⟩ /-- A left-regular element of a `Nontrivial` `MulZeroClass` is non-zero. -/ theorem IsLeftRegular.ne_zero [Nontrivial R] (la : IsLeftRegular a) : a ≠ 0 := by rintro rfl rcases exists_pair_ne R with ⟨x, y, xy⟩ refine xy (la (?_ : 0 * x = 0 * y)) -- Porting note: lean4 seems to need the type signature rw [zero_mul, zero_mul] /-- A right-regular element of a `Nontrivial` `MulZeroClass` is non-zero. -/ theorem IsRightRegular.ne_zero [Nontrivial R] (ra : IsRightRegular a) : a ≠ 0 := by rintro rfl rcases exists_pair_ne R with ⟨x, y, xy⟩ refine xy (ra (?_ : x * 0 = y * 0)) rw [mul_zero, mul_zero] /-- A regular element of a `Nontrivial` `MulZeroClass` is non-zero. -/ theorem IsRegular.ne_zero [Nontrivial R] (la : IsRegular a) : a ≠ 0 := la.left.ne_zero /-- In a non-trivial ring, the element `0` is not left-regular -- with typeclasses. -/ theorem not_isLeftRegular_zero [nR : Nontrivial R] : ¬IsLeftRegular (0 : R) := not_isLeftRegular_zero_iff.mpr nR /-- In a non-trivial ring, the element `0` is not right-regular -- with typeclasses. -/ theorem not_isRightRegular_zero [nR : Nontrivial R] : ¬IsRightRegular (0 : R) := not_isRightRegular_zero_iff.mpr nR /-- In a non-trivial ring, the element `0` is not regular -- with typeclasses. -/ theorem not_isRegular_zero [Nontrivial R] : ¬IsRegular (0 : R) := fun h => IsRegular.ne_zero h rfl @[simp] lemma IsLeftRegular.mul_left_eq_zero_iff (hb : IsLeftRegular b) : b * a = 0 ↔ a = 0 := by nth_rw 1 [← mul_zero b] exact ⟨fun h ↦ hb h, fun ha ↦ by rw [ha]⟩ @[simp] lemma IsRightRegular.mul_right_eq_zero_iff (hb : IsRightRegular b) : a * b = 0 ↔ a = 0 := by nth_rw 1 [← zero_mul b] exact ⟨fun h ↦ hb h, fun ha ↦ by rw [ha]⟩ end MulZeroClass section MulOneClass variable [MulOneClass R] /-- If multiplying by `1` on either side is the identity, `1` is regular. -/ @[to_additive "If adding `0` on either side is the identity, `0` is regular."] theorem isRegular_one : IsRegular (1 : R) := ⟨fun a b ab => (one_mul a).symm.trans (Eq.trans ab (one_mul b)), fun a b ab => (mul_one a).symm.trans (Eq.trans ab (mul_one b))⟩ end MulOneClass section CommSemigroup variable [CommSemigroup R] {a b : R} /-- A product is regular if and only if the factors are. -/ @[to_additive "A sum is add-regular if and only if the summands are."] theorem isRegular_mul_iff : IsRegular (a * b) ↔ IsRegular a ∧ IsRegular b := by refine Iff.trans ?_ isRegular_mul_and_mul_iff exact ⟨fun ab => ⟨ab, by rwa [mul_comm]⟩, fun rab => rab.1⟩ end CommSemigroup section Monoid variable [Monoid R] {a b : R} {n : ℕ} /-- An element admitting a left inverse is left-regular. -/ @[to_additive "An element admitting a left additive opposite is add-left-regular."] theorem isLeftRegular_of_mul_eq_one (h : b * a = 1) : IsLeftRegular a := IsLeftRegular.of_mul (a := b) (by rw [h]; exact isRegular_one.left)	/-- An element admitting a right inverse is right-regular. -/ @[to_additive "An element admitting a right additive opposite is add-right-regular."]	Mathlib/Algebra/Regular/Basic.lean	288	290
/- Copyright (c) 2022 Rémi Bottinelli. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Rémi Bottinelli, Junyan Xu -/ import Mathlib.Algebra.Group.Subgroup.Defs import Mathlib.CategoryTheory.Groupoid.VertexGroup import Mathlib.CategoryTheory.Groupoid.Basic import Mathlib.CategoryTheory.Groupoid import Mathlib.Data.Set.Lattice /-! # Subgroupoid This file defines subgroupoids as `structure`s containing the subsets of arrows and their stability under composition and inversion. Also defined are: * containment of subgroupoids is a complete lattice; * images and preimages of subgroupoids under a functor; * the notion of normality of subgroupoids and its stability under intersection and preimage; * compatibility of the above with `CategoryTheory.Groupoid.vertexGroup`. ## Main definitions Given a type `C` with associated `groupoid C` instance. * `CategoryTheory.Subgroupoid C` is the type of subgroupoids of `C` * `CategoryTheory.Subgroupoid.IsNormal` is the property that the subgroupoid is stable under conjugation by arbitrary arrows, _and_ that all identity arrows are contained in the subgroupoid. * `CategoryTheory.Subgroupoid.comap` is the "preimage" map of subgroupoids along a functor. * `CategoryTheory.Subgroupoid.map` is the "image" map of subgroupoids along a functor _injective on objects_. * `CategoryTheory.Subgroupoid.vertexSubgroup` is the subgroup of the vertex group at a given vertex `v`, assuming `v` is contained in the `CategoryTheory.Subgroupoid` (meaning, by definition, that the arrow `𝟙 v` is contained in the subgroupoid). ## Implementation details The structure of this file is copied from/inspired by `Mathlib/GroupTheory/Subgroup/Basic.lean` and `Mathlib/Combinatorics/SimpleGraph/Subgraph.lean`. ## TODO * Equivalent inductive characterization of generated (normal) subgroupoids. * Characterization of normal subgroupoids as kernels. * Prove that `CategoryTheory.Subgroupoid.full` and `CategoryTheory.Subgroupoid.disconnect` preserve intersections (and `CategoryTheory.Subgroupoid.disconnect` also unions) ## Tags category theory, groupoid, subgroupoid -/ namespace CategoryTheory open Set Groupoid universe u v variable {C : Type u} [Groupoid C] /-- A sugroupoid of `C` consists of a choice of arrows for each pair of vertices, closed under composition and inverses. -/ @[ext] structure Subgroupoid (C : Type u) [Groupoid C] where /-- The arrow choice for each pair of vertices -/ arrows : ∀ c d : C, Set (c ⟶ d) protected inv : ∀ {c d} {p : c ⟶ d}, p ∈ arrows c d → Groupoid.inv p ∈ arrows d c protected mul : ∀ {c d e} {p}, p ∈ arrows c d → ∀ {q}, q ∈ arrows d e → p ≫ q ∈ arrows c e namespace Subgroupoid variable (S : Subgroupoid C) theorem inv_mem_iff {c d : C} (f : c ⟶ d) : Groupoid.inv f ∈ S.arrows d c ↔ f ∈ S.arrows c d := by constructor · intro h simpa only [inv_eq_inv, IsIso.inv_inv] using S.inv h · apply S.inv theorem mul_mem_cancel_left {c d e : C} {f : c ⟶ d} {g : d ⟶ e} (hf : f ∈ S.arrows c d) : f ≫ g ∈ S.arrows c e ↔ g ∈ S.arrows d e := by constructor · rintro h suffices Groupoid.inv f ≫ f ≫ g ∈ S.arrows d e by simpa only [inv_eq_inv, IsIso.inv_hom_id_assoc] using this apply S.mul (S.inv hf) h · apply S.mul hf theorem mul_mem_cancel_right {c d e : C} {f : c ⟶ d} {g : d ⟶ e} (hg : g ∈ S.arrows d e) : f ≫ g ∈ S.arrows c e ↔ f ∈ S.arrows c d := by constructor · rintro h suffices (f ≫ g) ≫ Groupoid.inv g ∈ S.arrows c d by simpa only [inv_eq_inv, IsIso.hom_inv_id, Category.comp_id, Category.assoc] using this apply S.mul h (S.inv hg) · exact fun hf => S.mul hf hg /-- The vertices of `C` on which `S` has non-trivial isotropy -/ def objs : Set C := {c : C \| (S.arrows c c).Nonempty} theorem mem_objs_of_src {c d : C} {f : c ⟶ d} (h : f ∈ S.arrows c d) : c ∈ S.objs := ⟨f ≫ Groupoid.inv f, S.mul h (S.inv h)⟩ theorem mem_objs_of_tgt {c d : C} {f : c ⟶ d} (h : f ∈ S.arrows c d) : d ∈ S.objs := ⟨Groupoid.inv f ≫ f, S.mul (S.inv h) h⟩ theorem id_mem_of_nonempty_isotropy (c : C) : c ∈ objs S → 𝟙 c ∈ S.arrows c c := by rintro ⟨γ, hγ⟩ convert S.mul hγ (S.inv hγ) simp only [inv_eq_inv, IsIso.hom_inv_id] theorem id_mem_of_src {c d : C} {f : c ⟶ d} (h : f ∈ S.arrows c d) : 𝟙 c ∈ S.arrows c c := id_mem_of_nonempty_isotropy S c (mem_objs_of_src S h) theorem id_mem_of_tgt {c d : C} {f : c ⟶ d} (h : f ∈ S.arrows c d) : 𝟙 d ∈ S.arrows d d := id_mem_of_nonempty_isotropy S d (mem_objs_of_tgt S h) /-- A subgroupoid seen as a quiver on vertex set `C` -/ def asWideQuiver : Quiver C := ⟨fun c d => Subtype <\| S.arrows c d⟩ /-- The coercion of a subgroupoid as a groupoid -/ @[simps comp_coe, simps -isSimp inv_coe] instance coe : Groupoid S.objs where Hom a b := S.arrows a.val b.val id a := ⟨𝟙 a.val, id_mem_of_nonempty_isotropy S a.val a.prop⟩ comp p q := ⟨p.val ≫ q.val, S.mul p.prop q.prop⟩ inv p := ⟨Groupoid.inv p.val, S.inv p.prop⟩ @[simp] theorem coe_inv_coe' {c d : S.objs} (p : c ⟶ d) : (CategoryTheory.inv p).val = CategoryTheory.inv p.val := by simp only [← inv_eq_inv, coe_inv_coe] /-- The embedding of the coerced subgroupoid to its parent -/ def hom : S.objs ⥤ C where obj c := c.val map f := f.val map_id _ := rfl map_comp _ _ := rfl theorem hom.inj_on_objects : Function.Injective (hom S).obj := by rintro ⟨c, hc⟩ ⟨d, hd⟩ hcd simp only [Subtype.mk_eq_mk]; exact hcd theorem hom.faithful : ∀ c d, Function.Injective fun f : c ⟶ d => (hom S).map f := by rintro ⟨c, hc⟩ ⟨d, hd⟩ ⟨f, hf⟩ ⟨g, hg⟩ hfg; exact Subtype.eq hfg /-- The subgroup of the vertex group at `c` given by the subgroupoid -/ def vertexSubgroup {c : C} (hc : c ∈ S.objs) : Subgroup (c ⟶ c) where carrier := S.arrows c c mul_mem' hf hg := S.mul hf hg one_mem' := id_mem_of_nonempty_isotropy _ _ hc inv_mem' hf := S.inv hf /-- The set of all arrows of a subgroupoid, as a set in `Σ c d : C, c ⟶ d`. -/ @[coe] def toSet (S : Subgroupoid C) : Set (Σ c d : C, c ⟶ d) := {F \| F.2.2 ∈ S.arrows F.1 F.2.1} instance : SetLike (Subgroupoid C) (Σ c d : C, c ⟶ d) where coe := toSet coe_injective' := fun ⟨S, _, _⟩ ⟨T, _, _⟩ h => by ext c d f; apply Set.ext_iff.1 h ⟨c, d, f⟩ theorem mem_iff (S : Subgroupoid C) (F : Σ c d, c ⟶ d) : F ∈ S ↔ F.2.2 ∈ S.arrows F.1 F.2.1 := Iff.rfl theorem le_iff (S T : Subgroupoid C) : S ≤ T ↔ ∀ {c d}, S.arrows c d ⊆ T.arrows c d := by rw [SetLike.le_def, Sigma.forall]; exact forall_congr' fun c => Sigma.forall instance : Top (Subgroupoid C) := ⟨{ arrows := fun _ _ => Set.univ mul := by intros; trivial inv := by intros; trivial }⟩ theorem mem_top {c d : C} (f : c ⟶ d) : f ∈ (⊤ : Subgroupoid C).arrows c d := trivial theorem mem_top_objs (c : C) : c ∈ (⊤ : Subgroupoid C).objs := by dsimp [Top.top, objs] simp only [univ_nonempty] instance : Bot (Subgroupoid C) := ⟨{ arrows := fun _ _ => ∅ mul := False.elim inv := False.elim }⟩ instance : Inhabited (Subgroupoid C) := ⟨⊤⟩ instance : Min (Subgroupoid C) := ⟨fun S T => { arrows := fun c d => S.arrows c d ∩ T.arrows c d inv := fun hp ↦ ⟨S.inv hp.1, T.inv hp.2⟩ mul := fun hp _ hq ↦ ⟨S.mul hp.1 hq.1, T.mul hp.2 hq.2⟩ }⟩ instance : InfSet (Subgroupoid C) := ⟨fun s => { arrows := fun c d => ⋂ S ∈ s, Subgroupoid.arrows S c d inv := fun hp ↦ by rw [mem_iInter₂] at hp ⊢; exact fun S hS => S.inv (hp S hS) mul := fun hp _ hq ↦ by rw [mem_iInter₂] at hp hq ⊢ exact fun S hS => S.mul (hp S hS) (hq S hS) }⟩ theorem mem_sInf_arrows {s : Set (Subgroupoid C)} {c d : C} {p : c ⟶ d} : p ∈ (sInf s).arrows c d ↔ ∀ S ∈ s, p ∈ S.arrows c d := mem_iInter₂ theorem mem_sInf {s : Set (Subgroupoid C)} {p : Σ c d : C, c ⟶ d} : p ∈ sInf s ↔ ∀ S ∈ s, p ∈ S := mem_sInf_arrows instance : CompleteLattice (Subgroupoid C) := { completeLatticeOfInf (Subgroupoid C) (by refine fun s => ⟨fun S Ss F => ?_, fun T Tl F fT => ?_⟩ <;> simp only [mem_sInf] exacts [fun hp => hp S Ss, fun S Ss => Tl Ss fT]) with bot := ⊥ bot_le := fun _ => empty_subset _ top := ⊤ le_top := fun _ => subset_univ _ inf := (· ⊓ ·) le_inf := fun _ _ _ RS RT _ pR => ⟨RS pR, RT pR⟩ inf_le_left := fun _ _ _ => And.left inf_le_right := fun _ _ _ => And.right } theorem le_objs {S T : Subgroupoid C} (h : S ≤ T) : S.objs ⊆ T.objs := fun s ⟨γ, hγ⟩ => ⟨γ, @h ⟨s, s, γ⟩ hγ⟩ /-- The functor associated to the embedding of subgroupoids -/ def inclusion {S T : Subgroupoid C} (h : S ≤ T) : S.objs ⥤ T.objs where obj s := ⟨s.val, le_objs h s.prop⟩ map f := ⟨f.val, @h ⟨_, _, f.val⟩ f.prop⟩ map_id _ := rfl map_comp _ _ := rfl theorem inclusion_inj_on_objects {S T : Subgroupoid C} (h : S ≤ T) : Function.Injective (inclusion h).obj := fun ⟨s, hs⟩ ⟨t, ht⟩ => by simpa only [inclusion, Subtype.mk_eq_mk] using id theorem inclusion_faithful {S T : Subgroupoid C} (h : S ≤ T) (s t : S.objs) : Function.Injective fun f : s ⟶ t => (inclusion h).map f := fun ⟨f, hf⟩ ⟨g, hg⟩ => by -- Porting note: was `...; simpa only [Subtype.mk_eq_mk] using id` dsimp only [inclusion]; rw [Subtype.mk_eq_mk, Subtype.mk_eq_mk]; exact id theorem inclusion_refl {S : Subgroupoid C} : inclusion (le_refl S) = 𝟭 S.objs := Functor.hext (fun _ => rfl) fun _ _ _ => HEq.refl _ theorem inclusion_trans {R S T : Subgroupoid C} (k : R ≤ S) (h : S ≤ T) : inclusion (k.trans h) = inclusion k ⋙ inclusion h := rfl theorem inclusion_comp_embedding {S T : Subgroupoid C} (h : S ≤ T) : inclusion h ⋙ T.hom = S.hom := rfl /-- The family of arrows of the discrete groupoid -/ inductive Discrete.Arrows : ∀ c d : C, (c ⟶ d) → Prop \| id (c : C) : Discrete.Arrows c c (𝟙 c) /-- The only arrows of the discrete groupoid are the identity arrows. -/ def discrete : Subgroupoid C where arrows c d := {p \| Discrete.Arrows c d p} inv := by rintro _ _ _ ⟨⟩; simp only [inv_eq_inv, IsIso.inv_id]; constructor mul := by rintro _ _ _ _ ⟨⟩ _ ⟨⟩; rw [Category.comp_id]; constructor theorem mem_discrete_iff {c d : C} (f : c ⟶ d) : f ∈ discrete.arrows c d ↔ ∃ h : c = d, f = eqToHom h := ⟨by rintro ⟨⟩; exact ⟨rfl, rfl⟩, by rintro ⟨rfl, rfl⟩; constructor⟩ /-- A subgroupoid is wide if its carrier set is all of `C`. -/ structure IsWide : Prop where wide : ∀ c, 𝟙 c ∈ S.arrows c c theorem isWide_iff_objs_eq_univ : S.IsWide ↔ S.objs = Set.univ := by constructor · rintro h ext x; constructor <;> simp only [top_eq_univ, mem_univ, imp_true_iff, forall_true_left] apply mem_objs_of_src S (h.wide x) · rintro h refine ⟨fun c => ?_⟩ obtain ⟨γ, γS⟩ := (le_of_eq h.symm : ⊤ ⊆ S.objs) (Set.mem_univ c) exact id_mem_of_src S γS theorem IsWide.id_mem {S : Subgroupoid C} (Sw : S.IsWide) (c : C) : 𝟙 c ∈ S.arrows c c := Sw.wide c theorem IsWide.eqToHom_mem {S : Subgroupoid C} (Sw : S.IsWide) {c d : C} (h : c = d) : eqToHom h ∈ S.arrows c d := by cases h; simp only [eqToHom_refl]; apply Sw.id_mem c /-- A subgroupoid is normal if it is wide and satisfies the expected stability under conjugacy. -/ structure IsNormal : Prop extends IsWide S where conj : ∀ {c d} (p : c ⟶ d) {γ : c ⟶ c}, γ ∈ S.arrows c c → Groupoid.inv p ≫ γ ≫ p ∈ S.arrows d d theorem IsNormal.conj' {S : Subgroupoid C} (Sn : IsNormal S) : ∀ {c d} (p : d ⟶ c) {γ : c ⟶ c}, γ ∈ S.arrows c c → p ≫ γ ≫ Groupoid.inv p ∈ S.arrows d d := fun p γ hs => by convert Sn.conj (Groupoid.inv p) hs; simp theorem IsNormal.conjugation_bij (Sn : IsNormal S) {c d} (p : c ⟶ d) : Set.BijOn (fun γ : c ⟶ c => Groupoid.inv p ≫ γ ≫ p) (S.arrows c c) (S.arrows d d) := by refine ⟨fun γ γS => Sn.conj p γS, fun γ₁ _ γ₂ _ h => ?_, fun δ δS => ⟨p ≫ δ ≫ Groupoid.inv p, Sn.conj' p δS, ?_⟩⟩ · simpa only [inv_eq_inv, Category.assoc, IsIso.hom_inv_id, Category.comp_id, IsIso.hom_inv_id_assoc] using p ≫= h =≫ inv p · simp only [inv_eq_inv, Category.assoc, IsIso.inv_hom_id, Category.comp_id, IsIso.inv_hom_id_assoc] theorem top_isNormal : IsNormal (⊤ : Subgroupoid C) := { wide := fun _ => trivial conj := fun _ _ _ => trivial } theorem sInf_isNormal (s : Set <\| Subgroupoid C) (sn : ∀ S ∈ s, IsNormal S) : IsNormal (sInf s) := { wide := by simp_rw [sInf, mem_iInter₂]; exact fun c S Ss => (sn S Ss).wide c conj := by simp_rw [sInf, mem_iInter₂]; exact fun p γ hγ S Ss => (sn S Ss).conj p (hγ S Ss) } theorem discrete_isNormal : (@discrete C _).IsNormal := { wide := fun c => by constructor conj := fun f γ hγ => by cases hγ simp only [inv_eq_inv, Category.id_comp, IsIso.inv_hom_id]; constructor } theorem IsNormal.vertexSubgroup (Sn : IsNormal S) (c : C) (cS : c ∈ S.objs) : (S.vertexSubgroup cS).Normal where conj_mem x hx y := by rw [mul_assoc]; exact Sn.conj' y hx section GeneratedSubgroupoid -- TODO: proof that generated is just "words in X" and generatedNormal is similarly variable (X : ∀ c d : C, Set (c ⟶ d)) /-- The subgropoid generated by the set of arrows `X` -/ def generated : Subgroupoid C := sInf {S : Subgroupoid C \| ∀ c d, X c d ⊆ S.arrows c d} theorem subset_generated (c d : C) : X c d ⊆ (generated X).arrows c d := by dsimp only [generated, sInf] simp only [subset_iInter₂_iff] exact fun S hS f fS => hS _ _ fS /-- The normal sugroupoid generated by the set of arrows `X` -/ def generatedNormal : Subgroupoid C := sInf {S : Subgroupoid C \| (∀ c d, X c d ⊆ S.arrows c d) ∧ S.IsNormal} theorem generated_le_generatedNormal : generated X ≤ generatedNormal X := by apply @sInf_le_sInf (Subgroupoid C) _ exact fun S ⟨h, _⟩ => h theorem generatedNormal_isNormal : (generatedNormal X).IsNormal := sInf_isNormal _ fun _ h => h.right theorem IsNormal.generatedNormal_le {S : Subgroupoid C} (Sn : S.IsNormal) : generatedNormal X ≤ S ↔ ∀ c d, X c d ⊆ S.arrows c d := by constructor · rintro h c d have h' := generated_le_generatedNormal X rw [le_iff] at h h' exact ((subset_generated X c d).trans (@h' c d)).trans (@h c d) · rintro h apply @sInf_le (Subgroupoid C) _ exact ⟨h, Sn⟩ end GeneratedSubgroupoid section Hom	variable {D : Type*} [Groupoid D] (φ : C ⥤ D)	Mathlib/CategoryTheory/Groupoid/Subgroupoid.lean	369	371
/- Copyright (c) 2020 Sébastien Gouëzel. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Sébastien Gouëzel -/ import Mathlib.Topology.UniformSpace.Cauchy /-! # Uniform convergence A sequence of functions `Fₙ` (with values in a metric space) converges uniformly on a set `s` to a function `f` if, for all `ε > 0`, for all large enough `n`, one has for all `y ∈ s` the inequality `dist (f y, Fₙ y) < ε`. Under uniform convergence, many properties of the `Fₙ` pass to the limit, most notably continuity. We prove this in the file, defining the notion of uniform convergence in the more general setting of uniform spaces, and with respect to an arbitrary indexing set endowed with a filter (instead of just `ℕ` with `atTop`). ## Main results Let `α` be a topological space, `β` a uniform space, `Fₙ` and `f` be functions from `α` to `β` (where the index `n` belongs to an indexing type `ι` endowed with a filter `p`). * `TendstoUniformlyOn F f p s`: the fact that `Fₙ` converges uniformly to `f` on `s`. This means that, for any entourage `u` of the diagonal, for large enough `n` (with respect to `p`), one has `(f y, Fₙ y) ∈ u` for all `y ∈ s`. * `TendstoUniformly F f p`: same notion with `s = univ`. * `TendstoUniformlyOn.continuousOn`: a uniform limit on a set of functions which are continuous on this set is itself continuous on this set. * `TendstoUniformly.continuous`: a uniform limit of continuous functions is continuous. * `TendstoUniformlyOn.tendsto_comp`: If `Fₙ` tends uniformly to `f` on a set `s`, and `gₙ` tends to `x` within `s`, then `Fₙ gₙ` tends to `f x` if `f` is continuous at `x` within `s`. * `TendstoUniformly.tendsto_comp`: If `Fₙ` tends uniformly to `f`, and `gₙ` tends to `x`, then `Fₙ gₙ` tends to `f x`. Finally, we introduce the notion of a uniform Cauchy sequence, which is to uniform convergence what a Cauchy sequence is to the usual notion of convergence. ## Implementation notes We derive most of our initial results from an auxiliary definition `TendstoUniformlyOnFilter`. This definition in and of itself can sometimes be useful, e.g., when studying the local behavior of the `Fₙ` near a point, which would typically look like `TendstoUniformlyOnFilter F f p (𝓝 x)`. Still, while this may be the "correct" definition (see `tendstoUniformlyOn_iff_tendstoUniformlyOnFilter`), it is somewhat unwieldy to work with in practice. Thus, we provide the more traditional definition in `TendstoUniformlyOn`. ## Tags Uniform limit, uniform convergence, tends uniformly to -/ noncomputable section open Topology Uniformity Filter Set Uniform variable {α β γ ι : Type} [UniformSpace β] variable {F : ι → α → β} {f : α → β} {s s' : Set α} {x : α} {p : Filter ι} {p' : Filter α} /-! ### Different notions of uniform convergence We define uniform convergence, on a set or in the whole space. -/ /-- A sequence of functions `Fₙ` converges uniformly on a filter `p'` to a limiting function `f` with respect to the filter `p` if, for any entourage of the diagonal `u`, one has `p ×ˢ p'`-eventually `(f x, Fₙ x) ∈ u`. -/ def TendstoUniformlyOnFilter (F : ι → α → β) (f : α → β) (p : Filter ι) (p' : Filter α) := ∀ u ∈ 𝓤 β, ∀ᶠ n : ι × α in p ×ˢ p', (f n.snd, F n.fst n.snd) ∈ u /-- A sequence of functions `Fₙ` converges uniformly on a filter `p'` to a limiting function `f` w.r.t. filter `p` iff the function `(n, x) ↦ (f x, Fₙ x)` converges along `p ×ˢ p'` to the uniformity. In other words: one knows nothing about the behavior of `x` in this limit besides it being in `p'`. -/ theorem tendstoUniformlyOnFilter_iff_tendsto : TendstoUniformlyOnFilter F f p p' ↔ Tendsto (fun q : ι × α => (f q.2, F q.1 q.2)) (p ×ˢ p') (𝓤 β) := Iff.rfl /-- A sequence of functions `Fₙ` converges uniformly on a set `s` to a limiting function `f` with respect to the filter `p` if, for any entourage of the diagonal `u`, one has `p`-eventually `(f x, Fₙ x) ∈ u` for all `x ∈ s`. -/ def TendstoUniformlyOn (F : ι → α → β) (f : α → β) (p : Filter ι) (s : Set α) := ∀ u ∈ 𝓤 β, ∀ᶠ n in p, ∀ x : α, x ∈ s → (f x, F n x) ∈ u theorem tendstoUniformlyOn_iff_tendstoUniformlyOnFilter : TendstoUniformlyOn F f p s ↔ TendstoUniformlyOnFilter F f p (𝓟 s) := by simp only [TendstoUniformlyOn, TendstoUniformlyOnFilter] apply forall₂_congr simp_rw [eventually_prod_principal_iff] simp alias ⟨TendstoUniformlyOn.tendstoUniformlyOnFilter, TendstoUniformlyOnFilter.tendstoUniformlyOn⟩ := tendstoUniformlyOn_iff_tendstoUniformlyOnFilter /-- A sequence of functions `Fₙ` converges uniformly on a set `s` to a limiting function `f` w.r.t. filter `p` iff the function `(n, x) ↦ (f x, Fₙ x)` converges along `p ×ˢ 𝓟 s` to the uniformity. In other words: one knows nothing about the behavior of `x` in this limit besides it being in `s`. -/ theorem tendstoUniformlyOn_iff_tendsto : TendstoUniformlyOn F f p s ↔ Tendsto (fun q : ι × α => (f q.2, F q.1 q.2)) (p ×ˢ 𝓟 s) (𝓤 β) := by simp [tendstoUniformlyOn_iff_tendstoUniformlyOnFilter, tendstoUniformlyOnFilter_iff_tendsto] /-- A sequence of functions `Fₙ` converges uniformly to a limiting function `f` with respect to a filter `p` if, for any entourage of the diagonal `u`, one has `p`-eventually `(f x, Fₙ x) ∈ u` for all `x`. -/ def TendstoUniformly (F : ι → α → β) (f : α → β) (p : Filter ι) := ∀ u ∈ 𝓤 β, ∀ᶠ n in p, ∀ x : α, (f x, F n x) ∈ u theorem tendstoUniformlyOn_univ : TendstoUniformlyOn F f p univ ↔ TendstoUniformly F f p := by simp [TendstoUniformlyOn, TendstoUniformly] theorem tendstoUniformly_iff_tendstoUniformlyOnFilter : TendstoUniformly F f p ↔ TendstoUniformlyOnFilter F f p ⊤ := by rw [← tendstoUniformlyOn_univ, tendstoUniformlyOn_iff_tendstoUniformlyOnFilter, principal_univ] theorem TendstoUniformly.tendstoUniformlyOnFilter (h : TendstoUniformly F f p) : TendstoUniformlyOnFilter F f p ⊤ := by rwa [← tendstoUniformly_iff_tendstoUniformlyOnFilter] theorem tendstoUniformlyOn_iff_tendstoUniformly_comp_coe : TendstoUniformlyOn F f p s ↔ TendstoUniformly (fun i (x : s) => F i x) (f ∘ (↑)) p := forall₂_congr fun u _ => by simp /-- A sequence of functions `Fₙ` converges uniformly to a limiting function `f` w.r.t. filter `p` iff the function `(n, x) ↦ (f x, Fₙ x)` converges along `p ×ˢ ⊤` to the uniformity. In other words: one knows nothing about the behavior of `x` in this limit. -/ theorem tendstoUniformly_iff_tendsto : TendstoUniformly F f p ↔ Tendsto (fun q : ι × α => (f q.2, F q.1 q.2)) (p ×ˢ ⊤) (𝓤 β) := by simp [tendstoUniformly_iff_tendstoUniformlyOnFilter, tendstoUniformlyOnFilter_iff_tendsto] /-- Uniform convergence implies pointwise convergence. -/ theorem TendstoUniformlyOnFilter.tendsto_at (h : TendstoUniformlyOnFilter F f p p') (hx : 𝓟 {x} ≤ p') : Tendsto (fun n => F n x) p <\| 𝓝 (f x) := by refine Uniform.tendsto_nhds_right.mpr fun u hu => mem_map.mpr ?_ filter_upwards [(h u hu).curry] intro i h simpa using h.filter_mono hx /-- Uniform convergence implies pointwise convergence. -/ theorem TendstoUniformlyOn.tendsto_at (h : TendstoUniformlyOn F f p s) (hx : x ∈ s) : Tendsto (fun n => F n x) p <\| 𝓝 (f x) := h.tendstoUniformlyOnFilter.tendsto_at (le_principal_iff.mpr <\| mem_principal.mpr <\| singleton_subset_iff.mpr <\| hx) /-- Uniform convergence implies pointwise convergence. -/ theorem TendstoUniformly.tendsto_at (h : TendstoUniformly F f p) (x : α) : Tendsto (fun n => F n x) p <\| 𝓝 (f x) := h.tendstoUniformlyOnFilter.tendsto_at le_top theorem TendstoUniformlyOnFilter.mono_left {p'' : Filter ι} (h : TendstoUniformlyOnFilter F f p p') (hp : p'' ≤ p) : TendstoUniformlyOnFilter F f p'' p' := fun u hu => (h u hu).filter_mono (p'.prod_mono_left hp) theorem TendstoUniformlyOnFilter.mono_right {p'' : Filter α} (h : TendstoUniformlyOnFilter F f p p') (hp : p'' ≤ p') : TendstoUniformlyOnFilter F f p p'' := fun u hu => (h u hu).filter_mono (p.prod_mono_right hp) theorem TendstoUniformlyOn.mono (h : TendstoUniformlyOn F f p s) (h' : s' ⊆ s) : TendstoUniformlyOn F f p s' := tendstoUniformlyOn_iff_tendstoUniformlyOnFilter.mpr (h.tendstoUniformlyOnFilter.mono_right (le_principal_iff.mpr <\| mem_principal.mpr h')) theorem TendstoUniformlyOnFilter.congr {F' : ι → α → β} (hf : TendstoUniformlyOnFilter F f p p') (hff' : ∀ᶠ n : ι × α in p ×ˢ p', F n.fst n.snd = F' n.fst n.snd) : TendstoUniformlyOnFilter F' f p p' := by refine fun u hu => ((hf u hu).and hff').mono fun n h => ?_ rw [← h.right] exact h.left theorem TendstoUniformlyOn.congr {F' : ι → α → β} (hf : TendstoUniformlyOn F f p s) (hff' : ∀ᶠ n in p, Set.EqOn (F n) (F' n) s) : TendstoUniformlyOn F' f p s := by rw [tendstoUniformlyOn_iff_tendstoUniformlyOnFilter] at hf ⊢ refine hf.congr ?_ rw [eventually_iff] at hff' ⊢ simp only [Set.EqOn] at hff' simp only [mem_prod_principal, hff', mem_setOf_eq] lemma tendstoUniformly_congr {F' : ι → α → β} (hF : F =ᶠ[p] F') : TendstoUniformly F f p ↔ TendstoUniformly F' f p := by simp_rw [← tendstoUniformlyOn_univ] at have HF := EventuallyEq.exists_mem hF exact ⟨fun h => h.congr (by aesop), fun h => h.congr (by simp_rw [eqOn_comm]; aesop)⟩ theorem TendstoUniformlyOn.congr_right {g : α → β} (hf : TendstoUniformlyOn F f p s) (hfg : EqOn f g s) : TendstoUniformlyOn F g p s := fun u hu => by filter_upwards [hf u hu] with i hi a ha using hfg ha ▸ hi a ha protected theorem TendstoUniformly.tendstoUniformlyOn (h : TendstoUniformly F f p) : TendstoUniformlyOn F f p s := (tendstoUniformlyOn_univ.2 h).mono (subset_univ s) /-- Composing on the right by a function preserves uniform convergence on a filter -/ theorem TendstoUniformlyOnFilter.comp (h : TendstoUniformlyOnFilter F f p p') (g : γ → α) : TendstoUniformlyOnFilter (fun n => F n ∘ g) (f ∘ g) p (p'.comap g) := by rw [tendstoUniformlyOnFilter_iff_tendsto] at h ⊢ exact h.comp (tendsto_id.prodMap tendsto_comap) /-- Composing on the right by a function preserves uniform convergence on a set -/ theorem TendstoUniformlyOn.comp (h : TendstoUniformlyOn F f p s) (g : γ → α) : TendstoUniformlyOn (fun n => F n ∘ g) (f ∘ g) p (g ⁻¹' s) := by rw [tendstoUniformlyOn_iff_tendstoUniformlyOnFilter] at h ⊢ simpa [TendstoUniformlyOn, comap_principal] using TendstoUniformlyOnFilter.comp h g /-- Composing on the right by a function preserves uniform convergence -/ theorem TendstoUniformly.comp (h : TendstoUniformly F f p) (g : γ → α) : TendstoUniformly (fun n => F n ∘ g) (f ∘ g) p := by rw [tendstoUniformly_iff_tendstoUniformlyOnFilter] at h ⊢ simpa [principal_univ, comap_principal] using h.comp g /-- Composing on the left by a uniformly continuous function preserves uniform convergence on a filter -/ theorem UniformContinuous.comp_tendstoUniformlyOnFilter [UniformSpace γ] {g : β → γ} (hg : UniformContinuous g) (h : TendstoUniformlyOnFilter F f p p') : TendstoUniformlyOnFilter (fun i => g ∘ F i) (g ∘ f) p p' := fun _u hu => h _ (hg hu) /-- Composing on the left by a uniformly continuous function preserves uniform convergence on a set -/ theorem UniformContinuous.comp_tendstoUniformlyOn [UniformSpace γ] {g : β → γ} (hg : UniformContinuous g) (h : TendstoUniformlyOn F f p s) : TendstoUniformlyOn (fun i => g ∘ F i) (g ∘ f) p s := fun _u hu => h _ (hg hu) /-- Composing on the left by a uniformly continuous function preserves uniform convergence -/ theorem UniformContinuous.comp_tendstoUniformly [UniformSpace γ] {g : β → γ} (hg : UniformContinuous g) (h : TendstoUniformly F f p) : TendstoUniformly (fun i => g ∘ F i) (g ∘ f) p := fun _u hu => h _ (hg hu) theorem TendstoUniformlyOnFilter.prodMap {ι' α' β' : Type} [UniformSpace β'] {F' : ι' → α' → β'} {f' : α' → β'} {q : Filter ι'} {q' : Filter α'} (h : TendstoUniformlyOnFilter F f p p') (h' : TendstoUniformlyOnFilter F' f' q q') : TendstoUniformlyOnFilter (fun i : ι × ι' => Prod.map (F i.1) (F' i.2)) (Prod.map f f') (p ×ˢ q) (p' ×ˢ q') := by rw [tendstoUniformlyOnFilter_iff_tendsto] at h h' ⊢ rw [uniformity_prod_eq_comap_prod, tendsto_comap_iff, ← map_swap4_prod, tendsto_map'_iff] simpa using h.prodMap h' @[deprecated (since := "2025-03-10")] alias TendstoUniformlyOnFilter.prod_map := TendstoUniformlyOnFilter.prodMap theorem TendstoUniformlyOn.prodMap {ι' α' β' : Type} [UniformSpace β'] {F' : ι' → α' → β'} {f' : α' → β'} {p' : Filter ι'} {s' : Set α'} (h : TendstoUniformlyOn F f p s) (h' : TendstoUniformlyOn F' f' p' s') : TendstoUniformlyOn (fun i : ι × ι' => Prod.map (F i.1) (F' i.2)) (Prod.map f f') (p ×ˢ p') (s ×ˢ s') := by rw [tendstoUniformlyOn_iff_tendstoUniformlyOnFilter] at h h' ⊢ simpa only [prod_principal_principal] using h.prodMap h' @[deprecated (since := "2025-03-10")] alias TendstoUniformlyOn.prod_map := TendstoUniformlyOn.prodMap theorem TendstoUniformly.prodMap {ι' α' β' : Type} [UniformSpace β'] {F' : ι' → α' → β'} {f' : α' → β'} {p' : Filter ι'} (h : TendstoUniformly F f p) (h' : TendstoUniformly F' f' p') : TendstoUniformly (fun i : ι × ι' => Prod.map (F i.1) (F' i.2)) (Prod.map f f') (p ×ˢ p') := by rw [← tendstoUniformlyOn_univ, ← univ_prod_univ] at exact h.prodMap h' @[deprecated (since := "2025-03-10")] alias TendstoUniformly.prod_map := TendstoUniformly.prodMap theorem TendstoUniformlyOnFilter.prodMk {ι' β' : Type} [UniformSpace β'] {F' : ι' → α → β'} {f' : α → β'} {q : Filter ι'} (h : TendstoUniformlyOnFilter F f p p') (h' : TendstoUniformlyOnFilter F' f' q p') : TendstoUniformlyOnFilter (fun (i : ι × ι') a => (F i.1 a, F' i.2 a)) (fun a => (f a, f' a)) (p ×ˢ q) p' := fun u hu => ((h.prodMap h') u hu).diag_of_prod_right @[deprecated (since := "2025-03-10")] alias TendstoUniformlyOnFilter.prod := TendstoUniformlyOnFilter.prodMk protected theorem TendstoUniformlyOn.prodMk {ι' β' : Type} [UniformSpace β'] {F' : ι' → α → β'} {f' : α → β'} {p' : Filter ι'} (h : TendstoUniformlyOn F f p s) (h' : TendstoUniformlyOn F' f' p' s) : TendstoUniformlyOn (fun (i : ι × ι') a => (F i.1 a, F' i.2 a)) (fun a => (f a, f' a)) (p ×ˢ p') s := (congr_arg _ s.inter_self).mp ((h.prodMap h').comp fun a => (a, a)) @[deprecated (since := "2025-03-10")] alias TendstoUniformlyOn.prod := TendstoUniformlyOn.prodMk theorem TendstoUniformly.prodMk {ι' β' : Type*} [UniformSpace β'] {F' : ι' → α → β'} {f' : α → β'} {p' : Filter ι'} (h : TendstoUniformly F f p) (h' : TendstoUniformly F' f' p') : TendstoUniformly (fun (i : ι × ι') a => (F i.1 a, F' i.2 a)) (fun a => (f a, f' a)) (p ×ˢ p') := (h.prodMap h').comp fun a => (a, a) @[deprecated (since := "2025-03-10")] alias TendstoUniformly.prod := TendstoUniformly.prodMk /-- Uniform convergence on a filter `p'` to a constant function is equivalent to convergence in `p ×ˢ p'`. -/ theorem tendsto_prod_filter_iff {c : β} : Tendsto (↿F) (p ×ˢ p') (𝓝 c) ↔ TendstoUniformlyOnFilter F (fun _ => c) p p' := by simp_rw [nhds_eq_comap_uniformity, tendsto_comap_iff] rfl /-- Uniform convergence on a set `s` to a constant function is equivalent to convergence in `p ×ˢ 𝓟 s`. -/ theorem tendsto_prod_principal_iff {c : β} : Tendsto (↿F) (p ×ˢ 𝓟 s) (𝓝 c) ↔ TendstoUniformlyOn F (fun _ => c) p s := by rw [tendstoUniformlyOn_iff_tendstoUniformlyOnFilter] exact tendsto_prod_filter_iff /-- Uniform convergence to a constant function is equivalent to convergence in `p ×ˢ ⊤`. -/ theorem tendsto_prod_top_iff {c : β} : Tendsto (↿F) (p ×ˢ ⊤) (𝓝 c) ↔ TendstoUniformly F (fun _ => c) p := by rw [tendstoUniformly_iff_tendstoUniformlyOnFilter] exact tendsto_prod_filter_iff /-- Uniform convergence on the empty set is vacuously true -/ theorem tendstoUniformlyOn_empty : TendstoUniformlyOn F f p ∅ := fun u _ => by simp /-- Uniform convergence on a singleton is equivalent to regular convergence -/ theorem tendstoUniformlyOn_singleton_iff_tendsto : TendstoUniformlyOn F f p {x} ↔ Tendsto (fun n : ι => F n x) p (𝓝 (f x)) := by simp_rw [tendstoUniformlyOn_iff_tendsto, Uniform.tendsto_nhds_right, tendsto_def] exact forall₂_congr fun u _ => by simp [mem_prod_principal, preimage] /-- If a sequence `g` converges to some `b`, then the sequence of constant functions `fun n ↦ fun a ↦ g n` converges to the constant function `fun a ↦ b` on any set `s` -/ theorem Filter.Tendsto.tendstoUniformlyOnFilter_const {g : ι → β} {b : β} (hg : Tendsto g p (𝓝 b)) (p' : Filter α) : TendstoUniformlyOnFilter (fun n : ι => fun _ : α => g n) (fun _ : α => b) p p' := by simpa only [nhds_eq_comap_uniformity, tendsto_comap_iff] using hg.comp (tendsto_fst (g := p')) /-- If a sequence `g` converges to some `b`, then the sequence of constant functions `fun n ↦ fun a ↦ g n` converges to the constant function `fun a ↦ b` on any set `s` -/ theorem Filter.Tendsto.tendstoUniformlyOn_const {g : ι → β} {b : β} (hg : Tendsto g p (𝓝 b)) (s : Set α) : TendstoUniformlyOn (fun n : ι => fun _ : α => g n) (fun _ : α => b) p s := tendstoUniformlyOn_iff_tendstoUniformlyOnFilter.mpr (hg.tendstoUniformlyOnFilter_const (𝓟 s)) theorem UniformContinuousOn.tendstoUniformlyOn [UniformSpace α] [UniformSpace γ] {U : Set α} {V : Set β} {F : α → β → γ} (hF : UniformContinuousOn (↿F) (U ×ˢ V)) (hU : x ∈ U) : TendstoUniformlyOn F (F x) (𝓝[U] x) V := by set φ := fun q : α × β => ((x, q.2), q) rw [tendstoUniformlyOn_iff_tendsto] change Tendsto (Prod.map (↿F) ↿F ∘ φ) (𝓝[U] x ×ˢ 𝓟 V) (𝓤 γ) simp only [nhdsWithin, Filter.prod_eq_inf, comap_inf, inf_assoc, comap_principal, inf_principal] refine hF.comp (Tendsto.inf ?_ <\| tendsto_principal_principal.2 fun x hx => ⟨⟨hU, hx.2⟩, hx⟩) simp only [uniformity_prod_eq_comap_prod, tendsto_comap_iff, (· ∘ ·), nhds_eq_comap_uniformity, comap_comap] exact tendsto_comap.prodMk (tendsto_diag_uniformity _ _) theorem UniformContinuousOn.tendstoUniformly [UniformSpace α] [UniformSpace γ] {U : Set α} (hU : U ∈ 𝓝 x) {F : α → β → γ} (hF : UniformContinuousOn (↿F) (U ×ˢ (univ : Set β))) : TendstoUniformly F (F x) (𝓝 x) := by simpa only [tendstoUniformlyOn_univ, nhdsWithin_eq_nhds.2 hU] using hF.tendstoUniformlyOn (mem_of_mem_nhds hU) theorem UniformContinuous₂.tendstoUniformly [UniformSpace α] [UniformSpace γ] {f : α → β → γ} (h : UniformContinuous₂ f) : TendstoUniformly f (f x) (𝓝 x) := UniformContinuousOn.tendstoUniformly univ_mem <\| by rwa [univ_prod_univ, uniformContinuousOn_univ] /-- A sequence is uniformly Cauchy if eventually all of its pairwise differences are uniformly bounded -/ def UniformCauchySeqOnFilter (F : ι → α → β) (p : Filter ι) (p' : Filter α) : Prop := ∀ u ∈ 𝓤 β, ∀ᶠ m : (ι × ι) × α in (p ×ˢ p) ×ˢ p', (F m.fst.fst m.snd, F m.fst.snd m.snd) ∈ u /-- A sequence is uniformly Cauchy if eventually all of its pairwise differences are uniformly bounded -/ def UniformCauchySeqOn (F : ι → α → β) (p : Filter ι) (s : Set α) : Prop := ∀ u ∈ 𝓤 β, ∀ᶠ m : ι × ι in p ×ˢ p, ∀ x : α, x ∈ s → (F m.fst x, F m.snd x) ∈ u theorem uniformCauchySeqOn_iff_uniformCauchySeqOnFilter : UniformCauchySeqOn F p s ↔ UniformCauchySeqOnFilter F p (𝓟 s) := by simp only [UniformCauchySeqOn, UniformCauchySeqOnFilter] refine forall₂_congr fun u hu => ?_ rw [eventually_prod_principal_iff] theorem UniformCauchySeqOn.uniformCauchySeqOnFilter (hF : UniformCauchySeqOn F p s) : UniformCauchySeqOnFilter F p (𝓟 s) := by rwa [← uniformCauchySeqOn_iff_uniformCauchySeqOnFilter] /-- A sequence that converges uniformly is also uniformly Cauchy -/ theorem TendstoUniformlyOnFilter.uniformCauchySeqOnFilter (hF : TendstoUniformlyOnFilter F f p p') : UniformCauchySeqOnFilter F p p' := by intro u hu rcases comp_symm_of_uniformity hu with ⟨t, ht, htsymm, htmem⟩ have := tendsto_swap4_prod.eventually ((hF t ht).prod_mk (hF t ht)) apply this.diag_of_prod_right.mono simp only [and_imp, Prod.forall] intro n1 n2 x hl hr exact Set.mem_of_mem_of_subset (prodMk_mem_compRel (htsymm hl) hr) htmem /-- A sequence that converges uniformly is also uniformly Cauchy -/ theorem TendstoUniformlyOn.uniformCauchySeqOn (hF : TendstoUniformlyOn F f p s) : UniformCauchySeqOn F p s := uniformCauchySeqOn_iff_uniformCauchySeqOnFilter.mpr hF.tendstoUniformlyOnFilter.uniformCauchySeqOnFilter /-- A uniformly Cauchy sequence converges uniformly to its limit -/ theorem UniformCauchySeqOnFilter.tendstoUniformlyOnFilter_of_tendsto (hF : UniformCauchySeqOnFilter F p p') (hF' : ∀ᶠ x : α in p', Tendsto (fun n => F n x) p (𝓝 (f x))) : TendstoUniformlyOnFilter F f p p' := by rcases p.eq_or_neBot with rfl \| _ · simp only [TendstoUniformlyOnFilter, bot_prod, eventually_bot, implies_true] -- Proof idea: \|f_n(x) - f(x)\| ≤ \|f_n(x) - f_m(x)\| + \|f_m(x) - f(x)\|. We choose `n` -- so that \|f_n(x) - f_m(x)\| is uniformly small across `s` whenever `m ≥ n`. Then for -- a fixed `x`, we choose `m` sufficiently large such that \|f_m(x) - f(x)\| is small. intro u hu rcases comp_symm_of_uniformity hu with ⟨t, ht, htsymm, htmem⟩ -- We will choose n, x, and m simultaneously. n and x come from hF. m comes from hF' -- But we need to promote hF' to the full product filter to use it have hmc : ∀ᶠ x in (p ×ˢ p) ×ˢ p', Tendsto (fun n : ι => F n x.snd) p (𝓝 (f x.snd)) := by rw [eventually_prod_iff] exact ⟨fun _ => True, by simp, _, hF', by simp⟩ -- To apply filter operations we'll need to do some order manipulation rw [Filter.eventually_swap_iff] have := tendsto_prodAssoc.eventually (tendsto_prod_swap.eventually ((hF t ht).and hmc)) apply this.curry.mono simp only [Equiv.prodAssoc_apply, eventually_and, eventually_const, Prod.snd_swap, Prod.fst_swap, and_imp, Prod.forall] -- Complete the proof	intro x n hx hm' refine Set.mem_of_mem_of_subset (mem_compRel.mpr ?_) htmem	Mathlib/Topology/UniformSpace/UniformConvergence.lean	414	415
/- Copyright (c) 2021 Yury Kudryashov. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yury Kudryashov -/ import Mathlib.Analysis.Calculus.BumpFunction.FiniteDimension import Mathlib.Geometry.Manifold.ContMDiff.Atlas import Mathlib.Geometry.Manifold.ContMDiff.NormedSpace import Mathlib.Topology.MetricSpace.ProperSpace.Lemmas /-! # Smooth bump functions on a smooth manifold In this file we define `SmoothBumpFunction I c` to be a bundled smooth "bump" function centered at `c`. It is a structure that consists of two real numbers `0 < rIn < rOut` with small enough `rOut`. We define a coercion to function for this type, and for `f : SmoothBumpFunction I c`, the function `⇑f` written in the extended chart at `c` has the following properties: * `f x = 1` in the closed ball of radius `f.rIn` centered at `c`; * `f x = 0` outside of the ball of radius `f.rOut` centered at `c`; * `0 ≤ f x ≤ 1` for all `x`. The actual statements involve (pre)images under `extChartAt I f` and are given as lemmas in the `SmoothBumpFunction` namespace. ## Tags manifold, smooth bump function -/ universe uE uF uH uM variable {E : Type uE} [NormedAddCommGroup E] [NormedSpace ℝ E] {H : Type uH} [TopologicalSpace H] {I : ModelWithCorners ℝ E H} {M : Type uM} [TopologicalSpace M] [ChartedSpace H M] open Function Filter Module Set Metric open scoped Topology Manifold ContDiff noncomputable section /-! ### Smooth bump function In this section we define a structure for a bundled smooth bump function and prove its properties. -/ variable (I) in /-- Given a smooth manifold modelled on a finite dimensional space `E`, `f : SmoothBumpFunction I M` is a smooth function on `M` such that in the extended chart `e` at `f.c`: * `f x = 1` in the closed ball of radius `f.rIn` centered at `f.c`; * `f x = 0` outside of the ball of radius `f.rOut` centered at `f.c`; * `0 ≤ f x ≤ 1` for all `x`. The structure contains data required to construct a function with these properties. The function is available as `⇑f` or `f x`. Formal statements of the properties listed above involve some (pre)images under `extChartAt I f.c` and are given as lemmas in the `SmoothBumpFunction` namespace. -/ structure SmoothBumpFunction (c : M) extends ContDiffBump (extChartAt I c c) where closedBall_subset : closedBall (extChartAt I c c) rOut ∩ range I ⊆ (extChartAt I c).target namespace SmoothBumpFunction section FiniteDimensional variable [FiniteDimensional ℝ E] variable {c : M} (f : SmoothBumpFunction I c) {x : M} /-- The function defined by `f : SmoothBumpFunction c`. Use automatic coercion to function instead. -/ @[coe] def toFun : M → ℝ := indicator (chartAt H c).source (f.toContDiffBump ∘ extChartAt I c) instance : CoeFun (SmoothBumpFunction I c) fun _ => M → ℝ := ⟨toFun⟩ theorem coe_def : ⇑f = indicator (chartAt H c).source (f.toContDiffBump ∘ extChartAt I c) := rfl end FiniteDimensional variable {c : M} (f : SmoothBumpFunction I c) {x : M} theorem rOut_pos : 0 < f.rOut := f.toContDiffBump.rOut_pos theorem ball_subset : ball (extChartAt I c c) f.rOut ∩ range I ⊆ (extChartAt I c).target := Subset.trans (inter_subset_inter_left _ ball_subset_closedBall) f.closedBall_subset theorem ball_inter_range_eq_ball_inter_target : ball (extChartAt I c c) f.rOut ∩ range I = ball (extChartAt I c c) f.rOut ∩ (extChartAt I c).target := (subset_inter inter_subset_left f.ball_subset).antisymm <\| inter_subset_inter_right _ <\| extChartAt_target_subset_range _ section FiniteDimensional variable [FiniteDimensional ℝ E] theorem eqOn_source : EqOn f (f.toContDiffBump ∘ extChartAt I c) (chartAt H c).source := eqOn_indicator theorem eventuallyEq_of_mem_source (hx : x ∈ (chartAt H c).source) : f =ᶠ[𝓝 x] f.toContDiffBump ∘ extChartAt I c := f.eqOn_source.eventuallyEq_of_mem <\| (chartAt H c).open_source.mem_nhds hx theorem one_of_dist_le (hs : x ∈ (chartAt H c).source) (hd : dist (extChartAt I c x) (extChartAt I c c) ≤ f.rIn) : f x = 1 := by simp only [f.eqOn_source hs, (· ∘ ·), f.one_of_mem_closedBall hd] theorem support_eq_inter_preimage : support f = (chartAt H c).source ∩ extChartAt I c ⁻¹' ball (extChartAt I c c) f.rOut := by rw [coe_def, support_indicator, support_comp_eq_preimage, ← extChartAt_source I, ← (extChartAt I c).symm_image_target_inter_eq', ← (extChartAt I c).symm_image_target_inter_eq',	f.support_eq] theorem isOpen_support : IsOpen (support f) := by	Mathlib/Geometry/Manifold/BumpFunction.lean	119	121
/- Copyright (c) 2020 Floris van Doorn. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Floris van Doorn, Sébastien Gouëzel -/ import Mathlib.MeasureTheory.Measure.Haar.InnerProductSpace import Mathlib.MeasureTheory.Measure.Lebesgue.EqHaar import Mathlib.MeasureTheory.Integral.Bochner.Set /-! # Basic properties of Haar measures on real vector spaces -/ noncomputable section open Function Filter Inv MeasureTheory.Measure Module Set TopologicalSpace open scoped NNReal ENNReal Pointwise Topology namespace MeasureTheory namespace Measure /- The instance `MeasureTheory.Measure.IsAddHaarMeasure.noAtoms` applies in particular to show that an additive Haar measure on a nontrivial finite-dimensional real vector space has no atom. -/ example {E : Type} [NormedAddCommGroup E] [NormedSpace ℝ E] [Nontrivial E] [FiniteDimensional ℝ E] [MeasurableSpace E] [BorelSpace E] (μ : Measure E) [IsAddHaarMeasure μ] : NoAtoms μ := by infer_instance section LinearEquiv variable {𝕜 G H : Type} [MeasurableSpace G] [MeasurableSpace H] [NontriviallyNormedField 𝕜] [TopologicalSpace G] [TopologicalSpace H] [AddCommGroup G] [AddCommGroup H] [IsTopologicalAddGroup G] [IsTopologicalAddGroup H] [Module 𝕜 G] [Module 𝕜 H] (μ : Measure G) [IsAddHaarMeasure μ] [BorelSpace G] [BorelSpace H] [CompleteSpace 𝕜] [T2Space G] [FiniteDimensional 𝕜 G] [ContinuousSMul 𝕜 G] [ContinuousSMul 𝕜 H] [T2Space H] instance MapLinearEquiv.isAddHaarMeasure (e : G ≃ₗ[𝕜] H) : IsAddHaarMeasure (μ.map e) := e.toContinuousLinearEquiv.isAddHaarMeasure_map _ end LinearEquiv section SeminormedGroup variable {G H : Type} [MeasurableSpace G] [Group G] [TopologicalSpace G] [IsTopologicalGroup G] [BorelSpace G] [LocallyCompactSpace G] [MeasurableSpace H] [SeminormedGroup H] [OpensMeasurableSpace H] -- TODO: This could be streamlined by proving that inner regular measures always exist open Metric Bornology in @[to_additive] lemma _root_.MonoidHom.exists_nhds_isBounded (f : G → H) (hf : Measurable f) (x : G) : ∃ s ∈ 𝓝 x, IsBounded (f '' s) := by let K : PositiveCompacts G := Classical.arbitrary _ obtain ⟨n, hn⟩ : ∃ n : ℕ, 0 < haar (interior K ∩ f ⁻¹' ball 1 n) := by by_contra! simp_rw [nonpos_iff_eq_zero, ← measure_iUnion_null_iff, ← inter_iUnion, ← preimage_iUnion, iUnion_ball_nat, preimage_univ, inter_univ] at this exact this.not_gt <\| isOpen_interior.measure_pos _ K.interior_nonempty rw [← one_mul x, ← op_smul_eq_mul] refine ⟨_, smul_mem_nhds_smul _ <\| div_mem_nhds_one_of_haar_pos_ne_top haar _ (isOpen_interior.measurableSet.inter <\| hf measurableSet_ball) hn <\| mt (measure_mono_top <\| inter_subset_left.trans interior_subset) K.isCompact.measure_ne_top, ?_⟩ have : Bornology.IsBounded (f '' (interior K ∩ f ⁻¹' ball 1 n)) := isBounded_ball.subset <\| (image_mono inter_subset_right).trans <\| image_preimage_subset _ _ rw [image_op_smul_distrib, image_div] exact (this.div this).smul _ end SeminormedGroup /-- A Borel-measurable group hom from a locally compact normed group to a real normed space is continuous. -/ lemma AddMonoidHom.continuous_of_measurable {G H : Type} [SeminormedAddCommGroup G] [MeasurableSpace G] [BorelSpace G] [LocallyCompactSpace G] [SeminormedAddCommGroup H] [MeasurableSpace H] [OpensMeasurableSpace H] [NormedSpace ℝ H] (f : G →+ H) (hf : Measurable f) : Continuous f := let ⟨_s, hs, hbdd⟩ := f.exists_nhds_isBounded hf 0; f.continuous_of_isBounded_nhds_zero hs hbdd variable {E : Type} [NormedAddCommGroup E] [NormedSpace ℝ E] [MeasurableSpace E] [BorelSpace E] [FiniteDimensional ℝ E] (μ : Measure E) [IsAddHaarMeasure μ] {F : Type*} [NormedAddCommGroup F] [NormedSpace ℝ F] /-- The integral of `f (R • x)` with respect to an additive Haar measure is a multiple of the integral of `f`. The formula we give works even when `f` is not integrable or `R = 0` thanks to the convention that a non-integrable function has integral zero. -/ theorem integral_comp_smul (f : E → F) (R : ℝ) : ∫ x, f (R • x) ∂μ = \|(R ^ finrank ℝ E)⁻¹\| • ∫ x, f x ∂μ := by by_cases hF : CompleteSpace F; swap · simp [integral, hF] rcases eq_or_ne R 0 with (rfl \| hR) · simp only [zero_smul, integral_const] rcases Nat.eq_zero_or_pos (finrank ℝ E) with (hE \| hE) · have : Subsingleton E := finrank_zero_iff.1 hE have : f = fun _ => f 0 := by ext x; rw [Subsingleton.elim x 0] conv_rhs => rw [this] simp only [hE, pow_zero, inv_one, abs_one, one_smul, integral_const] · have : Nontrivial E := finrank_pos_iff.1 hE simp [zero_pow hE.ne', measure_univ_of_isAddLeftInvariant, measureReal_def] · calc (∫ x, f (R • x) ∂μ) = ∫ y, f y ∂Measure.map (fun x => R • x) μ := (integral_map_equiv (Homeomorph.smul (isUnit_iff_ne_zero.2 hR).unit).toMeasurableEquiv f).symm _ = \|(R ^ finrank ℝ E)⁻¹\| • ∫ x, f x ∂μ := by simp only [map_addHaar_smul μ hR, integral_smul_measure, ENNReal.toReal_ofReal, abs_nonneg] /-- The integral of `f (R • x)` with respect to an additive Haar measure is a multiple of the integral of `f`. The formula we give works even when `f` is not integrable or `R = 0` thanks to the convention that a non-integrable function has integral zero. -/	theorem integral_comp_smul_of_nonneg (f : E → F) (R : ℝ) {hR : 0 ≤ R} : ∫ x, f (R • x) ∂μ = (R ^ finrank ℝ E)⁻¹ • ∫ x, f x ∂μ := by rw [integral_comp_smul μ f R, abs_of_nonneg (inv_nonneg.2 (pow_nonneg hR _))] /-- The integral of `f (R⁻¹ • x)` with respect to an additive Haar measure is a multiple of the integral of `f`. The formula we give works even when `f` is not integrable or `R = 0` thanks to the convention that a non-integrable function has integral zero. -/ theorem integral_comp_inv_smul (f : E → F) (R : ℝ) : ∫ x, f (R⁻¹ • x) ∂μ = \|R ^ finrank ℝ E\| • ∫ x, f x ∂μ := by rw [integral_comp_smul μ f R⁻¹, inv_pow, inv_inv] /-- The integral of `f (R⁻¹ • x)` with respect to an additive Haar measure is a multiple of the integral of `f`. The formula we give works even when `f` is not integrable or `R = 0` thanks to the convention that a non-integrable function has integral zero. -/	Mathlib/MeasureTheory/Measure/Haar/NormedSpace.lean	110	123
/- Copyright (c) 2018 Kim Morrison. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Reid Barton, Mario Carneiro, Kim Morrison, Floris van Doorn -/ import Mathlib.CategoryTheory.Limits.IsLimit import Mathlib.CategoryTheory.Category.ULift import Mathlib.CategoryTheory.EssentiallySmall import Mathlib.CategoryTheory.Functor.EpiMono import Mathlib.Logic.Equiv.Basic /-! # Existence of limits and colimits In `CategoryTheory.Limits.IsLimit` we defined `IsLimit c`, the data showing that a cone `c` is a limit cone. The two main structures defined in this file are: * `LimitCone F`, which consists of a choice of cone for `F` and the fact it is a limit cone, and * `HasLimit F`, asserting the mere existence of some limit cone for `F`. `HasLimit` is a propositional typeclass (it's important that it is a proposition merely asserting the existence of a limit, as otherwise we would have non-defeq problems from incompatible instances). While `HasLimit` only asserts the existence of a limit cone, we happily use the axiom of choice in mathlib, so there are convenience functions all depending on `HasLimit F`: * `limit F : C`, producing some limit object (of course all such are isomorphic) * `limit.π F j : limit F ⟶ F.obj j`, the morphisms out of the limit, * `limit.lift F c : c.pt ⟶ limit F`, the universal morphism from any other `c : Cone F`, etc. Key to using the `HasLimit` interface is that there is an `@[ext]` lemma stating that to check `f = g`, for `f g : Z ⟶ limit F`, it suffices to check `f ≫ limit.π F j = g ≫ limit.π F j` for every `j`. This, combined with `@[simp]` lemmas, makes it possible to prove many easy facts about limits using automation (e.g. `tidy`). There are abbreviations `HasLimitsOfShape J C` and `HasLimits C` asserting the existence of classes of limits. Later more are introduced, for finite limits, special shapes of limits, etc. Ideally, many results about limits should be stated first in terms of `IsLimit`, and then a result in terms of `HasLimit` derived from this. At this point, however, this is far from uniformly achieved in mathlib --- often statements are only written in terms of `HasLimit`. ## Implementation At present we simply say everything twice, in order to handle both limits and colimits. It would be highly desirable to have some automation support, e.g. a `@[dualize]` attribute that behaves similarly to `@[to_additive]`. ## References * [Stacks: Limits and colimits](https://stacks.math.columbia.edu/tag/002D) -/ noncomputable section open CategoryTheory CategoryTheory.Category CategoryTheory.Functor Opposite namespace CategoryTheory.Limits -- morphism levels before object levels. See note [CategoryTheory universes]. universe v₁ u₁ v₂ u₂ v₃ u₃ v v' v'' u u' u'' variable {J : Type u₁} [Category.{v₁} J] {K : Type u₂} [Category.{v₂} K] variable {C : Type u} [Category.{v} C] variable {F : J ⥤ C} section Limit /-- `LimitCone F` contains a cone over `F` together with the information that it is a limit. -/ structure LimitCone (F : J ⥤ C) where /-- The cone itself -/ cone : Cone F /-- The proof that is the limit cone -/ isLimit : IsLimit cone /-- `HasLimit F` represents the mere existence of a limit for `F`. -/ class HasLimit (F : J ⥤ C) : Prop where mk' :: /-- There is some limit cone for `F` -/ exists_limit : Nonempty (LimitCone F) theorem HasLimit.mk {F : J ⥤ C} (d : LimitCone F) : HasLimit F := ⟨Nonempty.intro d⟩ /-- Use the axiom of choice to extract explicit `LimitCone F` from `HasLimit F`. -/ def getLimitCone (F : J ⥤ C) [HasLimit F] : LimitCone F := Classical.choice <\| HasLimit.exists_limit variable (J C) /-- `C` has limits of shape `J` if there exists a limit for every functor `F : J ⥤ C`. -/ class HasLimitsOfShape : Prop where /-- All functors `F : J ⥤ C` from `J` have limits -/ has_limit : ∀ F : J ⥤ C, HasLimit F := by infer_instance /-- `C` has all limits of size `v₁ u₁` (`HasLimitsOfSize.{v₁ u₁} C`) if it has limits of every shape `J : Type u₁` with `[Category.{v₁} J]`. -/ @[pp_with_univ] class HasLimitsOfSize (C : Type u) [Category.{v} C] : Prop where /-- All functors `F : J ⥤ C` from all small `J` have limits -/ has_limits_of_shape : ∀ (J : Type u₁) [Category.{v₁} J], HasLimitsOfShape J C := by infer_instance /-- `C` has all (small) limits if it has limits of every shape that is as big as its hom-sets. -/ abbrev HasLimits (C : Type u) [Category.{v} C] : Prop := HasLimitsOfSize.{v, v} C theorem HasLimits.has_limits_of_shape {C : Type u} [Category.{v} C] [HasLimits C] (J : Type v) [Category.{v} J] : HasLimitsOfShape J C := HasLimitsOfSize.has_limits_of_shape J variable {J C} -- see Note [lower instance priority] instance (priority := 100) hasLimitOfHasLimitsOfShape {J : Type u₁} [Category.{v₁} J] [HasLimitsOfShape J C] (F : J ⥤ C) : HasLimit F := HasLimitsOfShape.has_limit F -- see Note [lower instance priority] instance (priority := 100) hasLimitsOfShapeOfHasLimits {J : Type u₁} [Category.{v₁} J] [HasLimitsOfSize.{v₁, u₁} C] : HasLimitsOfShape J C := HasLimitsOfSize.has_limits_of_shape J -- Interface to the `HasLimit` class. /-- An arbitrary choice of limit cone for a functor. -/ def limit.cone (F : J ⥤ C) [HasLimit F] : Cone F := (getLimitCone F).cone /-- An arbitrary choice of limit object of a functor. -/ def limit (F : J ⥤ C) [HasLimit F] := (limit.cone F).pt /-- The projection from the limit object to a value of the functor. -/ def limit.π (F : J ⥤ C) [HasLimit F] (j : J) : limit F ⟶ F.obj j := (limit.cone F).π.app j @[reassoc] theorem limit.π_comp_eqToHom (F : J ⥤ C) [HasLimit F] {j j' : J} (hj : j = j') : limit.π F j ≫ eqToHom (by subst hj; rfl) = limit.π F j' := by subst hj simp @[simp] theorem limit.cone_x {F : J ⥤ C} [HasLimit F] : (limit.cone F).pt = limit F := rfl @[simp] theorem limit.cone_π {F : J ⥤ C} [HasLimit F] : (limit.cone F).π.app = limit.π _ := rfl @[reassoc (attr := simp)] theorem limit.w (F : J ⥤ C) [HasLimit F] {j j' : J} (f : j ⟶ j') : limit.π F j ≫ F.map f = limit.π F j' := (limit.cone F).w f /-- Evidence that the arbitrary choice of cone provided by `limit.cone F` is a limit cone. -/ def limit.isLimit (F : J ⥤ C) [HasLimit F] : IsLimit (limit.cone F) := (getLimitCone F).isLimit /-- The morphism from the cone point of any other cone to the limit object. -/ def limit.lift (F : J ⥤ C) [HasLimit F] (c : Cone F) : c.pt ⟶ limit F := (limit.isLimit F).lift c @[simp] theorem limit.isLimit_lift {F : J ⥤ C} [HasLimit F] (c : Cone F) : (limit.isLimit F).lift c = limit.lift F c := rfl @[reassoc (attr := simp)] theorem limit.lift_π {F : J ⥤ C} [HasLimit F] (c : Cone F) (j : J) : limit.lift F c ≫ limit.π F j = c.π.app j := IsLimit.fac _ c j /-- Functoriality of limits. Usually this morphism should be accessed through `lim.map`, but may be needed separately when you have specified limits for the source and target functors, but not necessarily for all functors of shape `J`. -/ def limMap {F G : J ⥤ C} [HasLimit F] [HasLimit G] (α : F ⟶ G) : limit F ⟶ limit G := IsLimit.map _ (limit.isLimit G) α @[reassoc (attr := simp)] theorem limMap_π {F G : J ⥤ C} [HasLimit F] [HasLimit G] (α : F ⟶ G) (j : J) : limMap α ≫ limit.π G j = limit.π F j ≫ α.app j := limit.lift_π _ j /-- The cone morphism from any cone to the arbitrary choice of limit cone. -/ def limit.coneMorphism {F : J ⥤ C} [HasLimit F] (c : Cone F) : c ⟶ limit.cone F := (limit.isLimit F).liftConeMorphism c @[simp] theorem limit.coneMorphism_hom {F : J ⥤ C} [HasLimit F] (c : Cone F) : (limit.coneMorphism c).hom = limit.lift F c := rfl theorem limit.coneMorphism_π {F : J ⥤ C} [HasLimit F] (c : Cone F) (j : J) : (limit.coneMorphism c).hom ≫ limit.π F j = c.π.app j := by simp @[reassoc (attr := simp)] theorem limit.conePointUniqueUpToIso_hom_comp {F : J ⥤ C} [HasLimit F] {c : Cone F} (hc : IsLimit c) (j : J) : (IsLimit.conePointUniqueUpToIso hc (limit.isLimit _)).hom ≫ limit.π F j = c.π.app j := IsLimit.conePointUniqueUpToIso_hom_comp _ _ _ @[reassoc (attr := simp)] theorem limit.conePointUniqueUpToIso_inv_comp {F : J ⥤ C} [HasLimit F] {c : Cone F} (hc : IsLimit c) (j : J) : (IsLimit.conePointUniqueUpToIso (limit.isLimit _) hc).inv ≫ limit.π F j = c.π.app j := IsLimit.conePointUniqueUpToIso_inv_comp _ _ _ theorem limit.existsUnique {F : J ⥤ C} [HasLimit F] (t : Cone F) : ∃! l : t.pt ⟶ limit F, ∀ j, l ≫ limit.π F j = t.π.app j := (limit.isLimit F).existsUnique _ /-- Given any other limit cone for `F`, the chosen `limit F` is isomorphic to the cone point. -/ def limit.isoLimitCone {F : J ⥤ C} [HasLimit F] (t : LimitCone F) : limit F ≅ t.cone.pt := IsLimit.conePointUniqueUpToIso (limit.isLimit F) t.isLimit @[reassoc (attr := simp)] theorem limit.isoLimitCone_hom_π {F : J ⥤ C} [HasLimit F] (t : LimitCone F) (j : J) : (limit.isoLimitCone t).hom ≫ t.cone.π.app j = limit.π F j := by dsimp [limit.isoLimitCone, IsLimit.conePointUniqueUpToIso] simp @[reassoc (attr := simp)] theorem limit.isoLimitCone_inv_π {F : J ⥤ C} [HasLimit F] (t : LimitCone F) (j : J) : (limit.isoLimitCone t).inv ≫ limit.π F j = t.cone.π.app j := by dsimp [limit.isoLimitCone, IsLimit.conePointUniqueUpToIso] simp @[ext] theorem limit.hom_ext {F : J ⥤ C} [HasLimit F] {X : C} {f f' : X ⟶ limit F} (w : ∀ j, f ≫ limit.π F j = f' ≫ limit.π F j) : f = f' := (limit.isLimit F).hom_ext w @[reassoc (attr := simp)] theorem limit.lift_map {F G : J ⥤ C} [HasLimit F] [HasLimit G] (c : Cone F) (α : F ⟶ G) : limit.lift F c ≫ limMap α = limit.lift G ((Cones.postcompose α).obj c) := by ext rw [assoc, limMap_π, limit.lift_π_assoc, limit.lift_π] rfl @[simp] theorem limit.lift_cone {F : J ⥤ C} [HasLimit F] : limit.lift F (limit.cone F) = 𝟙 (limit F) := (limit.isLimit _).lift_self /-- The isomorphism (in `Type`) between morphisms from a specified object `W` to the limit object, and cones with cone point `W`. -/ def limit.homIso (F : J ⥤ C) [HasLimit F] (W : C) : ULift.{u₁} (W ⟶ limit F : Type v) ≅ F.cones.obj (op W) := (limit.isLimit F).homIso W @[simp] theorem limit.homIso_hom (F : J ⥤ C) [HasLimit F] {W : C} (f : ULift (W ⟶ limit F)) : (limit.homIso F W).hom f = (const J).map f.down ≫ (limit.cone F).π := (limit.isLimit F).homIso_hom f /-- The isomorphism (in `Type`) between morphisms from a specified object `W` to the limit object, and an explicit componentwise description of cones with cone point `W`. -/ def limit.homIso' (F : J ⥤ C) [HasLimit F] (W : C) : ULift.{u₁} (W ⟶ limit F : Type v) ≅ { p : ∀ j, W ⟶ F.obj j // ∀ {j j' : J} (f : j ⟶ j'), p j ≫ F.map f = p j' } := (limit.isLimit F).homIso' W theorem limit.lift_extend {F : J ⥤ C} [HasLimit F] (c : Cone F) {X : C} (f : X ⟶ c.pt) : limit.lift F (c.extend f) = f ≫ limit.lift F c := by aesop_cat /-- If a functor `F` has a limit, so does any naturally isomorphic functor. -/ theorem hasLimit_of_iso {F G : J ⥤ C} [HasLimit F] (α : F ≅ G) : HasLimit G := HasLimit.mk { cone := (Cones.postcompose α.hom).obj (limit.cone F) isLimit := (IsLimit.postcomposeHomEquiv _ _).symm (limit.isLimit F) } @[deprecated (since := "2025-03-03")] alias hasLimitOfIso := hasLimit_of_iso theorem hasLimit_iff_of_iso {F G : J ⥤ C} (α : F ≅ G) : HasLimit F ↔ HasLimit G := ⟨fun _ ↦ hasLimit_of_iso α, fun _ ↦ hasLimit_of_iso α.symm⟩ -- See the construction of limits from products and equalizers -- for an example usage. /-- If a functor `G` has the same collection of cones as a functor `F` which has a limit, then `G` also has a limit. -/ theorem HasLimit.ofConesIso {J K : Type u₁} [Category.{v₁} J] [Category.{v₂} K] (F : J ⥤ C) (G : K ⥤ C) (h : F.cones ≅ G.cones) [HasLimit F] : HasLimit G := HasLimit.mk ⟨_, IsLimit.ofNatIso (IsLimit.natIso (limit.isLimit F) ≪≫ h)⟩ /-- The limits of `F : J ⥤ C` and `G : J ⥤ C` are isomorphic, if the functors are naturally isomorphic. -/ def HasLimit.isoOfNatIso {F G : J ⥤ C} [HasLimit F] [HasLimit G] (w : F ≅ G) : limit F ≅ limit G := IsLimit.conePointsIsoOfNatIso (limit.isLimit F) (limit.isLimit G) w @[reassoc (attr := simp)] theorem HasLimit.isoOfNatIso_hom_π {F G : J ⥤ C} [HasLimit F] [HasLimit G] (w : F ≅ G) (j : J) : (HasLimit.isoOfNatIso w).hom ≫ limit.π G j = limit.π F j ≫ w.hom.app j := IsLimit.conePointsIsoOfNatIso_hom_comp _ _ _ _ @[reassoc (attr := simp)] theorem HasLimit.isoOfNatIso_inv_π {F G : J ⥤ C} [HasLimit F] [HasLimit G] (w : F ≅ G) (j : J) : (HasLimit.isoOfNatIso w).inv ≫ limit.π F j = limit.π G j ≫ w.inv.app j := IsLimit.conePointsIsoOfNatIso_inv_comp _ _ _ _ @[reassoc (attr := simp)] theorem HasLimit.lift_isoOfNatIso_hom {F G : J ⥤ C} [HasLimit F] [HasLimit G] (t : Cone F) (w : F ≅ G) : limit.lift F t ≫ (HasLimit.isoOfNatIso w).hom = limit.lift G ((Cones.postcompose w.hom).obj _) := IsLimit.lift_comp_conePointsIsoOfNatIso_hom _ _ _ @[reassoc (attr := simp)] theorem HasLimit.lift_isoOfNatIso_inv {F G : J ⥤ C} [HasLimit F] [HasLimit G] (t : Cone G) (w : F ≅ G) : limit.lift G t ≫ (HasLimit.isoOfNatIso w).inv = limit.lift F ((Cones.postcompose w.inv).obj _) := IsLimit.lift_comp_conePointsIsoOfNatIso_inv _ _ _ /-- The limits of `F : J ⥤ C` and `G : K ⥤ C` are isomorphic, if there is an equivalence `e : J ≌ K` making the triangle commute up to natural isomorphism. -/ def HasLimit.isoOfEquivalence {F : J ⥤ C} [HasLimit F] {G : K ⥤ C} [HasLimit G] (e : J ≌ K) (w : e.functor ⋙ G ≅ F) : limit F ≅ limit G := IsLimit.conePointsIsoOfEquivalence (limit.isLimit F) (limit.isLimit G) e w @[simp] theorem HasLimit.isoOfEquivalence_hom_π {F : J ⥤ C} [HasLimit F] {G : K ⥤ C} [HasLimit G] (e : J ≌ K) (w : e.functor ⋙ G ≅ F) (k : K) : (HasLimit.isoOfEquivalence e w).hom ≫ limit.π G k = limit.π F (e.inverse.obj k) ≫ w.inv.app (e.inverse.obj k) ≫ G.map (e.counit.app k) := by simp only [HasLimit.isoOfEquivalence, IsLimit.conePointsIsoOfEquivalence_hom] dsimp simp @[simp] theorem HasLimit.isoOfEquivalence_inv_π {F : J ⥤ C} [HasLimit F] {G : K ⥤ C} [HasLimit G] (e : J ≌ K) (w : e.functor ⋙ G ≅ F) (j : J) : (HasLimit.isoOfEquivalence e w).inv ≫ limit.π F j = limit.π G (e.functor.obj j) ≫ w.hom.app j := by simp only [HasLimit.isoOfEquivalence, IsLimit.conePointsIsoOfEquivalence_hom] dsimp simp section Pre variable (F) variable [HasLimit F] (E : K ⥤ J) [HasLimit (E ⋙ F)] /-- The canonical morphism from the limit of `F` to the limit of `E ⋙ F`. -/ def limit.pre : limit F ⟶ limit (E ⋙ F) := limit.lift (E ⋙ F) ((limit.cone F).whisker E) @[reassoc (attr := simp)] theorem limit.pre_π (k : K) : limit.pre F E ≫ limit.π (E ⋙ F) k = limit.π F (E.obj k) := by erw [IsLimit.fac] rfl @[simp] theorem limit.lift_pre (c : Cone F) : limit.lift F c ≫ limit.pre F E = limit.lift (E ⋙ F) (c.whisker E) := by ext; simp variable {L : Type u₃} [Category.{v₃} L] variable (D : L ⥤ K) @[simp] theorem limit.pre_pre [h : HasLimit (D ⋙ E ⋙ F)] : haveI : HasLimit ((D ⋙ E) ⋙ F) := h limit.pre F E ≫ limit.pre (E ⋙ F) D = limit.pre F (D ⋙ E) := by haveI : HasLimit ((D ⋙ E) ⋙ F) := h ext j; erw [assoc, limit.pre_π, limit.pre_π, limit.pre_π]; rfl variable {E F} /-- - If we have particular limit cones available for `E ⋙ F` and for `F`, we obtain a formula for `limit.pre F E`. -/ theorem limit.pre_eq (s : LimitCone (E ⋙ F)) (t : LimitCone F) : limit.pre F E = (limit.isoLimitCone t).hom ≫ s.isLimit.lift (t.cone.whisker E) ≫ (limit.isoLimitCone s).inv := by aesop_cat end Pre section Post variable {D : Type u'} [Category.{v'} D] variable (F : J ⥤ C) [HasLimit F] (G : C ⥤ D) [HasLimit (F ⋙ G)] /-- The canonical morphism from `G` applied to the limit of `F` to the limit of `F ⋙ G`. -/ def limit.post : G.obj (limit F) ⟶ limit (F ⋙ G) := limit.lift (F ⋙ G) (G.mapCone (limit.cone F)) @[reassoc (attr := simp)] theorem limit.post_π (j : J) : limit.post F G ≫ limit.π (F ⋙ G) j = G.map (limit.π F j) := by erw [IsLimit.fac] rfl @[simp] theorem limit.lift_post (c : Cone F) : G.map (limit.lift F c) ≫ limit.post F G = limit.lift (F ⋙ G) (G.mapCone c) := by ext rw [assoc, limit.post_π, ← G.map_comp, limit.lift_π, limit.lift_π] rfl @[simp] theorem limit.post_post {E : Type u''} [Category.{v''} E] (H : D ⥤ E) [h : HasLimit ((F ⋙ G) ⋙ H)] : -- H G (limit F) ⟶ H (limit (F ⋙ G)) ⟶ limit ((F ⋙ G) ⋙ H) equals -- H G (limit F) ⟶ limit (F ⋙ (G ⋙ H)) haveI : HasLimit (F ⋙ G ⋙ H) := h H.map (limit.post F G) ≫ limit.post (F ⋙ G) H = limit.post F (G ⋙ H) := by haveI : HasLimit (F ⋙ G ⋙ H) := h ext; erw [assoc, limit.post_π, ← H.map_comp, limit.post_π, limit.post_π]; rfl end Post theorem limit.pre_post {D : Type u'} [Category.{v'} D] (E : K ⥤ J) (F : J ⥤ C) (G : C ⥤ D) [HasLimit F] [HasLimit (E ⋙ F)] [HasLimit (F ⋙ G)] [h : HasLimit ((E ⋙ F) ⋙ G)] :-- G (limit F) ⟶ G (limit (E ⋙ F)) ⟶ limit ((E ⋙ F) ⋙ G) vs -- G (limit F) ⟶ limit F ⋙ G ⟶ limit (E ⋙ (F ⋙ G)) or haveI : HasLimit (E ⋙ F ⋙ G) := h G.map (limit.pre F E) ≫ limit.post (E ⋙ F) G = limit.post F G ≫ limit.pre (F ⋙ G) E := by haveI : HasLimit (E ⋙ F ⋙ G) := h ext; erw [assoc, limit.post_π, ← G.map_comp, limit.pre_π, assoc, limit.pre_π, limit.post_π] open CategoryTheory.Equivalence instance hasLimitEquivalenceComp (e : K ≌ J) [HasLimit F] : HasLimit (e.functor ⋙ F) := HasLimit.mk { cone := Cone.whisker e.functor (limit.cone F) isLimit := IsLimit.whiskerEquivalence (limit.isLimit F) e } -- not entirely sure why this is needed /-- If a `E ⋙ F` has a limit, and `E` is an equivalence, we can construct a limit of `F`. -/ theorem hasLimitOfEquivalenceComp (e : K ≌ J) [HasLimit (e.functor ⋙ F)] : HasLimit F := by haveI : HasLimit (e.inverse ⋙ e.functor ⋙ F) := Limits.hasLimitEquivalenceComp e.symm apply hasLimit_of_iso (e.invFunIdAssoc F) -- `hasLimitCompEquivalence` and `hasLimitOfCompEquivalence` -- are proved in `CategoryTheory/Adjunction/Limits.lean`. section LimFunctor variable [HasLimitsOfShape J C] section /-- `limit F` is functorial in `F`, when `C` has all limits of shape `J`. -/ @[simps] def lim : (J ⥤ C) ⥤ C where obj F := limit F map α := limMap α map_id F := by apply Limits.limit.hom_ext; intro j simp map_comp α β := by apply Limits.limit.hom_ext; intro j simp [assoc] end variable {G : J ⥤ C} (α : F ⟶ G) theorem limMap_eq : limMap α = lim.map α := rfl theorem limit.map_pre [HasLimitsOfShape K C] (E : K ⥤ J) : lim.map α ≫ limit.pre G E = limit.pre F E ≫ lim.map (whiskerLeft E α) := by ext simp theorem limit.map_pre' [HasLimitsOfShape K C] (F : J ⥤ C) {E₁ E₂ : K ⥤ J} (α : E₁ ⟶ E₂) : limit.pre F E₂ = limit.pre F E₁ ≫ lim.map (whiskerRight α F) := by ext1; simp [← category.assoc] theorem limit.id_pre (F : J ⥤ C) : limit.pre F (𝟭 _) = lim.map (Functor.leftUnitor F).inv := by aesop_cat theorem limit.map_post {D : Type u'} [Category.{v'} D] [HasLimitsOfShape J D] (H : C ⥤ D) : /- H (limit F) ⟶ H (limit G) ⟶ limit (G ⋙ H) vs H (limit F) ⟶ limit (F ⋙ H) ⟶ limit (G ⋙ H) -/ H.map (limMap α) ≫ limit.post G H = limit.post F H ≫ limMap (whiskerRight α H) := by ext simp only [whiskerRight_app, limMap_π, assoc, limit.post_π_assoc, limit.post_π, ← H.map_comp] /-- The isomorphism between morphisms from `W` to the cone point of the limit cone for `F` and cones over `F` with cone point `W` is natural in `F`. -/ def limYoneda : lim ⋙ yoneda ⋙ (whiskeringRight _ _ _).obj uliftFunctor.{u₁} ≅ CategoryTheory.cones J C := NatIso.ofComponents fun F => NatIso.ofComponents fun W => limit.homIso F (unop W) /-- The constant functor and limit functor are adjoint to each other -/ def constLimAdj : (const J : C ⥤ J ⥤ C) ⊣ lim := Adjunction.mk' { homEquiv := fun c g ↦ { toFun := fun f => limit.lift _ ⟨c, f⟩ invFun := fun f => { app := fun _ => f ≫ limit.π _ _ } left_inv := by aesop_cat right_inv := by aesop_cat } unit := { app := fun _ => limit.lift _ ⟨_, 𝟙 _⟩ } counit := { app := fun g => { app := limit.π _ } } } instance : IsRightAdjoint (lim : (J ⥤ C) ⥤ C) := ⟨_, ⟨constLimAdj⟩⟩ end LimFunctor instance limMap_mono' {F G : J ⥤ C} [HasLimitsOfShape J C] (α : F ⟶ G) [Mono α] : Mono (limMap α) := (lim : (J ⥤ C) ⥤ C).map_mono α instance limMap_mono {F G : J ⥤ C} [HasLimit F] [HasLimit G] (α : F ⟶ G) [∀ j, Mono (α.app j)] : Mono (limMap α) := ⟨fun {Z} u v h => limit.hom_ext fun j => (cancel_mono (α.app j)).1 <\| by simpa using h =≫ limit.π _ j⟩ section Adjunction variable {L : (J ⥤ C) ⥤ C} (adj : Functor.const _ ⊣ L) /- The fact that the existence of limits of shape `J` is equivalent to the existence of a right adjoint to the constant functor `C ⥤ (J ⥤ C)` is obtained in the file `Mathlib.CategoryTheory.Limits.ConeCategory`: see the lemma `hasLimitsOfShape_iff_isLeftAdjoint_const`. In the definitions below, given an adjunction `adj : Functor.const _ ⊣ (L : (J ⥤ C) ⥤ C)`, we directly construct a limit cone for any `F : J ⥤ C`. -/ /-- The limit cone obtained from a right adjoint of the constant functor. -/ @[simps] noncomputable def coneOfAdj (F : J ⥤ C) : Cone F where pt := L.obj F π := adj.counit.app F /-- The cones defined by `coneOfAdj` are limit cones. -/ @[simps] def isLimitConeOfAdj (F : J ⥤ C) : IsLimit (coneOfAdj adj F) where lift s := adj.homEquiv _ _ s.π fac s j := by have eq := NatTrans.congr_app (adj.counit.naturality s.π) j have eq' := NatTrans.congr_app (adj.left_triangle_components s.pt) j dsimp at eq eq' ⊢ rw [adj.homEquiv_unit, assoc, eq, reassoc_of% eq'] uniq s m hm := (adj.homEquiv _ _).symm.injective (by ext j; simpa using hm j) end Adjunction /-- We can transport limits of shape `J` along an equivalence `J ≌ J'`. -/ theorem hasLimitsOfShape_of_equivalence {J' : Type u₂} [Category.{v₂} J'] (e : J ≌ J') [HasLimitsOfShape J C] : HasLimitsOfShape J' C := by constructor intro F apply hasLimitOfEquivalenceComp e variable (C) /-- A category that has larger limits also has smaller limits. -/ theorem hasLimitsOfSizeOfUnivLE [UnivLE.{v₂, v₁}] [UnivLE.{u₂, u₁}] [HasLimitsOfSize.{v₁, u₁} C] : HasLimitsOfSize.{v₂, u₂} C where has_limits_of_shape J {_} := hasLimitsOfShape_of_equivalence ((ShrinkHoms.equivalence J).trans <\| Shrink.equivalence _).symm /-- `hasLimitsOfSizeShrink.{v u} C` tries to obtain `HasLimitsOfSize.{v u} C` from some other `HasLimitsOfSize C`. -/ theorem hasLimitsOfSizeShrink [HasLimitsOfSize.{max v₁ v₂, max u₁ u₂} C] : HasLimitsOfSize.{v₁, u₁} C := hasLimitsOfSizeOfUnivLE.{max v₁ v₂, max u₁ u₂} C instance (priority := 100) hasSmallestLimitsOfHasLimits [HasLimits C] : HasLimitsOfSize.{0, 0} C := hasLimitsOfSizeShrink.{0, 0} C end Limit section Colimit /-- `ColimitCocone F` contains a cocone over `F` together with the information that it is a colimit. -/ structure ColimitCocone (F : J ⥤ C) where /-- The cocone itself -/ cocone : Cocone F /-- The proof that it is the colimit cocone -/ isColimit : IsColimit cocone /-- `HasColimit F` represents the mere existence of a colimit for `F`. -/ class HasColimit (F : J ⥤ C) : Prop where mk' :: /-- There exists a colimit for `F` -/ exists_colimit : Nonempty (ColimitCocone F) theorem HasColimit.mk {F : J ⥤ C} (d : ColimitCocone F) : HasColimit F := ⟨Nonempty.intro d⟩ /-- Use the axiom of choice to extract explicit `ColimitCocone F` from `HasColimit F`. -/ def getColimitCocone (F : J ⥤ C) [HasColimit F] : ColimitCocone F := Classical.choice <\| HasColimit.exists_colimit variable (J C) /-- `C` has colimits of shape `J` if there exists a colimit for every functor `F : J ⥤ C`. -/ class HasColimitsOfShape : Prop where /-- All `F : J ⥤ C` have colimits for a fixed `J` -/ has_colimit : ∀ F : J ⥤ C, HasColimit F := by infer_instance /-- `C` has all colimits of size `v₁ u₁` (`HasColimitsOfSize.{v₁ u₁} C`) if it has colimits of every shape `J : Type u₁` with `[Category.{v₁} J]`. -/ @[pp_with_univ] class HasColimitsOfSize (C : Type u) [Category.{v} C] : Prop where /-- All `F : J ⥤ C` have colimits for all small `J` -/ has_colimits_of_shape : ∀ (J : Type u₁) [Category.{v₁} J], HasColimitsOfShape J C := by infer_instance /-- `C` has all (small) colimits if it has colimits of every shape that is as big as its hom-sets. -/ abbrev HasColimits (C : Type u) [Category.{v} C] : Prop := HasColimitsOfSize.{v, v} C theorem HasColimits.hasColimitsOfShape {C : Type u} [Category.{v} C] [HasColimits C] (J : Type v) [Category.{v} J] : HasColimitsOfShape J C := HasColimitsOfSize.has_colimits_of_shape J variable {J C} -- see Note [lower instance priority] instance (priority := 100) hasColimitOfHasColimitsOfShape {J : Type u₁} [Category.{v₁} J] [HasColimitsOfShape J C] (F : J ⥤ C) : HasColimit F := HasColimitsOfShape.has_colimit F -- see Note [lower instance priority] instance (priority := 100) hasColimitsOfShapeOfHasColimitsOfSize {J : Type u₁} [Category.{v₁} J] [HasColimitsOfSize.{v₁, u₁} C] : HasColimitsOfShape J C := HasColimitsOfSize.has_colimits_of_shape J -- Interface to the `HasColimit` class. /-- An arbitrary choice of colimit cocone of a functor. -/ def colimit.cocone (F : J ⥤ C) [HasColimit F] : Cocone F := (getColimitCocone F).cocone /-- An arbitrary choice of colimit object of a functor. -/ def colimit (F : J ⥤ C) [HasColimit F] := (colimit.cocone F).pt /-- The coprojection from a value of the functor to the colimit object. -/ def colimit.ι (F : J ⥤ C) [HasColimit F] (j : J) : F.obj j ⟶ colimit F := (colimit.cocone F).ι.app j @[reassoc] theorem colimit.eqToHom_comp_ι (F : J ⥤ C) [HasColimit F] {j j' : J} (hj : j = j') : eqToHom (by subst hj; rfl) ≫ colimit.ι F j = colimit.ι F j' := by subst hj simp @[simp] theorem colimit.cocone_ι {F : J ⥤ C} [HasColimit F] (j : J) : (colimit.cocone F).ι.app j = colimit.ι _ j := rfl @[simp] theorem colimit.cocone_x {F : J ⥤ C} [HasColimit F] : (colimit.cocone F).pt = colimit F := rfl @[reassoc (attr := simp)] theorem colimit.w (F : J ⥤ C) [HasColimit F] {j j' : J} (f : j ⟶ j') : F.map f ≫ colimit.ι F j' = colimit.ι F j := (colimit.cocone F).w f /-- Evidence that the arbitrary choice of cocone is a colimit cocone. -/ def colimit.isColimit (F : J ⥤ C) [HasColimit F] : IsColimit (colimit.cocone F) := (getColimitCocone F).isColimit /-- The morphism from the colimit object to the cone point of any other cocone. -/ def colimit.desc (F : J ⥤ C) [HasColimit F] (c : Cocone F) : colimit F ⟶ c.pt := (colimit.isColimit F).desc c @[simp] theorem colimit.isColimit_desc {F : J ⥤ C} [HasColimit F] (c : Cocone F) : (colimit.isColimit F).desc c = colimit.desc F c := rfl /-- We have lots of lemmas describing how to simplify `colimit.ι F j ≫ _`, and combined with `colimit.ext` we rely on these lemmas for many calculations. However, since `Category.assoc` is a `@[simp]` lemma, often expressions are right associated, and it's hard to apply these lemmas about `colimit.ι`. We thus use `reassoc` to define additional `@[simp]` lemmas, with an arbitrary extra morphism. (see `Tactic/reassoc_axiom.lean`) -/ @[reassoc (attr := simp)] theorem colimit.ι_desc {F : J ⥤ C} [HasColimit F] (c : Cocone F) (j : J) : colimit.ι F j ≫ colimit.desc F c = c.ι.app j := IsColimit.fac _ c j /-- Functoriality of colimits. Usually this morphism should be accessed through `colim.map`, but may be needed separately when you have specified colimits for the source and target functors, but not necessarily for all functors of shape `J`. -/ def colimMap {F G : J ⥤ C} [HasColimit F] [HasColimit G] (α : F ⟶ G) : colimit F ⟶ colimit G := IsColimit.map (colimit.isColimit F) _ α @[reassoc (attr := simp)] theorem ι_colimMap {F G : J ⥤ C} [HasColimit F] [HasColimit G] (α : F ⟶ G) (j : J) : colimit.ι F j ≫ colimMap α = α.app j ≫ colimit.ι G j := colimit.ι_desc _ j /-- The cocone morphism from the arbitrary choice of colimit cocone to any cocone. -/ def colimit.coconeMorphism {F : J ⥤ C} [HasColimit F] (c : Cocone F) : colimit.cocone F ⟶ c := (colimit.isColimit F).descCoconeMorphism c @[simp] theorem colimit.coconeMorphism_hom {F : J ⥤ C} [HasColimit F] (c : Cocone F) : (colimit.coconeMorphism c).hom = colimit.desc F c := rfl theorem colimit.ι_coconeMorphism {F : J ⥤ C} [HasColimit F] (c : Cocone F) (j : J) : colimit.ι F j ≫ (colimit.coconeMorphism c).hom = c.ι.app j := by simp @[reassoc (attr := simp)] theorem colimit.comp_coconePointUniqueUpToIso_hom {F : J ⥤ C} [HasColimit F] {c : Cocone F} (hc : IsColimit c) (j : J) : colimit.ι F j ≫ (IsColimit.coconePointUniqueUpToIso (colimit.isColimit _) hc).hom = c.ι.app j := IsColimit.comp_coconePointUniqueUpToIso_hom _ _ _ @[reassoc (attr := simp)] theorem colimit.comp_coconePointUniqueUpToIso_inv {F : J ⥤ C} [HasColimit F] {c : Cocone F} (hc : IsColimit c) (j : J) : colimit.ι F j ≫ (IsColimit.coconePointUniqueUpToIso hc (colimit.isColimit _)).inv = c.ι.app j := IsColimit.comp_coconePointUniqueUpToIso_inv _ _ _ theorem colimit.existsUnique {F : J ⥤ C} [HasColimit F] (t : Cocone F) : ∃! d : colimit F ⟶ t.pt, ∀ j, colimit.ι F j ≫ d = t.ι.app j := (colimit.isColimit F).existsUnique _ /-- Given any other colimit cocone for `F`, the chosen `colimit F` is isomorphic to the cocone point. -/ def colimit.isoColimitCocone {F : J ⥤ C} [HasColimit F] (t : ColimitCocone F) : colimit F ≅ t.cocone.pt := IsColimit.coconePointUniqueUpToIso (colimit.isColimit F) t.isColimit @[reassoc (attr := simp)] theorem colimit.isoColimitCocone_ι_hom {F : J ⥤ C} [HasColimit F] (t : ColimitCocone F) (j : J) : colimit.ι F j ≫ (colimit.isoColimitCocone t).hom = t.cocone.ι.app j := by dsimp [colimit.isoColimitCocone, IsColimit.coconePointUniqueUpToIso] simp @[reassoc (attr := simp)] theorem colimit.isoColimitCocone_ι_inv {F : J ⥤ C} [HasColimit F] (t : ColimitCocone F) (j : J) : t.cocone.ι.app j ≫ (colimit.isoColimitCocone t).inv = colimit.ι F j := by dsimp [colimit.isoColimitCocone, IsColimit.coconePointUniqueUpToIso] simp @[ext] theorem colimit.hom_ext {F : J ⥤ C} [HasColimit F] {X : C} {f f' : colimit F ⟶ X} (w : ∀ j, colimit.ι F j ≫ f = colimit.ι F j ≫ f') : f = f' := (colimit.isColimit F).hom_ext w @[simp] theorem colimit.desc_cocone {F : J ⥤ C} [HasColimit F] : colimit.desc F (colimit.cocone F) = 𝟙 (colimit F) := (colimit.isColimit _).desc_self /-- The isomorphism (in `Type`) between morphisms from the colimit object to a specified object `W`, and cocones with cone point `W`. -/ def colimit.homIso (F : J ⥤ C) [HasColimit F] (W : C) : ULift.{u₁} (colimit F ⟶ W : Type v) ≅ F.cocones.obj W := (colimit.isColimit F).homIso W @[simp] theorem colimit.homIso_hom (F : J ⥤ C) [HasColimit F] {W : C} (f : ULift (colimit F ⟶ W)) : (colimit.homIso F W).hom f = (colimit.cocone F).ι ≫ (const J).map f.down := (colimit.isColimit F).homIso_hom f /-- The isomorphism (in `Type`) between morphisms from the colimit object to a specified object `W`, and an explicit componentwise description of cocones with cone point `W`. -/ def colimit.homIso' (F : J ⥤ C) [HasColimit F] (W : C) : ULift.{u₁} (colimit F ⟶ W : Type v) ≅ { p : ∀ j, F.obj j ⟶ W // ∀ {j j'} (f : j ⟶ j'), F.map f ≫ p j' = p j } := (colimit.isColimit F).homIso' W theorem colimit.desc_extend (F : J ⥤ C) [HasColimit F] (c : Cocone F) {X : C} (f : c.pt ⟶ X) : colimit.desc F (c.extend f) = colimit.desc F c ≫ f := by ext1; rw [← Category.assoc]; simp -- This has the isomorphism pointing in the opposite direction than in `has_limit_of_iso`. -- This is intentional; it seems to help with elaboration. /-- If `F` has a colimit, so does any naturally isomorphic functor. -/ theorem hasColimit_of_iso {F G : J ⥤ C} [HasColimit F] (α : G ≅ F) : HasColimit G := HasColimit.mk { cocone := (Cocones.precompose α.hom).obj (colimit.cocone F) isColimit := (IsColimit.precomposeHomEquiv _ _).symm (colimit.isColimit F) } @[deprecated (since := "2025-03-03")] alias hasColimitOfIso := hasColimit_of_iso theorem hasColimit_iff_of_iso {F G : J ⥤ C} (α : F ≅ G) : HasColimit F ↔ HasColimit G := ⟨fun _ ↦ hasColimit_of_iso α.symm, fun _ ↦ hasColimit_of_iso α⟩ /-- If a functor `G` has the same collection of cocones as a functor `F` which has a colimit, then `G` also has a colimit. -/ theorem HasColimit.ofCoconesIso {K : Type u₁} [Category.{v₂} K] (F : J ⥤ C) (G : K ⥤ C) (h : F.cocones ≅ G.cocones) [HasColimit F] : HasColimit G := HasColimit.mk ⟨_, IsColimit.ofNatIso (IsColimit.natIso (colimit.isColimit F) ≪≫ h)⟩ /-- The colimits of `F : J ⥤ C` and `G : J ⥤ C` are isomorphic, if the functors are naturally isomorphic. -/ def HasColimit.isoOfNatIso {F G : J ⥤ C} [HasColimit F] [HasColimit G] (w : F ≅ G) : colimit F ≅ colimit G := IsColimit.coconePointsIsoOfNatIso (colimit.isColimit F) (colimit.isColimit G) w @[reassoc (attr := simp)] theorem HasColimit.isoOfNatIso_ι_hom {F G : J ⥤ C} [HasColimit F] [HasColimit G] (w : F ≅ G) (j : J) : colimit.ι F j ≫ (HasColimit.isoOfNatIso w).hom = w.hom.app j ≫ colimit.ι G j := IsColimit.comp_coconePointsIsoOfNatIso_hom _ _ _ _ @[reassoc (attr := simp)] theorem HasColimit.isoOfNatIso_ι_inv {F G : J ⥤ C} [HasColimit F] [HasColimit G] (w : F ≅ G) (j : J) : colimit.ι G j ≫ (HasColimit.isoOfNatIso w).inv = w.inv.app j ≫ colimit.ι F j := IsColimit.comp_coconePointsIsoOfNatIso_inv _ _ _ _ @[reassoc (attr := simp)] theorem HasColimit.isoOfNatIso_hom_desc {F G : J ⥤ C} [HasColimit F] [HasColimit G] (t : Cocone G) (w : F ≅ G) : (HasColimit.isoOfNatIso w).hom ≫ colimit.desc G t = colimit.desc F ((Cocones.precompose w.hom).obj _) := IsColimit.coconePointsIsoOfNatIso_hom_desc _ _ _ @[reassoc (attr := simp)] theorem HasColimit.isoOfNatIso_inv_desc {F G : J ⥤ C} [HasColimit F] [HasColimit G] (t : Cocone F) (w : F ≅ G) : (HasColimit.isoOfNatIso w).inv ≫ colimit.desc F t = colimit.desc G ((Cocones.precompose w.inv).obj _) := IsColimit.coconePointsIsoOfNatIso_inv_desc _ _ _ /-- The colimits of `F : J ⥤ C` and `G : K ⥤ C` are isomorphic, if there is an equivalence `e : J ≌ K` making the triangle commute up to natural isomorphism. -/ def HasColimit.isoOfEquivalence {F : J ⥤ C} [HasColimit F] {G : K ⥤ C} [HasColimit G] (e : J ≌ K) (w : e.functor ⋙ G ≅ F) : colimit F ≅ colimit G := IsColimit.coconePointsIsoOfEquivalence (colimit.isColimit F) (colimit.isColimit G) e w @[simp] theorem HasColimit.isoOfEquivalence_hom_π {F : J ⥤ C} [HasColimit F] {G : K ⥤ C} [HasColimit G] (e : J ≌ K) (w : e.functor ⋙ G ≅ F) (j : J) : colimit.ι F j ≫ (HasColimit.isoOfEquivalence e w).hom = F.map (e.unit.app j) ≫ w.inv.app _ ≫ colimit.ι G _ := by simp [HasColimit.isoOfEquivalence, IsColimit.coconePointsIsoOfEquivalence_inv] @[simp] theorem HasColimit.isoOfEquivalence_inv_π {F : J ⥤ C} [HasColimit F] {G : K ⥤ C} [HasColimit G] (e : J ≌ K) (w : e.functor ⋙ G ≅ F) (k : K) : colimit.ι G k ≫ (HasColimit.isoOfEquivalence e w).inv = G.map (e.counitInv.app k) ≫ w.hom.app (e.inverse.obj k) ≫ colimit.ι F (e.inverse.obj k) := by simp [HasColimit.isoOfEquivalence, IsColimit.coconePointsIsoOfEquivalence_inv] section Pre variable (F) variable [HasColimit F] (E : K ⥤ J) [HasColimit (E ⋙ F)] /-- The canonical morphism from the colimit of `E ⋙ F` to the colimit of `F`. -/ def colimit.pre : colimit (E ⋙ F) ⟶ colimit F := colimit.desc (E ⋙ F) ((colimit.cocone F).whisker E) @[reassoc (attr := simp)] theorem colimit.ι_pre (k : K) : colimit.ι (E ⋙ F) k ≫ colimit.pre F E = colimit.ι F (E.obj k) := by erw [IsColimit.fac] rfl @[reassoc (attr := simp)] theorem colimit.ι_inv_pre [IsIso (pre F E)] (k : K) : colimit.ι F (E.obj k) ≫ inv (colimit.pre F E) = colimit.ι (E ⋙ F) k := by simp [IsIso.comp_inv_eq] @[reassoc (attr := simp)] theorem colimit.pre_desc (c : Cocone F) : colimit.pre F E ≫ colimit.desc F c = colimit.desc (E ⋙ F) (c.whisker E) := by ext; rw [← assoc, colimit.ι_pre]; simp variable {L : Type u₃} [Category.{v₃} L] variable (D : L ⥤ K) @[simp] theorem colimit.pre_pre [h : HasColimit (D ⋙ E ⋙ F)] : haveI : HasColimit ((D ⋙ E) ⋙ F) := h colimit.pre (E ⋙ F) D ≫ colimit.pre F E = colimit.pre F (D ⋙ E) := by ext j rw [← assoc, colimit.ι_pre, colimit.ι_pre] haveI : HasColimit ((D ⋙ E) ⋙ F) := h exact (colimit.ι_pre F (D ⋙ E) j).symm variable {E F} /-- - If we have particular colimit cocones available for `E ⋙ F` and for `F`, we obtain a formula for `colimit.pre F E`. -/ theorem colimit.pre_eq (s : ColimitCocone (E ⋙ F)) (t : ColimitCocone F) : colimit.pre F E = (colimit.isoColimitCocone s).hom ≫ s.isColimit.desc (t.cocone.whisker E) ≫ (colimit.isoColimitCocone t).inv := by aesop_cat end Pre section Post variable {D : Type u'} [Category.{v'} D] variable (F) variable [HasColimit F] (G : C ⥤ D) [HasColimit (F ⋙ G)] /-- The canonical morphism from `G` applied to the colimit of `F ⋙ G` to `G` applied to the colimit of `F`. -/ def colimit.post : colimit (F ⋙ G) ⟶ G.obj (colimit F) := colimit.desc (F ⋙ G) (G.mapCocone (colimit.cocone F)) @[reassoc (attr := simp)] theorem colimit.ι_post (j : J) : colimit.ι (F ⋙ G) j ≫ colimit.post F G = G.map (colimit.ι F j) := by erw [IsColimit.fac] rfl @[simp] theorem colimit.post_desc (c : Cocone F) : colimit.post F G ≫ G.map (colimit.desc F c) = colimit.desc (F ⋙ G) (G.mapCocone c) := by ext rw [← assoc, colimit.ι_post, ← G.map_comp, colimit.ι_desc, colimit.ι_desc] rfl @[simp] theorem colimit.post_post {E : Type u''} [Category.{v''} E] (H : D ⥤ E) -- H G (colimit F) ⟶ H (colimit (F ⋙ G)) ⟶ colimit ((F ⋙ G) ⋙ H) equals -- H G (colimit F) ⟶ colimit (F ⋙ (G ⋙ H)) [h : HasColimit ((F ⋙ G) ⋙ H)] : haveI : HasColimit (F ⋙ G ⋙ H) := h colimit.post (F ⋙ G) H ≫ H.map (colimit.post F G) = colimit.post F (G ⋙ H) := by ext j rw [← assoc, colimit.ι_post, ← H.map_comp, colimit.ι_post] haveI : HasColimit (F ⋙ G ⋙ H) := h exact (colimit.ι_post F (G ⋙ H) j).symm end Post theorem colimit.pre_post {D : Type u'} [Category.{v'} D] (E : K ⥤ J) (F : J ⥤ C) (G : C ⥤ D) [HasColimit F] [HasColimit (E ⋙ F)] [HasColimit (F ⋙ G)] [h : HasColimit ((E ⋙ F) ⋙ G)] : -- G (colimit F) ⟶ G (colimit (E ⋙ F)) ⟶ colimit ((E ⋙ F) ⋙ G) vs -- G (colimit F) ⟶ colimit F ⋙ G ⟶ colimit (E ⋙ (F ⋙ G)) or haveI : HasColimit (E ⋙ F ⋙ G) := h colimit.post (E ⋙ F) G ≫ G.map (colimit.pre F E) = colimit.pre (F ⋙ G) E ≫ colimit.post F G := by ext j rw [← assoc, colimit.ι_post, ← G.map_comp, colimit.ι_pre, ← assoc] haveI : HasColimit (E ⋙ F ⋙ G) := h erw [colimit.ι_pre (F ⋙ G) E j, colimit.ι_post] open CategoryTheory.Equivalence instance hasColimit_equivalence_comp (e : K ≌ J) [HasColimit F] : HasColimit (e.functor ⋙ F) := HasColimit.mk { cocone := Cocone.whisker e.functor (colimit.cocone F) isColimit := IsColimit.whiskerEquivalence (colimit.isColimit F) e } /-- If a `E ⋙ F` has a colimit, and `E` is an equivalence, we can construct a colimit of `F`. -/ theorem hasColimit_of_equivalence_comp (e : K ≌ J) [HasColimit (e.functor ⋙ F)] : HasColimit F := by haveI : HasColimit (e.inverse ⋙ e.functor ⋙ F) := Limits.hasColimit_equivalence_comp e.symm apply hasColimit_of_iso (e.invFunIdAssoc F).symm section ColimFunctor variable [HasColimitsOfShape J C] section /-- `colimit F` is functorial in `F`, when `C` has all colimits of shape `J`. -/ @[simps] def colim : (J ⥤ C) ⥤ C where obj F := colimit F map α := colimMap α end variable {G : J ⥤ C} (α : F ⟶ G) theorem colimMap_eq : colimMap α = colim.map α := rfl @[reassoc] theorem colimit.ι_map (j : J) : colimit.ι F j ≫ colim.map α = α.app j ≫ colimit.ι G j := by simp @[reassoc (attr := simp)] theorem colimit.map_desc (c : Cocone G) : colimMap α ≫ colimit.desc G c = colimit.desc F ((Cocones.precompose α).obj c) := by ext j simp [← assoc, colimit.ι_map, assoc, colimit.ι_desc, colimit.ι_desc] theorem colimit.pre_map [HasColimitsOfShape K C] (E : K ⥤ J) : colimit.pre F E ≫ colim.map α = colim.map (whiskerLeft E α) ≫ colimit.pre G E := by ext rw [← assoc, colimit.ι_pre, colimit.ι_map, ← assoc, colimit.ι_map, assoc, colimit.ι_pre] rfl theorem colimit.pre_map' [HasColimitsOfShape K C] (F : J ⥤ C) {E₁ E₂ : K ⥤ J} (α : E₁ ⟶ E₂) : colimit.pre F E₁ = colim.map (whiskerRight α F) ≫ colimit.pre F E₂ := by ext1 simp [← assoc, assoc] theorem colimit.pre_id (F : J ⥤ C) : colimit.pre F (𝟭 _) = colim.map (Functor.leftUnitor F).hom := by aesop_cat theorem colimit.map_post {D : Type u'} [Category.{v'} D] [HasColimitsOfShape J D] (H : C ⥤ D) :/- H (colimit F) ⟶ H (colimit G) ⟶ colimit (G ⋙ H) vs H (colimit F) ⟶ colimit (F ⋙ H) ⟶ colimit (G ⋙ H) -/ colimit.post F H ≫ H.map (colim.map α) = colim.map (whiskerRight α H) ≫ colimit.post G H := by ext rw [← assoc, colimit.ι_post, ← H.map_comp, colimit.ι_map, H.map_comp] rw [← assoc, colimit.ι_map, assoc, colimit.ι_post] rfl /-- The isomorphism between morphisms from the cone point of the colimit cocone for `F` to `W` and cocones over `F` with cone point `W` is natural in `F`. -/ def colimCoyoneda : colim.op ⋙ coyoneda ⋙ (whiskeringRight _ _ _).obj uliftFunctor.{u₁} ≅ CategoryTheory.cocones J C := NatIso.ofComponents fun F => NatIso.ofComponents fun W => colimit.homIso (unop F) W /-- The colimit functor and constant functor are adjoint to each other -/ def colimConstAdj : (colim : (J ⥤ C) ⥤ C) ⊣ const J := Adjunction.mk' { homEquiv := fun f c ↦ { toFun := fun g => { app := fun _ => colimit.ι _ _ ≫ g } invFun := fun g => colimit.desc _ ⟨_, g⟩ left_inv := by aesop_cat right_inv := by aesop_cat }	unit := { app := fun g => { app := colimit.ι _ } } counit := { app := fun _ => colimit.desc _ ⟨_, 𝟙 _⟩ } } instance : IsLeftAdjoint (colim : (J ⥤ C) ⥤ C) := ⟨_, ⟨colimConstAdj⟩⟩	Mathlib/CategoryTheory/Limits/HasLimits.lean	1,056	1,060
/- Copyright (c) 2022 Andrew Yang. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Andrew Yang -/ import Mathlib.Topology.Compactness.Bases import Mathlib.Topology.NoetherianSpace /-! # Quasi-separated spaces A topological space is quasi-separated if the intersections of any pairs of compact open subsets are still compact. Notable examples include spectral spaces, Noetherian spaces, and Hausdorff spaces. A non-example is the interval `[0, 1]` with doubled origin: the two copies of `[0, 1]` are compact open subsets, but their intersection `(0, 1]` is not. ## Main results - `IsQuasiSeparated`: A subset `s` of a topological space is quasi-separated if the intersections of any pairs of compact open subsets of `s` are still compact. - `QuasiSeparatedSpace`: A topological space is quasi-separated if the intersections of any pairs of compact open subsets are still compact. - `QuasiSeparatedSpace.of_isOpenEmbedding`: If `f : α → β` is an open embedding, and `β` is a quasi-separated space, then so is `α`. -/ open Set TopologicalSpace Topology variable {α β : Type} [TopologicalSpace α] [TopologicalSpace β] {f : α → β} /-- A subset `s` of a topological space is quasi-separated if the intersections of any pairs of compact open subsets of `s` are still compact. Note that this is equivalent to `s` being a `QuasiSeparatedSpace` only when `s` is open. -/ def IsQuasiSeparated (s : Set α) : Prop := ∀ U V : Set α, U ⊆ s → IsOpen U → IsCompact U → V ⊆ s → IsOpen V → IsCompact V → IsCompact (U ∩ V) /-- A topological space is quasi-separated if the intersections of any pairs of compact open subsets are still compact. -/ @[mk_iff] class QuasiSeparatedSpace (α : Type) [TopologicalSpace α] : Prop where /-- The intersection of two open compact subsets of a quasi-separated space is compact. -/ inter_isCompact : ∀ U V : Set α, IsOpen U → IsCompact U → IsOpen V → IsCompact V → IsCompact (U ∩ V) theorem isQuasiSeparated_univ_iff {α : Type*} [TopologicalSpace α] : IsQuasiSeparated (Set.univ : Set α) ↔ QuasiSeparatedSpace α := by rw [quasiSeparatedSpace_iff] simp [IsQuasiSeparated]	theorem isQuasiSeparated_univ {α : Type*} [TopologicalSpace α] [QuasiSeparatedSpace α] : IsQuasiSeparated (Set.univ : Set α) := isQuasiSeparated_univ_iff.mpr inferInstance	Mathlib/Topology/QuasiSeparated.lean	53	56
/- Copyright (c) 2022 Jiale Miao. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jiale Miao, Kevin Buzzard, Alexander Bentkamp -/ import Mathlib.Analysis.InnerProductSpace.PiL2 import Mathlib.LinearAlgebra.Matrix.Block /-! # Gram-Schmidt Orthogonalization and Orthonormalization In this file we introduce Gram-Schmidt Orthogonalization and Orthonormalization. The Gram-Schmidt process takes a set of vectors as input and outputs a set of orthogonal vectors which have the same span. ## Main results - `gramSchmidt` : the Gram-Schmidt process - `gramSchmidt_orthogonal` : `gramSchmidt` produces an orthogonal system of vectors. - `span_gramSchmidt` : `gramSchmidt` preserves span of vectors. - `gramSchmidt_ne_zero` : If the input vectors of `gramSchmidt` are linearly independent, then the output vectors are non-zero. - `gramSchmidt_basis` : The basis produced by the Gram-Schmidt process when given a basis as input. - `gramSchmidtNormed` : the normalized `gramSchmidt` (i.e each vector in `gramSchmidtNormed` has unit length.) - `gramSchmidt_orthonormal` : `gramSchmidtNormed` produces an orthornormal system of vectors. - `gramSchmidtOrthonormalBasis`: orthonormal basis constructed by the Gram-Schmidt process from an indexed set of vectors of the right size -/ open Finset Submodule Module variable (𝕜 : Type) {E : Type} [RCLike 𝕜] [NormedAddCommGroup E] [InnerProductSpace 𝕜 E] variable {ι : Type} [LinearOrder ι] [LocallyFiniteOrderBot ι] [WellFoundedLT ι] attribute [local instance] IsWellOrder.toHasWellFounded local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y /-- The Gram-Schmidt process takes a set of vectors as input and outputs a set of orthogonal vectors which have the same span. -/ noncomputable def gramSchmidt [WellFoundedLT ι] (f : ι → E) (n : ι) : E := f n - ∑ i : Iio n, (𝕜 ∙ gramSchmidt f i).orthogonalProjection (f n) termination_by n decreasing_by exact mem_Iio.1 i.2 /-- This lemma uses `∑ i in` instead of `∑ i :`. -/ theorem gramSchmidt_def (f : ι → E) (n : ι) : gramSchmidt 𝕜 f n = f n - ∑ i ∈ Iio n, (𝕜 ∙ gramSchmidt 𝕜 f i).orthogonalProjection (f n) := by rw [← sum_attach, attach_eq_univ, gramSchmidt] theorem gramSchmidt_def' (f : ι → E) (n : ι) : f n = gramSchmidt 𝕜 f n + ∑ i ∈ Iio n, (𝕜 ∙ gramSchmidt 𝕜 f i).orthogonalProjection (f n) := by rw [gramSchmidt_def, sub_add_cancel] theorem gramSchmidt_def'' (f : ι → E) (n : ι) : f n = gramSchmidt 𝕜 f n + ∑ i ∈ Iio n, (⟪gramSchmidt 𝕜 f i, f n⟫ / (‖gramSchmidt 𝕜 f i‖ : 𝕜) ^ 2) • gramSchmidt 𝕜 f i := by convert gramSchmidt_def' 𝕜 f n rw [orthogonalProjection_singleton, RCLike.ofReal_pow] @[simp] theorem gramSchmidt_zero {ι : Type} [LinearOrder ι] [LocallyFiniteOrder ι] [OrderBot ι] [WellFoundedLT ι] (f : ι → E) : gramSchmidt 𝕜 f ⊥ = f ⊥ := by rw [gramSchmidt_def, Iio_eq_Ico, Finset.Ico_self, Finset.sum_empty, sub_zero] /-- Gram-Schmidt Orthogonalisation: `gramSchmidt` produces an orthogonal system of vectors. -/ theorem gramSchmidt_orthogonal (f : ι → E) {a b : ι} (h₀ : a ≠ b) : ⟪gramSchmidt 𝕜 f a, gramSchmidt 𝕜 f b⟫ = 0 := by suffices ∀ a b : ι, a < b → ⟪gramSchmidt 𝕜 f a, gramSchmidt 𝕜 f b⟫ = 0 by rcases h₀.lt_or_lt with ha \| hb · exact this _ _ ha · rw [inner_eq_zero_symm] exact this _ _ hb clear h₀ a b intro a b h₀ revert a apply wellFounded_lt.induction b intro b ih a h₀ simp only [gramSchmidt_def 𝕜 f b, inner_sub_right, inner_sum, orthogonalProjection_singleton, inner_smul_right] rw [Finset.sum_eq_single_of_mem a (Finset.mem_Iio.mpr h₀)] · by_cases h : gramSchmidt 𝕜 f a = 0 · simp only [h, inner_zero_left, zero_div, zero_mul, sub_zero] · rw [RCLike.ofReal_pow, ← inner_self_eq_norm_sq_to_K, div_mul_cancel₀, sub_self] rwa [inner_self_ne_zero] intro i hi hia simp only [mul_eq_zero, div_eq_zero_iff, inner_self_eq_zero] right rcases hia.lt_or_lt with hia₁ \| hia₂ · rw [inner_eq_zero_symm] exact ih a h₀ i hia₁ · exact ih i (mem_Iio.1 hi) a hia₂ /-- This is another version of `gramSchmidt_orthogonal` using `Pairwise` instead. -/ theorem gramSchmidt_pairwise_orthogonal (f : ι → E) : Pairwise fun a b => ⟪gramSchmidt 𝕜 f a, gramSchmidt 𝕜 f b⟫ = 0 := fun _ _ => gramSchmidt_orthogonal 𝕜 f theorem gramSchmidt_inv_triangular (v : ι → E) {i j : ι} (hij : i < j) : ⟪gramSchmidt 𝕜 v j, v i⟫ = 0 := by rw [gramSchmidt_def'' 𝕜 v] simp only [inner_add_right, inner_sum, inner_smul_right] set b : ι → E := gramSchmidt 𝕜 v convert zero_add (0 : 𝕜) · exact gramSchmidt_orthogonal 𝕜 v hij.ne' apply Finset.sum_eq_zero rintro k hki' have hki : k < i := by simpa using hki' have : ⟪b j, b k⟫ = 0 := gramSchmidt_orthogonal 𝕜 v (hki.trans hij).ne' simp [this] open Submodule Set Order theorem mem_span_gramSchmidt (f : ι → E) {i j : ι} (hij : i ≤ j) : f i ∈ span 𝕜 (gramSchmidt 𝕜 f '' Set.Iic j) := by rw [gramSchmidt_def' 𝕜 f i] simp_rw [orthogonalProjection_singleton] exact Submodule.add_mem _ (subset_span <\| mem_image_of_mem _ hij) (Submodule.sum_mem _ fun k hk => smul_mem (span 𝕜 (gramSchmidt 𝕜 f '' Set.Iic j)) _ <\| subset_span <\| mem_image_of_mem (gramSchmidt 𝕜 f) <\| (Finset.mem_Iio.1 hk).le.trans hij) theorem gramSchmidt_mem_span (f : ι → E) : ∀ {j i}, i ≤ j → gramSchmidt 𝕜 f i ∈ span 𝕜 (f '' Set.Iic j) := by intro j i hij rw [gramSchmidt_def 𝕜 f i] simp_rw [orthogonalProjection_singleton] refine Submodule.sub_mem _ (subset_span (mem_image_of_mem _ hij)) (Submodule.sum_mem _ fun k hk => ?_) let hkj : k < j := (Finset.mem_Iio.1 hk).trans_le hij exact smul_mem _ _ (span_mono (image_subset f <\| Set.Iic_subset_Iic.2 hkj.le) <\| gramSchmidt_mem_span _ le_rfl) termination_by j => j theorem span_gramSchmidt_Iic (f : ι → E) (c : ι) : span 𝕜 (gramSchmidt 𝕜 f '' Set.Iic c) = span 𝕜 (f '' Set.Iic c) := span_eq_span (Set.image_subset_iff.2 fun _ => gramSchmidt_mem_span _ _) <\| Set.image_subset_iff.2 fun _ => mem_span_gramSchmidt _ _ theorem span_gramSchmidt_Iio (f : ι → E) (c : ι) : span 𝕜 (gramSchmidt 𝕜 f '' Set.Iio c) = span 𝕜 (f '' Set.Iio c) := span_eq_span (Set.image_subset_iff.2 fun _ hi => span_mono (image_subset _ <\| Iic_subset_Iio.2 hi) <\| gramSchmidt_mem_span _ _ le_rfl) <\| Set.image_subset_iff.2 fun _ hi => span_mono (image_subset _ <\| Iic_subset_Iio.2 hi) <\| mem_span_gramSchmidt _ _ le_rfl /-- `gramSchmidt` preserves span of vectors. -/ theorem span_gramSchmidt (f : ι → E) : span 𝕜 (range (gramSchmidt 𝕜 f)) = span 𝕜 (range f) := span_eq_span (range_subset_iff.2 fun _ => span_mono (image_subset_range _ _) <\| gramSchmidt_mem_span _ _ le_rfl) <\| range_subset_iff.2 fun _ => span_mono (image_subset_range _ _) <\| mem_span_gramSchmidt _ _ le_rfl theorem gramSchmidt_of_orthogonal {f : ι → E} (hf : Pairwise fun i j => ⟪f i, f j⟫ = 0) : gramSchmidt 𝕜 f = f := by ext i rw [gramSchmidt_def] trans f i - 0 · congr apply Finset.sum_eq_zero intro j hj rw [Submodule.coe_eq_zero] suffices span 𝕜 (f '' Set.Iic j) ⟂ 𝕜 ∙ f i by apply orthogonalProjection_mem_subspace_orthogonalComplement_eq_zero rw [mem_orthogonal_singleton_iff_inner_left] rw [← mem_orthogonal_singleton_iff_inner_right] exact this (gramSchmidt_mem_span 𝕜 f (le_refl j)) rw [isOrtho_span] rintro u ⟨k, hk, rfl⟩ v (rfl : v = f i) apply hf exact (lt_of_le_of_lt hk (Finset.mem_Iio.mp hj)).ne · simp variable {𝕜} theorem gramSchmidt_ne_zero_coe {f : ι → E} (n : ι) (h₀ : LinearIndependent 𝕜 (f ∘ ((↑) : Set.Iic n → ι))) : gramSchmidt 𝕜 f n ≠ 0 := by by_contra h have h₁ : f n ∈ span 𝕜 (f '' Set.Iio n) := by rw [← span_gramSchmidt_Iio 𝕜 f n, gramSchmidt_def' 𝕜 f, h, zero_add] apply Submodule.sum_mem _ _ intro a ha simp only [Set.mem_image, Set.mem_Iio, orthogonalProjection_singleton] apply Submodule.smul_mem _ _ _ rw [Finset.mem_Iio] at ha exact subset_span ⟨a, ha, by rfl⟩ have h₂ : (f ∘ ((↑) : Set.Iic n → ι)) ⟨n, le_refl n⟩ ∈ span 𝕜 (f ∘ ((↑) : Set.Iic n → ι) '' Set.Iio ⟨n, le_refl n⟩) := by rw [image_comp] simpa using h₁ apply LinearIndependent.not_mem_span_image h₀ _ h₂ simp only [Set.mem_Iio, lt_self_iff_false, not_false_iff] /-- If the input vectors of `gramSchmidt` are linearly independent, then the output vectors are non-zero. -/ theorem gramSchmidt_ne_zero {f : ι → E} (n : ι) (h₀ : LinearIndependent 𝕜 f) : gramSchmidt 𝕜 f n ≠ 0 := gramSchmidt_ne_zero_coe _ (LinearIndependent.comp h₀ _ Subtype.coe_injective) /-- `gramSchmidt` produces a triangular matrix of vectors when given a basis. -/ theorem gramSchmidt_triangular {i j : ι} (hij : i < j) (b : Basis ι 𝕜 E) : b.repr (gramSchmidt 𝕜 b i) j = 0 := by have : gramSchmidt 𝕜 b i ∈ span 𝕜 (gramSchmidt 𝕜 b '' Set.Iio j) := subset_span ((Set.mem_image _ _ _).2 ⟨i, hij, rfl⟩) have : gramSchmidt 𝕜 b i ∈ span 𝕜 (b '' Set.Iio j) := by rwa [← span_gramSchmidt_Iio 𝕜 b j] have : ↑(b.repr (gramSchmidt 𝕜 b i)).support ⊆ Set.Iio j := Basis.repr_support_subset_of_mem_span b (Set.Iio j) this exact (Finsupp.mem_supported' _ _).1 ((Finsupp.mem_supported 𝕜 _).2 this) j Set.not_mem_Iio_self /-- `gramSchmidt` produces linearly independent vectors when given linearly independent vectors. -/ theorem gramSchmidt_linearIndependent {f : ι → E} (h₀ : LinearIndependent 𝕜 f) : LinearIndependent 𝕜 (gramSchmidt 𝕜 f) := linearIndependent_of_ne_zero_of_inner_eq_zero (fun _ => gramSchmidt_ne_zero _ h₀) fun _ _ => gramSchmidt_orthogonal 𝕜 f /-- When given a basis, `gramSchmidt` produces a basis. -/ noncomputable def gramSchmidtBasis (b : Basis ι 𝕜 E) : Basis ι 𝕜 E := Basis.mk (gramSchmidt_linearIndependent b.linearIndependent) ((span_gramSchmidt 𝕜 b).trans b.span_eq).ge theorem coe_gramSchmidtBasis (b : Basis ι 𝕜 E) : (gramSchmidtBasis b : ι → E) = gramSchmidt 𝕜 b := Basis.coe_mk _ _ variable (𝕜) in /-- the normalized `gramSchmidt` (i.e each vector in `gramSchmidtNormed` has unit length.) -/ noncomputable def gramSchmidtNormed (f : ι → E) (n : ι) : E := (‖gramSchmidt 𝕜 f n‖ : 𝕜)⁻¹ • gramSchmidt 𝕜 f n theorem gramSchmidtNormed_unit_length_coe {f : ι → E} (n : ι) (h₀ : LinearIndependent 𝕜 (f ∘ ((↑) : Set.Iic n → ι))) : ‖gramSchmidtNormed 𝕜 f n‖ = 1 := by simp only [gramSchmidt_ne_zero_coe n h₀, gramSchmidtNormed, norm_smul_inv_norm, Ne, not_false_iff] theorem gramSchmidtNormed_unit_length {f : ι → E} (n : ι) (h₀ : LinearIndependent 𝕜 f) : ‖gramSchmidtNormed 𝕜 f n‖ = 1 := gramSchmidtNormed_unit_length_coe _ (LinearIndependent.comp h₀ _ Subtype.coe_injective) theorem gramSchmidtNormed_unit_length' {f : ι → E} {n : ι} (hn : gramSchmidtNormed 𝕜 f n ≠ 0) : ‖gramSchmidtNormed 𝕜 f n‖ = 1 := by rw [gramSchmidtNormed] at * rw [norm_smul_inv_norm] simpa using hn /-- Gram-Schmidt Orthonormalization: `gramSchmidtNormed` applied to a linearly independent set of vectors produces an orthornormal system of vectors. -/ theorem gramSchmidt_orthonormal {f : ι → E} (h₀ : LinearIndependent 𝕜 f) : Orthonormal 𝕜 (gramSchmidtNormed 𝕜 f) := by unfold Orthonormal constructor · simp only [gramSchmidtNormed_unit_length, h₀, eq_self_iff_true, imp_true_iff] · intro i j hij simp only [gramSchmidtNormed, inner_smul_left, inner_smul_right, RCLike.conj_inv, RCLike.conj_ofReal, mul_eq_zero, inv_eq_zero, RCLike.ofReal_eq_zero, norm_eq_zero] repeat' right exact gramSchmidt_orthogonal 𝕜 f hij /-- Gram-Schmidt Orthonormalization: `gramSchmidtNormed` produces an orthornormal system of vectors after removing the vectors which become zero in the process. -/ theorem gramSchmidt_orthonormal' (f : ι → E) : Orthonormal 𝕜 fun i : { i \| gramSchmidtNormed 𝕜 f i ≠ 0 } => gramSchmidtNormed 𝕜 f i := by refine ⟨fun i => gramSchmidtNormed_unit_length' i.prop, ?_⟩ rintro i j (hij : ¬_) rw [Subtype.ext_iff] at hij simp [gramSchmidtNormed, inner_smul_left, inner_smul_right, gramSchmidt_orthogonal 𝕜 f hij] theorem span_gramSchmidtNormed (f : ι → E) (s : Set ι) : span 𝕜 (gramSchmidtNormed 𝕜 f '' s) = span 𝕜 (gramSchmidt 𝕜 f '' s) := by refine span_eq_span (Set.image_subset_iff.2 fun i hi => smul_mem _ _ <\| subset_span <\| mem_image_of_mem _ hi) (Set.image_subset_iff.2 fun i hi => span_mono (image_subset _ <\| singleton_subset_set_iff.2 hi) ?_) simp only [coe_singleton, Set.image_singleton] by_cases h : gramSchmidt 𝕜 f i = 0 · simp [h] · refine mem_span_singleton.2 ⟨‖gramSchmidt 𝕜 f i‖, smul_inv_smul₀ ?_ _⟩ exact mod_cast norm_ne_zero_iff.2 h theorem span_gramSchmidtNormed_range (f : ι → E) : span 𝕜 (range (gramSchmidtNormed 𝕜 f)) = span 𝕜 (range (gramSchmidt 𝕜 f)) := by simpa only [image_univ.symm] using span_gramSchmidtNormed f univ section OrthonormalBasis variable [Fintype ι] [FiniteDimensional 𝕜 E] (h : finrank 𝕜 E = Fintype.card ι) (f : ι → E) /-- Given an indexed family `f : ι → E` of vectors in an inner product space `E`, for which the size of the index set is the dimension of `E`, produce an orthonormal basis for `E` which agrees with the orthonormal set produced by the Gram-Schmidt orthonormalization process on the elements of `ι` for which this process gives a nonzero number. -/ noncomputable def gramSchmidtOrthonormalBasis : OrthonormalBasis ι 𝕜 E := ((gramSchmidt_orthonormal' f).exists_orthonormalBasis_extension_of_card_eq (v := gramSchmidtNormed 𝕜 f) h).choose theorem gramSchmidtOrthonormalBasis_apply {f : ι → E} {i : ι} (hi : gramSchmidtNormed 𝕜 f i ≠ 0) : gramSchmidtOrthonormalBasis h f i = gramSchmidtNormed 𝕜 f i := ((gramSchmidt_orthonormal' f).exists_orthonormalBasis_extension_of_card_eq (v := gramSchmidtNormed 𝕜 f) h).choose_spec i hi theorem gramSchmidtOrthonormalBasis_apply_of_orthogonal {f : ι → E} (hf : Pairwise fun i j => ⟪f i, f j⟫ = 0) {i : ι} (hi : f i ≠ 0) : gramSchmidtOrthonormalBasis h f i = (‖f i‖⁻¹ : 𝕜) • f i := by have H : gramSchmidtNormed 𝕜 f i = (‖f i‖⁻¹ : 𝕜) • f i := by rw [gramSchmidtNormed, gramSchmidt_of_orthogonal 𝕜 hf] rw [gramSchmidtOrthonormalBasis_apply h, H] simpa [H] using hi theorem inner_gramSchmidtOrthonormalBasis_eq_zero {f : ι → E} {i : ι} (hi : gramSchmidtNormed 𝕜 f i = 0) (j : ι) : ⟪gramSchmidtOrthonormalBasis h f i, f j⟫ = 0 := by rw [← mem_orthogonal_singleton_iff_inner_right]	suffices span 𝕜 (gramSchmidtNormed 𝕜 f '' Set.Iic j) ⟂ 𝕜 ∙ gramSchmidtOrthonormalBasis h f i by apply this rw [span_gramSchmidtNormed]	Mathlib/Analysis/InnerProductSpace/GramSchmidtOrtho.lean	321	323
/- Copyright (c) 2021 Rémy Degenne. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Rémy Degenne -/ import Mathlib.Analysis.InnerProductSpace.LinearMap import Mathlib.MeasureTheory.Function.LpSpace.ContinuousFunctions import Mathlib.MeasureTheory.Function.StronglyMeasurable.Inner import Mathlib.MeasureTheory.Integral.Bochner.ContinuousLinearMap /-! # `L^2` space If `E` is an inner product space over `𝕜` (`ℝ` or `ℂ`), then `Lp E 2 μ` (defined in `Mathlib.MeasureTheory.Function.LpSpace`) is also an inner product space, with inner product defined as `inner f g = ∫ a, ⟪f a, g a⟫ ∂μ`. ### Main results * `mem_L1_inner` : for `f` and `g` in `Lp E 2 μ`, the pointwise inner product `fun x ↦ ⟪f x, g x⟫` belongs to `Lp 𝕜 1 μ`. * `integrable_inner` : for `f` and `g` in `Lp E 2 μ`, the pointwise inner product `fun x ↦ ⟪f x, g x⟫` is integrable. * `L2.innerProductSpace` : `Lp E 2 μ` is an inner product space. -/ noncomputable section open TopologicalSpace MeasureTheory MeasureTheory.Lp Filter open scoped NNReal ENNReal MeasureTheory namespace MeasureTheory section variable {α F : Type} {m : MeasurableSpace α} {μ : Measure α} [NormedAddCommGroup F] theorem MemLp.integrable_sq {f : α → ℝ} (h : MemLp f 2 μ) : Integrable (fun x => f x ^ 2) μ := by simpa [← memLp_one_iff_integrable] using h.norm_rpow two_ne_zero ENNReal.ofNat_ne_top @[deprecated (since := "2025-02-21")] alias Memℒp.integrable_sq := MemLp.integrable_sq theorem memLp_two_iff_integrable_sq_norm {f : α → F} (hf : AEStronglyMeasurable f μ) : MemLp f 2 μ ↔ Integrable (fun x => ‖f x‖ ^ 2) μ := by rw [← memLp_one_iff_integrable] convert (memLp_norm_rpow_iff hf two_ne_zero ENNReal.ofNat_ne_top).symm · simp · rw [div_eq_mul_inv, ENNReal.mul_inv_cancel two_ne_zero ENNReal.ofNat_ne_top] @[deprecated (since := "2025-02-21")] alias memℒp_two_iff_integrable_sq_norm := memLp_two_iff_integrable_sq_norm theorem memLp_two_iff_integrable_sq {f : α → ℝ} (hf : AEStronglyMeasurable f μ) : MemLp f 2 μ ↔ Integrable (fun x => f x ^ 2) μ := by convert memLp_two_iff_integrable_sq_norm hf using 3 simp @[deprecated (since := "2025-02-21")] alias memℒp_two_iff_integrable_sq := memLp_two_iff_integrable_sq end section InnerProductSpace variable {α : Type} {m : MeasurableSpace α} {p : ℝ≥0∞} {μ : Measure α} variable {E 𝕜 : Type*} [RCLike 𝕜] [NormedAddCommGroup E] [InnerProductSpace 𝕜 E] local notation "⟪" x ", " y "⟫" => @inner 𝕜 E _ x y theorem MemLp.const_inner (c : E) {f : α → E} (hf : MemLp f p μ) : MemLp (fun a => ⟪c, f a⟫) p μ := hf.of_le_mul (AEStronglyMeasurable.inner aestronglyMeasurable_const hf.1) (Eventually.of_forall fun _ => norm_inner_le_norm _ _) @[deprecated (since := "2025-02-21")] alias Memℒp.const_inner := MemLp.const_inner theorem MemLp.inner_const {f : α → E} (hf : MemLp f p μ) (c : E) : MemLp (fun a => ⟪f a, c⟫) p μ := hf.of_le_mul (c := ‖c‖) (AEStronglyMeasurable.inner hf.1 aestronglyMeasurable_const) (Eventually.of_forall fun x => by rw [mul_comm]; exact norm_inner_le_norm _ _) @[deprecated (since := "2025-02-21")] alias Memℒp.inner_const := MemLp.inner_const variable {f : α → E} @[fun_prop] theorem Integrable.const_inner (c : E) (hf : Integrable f μ) : Integrable (fun x => ⟪c, f x⟫) μ := by rw [← memLp_one_iff_integrable] at hf ⊢; exact hf.const_inner c @[fun_prop] theorem Integrable.inner_const (hf : Integrable f μ) (c : E) : Integrable (fun x => ⟪f x, c⟫) μ := by rw [← memLp_one_iff_integrable] at hf ⊢; exact hf.inner_const c variable [CompleteSpace E] [NormedSpace ℝ E] theorem _root_.integral_inner {f : α → E} (hf : Integrable f μ) (c : E) : ∫ x, ⟪c, f x⟫ ∂μ = ⟪c, ∫ x, f x ∂μ⟫ := ((innerSL 𝕜 c).restrictScalars ℝ).integral_comp_comm hf variable (𝕜)	theorem _root_.integral_eq_zero_of_forall_integral_inner_eq_zero (f : α → E) (hf : Integrable f μ) (hf_int : ∀ c : E, ∫ x, ⟪c, f x⟫ ∂μ = 0) : ∫ x, f x ∂μ = 0 := by	Mathlib/MeasureTheory/Function/L2Space.lean	104	106
/- Copyright (c) 2014 Robert Y. Lewis. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Robert Y. Lewis, Leonardo de Moura, Johannes Hölzl, Mario Carneiro -/ import Mathlib.Algebra.Field.Defs import Mathlib.Algebra.Ring.Commute import Mathlib.Algebra.Ring.Invertible import Mathlib.Order.Synonym /-! # Lemmas about division (semi)rings and (semi)fields -/ open Function OrderDual Set universe u variable {K L : Type} section DivisionSemiring variable [DivisionSemiring K] {a b c d : K} theorem add_div (a b c : K) : (a + b) / c = a / c + b / c := by simp_rw [div_eq_mul_inv, add_mul] @[field_simps] theorem div_add_div_same (a b c : K) : a / c + b / c = (a + b) / c := (add_div _ _ _).symm theorem same_add_div (h : b ≠ 0) : (b + a) / b = 1 + a / b := by rw [← div_self h, add_div] theorem div_add_same (h : b ≠ 0) : (a + b) / b = a / b + 1 := by rw [← div_self h, add_div] theorem one_add_div (h : b ≠ 0) : 1 + a / b = (b + a) / b := (same_add_div h).symm theorem div_add_one (h : b ≠ 0) : a / b + 1 = (a + b) / b := (div_add_same h).symm /-- See `inv_add_inv` for the more convenient version when `K` is commutative. -/ theorem inv_add_inv' (ha : a ≠ 0) (hb : b ≠ 0) : a⁻¹ + b⁻¹ = a⁻¹ (a + b) * b⁻¹ := let _ := invertibleOfNonzero ha; let _ := invertibleOfNonzero hb; invOf_add_invOf a b theorem one_div_mul_add_mul_one_div_eq_one_div_add_one_div (ha : a ≠ 0) (hb : b ≠ 0) : 1 / a * (a + b) * (1 / b) = 1 / a + 1 / b := by simpa only [one_div] using (inv_add_inv' ha hb).symm theorem add_div_eq_mul_add_div (a b : K) (hc : c ≠ 0) : a + b / c = (a * c + b) / c := (eq_div_iff_mul_eq hc).2 <\| by rw [right_distrib, div_mul_cancel₀ _ hc] @[field_simps] theorem add_div' (a b c : K) (hc : c ≠ 0) : b + a / c = (b * c + a) / c := by rw [add_div, mul_div_cancel_right₀ _ hc] @[field_simps] theorem div_add' (a b c : K) (hc : c ≠ 0) : a / c + b = (a + b * c) / c := by rwa [add_comm, add_div', add_comm] protected theorem Commute.div_add_div (hbc : Commute b c) (hbd : Commute b d) (hb : b ≠ 0) (hd : d ≠ 0) : a / b + c / d = (a * d + b * c) / (b * d) := by rw [add_div, mul_div_mul_right _ b hd, hbc.eq, hbd.eq, mul_div_mul_right c d hb] protected theorem Commute.one_div_add_one_div (hab : Commute a b) (ha : a ≠ 0) (hb : b ≠ 0) : 1 / a + 1 / b = (a + b) / (a * b) := by rw [(Commute.one_right a).div_add_div hab ha hb, one_mul, mul_one, add_comm] protected theorem Commute.inv_add_inv (hab : Commute a b) (ha : a ≠ 0) (hb : b ≠ 0) : a⁻¹ + b⁻¹ = (a + b) / (a * b) := by rw [inv_eq_one_div, inv_eq_one_div, hab.one_div_add_one_div ha hb] variable [NeZero (2 : K)] @[simp] lemma add_self_div_two (a : K) : (a + a) / 2 = a := by rw [← mul_two, mul_div_cancel_right₀ a two_ne_zero] @[simp] lemma add_halves (a : K) : a / 2 + a / 2 = a := by rw [← add_div, add_self_div_two] end DivisionSemiring section DivisionRing variable [DivisionRing K] {a b c d : K} @[simp] theorem div_neg_self {a : K} (h : a ≠ 0) : a / -a = -1 := by rw [div_neg_eq_neg_div, div_self h] @[simp] theorem neg_div_self {a : K} (h : a ≠ 0) : -a / a = -1 := by rw [neg_div, div_self h] theorem div_sub_div_same (a b c : K) : a / c - b / c = (a - b) / c := by rw [sub_eq_add_neg, ← neg_div, div_add_div_same, sub_eq_add_neg] theorem same_sub_div {a b : K} (h : b ≠ 0) : (b - a) / b = 1 - a / b := by simpa only [← @div_self _ _ b h] using (div_sub_div_same b a b).symm theorem one_sub_div {a b : K} (h : b ≠ 0) : 1 - a / b = (b - a) / b := (same_sub_div h).symm theorem div_sub_same {a b : K} (h : b ≠ 0) : (a - b) / b = a / b - 1 := by simpa only [← @div_self _ _ b h] using (div_sub_div_same a b b).symm theorem div_sub_one {a b : K} (h : b ≠ 0) : a / b - 1 = (a - b) / b := (div_sub_same h).symm theorem sub_div (a b c : K) : (a - b) / c = a / c - b / c := (div_sub_div_same _ _ _).symm /-- See `inv_sub_inv` for the more convenient version when `K` is commutative. -/ theorem inv_sub_inv' {a b : K} (ha : a ≠ 0) (hb : b ≠ 0) : a⁻¹ - b⁻¹ = a⁻¹ * (b - a) * b⁻¹ := let _ := invertibleOfNonzero ha; let _ := invertibleOfNonzero hb; invOf_sub_invOf a b theorem one_div_mul_sub_mul_one_div_eq_one_div_add_one_div (ha : a ≠ 0) (hb : b ≠ 0) : 1 / a * (b - a) * (1 / b) = 1 / a - 1 / b := by simpa only [one_div] using (inv_sub_inv' ha hb).symm -- see Note [lower instance priority] instance (priority := 100) DivisionRing.isDomain : IsDomain K := NoZeroDivisors.to_isDomain _		Mathlib/Algebra/Field/Basic.lean	122	122
/- Copyright (c) 2017 Mario Carneiro. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro -/ import Mathlib.Data.Finset.Pi import Mathlib.Data.Fintype.Basic import Mathlib.Data.Set.Finite.Basic /-! # Fintype instances for pi types -/ assert_not_exists OrderedRing MonoidWithZero open Finset Function variable {α β : Type} namespace Fintype variable [DecidableEq α] [Fintype α] {γ δ : α → Type} {s : ∀ a, Finset (γ a)} /-- Given for all `a : α` a finset `t a` of `δ a`, then one can define the finset `Fintype.piFinset t` of all functions taking values in `t a` for all `a`. This is the analogue of `Finset.pi` where the base finset is `univ` (but formally they are not the same, as there is an additional condition `i ∈ Finset.univ` in the `Finset.pi` definition). -/ def piFinset (t : ∀ a, Finset (δ a)) : Finset (∀ a, δ a) := (Finset.univ.pi t).map ⟨fun f a => f a (mem_univ a), fun _ _ => by simp +contextual [funext_iff]⟩ @[simp] theorem mem_piFinset {t : ∀ a, Finset (δ a)} {f : ∀ a, δ a} : f ∈ piFinset t ↔ ∀ a, f a ∈ t a := by constructor · simp only [piFinset, mem_map, and_imp, forall_prop_of_true, exists_prop, mem_univ, exists_imp, mem_pi] rintro g hg hgf a rw [← hgf] exact hg a · simp only [piFinset, mem_map, forall_prop_of_true, exists_prop, mem_univ, mem_pi] exact fun hf => ⟨fun a _ => f a, hf, rfl⟩ @[simp] theorem coe_piFinset (t : ∀ a, Finset (δ a)) : (piFinset t : Set (∀ a, δ a)) = Set.pi Set.univ fun a => t a :=	Set.ext fun x => by rw [Set.mem_univ_pi] exact Fintype.mem_piFinset theorem piFinset_subset (t₁ t₂ : ∀ a, Finset (δ a)) (h : ∀ a, t₁ a ⊆ t₂ a) :	Mathlib/Data/Fintype/Pi.lean	46	50
/- Copyright (c) 2020 Sébastien Gouëzel. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Sébastien Gouëzel -/ import Mathlib.Algebra.BigOperators.Fin import Mathlib.Algebra.Order.BigOperators.Group.Finset import Mathlib.Data.Finset.Sort /-! # Compositions A composition of a natural number `n` is a decomposition `n = i₀ + ... + i_{k-1}` of `n` into a sum of positive integers. Combinatorially, it corresponds to a decomposition of `{0, ..., n-1}` into non-empty blocks of consecutive integers, where the `iⱼ` are the lengths of the blocks. This notion is closely related to that of a partition of `n`, but in a composition of `n` the order of the `iⱼ`s matters. We implement two different structures covering these two viewpoints on compositions. The first one, made of a list of positive integers summing to `n`, is the main one and is called `Composition n`. The second one is useful for combinatorial arguments (for instance to show that the number of compositions of `n` is `2^(n-1)`). It is given by a subset of `{0, ..., n}` containing `0` and `n`, where the elements of the subset (other than `n`) correspond to the leftmost points of each block. The main API is built on `Composition n`, and we provide an equivalence between the two types. ## Main functions * `c : Composition n` is a structure, made of a list of integers which are all positive and add up to `n`. * `composition_card` states that the cardinality of `Composition n` is exactly `2^(n-1)`, which is proved by constructing an equiv with `CompositionAsSet n` (see below), which is itself in bijection with the subsets of `Fin (n-1)` (this holds even for `n = 0`, where `-` is nat subtraction). Let `c : Composition n` be a composition of `n`. Then * `c.blocks` is the list of blocks in `c`. * `c.length` is the number of blocks in the composition. * `c.blocksFun : Fin c.length → ℕ` is the realization of `c.blocks` as a function on `Fin c.length`. This is the main object when using compositions to understand the composition of analytic functions. * `c.sizeUpTo : ℕ → ℕ` is the sum of the size of the blocks up to `i`.; * `c.embedding i : Fin (c.blocksFun i) → Fin n` is the increasing embedding of the `i`-th block in `Fin n`; * `c.index j`, for `j : Fin n`, is the index of the block containing `j`. * `Composition.ones n` is the composition of `n` made of ones, i.e., `[1, ..., 1]`. * `Composition.single n (hn : 0 < n)` is the composition of `n` made of a single block of size `n`. Compositions can also be used to split lists. Let `l` be a list of length `n` and `c` a composition of `n`. * `l.splitWrtComposition c` is a list of lists, made of the slices of `l` corresponding to the blocks of `c`. * `join_splitWrtComposition` states that splitting a list and then joining it gives back the original list. * `splitWrtComposition_join` states that joining a list of lists, and then splitting it back according to the right composition, gives back the original list of lists. We turn to the second viewpoint on compositions, that we realize as a finset of `Fin (n+1)`. `c : CompositionAsSet n` is a structure made of a finset of `Fin (n+1)` called `c.boundaries` and proofs that it contains `0` and `n`. (Taking a finset of `Fin n` containing `0` would not make sense in the edge case `n = 0`, while the previous description works in all cases). The elements of this set (other than `n`) correspond to leftmost points of blocks. Thus, there is an equiv between `Composition n` and `CompositionAsSet n`. We only construct basic API on `CompositionAsSet` (notably `c.length` and `c.blocks`) to be able to construct this equiv, called `compositionEquiv n`. Since there is a straightforward equiv between `CompositionAsSet n` and finsets of `{1, ..., n-1}` (obtained by removing `0` and `n` from a `CompositionAsSet` and called `compositionAsSetEquiv n`), we deduce that `CompositionAsSet n` and `Composition n` are both fintypes of cardinality `2^(n - 1)` (see `compositionAsSet_card` and `composition_card`). ## Implementation details The main motivation for this structure and its API is in the construction of the composition of formal multilinear series, and the proof that the composition of analytic functions is analytic. The representation of a composition as a list is very handy as lists are very flexible and already have a well-developed API. ## Tags Composition, partition ## References <https://en.wikipedia.org/wiki/Composition_(combinatorics)> -/ assert_not_exists Field open List variable {n : ℕ} /-- A composition of `n` is a list of positive integers summing to `n`. -/ @[ext] structure Composition (n : ℕ) where /-- List of positive integers summing to `n` -/ blocks : List ℕ /-- Proof of positivity for `blocks` -/ blocks_pos : ∀ {i}, i ∈ blocks → 0 < i /-- Proof that `blocks` sums to `n` -/ blocks_sum : blocks.sum = n deriving DecidableEq attribute [simp] Composition.blocks_sum /-- Combinatorial viewpoint on a composition of `n`, by seeing it as non-empty blocks of consecutive integers in `{0, ..., n-1}`. We register every block by its left end-point, yielding a finset containing `0`. As this does not make sense for `n = 0`, we add `n` to this finset, and get a finset of `{0, ..., n}` containing `0` and `n`. This is the data in the structure `CompositionAsSet n`. -/ @[ext] structure CompositionAsSet (n : ℕ) where /-- Combinatorial viewpoint on a composition of `n` as consecutive integers `{0, ..., n-1}` -/ boundaries : Finset (Fin n.succ) /-- Proof that `0` is a member of `boundaries` -/ zero_mem : (0 : Fin n.succ) ∈ boundaries /-- Last element of the composition -/ getLast_mem : Fin.last n ∈ boundaries deriving DecidableEq instance {n : ℕ} : Inhabited (CompositionAsSet n) := ⟨⟨Finset.univ, Finset.mem_univ _, Finset.mem_univ _⟩⟩ attribute [simp] CompositionAsSet.zero_mem CompositionAsSet.getLast_mem /-! ### Compositions A composition of an integer `n` is a decomposition `n = i₀ + ... + i_{k-1}` of `n` into a sum of positive integers. -/ namespace Composition variable (c : Composition n) instance (n : ℕ) : ToString (Composition n) := ⟨fun c => toString c.blocks⟩ /-- The length of a composition, i.e., the number of blocks in the composition. -/ abbrev length : ℕ := c.blocks.length theorem blocks_length : c.blocks.length = c.length := rfl /-- The blocks of a composition, seen as a function on `Fin c.length`. When composing analytic functions using compositions, this is the main player. -/ def blocksFun : Fin c.length → ℕ := c.blocks.get @[simp] theorem ofFn_blocksFun : ofFn c.blocksFun = c.blocks := ofFn_get _ @[simp] theorem sum_blocksFun : ∑ i, c.blocksFun i = n := by conv_rhs => rw [← c.blocks_sum, ← ofFn_blocksFun, sum_ofFn] @[simp] theorem blocksFun_mem_blocks (i : Fin c.length) : c.blocksFun i ∈ c.blocks := get_mem _ _ theorem one_le_blocks {i : ℕ} (h : i ∈ c.blocks) : 1 ≤ i := c.blocks_pos h theorem blocks_le {i : ℕ} (h : i ∈ c.blocks) : i ≤ n := by rw [← c.blocks_sum] exact List.le_sum_of_mem h @[simp] theorem one_le_blocks' {i : ℕ} (h : i < c.length) : 1 ≤ c.blocks[i] := c.one_le_blocks (get_mem (blocks c) _) @[simp] theorem blocks_pos' (i : ℕ) (h : i < c.length) : 0 < c.blocks[i] := c.one_le_blocks' h @[simp] theorem one_le_blocksFun (i : Fin c.length) : 1 ≤ c.blocksFun i := c.one_le_blocks (c.blocksFun_mem_blocks i) @[simp] theorem blocksFun_le {n} (c : Composition n) (i : Fin c.length) : c.blocksFun i ≤ n := c.blocks_le <\| getElem_mem _ @[simp] theorem length_le : c.length ≤ n := by conv_rhs => rw [← c.blocks_sum] exact length_le_sum_of_one_le _ fun i hi => c.one_le_blocks hi @[simp] theorem blocks_eq_nil : c.blocks = [] ↔ n = 0 := by constructor · intro h simpa using congr(List.sum $h) · rintro rfl rw [← length_eq_zero_iff, ← nonpos_iff_eq_zero] exact c.length_le protected theorem length_eq_zero : c.length = 0 ↔ n = 0 := by simp @[simp] theorem length_pos_iff : 0 < c.length ↔ 0 < n := by simp [pos_iff_ne_zero] alias ⟨_, length_pos_of_pos⟩ := length_pos_iff /-- The sum of the sizes of the blocks in a composition up to `i`. -/ def sizeUpTo (i : ℕ) : ℕ := (c.blocks.take i).sum @[simp] theorem sizeUpTo_zero : c.sizeUpTo 0 = 0 := by simp [sizeUpTo] theorem sizeUpTo_ofLength_le (i : ℕ) (h : c.length ≤ i) : c.sizeUpTo i = n := by dsimp [sizeUpTo] convert c.blocks_sum exact take_of_length_le h @[simp] theorem sizeUpTo_length : c.sizeUpTo c.length = n := c.sizeUpTo_ofLength_le c.length le_rfl theorem sizeUpTo_le (i : ℕ) : c.sizeUpTo i ≤ n := by conv_rhs => rw [← c.blocks_sum, ← sum_take_add_sum_drop _ i] exact Nat.le_add_right _ _ theorem sizeUpTo_succ {i : ℕ} (h : i < c.length) : c.sizeUpTo (i + 1) = c.sizeUpTo i + c.blocks[i] := by simp only [sizeUpTo] rw [sum_take_succ _ _ h] theorem sizeUpTo_succ' (i : Fin c.length) : c.sizeUpTo ((i : ℕ) + 1) = c.sizeUpTo i + c.blocksFun i := c.sizeUpTo_succ i.2 theorem sizeUpTo_strict_mono {i : ℕ} (h : i < c.length) : c.sizeUpTo i < c.sizeUpTo (i + 1) := by rw [c.sizeUpTo_succ h] simp theorem monotone_sizeUpTo : Monotone c.sizeUpTo := monotone_sum_take _ /-- The `i`-th boundary of a composition, i.e., the leftmost point of the `i`-th block. We include a virtual point at the right of the last block, to make for a nice equiv with `CompositionAsSet n`. -/ def boundary : Fin (c.length + 1) ↪o Fin (n + 1) := (OrderEmbedding.ofStrictMono fun i => ⟨c.sizeUpTo i, Nat.lt_succ_of_le (c.sizeUpTo_le i)⟩) <\| Fin.strictMono_iff_lt_succ.2 fun ⟨_, hi⟩ => c.sizeUpTo_strict_mono hi @[simp] theorem boundary_zero : c.boundary 0 = 0 := by simp [boundary, Fin.ext_iff] @[simp] theorem boundary_last : c.boundary (Fin.last c.length) = Fin.last n := by simp [boundary, Fin.ext_iff] /-- The boundaries of a composition, i.e., the leftmost point of all the blocks. We include a virtual point at the right of the last block, to make for a nice equiv with `CompositionAsSet n`. -/ def boundaries : Finset (Fin (n + 1)) := Finset.univ.map c.boundary.toEmbedding theorem card_boundaries_eq_succ_length : c.boundaries.card = c.length + 1 := by simp [boundaries] /-- To `c : Composition n`, one can associate a `CompositionAsSet n` by registering the leftmost point of each block, and adding a virtual point at the right of the last block. -/ def toCompositionAsSet : CompositionAsSet n where boundaries := c.boundaries zero_mem := by simp only [boundaries, Finset.mem_univ, exists_prop_of_true, Finset.mem_map] exact ⟨0, And.intro True.intro rfl⟩ getLast_mem := by simp only [boundaries, Finset.mem_univ, exists_prop_of_true, Finset.mem_map] exact ⟨Fin.last c.length, And.intro True.intro c.boundary_last⟩ /-- The canonical increasing bijection between `Fin (c.length + 1)` and `c.boundaries` is exactly `c.boundary`. -/ theorem orderEmbOfFin_boundaries : c.boundaries.orderEmbOfFin c.card_boundaries_eq_succ_length = c.boundary := by refine (Finset.orderEmbOfFin_unique' _ ?_).symm exact fun i => (Finset.mem_map' _).2 (Finset.mem_univ _) /-- Embedding the `i`-th block of a composition (identified with `Fin (c.blocksFun i)`) into `Fin n` at the relevant position. -/ def embedding (i : Fin c.length) : Fin (c.blocksFun i) ↪o Fin n := (Fin.natAddOrderEmb <\| c.sizeUpTo i).trans <\| Fin.castLEOrderEmb <\| calc c.sizeUpTo i + c.blocksFun i = c.sizeUpTo (i + 1) := (c.sizeUpTo_succ i.2).symm _ ≤ c.sizeUpTo c.length := monotone_sum_take _ i.2 _ = n := c.sizeUpTo_length @[simp] theorem coe_embedding (i : Fin c.length) (j : Fin (c.blocksFun i)) : (c.embedding i j : ℕ) = c.sizeUpTo i + j := rfl /-- `index_exists` asserts there is some `i` with `j < c.sizeUpTo (i+1)`. In the next definition `index` we use `Nat.find` to produce the minimal such index. -/ theorem index_exists {j : ℕ} (h : j < n) : ∃ i : ℕ, j < c.sizeUpTo (i + 1) ∧ i < c.length := by have n_pos : 0 < n := lt_of_le_of_lt (zero_le j) h have : 0 < c.blocks.sum := by rwa [← c.blocks_sum] at n_pos have length_pos : 0 < c.blocks.length := length_pos_of_sum_pos (blocks c) this refine ⟨c.length - 1, ?_, Nat.pred_lt (ne_of_gt length_pos)⟩ have : c.length - 1 + 1 = c.length := Nat.succ_pred_eq_of_pos length_pos simp [this, h] /-- `c.index j` is the index of the block in the composition `c` containing `j`. -/ def index (j : Fin n) : Fin c.length := ⟨Nat.find (c.index_exists j.2), (Nat.find_spec (c.index_exists j.2)).2⟩ theorem lt_sizeUpTo_index_succ (j : Fin n) : (j : ℕ) < c.sizeUpTo (c.index j).succ := (Nat.find_spec (c.index_exists j.2)).1 theorem sizeUpTo_index_le (j : Fin n) : c.sizeUpTo (c.index j) ≤ j := by by_contra H set i := c.index j push_neg at H have i_pos : (0 : ℕ) < i := by by_contra! i_pos revert H simp [nonpos_iff_eq_zero.1 i_pos, c.sizeUpTo_zero] let i₁ := (i : ℕ).pred have i₁_lt_i : i₁ < i := Nat.pred_lt (ne_of_gt i_pos) have i₁_succ : i₁ + 1 = i := Nat.succ_pred_eq_of_pos i_pos have := Nat.find_min (c.index_exists j.2) i₁_lt_i simp [lt_trans i₁_lt_i (c.index j).2, i₁_succ] at this exact Nat.lt_le_asymm H this /-- Mapping an element `j` of `Fin n` to the element in the block containing it, identified with `Fin (c.blocksFun (c.index j))` through the canonical increasing bijection. -/ def invEmbedding (j : Fin n) : Fin (c.blocksFun (c.index j)) := ⟨j - c.sizeUpTo (c.index j), by rw [tsub_lt_iff_right, add_comm, ← sizeUpTo_succ'] · exact lt_sizeUpTo_index_succ _ _ · exact sizeUpTo_index_le _ _⟩ @[simp] theorem coe_invEmbedding (j : Fin n) : (c.invEmbedding j : ℕ) = j - c.sizeUpTo (c.index j) := rfl theorem embedding_comp_inv (j : Fin n) : c.embedding (c.index j) (c.invEmbedding j) = j := by rw [Fin.ext_iff] apply add_tsub_cancel_of_le (c.sizeUpTo_index_le j) theorem mem_range_embedding_iff {j : Fin n} {i : Fin c.length} : j ∈ Set.range (c.embedding i) ↔ c.sizeUpTo i ≤ j ∧ (j : ℕ) < c.sizeUpTo (i : ℕ).succ := by constructor · intro h rcases Set.mem_range.2 h with ⟨k, hk⟩ rw [Fin.ext_iff] at hk dsimp at hk rw [← hk] simp [sizeUpTo_succ', k.is_lt] · intro h apply Set.mem_range.2 refine ⟨⟨j - c.sizeUpTo i, ?_⟩, ?_⟩ · rw [tsub_lt_iff_left, ← sizeUpTo_succ'] · exact h.2 · exact h.1 · rw [Fin.ext_iff] exact add_tsub_cancel_of_le h.1 /-- The embeddings of different blocks of a composition are disjoint. -/ theorem disjoint_range {i₁ i₂ : Fin c.length} (h : i₁ ≠ i₂) : Disjoint (Set.range (c.embedding i₁)) (Set.range (c.embedding i₂)) := by classical wlog h' : i₁ < i₂ · exact (this c h.symm (h.lt_or_lt.resolve_left h')).symm by_contra d obtain ⟨x, hx₁, hx₂⟩ : ∃ x : Fin n, x ∈ Set.range (c.embedding i₁) ∧ x ∈ Set.range (c.embedding i₂) := Set.not_disjoint_iff.1 d have A : (i₁ : ℕ).succ ≤ i₂ := Nat.succ_le_of_lt h' apply lt_irrefl (x : ℕ) calc (x : ℕ) < c.sizeUpTo (i₁ : ℕ).succ := (c.mem_range_embedding_iff.1 hx₁).2 _ ≤ c.sizeUpTo (i₂ : ℕ) := monotone_sum_take _ A _ ≤ x := (c.mem_range_embedding_iff.1 hx₂).1 theorem mem_range_embedding (j : Fin n) : j ∈ Set.range (c.embedding (c.index j)) := by have : c.embedding (c.index j) (c.invEmbedding j) ∈ Set.range (c.embedding (c.index j)) := Set.mem_range_self _ rwa [c.embedding_comp_inv j] at this theorem mem_range_embedding_iff' {j : Fin n} {i : Fin c.length} : j ∈ Set.range (c.embedding i) ↔ i = c.index j := by constructor · rw [← not_imp_not] intro h exact Set.disjoint_right.1 (c.disjoint_range h) (c.mem_range_embedding j) · intro h rw [h] exact c.mem_range_embedding j theorem index_embedding (i : Fin c.length) (j : Fin (c.blocksFun i)) : c.index (c.embedding i j) = i := by symm rw [← mem_range_embedding_iff'] apply Set.mem_range_self theorem invEmbedding_comp (i : Fin c.length) (j : Fin (c.blocksFun i)) : (c.invEmbedding (c.embedding i j) : ℕ) = j := by simp_rw [coe_invEmbedding, index_embedding, coe_embedding, add_tsub_cancel_left] /-- Equivalence between the disjoint union of the blocks (each of them seen as `Fin (c.blocksFun i)`) with `Fin n`. -/ def blocksFinEquiv : (Σi : Fin c.length, Fin (c.blocksFun i)) ≃ Fin n where toFun x := c.embedding x.1 x.2 invFun j := ⟨c.index j, c.invEmbedding j⟩ left_inv x := by rcases x with ⟨i, y⟩ dsimp congr; · exact c.index_embedding _ _ rw [Fin.heq_ext_iff] · exact c.invEmbedding_comp _ _ · rw [c.index_embedding] right_inv j := c.embedding_comp_inv j theorem blocksFun_congr {n₁ n₂ : ℕ} (c₁ : Composition n₁) (c₂ : Composition n₂) (i₁ : Fin c₁.length) (i₂ : Fin c₂.length) (hn : n₁ = n₂) (hc : c₁.blocks = c₂.blocks) (hi : (i₁ : ℕ) = i₂) : c₁.blocksFun i₁ = c₂.blocksFun i₂ := by cases hn rw [← Composition.ext_iff] at hc cases hc congr rwa [Fin.ext_iff] /-- Two compositions (possibly of different integers) coincide if and only if they have the same sequence of blocks. -/ theorem sigma_eq_iff_blocks_eq {c : Σ n, Composition n} {c' : Σ n, Composition n} : c = c' ↔ c.2.blocks = c'.2.blocks := by refine ⟨fun H => by rw [H], fun H => ?_⟩ rcases c with ⟨n, c⟩ rcases c' with ⟨n', c'⟩ have : n = n' := by rw [← c.blocks_sum, ← c'.blocks_sum, H] induction this congr ext1 exact H /-! ### The composition `Composition.ones` -/ /-- The composition made of blocks all of size `1`. -/ def ones (n : ℕ) : Composition n := ⟨replicate n (1 : ℕ), fun {i} hi => by simp [List.eq_of_mem_replicate hi], by simp⟩ instance {n : ℕ} : Inhabited (Composition n) := ⟨Composition.ones n⟩ @[simp] theorem ones_length (n : ℕ) : (ones n).length = n := List.length_replicate @[simp] theorem ones_blocks (n : ℕ) : (ones n).blocks = replicate n (1 : ℕ) := rfl @[simp] theorem ones_blocksFun (n : ℕ) (i : Fin (ones n).length) : (ones n).blocksFun i = 1 := by simp only [blocksFun, ones, get_eq_getElem, getElem_replicate] @[simp] theorem ones_sizeUpTo (n : ℕ) (i : ℕ) : (ones n).sizeUpTo i = min i n := by simp [sizeUpTo, ones_blocks, take_replicate] @[simp] theorem ones_embedding (i : Fin (ones n).length) (h : 0 < (ones n).blocksFun i) : (ones n).embedding i ⟨0, h⟩ = ⟨i, lt_of_lt_of_le i.2 (ones n).length_le⟩ := by ext simpa using i.2.le theorem eq_ones_iff {c : Composition n} : c = ones n ↔ ∀ i ∈ c.blocks, i = 1 := by constructor · rintro rfl exact fun i => eq_of_mem_replicate · intro H ext1 have A : c.blocks = replicate c.blocks.length 1 := eq_replicate_of_mem H have : c.blocks.length = n := by conv_rhs => rw [← c.blocks_sum, A] simp rw [A, this, ones_blocks] theorem ne_ones_iff {c : Composition n} : c ≠ ones n ↔ ∃ i ∈ c.blocks, 1 < i := by refine (not_congr eq_ones_iff).trans ?_ have : ∀ j ∈ c.blocks, j = 1 ↔ j ≤ 1 := fun j hj => by simp [le_antisymm_iff, c.one_le_blocks hj] simp +contextual [this] theorem eq_ones_iff_length {c : Composition n} : c = ones n ↔ c.length = n := by constructor · rintro rfl exact ones_length n · contrapose intro H length_n apply lt_irrefl n calc n = ∑ i : Fin c.length, 1 := by simp [length_n]	_ < ∑ i : Fin c.length, c.blocksFun i := by { obtain ⟨i, hi, i_blocks⟩ : ∃ i ∈ c.blocks, 1 < i := ne_ones_iff.1 H rw [← ofFn_blocksFun, mem_ofFn' c.blocksFun, Set.mem_range] at hi obtain ⟨j : Fin c.length, hj : c.blocksFun j = i⟩ := hi rw [← hj] at i_blocks exact Finset.sum_lt_sum (fun i _ => one_le_blocksFun c i) ⟨j, Finset.mem_univ _, i_blocks⟩ } _ = n := c.sum_blocksFun theorem eq_ones_iff_le_length {c : Composition n} : c = ones n ↔ n ≤ c.length := by	Mathlib/Combinatorics/Enumerative/Composition.lean	505	515
/- Copyright (c) 2022 Markus Himmel. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Markus Himmel -/ import Mathlib.CategoryTheory.EpiMono import Mathlib.CategoryTheory.Limits.Shapes.StrongEpi import Mathlib.CategoryTheory.LiftingProperties.Adjunction /-! # Preservation and reflection of monomorphisms and epimorphisms We provide typeclasses that state that a functor preserves or reflects monomorphisms or epimorphisms. -/ open CategoryTheory universe v₁ v₂ v₃ u₁ u₂ u₃ namespace CategoryTheory.Functor variable {C : Type u₁} [Category.{v₁} C] {D : Type u₂} [Category.{v₂} D] {E : Type u₃} [Category.{v₃} E] /-- A functor preserves monomorphisms if it maps monomorphisms to monomorphisms. -/ class PreservesMonomorphisms (F : C ⥤ D) : Prop where /-- A functor preserves monomorphisms if it maps monomorphisms to monomorphisms. -/ preserves : ∀ {X Y : C} (f : X ⟶ Y) [Mono f], Mono (F.map f) instance map_mono (F : C ⥤ D) [PreservesMonomorphisms F] {X Y : C} (f : X ⟶ Y) [Mono f] : Mono (F.map f) := PreservesMonomorphisms.preserves f /-- A functor preserves epimorphisms if it maps epimorphisms to epimorphisms. -/ class PreservesEpimorphisms (F : C ⥤ D) : Prop where /-- A functor preserves epimorphisms if it maps epimorphisms to epimorphisms. -/ preserves : ∀ {X Y : C} (f : X ⟶ Y) [Epi f], Epi (F.map f) instance map_epi (F : C ⥤ D) [PreservesEpimorphisms F] {X Y : C} (f : X ⟶ Y) [Epi f] : Epi (F.map f) := PreservesEpimorphisms.preserves f /-- A functor reflects monomorphisms if morphisms that are mapped to monomorphisms are themselves monomorphisms. -/ class ReflectsMonomorphisms (F : C ⥤ D) : Prop where /-- A functor reflects monomorphisms if morphisms that are mapped to monomorphisms are themselves monomorphisms. -/ reflects : ∀ {X Y : C} (f : X ⟶ Y), Mono (F.map f) → Mono f theorem mono_of_mono_map (F : C ⥤ D) [ReflectsMonomorphisms F] {X Y : C} {f : X ⟶ Y} (h : Mono (F.map f)) : Mono f := ReflectsMonomorphisms.reflects f h /-- A functor reflects epimorphisms if morphisms that are mapped to epimorphisms are themselves epimorphisms. -/ class ReflectsEpimorphisms (F : C ⥤ D) : Prop where /-- A functor reflects epimorphisms if morphisms that are mapped to epimorphisms are themselves epimorphisms. -/ reflects : ∀ {X Y : C} (f : X ⟶ Y), Epi (F.map f) → Epi f theorem epi_of_epi_map (F : C ⥤ D) [ReflectsEpimorphisms F] {X Y : C} {f : X ⟶ Y} (h : Epi (F.map f)) : Epi f := ReflectsEpimorphisms.reflects f h instance preservesMonomorphisms_comp (F : C ⥤ D) (G : D ⥤ E) [PreservesMonomorphisms F] [PreservesMonomorphisms G] : PreservesMonomorphisms (F ⋙ G) where preserves f h := by rw [comp_map] exact inferInstance instance preservesEpimorphisms_comp (F : C ⥤ D) (G : D ⥤ E) [PreservesEpimorphisms F] [PreservesEpimorphisms G] : PreservesEpimorphisms (F ⋙ G) where preserves f h := by rw [comp_map] exact inferInstance instance reflectsMonomorphisms_comp (F : C ⥤ D) (G : D ⥤ E) [ReflectsMonomorphisms F] [ReflectsMonomorphisms G] : ReflectsMonomorphisms (F ⋙ G) where reflects _ h := F.mono_of_mono_map (G.mono_of_mono_map h) instance reflectsEpimorphisms_comp (F : C ⥤ D) (G : D ⥤ E) [ReflectsEpimorphisms F] [ReflectsEpimorphisms G] : ReflectsEpimorphisms (F ⋙ G) where reflects _ h := F.epi_of_epi_map (G.epi_of_epi_map h) theorem preservesEpimorphisms_of_preserves_of_reflects (F : C ⥤ D) (G : D ⥤ E) [PreservesEpimorphisms (F ⋙ G)] [ReflectsEpimorphisms G] : PreservesEpimorphisms F := ⟨fun f _ => G.epi_of_epi_map <\| show Epi ((F ⋙ G).map f) from inferInstance⟩ theorem preservesMonomorphisms_of_preserves_of_reflects (F : C ⥤ D) (G : D ⥤ E) [PreservesMonomorphisms (F ⋙ G)] [ReflectsMonomorphisms G] : PreservesMonomorphisms F := ⟨fun f _ => G.mono_of_mono_map <\| show Mono ((F ⋙ G).map f) from inferInstance⟩ theorem reflectsEpimorphisms_of_preserves_of_reflects (F : C ⥤ D) (G : D ⥤ E) [PreservesEpimorphisms G] [ReflectsEpimorphisms (F ⋙ G)] : ReflectsEpimorphisms F := ⟨fun f _ => (F ⋙ G).epi_of_epi_map <\| show Epi (G.map (F.map f)) from inferInstance⟩ theorem reflectsMonomorphisms_of_preserves_of_reflects (F : C ⥤ D) (G : D ⥤ E) [PreservesMonomorphisms G] [ReflectsMonomorphisms (F ⋙ G)] : ReflectsMonomorphisms F := ⟨fun f _ => (F ⋙ G).mono_of_mono_map <\| show Mono (G.map (F.map f)) from inferInstance⟩ theorem preservesMonomorphisms.of_iso {F G : C ⥤ D} [PreservesMonomorphisms F] (α : F ≅ G) : PreservesMonomorphisms G := { preserves := fun {X} {Y} f h => by suffices G.map f = (α.app X).inv ≫ F.map f ≫ (α.app Y).hom from this ▸ mono_comp _ _ rw [Iso.eq_inv_comp, Iso.app_hom, Iso.app_hom, NatTrans.naturality] } theorem preservesMonomorphisms.iso_iff {F G : C ⥤ D} (α : F ≅ G) : PreservesMonomorphisms F ↔ PreservesMonomorphisms G := ⟨fun _ => preservesMonomorphisms.of_iso α, fun _ => preservesMonomorphisms.of_iso α.symm⟩ theorem preservesEpimorphisms.of_iso {F G : C ⥤ D} [PreservesEpimorphisms F] (α : F ≅ G) : PreservesEpimorphisms G := { preserves := fun {X} {Y} f h => by suffices G.map f = (α.app X).inv ≫ F.map f ≫ (α.app Y).hom from this ▸ epi_comp _ _ rw [Iso.eq_inv_comp, Iso.app_hom, Iso.app_hom, NatTrans.naturality] } theorem preservesEpimorphisms.iso_iff {F G : C ⥤ D} (α : F ≅ G) : PreservesEpimorphisms F ↔ PreservesEpimorphisms G := ⟨fun _ => preservesEpimorphisms.of_iso α, fun _ => preservesEpimorphisms.of_iso α.symm⟩ theorem reflectsMonomorphisms.of_iso {F G : C ⥤ D} [ReflectsMonomorphisms F] (α : F ≅ G) : ReflectsMonomorphisms G := { reflects := fun {X} {Y} f h => by apply F.mono_of_mono_map suffices F.map f = (α.app X).hom ≫ G.map f ≫ (α.app Y).inv from this ▸ mono_comp _ _ rw [← Category.assoc, Iso.eq_comp_inv, Iso.app_hom, Iso.app_hom, NatTrans.naturality] } theorem reflectsMonomorphisms.iso_iff {F G : C ⥤ D} (α : F ≅ G) : ReflectsMonomorphisms F ↔ ReflectsMonomorphisms G := ⟨fun _ => reflectsMonomorphisms.of_iso α, fun _ => reflectsMonomorphisms.of_iso α.symm⟩ theorem reflectsEpimorphisms.of_iso {F G : C ⥤ D} [ReflectsEpimorphisms F] (α : F ≅ G) : ReflectsEpimorphisms G := { reflects := fun {X} {Y} f h => by apply F.epi_of_epi_map suffices F.map f = (α.app X).hom ≫ G.map f ≫ (α.app Y).inv from this ▸ epi_comp _ _ rw [← Category.assoc, Iso.eq_comp_inv, Iso.app_hom, Iso.app_hom, NatTrans.naturality] } theorem reflectsEpimorphisms.iso_iff {F G : C ⥤ D} (α : F ≅ G) : ReflectsEpimorphisms F ↔ ReflectsEpimorphisms G := ⟨fun _ => reflectsEpimorphisms.of_iso α, fun _ => reflectsEpimorphisms.of_iso α.symm⟩ theorem preservesEpimorphsisms_of_adjunction {F : C ⥤ D} {G : D ⥤ C} (adj : F ⊣ G) : PreservesEpimorphisms F := { preserves := fun {X} {Y} f hf => ⟨by intro Z g h H replace H := congr_arg (adj.homEquiv X Z) H rwa [adj.homEquiv_naturality_left, adj.homEquiv_naturality_left, cancel_epi, Equiv.apply_eq_iff_eq] at H⟩ } instance (priority := 100) preservesEpimorphisms_of_isLeftAdjoint (F : C ⥤ D) [IsLeftAdjoint F] : PreservesEpimorphisms F := preservesEpimorphsisms_of_adjunction (Adjunction.ofIsLeftAdjoint F) theorem preservesMonomorphisms_of_adjunction {F : C ⥤ D} {G : D ⥤ C} (adj : F ⊣ G) : PreservesMonomorphisms G := { preserves := fun {X} {Y} f hf => ⟨by intro Z g h H replace H := congr_arg (adj.homEquiv Z Y).symm H rwa [adj.homEquiv_naturality_right_symm, adj.homEquiv_naturality_right_symm, cancel_mono, Equiv.apply_eq_iff_eq] at H⟩ } instance (priority := 100) preservesMonomorphisms_of_isRightAdjoint (F : C ⥤ D) [IsRightAdjoint F] : PreservesMonomorphisms F := preservesMonomorphisms_of_adjunction (Adjunction.ofIsRightAdjoint F) instance (priority := 100) reflectsMonomorphisms_of_faithful (F : C ⥤ D) [Faithful F] : ReflectsMonomorphisms F where reflects {X} {Y} f _ := ⟨fun {Z} g h hgh => F.map_injective ((cancel_mono (F.map f)).1 (by rw [← F.map_comp, hgh, F.map_comp]))⟩ instance (priority := 100) reflectsEpimorphisms_of_faithful (F : C ⥤ D) [Faithful F] : ReflectsEpimorphisms F where reflects {X} {Y} f _ := ⟨fun {Z} g h hgh => F.map_injective ((cancel_epi (F.map f)).1 (by rw [← F.map_comp, hgh, F.map_comp]))⟩ section variable (F : C ⥤ D) {X Y : C} (f : X ⟶ Y) /-- If `F` is a fully faithful functor, split epimorphisms are preserved and reflected by `F`. -/ noncomputable def splitEpiEquiv [Full F] [Faithful F] : SplitEpi f ≃ SplitEpi (F.map f) where toFun f := f.map F invFun s := ⟨F.preimage s.section_, by apply F.map_injective simp only [map_comp, map_preimage, map_id] apply SplitEpi.id⟩ left_inv := by aesop_cat right_inv x := by aesop_cat @[simp] theorem isSplitEpi_iff [Full F] [Faithful F] : IsSplitEpi (F.map f) ↔ IsSplitEpi f := by constructor · intro h exact IsSplitEpi.mk' ((splitEpiEquiv F f).invFun h.exists_splitEpi.some) · intro h exact IsSplitEpi.mk' ((splitEpiEquiv F f).toFun h.exists_splitEpi.some) /-- If `F` is a fully faithful functor, split monomorphisms are preserved and reflected by `F`. -/ noncomputable def splitMonoEquiv [Full F] [Faithful F] : SplitMono f ≃ SplitMono (F.map f) where toFun f := f.map F invFun s := ⟨F.preimage s.retraction, by apply F.map_injective simp only [map_comp, map_preimage, map_id] apply SplitMono.id⟩ left_inv := by aesop_cat right_inv x := by aesop_cat @[simp] theorem isSplitMono_iff [Full F] [Faithful F] : IsSplitMono (F.map f) ↔ IsSplitMono f := by constructor · intro h exact IsSplitMono.mk' ((splitMonoEquiv F f).invFun h.exists_splitMono.some) · intro h exact IsSplitMono.mk' ((splitMonoEquiv F f).toFun h.exists_splitMono.some) @[simp] theorem epi_map_iff_epi [hF₁ : PreservesEpimorphisms F] [hF₂ : ReflectsEpimorphisms F] : Epi (F.map f) ↔ Epi f := by constructor · exact F.epi_of_epi_map · intro h exact F.map_epi f @[simp] theorem mono_map_iff_mono [hF₁ : PreservesMonomorphisms F] [hF₂ : ReflectsMonomorphisms F] : Mono (F.map f) ↔ Mono f := by constructor · exact F.mono_of_mono_map · intro h exact F.map_mono f /-- If `F : C ⥤ D` is an equivalence of categories and `C` is a `split_epi_category`, then `D` also is. -/ theorem splitEpiCategoryImpOfIsEquivalence [IsEquivalence F] [SplitEpiCategory C] : SplitEpiCategory D := ⟨fun {X} {Y} f => by intro rw [← F.inv.isSplitEpi_iff f] apply isSplitEpi_of_epi⟩ end end CategoryTheory.Functor namespace CategoryTheory.Adjunction variable {C D : Type*} [Category C] [Category D] {F : C ⥤ D} {F' : D ⥤ C} {A B : C} theorem strongEpi_map_of_strongEpi (adj : F ⊣ F') (f : A ⟶ B) [F'.PreservesMonomorphisms] [F.PreservesEpimorphisms] [StrongEpi f] : StrongEpi (F.map f) := ⟨inferInstance, fun X Y Z => by intro rw [adj.hasLiftingProperty_iff] infer_instance⟩ instance strongEpi_map_of_isEquivalence [F.IsEquivalence] (f : A ⟶ B) [_h : StrongEpi f] :	StrongEpi (F.map f) := F.asEquivalence.toAdjunction.strongEpi_map_of_strongEpi f instance (adj : F ⊣ F') {X : C} {Y : D} (f : F.obj X ⟶ Y) [hf : Mono f] [F.ReflectsMonomorphisms] : Mono (adj.homEquiv _ _ f) := F.mono_of_mono_map <\| by	Mathlib/CategoryTheory/Functor/EpiMono.lean	264	269
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Mario Carneiro -/ import Mathlib.MeasureTheory.MeasurableSpace.MeasurablyGenerated import Mathlib.MeasureTheory.Measure.NullMeasurable import Mathlib.Order.Interval.Set.Monotone /-! # Measure spaces The definition of a measure and a measure space are in `MeasureTheory.MeasureSpaceDef`, with only a few basic properties. This file provides many more properties of these objects. This separation allows the measurability tactic to import only the file `MeasureSpaceDef`, and to be available in `MeasureSpace` (through `MeasurableSpace`). Given a measurable space `α`, a measure on `α` is a function that sends measurable sets to the extended nonnegative reals that satisfies the following conditions: 1. `μ ∅ = 0`; 2. `μ` is countably additive. This means that the measure of a countable union of pairwise disjoint sets is equal to the measure of the individual sets. Every measure can be canonically extended to an outer measure, so that it assigns values to all subsets, not just the measurable subsets. On the other hand, a measure that is countably additive on measurable sets can be restricted to measurable sets to obtain a measure. In this file a measure is defined to be an outer measure that is countably additive on measurable sets, with the additional assumption that the outer measure is the canonical extension of the restricted measure. Measures on `α` form a complete lattice, and are closed under scalar multiplication with `ℝ≥0∞`. Given a measure, the null sets are the sets where `μ s = 0`, where `μ` denotes the corresponding outer measure (so `s` might not be measurable). We can then define the completion of `μ` as the measure on the least `σ`-algebra that also contains all null sets, by defining the measure to be `0` on the null sets. ## Main statements * `completion` is the completion of a measure to all null measurable sets. * `Measure.ofMeasurable` and `OuterMeasure.toMeasure` are two important ways to define a measure. ## Implementation notes Given `μ : Measure α`, `μ s` is the value of the outer measure applied to `s`. This conveniently allows us to apply the measure to sets without proving that they are measurable. We get countable subadditivity for all sets, but only countable additivity for measurable sets. You often don't want to define a measure via its constructor. Two ways that are sometimes more convenient: * `Measure.ofMeasurable` is a way to define a measure by only giving its value on measurable sets and proving the properties (1) and (2) mentioned above. * `OuterMeasure.toMeasure` is a way of obtaining a measure from an outer measure by showing that all measurable sets in the measurable space are Carathéodory measurable. To prove that two measures are equal, there are multiple options: * `ext`: two measures are equal if they are equal on all measurable sets. * `ext_of_generateFrom_of_iUnion`: two measures are equal if they are equal on a π-system generating the measurable sets, if the π-system contains a spanning increasing sequence of sets where the measures take finite value (in particular the measures are σ-finite). This is a special case of the more general `ext_of_generateFrom_of_cover` * `ext_of_generate_finite`: two finite measures are equal if they are equal on a π-system generating the measurable sets. This is a special case of `ext_of_generateFrom_of_iUnion` using `C ∪ {univ}`, but is easier to work with. A `MeasureSpace` is a class that is a measurable space with a canonical measure. The measure is denoted `volume`. ## References * <https://en.wikipedia.org/wiki/Measure_(mathematics)> * <https://en.wikipedia.org/wiki/Complete_measure> * <https://en.wikipedia.org/wiki/Almost_everywhere> ## Tags measure, almost everywhere, measure space, completion, null set, null measurable set -/ noncomputable section open Set open Filter hiding map open Function MeasurableSpace Topology Filter ENNReal NNReal Interval MeasureTheory open scoped symmDiff variable {α β γ δ ι R R' : Type} namespace MeasureTheory section variable {m : MeasurableSpace α} {μ μ₁ μ₂ : Measure α} {s s₁ s₂ t : Set α} instance ae_isMeasurablyGenerated : IsMeasurablyGenerated (ae μ) := ⟨fun _s hs => let ⟨t, hst, htm, htμ⟩ := exists_measurable_superset_of_null hs ⟨tᶜ, compl_mem_ae_iff.2 htμ, htm.compl, compl_subset_comm.1 hst⟩⟩ /-- See also `MeasureTheory.ae_restrict_uIoc_iff`. -/ theorem ae_uIoc_iff [LinearOrder α] {a b : α} {P : α → Prop} : (∀ᵐ x ∂μ, x ∈ Ι a b → P x) ↔ (∀ᵐ x ∂μ, x ∈ Ioc a b → P x) ∧ ∀ᵐ x ∂μ, x ∈ Ioc b a → P x := by simp only [uIoc_eq_union, mem_union, or_imp, eventually_and] theorem measure_union (hd : Disjoint s₁ s₂) (h : MeasurableSet s₂) : μ (s₁ ∪ s₂) = μ s₁ + μ s₂ := measure_union₀ h.nullMeasurableSet hd.aedisjoint theorem measure_union' (hd : Disjoint s₁ s₂) (h : MeasurableSet s₁) : μ (s₁ ∪ s₂) = μ s₁ + μ s₂ := measure_union₀' h.nullMeasurableSet hd.aedisjoint theorem measure_inter_add_diff (s : Set α) (ht : MeasurableSet t) : μ (s ∩ t) + μ (s \ t) = μ s := measure_inter_add_diff₀ _ ht.nullMeasurableSet theorem measure_diff_add_inter (s : Set α) (ht : MeasurableSet t) : μ (s \ t) + μ (s ∩ t) = μ s := (add_comm _ _).trans (measure_inter_add_diff s ht) theorem measure_diff_eq_top (hs : μ s = ∞) (ht : μ t ≠ ∞) : μ (s \ t) = ∞ := by contrapose! hs exact ((measure_mono (subset_diff_union s t)).trans_lt ((measure_union_le _ _).trans_lt (ENNReal.add_lt_top.2 ⟨hs.lt_top, ht.lt_top⟩))).ne theorem measure_union_add_inter (s : Set α) (ht : MeasurableSet t) : μ (s ∪ t) + μ (s ∩ t) = μ s + μ t := by rw [← measure_inter_add_diff (s ∪ t) ht, Set.union_inter_cancel_right, union_diff_right, ← measure_inter_add_diff s ht] ac_rfl theorem measure_union_add_inter' (hs : MeasurableSet s) (t : Set α) : μ (s ∪ t) + μ (s ∩ t) = μ s + μ t := by rw [union_comm, inter_comm, measure_union_add_inter t hs, add_comm] lemma measure_symmDiff_eq (hs : NullMeasurableSet s μ) (ht : NullMeasurableSet t μ) : μ (s ∆ t) = μ (s \ t) + μ (t \ s) := by simpa only [symmDiff_def, sup_eq_union] using measure_union₀ (ht.diff hs) disjoint_sdiff_sdiff.aedisjoint lemma measure_symmDiff_le (s t u : Set α) : μ (s ∆ u) ≤ μ (s ∆ t) + μ (t ∆ u) := le_trans (μ.mono <\| symmDiff_triangle s t u) (measure_union_le (s ∆ t) (t ∆ u)) theorem measure_symmDiff_eq_top (hs : μ s ≠ ∞) (ht : μ t = ∞) : μ (s ∆ t) = ∞ := measure_mono_top subset_union_right (measure_diff_eq_top ht hs) theorem measure_add_measure_compl (h : MeasurableSet s) : μ s + μ sᶜ = μ univ := measure_add_measure_compl₀ h.nullMeasurableSet theorem measure_biUnion₀ {s : Set β} {f : β → Set α} (hs : s.Countable) (hd : s.Pairwise (AEDisjoint μ on f)) (h : ∀ b ∈ s, NullMeasurableSet (f b) μ) : μ (⋃ b ∈ s, f b) = ∑' p : s, μ (f p) := by haveI := hs.toEncodable rw [biUnion_eq_iUnion] exact measure_iUnion₀ (hd.on_injective Subtype.coe_injective fun x => x.2) fun x => h x x.2 theorem measure_biUnion {s : Set β} {f : β → Set α} (hs : s.Countable) (hd : s.PairwiseDisjoint f) (h : ∀ b ∈ s, MeasurableSet (f b)) : μ (⋃ b ∈ s, f b) = ∑' p : s, μ (f p) := measure_biUnion₀ hs hd.aedisjoint fun b hb => (h b hb).nullMeasurableSet theorem measure_sUnion₀ {S : Set (Set α)} (hs : S.Countable) (hd : S.Pairwise (AEDisjoint μ)) (h : ∀ s ∈ S, NullMeasurableSet s μ) : μ (⋃₀ S) = ∑' s : S, μ s := by rw [sUnion_eq_biUnion, measure_biUnion₀ hs hd h] theorem measure_sUnion {S : Set (Set α)} (hs : S.Countable) (hd : S.Pairwise Disjoint) (h : ∀ s ∈ S, MeasurableSet s) : μ (⋃₀ S) = ∑' s : S, μ s := by rw [sUnion_eq_biUnion, measure_biUnion hs hd h] theorem measure_biUnion_finset₀ {s : Finset ι} {f : ι → Set α} (hd : Set.Pairwise (↑s) (AEDisjoint μ on f)) (hm : ∀ b ∈ s, NullMeasurableSet (f b) μ) : μ (⋃ b ∈ s, f b) = ∑ p ∈ s, μ (f p) := by rw [← Finset.sum_attach, Finset.attach_eq_univ, ← tsum_fintype] exact measure_biUnion₀ s.countable_toSet hd hm theorem measure_biUnion_finset {s : Finset ι} {f : ι → Set α} (hd : PairwiseDisjoint (↑s) f) (hm : ∀ b ∈ s, MeasurableSet (f b)) : μ (⋃ b ∈ s, f b) = ∑ p ∈ s, μ (f p) := measure_biUnion_finset₀ hd.aedisjoint fun b hb => (hm b hb).nullMeasurableSet /-- The measure of an a.e. disjoint union (even uncountable) of null-measurable sets is at least the sum of the measures of the sets. -/ theorem tsum_meas_le_meas_iUnion_of_disjoint₀ {ι : Type} {_ : MeasurableSpace α} (μ : Measure α) {As : ι → Set α} (As_mble : ∀ i : ι, NullMeasurableSet (As i) μ) (As_disj : Pairwise (AEDisjoint μ on As)) : (∑' i, μ (As i)) ≤ μ (⋃ i, As i) := by rw [ENNReal.tsum_eq_iSup_sum, iSup_le_iff] intro s simp only [← measure_biUnion_finset₀ (fun _i _hi _j _hj hij => As_disj hij) fun i _ => As_mble i] gcongr exact iUnion_subset fun _ ↦ Subset.rfl /-- The measure of a disjoint union (even uncountable) of measurable sets is at least the sum of the measures of the sets. -/ theorem tsum_meas_le_meas_iUnion_of_disjoint {ι : Type} {_ : MeasurableSpace α} (μ : Measure α) {As : ι → Set α} (As_mble : ∀ i : ι, MeasurableSet (As i)) (As_disj : Pairwise (Disjoint on As)) : (∑' i, μ (As i)) ≤ μ (⋃ i, As i) := tsum_meas_le_meas_iUnion_of_disjoint₀ μ (fun i ↦ (As_mble i).nullMeasurableSet) (fun _ _ h ↦ Disjoint.aedisjoint (As_disj h)) /-- If `s` is a countable set, then the measure of its preimage can be found as the sum of measures of the fibers `f ⁻¹' {y}`. -/ theorem tsum_measure_preimage_singleton {s : Set β} (hs : s.Countable) {f : α → β} (hf : ∀ y ∈ s, MeasurableSet (f ⁻¹' {y})) : (∑' b : s, μ (f ⁻¹' {↑b})) = μ (f ⁻¹' s) := by rw [← Set.biUnion_preimage_singleton, measure_biUnion hs (pairwiseDisjoint_fiber f s) hf] lemma measure_preimage_eq_zero_iff_of_countable {s : Set β} {f : α → β} (hs : s.Countable) : μ (f ⁻¹' s) = 0 ↔ ∀ x ∈ s, μ (f ⁻¹' {x}) = 0 := by rw [← biUnion_preimage_singleton, measure_biUnion_null_iff hs] /-- If `s` is a `Finset`, then the measure of its preimage can be found as the sum of measures of the fibers `f ⁻¹' {y}`. -/ theorem sum_measure_preimage_singleton (s : Finset β) {f : α → β} (hf : ∀ y ∈ s, MeasurableSet (f ⁻¹' {y})) : (∑ b ∈ s, μ (f ⁻¹' {b})) = μ (f ⁻¹' ↑s) := by simp only [← measure_biUnion_finset (pairwiseDisjoint_fiber f s) hf, Finset.set_biUnion_preimage_singleton] @[simp] lemma sum_measure_singleton {s : Finset α} [MeasurableSingletonClass α] : ∑ x ∈ s, μ {x} = μ s := by trans ∑ x ∈ s, μ (id ⁻¹' {x}) · simp rw [sum_measure_preimage_singleton] · simp · simp theorem measure_diff_null' (h : μ (s₁ ∩ s₂) = 0) : μ (s₁ \ s₂) = μ s₁ := measure_congr <\| diff_ae_eq_self.2 h theorem measure_add_diff (hs : NullMeasurableSet s μ) (t : Set α) : μ s + μ (t \ s) = μ (s ∪ t) := by rw [← measure_union₀' hs disjoint_sdiff_right.aedisjoint, union_diff_self] theorem measure_diff' (s : Set α) (hm : NullMeasurableSet t μ) (h_fin : μ t ≠ ∞) : μ (s \ t) = μ (s ∪ t) - μ t := ENNReal.eq_sub_of_add_eq h_fin <\| by rw [add_comm, measure_add_diff hm, union_comm] theorem measure_diff (h : s₂ ⊆ s₁) (h₂ : NullMeasurableSet s₂ μ) (h_fin : μ s₂ ≠ ∞) : μ (s₁ \ s₂) = μ s₁ - μ s₂ := by rw [measure_diff' _ h₂ h_fin, union_eq_self_of_subset_right h] theorem le_measure_diff : μ s₁ - μ s₂ ≤ μ (s₁ \ s₂) := tsub_le_iff_left.2 <\| (measure_le_inter_add_diff μ s₁ s₂).trans <\| by gcongr; apply inter_subset_right /-- If the measure of the symmetric difference of two sets is finite, then one has infinite measure if and only if the other one does. -/ theorem measure_eq_top_iff_of_symmDiff (hμst : μ (s ∆ t) ≠ ∞) : μ s = ∞ ↔ μ t = ∞ := by suffices h : ∀ u v, μ (u ∆ v) ≠ ∞ → μ u = ∞ → μ v = ∞ from ⟨h s t hμst, h t s (symmDiff_comm s t ▸ hμst)⟩ intro u v hμuv hμu by_contra! hμv apply hμuv rw [Set.symmDiff_def, eq_top_iff] calc ∞ = μ u - μ v := by rw [ENNReal.sub_eq_top_iff.2 ⟨hμu, hμv⟩] _ ≤ μ (u \ v) := le_measure_diff _ ≤ μ (u \ v ∪ v \ u) := measure_mono subset_union_left /-- If the measure of the symmetric difference of two sets is finite, then one has finite measure if and only if the other one does. -/ theorem measure_ne_top_iff_of_symmDiff (hμst : μ (s ∆ t) ≠ ∞) : μ s ≠ ∞ ↔ μ t ≠ ∞ := (measure_eq_top_iff_of_symmDiff hμst).ne theorem measure_diff_lt_of_lt_add (hs : NullMeasurableSet s μ) (hst : s ⊆ t) (hs' : μ s ≠ ∞) {ε : ℝ≥0∞} (h : μ t < μ s + ε) : μ (t \ s) < ε := by rw [measure_diff hst hs hs']; rw [add_comm] at h exact ENNReal.sub_lt_of_lt_add (measure_mono hst) h theorem measure_diff_le_iff_le_add (hs : NullMeasurableSet s μ) (hst : s ⊆ t) (hs' : μ s ≠ ∞) {ε : ℝ≥0∞} : μ (t \ s) ≤ ε ↔ μ t ≤ μ s + ε := by rw [measure_diff hst hs hs', tsub_le_iff_left] theorem measure_eq_measure_of_null_diff {s t : Set α} (hst : s ⊆ t) (h_nulldiff : μ (t \ s) = 0) : μ s = μ t := measure_congr <\| EventuallyLE.antisymm (HasSubset.Subset.eventuallyLE hst) (ae_le_set.mpr h_nulldiff) theorem measure_eq_measure_of_between_null_diff {s₁ s₂ s₃ : Set α} (h12 : s₁ ⊆ s₂) (h23 : s₂ ⊆ s₃) (h_nulldiff : μ (s₃ \ s₁) = 0) : μ s₁ = μ s₂ ∧ μ s₂ = μ s₃ := by have le12 : μ s₁ ≤ μ s₂ := measure_mono h12 have le23 : μ s₂ ≤ μ s₃ := measure_mono h23 have key : μ s₃ ≤ μ s₁ := calc μ s₃ = μ (s₃ \ s₁ ∪ s₁) := by rw [diff_union_of_subset (h12.trans h23)] _ ≤ μ (s₃ \ s₁) + μ s₁ := measure_union_le _ _ _ = μ s₁ := by simp only [h_nulldiff, zero_add] exact ⟨le12.antisymm (le23.trans key), le23.antisymm (key.trans le12)⟩ theorem measure_eq_measure_smaller_of_between_null_diff {s₁ s₂ s₃ : Set α} (h12 : s₁ ⊆ s₂) (h23 : s₂ ⊆ s₃) (h_nulldiff : μ (s₃ \ s₁) = 0) : μ s₁ = μ s₂ := (measure_eq_measure_of_between_null_diff h12 h23 h_nulldiff).1 theorem measure_eq_measure_larger_of_between_null_diff {s₁ s₂ s₃ : Set α} (h12 : s₁ ⊆ s₂) (h23 : s₂ ⊆ s₃) (h_nulldiff : μ (s₃ \ s₁) = 0) : μ s₂ = μ s₃ := (measure_eq_measure_of_between_null_diff h12 h23 h_nulldiff).2 lemma measure_compl₀ (h : NullMeasurableSet s μ) (hs : μ s ≠ ∞) : μ sᶜ = μ Set.univ - μ s := by rw [← measure_add_measure_compl₀ h, ENNReal.add_sub_cancel_left hs] theorem measure_compl (h₁ : MeasurableSet s) (h_fin : μ s ≠ ∞) : μ sᶜ = μ univ - μ s := measure_compl₀ h₁.nullMeasurableSet h_fin lemma measure_inter_conull' (ht : μ (s \ t) = 0) : μ (s ∩ t) = μ s := by rw [← diff_compl, measure_diff_null']; rwa [← diff_eq] lemma measure_inter_conull (ht : μ tᶜ = 0) : μ (s ∩ t) = μ s := by rw [← diff_compl, measure_diff_null ht] @[simp] theorem union_ae_eq_left_iff_ae_subset : (s ∪ t : Set α) =ᵐ[μ] s ↔ t ≤ᵐ[μ] s := by rw [ae_le_set] refine ⟨fun h => by simpa only [union_diff_left] using (ae_eq_set.mp h).1, fun h => eventuallyLE_antisymm_iff.mpr ⟨by rwa [ae_le_set, union_diff_left], HasSubset.Subset.eventuallyLE subset_union_left⟩⟩ @[simp] theorem union_ae_eq_right_iff_ae_subset : (s ∪ t : Set α) =ᵐ[μ] t ↔ s ≤ᵐ[μ] t := by rw [union_comm, union_ae_eq_left_iff_ae_subset] theorem ae_eq_of_ae_subset_of_measure_ge (h₁ : s ≤ᵐ[μ] t) (h₂ : μ t ≤ μ s) (hsm : NullMeasurableSet s μ) (ht : μ t ≠ ∞) : s =ᵐ[μ] t := by refine eventuallyLE_antisymm_iff.mpr ⟨h₁, ae_le_set.mpr ?_⟩ replace h₂ : μ t = μ s := h₂.antisymm (measure_mono_ae h₁) replace ht : μ s ≠ ∞ := h₂ ▸ ht rw [measure_diff' t hsm ht, measure_congr (union_ae_eq_left_iff_ae_subset.mpr h₁), h₂, tsub_self] /-- If `s ⊆ t`, `μ t ≤ μ s`, `μ t ≠ ∞`, and `s` is measurable, then `s =ᵐ[μ] t`. -/ theorem ae_eq_of_subset_of_measure_ge (h₁ : s ⊆ t) (h₂ : μ t ≤ μ s) (hsm : NullMeasurableSet s μ) (ht : μ t ≠ ∞) : s =ᵐ[μ] t := ae_eq_of_ae_subset_of_measure_ge (HasSubset.Subset.eventuallyLE h₁) h₂ hsm ht theorem measure_iUnion_congr_of_subset {ι : Sort} [Countable ι] {s : ι → Set α} {t : ι → Set α} (hsub : ∀ i, s i ⊆ t i) (h_le : ∀ i, μ (t i) ≤ μ (s i)) : μ (⋃ i, s i) = μ (⋃ i, t i) := by refine le_antisymm (by gcongr; apply hsub) ?_ rcases Classical.em (∃ i, μ (t i) = ∞) with (⟨i, hi⟩ \| htop) · calc μ (⋃ i, t i) ≤ ∞ := le_top _ ≤ μ (s i) := hi ▸ h_le i _ ≤ μ (⋃ i, s i) := measure_mono <\| subset_iUnion _ _ push_neg at htop set M := toMeasurable μ have H : ∀ b, (M (t b) ∩ M (⋃ b, s b) : Set α) =ᵐ[μ] M (t b) := by refine fun b => ae_eq_of_subset_of_measure_ge inter_subset_left ?_ ?_ ?_ · calc μ (M (t b)) = μ (t b) := measure_toMeasurable _ _ ≤ μ (s b) := h_le b _ ≤ μ (M (t b) ∩ M (⋃ b, s b)) := measure_mono <\| subset_inter ((hsub b).trans <\| subset_toMeasurable _ _) ((subset_iUnion _ _).trans <\| subset_toMeasurable _ _) · measurability · rw [measure_toMeasurable] exact htop b calc μ (⋃ b, t b) ≤ μ (⋃ b, M (t b)) := measure_mono (iUnion_mono fun b => subset_toMeasurable _ _) _ = μ (⋃ b, M (t b) ∩ M (⋃ b, s b)) := measure_congr (EventuallyEq.countable_iUnion H).symm _ ≤ μ (M (⋃ b, s b)) := measure_mono (iUnion_subset fun b => inter_subset_right) _ = μ (⋃ b, s b) := measure_toMeasurable _ theorem measure_union_congr_of_subset {t₁ t₂ : Set α} (hs : s₁ ⊆ s₂) (hsμ : μ s₂ ≤ μ s₁) (ht : t₁ ⊆ t₂) (htμ : μ t₂ ≤ μ t₁) : μ (s₁ ∪ t₁) = μ (s₂ ∪ t₂) := by rw [union_eq_iUnion, union_eq_iUnion] exact measure_iUnion_congr_of_subset (Bool.forall_bool.2 ⟨ht, hs⟩) (Bool.forall_bool.2 ⟨htμ, hsμ⟩) @[simp] theorem measure_iUnion_toMeasurable {ι : Sort*} [Countable ι] (s : ι → Set α) : μ (⋃ i, toMeasurable μ (s i)) = μ (⋃ i, s i) := Eq.symm <\| measure_iUnion_congr_of_subset (fun _i => subset_toMeasurable _ _) fun _i ↦ (measure_toMeasurable _).le theorem measure_biUnion_toMeasurable {I : Set β} (hc : I.Countable) (s : β → Set α) : μ (⋃ b ∈ I, toMeasurable μ (s b)) = μ (⋃ b ∈ I, s b) := by haveI := hc.toEncodable simp only [biUnion_eq_iUnion, measure_iUnion_toMeasurable] @[simp] theorem measure_toMeasurable_union : μ (toMeasurable μ s ∪ t) = μ (s ∪ t) := Eq.symm <\| measure_union_congr_of_subset (subset_toMeasurable _ _) (measure_toMeasurable _).le Subset.rfl le_rfl @[simp] theorem measure_union_toMeasurable : μ (s ∪ toMeasurable μ t) = μ (s ∪ t) := Eq.symm <\| measure_union_congr_of_subset Subset.rfl le_rfl (subset_toMeasurable _ _) (measure_toMeasurable _).le theorem sum_measure_le_measure_univ {s : Finset ι} {t : ι → Set α} (h : ∀ i ∈ s, NullMeasurableSet (t i) μ) (H : Set.Pairwise s (AEDisjoint μ on t)) : (∑ i ∈ s, μ (t i)) ≤ μ (univ : Set α) := by rw [← measure_biUnion_finset₀ H h] exact measure_mono (subset_univ _) theorem tsum_measure_le_measure_univ {s : ι → Set α} (hs : ∀ i, NullMeasurableSet (s i) μ) (H : Pairwise (AEDisjoint μ on s)) : ∑' i, μ (s i) ≤ μ (univ : Set α) := by rw [ENNReal.tsum_eq_iSup_sum] exact iSup_le fun s => sum_measure_le_measure_univ (fun i _hi => hs i) fun i _hi j _hj hij => H hij /-- Pigeonhole principle for measure spaces: if `∑' i, μ (s i) > μ univ`, then one of the intersections `s i ∩ s j` is not empty. -/ theorem exists_nonempty_inter_of_measure_univ_lt_tsum_measure {m : MeasurableSpace α} (μ : Measure α) {s : ι → Set α} (hs : ∀ i, NullMeasurableSet (s i) μ) (H : μ (univ : Set α) < ∑' i, μ (s i)) : ∃ i j, i ≠ j ∧ (s i ∩ s j).Nonempty := by contrapose! H apply tsum_measure_le_measure_univ hs intro i j hij exact (disjoint_iff_inter_eq_empty.mpr (H i j hij)).aedisjoint /-- Pigeonhole principle for measure spaces: if `s` is a `Finset` and `∑ i ∈ s, μ (t i) > μ univ`, then one of the intersections `t i ∩ t j` is not empty. -/ theorem exists_nonempty_inter_of_measure_univ_lt_sum_measure {m : MeasurableSpace α} (μ : Measure α) {s : Finset ι} {t : ι → Set α} (h : ∀ i ∈ s, NullMeasurableSet (t i) μ) (H : μ (univ : Set α) < ∑ i ∈ s, μ (t i)) : ∃ i ∈ s, ∃ j ∈ s, ∃ _h : i ≠ j, (t i ∩ t j).Nonempty := by contrapose! H apply sum_measure_le_measure_univ h intro i hi j hj hij exact (disjoint_iff_inter_eq_empty.mpr (H i hi j hj hij)).aedisjoint /-- If two sets `s` and `t` are included in a set `u`, and `μ s + μ t > μ u`, then `s` intersects `t`. Version assuming that `t` is measurable. -/ theorem nonempty_inter_of_measure_lt_add {m : MeasurableSpace α} (μ : Measure α) {s t u : Set α} (ht : MeasurableSet t) (h's : s ⊆ u) (h't : t ⊆ u) (h : μ u < μ s + μ t) : (s ∩ t).Nonempty := by rw [← Set.not_disjoint_iff_nonempty_inter] contrapose! h calc μ s + μ t = μ (s ∪ t) := (measure_union h ht).symm _ ≤ μ u := measure_mono (union_subset h's h't) /-- If two sets `s` and `t` are included in a set `u`, and `μ s + μ t > μ u`, then `s` intersects `t`. Version assuming that `s` is measurable. -/ theorem nonempty_inter_of_measure_lt_add' {m : MeasurableSpace α} (μ : Measure α) {s t u : Set α} (hs : MeasurableSet s) (h's : s ⊆ u) (h't : t ⊆ u) (h : μ u < μ s + μ t) : (s ∩ t).Nonempty := by rw [add_comm] at h rw [inter_comm] exact nonempty_inter_of_measure_lt_add μ hs h't h's h /-- Continuity from below: the measure of the union of a directed sequence of (not necessarily measurable) sets is the supremum of the measures. -/ theorem _root_.Directed.measure_iUnion [Countable ι] {s : ι → Set α} (hd : Directed (· ⊆ ·) s) : μ (⋃ i, s i) = ⨆ i, μ (s i) := by -- WLOG, `ι = ℕ` rcases Countable.exists_injective_nat ι with ⟨e, he⟩ generalize ht : Function.extend e s ⊥ = t replace hd : Directed (· ⊆ ·) t := ht ▸ hd.extend_bot he suffices μ (⋃ n, t n) = ⨆ n, μ (t n) by	simp only [← ht, Function.apply_extend μ, ← iSup_eq_iUnion, iSup_extend_bot he, Function.comp_def, Pi.bot_apply, bot_eq_empty, measure_empty] at this exact this.trans (iSup_extend_bot he _) clear! ι -- The `≥` inequality is trivial refine le_antisymm ?_ (iSup_le fun i ↦ measure_mono <\| subset_iUnion _ _) -- Choose `T n ⊇ t n` of the same measure, put `Td n = disjointed T` set T : ℕ → Set α := fun n => toMeasurable μ (t n)	Mathlib/MeasureTheory/Measure/MeasureSpace.lean	448	455
/- Copyright (c) 2018 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Kenny Lau, Johan Commelin, Mario Carneiro, Kevin Buzzard, Amelia Livingston, Yury Kudryashov -/ import Mathlib.Algebra.BigOperators.Group.Multiset.Defs import Mathlib.Algebra.FreeMonoid.Basic import Mathlib.Algebra.Group.Idempotent import Mathlib.Algebra.Group.Nat.Hom import Mathlib.Algebra.Group.Submonoid.MulOpposite import Mathlib.Algebra.Group.Submonoid.Operations import Mathlib.Data.Fintype.EquivFin import Mathlib.Data.Int.Basic /-! # Submonoids: membership criteria In this file we prove various facts about membership in a submonoid: * `pow_mem`, `nsmul_mem`: if `x ∈ S` where `S` is a multiplicative (resp., additive) submonoid and `n` is a natural number, then `x^n` (resp., `n • x`) belongs to `S`; * `mem_iSup_of_directed`, `coe_iSup_of_directed`, `mem_sSup_of_directedOn`, `coe_sSup_of_directedOn`: the supremum of a directed collection of submonoid is their union. * `sup_eq_range`, `mem_sup`: supremum of two submonoids `S`, `T` of a commutative monoid is the set of products; * `closure_singleton_eq`, `mem_closure_singleton`, `mem_closure_pair`: the multiplicative (resp., additive) closure of `{x}` consists of powers (resp., natural multiples) of `x`, and a similar result holds for the closure of `{x, y}`. ## Tags submonoid, submonoids -/ assert_not_exists MonoidWithZero variable {M A B : Type} section Assoc variable [Monoid M] [SetLike B M] [SubmonoidClass B M] {S : B} end Assoc section NonAssoc variable [MulOneClass M] open Set namespace Submonoid -- TODO: this section can be generalized to `[SubmonoidClass B M] [CompleteLattice B]` -- such that `CompleteLattice.LE` coincides with `SetLike.LE` @[to_additive] theorem mem_iSup_of_directed {ι} [hι : Nonempty ι] {S : ι → Submonoid M} (hS : Directed (· ≤ ·) S) {x : M} : (x ∈ ⨆ i, S i) ↔ ∃ i, x ∈ S i := by refine ⟨?_, fun ⟨i, hi⟩ ↦ le_iSup S i hi⟩ suffices x ∈ closure (⋃ i, (S i : Set M)) → ∃ i, x ∈ S i by simpa only [closure_iUnion, closure_eq (S _)] using this refine closure_induction (fun _ ↦ mem_iUnion.1) ?_ ?_ · exact hι.elim fun i ↦ ⟨i, (S i).one_mem⟩ · rintro x y - - ⟨i, hi⟩ ⟨j, hj⟩ rcases hS i j with ⟨k, hki, hkj⟩ exact ⟨k, (S k).mul_mem (hki hi) (hkj hj)⟩ @[to_additive] theorem coe_iSup_of_directed {ι} [Nonempty ι] {S : ι → Submonoid M} (hS : Directed (· ≤ ·) S) : ((⨆ i, S i : Submonoid M) : Set M) = ⋃ i, S i := Set.ext fun x ↦ by simp [mem_iSup_of_directed hS] @[to_additive] theorem mem_sSup_of_directedOn {S : Set (Submonoid M)} (Sne : S.Nonempty) (hS : DirectedOn (· ≤ ·) S) {x : M} : x ∈ sSup S ↔ ∃ s ∈ S, x ∈ s := by haveI : Nonempty S := Sne.to_subtype simp [sSup_eq_iSup', mem_iSup_of_directed hS.directed_val, SetCoe.exists, Subtype.coe_mk] @[to_additive] theorem coe_sSup_of_directedOn {S : Set (Submonoid M)} (Sne : S.Nonempty) (hS : DirectedOn (· ≤ ·) S) : (↑(sSup S) : Set M) = ⋃ s ∈ S, ↑s := Set.ext fun x => by simp [mem_sSup_of_directedOn Sne hS] @[to_additive] theorem mem_sup_left {S T : Submonoid M} : ∀ {x : M}, x ∈ S → x ∈ S ⊔ T := by rw [← SetLike.le_def] exact le_sup_left @[to_additive] theorem mem_sup_right {S T : Submonoid M} : ∀ {x : M}, x ∈ T → x ∈ S ⊔ T := by rw [← SetLike.le_def] exact le_sup_right @[to_additive] theorem mul_mem_sup {S T : Submonoid M} {x y : M} (hx : x ∈ S) (hy : y ∈ T) : x y ∈ S ⊔ T := (S ⊔ T).mul_mem (mem_sup_left hx) (mem_sup_right hy) @[to_additive] theorem mem_iSup_of_mem {ι : Sort} {S : ι → Submonoid M} (i : ι) : ∀ {x : M}, x ∈ S i → x ∈ iSup S := by rw [← SetLike.le_def] exact le_iSup _ _ @[to_additive] theorem mem_sSup_of_mem {S : Set (Submonoid M)} {s : Submonoid M} (hs : s ∈ S) : ∀ {x : M}, x ∈ s → x ∈ sSup S := by rw [← SetLike.le_def] exact le_sSup hs /-- An induction principle for elements of `⨆ i, S i`. If `C` holds for `1` and all elements of `S i` for all `i`, and is preserved under multiplication, then it holds for all elements of the supremum of `S`. -/ @[to_additive (attr := elab_as_elim) " An induction principle for elements of `⨆ i, S i`. If `C` holds for `0` and all elements of `S i` for all `i`, and is preserved under addition, then it holds for all elements of the supremum of `S`. "] theorem iSup_induction {ι : Sort} (S : ι → Submonoid M) {motive : M → Prop} {x : M} (hx : x ∈ ⨆ i, S i) (mem : ∀ (i), ∀ x ∈ S i, motive x) (one : motive 1) (mul : ∀ x y, motive x → motive y → motive (x * y)) : motive x := by rw [iSup_eq_closure] at hx refine closure_induction (fun x hx => ?_) one (fun _ _ _ _ ↦ mul _ _) hx obtain ⟨i, hi⟩ := Set.mem_iUnion.mp hx exact mem _ _ hi /-- A dependent version of `Submonoid.iSup_induction`. -/ @[to_additive (attr := elab_as_elim) "A dependent version of `AddSubmonoid.iSup_induction`. "] theorem iSup_induction' {ι : Sort} (S : ι → Submonoid M) {motive : ∀ x, (x ∈ ⨆ i, S i) → Prop} (mem : ∀ (i), ∀ (x) (hxS : x ∈ S i), motive x (mem_iSup_of_mem i hxS)) (one : motive 1 (one_mem _)) (mul : ∀ x y hx hy, motive x hx → motive y hy → motive (x y) (mul_mem ‹_› ‹_›)) {x : M} (hx : x ∈ ⨆ i, S i) : motive x hx := by refine Exists.elim (?_ : ∃ Hx, motive x Hx) fun (hx : x ∈ ⨆ i, S i) (hc : motive x hx) => hc refine @iSup_induction _ _ ι S (fun m => ∃ hm, motive m hm) _ hx (fun i x hx => ?_) ?_ fun x y => ?_ · exact ⟨_, mem _ _ hx⟩ · exact ⟨_, one⟩ · rintro ⟨_, Cx⟩ ⟨_, Cy⟩ exact ⟨_, mul _ _ _ _ Cx Cy⟩ end Submonoid end NonAssoc namespace FreeMonoid variable {α : Type} open Submonoid @[to_additive] theorem closure_range_of : closure (Set.range <\| @of α) = ⊤ := eq_top_iff.2 fun x _ => FreeMonoid.recOn x (one_mem _) fun _x _xs hxs => mul_mem (subset_closure <\| Set.mem_range_self _) hxs end FreeMonoid namespace Submonoid variable [Monoid M] {a : M} open MonoidHom theorem closure_singleton_eq (x : M) : closure ({x} : Set M) = mrange (powersHom M x) := closure_eq_of_le (Set.singleton_subset_iff.2 ⟨Multiplicative.ofAdd 1, pow_one x⟩) fun _ ⟨_, hn⟩ => hn ▸ pow_mem (subset_closure <\| Set.mem_singleton _) _ /-- The submonoid generated by an element of a monoid equals the set of natural number powers of the element. -/ theorem mem_closure_singleton {x y : M} : y ∈ closure ({x} : Set M) ↔ ∃ n : ℕ, x ^ n = y := by rw [closure_singleton_eq, mem_mrange]; rfl theorem mem_closure_singleton_self {y : M} : y ∈ closure ({y} : Set M) := mem_closure_singleton.2 ⟨1, pow_one y⟩ theorem closure_singleton_one : closure ({1} : Set M) = ⊥ := by simp [eq_bot_iff_forall, mem_closure_singleton] section Submonoid variable {S : Submonoid M} [Fintype S] open Fintype /- curly brackets `{}` are used here instead of instance brackets `[]` because the instance in a goal is often not the same as the one inferred by type class inference. -/ @[to_additive] theorem card_bot {_ : Fintype (⊥ : Submonoid M)} : card (⊥ : Submonoid M) = 1 := card_eq_one_iff.2 ⟨⟨(1 : M), Set.mem_singleton 1⟩, fun ⟨_y, hy⟩ => Subtype.eq <\| mem_bot.1 hy⟩ @[to_additive] theorem eq_bot_of_card_le (h : card S ≤ 1) : S = ⊥ := let _ := card_le_one_iff_subsingleton.mp h eq_bot_of_subsingleton S @[to_additive] theorem eq_bot_of_card_eq (h : card S = 1) : S = ⊥ := S.eq_bot_of_card_le (le_of_eq h) @[to_additive card_le_one_iff_eq_bot] theorem card_le_one_iff_eq_bot : card S ≤ 1 ↔ S = ⊥ := ⟨fun h => (eq_bot_iff_forall _).2 fun x hx => by simpa [Subtype.ext_iff] using card_le_one_iff.1 h ⟨x, hx⟩ 1, fun h => by simp [h]⟩ @[to_additive] lemma eq_bot_iff_card : S = ⊥ ↔ card S = 1 := ⟨by rintro rfl; exact card_bot, eq_bot_of_card_eq⟩ end Submonoid @[to_additive] theorem _root_.FreeMonoid.mrange_lift {α} (f : α → M) : mrange (FreeMonoid.lift f) = closure (Set.range f) := by rw [mrange_eq_map, ← FreeMonoid.closure_range_of, map_mclosure, ← Set.range_comp, FreeMonoid.lift_comp_of] @[to_additive] theorem closure_eq_mrange (s : Set M) : closure s = mrange (FreeMonoid.lift ((↑) : s → M)) := by rw [FreeMonoid.mrange_lift, Subtype.range_coe] @[to_additive] theorem closure_eq_image_prod (s : Set M) : (closure s : Set M) = List.prod '' { l : List M \| ∀ x ∈ l, x ∈ s } := by rw [closure_eq_mrange, coe_mrange, ← Set.range_list_map_coe, ← Set.range_comp] exact congrArg _ (funext <\| FreeMonoid.lift_apply _) @[to_additive] theorem exists_list_of_mem_closure {s : Set M} {x : M} (hx : x ∈ closure s) : ∃ l : List M, (∀ y ∈ l, y ∈ s) ∧ l.prod = x := by rwa [← SetLike.mem_coe, closure_eq_image_prod, Set.mem_image] at hx @[to_additive] theorem exists_multiset_of_mem_closure {M : Type} [CommMonoid M] {s : Set M} {x : M} (hx : x ∈ closure s) : ∃ l : Multiset M, (∀ y ∈ l, y ∈ s) ∧ l.prod = x := by obtain ⟨l, h1, h2⟩ := exists_list_of_mem_closure hx exact ⟨l, h1, (Multiset.prod_coe l).trans h2⟩ @[to_additive (attr := elab_as_elim)] theorem closure_induction_left {s : Set M} {p : (m : M) → m ∈ closure s → Prop} (one : p 1 (one_mem _)) (mul_left : ∀ x (hx : x ∈ s), ∀ (y) hy, p y hy → p (x * y) (mul_mem (subset_closure hx) hy)) {x : M} (h : x ∈ closure s) : p x h := by simp_rw [closure_eq_mrange] at h obtain ⟨l, rfl⟩ := h induction l using FreeMonoid.inductionOn' with \| one => exact one \| mul_of x y ih => simp only [map_mul, FreeMonoid.lift_eval_of] refine mul_left _ x.prop (FreeMonoid.lift Subtype.val y) _ (ih ?_) simp only [closure_eq_mrange, mem_mrange, exists_apply_eq_apply] @[to_additive (attr := elab_as_elim)] theorem induction_of_closure_eq_top_left {s : Set M} {p : M → Prop} (hs : closure s = ⊤) (x : M) (one : p 1) (mul : ∀ x ∈ s, ∀ (y), p y → p (x * y)) : p x := by have : x ∈ closure s := by simp [hs] induction this using closure_induction_left with \| one => exact one \| mul_left x hx y _ ih => exact mul x hx y ih @[to_additive (attr := elab_as_elim)] theorem closure_induction_right {s : Set M} {p : (m : M) → m ∈ closure s → Prop} (one : p 1 (one_mem _)) (mul_right : ∀ x hx, ∀ (y) (hy : y ∈ s), p x hx → p (x * y) (mul_mem hx (subset_closure hy))) {x : M} (h : x ∈ closure s) : p x h := closure_induction_left (s := MulOpposite.unop ⁻¹' s) (p := fun m hm => p m.unop <\| by rwa [← op_closure] at hm) one (fun _x hx _y _ => mul_right _ _ _ hx) (by rwa [← op_closure]) @[to_additive (attr := elab_as_elim)] theorem induction_of_closure_eq_top_right {s : Set M} {p : M → Prop} (hs : closure s = ⊤) (x : M) (H1 : p 1) (Hmul : ∀ (x), ∀ y ∈ s, p x → p (x * y)) : p x := by have : x ∈ closure s := by simp [hs] induction this using closure_induction_right with \| one => exact H1 \| mul_right x _ y hy ih => exact Hmul x y hy ih /-- The submonoid generated by an element. -/ def powers (n : M) : Submonoid M := Submonoid.copy (mrange (powersHom M n)) (Set.range (n ^ · : ℕ → M)) <\| Set.ext fun n => exists_congr fun i => by simp; rfl theorem mem_powers (n : M) : n ∈ powers n := ⟨1, pow_one _⟩ theorem coe_powers (x : M) : ↑(powers x) = Set.range fun n : ℕ => x ^ n := rfl theorem mem_powers_iff (x z : M) : x ∈ powers z ↔ ∃ n : ℕ, z ^ n = x := Iff.rfl noncomputable instance decidableMemPowers : DecidablePred (· ∈ Submonoid.powers a) := Classical.decPred _ -- Porting note (https://github.com/leanprover-community/mathlib4/issues/11215): TODO the following instance should follow from a more general principle -- See also https://github.com/leanprover-community/mathlib4/issues/2417 noncomputable instance fintypePowers [Fintype M] : Fintype (powers a) := inferInstanceAs <\| Fintype {y // y ∈ powers a} theorem powers_eq_closure (n : M) : powers n = closure {n} := by ext exact mem_closure_singleton.symm lemma powers_le {n : M} {P : Submonoid M} : powers n ≤ P ↔ n ∈ P := by simp [powers_eq_closure] lemma powers_one : powers (1 : M) = ⊥ := bot_unique <\| powers_le.2 <\| one_mem _ theorem _root_.IsIdempotentElem.coe_powers {a : M} (ha : IsIdempotentElem a) : (Submonoid.powers a : Set M) = {1, a} := let S : Submonoid M := { carrier := {1, a}, mul_mem' := by rintro _ _ (rfl\|rfl) (rfl\|rfl) · rw [one_mul]; exact .inl rfl · rw [one_mul]; exact .inr rfl · rw [mul_one]; exact .inr rfl · rw [ha]; exact .inr rfl one_mem' := .inl rfl } suffices Submonoid.powers a = S from congr_arg _ this le_antisymm (Submonoid.powers_le.mpr <\| .inr rfl) (by rintro _ (rfl\|rfl); exacts [one_mem _, Submonoid.mem_powers _]) /-- The submonoid generated by an element is a group if that element has finite order. -/ abbrev groupPowers {x : M} {n : ℕ} (hpos : 0 < n) (hx : x ^ n = 1) : Group (powers x) where inv x := x ^ (n - 1) inv_mul_cancel y := Subtype.ext <\| by obtain ⟨_, k, rfl⟩ := y simp only [coe_one, coe_mul, SubmonoidClass.coe_pow] rw [← pow_succ, Nat.sub_add_cancel hpos, ← pow_mul, mul_comm, pow_mul, hx, one_pow] zpow z x := x ^ z.natMod n zpow_zero' z := by simp only [Int.natMod, Int.zero_emod, Int.toNat_zero, pow_zero] zpow_neg' m x := Subtype.ext <\| by obtain ⟨_, k, rfl⟩ := x simp only [← pow_mul, Int.natMod, SubmonoidClass.coe_pow] rw [Int.negSucc_eq, ← Int.natCast_succ, ← Int.add_mul_emod_self_right (b := (m + 1 : ℕ))] nth_rw 1 [← mul_one ((m + 1 : ℕ) : ℤ)] rw [← sub_eq_neg_add, ← Int.mul_sub, ← Int.natCast_pred_of_pos hpos]; norm_cast simp only [Int.toNat_natCast] rw [mul_comm, pow_mul, ← pow_eq_pow_mod _ hx, mul_comm k, mul_assoc, pow_mul _ (_ % _), ← pow_eq_pow_mod _ hx, pow_mul, pow_mul] zpow_succ' m x := Subtype.ext <\| by obtain ⟨_, k, rfl⟩ := x simp only [← pow_mul, Int.natMod, SubmonoidClass.coe_pow, coe_mul] norm_cast iterate 2 rw [Int.toNat_natCast, mul_comm, pow_mul, ← pow_eq_pow_mod _ hx] rw [← pow_mul _ m, mul_comm, pow_mul, ← pow_succ, ← pow_mul, mul_comm, pow_mul] /-- Exponentiation map from natural numbers to powers. -/ @[simps!] def pow (n : M) (m : ℕ) : powers n := (powersHom M n).mrangeRestrict (Multiplicative.ofAdd m) theorem pow_apply (n : M) (m : ℕ) : Submonoid.pow n m = ⟨n ^ m, m, rfl⟩ := rfl /-- Logarithms from powers to natural numbers. -/ def log [DecidableEq M] {n : M} (p : powers n) : ℕ := Nat.find <\| (mem_powers_iff p.val n).mp p.prop @[simp] theorem pow_log_eq_self [DecidableEq M] {n : M} (p : powers n) : pow n (log p) = p := Subtype.ext <\| Nat.find_spec p.prop theorem pow_right_injective_iff_pow_injective {n : M} : (Function.Injective fun m : ℕ => n ^ m) ↔ Function.Injective (pow n) := Subtype.coe_injective.of_comp_iff (pow n) @[simp] theorem log_pow_eq_self [DecidableEq M] {n : M} (h : Function.Injective fun m : ℕ => n ^ m) (m : ℕ) : log (pow n m) = m := pow_right_injective_iff_pow_injective.mp h <\| pow_log_eq_self _ /-- The exponentiation map is an isomorphism from the additive monoid on natural numbers to powers when it is injective. The inverse is given by the logarithms. -/ @[simps] def powLogEquiv [DecidableEq M] {n : M} (h : Function.Injective fun m : ℕ => n ^ m) : Multiplicative ℕ ≃* powers n where toFun m := pow n m.toAdd invFun m := Multiplicative.ofAdd (log m) left_inv := log_pow_eq_self h right_inv := pow_log_eq_self map_mul' _ _ := by simp only [pow, map_mul, ofAdd_add, toAdd_mul] theorem log_mul [DecidableEq M] {n : M} (h : Function.Injective fun m : ℕ => n ^ m) (x y : powers (n : M)) : log (x * y) = log x + log y := map_mul (powLogEquiv h).symm x y theorem log_pow_int_eq_self {x : ℤ} (h : 1 < x.natAbs) (m : ℕ) : log (pow x m) = m := (powLogEquiv (Int.pow_right_injective h)).symm_apply_apply _ @[simp] theorem map_powers {N : Type} {F : Type} [Monoid N] [FunLike F M N] [MonoidHomClass F M N] (f : F) (m : M) : (powers m).map f = powers (f m) := by simp only [powers_eq_closure, map_mclosure f, Set.image_singleton] end Submonoid @[to_additive] theorem IsScalarTower.of_mclosure_eq_top {N α} [Monoid M] [MulAction M N] [SMul N α] [MulAction M α] {s : Set M} (htop : Submonoid.closure s = ⊤) (hs : ∀ x ∈ s, ∀ (y : N) (z : α), (x • y) • z = x • y • z) : IsScalarTower M N α := by refine ⟨fun x => Submonoid.induction_of_closure_eq_top_left htop x ?_ ?_⟩ · intro y z rw [one_smul, one_smul] · clear x intro x hx x' hx' y z rw [mul_smul, mul_smul, hs x hx, hx'] @[to_additive] theorem SMulCommClass.of_mclosure_eq_top {N α} [Monoid M] [SMul N α] [MulAction M α] {s : Set M} (htop : Submonoid.closure s = ⊤) (hs : ∀ x ∈ s, ∀ (y : N) (z : α), x • y • z = y • x • z) : SMulCommClass M N α := by refine ⟨fun x => Submonoid.induction_of_closure_eq_top_left htop x ?_ ?_⟩ · intro y z rw [one_smul, one_smul] · clear x intro x hx x' hx' y z rw [mul_smul, mul_smul, hx', hs x hx] namespace Submonoid variable {N : Type} [CommMonoid N] open MonoidHom @[to_additive] theorem sup_eq_range (s t : Submonoid N) : s ⊔ t = mrange (s.subtype.coprod t.subtype) := by rw [mrange_eq_map, ← mrange_inl_sup_mrange_inr, map_sup, map_mrange, coprod_comp_inl, map_mrange, coprod_comp_inr, mrange_subtype, mrange_subtype] @[to_additive] theorem mem_sup {s t : Submonoid N} {x : N} : x ∈ s ⊔ t ↔ ∃ y ∈ s, ∃ z ∈ t, y z = x := by simp only [sup_eq_range, mem_mrange, coprod_apply, coe_subtype, Prod.exists, Subtype.exists, exists_prop] end Submonoid namespace AddSubmonoid variable [AddMonoid A] open Set theorem closure_singleton_eq (x : A) : closure ({x} : Set A) = AddMonoidHom.mrange (multiplesHom A x) := closure_eq_of_le (Set.singleton_subset_iff.2 ⟨1, one_nsmul x⟩) fun _ ⟨_n, hn⟩ => hn ▸ nsmul_mem (subset_closure <\| Set.mem_singleton _) _ /-- The `AddSubmonoid` generated by an element of an `AddMonoid` equals the set of natural number multiples of the element. -/ theorem mem_closure_singleton {x y : A} : y ∈ closure ({x} : Set A) ↔ ∃ n : ℕ, n • x = y := by rw [closure_singleton_eq, AddMonoidHom.mem_mrange]; rfl theorem closure_singleton_zero : closure ({0} : Set A) = ⊥ := by simp [eq_bot_iff_forall, mem_closure_singleton, nsmul_zero] /-- The additive submonoid generated by an element. -/ def multiples (x : A) : AddSubmonoid A := AddSubmonoid.copy (AddMonoidHom.mrange (multiplesHom A x)) (Set.range (fun i => i • x : ℕ → A)) <\| Set.ext fun n => exists_congr fun i => by simp attribute [to_additive existing] Submonoid.powers attribute [to_additive (attr := simp)] Submonoid.mem_powers attribute [to_additive (attr := norm_cast)] Submonoid.coe_powers attribute [to_additive] Submonoid.mem_powers_iff attribute [to_additive] Submonoid.decidableMemPowers attribute [to_additive] Submonoid.fintypePowers attribute [to_additive] Submonoid.powers_eq_closure attribute [to_additive] Submonoid.powers_le attribute [to_additive (attr := simp)] Submonoid.powers_one attribute [to_additive "The additive submonoid generated by an element is an additive group if that element has finite order."] Submonoid.groupPowers end AddSubmonoid namespace Submonoid /-- An element is in the closure of a two-element set if it is a linear combination of those two elements. -/ @[to_additive "An element is in the closure of a two-element set if it is a linear combination of those two elements."] theorem mem_closure_pair {A : Type} [CommMonoid A] (a b c : A) : c ∈ Submonoid.closure ({a, b} : Set A) ↔ ∃ m n : ℕ, a ^ m b ^ n = c := by rw [← Set.singleton_union, Submonoid.closure_union, mem_sup] simp_rw [mem_closure_singleton, exists_exists_eq_and] end Submonoid section mul_add theorem ofMul_image_powers_eq_multiples_ofMul [Monoid M] {x : M} : Additive.ofMul '' (Submonoid.powers x : Set M) = AddSubmonoid.multiples (Additive.ofMul x) := by ext constructor · rintro ⟨y, ⟨n, hy1⟩, hy2⟩ use n simpa [← ofMul_pow, hy1] · rintro ⟨n, hn⟩ refine ⟨x ^ n, ⟨n, rfl⟩, ?_⟩ rwa [ofMul_pow] theorem ofAdd_image_multiples_eq_powers_ofAdd [AddMonoid A] {x : A} : Multiplicative.ofAdd '' (AddSubmonoid.multiples x : Set A) = Submonoid.powers (Multiplicative.ofAdd x) := by symm rw [Equiv.eq_image_iff_symm_image_eq] exact ofMul_image_powers_eq_multiples_ofMul end mul_add		Mathlib/Algebra/Group/Submonoid/Membership.lean	607	615
/- Copyright (c) 2021 Andrew Yang. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Andrew Yang -/ import Mathlib.AlgebraicGeometry.Cover.Open import Mathlib.AlgebraicGeometry.Over /-! # Restriction of Schemes and Morphisms ## Main definition - `AlgebraicGeometry.Scheme.restrict`: The restriction of a scheme along an open embedding. The map `X.restrict f ⟶ X` is `AlgebraicGeometry.Scheme.ofRestrict`. `U : X.Opens` has a coercion to `Scheme` and `U.ι` is a shorthand for `X.restrict U.open_embedding : U ⟶ X`. - `AlgebraicGeometry.morphism_restrict`: The restriction of `X ⟶ Y` to `X ∣_ᵤ f ⁻¹ᵁ U ⟶ Y ∣_ᵤ U`. -/ -- Explicit universe annotations were used in this file to improve performance https://github.com/leanprover-community/mathlib4/issues/12737 noncomputable section open TopologicalSpace CategoryTheory Opposite open CategoryTheory.Limits namespace AlgebraicGeometry universe v v₁ v₂ u u₁ variable {C : Type u₁} [Category.{v} C] section variable {X : Scheme.{u}} (U : X.Opens) namespace Scheme.Opens /-- Open subset of a scheme as a scheme. -/ @[coe] def toScheme {X : Scheme.{u}} (U : X.Opens) : Scheme.{u} := X.restrict U.isOpenEmbedding instance : CoeOut X.Opens Scheme := ⟨toScheme⟩ /-- The restriction of a scheme to an open subset. -/ def ι : ↑U ⟶ X := X.ofRestrict _ @[simp] lemma ι_base_apply (x : U) : U.ι.base x = x.val := rfl instance : IsOpenImmersion U.ι := inferInstanceAs (IsOpenImmersion (X.ofRestrict _)) @[simps! over] instance : U.toScheme.CanonicallyOver X where hom := U.ι instance (U : X.Opens) : U.ι.IsOver X where lemma toScheme_carrier : (U : Type u) = (U : Set X) := rfl lemma toScheme_presheaf_obj (V) : Γ(U, V) = Γ(X, U.ι ''ᵁ V) := rfl @[simp] lemma toScheme_presheaf_map {V W} (i : V ⟶ W) : U.toScheme.presheaf.map i = X.presheaf.map (U.ι.opensFunctor.map i.unop).op := rfl	@[simp] lemma ι_app (V) : U.ι.app V = X.presheaf.map (homOfLE (x := U.ι ''ᵁ U.ι ⁻¹ᵁ V) (Set.image_preimage_subset _ _)).op := rfl @[simp] lemma ι_appTop : U.ι.appTop = X.presheaf.map (homOfLE (x := U.ι ''ᵁ ⊤) le_top).op := rfl	Mathlib/AlgebraicGeometry/Restrict.lean	70	78
/- Copyright (c) 2024 David Loeffler. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: David Loeffler -/ import Mathlib.NumberTheory.LSeries.RiemannZeta import Mathlib.NumberTheory.Harmonic.GammaDeriv /-! # Asymptotics of `ζ s` as `s → 1` The goal of this file is to evaluate the limit of `ζ s - 1 / (s - 1)` as `s → 1`. ### Main results * `tendsto_riemannZeta_sub_one_div`: the limit of `ζ s - 1 / (s - 1)`, at the filter of punctured neighbourhoods of 1 in `ℂ`, exists and is equal to the Euler-Mascheroni constant `γ`. * `riemannZeta_one_ne_zero`: with our definition of `ζ 1` (which is characterised as the limit of `ζ s - 1 / (s - 1) / Gammaℝ s` as `s → 1`), we have `ζ 1 ≠ 0`. ### Outline of arguments We consider the sum `F s = ∑' n : ℕ, f (n + 1) s`, where `s` is a real variable and `f n s = ∫ x in n..(n + 1), (x - n) / x ^ (s + 1)`. We show that `F s` is continuous on `[1, ∞)`, that `F 1 = 1 - γ`, and that `F s = 1 / (s - 1) - ζ s / s` for `1 < s`. By combining these formulae, one deduces that the limit of `ζ s - 1 / (s - 1)` at `𝓝[>] (1 : ℝ)` exists and is equal to `γ`. Finally, using this and the Riemann removable singularity criterion we obtain the limit along punctured neighbourhoods of 1 in `ℂ`. -/ open Real Set MeasureTheory Filter Topology @[inherit_doc] local notation "γ" => eulerMascheroniConstant namespace ZetaAsymptotics -- since the intermediate lemmas are of little interest in themselves we put them in a namespace /-! ## Definitions -/ /-- Auxiliary function used in studying zeta-function asymptotics. -/ noncomputable def term (n : ℕ) (s : ℝ) : ℝ := ∫ x : ℝ in n..(n + 1), (x - n) / x ^ (s + 1) /-- Sum of finitely many `term`s. -/ noncomputable def term_sum (s : ℝ) (N : ℕ) : ℝ := ∑ n ∈ Finset.range N, term (n + 1) s /-- Topological sum of `term`s. -/ noncomputable def term_tsum (s : ℝ) : ℝ := ∑' n, term (n + 1) s lemma term_nonneg (n : ℕ) (s : ℝ) : 0 ≤ term n s := by	rw [term, intervalIntegral.integral_of_le (by simp)] refine setIntegral_nonneg measurableSet_Ioc (fun x hx ↦ ?_) refine div_nonneg ?_ (rpow_nonneg ?_ _) all_goals linarith [hx.1]	Mathlib/NumberTheory/Harmonic/ZetaAsymp.lean	53	57
/- Copyright (c) 2022 Joël Riou. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Joël Riou -/ import Mathlib.AlgebraicTopology.DoldKan.Faces import Mathlib.CategoryTheory.Idempotents.Basic /-! # Construction of projections for the Dold-Kan correspondence In this file, we construct endomorphisms `P q : K[X] ⟶ K[X]` for all `q : ℕ`. We study how they behave with respect to face maps with the lemmas `HigherFacesVanish.of_P`, `HigherFacesVanish.comp_P_eq_self` and `comp_P_eq_self_iff`. Then, we show that they are projections (see `P_f_idem` and `P_idem`). They are natural transformations (see `natTransP` and `P_f_naturality`) and are compatible with the application of additive functors (see `map_P`). By passing to the limit, these endomorphisms `P q` shall be used in `PInfty.lean` in order to define `PInfty : K[X] ⟶ K[X]`. (See `Equivalence.lean` for the general strategy of proof of the Dold-Kan equivalence.) -/ open CategoryTheory CategoryTheory.Category CategoryTheory.Limits CategoryTheory.Preadditive CategoryTheory.SimplicialObject Opposite CategoryTheory.Idempotents open Simplicial DoldKan noncomputable section namespace AlgebraicTopology namespace DoldKan variable {C : Type*} [Category C] [Preadditive C] {X : SimplicialObject C} /-- This is the inductive definition of the projections `P q : K[X] ⟶ K[X]`, with `P 0 := 𝟙 _` and `P (q+1) := P q ≫ (𝟙 _ + Hσ q)`. -/ noncomputable def P : ℕ → (K[X] ⟶ K[X]) \| 0 => 𝟙 _ \| q + 1 => P q ≫ (𝟙 _ + Hσ q) lemma P_zero : (P 0 : K[X] ⟶ K[X]) = 𝟙 _ := rfl lemma P_succ (q : ℕ) : (P (q+1) : K[X] ⟶ K[X]) = P q ≫ (𝟙 _ + Hσ q) := rfl /-- All the `P q` coincide with `𝟙 _` in degree 0. -/ @[simp] theorem P_f_0_eq (q : ℕ) : ((P q).f 0 : X _⦋0⦌ ⟶ X _⦋0⦌) = 𝟙 _ := by induction' q with q hq · rfl · simp only [P_succ, HomologicalComplex.add_f_apply, HomologicalComplex.comp_f, HomologicalComplex.id_f, id_comp, hq, Hσ_eq_zero, add_zero]	/-- `Q q` is the complement projection associated to `P q` -/ def Q (q : ℕ) : K[X] ⟶ K[X] := 𝟙 _ - P q theorem P_add_Q (q : ℕ) : P q + Q q = 𝟙 K[X] := by	Mathlib/AlgebraicTopology/DoldKan/Projections.lean	61	65
/- Copyright (c) 2017 Mario Carneiro. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro -/ import Mathlib.Data.Ordmap.Invariants /-! # Verification of `Ordnode` This file uses the invariants defined in `Mathlib.Data.Ordmap.Invariants` to construct `Ordset α`, a wrapper around `Ordnode α` which includes the correctness invariant of the type. It exposes parallel operations like `insert` as functions on `Ordset` that do the same thing but bundle the correctness proofs. The advantage is that it is possible to, for example, prove that the result of `find` on `insert` will actually find the element, while `Ordnode` cannot guarantee this if the input tree did not satisfy the type invariants. ## Main definitions * `Ordnode.Valid`: The validity predicate for an `Ordnode` subtree. * `Ordset α`: A well formed set of values of type `α`. ## Implementation notes Because the `Ordnode` file was ported from Haskell, the correctness invariants of some of the functions have not been spelled out, and some theorems like `Ordnode.Valid'.balanceL_aux` show very intricate assumptions on the sizes, which may need to be revised if it turns out some operations violate these assumptions, because there is a decent amount of slop in the actual data structure invariants, so the theorem will go through with multiple choices of assumption. -/ variable {α : Type} namespace Ordnode section Valid variable [Preorder α] /-- The validity predicate for an `Ordnode` subtree. This asserts that the `size` fields are correct, the tree is balanced, and the elements of the tree are organized according to the ordering. This version of `Valid` also puts all elements in the tree in the interval `(lo, hi)`. -/ structure Valid' (lo : WithBot α) (t : Ordnode α) (hi : WithTop α) : Prop where ord : t.Bounded lo hi sz : t.Sized bal : t.Balanced /-- The validity predicate for an `Ordnode` subtree. This asserts that the `size` fields are correct, the tree is balanced, and the elements of the tree are organized according to the ordering. -/ def Valid (t : Ordnode α) : Prop := Valid' ⊥ t ⊤ theorem Valid'.mono_left {x y : α} (xy : x ≤ y) {t : Ordnode α} {o} (h : Valid' y t o) : Valid' x t o := ⟨h.1.mono_left xy, h.2, h.3⟩ theorem Valid'.mono_right {x y : α} (xy : x ≤ y) {t : Ordnode α} {o} (h : Valid' o t x) : Valid' o t y := ⟨h.1.mono_right xy, h.2, h.3⟩ theorem Valid'.trans_left {t₁ t₂ : Ordnode α} {x : α} {o₁ o₂} (h : Bounded t₁ o₁ x) (H : Valid' x t₂ o₂) : Valid' o₁ t₂ o₂ := ⟨h.trans_left H.1, H.2, H.3⟩ theorem Valid'.trans_right {t₁ t₂ : Ordnode α} {x : α} {o₁ o₂} (H : Valid' o₁ t₁ x) (h : Bounded t₂ x o₂) : Valid' o₁ t₁ o₂ := ⟨H.1.trans_right h, H.2, H.3⟩ theorem Valid'.of_lt {t : Ordnode α} {x : α} {o₁ o₂} (H : Valid' o₁ t o₂) (h₁ : Bounded nil o₁ x) (h₂ : All (· < x) t) : Valid' o₁ t x := ⟨H.1.of_lt h₁ h₂, H.2, H.3⟩ theorem Valid'.of_gt {t : Ordnode α} {x : α} {o₁ o₂} (H : Valid' o₁ t o₂) (h₁ : Bounded nil x o₂) (h₂ : All (· > x) t) : Valid' x t o₂ := ⟨H.1.of_gt h₁ h₂, H.2, H.3⟩ theorem Valid'.valid {t o₁ o₂} (h : @Valid' α _ o₁ t o₂) : Valid t := ⟨h.1.weak, h.2, h.3⟩ theorem valid'_nil {o₁ o₂} (h : Bounded nil o₁ o₂) : Valid' o₁ (@nil α) o₂ := ⟨h, ⟨⟩, ⟨⟩⟩ theorem valid_nil : Valid (@nil α) := valid'_nil ⟨⟩ theorem Valid'.node {s l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) (H : BalancedSz (size l) (size r)) (hs : s = size l + size r + 1) : Valid' o₁ (@node α s l x r) o₂ := ⟨⟨hl.1, hr.1⟩, ⟨hs, hl.2, hr.2⟩, ⟨H, hl.3, hr.3⟩⟩ theorem Valid'.dual : ∀ {t : Ordnode α} {o₁ o₂}, Valid' o₁ t o₂ → @Valid' αᵒᵈ _ o₂ (dual t) o₁ \| .nil, _, _, h => valid'_nil h.1.dual \| .node _ l _ r, _, _, ⟨⟨ol, Or⟩, ⟨rfl, sl, sr⟩, ⟨b, bl, br⟩⟩ => let ⟨ol', sl', bl'⟩ := Valid'.dual ⟨ol, sl, bl⟩ let ⟨or', sr', br'⟩ := Valid'.dual ⟨Or, sr, br⟩ ⟨⟨or', ol'⟩, ⟨by simp [size_dual, add_comm], sr', sl'⟩, ⟨by rw [size_dual, size_dual]; exact b.symm, br', bl'⟩⟩ theorem Valid'.dual_iff {t : Ordnode α} {o₁ o₂} : Valid' o₁ t o₂ ↔ @Valid' αᵒᵈ _ o₂ (.dual t) o₁ := ⟨Valid'.dual, fun h => by have := Valid'.dual h; rwa [dual_dual, OrderDual.Preorder.dual_dual] at this⟩ theorem Valid.dual {t : Ordnode α} : Valid t → @Valid αᵒᵈ _ (.dual t) := Valid'.dual theorem Valid.dual_iff {t : Ordnode α} : Valid t ↔ @Valid αᵒᵈ _ (.dual t) := Valid'.dual_iff theorem Valid'.left {s l x r o₁ o₂} (H : Valid' o₁ (@Ordnode.node α s l x r) o₂) : Valid' o₁ l x := ⟨H.1.1, H.2.2.1, H.3.2.1⟩ theorem Valid'.right {s l x r o₁ o₂} (H : Valid' o₁ (@Ordnode.node α s l x r) o₂) : Valid' x r o₂ := ⟨H.1.2, H.2.2.2, H.3.2.2⟩ nonrec theorem Valid.left {s l x r} (H : Valid (@node α s l x r)) : Valid l := H.left.valid nonrec theorem Valid.right {s l x r} (H : Valid (@node α s l x r)) : Valid r := H.right.valid theorem Valid.size_eq {s l x r} (H : Valid (@node α s l x r)) : size (@node α s l x r) = size l + size r + 1 := H.2.1 theorem Valid'.node' {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) (H : BalancedSz (size l) (size r)) : Valid' o₁ (@node' α l x r) o₂ := hl.node hr H rfl theorem valid'_singleton {x : α} {o₁ o₂} (h₁ : Bounded nil o₁ x) (h₂ : Bounded nil x o₂) : Valid' o₁ (singleton x : Ordnode α) o₂ := (valid'_nil h₁).node (valid'_nil h₂) (Or.inl zero_le_one) rfl theorem valid_singleton {x : α} : Valid (singleton x : Ordnode α) := valid'_singleton ⟨⟩ ⟨⟩ theorem Valid'.node3L {l} {x : α} {m} {y : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hm : Valid' x m y) (hr : Valid' y r o₂) (H1 : BalancedSz (size l) (size m)) (H2 : BalancedSz (size l + size m + 1) (size r)) : Valid' o₁ (@node3L α l x m y r) o₂ := (hl.node' hm H1).node' hr H2 theorem Valid'.node3R {l} {x : α} {m} {y : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hm : Valid' x m y) (hr : Valid' y r o₂) (H1 : BalancedSz (size l) (size m + size r + 1)) (H2 : BalancedSz (size m) (size r)) : Valid' o₁ (@node3R α l x m y r) o₂ := hl.node' (hm.node' hr H2) H1 theorem Valid'.node4L_lemma₁ {a b c d : ℕ} (lr₂ : 3 (b + c + 1 + d) ≤ 16 * a + 9) (mr₂ : b + c + 1 ≤ 3 * d) (mm₁ : b ≤ 3 * c) : b < 3 * a + 1 := by omega theorem Valid'.node4L_lemma₂ {b c d : ℕ} (mr₂ : b + c + 1 ≤ 3 * d) : c ≤ 3 * d := by omega theorem Valid'.node4L_lemma₃ {b c d : ℕ} (mr₁ : 2 * d ≤ b + c + 1) (mm₁ : b ≤ 3 * c) : d ≤ 3 * c := by omega theorem Valid'.node4L_lemma₄ {a b c d : ℕ} (lr₁ : 3 * a ≤ b + c + 1 + d) (mr₂ : b + c + 1 ≤ 3 * d) (mm₁ : b ≤ 3 * c) : a + b + 1 ≤ 3 * (c + d + 1) := by omega theorem Valid'.node4L_lemma₅ {a b c d : ℕ} (lr₂ : 3 * (b + c + 1 + d) ≤ 16 * a + 9) (mr₁ : 2 * d ≤ b + c + 1) (mm₂ : c ≤ 3 * b) : c + d + 1 ≤ 3 * (a + b + 1) := by omega theorem Valid'.node4L {l} {x : α} {m} {y : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hm : Valid' x m y) (hr : Valid' (↑y) r o₂) (Hm : 0 < size m) (H : size l = 0 ∧ size m = 1 ∧ size r ≤ 1 ∨ 0 < size l ∧ ratio * size r ≤ size m ∧ delta * size l ≤ size m + size r ∧ 3 * (size m + size r) ≤ 16 * size l + 9 ∧ size m ≤ delta * size r) : Valid' o₁ (@node4L α l x m y r) o₂ := by obtain - \| ⟨s, ml, z, mr⟩ := m; · cases Hm suffices BalancedSz (size l) (size ml) ∧ BalancedSz (size mr) (size r) ∧ BalancedSz (size l + size ml + 1) (size mr + size r + 1) from Valid'.node' (hl.node' hm.left this.1) (hm.right.node' hr this.2.1) this.2.2 rcases H with (⟨l0, m1, r0⟩ \| ⟨l0, mr₁, lr₁, lr₂, mr₂⟩) · rw [hm.2.size_eq, Nat.succ_inj, add_eq_zero] at m1 rw [l0, m1.1, m1.2]; revert r0; rcases size r with (_ \| _ \| _) <;> [decide; decide; (intro r0; unfold BalancedSz delta; omega)] · rcases Nat.eq_zero_or_pos (size r) with r0 \| r0 · rw [r0] at mr₂; cases not_le_of_lt Hm mr₂ rw [hm.2.size_eq] at lr₁ lr₂ mr₁ mr₂ by_cases mm : size ml + size mr ≤ 1 · have r1 := le_antisymm ((mul_le_mul_left (by decide)).1 (le_trans mr₁ (Nat.succ_le_succ mm) : _ ≤ ratio * 1)) r0 rw [r1, add_assoc] at lr₁ have l1 := le_antisymm ((mul_le_mul_left (by decide)).1 (le_trans lr₁ (add_le_add_right mm 2) : _ ≤ delta * 1)) l0 rw [l1, r1] revert mm; cases size ml <;> cases size mr <;> intro mm · decide · rw [zero_add] at mm; rcases mm with (_ \| ⟨⟨⟩⟩) decide · rcases mm with (_ \| ⟨⟨⟩⟩); decide · rw [Nat.succ_add] at mm; rcases mm with (_ \| ⟨⟨⟩⟩) rcases hm.3.1.resolve_left mm with ⟨mm₁, mm₂⟩ rcases Nat.eq_zero_or_pos (size ml) with ml0 \| ml0 · rw [ml0, mul_zero, Nat.le_zero] at mm₂ rw [ml0, mm₂] at mm; cases mm (by decide) have : 2 * size l ≤ size ml + size mr + 1 := by have := Nat.mul_le_mul_left ratio lr₁ rw [mul_left_comm, mul_add] at this have := le_trans this (add_le_add_left mr₁ _) rw [← Nat.succ_mul] at this exact (mul_le_mul_left (by decide)).1 this refine ⟨Or.inr ⟨?_, ?_⟩, Or.inr ⟨?_, ?_⟩, Or.inr ⟨?_, ?_⟩⟩ · refine (mul_le_mul_left (by decide)).1 (le_trans this ?_) rw [two_mul, Nat.succ_le_iff] refine add_lt_add_of_lt_of_le ?_ mm₂ simpa using (mul_lt_mul_right ml0).2 (by decide : 1 < 3) · exact Nat.le_of_lt_succ (Valid'.node4L_lemma₁ lr₂ mr₂ mm₁) · exact Valid'.node4L_lemma₂ mr₂ · exact Valid'.node4L_lemma₃ mr₁ mm₁ · exact Valid'.node4L_lemma₄ lr₁ mr₂ mm₁ · exact Valid'.node4L_lemma₅ lr₂ mr₁ mm₂ theorem Valid'.rotateL_lemma₁ {a b c : ℕ} (H2 : 3 * a ≤ b + c) (hb₂ : c ≤ 3 * b) : a ≤ 3 * b := by omega theorem Valid'.rotateL_lemma₂ {a b c : ℕ} (H3 : 2 * (b + c) ≤ 9 * a + 3) (h : b < 2 * c) : b < 3 * a + 1 := by omega theorem Valid'.rotateL_lemma₃ {a b c : ℕ} (H2 : 3 * a ≤ b + c) (h : b < 2 * c) : a + b < 3 * c := by omega theorem Valid'.rotateL_lemma₄ {a b : ℕ} (H3 : 2 * b ≤ 9 * a + 3) : 3 * b ≤ 16 * a + 9 := by omega theorem Valid'.rotateL {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) (H1 : ¬size l + size r ≤ 1) (H2 : delta * size l < size r) (H3 : 2 * size r ≤ 9 * size l + 5 ∨ size r ≤ 3) : Valid' o₁ (@rotateL α l x r) o₂ := by obtain - \| ⟨rs, rl, rx, rr⟩ := r; · cases H2 rw [hr.2.size_eq, Nat.lt_succ_iff] at H2 rw [hr.2.size_eq] at H3 replace H3 : 2 * (size rl + size rr) ≤ 9 * size l + 3 ∨ size rl + size rr ≤ 2 := H3.imp (@Nat.le_of_add_le_add_right _ 2 _) Nat.le_of_succ_le_succ have H3_0 : size l = 0 → size rl + size rr ≤ 2 := by intro l0; rw [l0] at H3 exact (or_iff_right_of_imp fun h => (mul_le_mul_left (by decide)).1 (le_trans h (by decide))).1 H3 have H3p : size l > 0 → 2 * (size rl + size rr) ≤ 9 * size l + 3 := fun l0 : 1 ≤ size l => (or_iff_left_of_imp <\| by omega).1 H3 have ablem : ∀ {a b : ℕ}, 1 ≤ a → a + b ≤ 2 → b ≤ 1 := by omega have hlp : size l > 0 → ¬size rl + size rr ≤ 1 := fun l0 hb => absurd (le_trans (le_trans (Nat.mul_le_mul_left _ l0) H2) hb) (by decide) rw [Ordnode.rotateL_node]; split_ifs with h · have rr0 : size rr > 0 := (mul_lt_mul_left (by decide)).1 (lt_of_le_of_lt (Nat.zero_le _) h : ratio * 0 < _) suffices BalancedSz (size l) (size rl) ∧ BalancedSz (size l + size rl + 1) (size rr) by exact hl.node3L hr.left hr.right this.1 this.2 rcases Nat.eq_zero_or_pos (size l) with l0 \| l0 · rw [l0]; replace H3 := H3_0 l0 have := hr.3.1 rcases Nat.eq_zero_or_pos (size rl) with rl0 \| rl0 · rw [rl0] at this ⊢ rw [le_antisymm (balancedSz_zero.1 this.symm) rr0] decide have rr1 : size rr = 1 := le_antisymm (ablem rl0 H3) rr0 rw [add_comm] at H3 rw [rr1, show size rl = 1 from le_antisymm (ablem rr0 H3) rl0] decide replace H3 := H3p l0 rcases hr.3.1.resolve_left (hlp l0) with ⟨_, hb₂⟩ refine ⟨Or.inr ⟨?_, ?_⟩, Or.inr ⟨?_, ?_⟩⟩ · exact Valid'.rotateL_lemma₁ H2 hb₂ · exact Nat.le_of_lt_succ (Valid'.rotateL_lemma₂ H3 h) · exact Valid'.rotateL_lemma₃ H2 h · exact le_trans hb₂ (Nat.mul_le_mul_left _ <\| le_trans (Nat.le_add_left _ _) (Nat.le_add_right _ _)) · rcases Nat.eq_zero_or_pos (size rl) with rl0 \| rl0 · rw [rl0, not_lt, Nat.le_zero, Nat.mul_eq_zero] at h replace h := h.resolve_left (by decide) rw [rl0, h, Nat.le_zero, Nat.mul_eq_zero] at H2 rw [hr.2.size_eq, rl0, h, H2.resolve_left (by decide)] at H1 cases H1 (by decide) refine hl.node4L hr.left hr.right rl0 ?_ rcases Nat.eq_zero_or_pos (size l) with l0 \| l0 · replace H3 := H3_0 l0 rcases Nat.eq_zero_or_pos (size rr) with rr0 \| rr0 · have := hr.3.1 rw [rr0] at this exact Or.inl ⟨l0, le_antisymm (balancedSz_zero.1 this) rl0, rr0.symm ▸ zero_le_one⟩ exact Or.inl ⟨l0, le_antisymm (ablem rr0 <\| by rwa [add_comm]) rl0, ablem rl0 H3⟩ exact Or.inr ⟨l0, not_lt.1 h, H2, Valid'.rotateL_lemma₄ (H3p l0), (hr.3.1.resolve_left (hlp l0)).1⟩ theorem Valid'.rotateR {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) (H1 : ¬size l + size r ≤ 1) (H2 : delta * size r < size l) (H3 : 2 * size l ≤ 9 * size r + 5 ∨ size l ≤ 3) : Valid' o₁ (@rotateR α l x r) o₂ := by refine Valid'.dual_iff.2 ?_ rw [dual_rotateR] refine hr.dual.rotateL hl.dual ?_ ?_ ?_ · rwa [size_dual, size_dual, add_comm] · rwa [size_dual, size_dual] · rwa [size_dual, size_dual] theorem Valid'.balance'_aux {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) (H₁ : 2 * @size α r ≤ 9 * size l + 5 ∨ size r ≤ 3) (H₂ : 2 * @size α l ≤ 9 * size r + 5 ∨ size l ≤ 3) : Valid' o₁ (@balance' α l x r) o₂ := by rw [balance']; split_ifs with h h_1 h_2 · exact hl.node' hr (Or.inl h) · exact hl.rotateL hr h h_1 H₁ · exact hl.rotateR hr h h_2 H₂ · exact hl.node' hr (Or.inr ⟨not_lt.1 h_2, not_lt.1 h_1⟩) theorem Valid'.balance'_lemma {α l l' r r'} (H1 : BalancedSz l' r') (H2 : Nat.dist (@size α l) l' ≤ 1 ∧ size r = r' ∨ Nat.dist (size r) r' ≤ 1 ∧ size l = l') : 2 * @size α r ≤ 9 * size l + 5 ∨ size r ≤ 3 := by suffices @size α r ≤ 3 * (size l + 1) by omega rcases H2 with (⟨hl, rfl⟩ \| ⟨hr, rfl⟩) <;> rcases H1 with (h \| ⟨_, h₂⟩) · exact le_trans (Nat.le_add_left _ _) (le_trans h (Nat.le_add_left _ _)) · exact le_trans h₂ (Nat.mul_le_mul_left _ <\| le_trans (Nat.dist_tri_right _ _) (Nat.add_le_add_left hl _)) · exact le_trans (Nat.dist_tri_left' _ _) (le_trans (add_le_add hr (le_trans (Nat.le_add_left _ _) h)) (by omega)) · rw [Nat.mul_succ] exact le_trans (Nat.dist_tri_right' _ _) (add_le_add h₂ (le_trans hr (by decide))) theorem Valid'.balance' {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) (H : ∃ l' r', BalancedSz l' r' ∧ (Nat.dist (size l) l' ≤ 1 ∧ size r = r' ∨ Nat.dist (size r) r' ≤ 1 ∧ size l = l')) : Valid' o₁ (@balance' α l x r) o₂ := let ⟨_, _, H1, H2⟩ := H Valid'.balance'_aux hl hr (Valid'.balance'_lemma H1 H2) (Valid'.balance'_lemma H1.symm H2.symm) theorem Valid'.balance {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) (H : ∃ l' r', BalancedSz l' r' ∧ (Nat.dist (size l) l' ≤ 1 ∧ size r = r' ∨ Nat.dist (size r) r' ≤ 1 ∧ size l = l')) : Valid' o₁ (@balance α l x r) o₂ := by rw [balance_eq_balance' hl.3 hr.3 hl.2 hr.2]; exact hl.balance' hr H theorem Valid'.balanceL_aux {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) (H₁ : size l = 0 → size r ≤ 1) (H₂ : 1 ≤ size l → 1 ≤ size r → size r ≤ delta * size l) (H₃ : 2 * @size α l ≤ 9 * size r + 5 ∨ size l ≤ 3) : Valid' o₁ (@balanceL α l x r) o₂ := by rw [balanceL_eq_balance hl.2 hr.2 H₁ H₂, balance_eq_balance' hl.3 hr.3 hl.2 hr.2] refine hl.balance'_aux hr (Or.inl ?_) H₃ rcases Nat.eq_zero_or_pos (size r) with r0 \| r0 · rw [r0]; exact Nat.zero_le _ rcases Nat.eq_zero_or_pos (size l) with l0 \| l0 · rw [l0]; exact le_trans (Nat.mul_le_mul_left _ (H₁ l0)) (by decide) replace H₂ : _ ≤ 3 * _ := H₂ l0 r0; omega theorem Valid'.balanceL {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) (H : (∃ l', Raised l' (size l) ∧ BalancedSz l' (size r)) ∨ ∃ r', Raised (size r) r' ∧ BalancedSz (size l) r') : Valid' o₁ (@balanceL α l x r) o₂ := by rw [balanceL_eq_balance' hl.3 hr.3 hl.2 hr.2 H] refine hl.balance' hr ?_ rcases H with (⟨l', e, H⟩ \| ⟨r', e, H⟩) · exact ⟨_, _, H, Or.inl ⟨e.dist_le', rfl⟩⟩ · exact ⟨_, _, H, Or.inr ⟨e.dist_le, rfl⟩⟩ theorem Valid'.balanceR_aux {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) (H₁ : size r = 0 → size l ≤ 1) (H₂ : 1 ≤ size r → 1 ≤ size l → size l ≤ delta * size r) (H₃ : 2 * @size α r ≤ 9 * size l + 5 ∨ size r ≤ 3) : Valid' o₁ (@balanceR α l x r) o₂ := by rw [Valid'.dual_iff, dual_balanceR] have := hr.dual.balanceL_aux hl.dual rw [size_dual, size_dual] at this exact this H₁ H₂ H₃ theorem Valid'.balanceR {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) (H : (∃ l', Raised (size l) l' ∧ BalancedSz l' (size r)) ∨ ∃ r', Raised r' (size r) ∧ BalancedSz (size l) r') : Valid' o₁ (@balanceR α l x r) o₂ := by rw [Valid'.dual_iff, dual_balanceR]; exact hr.dual.balanceL hl.dual (balance_sz_dual H) theorem Valid'.eraseMax_aux {s l x r o₁ o₂} (H : Valid' o₁ (.node s l x r) o₂) : Valid' o₁ (@eraseMax α (.node' l x r)) ↑(findMax' x r) ∧ size (.node' l x r) = size (eraseMax (.node' l x r)) + 1 := by have := H.2.eq_node'; rw [this] at H; clear this induction r generalizing l x o₁ with \| nil => exact ⟨H.left, rfl⟩ \| node rs rl rx rr _ IHrr => have := H.2.2.2.eq_node'; rw [this] at H ⊢ rcases IHrr H.right with ⟨h, e⟩ refine ⟨Valid'.balanceL H.left h (Or.inr ⟨_, Or.inr e, H.3.1⟩), ?_⟩ rw [eraseMax, size_balanceL H.3.2.1 h.3 H.2.2.1 h.2 (Or.inr ⟨_, Or.inr e, H.3.1⟩)] rw [size_node, e]; rfl theorem Valid'.eraseMin_aux {s l} {x : α} {r o₁ o₂} (H : Valid' o₁ (.node s l x r) o₂) : Valid' ↑(findMin' l x) (@eraseMin α (.node' l x r)) o₂ ∧ size (.node' l x r) = size (eraseMin (.node' l x r)) + 1 := by have := H.dual.eraseMax_aux rwa [← dual_node', size_dual, ← dual_eraseMin, size_dual, ← Valid'.dual_iff, findMax'_dual] at this theorem eraseMin.valid : ∀ {t}, @Valid α _ t → Valid (eraseMin t) \| nil, _ => valid_nil \| node _ l x r, h => by rw [h.2.eq_node']; exact h.eraseMin_aux.1.valid theorem eraseMax.valid {t} (h : @Valid α _ t) : Valid (eraseMax t) := by rw [Valid.dual_iff, dual_eraseMax]; exact eraseMin.valid h.dual theorem Valid'.glue_aux {l r o₁ o₂} (hl : Valid' o₁ l o₂) (hr : Valid' o₁ r o₂) (sep : l.All fun x => r.All fun y => x < y) (bal : BalancedSz (size l) (size r)) : Valid' o₁ (@glue α l r) o₂ ∧ size (glue l r) = size l + size r := by obtain - \| ⟨ls, ll, lx, lr⟩ := l; · exact ⟨hr, (zero_add _).symm⟩ obtain - \| ⟨rs, rl, rx, rr⟩ := r; · exact ⟨hl, rfl⟩ dsimp [glue]; split_ifs · rw [splitMax_eq] · obtain ⟨v, e⟩ := Valid'.eraseMax_aux hl suffices H : _ by refine ⟨Valid'.balanceR v (hr.of_gt ?_ ?_) H, ?_⟩ · refine findMax'_all (P := fun a : α => Bounded nil (a : WithTop α) o₂) lx lr hl.1.2.to_nil (sep.2.2.imp ?_) exact fun x h => hr.1.2.to_nil.mono_left (le_of_lt h.2.1) · exact @findMax'_all _ (fun a => All (· > a) (.node rs rl rx rr)) lx lr sep.2.1 sep.2.2 · rw [size_balanceR v.3 hr.3 v.2 hr.2 H, add_right_comm, ← e, hl.2.1]; rfl refine Or.inl ⟨_, Or.inr e, ?_⟩ rwa [hl.2.eq_node'] at bal · rw [splitMin_eq] · obtain ⟨v, e⟩ := Valid'.eraseMin_aux hr suffices H : _ by refine ⟨Valid'.balanceL (hl.of_lt ?_ ?_) v H, ?_⟩ · refine @findMin'_all (P := fun a : α => Bounded nil o₁ (a : WithBot α)) _ rl rx (sep.2.1.1.imp ?_) hr.1.1.to_nil exact fun y h => hl.1.1.to_nil.mono_right (le_of_lt h) · exact @findMin'_all _ (fun a => All (· < a) (.node ls ll lx lr)) rl rx (all_iff_forall.2 fun x hx => sep.imp fun y hy => all_iff_forall.1 hy.1 _ hx) (sep.imp fun y hy => hy.2.1) · rw [size_balanceL hl.3 v.3 hl.2 v.2 H, add_assoc, ← e, hr.2.1]; rfl refine Or.inr ⟨_, Or.inr e, ?_⟩ rwa [hr.2.eq_node'] at bal theorem Valid'.glue {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) : BalancedSz (size l) (size r) → Valid' o₁ (@glue α l r) o₂ ∧ size (@glue α l r) = size l + size r := Valid'.glue_aux (hl.trans_right hr.1) (hr.trans_left hl.1) (hl.1.to_sep hr.1) theorem Valid'.merge_lemma {a b c : ℕ} (h₁ : 3 * a < b + c + 1) (h₂ : b ≤ 3 * c) : 2 * (a + b) ≤ 9 * c + 5 := by omega theorem Valid'.merge_aux₁ {o₁ o₂ ls ll lx lr rs rl rx rr t} (hl : Valid' o₁ (@Ordnode.node α ls ll lx lr) o₂) (hr : Valid' o₁ (.node rs rl rx rr) o₂) (h : delta * ls < rs) (v : Valid' o₁ t rx) (e : size t = ls + size rl) : Valid' o₁ (.balanceL t rx rr) o₂ ∧ size (.balanceL t rx rr) = ls + rs := by rw [hl.2.1] at e rw [hl.2.1, hr.2.1, delta] at h rcases hr.3.1 with (H \| ⟨hr₁, hr₂⟩); · omega suffices H₂ : _ by suffices H₁ : _ by refine ⟨Valid'.balanceL_aux v hr.right H₁ H₂ ?_, ?_⟩ · rw [e]; exact Or.inl (Valid'.merge_lemma h hr₁) · rw [balanceL_eq_balance v.2 hr.2.2.2 H₁ H₂, balance_eq_balance' v.3 hr.3.2.2 v.2 hr.2.2.2, size_balance' v.2 hr.2.2.2, e, hl.2.1, hr.2.1] abel · rw [e, add_right_comm]; rintro ⟨⟩ intro _ _; rw [e]; unfold delta at hr₂ ⊢; omega theorem Valid'.merge_aux {l r o₁ o₂} (hl : Valid' o₁ l o₂) (hr : Valid' o₁ r o₂) (sep : l.All fun x => r.All fun y => x < y) : Valid' o₁ (@merge α l r) o₂ ∧ size (merge l r) = size l + size r := by induction l generalizing o₁ o₂ r with \| nil => exact ⟨hr, (zero_add _).symm⟩ \| node ls ll lx lr _ IHlr => ?_ induction r generalizing o₁ o₂ with \| nil => exact ⟨hl, rfl⟩ \| node rs rl rx rr IHrl _ => ?_ rw [merge_node]; split_ifs with h h_1 · obtain ⟨v, e⟩ := IHrl (hl.of_lt hr.1.1.to_nil <\| sep.imp fun x h => h.2.1) hr.left (sep.imp fun x h => h.1) exact Valid'.merge_aux₁ hl hr h v e · obtain ⟨v, e⟩ := IHlr hl.right (hr.of_gt hl.1.2.to_nil sep.2.1) sep.2.2 have := Valid'.merge_aux₁ hr.dual hl.dual h_1 v.dual rw [size_dual, add_comm, size_dual, ← dual_balanceR, ← Valid'.dual_iff, size_dual, add_comm rs] at this exact this e · refine Valid'.glue_aux hl hr sep (Or.inr ⟨not_lt.1 h_1, not_lt.1 h⟩) theorem Valid.merge {l r} (hl : Valid l) (hr : Valid r) (sep : l.All fun x => r.All fun y => x < y) : Valid (@merge α l r) := (Valid'.merge_aux hl hr sep).1 theorem insertWith.valid_aux [IsTotal α (· ≤ ·)] [DecidableLE α] (f : α → α) (x : α) (hf : ∀ y, x ≤ y ∧ y ≤ x → x ≤ f y ∧ f y ≤ x) : ∀ {t o₁ o₂}, Valid' o₁ t o₂ → Bounded nil o₁ x → Bounded nil x o₂ → Valid' o₁ (insertWith f x t) o₂ ∧ Raised (size t) (size (insertWith f x t)) \| nil, _, _, _, bl, br => ⟨valid'_singleton bl br, Or.inr rfl⟩ \| node sz l y r, o₁, o₂, h, bl, br => by rw [insertWith, cmpLE] split_ifs with h_1 h_2 <;> dsimp only · rcases h with ⟨⟨lx, xr⟩, hs, hb⟩ rcases hf _ ⟨h_1, h_2⟩ with ⟨xf, fx⟩ refine ⟨⟨⟨lx.mono_right (le_trans h_2 xf), xr.mono_left (le_trans fx h_1)⟩, hs, hb⟩, Or.inl rfl⟩ · rcases insertWith.valid_aux f x hf h.left bl (lt_of_le_not_le h_1 h_2) with ⟨vl, e⟩ suffices H : _ by refine ⟨vl.balanceL h.right H, ?_⟩ rw [size_balanceL vl.3 h.3.2.2 vl.2 h.2.2.2 H, h.2.size_eq] exact (e.add_right _).add_right _ exact Or.inl ⟨_, e, h.3.1⟩ · have : y < x := lt_of_le_not_le ((total_of (· ≤ ·) _ _).resolve_left h_1) h_1 rcases insertWith.valid_aux f x hf h.right this br with ⟨vr, e⟩ suffices H : _ by refine ⟨h.left.balanceR vr H, ?_⟩ rw [size_balanceR h.3.2.1 vr.3 h.2.2.1 vr.2 H, h.2.size_eq] exact (e.add_left _).add_right _ exact Or.inr ⟨_, e, h.3.1⟩ theorem insertWith.valid [IsTotal α (· ≤ ·)] [DecidableLE α] (f : α → α) (x : α) (hf : ∀ y, x ≤ y ∧ y ≤ x → x ≤ f y ∧ f y ≤ x) {t} (h : Valid t) : Valid (insertWith f x t) := (insertWith.valid_aux _ _ hf h ⟨⟩ ⟨⟩).1 theorem insert_eq_insertWith [DecidableLE α] (x : α) : ∀ t, Ordnode.insert x t = insertWith (fun _ => x) x t \| nil => rfl \| node _ l y r => by unfold Ordnode.insert insertWith; cases cmpLE x y <;> simp [insert_eq_insertWith] theorem insert.valid [IsTotal α (· ≤ ·)] [DecidableLE α] (x : α) {t} (h : Valid t) : Valid (Ordnode.insert x t) := by rw [insert_eq_insertWith]; exact insertWith.valid _ _ (fun _ _ => ⟨le_rfl, le_rfl⟩) h theorem insert'_eq_insertWith [DecidableLE α] (x : α) : ∀ t, insert' x t = insertWith id x t \| nil => rfl \| node _ l y r => by unfold insert' insertWith; cases cmpLE x y <;> simp [insert'_eq_insertWith] theorem insert'.valid [IsTotal α (· ≤ ·)] [DecidableLE α] (x : α) {t} (h : Valid t) : Valid (insert' x t) := by rw [insert'_eq_insertWith]; exact insertWith.valid _ _ (fun _ => id) h theorem Valid'.map_aux {β} [Preorder β] {f : α → β} (f_strict_mono : StrictMono f) {t a₁ a₂} (h : Valid' a₁ t a₂) : Valid' (Option.map f a₁) (map f t) (Option.map f a₂) ∧ (map f t).size = t.size := by induction t generalizing a₁ a₂ with \| nil => simp only [map, size_nil, and_true]; apply valid'_nil cases a₁; · trivial cases a₂; · trivial simp only [Option.map, Bounded] exact f_strict_mono h.ord \| node _ _ _ _ t_ih_l t_ih_r => have t_ih_l' := t_ih_l h.left have t_ih_r' := t_ih_r h.right clear t_ih_l t_ih_r obtain ⟨t_l_valid, t_l_size⟩ := t_ih_l' obtain ⟨t_r_valid, t_r_size⟩ := t_ih_r' simp only [map, size_node, and_true] constructor · exact And.intro t_l_valid.ord t_r_valid.ord · constructor · rw [t_l_size, t_r_size]; exact h.sz.1 · constructor · exact t_l_valid.sz · exact t_r_valid.sz · constructor · rw [t_l_size, t_r_size]; exact h.bal.1 · constructor · exact t_l_valid.bal · exact t_r_valid.bal theorem map.valid {β} [Preorder β] {f : α → β} (f_strict_mono : StrictMono f) {t} (h : Valid t) : Valid (map f t) := (Valid'.map_aux f_strict_mono h).1 theorem Valid'.erase_aux [DecidableLE α] (x : α) {t a₁ a₂} (h : Valid' a₁ t a₂) : Valid' a₁ (erase x t) a₂ ∧ Raised (erase x t).size t.size := by induction t generalizing a₁ a₂ with \| nil => simpa [erase, Raised] \| node _ t_l t_x t_r t_ih_l t_ih_r => simp only [erase, size_node] have t_ih_l' := t_ih_l h.left have t_ih_r' := t_ih_r h.right clear t_ih_l t_ih_r obtain ⟨t_l_valid, t_l_size⟩ := t_ih_l' obtain ⟨t_r_valid, t_r_size⟩ := t_ih_r' cases cmpLE x t_x <;> rw [h.sz.1] · suffices h_balanceable : _ by constructor · exact Valid'.balanceR t_l_valid h.right h_balanceable	· rw [size_balanceR t_l_valid.bal h.right.bal t_l_valid.sz h.right.sz h_balanceable] repeat apply Raised.add_right	Mathlib/Data/Ordmap/Ordset.lean	586	587
/- Copyright (c) 2022 Yury Kudryashov. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yury Kudryashov -/ import Mathlib.Analysis.Complex.CauchyIntegral import Mathlib.Analysis.Calculus.FDeriv.Analytic import Mathlib.Analysis.Normed.Module.Completion /-! # Liouville's theorem In this file we prove Liouville's theorem: if `f : E → F` is complex differentiable on the whole space and its range is bounded, then the function is a constant. Various versions of this theorem are formalized in `Differentiable.apply_eq_apply_of_bounded`, `Differentiable.exists_const_forall_eq_of_bounded`, and `Differentiable.exists_eq_const_of_bounded`. The proof is based on the Cauchy integral formula for the derivative of an analytic function, see `Complex.deriv_eq_smul_circleIntegral`. -/ open TopologicalSpace Metric Set Filter Asymptotics Function MeasureTheory Bornology open scoped Topology Filter NNReal Real universe u v variable {E : Type u} [NormedAddCommGroup E] [NormedSpace ℂ E] {F : Type v} [NormedAddCommGroup F] [NormedSpace ℂ F] local postfix:100 "̂" => UniformSpace.Completion namespace Complex /-- If `f` is complex differentiable on an open disc with center `c` and radius `R > 0` and is continuous on its closure, then `f' c` can be represented as an integral over the corresponding circle. TODO: add a version for `w ∈ Metric.ball c R`. TODO: add a version for higher derivatives. -/ theorem deriv_eq_smul_circleIntegral [CompleteSpace F] {R : ℝ} {c : ℂ} {f : ℂ → F} (hR : 0 < R) (hf : DiffContOnCl ℂ f (ball c R)) : deriv f c = (2 * π * I : ℂ)⁻¹ • ∮ z in C(c, R), (z - c) ^ (-2 : ℤ) • f z := by lift R to ℝ≥0 using hR.le refine (hf.hasFPowerSeriesOnBall hR).hasFPowerSeriesAt.deriv.trans ?_ simp only [cauchyPowerSeries_apply, one_div, zpow_neg, pow_one, smul_smul, zpow_two, mul_inv] theorem norm_deriv_le_aux [CompleteSpace F] {c : ℂ} {R C : ℝ} {f : ℂ → F} (hR : 0 < R) (hf : DiffContOnCl ℂ f (ball c R)) (hC : ∀ z ∈ sphere c R, ‖f z‖ ≤ C) : ‖deriv f c‖ ≤ C / R := by have : ∀ z ∈ sphere c R, ‖(z - c) ^ (-2 : ℤ) • f z‖ ≤ C / (R * R) := fun z (hz : ‖z - c‖ = R) => by simpa [-mul_inv_rev, norm_smul, hz, zpow_two, ← div_eq_inv_mul] using (div_le_div_iff_of_pos_right (mul_pos hR hR)).2 (hC z hz) calc ‖deriv f c‖ = ‖(2 * π * I : ℂ)⁻¹ • ∮ z in C(c, R), (z - c) ^ (-2 : ℤ) • f z‖ := congr_arg norm (deriv_eq_smul_circleIntegral hR hf) _ ≤ R * (C / (R * R)) := (circleIntegral.norm_two_pi_i_inv_smul_integral_le_of_norm_le_const hR.le this) _ = C / R := by rw [mul_div_left_comm, div_self_mul_self', div_eq_mul_inv] /-- If `f` is complex differentiable on an open disc of radius `R > 0`, is continuous on its closure, and its values on the boundary circle of this disc are bounded from above by `C`, then the norm of its derivative at the center is at most `C / R`. -/ theorem norm_deriv_le_of_forall_mem_sphere_norm_le {c : ℂ} {R C : ℝ} {f : ℂ → F} (hR : 0 < R) (hd : DiffContOnCl ℂ f (ball c R)) (hC : ∀ z ∈ sphere c R, ‖f z‖ ≤ C) : ‖deriv f c‖ ≤ C / R := by set e : F →L[ℂ] F̂ := UniformSpace.Completion.toComplL have : HasDerivAt (e ∘ f) (e (deriv f c)) c := e.hasFDerivAt.comp_hasDerivAt c (hd.differentiableAt isOpen_ball <\| mem_ball_self hR).hasDerivAt calc ‖deriv f c‖ = ‖deriv (e ∘ f) c‖ := by rw [this.deriv] exact (UniformSpace.Completion.norm_coe _).symm _ ≤ C / R := norm_deriv_le_aux hR (e.differentiable.comp_diffContOnCl hd) fun z hz => (UniformSpace.Completion.norm_coe _).trans_le (hC z hz) /-- An auxiliary lemma for Liouville's theorem `Differentiable.apply_eq_apply_of_bounded`. -/ theorem liouville_theorem_aux {f : ℂ → F} (hf : Differentiable ℂ f) (hb : IsBounded (range f)) (z w : ℂ) : f z = f w := by suffices ∀ c, deriv f c = 0 from is_const_of_deriv_eq_zero hf this z w clear z w; intro c obtain ⟨C, C₀, hC⟩ : ∃ C > (0 : ℝ), ∀ z, ‖f z‖ ≤ C := by rcases isBounded_iff_forall_norm_le.1 hb with ⟨C, hC⟩ exact ⟨max C 1, lt_max_iff.2 (Or.inr zero_lt_one), fun z => (hC (f z) (mem_range_self _)).trans (le_max_left _ _)⟩ refine norm_le_zero_iff.1 (le_of_forall_gt_imp_ge_of_dense fun ε ε₀ => ?_) calc ‖deriv f c‖ ≤ C / (C / ε) := norm_deriv_le_of_forall_mem_sphere_norm_le (div_pos C₀ ε₀) hf.diffContOnCl fun z _ => hC z _ = ε := div_div_cancel₀ C₀.lt.ne' end Complex namespace Differentiable open Complex /-- Liouville's theorem: a complex differentiable bounded function `f : E → F` is a constant. -/ theorem apply_eq_apply_of_bounded {f : E → F} (hf : Differentiable ℂ f) (hb : IsBounded (range f)) (z w : E) : f z = f w := by set g : ℂ → F := f ∘ fun t : ℂ => t • (w - z) + z suffices g 0 = g 1 by simpa [g] apply liouville_theorem_aux exacts [hf.comp ((differentiable_id.smul_const (w - z)).add_const z),	hb.subset (range_comp_subset_range _ _)] /-- Liouville's theorem: a complex differentiable bounded function is a constant. -/ theorem exists_const_forall_eq_of_bounded {f : E → F} (hf : Differentiable ℂ f) (hb : IsBounded (range f)) : ∃ c, ∀ z, f z = c := ⟨f 0, fun _ => hf.apply_eq_apply_of_bounded hb _ _⟩	Mathlib/Analysis/Complex/Liouville.lean	111	117
/- Copyright (c) 2019 Jeremy Avigad. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jeremy Avigad, Sébastien Gouëzel, Yury Kudryashov -/ import Mathlib.Analysis.Analytic.Constructions import Mathlib.Analysis.Calculus.FDeriv.Analytic import Mathlib.Analysis.Calculus.FDeriv.Bilinear /-! # Multiplicative operations on derivatives For detailed documentation of the Fréchet derivative, see the module docstring of `Mathlib/Analysis/Calculus/FDeriv/Basic.lean`. This file contains the usual formulas (and existence assertions) for the derivative of * multiplication of a function by a scalar function * product of finitely many scalar functions * taking the pointwise multiplicative inverse (i.e. `Inv.inv` or `Ring.inverse`) of a function -/ open Asymptotics ContinuousLinearMap Topology section variable {𝕜 : Type} [NontriviallyNormedField 𝕜] variable {E : Type} [NormedAddCommGroup E] [NormedSpace 𝕜 E] variable {F : Type} [NormedAddCommGroup F] [NormedSpace 𝕜 F] variable {G : Type} [NormedAddCommGroup G] [NormedSpace 𝕜 G] variable {f : E → F} variable {f' : E →L[𝕜] F} variable {x : E} variable {s : Set E} section CLMCompApply /-! ### Derivative of the pointwise composition/application of continuous linear maps -/ variable {H : Type} [NormedAddCommGroup H] [NormedSpace 𝕜 H] {c : E → G →L[𝕜] H} {c' : E →L[𝕜] G →L[𝕜] H} {d : E → F →L[𝕜] G} {d' : E →L[𝕜] F →L[𝕜] G} {u : E → G} {u' : E →L[𝕜] G} #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 split proof term into steps to solve unification issues. -/ @[fun_prop] theorem HasStrictFDerivAt.clm_comp (hc : HasStrictFDerivAt c c' x) (hd : HasStrictFDerivAt d d' x) : HasStrictFDerivAt (fun y => (c y).comp (d y)) ((compL 𝕜 F G H (c x)).comp d' + ((compL 𝕜 F G H).flip (d x)).comp c') x := by have := isBoundedBilinearMap_comp.hasStrictFDerivAt (c x, d x) have := this.comp x (hc.prodMk hd) exact this #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivWithinAt.clm_comp (hc : HasFDerivWithinAt c c' s x) (hd : HasFDerivWithinAt d d' s x) : HasFDerivWithinAt (fun y => (c y).comp (d y)) ((compL 𝕜 F G H (c x)).comp d' + ((compL 𝕜 F G H).flip (d x)).comp c') s x := by exact (isBoundedBilinearMap_comp.hasFDerivAt (c x, d x) :).comp_hasFDerivWithinAt x (hc.prodMk hd) #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivAt.clm_comp (hc : HasFDerivAt c c' x) (hd : HasFDerivAt d d' x) : HasFDerivAt (fun y => (c y).comp (d y)) ((compL 𝕜 F G H (c x)).comp d' + ((compL 𝕜 F G H).flip (d x)).comp c') x := by exact (isBoundedBilinearMap_comp.hasFDerivAt (c x, d x) :).comp x <\| hc.prodMk hd @[fun_prop] theorem DifferentiableWithinAt.clm_comp (hc : DifferentiableWithinAt 𝕜 c s x) (hd : DifferentiableWithinAt 𝕜 d s x) : DifferentiableWithinAt 𝕜 (fun y => (c y).comp (d y)) s x := (hc.hasFDerivWithinAt.clm_comp hd.hasFDerivWithinAt).differentiableWithinAt @[fun_prop] theorem DifferentiableAt.clm_comp (hc : DifferentiableAt 𝕜 c x) (hd : DifferentiableAt 𝕜 d x) : DifferentiableAt 𝕜 (fun y => (c y).comp (d y)) x := (hc.hasFDerivAt.clm_comp hd.hasFDerivAt).differentiableAt @[fun_prop] theorem DifferentiableOn.clm_comp (hc : DifferentiableOn 𝕜 c s) (hd : DifferentiableOn 𝕜 d s) : DifferentiableOn 𝕜 (fun y => (c y).comp (d y)) s := fun x hx => (hc x hx).clm_comp (hd x hx) @[fun_prop] theorem Differentiable.clm_comp (hc : Differentiable 𝕜 c) (hd : Differentiable 𝕜 d) : Differentiable 𝕜 fun y => (c y).comp (d y) := fun x => (hc x).clm_comp (hd x) theorem fderivWithin_clm_comp (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (hd : DifferentiableWithinAt 𝕜 d s x) : fderivWithin 𝕜 (fun y => (c y).comp (d y)) s x = (compL 𝕜 F G H (c x)).comp (fderivWithin 𝕜 d s x) + ((compL 𝕜 F G H).flip (d x)).comp (fderivWithin 𝕜 c s x) := (hc.hasFDerivWithinAt.clm_comp hd.hasFDerivWithinAt).fderivWithin hxs theorem fderiv_clm_comp (hc : DifferentiableAt 𝕜 c x) (hd : DifferentiableAt 𝕜 d x) : fderiv 𝕜 (fun y => (c y).comp (d y)) x = (compL 𝕜 F G H (c x)).comp (fderiv 𝕜 d x) + ((compL 𝕜 F G H).flip (d x)).comp (fderiv 𝕜 c x) := (hc.hasFDerivAt.clm_comp hd.hasFDerivAt).fderiv @[fun_prop] theorem HasStrictFDerivAt.clm_apply (hc : HasStrictFDerivAt c c' x) (hu : HasStrictFDerivAt u u' x) : HasStrictFDerivAt (fun y => (c y) (u y)) ((c x).comp u' + c'.flip (u x)) x := (isBoundedBilinearMap_apply.hasStrictFDerivAt (c x, u x)).comp x (hc.prodMk hu) #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivWithinAt.clm_apply (hc : HasFDerivWithinAt c c' s x) (hu : HasFDerivWithinAt u u' s x) : HasFDerivWithinAt (fun y => (c y) (u y)) ((c x).comp u' + c'.flip (u x)) s x := by exact (isBoundedBilinearMap_apply.hasFDerivAt (c x, u x) :).comp_hasFDerivWithinAt x (hc.prodMk hu) #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivAt.clm_apply (hc : HasFDerivAt c c' x) (hu : HasFDerivAt u u' x) : HasFDerivAt (fun y => (c y) (u y)) ((c x).comp u' + c'.flip (u x)) x := by exact (isBoundedBilinearMap_apply.hasFDerivAt (c x, u x) :).comp x (hc.prodMk hu) @[fun_prop] theorem DifferentiableWithinAt.clm_apply (hc : DifferentiableWithinAt 𝕜 c s x) (hu : DifferentiableWithinAt 𝕜 u s x) : DifferentiableWithinAt 𝕜 (fun y => (c y) (u y)) s x := (hc.hasFDerivWithinAt.clm_apply hu.hasFDerivWithinAt).differentiableWithinAt @[fun_prop] theorem DifferentiableAt.clm_apply (hc : DifferentiableAt 𝕜 c x) (hu : DifferentiableAt 𝕜 u x) : DifferentiableAt 𝕜 (fun y => (c y) (u y)) x := (hc.hasFDerivAt.clm_apply hu.hasFDerivAt).differentiableAt @[fun_prop] theorem DifferentiableOn.clm_apply (hc : DifferentiableOn 𝕜 c s) (hu : DifferentiableOn 𝕜 u s) : DifferentiableOn 𝕜 (fun y => (c y) (u y)) s := fun x hx => (hc x hx).clm_apply (hu x hx) @[fun_prop] theorem Differentiable.clm_apply (hc : Differentiable 𝕜 c) (hu : Differentiable 𝕜 u) : Differentiable 𝕜 fun y => (c y) (u y) := fun x => (hc x).clm_apply (hu x) theorem fderivWithin_clm_apply (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (hu : DifferentiableWithinAt 𝕜 u s x) : fderivWithin 𝕜 (fun y => (c y) (u y)) s x = (c x).comp (fderivWithin 𝕜 u s x) + (fderivWithin 𝕜 c s x).flip (u x) := (hc.hasFDerivWithinAt.clm_apply hu.hasFDerivWithinAt).fderivWithin hxs theorem fderiv_clm_apply (hc : DifferentiableAt 𝕜 c x) (hu : DifferentiableAt 𝕜 u x) : fderiv 𝕜 (fun y => (c y) (u y)) x = (c x).comp (fderiv 𝕜 u x) + (fderiv 𝕜 c x).flip (u x) := (hc.hasFDerivAt.clm_apply hu.hasFDerivAt).fderiv end CLMCompApply section ContinuousMultilinearApplyConst /-! ### Derivative of the application of continuous multilinear maps to a constant -/ variable {ι : Type} [Fintype ι] {M : ι → Type} [∀ i, NormedAddCommGroup (M i)] [∀ i, NormedSpace 𝕜 (M i)] {H : Type} [NormedAddCommGroup H] [NormedSpace 𝕜 H] {c : E → ContinuousMultilinearMap 𝕜 M H} {c' : E →L[𝕜] ContinuousMultilinearMap 𝕜 M H} @[fun_prop] theorem HasStrictFDerivAt.continuousMultilinear_apply_const (hc : HasStrictFDerivAt c c' x) (u : ∀ i, M i) : HasStrictFDerivAt (fun y ↦ (c y) u) (c'.flipMultilinear u) x := (ContinuousMultilinearMap.apply 𝕜 M H u).hasStrictFDerivAt.comp x hc @[fun_prop] theorem HasFDerivWithinAt.continuousMultilinear_apply_const (hc : HasFDerivWithinAt c c' s x) (u : ∀ i, M i) : HasFDerivWithinAt (fun y ↦ (c y) u) (c'.flipMultilinear u) s x := (ContinuousMultilinearMap.apply 𝕜 M H u).hasFDerivAt.comp_hasFDerivWithinAt x hc @[fun_prop] theorem HasFDerivAt.continuousMultilinear_apply_const (hc : HasFDerivAt c c' x) (u : ∀ i, M i) : HasFDerivAt (fun y ↦ (c y) u) (c'.flipMultilinear u) x := (ContinuousMultilinearMap.apply 𝕜 M H u).hasFDerivAt.comp x hc @[fun_prop] theorem DifferentiableWithinAt.continuousMultilinear_apply_const (hc : DifferentiableWithinAt 𝕜 c s x) (u : ∀ i, M i) : DifferentiableWithinAt 𝕜 (fun y ↦ (c y) u) s x := (hc.hasFDerivWithinAt.continuousMultilinear_apply_const u).differentiableWithinAt @[fun_prop] theorem DifferentiableAt.continuousMultilinear_apply_const (hc : DifferentiableAt 𝕜 c x) (u : ∀ i, M i) : DifferentiableAt 𝕜 (fun y ↦ (c y) u) x := (hc.hasFDerivAt.continuousMultilinear_apply_const u).differentiableAt @[fun_prop] theorem DifferentiableOn.continuousMultilinear_apply_const (hc : DifferentiableOn 𝕜 c s) (u : ∀ i, M i) : DifferentiableOn 𝕜 (fun y ↦ (c y) u) s := fun x hx ↦ (hc x hx).continuousMultilinear_apply_const u @[fun_prop] theorem Differentiable.continuousMultilinear_apply_const (hc : Differentiable 𝕜 c) (u : ∀ i, M i) : Differentiable 𝕜 fun y ↦ (c y) u := fun x ↦ (hc x).continuousMultilinear_apply_const u theorem fderivWithin_continuousMultilinear_apply_const (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (u : ∀ i, M i) : fderivWithin 𝕜 (fun y ↦ (c y) u) s x = ((fderivWithin 𝕜 c s x).flipMultilinear u) := (hc.hasFDerivWithinAt.continuousMultilinear_apply_const u).fderivWithin hxs theorem fderiv_continuousMultilinear_apply_const (hc : DifferentiableAt 𝕜 c x) (u : ∀ i, M i) : (fderiv 𝕜 (fun y ↦ (c y) u) x) = (fderiv 𝕜 c x).flipMultilinear u := (hc.hasFDerivAt.continuousMultilinear_apply_const u).fderiv /-- Application of a `ContinuousMultilinearMap` to a constant commutes with `fderivWithin`. -/ theorem fderivWithin_continuousMultilinear_apply_const_apply (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (u : ∀ i, M i) (m : E) : (fderivWithin 𝕜 (fun y ↦ (c y) u) s x) m = (fderivWithin 𝕜 c s x) m u := by simp [fderivWithin_continuousMultilinear_apply_const hxs hc] /-- Application of a `ContinuousMultilinearMap` to a constant commutes with `fderiv`. -/ theorem fderiv_continuousMultilinear_apply_const_apply (hc : DifferentiableAt 𝕜 c x) (u : ∀ i, M i) (m : E) : (fderiv 𝕜 (fun y ↦ (c y) u) x) m = (fderiv 𝕜 c x) m u := by simp [fderiv_continuousMultilinear_apply_const hc] end ContinuousMultilinearApplyConst section SMul /-! ### Derivative of the product of a scalar-valued function and a vector-valued function If `c` is a differentiable scalar-valued function and `f` is a differentiable vector-valued function, then `fun x ↦ c x • f x` is differentiable as well. Lemmas in this section works for function `c` taking values in the base field, as well as in a normed algebra over the base field: e.g., they work for `c : E → ℂ` and `f : E → F` provided that `F` is a complex normed vector space. -/ variable {𝕜' : Type*} [NontriviallyNormedField 𝕜'] [NormedAlgebra 𝕜 𝕜'] [NormedSpace 𝕜' F] [IsScalarTower 𝕜 𝕜' F] variable {c : E → 𝕜'} {c' : E →L[𝕜] 𝕜'} @[fun_prop] theorem HasStrictFDerivAt.smul (hc : HasStrictFDerivAt c c' x) (hf : HasStrictFDerivAt f f' x) : HasStrictFDerivAt (fun y => c y • f y) (c x • f' + c'.smulRight (f x)) x := (isBoundedBilinearMap_smul.hasStrictFDerivAt (c x, f x)).comp x <\| hc.prodMk hf #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivWithinAt.smul (hc : HasFDerivWithinAt c c' s x) (hf : HasFDerivWithinAt f f' s x) : HasFDerivWithinAt (fun y => c y • f y) (c x • f' + c'.smulRight (f x)) s x := by exact (isBoundedBilinearMap_smul.hasFDerivAt (𝕜 := 𝕜) (c x, f x) :).comp_hasFDerivWithinAt x <\| hc.prodMk hf #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 `by exact` to solve unification issues. -/ @[fun_prop] theorem HasFDerivAt.smul (hc : HasFDerivAt c c' x) (hf : HasFDerivAt f f' x) : HasFDerivAt (fun y => c y • f y) (c x • f' + c'.smulRight (f x)) x := by exact (isBoundedBilinearMap_smul.hasFDerivAt (𝕜 := 𝕜) (c x, f x) :).comp x <\| hc.prodMk hf @[fun_prop] theorem DifferentiableWithinAt.smul (hc : DifferentiableWithinAt 𝕜 c s x) (hf : DifferentiableWithinAt 𝕜 f s x) : DifferentiableWithinAt 𝕜 (fun y => c y • f y) s x := (hc.hasFDerivWithinAt.smul hf.hasFDerivWithinAt).differentiableWithinAt @[simp, fun_prop] theorem DifferentiableAt.smul (hc : DifferentiableAt 𝕜 c x) (hf : DifferentiableAt 𝕜 f x) : DifferentiableAt 𝕜 (fun y => c y • f y) x := (hc.hasFDerivAt.smul hf.hasFDerivAt).differentiableAt @[fun_prop] theorem DifferentiableOn.smul (hc : DifferentiableOn 𝕜 c s) (hf : DifferentiableOn 𝕜 f s) : DifferentiableOn 𝕜 (fun y => c y • f y) s := fun x hx => (hc x hx).smul (hf x hx) @[simp, fun_prop] theorem Differentiable.smul (hc : Differentiable 𝕜 c) (hf : Differentiable 𝕜 f) : Differentiable 𝕜 fun y => c y • f y := fun x => (hc x).smul (hf x) theorem fderivWithin_smul (hxs : UniqueDiffWithinAt 𝕜 s x) (hc : DifferentiableWithinAt 𝕜 c s x) (hf : DifferentiableWithinAt 𝕜 f s x) : fderivWithin 𝕜 (fun y => c y • f y) s x = c x • fderivWithin 𝕜 f s x + (fderivWithin 𝕜 c s x).smulRight (f x) := (hc.hasFDerivWithinAt.smul hf.hasFDerivWithinAt).fderivWithin hxs theorem fderiv_smul (hc : DifferentiableAt 𝕜 c x) (hf : DifferentiableAt 𝕜 f x) : fderiv 𝕜 (fun y => c y • f y) x = c x • fderiv 𝕜 f x + (fderiv 𝕜 c x).smulRight (f x) := (hc.hasFDerivAt.smul hf.hasFDerivAt).fderiv @[fun_prop] theorem HasStrictFDerivAt.smul_const (hc : HasStrictFDerivAt c c' x) (f : F) : HasStrictFDerivAt (fun y => c y • f) (c'.smulRight f) x := by simpa only [smul_zero, zero_add] using hc.smul (hasStrictFDerivAt_const f x) @[fun_prop] theorem HasFDerivWithinAt.smul_const (hc : HasFDerivWithinAt c c' s x) (f : F) : HasFDerivWithinAt (fun y => c y • f) (c'.smulRight f) s x := by simpa only [smul_zero, zero_add] using hc.smul (hasFDerivWithinAt_const f x s) @[fun_prop] theorem HasFDerivAt.smul_const (hc : HasFDerivAt c c' x) (f : F) : HasFDerivAt (fun y => c y • f) (c'.smulRight f) x := by simpa only [smul_zero, zero_add] using hc.smul (hasFDerivAt_const f x) @[fun_prop] theorem DifferentiableWithinAt.smul_const (hc : DifferentiableWithinAt 𝕜 c s x) (f : F) : DifferentiableWithinAt 𝕜 (fun y => c y • f) s x := (hc.hasFDerivWithinAt.smul_const f).differentiableWithinAt @[fun_prop] theorem DifferentiableAt.smul_const (hc : DifferentiableAt 𝕜 c x) (f : F) : DifferentiableAt 𝕜 (fun y => c y • f) x := (hc.hasFDerivAt.smul_const f).differentiableAt @[fun_prop] theorem DifferentiableOn.smul_const (hc : DifferentiableOn 𝕜 c s) (f : F) : DifferentiableOn 𝕜 (fun y => c y • f) s := fun x hx => (hc x hx).smul_const f	@[fun_prop] theorem Differentiable.smul_const (hc : Differentiable 𝕜 c) (f : F) :	Mathlib/Analysis/Calculus/FDeriv/Mul.lean	319	321
/- Copyright (c) 2022 Violeta Hernández Palacios. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Violeta Hernández Palacios -/ import Mathlib.SetTheory.Ordinal.FixedPoint /-! # Principal ordinals We define principal or indecomposable ordinals, and we prove the standard properties about them. ## Main definitions and results * `Principal`: A principal or indecomposable ordinal under some binary operation. We include 0 and any other typically excluded edge cases for simplicity. * `not_bddAbove_principal`: Principal ordinals (under any operation) are unbounded. * `principal_add_iff_zero_or_omega0_opow`: The main characterization theorem for additive principal ordinals. * `principal_mul_iff_le_two_or_omega0_opow_opow`: The main characterization theorem for multiplicative principal ordinals. ## TODO * Prove that exponential principal ordinals are 0, 1, 2, ω, or epsilon numbers, i.e. fixed points of `fun x ↦ ω ^ x`. -/ universe u open Order namespace Ordinal variable {a b c o : Ordinal.{u}} section Arbitrary variable {op : Ordinal → Ordinal → Ordinal} /-! ### Principal ordinals -/ /-- An ordinal `o` is said to be principal or indecomposable under an operation when the set of ordinals less than it is closed under that operation. In standard mathematical usage, this term is almost exclusively used for additive and multiplicative principal ordinals. For simplicity, we break usual convention and regard `0` as principal. -/ def Principal (op : Ordinal → Ordinal → Ordinal) (o : Ordinal) : Prop := ∀ ⦃a b⦄, a < o → b < o → op a b < o theorem principal_swap_iff : Principal (Function.swap op) o ↔ Principal op o := by constructor <;> exact fun h a b ha hb => h hb ha theorem not_principal_iff : ¬ Principal op o ↔ ∃ a < o, ∃ b < o, o ≤ op a b := by simp [Principal] theorem principal_iff_of_monotone (h₁ : ∀ a, Monotone (op a)) (h₂ : ∀ a, Monotone (Function.swap op a)) : Principal op o ↔ ∀ a < o, op a a < o := by use fun h a ha => h ha ha intro H a b ha hb obtain hab \| hba := le_or_lt a b · exact (h₂ b hab).trans_lt <\| H b hb · exact (h₁ a hba.le).trans_lt <\| H a ha theorem not_principal_iff_of_monotone (h₁ : ∀ a, Monotone (op a)) (h₂ : ∀ a, Monotone (Function.swap op a)) : ¬ Principal op o ↔ ∃ a < o, o ≤ op a a := by simp [principal_iff_of_monotone h₁ h₂] theorem principal_zero : Principal op 0 := fun a _ h => (Ordinal.not_lt_zero a h).elim @[simp] theorem principal_one_iff : Principal op 1 ↔ op 0 0 = 0 := by refine ⟨fun h => ?_, fun h a b ha hb => ?_⟩ · rw [← lt_one_iff_zero] exact h zero_lt_one zero_lt_one · rwa [lt_one_iff_zero, ha, hb] at * theorem Principal.iterate_lt (hao : a < o) (ho : Principal op o) (n : ℕ) : (op a)^[n] a < o := by induction' n with n hn · rwa [Function.iterate_zero] · rw [Function.iterate_succ'] exact ho hao hn theorem op_eq_self_of_principal (hao : a < o) (H : IsNormal (op a)) (ho : Principal op o) (ho' : IsLimit o) : op a o = o := by apply H.le_apply.antisymm' rw [← IsNormal.bsup_eq.{u, u} H ho', bsup_le_iff] exact fun b hbo => (ho hao hbo).le theorem nfp_le_of_principal (hao : a < o) (ho : Principal op o) : nfp (op a) a ≤ o := nfp_le fun n => (ho.iterate_lt hao n).le end Arbitrary /-! ### Principal ordinals are unbounded -/ /-- We give an explicit construction for a principal ordinal larger or equal than `o`. -/ private theorem principal_nfp_iSup (op : Ordinal → Ordinal → Ordinal) (o : Ordinal) : Principal op (nfp (fun x ↦ ⨆ y : Set.Iio x ×ˢ Set.Iio x, succ (op y.1.1 y.1.2)) o) := by intro a b ha hb rw [lt_nfp_iff] at * obtain ⟨m, ha⟩ := ha obtain ⟨n, hb⟩ := hb obtain h \| h := le_total ((fun x ↦ ⨆ y : Set.Iio x ×ˢ Set.Iio x, succ (op y.1.1 y.1.2))^[m] o) ((fun x ↦ ⨆ y : Set.Iio x ×ˢ Set.Iio x, succ (op y.1.1 y.1.2))^[n] o) · use n + 1 rw [Function.iterate_succ'] apply (lt_succ _).trans_le exact Ordinal.le_iSup (fun y : Set.Iio _ ×ˢ Set.Iio _ ↦ succ (op y.1.1 y.1.2)) ⟨_, Set.mk_mem_prod (ha.trans_le h) hb⟩ · use m + 1 rw [Function.iterate_succ'] apply (lt_succ _).trans_le exact Ordinal.le_iSup (fun y : Set.Iio _ ×ˢ Set.Iio _ ↦ succ (op y.1.1 y.1.2)) ⟨_, Set.mk_mem_prod ha (hb.trans_le h)⟩ /-- Principal ordinals under any operation are unbounded. -/ theorem not_bddAbove_principal (op : Ordinal → Ordinal → Ordinal) : ¬ BddAbove { o \| Principal op o } := by rintro ⟨a, ha⟩ exact ((le_nfp _ _).trans (ha (principal_nfp_iSup op (succ a)))).not_lt (lt_succ a) /-! #### Additive principal ordinals -/ theorem principal_add_one : Principal (· + ·) 1 := principal_one_iff.2 <\| zero_add 0 theorem principal_add_of_le_one (ho : o ≤ 1) : Principal (· + ·) o := by rcases le_one_iff.1 ho with (rfl \| rfl) · exact principal_zero · exact principal_add_one theorem isLimit_of_principal_add (ho₁ : 1 < o) (ho : Principal (· + ·) o) : o.IsLimit := by rw [isLimit_iff, isSuccPrelimit_iff_succ_lt] exact ⟨ho₁.ne_bot, fun _ ha ↦ ho ha ho₁⟩ theorem principal_add_iff_add_left_eq_self : Principal (· + ·) o ↔ ∀ a < o, a + o = o := by refine ⟨fun ho a hao => ?_, fun h a b hao hbo => ?_⟩ · rcases lt_or_le 1 o with ho₁ \| ho₁ · exact op_eq_self_of_principal hao (isNormal_add_right a) ho (isLimit_of_principal_add ho₁ ho) · rcases le_one_iff.1 ho₁ with (rfl \| rfl) · exact (Ordinal.not_lt_zero a hao).elim · rw [lt_one_iff_zero] at hao rw [hao, zero_add] · rw [← h a hao] exact (isNormal_add_right a).strictMono hbo theorem exists_lt_add_of_not_principal_add (ha : ¬ Principal (· + ·) a) : ∃ b < a, ∃ c < a, b + c = a := by rw [not_principal_iff] at ha rcases ha with ⟨b, hb, c, hc, H⟩ refine ⟨b, hb, _, lt_of_le_of_ne (sub_le_self a b) fun hab => ?_, Ordinal.add_sub_cancel_of_le hb.le⟩ rw [← sub_le, hab] at H exact H.not_lt hc theorem principal_add_iff_add_lt_ne_self : Principal (· + ·) a ↔ ∀ b < a, ∀ c < a, b + c ≠ a := ⟨fun ha _ hb _ hc => (ha hb hc).ne, fun H => by by_contra! ha rcases exists_lt_add_of_not_principal_add ha with ⟨b, hb, c, hc, rfl⟩ exact (H b hb c hc).irrefl⟩ theorem principal_add_omega0 : Principal (· + ·) ω := principal_add_iff_add_left_eq_self.2 fun _ => add_omega0 theorem add_omega0_opow (h : a < ω ^ b) : a + ω ^ b = ω ^ b := by refine le_antisymm ?_ (le_add_left _ a) induction' b using limitRecOn with b _ b l IH · rw [opow_zero, ← succ_zero, lt_succ_iff, Ordinal.le_zero] at h rw [h, zero_add] · rw [opow_succ] at h rcases (lt_mul_of_limit isLimit_omega0).1 h with ⟨x, xo, ax⟩ apply (add_le_add_right ax.le _).trans rw [opow_succ, ← mul_add, add_omega0 xo] · rcases (lt_opow_of_limit omega0_ne_zero l).1 h with ⟨x, xb, ax⟩ apply (((isNormal_add_right a).trans <\| isNormal_opow one_lt_omega0).limit_le l).2 intro y yb calc a + ω ^ y ≤ a + ω ^ max x y := add_le_add_left (opow_le_opow_right omega0_pos (le_max_right x y)) _ _ ≤ ω ^ max x y := IH _ (max_lt xb yb) <\| ax.trans_le <\| opow_le_opow_right omega0_pos <\| le_max_left x y _ ≤ ω ^ b := opow_le_opow_right omega0_pos <\| (max_lt xb yb).le theorem principal_add_omega0_opow (o : Ordinal) : Principal (· + ·) (ω ^ o) := principal_add_iff_add_left_eq_self.2 fun _ => add_omega0_opow /-- The main characterization theorem for additive principal ordinals. -/ theorem principal_add_iff_zero_or_omega0_opow : Principal (· + ·) o ↔ o = 0 ∨ o ∈ Set.range (ω ^ · : Ordinal → Ordinal) := by rcases eq_or_ne o 0 with (rfl \| ho) · simp only [principal_zero, Or.inl] · rw [principal_add_iff_add_left_eq_self] simp only [ho, false_or] refine ⟨fun H => ⟨_, ((lt_or_eq_of_le (opow_log_le_self _ ho)).resolve_left fun h => ?_)⟩, fun ⟨b, e⟩ => e.symm ▸ fun a => add_omega0_opow⟩ have := H _ h have := lt_opow_succ_log_self one_lt_omega0 o rw [opow_succ, lt_mul_of_limit isLimit_omega0] at this rcases this with ⟨a, ao, h'⟩ rcases lt_omega0.1 ao with ⟨n, rfl⟩ clear ao revert h' apply not_lt_of_le suffices e : ω ^ log ω o * n + o = o by simpa only [e] using le_add_right (ω ^ log ω o * ↑n) o induction' n with n IH · simp [Nat.cast_zero, mul_zero, zero_add] · simp only [Nat.cast_succ, mul_add_one, add_assoc, this, IH] theorem principal_add_opow_of_principal_add {a} (ha : Principal (· + ·) a) (b : Ordinal) : Principal (· + ·) (a ^ b) := by rcases principal_add_iff_zero_or_omega0_opow.1 ha with (rfl \| ⟨c, rfl⟩) · rcases eq_or_ne b 0 with (rfl \| hb) · rw [opow_zero] exact principal_add_one · rwa [zero_opow hb] · rw [← opow_mul] exact principal_add_omega0_opow _ theorem add_absorp (h₁ : a < ω ^ b) (h₂ : ω ^ b ≤ c) : a + c = c := by rw [← Ordinal.add_sub_cancel_of_le h₂, ← add_assoc, add_omega0_opow h₁] theorem principal_add_mul_of_principal_add (a : Ordinal.{u}) {b : Ordinal.{u}} (hb₁ : b ≠ 1) (hb : Principal (· + ·) b) : Principal (· + ·) (a * b) := by rcases eq_zero_or_pos a with (rfl \| _) · rw [zero_mul] exact principal_zero · rcases eq_zero_or_pos b with (rfl \| hb₁') · rw [mul_zero] exact principal_zero · rw [← succ_le_iff, succ_zero] at hb₁' intro c d hc hd rw [lt_mul_of_limit (isLimit_of_principal_add (lt_of_le_of_ne hb₁' hb₁.symm) hb)] at * rcases hc with ⟨x, hx, hx'⟩ rcases hd with ⟨y, hy, hy'⟩ use x + y, hb hx hy rw [mul_add] exact Left.add_lt_add hx' hy' /-! #### Multiplicative principal ordinals -/ theorem principal_mul_one : Principal (· * ·) 1 := by rw [principal_one_iff] exact zero_mul _ theorem principal_mul_two : Principal (· * ·) 2 := by intro a b ha hb rw [← succ_one, lt_succ_iff] at * convert mul_le_mul' ha hb exact (mul_one 1).symm theorem principal_mul_of_le_two (ho : o ≤ 2) : Principal (· * ·) o := by rcases lt_or_eq_of_le ho with (ho \| rfl) · rw [← succ_one, lt_succ_iff] at ho rcases lt_or_eq_of_le ho with (ho \| rfl) · rw [lt_one_iff_zero.1 ho] exact principal_zero · exact principal_mul_one · exact principal_mul_two theorem principal_add_of_principal_mul (ho : Principal (· * ·) o) (ho₂ : o ≠ 2) : Principal (· + ·) o := by rcases lt_or_gt_of_ne ho₂ with ho₁ \| ho₂ · replace ho₁ : o < succ 1 := by rwa [succ_one] rw [lt_succ_iff] at ho₁ exact principal_add_of_le_one ho₁ · refine fun a b hao hbo => lt_of_le_of_lt ?_ (ho (max_lt hao hbo) ho₂) dsimp only rw [← one_add_one_eq_two, mul_add, mul_one] exact add_le_add (le_max_left a b) (le_max_right a b) theorem isLimit_of_principal_mul (ho₂ : 2 < o) (ho : Principal (· * ·) o) : o.IsLimit := isLimit_of_principal_add ((lt_succ 1).trans (succ_one ▸ ho₂)) (principal_add_of_principal_mul ho (ne_of_gt ho₂)) theorem principal_mul_iff_mul_left_eq : Principal (· * ·) o ↔ ∀ a, 0 < a → a < o → a * o = o := by refine ⟨fun h a ha₀ hao => ?_, fun h a b hao hbo => ?_⟩ · rcases le_or_gt o 2 with ho \| ho · convert one_mul o apply le_antisymm · rw [← lt_succ_iff, succ_one] exact hao.trans_le ho · rwa [← succ_le_iff, succ_zero] at ha₀ · exact op_eq_self_of_principal hao (isNormal_mul_right ha₀) h (isLimit_of_principal_mul ho h) · rcases eq_or_ne a 0 with (rfl \| ha) · dsimp only; rwa [zero_mul] rw [← Ordinal.pos_iff_ne_zero] at ha rw [← h a ha hao] exact (isNormal_mul_right ha).strictMono hbo theorem principal_mul_omega0 : Principal (· * ·) ω := fun a b ha hb => match a, b, lt_omega0.1 ha, lt_omega0.1 hb with \| _, _, ⟨m, rfl⟩, ⟨n, rfl⟩ => by dsimp only; rw [← natCast_mul] apply nat_lt_omega0 theorem mul_omega0 (a0 : 0 < a) (ha : a < ω) : a * ω = ω := principal_mul_iff_mul_left_eq.1 principal_mul_omega0 a a0 ha	theorem natCast_mul_omega0 {n : ℕ} (hn : 0 < n) : n * ω = ω := mul_omega0 (mod_cast hn) (nat_lt_omega0 n)	Mathlib/SetTheory/Ordinal/Principal.lean	305	308
/- Copyright (c) 2020 Aaron Anderson. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Aaron Anderson -/ import Mathlib.Data.Finset.Fold import Mathlib.Algebra.GCDMonoid.Multiset /-! # GCD and LCM operations on finsets ## Main definitions - `Finset.gcd` - the greatest common denominator of a `Finset` of elements of a `GCDMonoid` - `Finset.lcm` - the least common multiple of a `Finset` of elements of a `GCDMonoid` ## Implementation notes Many of the proofs use the lemmas `gcd_def` and `lcm_def`, which relate `Finset.gcd` and `Finset.lcm` to `Multiset.gcd` and `Multiset.lcm`. TODO: simplify with a tactic and `Data.Finset.Lattice` ## Tags finset, gcd -/ variable {ι α β γ : Type} namespace Finset open Multiset variable [CancelCommMonoidWithZero α] [NormalizedGCDMonoid α] /-! ### lcm -/ section lcm /-- Least common multiple of a finite set -/ def lcm (s : Finset β) (f : β → α) : α := s.fold GCDMonoid.lcm 1 f variable {s s₁ s₂ : Finset β} {f : β → α} theorem lcm_def : s.lcm f = (s.1.map f).lcm := rfl @[simp] theorem lcm_empty : (∅ : Finset β).lcm f = 1 := fold_empty @[simp] theorem lcm_dvd_iff {a : α} : s.lcm f ∣ a ↔ ∀ b ∈ s, f b ∣ a := by apply Iff.trans Multiset.lcm_dvd simp only [Multiset.mem_map, and_imp, exists_imp] exact ⟨fun k b hb ↦ k _ _ hb rfl, fun k a' b hb h ↦ h ▸ k _ hb⟩ theorem lcm_dvd {a : α} : (∀ b ∈ s, f b ∣ a) → s.lcm f ∣ a := lcm_dvd_iff.2 theorem dvd_lcm {b : β} (hb : b ∈ s) : f b ∣ s.lcm f := lcm_dvd_iff.1 dvd_rfl _ hb @[simp] theorem lcm_insert [DecidableEq β] {b : β} : (insert b s : Finset β).lcm f = GCDMonoid.lcm (f b) (s.lcm f) := by by_cases h : b ∈ s · rw [insert_eq_of_mem h, (lcm_eq_right_iff (f b) (s.lcm f) (Multiset.normalize_lcm (s.1.map f))).2 (dvd_lcm h)] apply fold_insert h @[simp] theorem lcm_singleton {b : β} : ({b} : Finset β).lcm f = normalize (f b) := Multiset.lcm_singleton @[local simp] -- This will later be provable by other `simp` lemmas. theorem normalize_lcm : normalize (s.lcm f) = s.lcm f := by simp [lcm_def] theorem lcm_union [DecidableEq β] : (s₁ ∪ s₂).lcm f = GCDMonoid.lcm (s₁.lcm f) (s₂.lcm f) := Finset.induction_on s₁ (by rw [empty_union, lcm_empty, lcm_one_left, normalize_lcm]) fun a s _ ih ↦ by rw [insert_union, lcm_insert, lcm_insert, ih, lcm_assoc] theorem lcm_congr {f g : β → α} (hs : s₁ = s₂) (hfg : ∀ a ∈ s₂, f a = g a) : s₁.lcm f = s₂.lcm g := by subst hs exact Finset.fold_congr hfg theorem lcm_mono_fun {g : β → α} (h : ∀ b ∈ s, f b ∣ g b) : s.lcm f ∣ s.lcm g := lcm_dvd fun b hb ↦ (h b hb).trans (dvd_lcm hb) theorem lcm_mono (h : s₁ ⊆ s₂) : s₁.lcm f ∣ s₂.lcm f := lcm_dvd fun _ hb ↦ dvd_lcm (h hb) theorem lcm_image [DecidableEq β] {g : γ → β} (s : Finset γ) : (s.image g).lcm f = s.lcm (f ∘ g) := by classical induction s using Finset.induction <;> simp [] theorem lcm_eq_lcm_image [DecidableEq α] : s.lcm f = (s.image f).lcm id := Eq.symm <\| lcm_image _ theorem lcm_eq_zero_iff [Nontrivial α] : s.lcm f = 0 ↔ 0 ∈ f '' s := by simp only [Multiset.mem_map, lcm_def, Multiset.lcm_eq_zero_iff, Set.mem_image, mem_coe, ← Finset.mem_def] end lcm /-! ### gcd -/ section gcd /-- Greatest common divisor of a finite set -/ def gcd (s : Finset β) (f : β → α) : α := s.fold GCDMonoid.gcd 0 f variable {s s₁ s₂ : Finset β} {f : β → α} theorem gcd_def : s.gcd f = (s.1.map f).gcd := rfl @[simp] theorem gcd_empty : (∅ : Finset β).gcd f = 0 := fold_empty theorem dvd_gcd_iff {a : α} : a ∣ s.gcd f ↔ ∀ b ∈ s, a ∣ f b := by apply Iff.trans Multiset.dvd_gcd simp only [Multiset.mem_map, and_imp, exists_imp] exact ⟨fun k b hb ↦ k _ _ hb rfl, fun k a' b hb h ↦ h ▸ k _ hb⟩ theorem gcd_dvd {b : β} (hb : b ∈ s) : s.gcd f ∣ f b := dvd_gcd_iff.1 dvd_rfl _ hb theorem dvd_gcd {a : α} : (∀ b ∈ s, a ∣ f b) → a ∣ s.gcd f := dvd_gcd_iff.2 @[simp] theorem gcd_insert [DecidableEq β] {b : β} : (insert b s : Finset β).gcd f = GCDMonoid.gcd (f b) (s.gcd f) := by by_cases h : b ∈ s · rw [insert_eq_of_mem h, (gcd_eq_right_iff (f b) (s.gcd f) (Multiset.normalize_gcd (s.1.map f))).2 (gcd_dvd h)] apply fold_insert h @[simp] theorem gcd_singleton {b : β} : ({b} : Finset β).gcd f = normalize (f b) := Multiset.gcd_singleton @[local simp] -- This will later be provable by other `simp` lemmas. theorem normalize_gcd : normalize (s.gcd f) = s.gcd f := by simp [gcd_def] theorem gcd_union [DecidableEq β] : (s₁ ∪ s₂).gcd f = GCDMonoid.gcd (s₁.gcd f) (s₂.gcd f) := Finset.induction_on s₁ (by rw [empty_union, gcd_empty, gcd_zero_left, normalize_gcd]) fun a s _ ih ↦ by rw [insert_union, gcd_insert, gcd_insert, ih, gcd_assoc] theorem gcd_congr {f g : β → α} (hs : s₁ = s₂) (hfg : ∀ a ∈ s₂, f a = g a) : s₁.gcd f = s₂.gcd g := by subst hs exact Finset.fold_congr hfg theorem gcd_mono_fun {g : β → α} (h : ∀ b ∈ s, f b ∣ g b) : s.gcd f ∣ s.gcd g := dvd_gcd fun b hb ↦ (gcd_dvd hb).trans (h b hb) theorem gcd_mono (h : s₁ ⊆ s₂) : s₂.gcd f ∣ s₁.gcd f := dvd_gcd fun _ hb ↦ gcd_dvd (h hb) theorem gcd_image [DecidableEq β] {g : γ → β} (s : Finset γ) : (s.image g).gcd f = s.gcd (f ∘ g) := by classical induction s using Finset.induction <;> simp [] theorem gcd_eq_gcd_image [DecidableEq α] : s.gcd f = (s.image f).gcd id := Eq.symm <\| gcd_image _ theorem gcd_eq_zero_iff : s.gcd f = 0 ↔ ∀ x : β, x ∈ s → f x = 0 := by rw [gcd_def, Multiset.gcd_eq_zero_iff] constructor <;> intro h · intro b bs apply h (f b) simp only [Multiset.mem_map, mem_def.1 bs] use b simp only [mem_def.1 bs, eq_self_iff_true, and_self] · intro a as rw [Multiset.mem_map] at as rcases as with ⟨b, ⟨bs, rfl⟩⟩ apply h b (mem_def.1 bs) theorem gcd_eq_gcd_filter_ne_zero [DecidablePred fun x : β ↦ f x = 0] : s.gcd f = {x ∈ s \| f x ≠ 0}.gcd f := by classical trans ({x ∈ s \| f x = 0} ∪ {x ∈ s \| f x ≠ 0}).gcd f · rw [filter_union_filter_neg_eq] rw [gcd_union] refine Eq.trans (?_ : _ = GCDMonoid.gcd (0 : α) ?_) (?_ : GCDMonoid.gcd (0 : α) _ = _) · exact gcd {x ∈ s \| f x ≠ 0} f · refine congr (congr rfl <\| s.induction_on ?_ ?_) (by simp) · simp · intro a s _ h rw [filter_insert] split_ifs with h1 <;> simp [h, h1] simp only [gcd_zero_left, normalize_gcd] nonrec theorem gcd_mul_left {a : α} : (s.gcd fun x ↦ a f x) = normalize a * s.gcd f := by classical refine s.induction_on ?_ ?_ · simp · intro b t _ h rw [gcd_insert, gcd_insert, h, ← gcd_mul_left] apply ((normalize_associated a).mul_right _).gcd_eq_right nonrec theorem gcd_mul_right {a : α} : (s.gcd fun x ↦ f x * a) = s.gcd f * normalize a := by classical refine s.induction_on ?_ ?_ · simp · intro b t _ h rw [gcd_insert, gcd_insert, h, ← gcd_mul_right] apply ((normalize_associated a).mul_left _).gcd_eq_right theorem extract_gcd' (f g : β → α) (hs : ∃ x, x ∈ s ∧ f x ≠ 0) (hg : ∀ b ∈ s, f b = s.gcd f * g b) : s.gcd g = 1 := ((@mul_right_eq_self₀ _ _ (s.gcd f) _).1 <\| by conv_lhs => rw [← normalize_gcd, ← gcd_mul_left, ← gcd_congr rfl hg]).resolve_right <\| by contrapose! hs exact gcd_eq_zero_iff.1 hs theorem extract_gcd (f : β → α) (hs : s.Nonempty) : ∃ g : β → α, (∀ b ∈ s, f b = s.gcd f * g b) ∧ s.gcd g = 1 := by classical by_cases h : ∀ x ∈ s, f x = (0 : α) · refine ⟨fun _ ↦ 1, fun b hb ↦ by rw [h b hb, gcd_eq_zero_iff.2 h, mul_one], ?_⟩ rw [gcd_eq_gcd_image, image_const hs, gcd_singleton, id, normalize_one] · choose g' hg using @gcd_dvd _ _ _ _ s f push_neg at h refine ⟨fun b ↦ if hb : b ∈ s then g' hb else 0, fun b hb ↦ ?_, extract_gcd' f _ h fun b hb ↦ ?_⟩ · simp only [hb, hg, dite_true] rw [dif_pos hb, hg hb] variable [Div α] [MulDivCancelClass α] {f : ι → α} {s : Finset ι} {i : ι} /-- Given a nonempty Finset `s` and a function `f` from `s` to `ℕ`, if `d = s.gcd`, then the `gcd` of `(f i) / d` is equal to `1`. -/ lemma gcd_div_eq_one (his : i ∈ s) (hfi : f i ≠ 0) : s.gcd (fun j ↦ f j / s.gcd f) = 1 := by obtain ⟨g, he, hg⟩ := Finset.extract_gcd f ⟨i, his⟩ refine (Finset.gcd_congr rfl fun a ha ↦ ?_).trans hg rw [he a ha, mul_div_cancel_left₀] exact mt Finset.gcd_eq_zero_iff.1 fun h ↦ hfi <\| h i his lemma gcd_div_id_eq_one {s : Finset α} {a : α} (has : a ∈ s) (ha : a ≠ 0) : s.gcd (fun b ↦ b / s.gcd id) = 1 := gcd_div_eq_one has ha end gcd end Finset namespace Finset section IsDomain variable [CommRing α] [IsDomain α] [NormalizedGCDMonoid α] theorem gcd_eq_of_dvd_sub {s : Finset β} {f g : β → α} {a : α} (h : ∀ x : β, x ∈ s → a ∣ f x - g x) : GCDMonoid.gcd a (s.gcd f) = GCDMonoid.gcd a (s.gcd g) := by classical revert h refine s.induction_on ?_ ?_ · simp intro b s _ hi h rw [gcd_insert, gcd_insert, gcd_comm (f b), ← gcd_assoc, hi fun x hx ↦ h _ (mem_insert_of_mem hx), gcd_comm a, gcd_assoc, gcd_comm a (GCDMonoid.gcd _ _), gcd_comm (g b), gcd_assoc _ _ a, gcd_comm _ a] exact congr_arg _ (gcd_eq_of_dvd_sub_right (h _ (mem_insert_self _ _))) end IsDomain end Finset		Mathlib/Algebra/GCDMonoid/Finset.lean	313	324
/- Copyright (c) 2024 Antoine Chambert-Loir. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Antoine Chambert-Loir -/ import Mathlib.Algebra.Pointwise.Stabilizer import Mathlib.Data.Setoid.Partition import Mathlib.GroupTheory.GroupAction.Pointwise import Mathlib.GroupTheory.GroupAction.SubMulAction import Mathlib.GroupTheory.Index import Mathlib.Tactic.IntervalCases /-! # Blocks Given `SMul G X`, an action of a type `G` on a type `X`, we define - the predicate `MulAction.IsBlock G B` states that `B : Set X` is a block, which means that the sets `g • B`, for `g ∈ G`, are equal or disjoint. Under `Group G` and `MulAction G X`, this is equivalent to the classical definition `MulAction.IsBlock.def_one` - a bunch of lemmas that give examples of “trivial” blocks : ⊥, ⊤, singletons, and non trivial blocks: orbit of the group, orbit of a normal subgroup… The non-existence of nontrivial blocks is the definition of primitive actions. ## Results for actions on finite sets - `MulAction.IsBlock.ncard_block_mul_ncard_orbit_eq` : The cardinality of a block multiplied by the number of its translates is the cardinal of the ambient type - `MulAction.IsBlock.eq_univ_of_card_lt` : a too large block is equal to `Set.univ` - `MulAction.IsBlock.subsingleton_of_card_lt` : a too small block is a subsingleton - `MulAction.IsBlock.of_subset` : the intersections of the translates of a finite subset that contain a given point is a block - `MulAction.BlockMem` : the type of blocks containing a given element - `MulAction.BlockMem.instBoundedOrder` : the type of blocks containing a given element is a bounded order. ## References We follow [Wielandt-1964]. -/ open Set	open scoped Pointwise namespace MulAction section orbits variable {G : Type} [Group G] {X : Type} [MulAction G X]	Mathlib/GroupTheory/GroupAction/Blocks.lean	51	57
/- Copyright (c) 2019 Jeremy Avigad. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jeremy Avigad, Sébastien Gouëzel, Yury Kudryashov -/ import Mathlib.Analysis.Asymptotics.AsymptoticEquivalent import Mathlib.Analysis.Calculus.FDeriv.Linear import Mathlib.Analysis.Calculus.FDeriv.Comp /-! # The derivative of a linear equivalence For detailed documentation of the Fréchet derivative, see the module docstring of `Analysis/Calculus/FDeriv/Basic.lean`. This file contains the usual formulas (and existence assertions) for the derivative of continuous linear equivalences. We also prove the usual formula for the derivative of the inverse function, assuming it exists. The inverse function theorem is in `Mathlib/Analysis/Calculus/InverseFunctionTheorem/FDeriv.lean`. -/ open Filter Asymptotics ContinuousLinearMap Set Metric Topology NNReal ENNReal noncomputable section section variable {𝕜 : Type} [NontriviallyNormedField 𝕜] variable {E : Type} [NormedAddCommGroup E] [NormedSpace 𝕜 E] variable {F : Type} [NormedAddCommGroup F] [NormedSpace 𝕜 F] variable {G : Type} [NormedAddCommGroup G] [NormedSpace 𝕜 G] variable {G' : Type*} [NormedAddCommGroup G'] [NormedSpace 𝕜 G'] variable {f : E → F} {f' : E →L[𝕜] F} {x : E} {s : Set E} {c : F} namespace ContinuousLinearEquiv /-! ### Differentiability of linear equivs, and invariance of differentiability -/ variable (iso : E ≃L[𝕜] F) @[fun_prop] protected theorem hasStrictFDerivAt : HasStrictFDerivAt iso (iso : E →L[𝕜] F) x := iso.toContinuousLinearMap.hasStrictFDerivAt @[fun_prop] protected theorem hasFDerivWithinAt : HasFDerivWithinAt iso (iso : E →L[𝕜] F) s x := iso.toContinuousLinearMap.hasFDerivWithinAt @[fun_prop] protected theorem hasFDerivAt : HasFDerivAt iso (iso : E →L[𝕜] F) x := iso.toContinuousLinearMap.hasFDerivAtFilter @[fun_prop] protected theorem differentiableAt : DifferentiableAt 𝕜 iso x := iso.hasFDerivAt.differentiableAt @[fun_prop] protected theorem differentiableWithinAt : DifferentiableWithinAt 𝕜 iso s x := iso.differentiableAt.differentiableWithinAt protected theorem fderiv : fderiv 𝕜 iso x = iso := iso.hasFDerivAt.fderiv protected theorem fderivWithin (hxs : UniqueDiffWithinAt 𝕜 s x) : fderivWithin 𝕜 iso s x = iso := iso.toContinuousLinearMap.fderivWithin hxs @[fun_prop] protected theorem differentiable : Differentiable 𝕜 iso := fun _ => iso.differentiableAt @[fun_prop] protected theorem differentiableOn : DifferentiableOn 𝕜 iso s := iso.differentiable.differentiableOn theorem comp_differentiableWithinAt_iff {f : G → E} {s : Set G} {x : G} : DifferentiableWithinAt 𝕜 (iso ∘ f) s x ↔ DifferentiableWithinAt 𝕜 f s x := by refine ⟨fun H => ?_, fun H => iso.differentiable.differentiableAt.comp_differentiableWithinAt x H⟩ have : DifferentiableWithinAt 𝕜 (iso.symm ∘ iso ∘ f) s x := iso.symm.differentiable.differentiableAt.comp_differentiableWithinAt x H rwa [← Function.comp_assoc iso.symm iso f, iso.symm_comp_self] at this theorem comp_differentiableAt_iff {f : G → E} {x : G} : DifferentiableAt 𝕜 (iso ∘ f) x ↔ DifferentiableAt 𝕜 f x := by rw [← differentiableWithinAt_univ, ← differentiableWithinAt_univ, iso.comp_differentiableWithinAt_iff] theorem comp_differentiableOn_iff {f : G → E} {s : Set G} : DifferentiableOn 𝕜 (iso ∘ f) s ↔ DifferentiableOn 𝕜 f s := by rw [DifferentiableOn, DifferentiableOn] simp only [iso.comp_differentiableWithinAt_iff] theorem comp_differentiable_iff {f : G → E} : Differentiable 𝕜 (iso ∘ f) ↔ Differentiable 𝕜 f := by rw [← differentiableOn_univ, ← differentiableOn_univ] exact iso.comp_differentiableOn_iff theorem comp_hasFDerivWithinAt_iff {f : G → E} {s : Set G} {x : G} {f' : G →L[𝕜] E} : HasFDerivWithinAt (iso ∘ f) ((iso : E →L[𝕜] F).comp f') s x ↔ HasFDerivWithinAt f f' s x := by refine ⟨fun H => ?_, fun H => iso.hasFDerivAt.comp_hasFDerivWithinAt x H⟩ have A : f = iso.symm ∘ iso ∘ f := by rw [← Function.comp_assoc, iso.symm_comp_self] rfl have B : f' = (iso.symm : F →L[𝕜] E).comp ((iso : E →L[𝕜] F).comp f') := by rw [← ContinuousLinearMap.comp_assoc, iso.coe_symm_comp_coe, ContinuousLinearMap.id_comp] rw [A, B] exact iso.symm.hasFDerivAt.comp_hasFDerivWithinAt x H theorem comp_hasStrictFDerivAt_iff {f : G → E} {x : G} {f' : G →L[𝕜] E} : HasStrictFDerivAt (iso ∘ f) ((iso : E →L[𝕜] F).comp f') x ↔ HasStrictFDerivAt f f' x := by refine ⟨fun H => ?_, fun H => iso.hasStrictFDerivAt.comp x H⟩ convert iso.symm.hasStrictFDerivAt.comp x H using 1 <;> ext z <;> apply (iso.symm_apply_apply _).symm theorem comp_hasFDerivAt_iff {f : G → E} {x : G} {f' : G →L[𝕜] E} : HasFDerivAt (iso ∘ f) ((iso : E →L[𝕜] F).comp f') x ↔ HasFDerivAt f f' x := by simp_rw [← hasFDerivWithinAt_univ, iso.comp_hasFDerivWithinAt_iff] theorem comp_hasFDerivWithinAt_iff' {f : G → E} {s : Set G} {x : G} {f' : G →L[𝕜] F} : HasFDerivWithinAt (iso ∘ f) f' s x ↔ HasFDerivWithinAt f ((iso.symm : F →L[𝕜] E).comp f') s x := by rw [← iso.comp_hasFDerivWithinAt_iff, ← ContinuousLinearMap.comp_assoc, iso.coe_comp_coe_symm, ContinuousLinearMap.id_comp] theorem comp_hasFDerivAt_iff' {f : G → E} {x : G} {f' : G →L[𝕜] F} : HasFDerivAt (iso ∘ f) f' x ↔ HasFDerivAt f ((iso.symm : F →L[𝕜] E).comp f') x := by simp_rw [← hasFDerivWithinAt_univ, iso.comp_hasFDerivWithinAt_iff'] theorem comp_fderivWithin {f : G → E} {s : Set G} {x : G} (hxs : UniqueDiffWithinAt 𝕜 s x) : fderivWithin 𝕜 (iso ∘ f) s x = (iso : E →L[𝕜] F).comp (fderivWithin 𝕜 f s x) := by by_cases h : DifferentiableWithinAt 𝕜 f s x · rw [fderiv_comp_fderivWithin x iso.differentiableAt h hxs, iso.fderiv] · have : ¬DifferentiableWithinAt 𝕜 (iso ∘ f) s x := mt iso.comp_differentiableWithinAt_iff.1 h rw [fderivWithin_zero_of_not_differentiableWithinAt h, fderivWithin_zero_of_not_differentiableWithinAt this, ContinuousLinearMap.comp_zero] theorem comp_fderiv {f : G → E} {x : G} : fderiv 𝕜 (iso ∘ f) x = (iso : E →L[𝕜] F).comp (fderiv 𝕜 f x) := by rw [← fderivWithin_univ, ← fderivWithin_univ] exact iso.comp_fderivWithin uniqueDiffWithinAt_univ lemma _root_.fderivWithin_continuousLinearEquiv_comp (L : G ≃L[𝕜] G') (f : E → (F →L[𝕜] G)) (hs : UniqueDiffWithinAt 𝕜 s x) : fderivWithin 𝕜 (fun x ↦ (L : G →L[𝕜] G').comp (f x)) s x = (((ContinuousLinearEquiv.refl 𝕜 F).arrowCongr L)) ∘L (fderivWithin 𝕜 f s x) := by change fderivWithin 𝕜 (((ContinuousLinearEquiv.refl 𝕜 F).arrowCongr L) ∘ f) s x = _ rw [ContinuousLinearEquiv.comp_fderivWithin _ hs] lemma _root_.fderiv_continuousLinearEquiv_comp (L : G ≃L[𝕜] G') (f : E → (F →L[𝕜] G)) (x : E) : fderiv 𝕜 (fun x ↦ (L : G →L[𝕜] G').comp (f x)) x = (((ContinuousLinearEquiv.refl 𝕜 F).arrowCongr L)) ∘L (fderiv 𝕜 f x) := by change fderiv 𝕜 (((ContinuousLinearEquiv.refl 𝕜 F).arrowCongr L) ∘ f) x = _ rw [ContinuousLinearEquiv.comp_fderiv] lemma _root_.fderiv_continuousLinearEquiv_comp' (L : G ≃L[𝕜] G') (f : E → (F →L[𝕜] G)) : fderiv 𝕜 (fun x ↦ (L : G →L[𝕜] G').comp (f x)) = fun x ↦ (((ContinuousLinearEquiv.refl 𝕜 F).arrowCongr L)) ∘L (fderiv 𝕜 f x) := by ext x : 1 exact fderiv_continuousLinearEquiv_comp L f x theorem comp_right_differentiableWithinAt_iff {f : F → G} {s : Set F} {x : E} : DifferentiableWithinAt 𝕜 (f ∘ iso) (iso ⁻¹' s) x ↔ DifferentiableWithinAt 𝕜 f s (iso x) := by refine ⟨fun H => ?_, fun H => H.comp x iso.differentiableWithinAt (mapsTo_preimage _ s)⟩ have : DifferentiableWithinAt 𝕜 ((f ∘ iso) ∘ iso.symm) s (iso x) := by rw [← iso.symm_apply_apply x] at H apply H.comp (iso x) iso.symm.differentiableWithinAt intro y hy simpa only [mem_preimage, apply_symm_apply] using hy rwa [Function.comp_assoc, iso.self_comp_symm] at this theorem comp_right_differentiableAt_iff {f : F → G} {x : E} : DifferentiableAt 𝕜 (f ∘ iso) x ↔ DifferentiableAt 𝕜 f (iso x) := by simp only [← differentiableWithinAt_univ, ← iso.comp_right_differentiableWithinAt_iff, preimage_univ] theorem comp_right_differentiableOn_iff {f : F → G} {s : Set F} : DifferentiableOn 𝕜 (f ∘ iso) (iso ⁻¹' s) ↔ DifferentiableOn 𝕜 f s := by refine ⟨fun H y hy => ?_, fun H y hy => iso.comp_right_differentiableWithinAt_iff.2 (H _ hy)⟩ rw [← iso.apply_symm_apply y, ← comp_right_differentiableWithinAt_iff] apply H simpa only [mem_preimage, apply_symm_apply] using hy theorem comp_right_differentiable_iff {f : F → G} : Differentiable 𝕜 (f ∘ iso) ↔ Differentiable 𝕜 f := by simp only [← differentiableOn_univ, ← iso.comp_right_differentiableOn_iff, preimage_univ] theorem comp_right_hasFDerivWithinAt_iff {f : F → G} {s : Set F} {x : E} {f' : F →L[𝕜] G} : HasFDerivWithinAt (f ∘ iso) (f'.comp (iso : E →L[𝕜] F)) (iso ⁻¹' s) x ↔ HasFDerivWithinAt f f' s (iso x) := by refine ⟨fun H => ?_, fun H => H.comp x iso.hasFDerivWithinAt (mapsTo_preimage _ s)⟩ rw [← iso.symm_apply_apply x] at H have A : f = (f ∘ iso) ∘ iso.symm := by rw [Function.comp_assoc, iso.self_comp_symm] rfl have B : f' = (f'.comp (iso : E →L[𝕜] F)).comp (iso.symm : F →L[𝕜] E) := by rw [ContinuousLinearMap.comp_assoc, iso.coe_comp_coe_symm, ContinuousLinearMap.comp_id] rw [A, B] apply H.comp (iso x) iso.symm.hasFDerivWithinAt intro y hy simpa only [mem_preimage, apply_symm_apply] using hy theorem comp_right_hasFDerivAt_iff {f : F → G} {x : E} {f' : F →L[𝕜] G} : HasFDerivAt (f ∘ iso) (f'.comp (iso : E →L[𝕜] F)) x ↔ HasFDerivAt f f' (iso x) := by simp only [← hasFDerivWithinAt_univ, ← comp_right_hasFDerivWithinAt_iff, preimage_univ] theorem comp_right_hasFDerivWithinAt_iff' {f : F → G} {s : Set F} {x : E} {f' : E →L[𝕜] G} : HasFDerivWithinAt (f ∘ iso) f' (iso ⁻¹' s) x ↔ HasFDerivWithinAt f (f'.comp (iso.symm : F →L[𝕜] E)) s (iso x) := by rw [← iso.comp_right_hasFDerivWithinAt_iff, ContinuousLinearMap.comp_assoc, iso.coe_symm_comp_coe, ContinuousLinearMap.comp_id] theorem comp_right_hasFDerivAt_iff' {f : F → G} {x : E} {f' : E →L[𝕜] G} : HasFDerivAt (f ∘ iso) f' x ↔ HasFDerivAt f (f'.comp (iso.symm : F →L[𝕜] E)) (iso x) := by simp only [← hasFDerivWithinAt_univ, ← iso.comp_right_hasFDerivWithinAt_iff', preimage_univ] theorem comp_right_fderivWithin {f : F → G} {s : Set F} {x : E} (hxs : UniqueDiffWithinAt 𝕜 (iso ⁻¹' s) x) : fderivWithin 𝕜 (f ∘ iso) (iso ⁻¹' s) x = (fderivWithin 𝕜 f s (iso x)).comp (iso : E →L[𝕜] F) := by by_cases h : DifferentiableWithinAt 𝕜 f s (iso x) · exact (iso.comp_right_hasFDerivWithinAt_iff.2 h.hasFDerivWithinAt).fderivWithin hxs · have : ¬DifferentiableWithinAt 𝕜 (f ∘ iso) (iso ⁻¹' s) x := by intro h' exact h (iso.comp_right_differentiableWithinAt_iff.1 h') rw [fderivWithin_zero_of_not_differentiableWithinAt h, fderivWithin_zero_of_not_differentiableWithinAt this, ContinuousLinearMap.zero_comp] theorem comp_right_fderiv {f : F → G} {x : E} : fderiv 𝕜 (f ∘ iso) x = (fderiv 𝕜 f (iso x)).comp (iso : E →L[𝕜] F) := by rw [← fderivWithin_univ, ← fderivWithin_univ, ← iso.comp_right_fderivWithin, preimage_univ] exact uniqueDiffWithinAt_univ end ContinuousLinearEquiv namespace LinearIsometryEquiv /-! ### Differentiability of linear isometry equivs, and invariance of differentiability -/ variable (iso : E ≃ₗᵢ[𝕜] F) @[fun_prop] protected theorem hasStrictFDerivAt : HasStrictFDerivAt iso (iso : E →L[𝕜] F) x := (iso : E ≃L[𝕜] F).hasStrictFDerivAt @[fun_prop] protected theorem hasFDerivWithinAt : HasFDerivWithinAt iso (iso : E →L[𝕜] F) s x := (iso : E ≃L[𝕜] F).hasFDerivWithinAt @[fun_prop] protected theorem hasFDerivAt : HasFDerivAt iso (iso : E →L[𝕜] F) x := (iso : E ≃L[𝕜] F).hasFDerivAt @[fun_prop] protected theorem differentiableAt : DifferentiableAt 𝕜 iso x := iso.hasFDerivAt.differentiableAt @[fun_prop] protected theorem differentiableWithinAt : DifferentiableWithinAt 𝕜 iso s x := iso.differentiableAt.differentiableWithinAt protected theorem fderiv : fderiv 𝕜 iso x = iso := iso.hasFDerivAt.fderiv protected theorem fderivWithin (hxs : UniqueDiffWithinAt 𝕜 s x) : fderivWithin 𝕜 iso s x = iso := (iso : E ≃L[𝕜] F).fderivWithin hxs	@[fun_prop] protected theorem differentiable : Differentiable 𝕜 iso := fun _ => iso.differentiableAt	Mathlib/Analysis/Calculus/FDeriv/Equiv.lean	267	270
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Mario Carneiro, Floris van Doorn -/ import Mathlib.Order.Hom.CompleteLattice import Mathlib.Topology.Compactness.Bases import Mathlib.Topology.ContinuousMap.Basic import Mathlib.Order.CompactlyGenerated.Basic import Mathlib.Order.Copy /-! # Open sets ## Summary We define the subtype of open sets in a topological space. ## Main Definitions ### Bundled open sets - `TopologicalSpace.Opens α` is the type of open subsets of a topological space `α`. - `TopologicalSpace.Opens.IsBasis` is a predicate saying that a set of `Opens`s form a topological basis. - `TopologicalSpace.Opens.comap`: preimage of an open set under a continuous map as a `FrameHom`. - `Homeomorph.opensCongr`: order-preserving equivalence between open sets in the domain and the codomain of a homeomorphism. ### Bundled open neighborhoods - `TopologicalSpace.OpenNhdsOf x` is the type of open subsets of a topological space `α` containing `x : α`. - `TopologicalSpace.OpenNhdsOf.comap f x U` is the preimage of open neighborhood `U` of `f x` under `f : C(α, β)`. ## Main results We define order structures on both `Opens α` (`CompleteLattice`, `Frame`) and `OpenNhdsOf x` (`OrderTop`, `DistribLattice`). ## TODO - Rename `TopologicalSpace.Opens` to `Open`? - Port the `auto_cases` tactic version (as a plugin if the ported `auto_cases` will allow plugins). -/ open Filter Function Order Set open Topology variable {ι α β γ : Type*} [TopologicalSpace α] [TopologicalSpace β] [TopologicalSpace γ] namespace TopologicalSpace variable (α) in /-- The type of open subsets of a topological space. -/ structure Opens where /-- The underlying set of a bundled `TopologicalSpace.Opens` object. -/ carrier : Set α /-- The `TopologicalSpace.Opens.carrier _` is an open set. -/ is_open' : IsOpen carrier namespace Opens instance : SetLike (Opens α) α where coe := Opens.carrier coe_injective' := fun ⟨_, _⟩ ⟨_, _⟩ _ => by congr instance : CanLift (Set α) (Opens α) (↑) IsOpen := ⟨fun s h => ⟨⟨s, h⟩, rfl⟩⟩ instance instSecondCountableOpens [SecondCountableTopology α] (U : Opens α) : SecondCountableTopology U := inferInstanceAs (SecondCountableTopology U.1) theorem «forall» {p : Opens α → Prop} : (∀ U, p U) ↔ ∀ (U : Set α) (hU : IsOpen U), p ⟨U, hU⟩ := ⟨fun h _ _ => h _, fun h _ => h _ _⟩ @[simp] theorem carrier_eq_coe (U : Opens α) : U.1 = ↑U := rfl /-- the coercion `Opens α → Set α` applied to a pair is the same as taking the first component -/ @[simp] theorem coe_mk {U : Set α} {hU : IsOpen U} : ↑(⟨U, hU⟩ : Opens α) = U := rfl @[simp] theorem mem_mk {x : α} {U : Set α} {h : IsOpen U} : x ∈ mk U h ↔ x ∈ U := Iff.rfl protected theorem nonempty_coeSort {U : Opens α} : Nonempty U ↔ (U : Set α).Nonempty := Set.nonempty_coe_sort -- TODO: should this theorem be proved for a `SetLike`? protected theorem nonempty_coe {U : Opens α} : (U : Set α).Nonempty ↔ ∃ x, x ∈ U := Iff.rfl @[ext] -- TODO: replace with `∀ x, x ∈ U ↔ x ∈ V`? theorem ext {U V : Opens α} (h : (U : Set α) = V) : U = V := SetLike.coe_injective h theorem coe_inj {U V : Opens α} : (U : Set α) = V ↔ U = V := SetLike.ext'_iff.symm /-- A version of `Set.inclusion` not requiring definitional abuse -/ abbrev inclusion {U V : Opens α} (h : U ≤ V) : U → V := Set.inclusion h protected theorem isOpen (U : Opens α) : IsOpen (U : Set α) := U.is_open' @[simp] theorem mk_coe (U : Opens α) : mk (↑U) U.isOpen = U := rfl /-- See Note [custom simps projection]. -/ def Simps.coe (U : Opens α) : Set α := U initialize_simps_projections Opens (carrier → coe, as_prefix coe) /-- The interior of a set, as an element of `Opens`. -/ @[simps] protected def interior (s : Set α) : Opens α := ⟨interior s, isOpen_interior⟩ @[simp] theorem mem_interior {s : Set α} {x : α} : x ∈ Opens.interior s ↔ x ∈ _root_.interior s := .rfl theorem gc : GaloisConnection ((↑) : Opens α → Set α) Opens.interior := fun U _ => ⟨fun h => interior_maximal h U.isOpen, fun h => le_trans h interior_subset⟩ /-- The galois coinsertion between sets and opens. -/ def gi : GaloisCoinsertion (↑) (@Opens.interior α _) where choice s hs := ⟨s, interior_eq_iff_isOpen.mp <\| le_antisymm interior_subset hs⟩ gc := gc u_l_le _ := interior_subset choice_eq _s hs := le_antisymm hs interior_subset instance : CompleteLattice (Opens α) := CompleteLattice.copy (GaloisCoinsertion.liftCompleteLattice gi) -- le (fun U V => (U : Set α) ⊆ V) rfl -- top ⟨univ, isOpen_univ⟩ (ext interior_univ.symm) -- bot ⟨∅, isOpen_empty⟩ rfl -- sup (fun U V => ⟨↑U ∪ ↑V, U.2.union V.2⟩) rfl -- inf (fun U V => ⟨↑U ∩ ↑V, U.2.inter V.2⟩) (funext₂ fun U V => ext (U.2.inter V.2).interior_eq.symm) -- sSup (fun S => ⟨⋃ s ∈ S, ↑s, isOpen_biUnion fun s _ => s.2⟩) (funext fun _ => ext sSup_image.symm) -- sInf _ rfl @[simp] theorem mk_inf_mk {U V : Set α} {hU : IsOpen U} {hV : IsOpen V} : (⟨U, hU⟩ ⊓ ⟨V, hV⟩ : Opens α) = ⟨U ⊓ V, IsOpen.inter hU hV⟩ := rfl @[simp, norm_cast] theorem coe_inf (s t : Opens α) : (↑(s ⊓ t) : Set α) = ↑s ∩ ↑t := rfl @[simp] lemma mem_inf {s t : Opens α} {x : α} : x ∈ s ⊓ t ↔ x ∈ s ∧ x ∈ t := Iff.rfl @[simp, norm_cast] theorem coe_sup (s t : Opens α) : (↑(s ⊔ t) : Set α) = ↑s ∪ ↑t := rfl @[simp, norm_cast] theorem coe_bot : ((⊥ : Opens α) : Set α) = ∅ := rfl @[simp] lemma mem_bot {x : α} : x ∈ (⊥ : Opens α) ↔ False := Iff.rfl @[simp] theorem mk_empty : (⟨∅, isOpen_empty⟩ : Opens α) = ⊥ := rfl @[simp, norm_cast] theorem coe_eq_empty {U : Opens α} : (U : Set α) = ∅ ↔ U = ⊥ := SetLike.coe_injective.eq_iff' rfl @[simp] lemma mem_top (x : α) : x ∈ (⊤ : Opens α) := trivial @[simp, norm_cast] theorem coe_top : ((⊤ : Opens α) : Set α) = Set.univ := rfl @[simp] theorem mk_univ : (⟨univ, isOpen_univ⟩ : Opens α) = ⊤ := rfl @[simp, norm_cast] theorem coe_eq_univ {U : Opens α} : (U : Set α) = univ ↔ U = ⊤ := SetLike.coe_injective.eq_iff' rfl @[simp, norm_cast] theorem coe_sSup {S : Set (Opens α)} : (↑(sSup S) : Set α) = ⋃ i ∈ S, ↑i := rfl @[simp, norm_cast] theorem coe_finset_sup (f : ι → Opens α) (s : Finset ι) : (↑(s.sup f) : Set α) = s.sup ((↑) ∘ f) := map_finset_sup (⟨⟨(↑), coe_sup⟩, coe_bot⟩ : SupBotHom (Opens α) (Set α)) _ _ @[simp, norm_cast] theorem coe_finset_inf (f : ι → Opens α) (s : Finset ι) : (↑(s.inf f) : Set α) = s.inf ((↑) ∘ f) := map_finset_inf (⟨⟨(↑), coe_inf⟩, coe_top⟩ : InfTopHom (Opens α) (Set α)) _ _ instance : Inhabited (Opens α) := ⟨⊥⟩ instance [IsEmpty α] : Unique (Opens α) where uniq _ := ext <\| Subsingleton.elim _ _ instance [Nonempty α] : Nontrivial (Opens α) where exists_pair_ne := ⟨⊥, ⊤, mt coe_inj.2 empty_ne_univ⟩ @[simp, norm_cast] theorem coe_iSup {ι} (s : ι → Opens α) : ((⨆ i, s i : Opens α) : Set α) = ⋃ i, s i := by simp [iSup] theorem iSup_def {ι} (s : ι → Opens α) : ⨆ i, s i = ⟨⋃ i, s i, isOpen_iUnion fun i => (s i).2⟩ := ext <\| coe_iSup s @[simp] theorem iSup_mk {ι} (s : ι → Set α) (h : ∀ i, IsOpen (s i)) : (⨆ i, ⟨s i, h i⟩ : Opens α) = ⟨⋃ i, s i, isOpen_iUnion h⟩ := iSup_def _ @[simp] theorem mem_iSup {ι} {x : α} {s : ι → Opens α} : x ∈ iSup s ↔ ∃ i, x ∈ s i := by rw [← SetLike.mem_coe] simp @[simp] theorem mem_sSup {Us : Set (Opens α)} {x : α} : x ∈ sSup Us ↔ ∃ u ∈ Us, x ∈ u := by simp_rw [sSup_eq_iSup, mem_iSup, exists_prop] /-- Open sets in a topological space form a frame. -/ def frameMinimalAxioms : Frame.MinimalAxioms (Opens α) where inf_sSup_le_iSup_inf a s := (ext <\| by simp only [coe_inf, coe_iSup, coe_sSup, Set.inter_iUnion₂]).le instance instFrame : Frame (Opens α) := .ofMinimalAxioms frameMinimalAxioms theorem isOpenEmbedding' (U : Opens α) : IsOpenEmbedding (Subtype.val : U → α) := U.isOpen.isOpenEmbedding_subtypeVal theorem isOpenEmbedding_of_le {U V : Opens α} (i : U ≤ V) : IsOpenEmbedding (Set.inclusion <\| SetLike.coe_subset_coe.2 i) where toIsEmbedding := .inclusion i isOpen_range := by rw [Set.range_inclusion i] exact U.isOpen.preimage continuous_subtype_val theorem not_nonempty_iff_eq_bot (U : Opens α) : ¬Set.Nonempty (U : Set α) ↔ U = ⊥ := by rw [← coe_inj, coe_bot, ← Set.not_nonempty_iff_eq_empty] theorem ne_bot_iff_nonempty (U : Opens α) : U ≠ ⊥ ↔ Set.Nonempty (U : Set α) := by rw [Ne, ← not_nonempty_iff_eq_bot, not_not] /-- An open set in the indiscrete topology is either empty or the whole space. -/ theorem eq_bot_or_top {α} [t : TopologicalSpace α] (h : t = ⊤) (U : Opens α) : U = ⊥ ∨ U = ⊤ := by subst h; letI : TopologicalSpace α := ⊤ rw [← coe_eq_empty, ← coe_eq_univ, ← isOpen_top_iff] exact U.2 instance [Nonempty α] [Subsingleton α] : IsSimpleOrder (Opens α) where eq_bot_or_eq_top := eq_bot_or_top <\| Subsingleton.elim _ _ /-- A set of `opens α` is a basis if the set of corresponding sets is a topological basis. -/ def IsBasis (B : Set (Opens α)) : Prop := IsTopologicalBasis (((↑) : _ → Set α) '' B) theorem isBasis_iff_nbhd {B : Set (Opens α)} : IsBasis B ↔ ∀ {U : Opens α} {x}, x ∈ U → ∃ U' ∈ B, x ∈ U' ∧ U' ≤ U := by constructor <;> intro h · rintro ⟨sU, hU⟩ x hx rcases h.mem_nhds_iff.mp (IsOpen.mem_nhds hU hx) with ⟨sV, ⟨⟨V, H₁, H₂⟩, hsV⟩⟩ refine ⟨V, H₁, ?_⟩ cases V dsimp at H₂ subst H₂ exact hsV · refine isTopologicalBasis_of_isOpen_of_nhds ?_ ?_ · rintro sU ⟨U, -, rfl⟩ exact U.2 · intro x sU hx hsU rcases @h ⟨sU, hsU⟩ x hx with ⟨V, hV, H⟩ exact ⟨V, ⟨V, hV, rfl⟩, H⟩ theorem isBasis_iff_cover {B : Set (Opens α)} : IsBasis B ↔ ∀ U : Opens α, ∃ Us, Us ⊆ B ∧ U = sSup Us := by constructor · intro hB U refine ⟨{ V : Opens α \| V ∈ B ∧ V ≤ U }, fun U hU => hU.left, ext ?_⟩ rw [coe_sSup, hB.open_eq_sUnion' U.isOpen]	simp_rw [sUnion_eq_biUnion, iUnion, mem_setOf_eq, iSup_and, iSup_image] rfl · intro h rw [isBasis_iff_nbhd] intro U x hx rcases h U with ⟨Us, hUs, rfl⟩ rcases mem_sSup.1 hx with ⟨U, Us, xU⟩ exact ⟨U, hUs Us, xU, le_sSup Us⟩ /-- If `α` has a basis consisting of compact opens, then an open set in `α` is compact open iff it is a finite union of some elements in the basis -/ theorem IsBasis.isCompact_open_iff_eq_finite_iUnion {ι : Type*} (b : ι → Opens α) (hb : IsBasis (Set.range b)) (hb' : ∀ i, IsCompact (b i : Set α)) (U : Set α) : IsCompact U ∧ IsOpen U ↔ ∃ s : Set ι, s.Finite ∧ U = ⋃ i ∈ s, b i := by apply isCompact_open_iff_eq_finite_iUnion_of_isTopologicalBasis fun i : ι => (b i).1 · convert (config := {transparency := .default}) hb	Mathlib/Topology/Sets/Opens.lean	296	311
/- Copyright (c) 2023 Jireh Loreaux. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jireh Loreaux -/ import Mathlib.Algebra.Algebra.NonUnitalSubalgebra import Mathlib.Algebra.Star.StarAlgHom import Mathlib.Algebra.Star.Center import Mathlib.Algebra.Star.SelfAdjoint /-! # Non-unital Star Subalgebras In this file we define `NonUnitalStarSubalgebra`s and the usual operations on them (`map`, `comap`). ## TODO * once we have scalar actions by semigroups (as opposed to monoids), implement the action of a non-unital subalgebra on the larger algebra. -/ namespace StarMemClass /-- If a type carries an involutive star, then any star-closed subset does too. -/ instance instInvolutiveStar {S R : Type} [InvolutiveStar R] [SetLike S R] [StarMemClass S R] (s : S) : InvolutiveStar s where star_involutive r := Subtype.ext <\| star_star (r : R) /-- In a star magma (i.e., a multiplication with an antimultiplicative involutive star operation), any star-closed subset which is also closed under multiplication is itself a star magma. -/ instance instStarMul {S R : Type} [Mul R] [StarMul R] [SetLike S R] [MulMemClass S R] [StarMemClass S R] (s : S) : StarMul s where star_mul _ _ := Subtype.ext <\| star_mul _ _ /-- In a `StarAddMonoid` (i.e., an additive monoid with an additive involutive star operation), any star-closed subset which is also closed under addition and contains zero is itself a `StarAddMonoid`. -/ instance instStarAddMonoid {S R : Type} [AddMonoid R] [StarAddMonoid R] [SetLike S R] [AddSubmonoidClass S R] [StarMemClass S R] (s : S) : StarAddMonoid s where star_add _ _ := Subtype.ext <\| star_add _ _ /-- In a star ring (i.e., a non-unital, non-associative, semiring with an additive, antimultiplicative, involutive star operation), a star-closed non-unital subsemiring is itself a star ring. -/ instance instStarRing {S R : Type} [NonUnitalNonAssocSemiring R] [StarRing R] [SetLike S R] [NonUnitalSubsemiringClass S R] [StarMemClass S R] (s : S) : StarRing s := { StarMemClass.instStarMul s, StarMemClass.instStarAddMonoid s with } /-- In a star `R`-module (i.e., `star (r • m) = (star r) • m`) any star-closed subset which is also closed under the scalar action by `R` is itself a star `R`-module. -/ instance instStarModule {S : Type} (R : Type) {M : Type} [Star R] [Star M] [SMul R M] [StarModule R M] [SetLike S M] [SMulMemClass S R M] [StarMemClass S M] (s : S) : StarModule R s where star_smul _ _ := Subtype.ext <\| star_smul _ _ end StarMemClass universe u u' v v' w w' w'' variable {F : Type v'} {R' : Type u'} {R : Type u} variable {A : Type v} {B : Type w} {C : Type w'} namespace NonUnitalStarSubalgebraClass variable [CommSemiring R] [NonUnitalNonAssocSemiring A] variable [Star A] [Module R A] variable {S : Type w''} [SetLike S A] [NonUnitalSubsemiringClass S A] variable [hSR : SMulMemClass S R A] [StarMemClass S A] (s : S) /-- Embedding of a non-unital star subalgebra into the non-unital star algebra. -/ def subtype (s : S) : s →⋆ₙₐ[R] A := { NonUnitalSubalgebraClass.subtype s with toFun := Subtype.val map_star' := fun _ => rfl } variable {s} in @[simp] lemma subtype_apply (x : s) : subtype s x = x := rfl lemma subtype_injective : Function.Injective (subtype s) := Subtype.coe_injective @[simp] theorem coe_subtype : (subtype s : s → A) = Subtype.val := rfl @[deprecated (since := "2025-02-18")] alias coeSubtype := coe_subtype end NonUnitalStarSubalgebraClass /-- A non-unital star subalgebra is a non-unital subalgebra which is closed under the `star` operation. -/ structure NonUnitalStarSubalgebra (R : Type u) (A : Type v) [CommSemiring R] [NonUnitalNonAssocSemiring A] [Module R A] [Star A] : Type v extends NonUnitalSubalgebra R A where /-- The `carrier` of a `NonUnitalStarSubalgebra` is closed under the `star` operation. -/ star_mem' : ∀ {a : A} (_ha : a ∈ carrier), star a ∈ carrier /-- Reinterpret a `NonUnitalStarSubalgebra` as a `NonUnitalSubalgebra`. -/ add_decl_doc NonUnitalStarSubalgebra.toNonUnitalSubalgebra namespace NonUnitalStarSubalgebra variable [CommSemiring R] variable [NonUnitalNonAssocSemiring A] [Module R A] [Star A] variable [NonUnitalNonAssocSemiring B] [Module R B] [Star B] variable [NonUnitalNonAssocSemiring C] [Module R C] [Star C] variable [FunLike F A B] [NonUnitalAlgHomClass F R A B] [StarHomClass F A B] instance instSetLike : SetLike (NonUnitalStarSubalgebra R A) A where coe {s} := s.carrier coe_injective' p q h := by cases p; cases q; congr; exact SetLike.coe_injective h /-- The actual `NonUnitalStarSubalgebra` obtained from an element of a type satisfying `NonUnitalSubsemiringClass`, `SMulMemClass` and `StarMemClass`. -/ @[simps] def ofClass {S R A : Type} [CommSemiring R] [NonUnitalNonAssocSemiring A] [Module R A] [Star A] [SetLike S A] [NonUnitalSubsemiringClass S A] [SMulMemClass S R A] [StarMemClass S A] (s : S) : NonUnitalStarSubalgebra R A where carrier := s add_mem' := add_mem zero_mem' := zero_mem _ mul_mem' := mul_mem smul_mem' := SMulMemClass.smul_mem star_mem' := star_mem instance (priority := 100) : CanLift (Set A) (NonUnitalStarSubalgebra R A) (↑) (fun s ↦ 0 ∈ s ∧ (∀ {x y}, x ∈ s → y ∈ s → x + y ∈ s) ∧ (∀ {x y}, x ∈ s → y ∈ s → x * y ∈ s) ∧ (∀ (r : R) {x}, x ∈ s → r • x ∈ s) ∧ ∀ {x}, x ∈ s → star x ∈ s) where prf s h := ⟨ { carrier := s zero_mem' := h.1 add_mem' := h.2.1 mul_mem' := h.2.2.1 smul_mem' := h.2.2.2.1 star_mem' := h.2.2.2.2 }, rfl ⟩ instance instNonUnitalSubsemiringClass : NonUnitalSubsemiringClass (NonUnitalStarSubalgebra R A) A where add_mem {s} := s.add_mem' mul_mem {s} := s.mul_mem' zero_mem {s} := s.zero_mem' instance instSMulMemClass : SMulMemClass (NonUnitalStarSubalgebra R A) R A where smul_mem {s} := s.smul_mem' instance instStarMemClass : StarMemClass (NonUnitalStarSubalgebra R A) A where star_mem {s} := s.star_mem' instance instNonUnitalSubringClass {R : Type u} {A : Type v} [CommRing R] [NonUnitalNonAssocRing A] [Module R A] [Star A] : NonUnitalSubringClass (NonUnitalStarSubalgebra R A) A := { NonUnitalStarSubalgebra.instNonUnitalSubsemiringClass with neg_mem := fun _S {x} hx => neg_one_smul R x ▸ SMulMemClass.smul_mem _ hx } theorem mem_carrier {s : NonUnitalStarSubalgebra R A} {x : A} : x ∈ s.carrier ↔ x ∈ s := Iff.rfl @[ext] theorem ext {S T : NonUnitalStarSubalgebra R A} (h : ∀ x : A, x ∈ S ↔ x ∈ T) : S = T := SetLike.ext h @[simp] theorem mem_toNonUnitalSubalgebra {S : NonUnitalStarSubalgebra R A} {x} : x ∈ S.toNonUnitalSubalgebra ↔ x ∈ S := Iff.rfl @[simp] theorem coe_toNonUnitalSubalgebra (S : NonUnitalStarSubalgebra R A) : (↑S.toNonUnitalSubalgebra : Set A) = S := rfl theorem toNonUnitalSubalgebra_injective : Function.Injective (toNonUnitalSubalgebra : NonUnitalStarSubalgebra R A → NonUnitalSubalgebra R A) := fun S T h => ext fun x => by rw [← mem_toNonUnitalSubalgebra, ← mem_toNonUnitalSubalgebra, h] theorem toNonUnitalSubalgebra_inj {S U : NonUnitalStarSubalgebra R A} : S.toNonUnitalSubalgebra = U.toNonUnitalSubalgebra ↔ S = U := toNonUnitalSubalgebra_injective.eq_iff theorem toNonUnitalSubalgebra_le_iff {S₁ S₂ : NonUnitalStarSubalgebra R A} : S₁.toNonUnitalSubalgebra ≤ S₂.toNonUnitalSubalgebra ↔ S₁ ≤ S₂ := Iff.rfl /-- Copy of a non-unital star subalgebra with a new `carrier` equal to the old one. Useful to fix definitional equalities. -/ protected def copy (S : NonUnitalStarSubalgebra R A) (s : Set A) (hs : s = ↑S) : NonUnitalStarSubalgebra R A := { S.toNonUnitalSubalgebra.copy s hs with star_mem' := @fun x (hx : x ∈ s) => by show star x ∈ s rw [hs] at hx ⊢ exact S.star_mem' hx } @[simp] theorem coe_copy (S : NonUnitalStarSubalgebra R A) (s : Set A) (hs : s = ↑S) : (S.copy s hs : Set A) = s := rfl theorem copy_eq (S : NonUnitalStarSubalgebra R A) (s : Set A) (hs : s = ↑S) : S.copy s hs = S := SetLike.coe_injective hs variable (S : NonUnitalStarSubalgebra R A) /-- A non-unital star subalgebra over a ring is also a `Subring`. -/ def toNonUnitalSubring {R : Type u} {A : Type v} [CommRing R] [NonUnitalRing A] [Module R A] [Star A] (S : NonUnitalStarSubalgebra R A) : NonUnitalSubring A where toNonUnitalSubsemiring := S.toNonUnitalSubsemiring neg_mem' := neg_mem (s := S) @[simp] theorem mem_toNonUnitalSubring {R : Type u} {A : Type v} [CommRing R] [NonUnitalRing A] [Module R A] [Star A] {S : NonUnitalStarSubalgebra R A} {x} : x ∈ S.toNonUnitalSubring ↔ x ∈ S := Iff.rfl @[simp] theorem coe_toNonUnitalSubring {R : Type u} {A : Type v} [CommRing R] [NonUnitalRing A] [Module R A] [Star A] (S : NonUnitalStarSubalgebra R A) : (↑S.toNonUnitalSubring : Set A) = S := rfl theorem toNonUnitalSubring_injective {R : Type u} {A : Type v} [CommRing R] [NonUnitalRing A] [Module R A] [Star A] : Function.Injective (toNonUnitalSubring : NonUnitalStarSubalgebra R A → NonUnitalSubring A) := fun S T h => ext fun x => by rw [← mem_toNonUnitalSubring, ← mem_toNonUnitalSubring, h] theorem toNonUnitalSubring_inj {R : Type u} {A : Type v} [CommRing R] [NonUnitalRing A] [Module R A] [Star A] {S U : NonUnitalStarSubalgebra R A} : S.toNonUnitalSubring = U.toNonUnitalSubring ↔ S = U := toNonUnitalSubring_injective.eq_iff instance instInhabited : Inhabited S := ⟨(0 : S.toNonUnitalSubalgebra)⟩ section /-! `NonUnitalStarSubalgebra`s inherit structure from their `NonUnitalSubsemiringClass` and `NonUnitalSubringClass` instances. -/ instance toNonUnitalSemiring {R A} [CommSemiring R] [NonUnitalSemiring A] [Module R A] [Star A] (S : NonUnitalStarSubalgebra R A) : NonUnitalSemiring S := inferInstance instance toNonUnitalCommSemiring {R A} [CommSemiring R] [NonUnitalCommSemiring A] [Module R A] [Star A] (S : NonUnitalStarSubalgebra R A) : NonUnitalCommSemiring S := inferInstance instance toNonUnitalRing {R A} [CommRing R] [NonUnitalRing A] [Module R A] [Star A] (S : NonUnitalStarSubalgebra R A) : NonUnitalRing S := inferInstance instance toNonUnitalCommRing {R A} [CommRing R] [NonUnitalCommRing A] [Module R A] [Star A] (S : NonUnitalStarSubalgebra R A) : NonUnitalCommRing S := inferInstance end /-- The forgetful map from `NonUnitalStarSubalgebra` to `NonUnitalSubalgebra` as an `OrderEmbedding` -/ def toNonUnitalSubalgebra' : NonUnitalStarSubalgebra R A ↪o NonUnitalSubalgebra R A where toEmbedding := { toFun := fun S => S.toNonUnitalSubalgebra inj' := fun S T h => ext <\| by apply SetLike.ext_iff.1 h } map_rel_iff' := SetLike.coe_subset_coe.symm.trans SetLike.coe_subset_coe section /-! `NonUnitalStarSubalgebra`s inherit structure from their `Submodule` coercions. -/ instance module' [Semiring R'] [SMul R' R] [Module R' A] [IsScalarTower R' R A] : Module R' S := SMulMemClass.toModule' _ R' R A S instance instModule : Module R S := S.module' instance instIsScalarTower' [Semiring R'] [SMul R' R] [Module R' A] [IsScalarTower R' R A] : IsScalarTower R' R S := S.toNonUnitalSubalgebra.instIsScalarTower' instance instIsScalarTower [IsScalarTower R A A] : IsScalarTower R S S where smul_assoc r x y := Subtype.ext <\| smul_assoc r (x : A) (y : A) instance instSMulCommClass' [Semiring R'] [SMul R' R] [Module R' A] [IsScalarTower R' R A] [SMulCommClass R' R A] : SMulCommClass R' R S where smul_comm r' r s := Subtype.ext <\| smul_comm r' r (s : A) instance instSMulCommClass [SMulCommClass R A A] : SMulCommClass R S S where smul_comm r x y := Subtype.ext <\| smul_comm r (x : A) (y : A) end instance noZeroSMulDivisors_bot [NoZeroSMulDivisors R A] : NoZeroSMulDivisors R S := ⟨fun {c x} h => have : c = 0 ∨ (x : A) = 0 := eq_zero_or_eq_zero_of_smul_eq_zero (congr_arg ((↑) : S → A) h) this.imp_right (@Subtype.ext_iff _ _ x 0).mpr⟩ protected theorem coe_add (x y : S) : (↑(x + y) : A) = ↑x + ↑y := rfl protected theorem coe_mul (x y : S) : (↑(x * y) : A) = ↑x * ↑y := rfl protected theorem coe_zero : ((0 : S) : A) = 0 := rfl protected theorem coe_neg {R : Type u} {A : Type v} [CommRing R] [NonUnitalNonAssocRing A] [Module R A] [Star A] {S : NonUnitalStarSubalgebra R A} (x : S) : (↑(-x) : A) = -↑x := rfl protected theorem coe_sub {R : Type u} {A : Type v} [CommRing R] [NonUnitalNonAssocRing A] [Module R A] [Star A] {S : NonUnitalStarSubalgebra R A} (x y : S) : (↑(x - y) : A) = ↑x - ↑y := rfl @[simp, norm_cast] theorem coe_smul [SMul R' R] [SMul R' A] [IsScalarTower R' R A] (r : R') (x : S) : ↑(r • x) = r • (x : A) := rfl protected theorem coe_eq_zero {x : S} : (x : A) = 0 ↔ x = 0 := ZeroMemClass.coe_eq_zero @[simp] theorem toNonUnitalSubalgebra_subtype : NonUnitalSubalgebraClass.subtype S = NonUnitalStarSubalgebraClass.subtype S := rfl @[simp] theorem toSubring_subtype {R A : Type} [CommRing R] [NonUnitalNonAssocRing A] [Module R A] [Star A] (S : NonUnitalStarSubalgebra R A) : NonUnitalSubringClass.subtype S = NonUnitalStarSubalgebraClass.subtype S := rfl /-- Transport a non-unital star subalgebra via a non-unital star algebra homomorphism. -/ def map (f : F) (S : NonUnitalStarSubalgebra R A) : NonUnitalStarSubalgebra R B where toNonUnitalSubalgebra := S.toNonUnitalSubalgebra.map (f : A →ₙₐ[R] B) star_mem' := by rintro _ ⟨a, ha, rfl⟩; exact ⟨star a, star_mem (s := S) ha, map_star f a⟩ theorem map_mono {S₁ S₂ : NonUnitalStarSubalgebra R A} {f : F} : S₁ ≤ S₂ → (map f S₁ : NonUnitalStarSubalgebra R B) ≤ map f S₂ := Set.image_subset f theorem map_injective {f : F} (hf : Function.Injective f) : Function.Injective (map f : NonUnitalStarSubalgebra R A → NonUnitalStarSubalgebra R B) := fun _S₁ _S₂ ih => ext <\| Set.ext_iff.1 <\| Set.image_injective.2 hf <\| Set.ext <\| SetLike.ext_iff.mp ih @[simp] theorem map_id (S : NonUnitalStarSubalgebra R A) : map (NonUnitalStarAlgHom.id R A) S = S := SetLike.coe_injective <\| Set.image_id _ theorem map_map (S : NonUnitalStarSubalgebra R A) (g : B →⋆ₙₐ[R] C) (f : A →⋆ₙₐ[R] B) : (S.map f).map g = S.map (g.comp f) := SetLike.coe_injective <\| Set.image_image _ _ _ @[simp] theorem mem_map {S : NonUnitalStarSubalgebra R A} {f : F} {y : B} : y ∈ map f S ↔ ∃ x ∈ S, f x = y := NonUnitalSubalgebra.mem_map theorem map_toNonUnitalSubalgebra {S : NonUnitalStarSubalgebra R A} {f : F} : (map f S : NonUnitalStarSubalgebra R B).toNonUnitalSubalgebra = NonUnitalSubalgebra.map f S.toNonUnitalSubalgebra := SetLike.coe_injective rfl @[simp] theorem coe_map (S : NonUnitalStarSubalgebra R A) (f : F) : map f S = f '' S := rfl /-- Preimage of a non-unital star subalgebra under a non-unital star algebra homomorphism. -/ def comap (f : F) (S : NonUnitalStarSubalgebra R B) : NonUnitalStarSubalgebra R A where toNonUnitalSubalgebra := S.toNonUnitalSubalgebra.comap f star_mem' := @fun a (ha : f a ∈ S) => show f (star a) ∈ S from (map_star f a).symm ▸ star_mem (s := S) ha theorem map_le {S : NonUnitalStarSubalgebra R A} {f : F} {U : NonUnitalStarSubalgebra R B} : map f S ≤ U ↔ S ≤ comap f U := Set.image_subset_iff theorem gc_map_comap (f : F) : GaloisConnection (map f) (comap f) := fun _S _U => map_le @[simp] theorem mem_comap (S : NonUnitalStarSubalgebra R B) (f : F) (x : A) : x ∈ comap f S ↔ f x ∈ S := Iff.rfl @[simp, norm_cast] theorem coe_comap (S : NonUnitalStarSubalgebra R B) (f : F) : comap f S = f ⁻¹' (S : Set B) := rfl instance instNoZeroDivisors {R A : Type} [CommSemiring R] [NonUnitalSemiring A] [NoZeroDivisors A] [Module R A] [Star A] (S : NonUnitalStarSubalgebra R A) : NoZeroDivisors S := NonUnitalSubsemiringClass.noZeroDivisors S end NonUnitalStarSubalgebra namespace NonUnitalSubalgebra variable [CommSemiring R] [NonUnitalSemiring A] [Module R A] [Star A] variable (s : NonUnitalSubalgebra R A) /-- A non-unital subalgebra closed under `star` is a non-unital star subalgebra. -/ def toNonUnitalStarSubalgebra (h_star : ∀ x, x ∈ s → star x ∈ s) : NonUnitalStarSubalgebra R A := { s with star_mem' := @h_star } @[simp] theorem mem_toNonUnitalStarSubalgebra {s : NonUnitalSubalgebra R A} {h_star} {x} : x ∈ s.toNonUnitalStarSubalgebra h_star ↔ x ∈ s := Iff.rfl @[simp] theorem coe_toNonUnitalStarSubalgebra (s : NonUnitalSubalgebra R A) (h_star) : (s.toNonUnitalStarSubalgebra h_star : Set A) = s := rfl @[simp] theorem toNonUnitalStarSubalgebra_toNonUnitalSubalgebra (s : NonUnitalSubalgebra R A) (h_star) : (s.toNonUnitalStarSubalgebra h_star).toNonUnitalSubalgebra = s := SetLike.coe_injective rfl @[simp] theorem _root_.NonUnitalStarSubalgebra.toNonUnitalSubalgebra_toNonUnitalStarSubalgebra (S : NonUnitalStarSubalgebra R A) : (S.toNonUnitalSubalgebra.toNonUnitalStarSubalgebra fun _ => star_mem (s := S)) = S := SetLike.coe_injective rfl end NonUnitalSubalgebra namespace NonUnitalStarAlgHom variable [CommSemiring R] variable [NonUnitalNonAssocSemiring A] [Module R A] [Star A] variable [NonUnitalNonAssocSemiring B] [Module R B] [Star B] variable [NonUnitalNonAssocSemiring C] [Module R C] [Star C] variable [FunLike F A B] [NonUnitalAlgHomClass F R A B] [StarHomClass F A B] /-- Range of an `NonUnitalAlgHom` as a `NonUnitalStarSubalgebra`. -/ protected def range (φ : F) : NonUnitalStarSubalgebra R B where toNonUnitalSubalgebra := NonUnitalAlgHom.range (φ : A →ₙₐ[R] B) star_mem' := by rintro _ ⟨a, rfl⟩; exact ⟨star a, map_star φ a⟩ @[simp] theorem mem_range (φ : F) {y : B} : y ∈ (NonUnitalStarAlgHom.range φ : NonUnitalStarSubalgebra R B) ↔ ∃ x : A, φ x = y := NonUnitalRingHom.mem_srange theorem mem_range_self (φ : F) (x : A) : φ x ∈ (NonUnitalStarAlgHom.range φ : NonUnitalStarSubalgebra R B) := (NonUnitalAlgHom.mem_range φ).2 ⟨x, rfl⟩ @[simp] theorem coe_range (φ : F) : ((NonUnitalStarAlgHom.range φ : NonUnitalStarSubalgebra R B) : Set B) = Set.range (φ : A → B) := by ext; rw [SetLike.mem_coe, mem_range]; rfl theorem range_comp (f : A →⋆ₙₐ[R] B) (g : B →⋆ₙₐ[R] C) : NonUnitalStarAlgHom.range (g.comp f) = (NonUnitalStarAlgHom.range f).map g := SetLike.coe_injective (Set.range_comp g f) theorem range_comp_le_range (f : A →⋆ₙₐ[R] B) (g : B →⋆ₙₐ[R] C) : NonUnitalStarAlgHom.range (g.comp f) ≤ NonUnitalStarAlgHom.range g := SetLike.coe_mono (Set.range_comp_subset_range f g) /-- Restrict the codomain of a non-unital star algebra homomorphism. -/ def codRestrict (f : F) (S : NonUnitalStarSubalgebra R B) (hf : ∀ x, f x ∈ S) : A →⋆ₙₐ[R] S where toNonUnitalAlgHom := NonUnitalAlgHom.codRestrict f S.toNonUnitalSubalgebra hf map_star' := fun a => Subtype.ext <\| map_star f a @[simp] theorem subtype_comp_codRestrict (f : F) (S : NonUnitalStarSubalgebra R B) (hf : ∀ x : A, f x ∈ S) : (NonUnitalStarSubalgebraClass.subtype S).comp (NonUnitalStarAlgHom.codRestrict f S hf) = f := NonUnitalStarAlgHom.ext fun _ => rfl @[simp] theorem coe_codRestrict (f : F) (S : NonUnitalStarSubalgebra R B) (hf : ∀ x, f x ∈ S) (x : A) : ↑(NonUnitalStarAlgHom.codRestrict f S hf x) = f x := rfl theorem injective_codRestrict (f : F) (S : NonUnitalStarSubalgebra R B) (hf : ∀ x : A, f x ∈ S) : Function.Injective (NonUnitalStarAlgHom.codRestrict f S hf) ↔ Function.Injective f := ⟨fun H _x _y hxy => H <\| Subtype.eq hxy, fun H _x _y hxy => H (congr_arg Subtype.val hxy :)⟩ /-- Restrict the codomain of a non-unital star algebra homomorphism `f` to `f.range`. This is the bundled version of `Set.rangeFactorization`. -/ abbrev rangeRestrict (f : F) : A →⋆ₙₐ[R] (NonUnitalStarAlgHom.range f : NonUnitalStarSubalgebra R B) := NonUnitalStarAlgHom.codRestrict f (NonUnitalStarAlgHom.range f) (NonUnitalStarAlgHom.mem_range_self f) /-- The equalizer of two non-unital star `R`-algebra homomorphisms -/ def equalizer (ϕ ψ : F) : NonUnitalStarSubalgebra R A where toNonUnitalSubalgebra := NonUnitalAlgHom.equalizer ϕ ψ star_mem' := @fun x (hx : ϕ x = ψ x) => by simp [map_star, hx] @[simp] theorem mem_equalizer (φ ψ : F) (x : A) : x ∈ NonUnitalStarAlgHom.equalizer φ ψ ↔ φ x = ψ x := Iff.rfl end NonUnitalStarAlgHom namespace StarAlgEquiv variable [CommSemiring R] variable [NonUnitalSemiring A] [Module R A] [Star A] variable [NonUnitalSemiring B] [Module R B] [Star B] variable [NonUnitalSemiring C] [Module R C] [Star C] variable [FunLike F A B] [NonUnitalAlgHomClass F R A B] [StarHomClass F A B] /-- Restrict a non-unital star algebra homomorphism with a left inverse to an algebra isomorphism to its range. This is a computable alternative to `StarAlgEquiv.ofInjective`. -/ def ofLeftInverse' {g : B → A} {f : F} (h : Function.LeftInverse g f) : A ≃⋆ₐ[R] NonUnitalStarAlgHom.range f := { NonUnitalStarAlgHom.rangeRestrict f with toFun := NonUnitalStarAlgHom.rangeRestrict f invFun := g ∘ (NonUnitalStarSubalgebraClass.subtype <\| NonUnitalStarAlgHom.range f) left_inv := h right_inv := fun x => Subtype.ext <\| let ⟨x', hx'⟩ := (NonUnitalStarAlgHom.mem_range f).mp x.prop show f (g x) = x by rw [← hx', h x'] } @[simp] theorem ofLeftInverse'_apply {g : B → A} {f : F} (h : Function.LeftInverse g f) (x : A) : ofLeftInverse' h x = f x := rfl @[simp] theorem ofLeftInverse'_symm_apply {g : B → A} {f : F} (h : Function.LeftInverse g f) (x : NonUnitalStarAlgHom.range f) : (ofLeftInverse' h).symm x = g x := rfl /-- Restrict an injective non-unital star algebra homomorphism to a star algebra isomorphism -/ noncomputable def ofInjective' (f : F) (hf : Function.Injective f) : A ≃⋆ₐ[R] NonUnitalStarAlgHom.range f := ofLeftInverse' (Classical.choose_spec hf.hasLeftInverse) @[simp] theorem ofInjective'_apply (f : F) (hf : Function.Injective f) (x : A) : ofInjective' f hf x = f x := rfl end StarAlgEquiv /-! ### The star closure of a subalgebra -/ namespace NonUnitalSubalgebra open scoped Pointwise variable [CommSemiring R] [StarRing R] variable [NonUnitalSemiring A] [StarRing A] [Module R A] variable [StarModule R A] /-- The pointwise `star` of a non-unital subalgebra is a non-unital subalgebra. -/ instance instInvolutiveStar : InvolutiveStar (NonUnitalSubalgebra R A) where star S := { carrier := star S.carrier mul_mem' := @fun x y hx hy => by simpa only [Set.mem_star, NonUnitalSubalgebra.mem_carrier] using (star_mul x y).symm ▸ mul_mem hy hx add_mem' := @fun x y hx hy => by simpa only [Set.mem_star, NonUnitalSubalgebra.mem_carrier] using (star_add x y).symm ▸ add_mem hx hy zero_mem' := Set.mem_star.mp ((star_zero A).symm ▸ zero_mem S : star (0 : A) ∈ S) smul_mem' := fun r x hx => by simpa only [Set.mem_star, NonUnitalSubalgebra.mem_carrier] using (star_smul r x).symm ▸ SMulMemClass.smul_mem (star r) hx } star_involutive S := NonUnitalSubalgebra.ext fun x => ⟨fun hx => star_star x ▸ hx, fun hx => ((star_star x).symm ▸ hx : star (star x) ∈ S)⟩ @[simp] theorem mem_star_iff (S : NonUnitalSubalgebra R A) (x : A) : x ∈ star S ↔ star x ∈ S := Iff.rfl theorem star_mem_star_iff (S : NonUnitalSubalgebra R A) (x : A) : star x ∈ star S ↔ x ∈ S := by simp @[simp] theorem coe_star (S : NonUnitalSubalgebra R A) : star S = star (S : Set A) := rfl theorem star_mono : Monotone (star : NonUnitalSubalgebra R A → NonUnitalSubalgebra R A) := fun _ _ h _ hx => h hx variable (R) variable [IsScalarTower R A A] [SMulCommClass R A A] /-- The star operation on `NonUnitalSubalgebra` commutes with `NonUnitalAlgebra.adjoin`. -/ theorem star_adjoin_comm (s : Set A) : star (NonUnitalAlgebra.adjoin R s) = NonUnitalAlgebra.adjoin R (star s) := have this : ∀ t : Set A, NonUnitalAlgebra.adjoin R (star t) ≤ star (NonUnitalAlgebra.adjoin R t) := fun _ => NonUnitalAlgebra.adjoin_le fun _ hx => NonUnitalAlgebra.subset_adjoin R hx le_antisymm (by simpa only [star_star] using NonUnitalSubalgebra.star_mono (this (star s))) (this s) variable {R} /-- The `NonUnitalStarSubalgebra` obtained from `S : NonUnitalSubalgebra R A` by taking the smallest non-unital subalgebra containing both `S` and `star S`. -/ @[simps!] def starClosure (S : NonUnitalSubalgebra R A) : NonUnitalStarSubalgebra R A where toNonUnitalSubalgebra := S ⊔ star S star_mem' := @fun a (ha : a ∈ S ⊔ star S) => show star a ∈ S ⊔ star S by simp only [← mem_star_iff _ a, ← (@NonUnitalAlgebra.gi R A _ _ _ _ _).l_sup_u _ _] at * convert ha using 2 simp only [Set.sup_eq_union, star_adjoin_comm, Set.union_star, coe_star, star_star, Set.union_comm] theorem starClosure_le {S₁ : NonUnitalSubalgebra R A} {S₂ : NonUnitalStarSubalgebra R A} (h : S₁ ≤ S₂.toNonUnitalSubalgebra) : S₁.starClosure ≤ S₂ := NonUnitalStarSubalgebra.toNonUnitalSubalgebra_le_iff.1 <\| sup_le h fun x hx => (star_star x ▸ star_mem (show star x ∈ S₂ from h <\| (S₁.mem_star_iff _).1 hx) : x ∈ S₂) theorem starClosure_le_iff {S₁ : NonUnitalSubalgebra R A} {S₂ : NonUnitalStarSubalgebra R A} : S₁.starClosure ≤ S₂ ↔ S₁ ≤ S₂.toNonUnitalSubalgebra := ⟨fun h => le_sup_left.trans h, starClosure_le⟩ @[simp] theorem starClosure_toNonunitalSubalgebra {S : NonUnitalSubalgebra R A} : S.starClosure.toNonUnitalSubalgebra = S ⊔ star S := rfl @[mono] theorem starClosure_mono : Monotone (starClosure (R := R) (A := A)) := fun _ _ h => starClosure_le <\| h.trans le_sup_left end NonUnitalSubalgebra namespace NonUnitalStarAlgebra variable [CommSemiring R] [StarRing R] variable [NonUnitalSemiring A] [StarRing A] [Module R A] variable [NonUnitalSemiring B] [StarRing B] [Module R B] variable [FunLike F A B] [NonUnitalAlgHomClass F R A B] [StarHomClass F A B] section StarSubAlgebraA variable [IsScalarTower R A A] [SMulCommClass R A A] [StarModule R A] open scoped Pointwise open NonUnitalStarSubalgebra variable (R) /-- The minimal non-unital subalgebra that includes `s`. -/ def adjoin (s : Set A) : NonUnitalStarSubalgebra R A where toNonUnitalSubalgebra := NonUnitalAlgebra.adjoin R (s ∪ star s) star_mem' _ := by rwa [NonUnitalSubalgebra.mem_carrier, ← NonUnitalSubalgebra.mem_star_iff, NonUnitalSubalgebra.star_adjoin_comm, Set.union_star, star_star, Set.union_comm] theorem adjoin_eq_starClosure_adjoin (s : Set A) : adjoin R s = (NonUnitalAlgebra.adjoin R s).starClosure := toNonUnitalSubalgebra_injective <\| show NonUnitalAlgebra.adjoin R (s ∪ star s) = NonUnitalAlgebra.adjoin R s ⊔ star (NonUnitalAlgebra.adjoin R s) from (NonUnitalSubalgebra.star_adjoin_comm R s).symm ▸ NonUnitalAlgebra.adjoin_union s (star s) theorem adjoin_toNonUnitalSubalgebra (s : Set A) : (adjoin R s).toNonUnitalSubalgebra = NonUnitalAlgebra.adjoin R (s ∪ star s) := rfl @[aesop safe 20 apply (rule_sets := [SetLike])] theorem subset_adjoin (s : Set A) : s ⊆ adjoin R s := Set.subset_union_left.trans <\| NonUnitalAlgebra.subset_adjoin R theorem star_subset_adjoin (s : Set A) : star s ⊆ adjoin R s := Set.subset_union_right.trans <\| NonUnitalAlgebra.subset_adjoin R theorem self_mem_adjoin_singleton (x : A) : x ∈ adjoin R ({x} : Set A) := NonUnitalAlgebra.subset_adjoin R <\| Set.mem_union_left _ (Set.mem_singleton x) theorem star_self_mem_adjoin_singleton (x : A) : star x ∈ adjoin R ({x} : Set A) := star_mem <\| self_mem_adjoin_singleton R x @[elab_as_elim] lemma adjoin_induction {s : Set A} {p : (x : A) → x ∈ adjoin R s → Prop} (mem : ∀ (x : A) (hx : x ∈ s), p x (subset_adjoin R s hx)) (add : ∀ x y hx hy, p x hx → p y hy → p (x + y) (add_mem hx hy)) (zero : p 0 (zero_mem _)) (mul : ∀ x y hx hy, p x hx → p y hy → p (x * y) (mul_mem hx hy)) (smul : ∀ (r : R) x hx, p x hx → p (r • x) (SMulMemClass.smul_mem r hx)) (star : ∀ x hx, p x hx → p (star x) (star_mem hx)) {a : A} (ha : a ∈ adjoin R s) : p a ha := by refine NonUnitalAlgebra.adjoin_induction (fun x hx ↦ ?_) add zero mul smul ha simp only [Set.mem_union, Set.mem_star] at hx obtain (hx \| hx) := hx · exact mem x hx · simpa using star _ (NonUnitalAlgebra.subset_adjoin R (by simpa using Or.inl hx)) (mem _ hx) variable {R} protected theorem gc : GaloisConnection (adjoin R : Set A → NonUnitalStarSubalgebra R A) (↑) := by intro s S rw [← toNonUnitalSubalgebra_le_iff, adjoin_toNonUnitalSubalgebra, NonUnitalAlgebra.adjoin_le_iff, coe_toNonUnitalSubalgebra] exact ⟨fun h => Set.subset_union_left.trans h, fun h => Set.union_subset h fun x hx => star_star x ▸ star_mem (show star x ∈ S from h hx)⟩ /-- Galois insertion between `adjoin` and `Subtype.val`. -/ protected def gi : GaloisInsertion (adjoin R : Set A → NonUnitalStarSubalgebra R A) (↑) where choice s hs := (adjoin R s).copy s <\| le_antisymm (NonUnitalStarAlgebra.gc.le_u_l s) hs gc := NonUnitalStarAlgebra.gc le_l_u S := (NonUnitalStarAlgebra.gc (S : Set A) (adjoin R S)).1 <\| le_rfl choice_eq _ _ := NonUnitalStarSubalgebra.copy_eq _ _ _ theorem adjoin_le {S : NonUnitalStarSubalgebra R A} {s : Set A} (hs : s ⊆ S) : adjoin R s ≤ S := NonUnitalStarAlgebra.gc.l_le hs theorem adjoin_le_iff {S : NonUnitalStarSubalgebra R A} {s : Set A} : adjoin R s ≤ S ↔ s ⊆ S := NonUnitalStarAlgebra.gc _ _ lemma adjoin_eq (s : NonUnitalStarSubalgebra R A) : adjoin R (s : Set A) = s := le_antisymm (adjoin_le le_rfl) (subset_adjoin R (s : Set A)) lemma adjoin_eq_span (s : Set A) : (adjoin R s).toSubmodule = Submodule.span R (Subsemigroup.closure (s ∪ star s)) := by rw [adjoin_toNonUnitalSubalgebra, NonUnitalAlgebra.adjoin_eq_span] @[simp] lemma span_eq_toSubmodule {R} [CommSemiring R] [Module R A] (s : NonUnitalStarSubalgebra R A) : Submodule.span R (s : Set A) = s.toSubmodule := by simp [SetLike.ext'_iff, Submodule.coe_span_eq_self] theorem _root_.NonUnitalSubalgebra.starClosure_eq_adjoin (S : NonUnitalSubalgebra R A) : S.starClosure = adjoin R (S : Set A) := le_antisymm (NonUnitalSubalgebra.starClosure_le_iff.2 <\| subset_adjoin R (S : Set A)) (adjoin_le (le_sup_left : S ≤ S ⊔ star S)) instance : CompleteLattice (NonUnitalStarSubalgebra R A) := GaloisInsertion.liftCompleteLattice NonUnitalStarAlgebra.gi @[simp] theorem coe_top : ((⊤ : NonUnitalStarSubalgebra R A) : Set A) = Set.univ := rfl @[simp] theorem mem_top {x : A} : x ∈ (⊤ : NonUnitalStarSubalgebra R A) := Set.mem_univ x @[simp] theorem top_toNonUnitalSubalgebra : (⊤ : NonUnitalStarSubalgebra R A).toNonUnitalSubalgebra = ⊤ := by ext; simp @[simp] theorem toNonUnitalSubalgebra_eq_top {S : NonUnitalStarSubalgebra R A} : S.toNonUnitalSubalgebra = ⊤ ↔ S = ⊤ := NonUnitalStarSubalgebra.toNonUnitalSubalgebra_injective.eq_iff' top_toNonUnitalSubalgebra theorem mem_sup_left {S T : NonUnitalStarSubalgebra R A} : ∀ {x : A}, x ∈ S → x ∈ S ⊔ T := by rw [← SetLike.le_def] exact le_sup_left theorem mem_sup_right {S T : NonUnitalStarSubalgebra R A} : ∀ {x : A}, x ∈ T → x ∈ S ⊔ T := by rw [← SetLike.le_def] exact le_sup_right theorem mul_mem_sup {S T : NonUnitalStarSubalgebra R A} {x y : A} (hx : x ∈ S) (hy : y ∈ T) : x * y ∈ S ⊔ T := mul_mem (mem_sup_left hx) (mem_sup_right hy) theorem map_sup [IsScalarTower R B B] [SMulCommClass R B B] [StarModule R B] (f : F) (S T : NonUnitalStarSubalgebra R A) : ((S ⊔ T).map f : NonUnitalStarSubalgebra R B) = S.map f ⊔ T.map f := (NonUnitalStarSubalgebra.gc_map_comap f).l_sup theorem map_inf [IsScalarTower R B B] [SMulCommClass R B B] [StarModule R B] (f : F) (hf : Function.Injective f) (S T : NonUnitalStarSubalgebra R A) : ((S ⊓ T).map f : NonUnitalStarSubalgebra R B) = S.map f ⊓ T.map f := SetLike.coe_injective (Set.image_inter hf)	@[simp, norm_cast] theorem coe_inf (S T : NonUnitalStarSubalgebra R A) : (↑(S ⊓ T) : Set A) = (S : Set A) ∩ T := rfl	Mathlib/Algebra/Star/NonUnitalSubalgebra.lean	779	782
/- Copyright (c) 2021 Floris van Doorn. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Floris van Doorn -/ import Mathlib.Logic.Function.Basic import Mathlib.Logic.Relator /-! # Types that are empty In this file we define a typeclass `IsEmpty`, which expresses that a type has no elements. ## Main declaration * `IsEmpty`: a typeclass that expresses that a type is empty. -/ variable {α β γ : Sort} /-- `IsEmpty α` expresses that `α` is empty. -/ class IsEmpty (α : Sort) : Prop where protected false : α → False instance Empty.instIsEmpty : IsEmpty Empty := ⟨Empty.elim⟩ instance PEmpty.instIsEmpty : IsEmpty PEmpty := ⟨PEmpty.elim⟩ instance : IsEmpty False := ⟨id⟩ instance Fin.isEmpty : IsEmpty (Fin 0) := ⟨fun n ↦ Nat.not_lt_zero n.1 n.2⟩ instance Fin.isEmpty' : IsEmpty (Fin Nat.zero) := Fin.isEmpty protected theorem Function.isEmpty [IsEmpty β] (f : α → β) : IsEmpty α := ⟨fun x ↦ IsEmpty.false (f x)⟩ theorem Function.Surjective.isEmpty [IsEmpty α] {f : α → β} (hf : f.Surjective) : IsEmpty β := ⟨fun y ↦ let ⟨x, _⟩ := hf y; IsEmpty.false x⟩ -- See note [instance argument order] instance {p : α → Sort} [∀ x, IsEmpty (p x)] [h : Nonempty α] : IsEmpty (∀ x, p x) := h.elim fun x ↦ Function.isEmpty <\| Function.eval x instance PProd.isEmpty_left [IsEmpty α] : IsEmpty (PProd α β) := Function.isEmpty PProd.fst instance PProd.isEmpty_right [IsEmpty β] : IsEmpty (PProd α β) := Function.isEmpty PProd.snd instance Prod.isEmpty_left {α β} [IsEmpty α] : IsEmpty (α × β) := Function.isEmpty Prod.fst instance Prod.isEmpty_right {α β} [IsEmpty β] : IsEmpty (α × β) := Function.isEmpty Prod.snd instance Quot.instIsEmpty {α : Sort} [IsEmpty α] {r : α → α → Prop} : IsEmpty (Quot r) := Function.Surjective.isEmpty Quot.exists_rep instance Quotient.instIsEmpty {α : Sort} [IsEmpty α] {s : Setoid α} : IsEmpty (Quotient s) := Quot.instIsEmpty instance [IsEmpty α] [IsEmpty β] : IsEmpty (α ⊕' β) := ⟨fun x ↦ PSum.rec IsEmpty.false IsEmpty.false x⟩ instance instIsEmptySum {α β} [IsEmpty α] [IsEmpty β] : IsEmpty (α ⊕ β) := ⟨fun x ↦ Sum.rec IsEmpty.false IsEmpty.false x⟩ /-- subtypes of an empty type are empty -/ instance [IsEmpty α] (p : α → Prop) : IsEmpty (Subtype p) := ⟨fun x ↦ IsEmpty.false x.1⟩ /-- subtypes by an all-false predicate are false. -/ theorem Subtype.isEmpty_of_false {p : α → Prop} (hp : ∀ a, ¬p a) : IsEmpty (Subtype p) := ⟨fun x ↦ hp _ x.2⟩ /-- subtypes by false are false. -/ instance Subtype.isEmpty_false : IsEmpty { _a : α // False } := Subtype.isEmpty_of_false fun _ ↦ id instance Sigma.isEmpty_left {α} [IsEmpty α] {E : α → Type} : IsEmpty (Sigma E) := Function.isEmpty Sigma.fst example [h : Nonempty α] [IsEmpty β] : IsEmpty (α → β) := by infer_instance /-- Eliminate out of a type that `IsEmpty` (without using projection notation). -/ @[elab_as_elim] def isEmptyElim [IsEmpty α] {p : α → Sort} (a : α) : p a := (IsEmpty.false a).elim theorem isEmpty_iff : IsEmpty α ↔ α → False := ⟨@IsEmpty.false α, IsEmpty.mk⟩ namespace IsEmpty open Function universe u in /-- Eliminate out of a type that `IsEmpty` (using projection notation). -/ @[elab_as_elim] protected def elim {α : Sort u} (_ : IsEmpty α) {p : α → Sort} (a : α) : p a := isEmptyElim a /-- Non-dependent version of `IsEmpty.elim`. Helpful if the elaborator cannot elaborate `h.elim a` correctly. -/ protected def elim' {β : Sort} (h : IsEmpty α) (a : α) : β := (h.false a).elim protected theorem prop_iff {p : Prop} : IsEmpty p ↔ ¬p := isEmpty_iff variable [IsEmpty α] @[simp] theorem forall_iff {p : α → Prop} : (∀ a, p a) ↔ True := iff_true_intro isEmptyElim @[simp] theorem exists_iff {p : α → Prop} : (∃ a, p a) ↔ False := iff_false_intro fun ⟨x, _⟩ ↦ IsEmpty.false x -- see Note [lower instance priority] instance (priority := 100) : Subsingleton α := ⟨isEmptyElim⟩ end IsEmpty @[simp] theorem not_nonempty_iff : ¬Nonempty α ↔ IsEmpty α := ⟨fun h ↦ ⟨fun x ↦ h ⟨x⟩⟩, fun h1 h2 ↦ h2.elim h1.elim⟩ @[simp] theorem not_isEmpty_iff : ¬IsEmpty α ↔ Nonempty α := not_iff_comm.mp not_nonempty_iff @[simp] theorem isEmpty_Prop {p : Prop} : IsEmpty p ↔ ¬p := by simp only [← not_nonempty_iff, nonempty_prop] @[simp] theorem isEmpty_pi {π : α → Sort} : IsEmpty (∀ a, π a) ↔ ∃ a, IsEmpty (π a) := by simp only [← not_nonempty_iff, Classical.nonempty_pi, not_forall] theorem isEmpty_fun : IsEmpty (α → β) ↔ Nonempty α ∧ IsEmpty β := by rw [isEmpty_pi, ← exists_true_iff_nonempty, ← exists_and_right, true_and] @[simp] theorem nonempty_fun : Nonempty (α → β) ↔ IsEmpty α ∨ Nonempty β := not_iff_not.mp <\| by rw [not_or, not_nonempty_iff, not_nonempty_iff, isEmpty_fun, not_isEmpty_iff] @[simp] theorem isEmpty_sigma {α} {E : α → Type} : IsEmpty (Sigma E) ↔ ∀ a, IsEmpty (E a) := by simp only [← not_nonempty_iff, nonempty_sigma, not_exists] @[simp] theorem isEmpty_psigma {α} {E : α → Sort} : IsEmpty (PSigma E) ↔ ∀ a, IsEmpty (E a) := by simp only [← not_nonempty_iff, nonempty_psigma, not_exists] theorem isEmpty_subtype (p : α → Prop) : IsEmpty (Subtype p) ↔ ∀ x, ¬p x := by simp only [← not_nonempty_iff, nonempty_subtype, not_exists] @[simp] theorem isEmpty_prod {α β : Type*} : IsEmpty (α × β) ↔ IsEmpty α ∨ IsEmpty β := by simp only [← not_nonempty_iff, nonempty_prod, not_and_or] @[simp] theorem isEmpty_pprod : IsEmpty (PProd α β) ↔ IsEmpty α ∨ IsEmpty β := by simp only [← not_nonempty_iff, nonempty_pprod, not_and_or] @[simp] theorem isEmpty_sum {α β} : IsEmpty (α ⊕ β) ↔ IsEmpty α ∧ IsEmpty β := by simp only [← not_nonempty_iff, nonempty_sum, not_or] @[simp] theorem isEmpty_psum {α β} : IsEmpty (α ⊕' β) ↔ IsEmpty α ∧ IsEmpty β := by simp only [← not_nonempty_iff, nonempty_psum, not_or] @[simp] theorem isEmpty_ulift {α} : IsEmpty (ULift α) ↔ IsEmpty α := by simp only [← not_nonempty_iff, nonempty_ulift] @[simp] theorem isEmpty_plift {α} : IsEmpty (PLift α) ↔ IsEmpty α := by simp only [← not_nonempty_iff, nonempty_plift] theorem wellFounded_of_isEmpty {α} [IsEmpty α] (r : α → α → Prop) : WellFounded r := ⟨isEmptyElim⟩ variable (α)	theorem isEmpty_or_nonempty : IsEmpty α ∨ Nonempty α := (em <\| IsEmpty α).elim Or.inl <\| Or.inr ∘ not_isEmpty_iff.mp	Mathlib/Logic/IsEmpty.lean	196	197
/- Copyright (c) 2022 Andrew Yang. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Andrew Yang -/ import Mathlib.CategoryTheory.Adjunction.FullyFaithful import Mathlib.CategoryTheory.Adjunction.Limits import Mathlib.CategoryTheory.Limits.Shapes.Pullback.CommSq import Mathlib.CategoryTheory.Limits.Shapes.StrictInitial import Mathlib.CategoryTheory.Limits.FunctorCategory.Basic import Mathlib.CategoryTheory.Limits.Constructions.FiniteProductsOfBinaryProducts /-! # Universal colimits and van Kampen colimits ## Main definitions - `CategoryTheory.IsUniversalColimit`: A (colimit) cocone over a diagram `F : J ⥤ C` is universal if it is stable under pullbacks. - `CategoryTheory.IsVanKampenColimit`: A (colimit) cocone over a diagram `F : J ⥤ C` is van Kampen if for every cocone `c'` over the pullback of the diagram `F' : J ⥤ C'`, `c'` is colimiting iff `c'` is the pullback of `c`. ## References - https://ncatlab.org/nlab/show/van+Kampen+colimit - [Stephen Lack and Paweł Sobociński, Adhesive Categories][adhesive2004] -/ open CategoryTheory.Limits namespace CategoryTheory universe v' u' v u variable {J : Type v'} [Category.{u'} J] {C : Type u} [Category.{v} C] variable {K : Type} [Category K] {D : Type} [Category D] section NatTrans /-- A natural transformation is equifibered if every commutative square of the following form is a pullback. ``` F(X) → F(Y) ↓ ↓ G(X) → G(Y) ``` -/ def NatTrans.Equifibered {F G : J ⥤ C} (α : F ⟶ G) : Prop := ∀ ⦃i j : J⦄ (f : i ⟶ j), IsPullback (F.map f) (α.app i) (α.app j) (G.map f) theorem NatTrans.equifibered_of_isIso {F G : J ⥤ C} (α : F ⟶ G) [IsIso α] : Equifibered α := fun _ _ f => IsPullback.of_vert_isIso ⟨NatTrans.naturality _ f⟩ theorem NatTrans.Equifibered.comp {F G H : J ⥤ C} {α : F ⟶ G} {β : G ⟶ H} (hα : Equifibered α) (hβ : Equifibered β) : Equifibered (α ≫ β) := fun _ _ f => (hα f).paste_vert (hβ f) theorem NatTrans.Equifibered.whiskerRight {F G : J ⥤ C} {α : F ⟶ G} (hα : Equifibered α) (H : C ⥤ D) [∀ (i j : J) (f : j ⟶ i), PreservesLimit (cospan (α.app i) (G.map f)) H] : Equifibered (whiskerRight α H) := fun _ _ f => (hα f).map H theorem NatTrans.Equifibered.whiskerLeft {K : Type} [Category K] {F G : J ⥤ C} {α : F ⟶ G} (hα : Equifibered α) (H : K ⥤ J) : Equifibered (whiskerLeft H α) := fun _ _ f => hα (H.map f) theorem mapPair_equifibered {F F' : Discrete WalkingPair ⥤ C} (α : F ⟶ F') : NatTrans.Equifibered α := by rintro ⟨⟨⟩⟩ ⟨j⟩ ⟨⟨rfl : _ = j⟩⟩ all_goals dsimp; simp only [Discrete.functor_map_id] exact IsPullback.of_horiz_isIso ⟨by simp only [Category.comp_id, Category.id_comp]⟩ theorem NatTrans.equifibered_of_discrete {ι : Type} {F G : Discrete ι ⥤ C} (α : F ⟶ G) : NatTrans.Equifibered α := by rintro ⟨i⟩ ⟨j⟩ ⟨⟨rfl : i = j⟩⟩ simp only [Discrete.functor_map_id] exact IsPullback.of_horiz_isIso ⟨by rw [Category.id_comp, Category.comp_id]⟩ end NatTrans /-- A (colimit) cocone over a diagram `F : J ⥤ C` is universal if it is stable under pullbacks. -/ def IsUniversalColimit {F : J ⥤ C} (c : Cocone F) : Prop := ∀ ⦃F' : J ⥤ C⦄ (c' : Cocone F') (α : F' ⟶ F) (f : c'.pt ⟶ c.pt) (_ : α ≫ c.ι = c'.ι ≫ (Functor.const J).map f) (_ : NatTrans.Equifibered α), (∀ j : J, IsPullback (c'.ι.app j) (α.app j) f (c.ι.app j)) → Nonempty (IsColimit c') /-- A (colimit) cocone over a diagram `F : J ⥤ C` is van Kampen if for every cocone `c'` over the pullback of the diagram `F' : J ⥤ C'`, `c'` is colimiting iff `c'` is the pullback of `c`. TODO: Show that this is iff the functor `C ⥤ Catᵒᵖ` sending `x` to `C/x` preserves it. TODO: Show that this is iff the inclusion functor `C ⥤ Span(C)` preserves it. -/ def IsVanKampenColimit {F : J ⥤ C} (c : Cocone F) : Prop := ∀ ⦃F' : J ⥤ C⦄ (c' : Cocone F') (α : F' ⟶ F) (f : c'.pt ⟶ c.pt) (_ : α ≫ c.ι = c'.ι ≫ (Functor.const J).map f) (_ : NatTrans.Equifibered α), Nonempty (IsColimit c') ↔ ∀ j : J, IsPullback (c'.ι.app j) (α.app j) f (c.ι.app j) theorem IsVanKampenColimit.isUniversal {F : J ⥤ C} {c : Cocone F} (H : IsVanKampenColimit c) : IsUniversalColimit c := fun _ c' α f h hα => (H c' α f h hα).mpr /-- A universal colimit is a colimit. -/ noncomputable def IsUniversalColimit.isColimit {F : J ⥤ C} {c : Cocone F} (h : IsUniversalColimit c) : IsColimit c := by refine ((h c (𝟙 F) (𝟙 c.pt :) (by rw [Functor.map_id, Category.comp_id, Category.id_comp]) (NatTrans.equifibered_of_isIso _)) fun j => ?_).some haveI : IsIso (𝟙 c.pt) := inferInstance exact IsPullback.of_vert_isIso ⟨by simp⟩ /-- A van Kampen colimit is a colimit. -/ noncomputable def IsVanKampenColimit.isColimit {F : J ⥤ C} {c : Cocone F} (h : IsVanKampenColimit c) : IsColimit c := h.isUniversal.isColimit theorem IsInitial.isVanKampenColimit [HasStrictInitialObjects C] {X : C} (h : IsInitial X) : IsVanKampenColimit (asEmptyCocone X) := by intro F' c' α f hf hα have : F' = Functor.empty C := by apply Functor.hext <;> rintro ⟨⟨⟩⟩ subst this haveI := h.isIso_to f refine ⟨by rintro _ ⟨⟨⟩⟩, fun _ => ⟨IsColimit.ofIsoColimit h (Cocones.ext (asIso f).symm <\| by rintro ⟨⟨⟩⟩)⟩⟩ section Functor theorem IsUniversalColimit.of_iso {F : J ⥤ C} {c c' : Cocone F} (hc : IsUniversalColimit c) (e : c ≅ c') : IsUniversalColimit c' := by intro F' c'' α f h hα H have : c'.ι ≫ (Functor.const J).map e.inv.hom = c.ι := by ext j exact e.inv.2 j apply hc c'' α (f ≫ e.inv.1) (by rw [Functor.map_comp, ← reassoc_of% h, this]) hα intro j rw [← Category.comp_id (α.app j)] have : IsIso e.inv.hom := Functor.map_isIso (Cocones.forget _) e.inv exact (H j).paste_vert (IsPullback.of_vert_isIso ⟨by simp⟩) theorem IsVanKampenColimit.of_iso {F : J ⥤ C} {c c' : Cocone F} (H : IsVanKampenColimit c) (e : c ≅ c') : IsVanKampenColimit c' := by intro F' c'' α f h hα have : c'.ι ≫ (Functor.const J).map e.inv.hom = c.ι := by ext j exact e.inv.2 j rw [H c'' α (f ≫ e.inv.1) (by rw [Functor.map_comp, ← reassoc_of% h, this]) hα] apply forall_congr' intro j conv_lhs => rw [← Category.comp_id (α.app j)] haveI : IsIso e.inv.hom := Functor.map_isIso (Cocones.forget _) e.inv exact (IsPullback.of_vert_isIso ⟨by simp⟩).paste_vert_iff (NatTrans.congr_app h j).symm theorem IsVanKampenColimit.precompose_isIso {F G : J ⥤ C} (α : F ⟶ G) [IsIso α] {c : Cocone G} (hc : IsVanKampenColimit c) : IsVanKampenColimit ((Cocones.precompose α).obj c) := by intros F' c' α' f e hα refine (hc c' (α' ≫ α) f ((Category.assoc _ _ _).trans e) (hα.comp (NatTrans.equifibered_of_isIso _))).trans ?_ apply forall_congr' intro j simp only [Functor.const_obj_obj, NatTrans.comp_app, Cocones.precompose_obj_pt, Cocones.precompose_obj_ι] have : IsPullback (α.app j ≫ c.ι.app j) (α.app j) (𝟙 _) (c.ι.app j) := IsPullback.of_vert_isIso ⟨Category.comp_id _⟩ rw [← IsPullback.paste_vert_iff this _, Category.comp_id] exact (congr_app e j).symm theorem IsUniversalColimit.precompose_isIso {F G : J ⥤ C} (α : F ⟶ G) [IsIso α] {c : Cocone G} (hc : IsUniversalColimit c) : IsUniversalColimit ((Cocones.precompose α).obj c) := by intros F' c' α' f e hα H apply (hc c' (α' ≫ α) f ((Category.assoc _ _ _).trans e) (hα.comp (NatTrans.equifibered_of_isIso _))) intro j simp only [Functor.const_obj_obj, NatTrans.comp_app, Cocones.precompose_obj_pt, Cocones.precompose_obj_ι] rw [← Category.comp_id f] exact (H j).paste_vert (IsPullback.of_vert_isIso ⟨Category.comp_id _⟩) theorem IsVanKampenColimit.precompose_isIso_iff {F G : J ⥤ C} (α : F ⟶ G) [IsIso α] {c : Cocone G} : IsVanKampenColimit ((Cocones.precompose α).obj c) ↔ IsVanKampenColimit c := ⟨fun hc ↦ IsVanKampenColimit.of_iso (IsVanKampenColimit.precompose_isIso (inv α) hc) (Cocones.ext (Iso.refl _) (by simp)), IsVanKampenColimit.precompose_isIso α⟩ theorem IsUniversalColimit.of_mapCocone (G : C ⥤ D) {F : J ⥤ C} {c : Cocone F} [PreservesLimitsOfShape WalkingCospan G] [ReflectsColimitsOfShape J G] (hc : IsUniversalColimit (G.mapCocone c)) : IsUniversalColimit c := fun F' c' α f h hα H ↦ ⟨isColimitOfReflects _ (hc (G.mapCocone c') (whiskerRight α G) (G.map f) (by ext j; simpa using G.congr_map (NatTrans.congr_app h j)) (hα.whiskerRight G) (fun j ↦ (H j).map G)).some⟩ theorem IsVanKampenColimit.of_mapCocone (G : C ⥤ D) {F : J ⥤ C} {c : Cocone F} [∀ (i j : J) (X : C) (f : X ⟶ F.obj j) (g : i ⟶ j), PreservesLimit (cospan f (F.map g)) G] [∀ (i : J) (X : C) (f : X ⟶ c.pt), PreservesLimit (cospan f (c.ι.app i)) G] [ReflectsLimitsOfShape WalkingCospan G] [PreservesColimitsOfShape J G] [ReflectsColimitsOfShape J G] (H : IsVanKampenColimit (G.mapCocone c)) : IsVanKampenColimit c := by intro F' c' α f h hα refine (Iff.trans ?_ (H (G.mapCocone c') (whiskerRight α G) (G.map f) (by ext j; simpa using G.congr_map (NatTrans.congr_app h j)) (hα.whiskerRight G))).trans (forall_congr' fun j => ?_) · exact ⟨fun h => ⟨isColimitOfPreserves G h.some⟩, fun h => ⟨isColimitOfReflects G h.some⟩⟩ · exact IsPullback.map_iff G (NatTrans.congr_app h.symm j) theorem IsVanKampenColimit.mapCocone_iff (G : C ⥤ D) {F : J ⥤ C} {c : Cocone F} [G.IsEquivalence] : IsVanKampenColimit (G.mapCocone c) ↔ IsVanKampenColimit c := ⟨IsVanKampenColimit.of_mapCocone G, fun hc ↦ by let e : F ⋙ G ⋙ Functor.inv G ≅ F := NatIso.hcomp (Iso.refl F) G.asEquivalence.unitIso.symm apply IsVanKampenColimit.of_mapCocone G.inv apply (IsVanKampenColimit.precompose_isIso_iff e.inv).mp exact hc.of_iso (Cocones.ext (G.asEquivalence.unitIso.app c.pt) (fun j => (by simp [e])))⟩ theorem IsUniversalColimit.whiskerEquivalence {K : Type} [Category K] (e : J ≌ K) {F : K ⥤ C} {c : Cocone F} (hc : IsUniversalColimit c) : IsUniversalColimit (c.whisker e.functor) := by intro F' c' α f e' hα H convert hc (c'.whisker e.inverse) (whiskerLeft e.inverse α ≫ (e.invFunIdAssoc F).hom) f ?_ ((hα.whiskerLeft _).comp (NatTrans.equifibered_of_isIso _)) ?_ using 1 · exact (IsColimit.whiskerEquivalenceEquiv e.symm).nonempty_congr · convert congr_arg (whiskerLeft e.inverse) e' ext simp · intro k rw [← Category.comp_id f] refine (H (e.inverse.obj k)).paste_vert ?_ have : IsIso (𝟙 (Cocone.whisker e.functor c).pt) := inferInstance exact IsPullback.of_vert_isIso ⟨by simp⟩ theorem IsUniversalColimit.whiskerEquivalence_iff {K : Type} [Category K] (e : J ≌ K) {F : K ⥤ C} {c : Cocone F} : IsUniversalColimit (c.whisker e.functor) ↔ IsUniversalColimit c := ⟨fun hc ↦ ((hc.whiskerEquivalence e.symm).precompose_isIso (e.invFunIdAssoc F).inv).of_iso (Cocones.ext (Iso.refl _) (by simp)), IsUniversalColimit.whiskerEquivalence e⟩ theorem IsVanKampenColimit.whiskerEquivalence {K : Type} [Category K] (e : J ≌ K) {F : K ⥤ C} {c : Cocone F} (hc : IsVanKampenColimit c) : IsVanKampenColimit (c.whisker e.functor) := by intro F' c' α f e' hα convert hc (c'.whisker e.inverse) (whiskerLeft e.inverse α ≫ (e.invFunIdAssoc F).hom) f ?_ ((hα.whiskerLeft _).comp (NatTrans.equifibered_of_isIso _)) using 1 · exact (IsColimit.whiskerEquivalenceEquiv e.symm).nonempty_congr · simp only [Functor.const_obj_obj, Functor.comp_obj, Cocone.whisker_pt, Cocone.whisker_ι, whiskerLeft_app, NatTrans.comp_app, Equivalence.invFunIdAssoc_hom_app, Functor.id_obj] constructor · intro H k rw [← Category.comp_id f] refine (H (e.inverse.obj k)).paste_vert ?_ have : IsIso (𝟙 (Cocone.whisker e.functor c).pt) := inferInstance exact IsPullback.of_vert_isIso ⟨by simp⟩ · intro H j have : α.app j = F'.map (e.unit.app _) ≫ α.app _ ≫ F.map (e.counit.app (e.functor.obj j)) := by simp [← Functor.map_comp] rw [← Category.id_comp f, this] refine IsPullback.paste_vert ?_ (H (e.functor.obj j)) exact IsPullback.of_vert_isIso ⟨by simp⟩ · ext k simpa using congr_app e' (e.inverse.obj k) theorem IsVanKampenColimit.whiskerEquivalence_iff {K : Type} [Category K] (e : J ≌ K) {F : K ⥤ C} {c : Cocone F} : IsVanKampenColimit (c.whisker e.functor) ↔ IsVanKampenColimit c := ⟨fun hc ↦ ((hc.whiskerEquivalence e.symm).precompose_isIso (e.invFunIdAssoc F).inv).of_iso (Cocones.ext (Iso.refl _) (by simp)), IsVanKampenColimit.whiskerEquivalence e⟩ theorem isVanKampenColimit_of_evaluation [HasPullbacks D] [HasColimitsOfShape J D] (F : J ⥤ C ⥤ D) (c : Cocone F) (hc : ∀ x : C, IsVanKampenColimit (((evaluation C D).obj x).mapCocone c)) : IsVanKampenColimit c := by intro F' c' α f e hα have := fun x => hc x (((evaluation C D).obj x).mapCocone c') (whiskerRight α _) (((evaluation C D).obj x).map f) (by ext y dsimp exact NatTrans.congr_app (NatTrans.congr_app e y) x) (hα.whiskerRight _) constructor · rintro ⟨hc'⟩ j refine ⟨⟨(NatTrans.congr_app e j).symm⟩, ⟨evaluationJointlyReflectsLimits _ ?_⟩⟩ refine fun x => (isLimitMapConePullbackConeEquiv _ _).symm ?_ exact ((this x).mp ⟨isColimitOfPreserves _ hc'⟩ _).isLimit · exact fun H => ⟨evaluationJointlyReflectsColimits _ fun x => ((this x).mpr fun j => (H j).map ((evaluation C D).obj x)).some⟩ end Functor section reflective theorem IsUniversalColimit.map_reflective {Gl : C ⥤ D} {Gr : D ⥤ C} (adj : Gl ⊣ Gr) [Gr.Full] [Gr.Faithful] {F : J ⥤ D} {c : Cocone (F ⋙ Gr)} (H : IsUniversalColimit c) [∀ X (f : X ⟶ Gl.obj c.pt), HasPullback (Gr.map f) (adj.unit.app c.pt)] [∀ X (f : X ⟶ Gl.obj c.pt), PreservesLimit (cospan (Gr.map f) (adj.unit.app c.pt)) Gl] : IsUniversalColimit (Gl.mapCocone c) := by have := adj.rightAdjoint_preservesLimits have : PreservesColimitsOfSize.{u', v'} Gl := adj.leftAdjoint_preservesColimits intros F' c' α f h hα hc' have : HasPullback (Gl.map (Gr.map f)) (Gl.map (adj.unit.app c.pt)) := ⟨⟨_, isLimitPullbackConeMapOfIsLimit _ pullback.condition (IsPullback.of_hasPullback _ _).isLimit⟩⟩ let α' := α ≫ (Functor.associator _ _ _).hom ≫ whiskerLeft F adj.counit ≫ F.rightUnitor.hom have hα' : NatTrans.Equifibered α' := hα.comp (NatTrans.equifibered_of_isIso _) have hadj : ∀ X, Gl.map (adj.unit.app X) = inv (adj.counit.app _) := by intro X apply IsIso.eq_inv_of_inv_hom_id exact adj.left_triangle_components _ haveI : ∀ X, IsIso (Gl.map (adj.unit.app X)) := by simp_rw [hadj] infer_instance have hα'' : ∀ j, Gl.map (Gr.map <\| α'.app j) = adj.counit.app _ ≫ α.app j := by intro j rw [← cancel_mono (adj.counit.app <\| F.obj j)] dsimp [α'] simp only [Category.comp_id, Adjunction.counit_naturality_assoc, Category.id_comp, Adjunction.counit_naturality, Category.assoc, Functor.map_comp] have hc'' : ∀ j, α.app j ≫ Gl.map (c.ι.app j) = c'.ι.app j ≫ f := NatTrans.congr_app h let β := isoWhiskerLeft F' (asIso adj.counit) ≪≫ F'.rightUnitor let c'' : Cocone (F' ⋙ Gr) := by refine { pt := pullback (Gr.map f) (adj.unit.app _) ι := { app := fun j ↦ pullback.lift (Gr.map <\| c'.ι.app j) (Gr.map (α'.app j) ≫ c.ι.app j) ?_ naturality := ?_ } } · rw [← Gr.map_comp, ← hc''] erw [← adj.unit_naturality] rw [Gl.map_comp, hα''] dsimp simp only [Category.assoc, Functor.map_comp, adj.right_triangle_components_assoc] · intros i j g dsimp [α'] ext all_goals simp only [Category.comp_id, Category.id_comp, Category.assoc, ← Functor.map_comp, pullback.lift_fst, pullback.lift_snd, ← Functor.map_comp_assoc] · congr 1 exact c'.w _ · rw [α.naturality_assoc] dsimp rw [adj.counit_naturality, ← Category.assoc, Gr.map_comp_assoc] congr 1 exact c.w _ let cf : (Cocones.precompose β.hom).obj c' ⟶ Gl.mapCocone c'' := by refine { hom := pullback.lift ?_ f ?_ ≫ (PreservesPullback.iso _ _ _).inv, w := ?_ } · exact inv <\| adj.counit.app c'.pt · simp [← cancel_mono (adj.counit.app <\| Gl.obj c.pt)] · intro j rw [← Category.assoc, Iso.comp_inv_eq] ext all_goals simp only [c'', PreservesPullback.iso_hom_fst, PreservesPullback.iso_hom_snd, pullback.lift_fst, pullback.lift_snd, Category.assoc, Functor.mapCocone_ι_app, ← Gl.map_comp] · rw [IsIso.comp_inv_eq, adj.counit_naturality] dsimp [β] rw [Category.comp_id] · rw [Gl.map_comp, hα'', Category.assoc, hc''] dsimp [β] rw [Category.comp_id, Category.assoc] have : cf.hom ≫ (PreservesPullback.iso _ _ _).hom ≫ pullback.fst _ _ ≫ adj.counit.app _ = 𝟙 _ := by simp only [cf, IsIso.inv_hom_id, Iso.inv_hom_id_assoc, Category.assoc, pullback.lift_fst_assoc] have : IsIso cf := by apply @Cocones.cocone_iso_of_hom_iso (i := ?_) rw [← IsIso.eq_comp_inv] at this rw [this] infer_instance have ⟨Hc''⟩ := H c'' (whiskerRight α' Gr) (pullback.snd _ _) ?_ (hα'.whiskerRight Gr) ?_ · exact ⟨IsColimit.precomposeHomEquiv β c' <\| (isColimitOfPreserves Gl Hc'').ofIsoColimit (asIso cf).symm⟩ · ext j dsimp [c''] simp only [Category.comp_id, Category.id_comp, Category.assoc, Functor.map_comp, pullback.lift_snd] · intro j apply IsPullback.of_right _ _ (IsPullback.of_hasPullback _ _) · dsimp [α', c''] simp only [Category.comp_id, Category.id_comp, Category.assoc, Functor.map_comp, pullback.lift_fst] rw [← Category.comp_id (Gr.map f)] refine ((hc' j).map Gr).paste_vert (IsPullback.of_vert_isIso ⟨?_⟩) rw [← adj.unit_naturality, Category.comp_id, ← Category.assoc, ← Category.id_comp (Gr.map ((Gl.mapCocone c).ι.app j))] congr 1 rw [← cancel_mono (Gr.map (adj.counit.app (F.obj j)))] dsimp simp only [Category.comp_id, Adjunction.right_triangle_components, Category.id_comp, Category.assoc] · dsimp [c''] simp only [Category.comp_id, Category.id_comp, Category.assoc, Functor.map_comp, pullback.lift_snd] theorem IsVanKampenColimit.map_reflective [HasColimitsOfShape J C] {Gl : C ⥤ D} {Gr : D ⥤ C} (adj : Gl ⊣ Gr) [Gr.Full] [Gr.Faithful] {F : J ⥤ D} {c : Cocone (F ⋙ Gr)} (H : IsVanKampenColimit c) [∀ X (f : X ⟶ Gl.obj c.pt), HasPullback (Gr.map f) (adj.unit.app c.pt)] [∀ X (f : X ⟶ Gl.obj c.pt), PreservesLimit (cospan (Gr.map f) (adj.unit.app c.pt)) Gl] [∀ X i (f : X ⟶ c.pt), PreservesLimit (cospan f (c.ι.app i)) Gl] : IsVanKampenColimit (Gl.mapCocone c) := by have := adj.rightAdjoint_preservesLimits have : PreservesColimitsOfSize.{u', v'} Gl := adj.leftAdjoint_preservesColimits intro F' c' α f h hα refine ⟨?_, H.isUniversal.map_reflective adj c' α f h hα⟩ intro ⟨hc'⟩ j let α' := α ≫ (Functor.associator _ _ _).hom ≫ whiskerLeft F adj.counit ≫ F.rightUnitor.hom have hα' : NatTrans.Equifibered α' := hα.comp (NatTrans.equifibered_of_isIso _) have hα'' : ∀ j, Gl.map (Gr.map <\| α'.app j) = adj.counit.app _ ≫ α.app j := by intro j rw [← cancel_mono (adj.counit.app <\| F.obj j)] dsimp [α'] simp only [Category.comp_id, Adjunction.counit_naturality_assoc, Category.id_comp, Adjunction.counit_naturality, Category.assoc, Functor.map_comp] let β := isoWhiskerLeft F' (asIso adj.counit) ≪≫ F'.rightUnitor let hl := (IsColimit.precomposeHomEquiv β c').symm hc' let hr := isColimitOfPreserves Gl (colimit.isColimit <\| F' ⋙ Gr) have : α.app j = β.inv.app _ ≫ Gl.map (Gr.map <\| α'.app j) := by rw [hα''] simp [β] rw [this] have : f = (hl.coconePointUniqueUpToIso hr).hom ≫ Gl.map (colimit.desc _ ⟨_, whiskerRight α' Gr ≫ c.2⟩) := by symm convert @IsColimit.coconePointUniqueUpToIso_hom_desc _ _ _ _ ((F' ⋙ Gr) ⋙ Gl) (Gl.mapCocone ⟨_, (whiskerRight α' Gr ≫ c.2 :)⟩) _ _ hl hr using 2 · apply hr.hom_ext intro j rw [hr.fac, Functor.mapCocone_ι_app, ← Gl.map_comp, colimit.cocone_ι, colimit.ι_desc] rfl · clear_value α' apply hl.hom_ext intro j rw [hl.fac] dsimp [β] simp only [Category.comp_id, hα'', Category.assoc, Gl.map_comp] congr 1 exact (NatTrans.congr_app h j).symm rw [this] have := ((H (colimit.cocone <\| F' ⋙ Gr) (whiskerRight α' Gr) (colimit.desc _ ⟨_, whiskerRight α' Gr ≫ c.2⟩) ?_ (hα'.whiskerRight Gr)).mp ⟨(getColimitCocone <\| F' ⋙ Gr).2⟩ j).map Gl · convert IsPullback.paste_vert _ this refine IsPullback.of_vert_isIso ⟨?_⟩ rw [← IsIso.inv_comp_eq, ← Category.assoc, NatIso.inv_inv_app] exact IsColimit.comp_coconePointUniqueUpToIso_hom hl hr _ · clear_value α' ext j simp end reflective section Initial theorem hasStrictInitial_of_isUniversal [HasInitial C] (H : IsUniversalColimit (BinaryCofan.mk (𝟙 (⊥_ C)) (𝟙 (⊥_ C)))) : HasStrictInitialObjects C := hasStrictInitialObjects_of_initial_is_strict (by intro A f suffices IsColimit (BinaryCofan.mk (𝟙 A) (𝟙 A)) by obtain ⟨l, h₁, h₂⟩ := Limits.BinaryCofan.IsColimit.desc' this (f ≫ initial.to A) (𝟙 A) rcases(Category.id_comp _).symm.trans h₂ with rfl exact ⟨⟨_, ((Category.id_comp _).symm.trans h₁).symm, initialIsInitial.hom_ext _ _⟩⟩ refine (H (BinaryCofan.mk (𝟙 _) (𝟙 _)) (mapPair f f) f (by ext ⟨⟨⟩⟩ <;> dsimp <;> simp) (mapPair_equifibered _) ?_).some rintro ⟨⟨⟩⟩ <;> dsimp <;> exact IsPullback.of_horiz_isIso ⟨(Category.id_comp _).trans (Category.comp_id _).symm⟩) theorem isVanKampenColimit_of_isEmpty [HasStrictInitialObjects C] [IsEmpty J] {F : J ⥤ C} (c : Cocone F) (hc : IsColimit c) : IsVanKampenColimit c := by have : IsInitial c.pt := by have := (IsColimit.precomposeInvEquiv (Functor.uniqueFromEmpty _) _).symm (hc.whiskerEquivalence (equivalenceOfIsEmpty (Discrete PEmpty.{1}) J)) exact IsColimit.ofIsoColimit this (Cocones.ext (Iso.refl c.pt) (fun {X} ↦ isEmptyElim X)) replace this := IsInitial.isVanKampenColimit this apply (IsVanKampenColimit.whiskerEquivalence_iff (equivalenceOfIsEmpty (Discrete PEmpty.{1}) J)).mp exact (this.precompose_isIso (Functor.uniqueFromEmpty ((equivalenceOfIsEmpty (Discrete PEmpty.{1}) J).functor ⋙ F)).hom).of_iso (Cocones.ext (Iso.refl _) (by simp)) end Initial section BinaryCoproduct variable {X Y : C} theorem BinaryCofan.isVanKampen_iff (c : BinaryCofan X Y) : IsVanKampenColimit c ↔ ∀ {X' Y' : C} (c' : BinaryCofan X' Y') (αX : X' ⟶ X) (αY : Y' ⟶ Y) (f : c'.pt ⟶ c.pt) (_ : αX ≫ c.inl = c'.inl ≫ f) (_ : αY ≫ c.inr = c'.inr ≫ f), Nonempty (IsColimit c') ↔ IsPullback c'.inl αX f c.inl ∧ IsPullback c'.inr αY f c.inr := by constructor · introv H hαX hαY rw [H c' (mapPair αX αY) f (by ext ⟨⟨⟩⟩ <;> dsimp <;> assumption) (mapPair_equifibered _)] constructor · intro H exact ⟨H _, H _⟩ · rintro H ⟨⟨⟩⟩ exacts [H.1, H.2] · introv H F' hα h let X' := F'.obj ⟨WalkingPair.left⟩ let Y' := F'.obj ⟨WalkingPair.right⟩ have : F' = pair X' Y' := by apply Functor.hext · rintro ⟨⟨⟩⟩ <;> rfl · rintro ⟨⟨⟩⟩ ⟨j⟩ ⟨⟨rfl : _ = j⟩⟩ <;> simp [X', Y'] clear_value X' Y' subst this change BinaryCofan X' Y' at c' rw [H c' _ _ _ (NatTrans.congr_app hα ⟨WalkingPair.left⟩) (NatTrans.congr_app hα ⟨WalkingPair.right⟩)] constructor · rintro H ⟨⟨⟩⟩ exacts [H.1, H.2] · intro H exact ⟨H _, H _⟩ theorem BinaryCofan.isVanKampen_mk {X Y : C} (c : BinaryCofan X Y) (cofans : ∀ X Y : C, BinaryCofan X Y) (colimits : ∀ X Y, IsColimit (cofans X Y)) (cones : ∀ {X Y Z : C} (f : X ⟶ Z) (g : Y ⟶ Z), PullbackCone f g) (limits : ∀ {X Y Z : C} (f : X ⟶ Z) (g : Y ⟶ Z), IsLimit (cones f g)) (h₁ : ∀ {X' Y' : C} (αX : X' ⟶ X) (αY : Y' ⟶ Y) (f : (cofans X' Y').pt ⟶ c.pt) (_ : αX ≫ c.inl = (cofans X' Y').inl ≫ f) (_ : αY ≫ c.inr = (cofans X' Y').inr ≫ f), IsPullback (cofans X' Y').inl αX f c.inl ∧ IsPullback (cofans X' Y').inr αY f c.inr) (h₂ : ∀ {Z : C} (f : Z ⟶ c.pt), IsColimit (BinaryCofan.mk (cones f c.inl).fst (cones f c.inr).fst)) : IsVanKampenColimit c := by rw [BinaryCofan.isVanKampen_iff] introv hX hY constructor · rintro ⟨h⟩ let e := h.coconePointUniqueUpToIso (colimits _ _) obtain ⟨hl, hr⟩ := h₁ αX αY (e.inv ≫ f) (by simp [e, hX]) (by simp [e, hY]) constructor · rw [← Category.id_comp αX, ← Iso.hom_inv_id_assoc e f] haveI : IsIso (𝟙 X') := inferInstance have : c'.inl ≫ e.hom = 𝟙 X' ≫ (cofans X' Y').inl := by dsimp [e] simp exact (IsPullback.of_vert_isIso ⟨this⟩).paste_vert hl · rw [← Category.id_comp αY, ← Iso.hom_inv_id_assoc e f] haveI : IsIso (𝟙 Y') := inferInstance have : c'.inr ≫ e.hom = 𝟙 Y' ≫ (cofans X' Y').inr := by dsimp [e] simp exact (IsPullback.of_vert_isIso ⟨this⟩).paste_vert hr · rintro ⟨H₁, H₂⟩ refine ⟨IsColimit.ofIsoColimit ?_ <\| (isoBinaryCofanMk _).symm⟩ let e₁ : X' ≅ _ := H₁.isLimit.conePointUniqueUpToIso (limits _ _) let e₂ : Y' ≅ _ := H₂.isLimit.conePointUniqueUpToIso (limits _ _) have he₁ : c'.inl = e₁.hom ≫ (cones f c.inl).fst := by simp [e₁] have he₂ : c'.inr = e₂.hom ≫ (cones f c.inr).fst := by simp [e₂] rw [he₁, he₂] exact (BinaryCofan.mk _ _).isColimitCompRightIso e₂.hom ((BinaryCofan.mk _ _).isColimitCompLeftIso e₁.hom (h₂ f)) theorem BinaryCofan.mono_inr_of_isVanKampen [HasInitial C] {X Y : C} {c : BinaryCofan X Y} (h : IsVanKampenColimit c) : Mono c.inr := by refine PullbackCone.mono_of_isLimitMkIdId _ (IsPullback.isLimit ?_) refine (h (BinaryCofan.mk (initial.to Y) (𝟙 Y)) (mapPair (initial.to X) (𝟙 Y)) c.inr ?_ (mapPair_equifibered _)).mp ⟨?_⟩ ⟨WalkingPair.right⟩ · ext ⟨⟨⟩⟩ <;> dsimp; simp · exact ((BinaryCofan.isColimit_iff_isIso_inr initialIsInitial _).mpr (by dsimp infer_instance)).some theorem BinaryCofan.isPullback_initial_to_of_isVanKampen [HasInitial C] {c : BinaryCofan X Y} (h : IsVanKampenColimit c) : IsPullback (initial.to _) (initial.to _) c.inl c.inr := by refine ((h (BinaryCofan.mk (initial.to Y) (𝟙 Y)) (mapPair (initial.to X) (𝟙 Y)) c.inr ?_ (mapPair_equifibered _)).mp ⟨?_⟩ ⟨WalkingPair.left⟩).flip · ext ⟨⟨⟩⟩ <;> dsimp; simp · exact ((BinaryCofan.isColimit_iff_isIso_inr initialIsInitial _).mpr (by dsimp infer_instance)).some end BinaryCoproduct section FiniteCoproducts theorem isUniversalColimit_extendCofan {n : ℕ} (f : Fin (n + 1) → C) {c₁ : Cofan fun i : Fin n ↦ f i.succ} {c₂ : BinaryCofan (f 0) c₁.pt} (t₁ : IsUniversalColimit c₁) (t₂ : IsUniversalColimit c₂) [∀ {Z} (i : Z ⟶ c₂.pt), HasPullback c₂.inr i] : IsUniversalColimit (extendCofan c₁ c₂) := by intro F c α i e hα H let F' : Fin (n + 1) → C := F.obj ∘ Discrete.mk have : F = Discrete.functor F' := by apply Functor.hext · exact fun i ↦ rfl · rintro ⟨i⟩ ⟨j⟩ ⟨⟨rfl : i = j⟩⟩ simp [F'] have t₁' := @t₁ (Discrete.functor (fun j ↦ F.obj ⟨j.succ⟩)) (Cofan.mk (pullback c₂.inr i) fun j ↦ pullback.lift (α.app _ ≫ c₁.inj _) (c.ι.app _) ?_) (Discrete.natTrans fun i ↦ α.app _) (pullback.fst _ _) ?_ (NatTrans.equifibered_of_discrete _) ?_ rotate_left · simpa only [Functor.const_obj_obj, pair_obj_right, Discrete.functor_obj, Category.assoc, extendCofan_pt, Functor.const_obj_obj, NatTrans.comp_app, extendCofan_ι_app, Fin.cases_succ, Functor.const_map_app] using congr_app e ⟨j.succ⟩ · ext j dsimp simp only [limit.lift_π, PullbackCone.mk_pt, PullbackCone.mk_π_app, Cofan.inj] · intro j simp only [pair_obj_right, Functor.const_obj_obj, Discrete.functor_obj, id_eq, extendCofan_pt, eq_mpr_eq_cast, Cofan.mk_pt, Cofan.mk_ι_app, Discrete.natTrans_app] refine IsPullback.of_right ?_ ?_ (IsPullback.of_hasPullback (BinaryCofan.inr c₂) i).flip · simp only [Functor.const_obj_obj, pair_obj_right, limit.lift_π, PullbackCone.mk_pt, PullbackCone.mk_π_app] exact H _ · simp only [limit.lift_π, PullbackCone.mk_pt, PullbackCone.mk_π_app, Cofan.inj] obtain ⟨H₁⟩ := t₁' have t₂' := @t₂ (pair (F.obj ⟨0⟩) (pullback c₂.inr i)) (BinaryCofan.mk (c.ι.app ⟨0⟩) (pullback.snd _ _)) (mapPair (α.app _) (pullback.fst _ _)) i ?_ (mapPair_equifibered _) ?_ rotate_left · ext ⟨⟨⟩⟩ · simpa [mapPair] using congr_app e ⟨0⟩ · simpa using pullback.condition · rintro ⟨⟨⟩⟩ · simp only [pair_obj_right, Functor.const_obj_obj, pair_obj_left, BinaryCofan.mk_pt, BinaryCofan.ι_app_left, BinaryCofan.mk_inl, mapPair_left] exact H ⟨0⟩ · simp only [pair_obj_right, Functor.const_obj_obj, BinaryCofan.mk_pt, BinaryCofan.ι_app_right, BinaryCofan.mk_inr, mapPair_right] exact (IsPullback.of_hasPullback (BinaryCofan.inr c₂) i).flip obtain ⟨H₂⟩ := t₂' clear_value F' subst this refine ⟨IsColimit.ofIsoColimit (extendCofanIsColimit (fun i ↦ (Discrete.functor F').obj ⟨i⟩) H₁ H₂) <\| Cocones.ext (Iso.refl _) ?_⟩ dsimp rintro ⟨j⟩ simp only [Discrete.functor_obj, limit.lift_π, PullbackCone.mk_pt, PullbackCone.mk_π_app, Category.comp_id] induction' j using Fin.inductionOn · simp only [Fin.cases_zero] · simp only [Fin.cases_succ] theorem isVanKampenColimit_extendCofan {n : ℕ} (f : Fin (n + 1) → C) {c₁ : Cofan fun i : Fin n ↦ f i.succ} {c₂ : BinaryCofan (f 0) c₁.pt} (t₁ : IsVanKampenColimit c₁) (t₂ : IsVanKampenColimit c₂) [∀ {Z} (i : Z ⟶ c₂.pt), HasPullback c₂.inr i] [HasFiniteCoproducts C] : IsVanKampenColimit (extendCofan c₁ c₂) := by intro F c α i e hα refine ⟨?_, isUniversalColimit_extendCofan f t₁.isUniversal t₂.isUniversal c α i e hα⟩ intro ⟨Hc⟩ ⟨j⟩ have t₂' := (@t₂ (pair (F.obj ⟨0⟩) (∐ fun (j : Fin n) ↦ F.obj ⟨j.succ⟩)) (BinaryCofan.mk (P := c.pt) (c.ι.app _) (Sigma.desc fun b ↦ c.ι.app _)) (mapPair (α.app _) (Sigma.desc fun b ↦ α.app _ ≫ c₁.inj _)) i ?_ (mapPair_equifibered _)).mp ⟨?_⟩ rotate_left · ext ⟨⟨⟩⟩ · simpa only [pair_obj_left, Functor.const_obj_obj, pair_obj_right, Discrete.functor_obj, NatTrans.comp_app, mapPair_left, BinaryCofan.ι_app_left, BinaryCofan.mk_pt, BinaryCofan.mk_inl, Functor.const_map_app, extendCofan_pt, extendCofan_ι_app, Fin.cases_zero] using congr_app e ⟨0⟩ · dsimp ext j simpa only [colimit.ι_desc_assoc, Discrete.functor_obj, Cofan.mk_pt, Cofan.mk_ι_app, Category.assoc, extendCofan_pt, Functor.const_obj_obj, NatTrans.comp_app, extendCofan_ι_app, Fin.cases_succ, Functor.const_map_app] using congr_app e ⟨j.succ⟩ · let F' : Fin (n + 1) → C := F.obj ∘ Discrete.mk have : F = Discrete.functor F' := by apply Functor.hext · exact fun i ↦ rfl · rintro ⟨i⟩ ⟨j⟩ ⟨⟨rfl : i = j⟩⟩ simp [F'] clear_value F' subst this apply BinaryCofan.IsColimit.mk _ (fun {T} f₁ f₂ ↦ Hc.desc (Cofan.mk T (Fin.cases f₁ (fun i ↦ Sigma.ι (fun (j : Fin n) ↦ (Discrete.functor F').obj ⟨j.succ⟩) _ ≫ f₂)))) · intro T f₁ f₂ simp only [Discrete.functor_obj, pair_obj_left, BinaryCofan.mk_pt, Functor.const_obj_obj, BinaryCofan.ι_app_left, BinaryCofan.mk_inl, IsColimit.fac, Cofan.mk_pt, Cofan.mk_ι_app, Fin.cases_zero] · intro T f₁ f₂ simp only [Discrete.functor_obj, pair_obj_right, BinaryCofan.mk_pt, Functor.const_obj_obj, BinaryCofan.ι_app_right, BinaryCofan.mk_inr] ext j simp only [colimit.ι_desc_assoc, Discrete.functor_obj, Cofan.mk_pt, Cofan.mk_ι_app, IsColimit.fac, Fin.cases_succ] · intro T f₁ f₂ f₃ m₁ m₂ simp at m₁ m₂ ⊢ refine Hc.uniq (Cofan.mk T (Fin.cases f₁ (fun i ↦ Sigma.ι (fun (j : Fin n) ↦ (Discrete.functor F').obj ⟨j.succ⟩) _ ≫ f₂))) _ ?_ intro ⟨j⟩ simp only [Discrete.functor_obj, Cofan.mk_pt, Functor.const_obj_obj, Cofan.mk_ι_app] induction' j using Fin.inductionOn with j _ · simp only [Fin.cases_zero, m₁] · simp only [← m₂, colimit.ι_desc_assoc, Discrete.functor_obj, Cofan.mk_pt, Cofan.mk_ι_app, Fin.cases_succ] induction' j using Fin.inductionOn with j _ · exact t₂' ⟨WalkingPair.left⟩ · have t₁' := (@t₁ (Discrete.functor (fun j ↦ F.obj ⟨j.succ⟩)) (Cofan.mk _ _) (Discrete.natTrans fun i ↦ α.app _) (Sigma.desc (fun j ↦ α.app _ ≫ c₁.inj _)) ?_ (NatTrans.equifibered_of_discrete _)).mp ⟨coproductIsCoproduct _⟩ ⟨j⟩ rotate_left · ext ⟨j⟩ dsimp rw [colimit.ι_desc] rfl simpa [Functor.const_obj_obj, Discrete.functor_obj, extendCofan_pt, extendCofan_ι_app, Fin.cases_succ, BinaryCofan.mk_pt, colimit.cocone_x, Cofan.mk_pt, Cofan.mk_ι_app, BinaryCofan.ι_app_right, BinaryCofan.mk_inr, colimit.ι_desc, Discrete.natTrans_app] using t₁'.paste_horiz (t₂' ⟨WalkingPair.right⟩) theorem isPullback_of_cofan_isVanKampen [HasInitial C] {ι : Type} {X : ι → C} {c : Cofan X} (hc : IsVanKampenColimit c) (i j : ι) [DecidableEq ι] : IsPullback (P := (if j = i then X i else ⊥_ C)) (if h : j = i then eqToHom (if_pos h) else eqToHom (if_neg h) ≫ initial.to (X i)) (if h : j = i then eqToHom ((if_pos h).trans (congr_arg X h.symm)) else eqToHom (if_neg h) ≫ initial.to (X j)) (Cofan.inj c i) (Cofan.inj c j) := by refine (hc (Cofan.mk (X i) (f := fun k ↦ if k = i then X i else ⊥_ C) (fun k ↦ if h : k = i then (eqToHom <\| if_pos h) else (eqToHom <\| if_neg h) ≫ initial.to _)) (Discrete.natTrans (fun k ↦ if h : k.1 = i then (eqToHom <\| (if_pos h).trans (congr_arg X h.symm)) else (eqToHom <\| if_neg h) ≫ initial.to _)) (c.inj i) ?_ (NatTrans.equifibered_of_discrete _)).mp ⟨?_⟩ ⟨j⟩ · ext ⟨k⟩ simp only [Discrete.functor_obj, Functor.const_obj_obj, NatTrans.comp_app, Discrete.natTrans_app, Cofan.mk_pt, Cofan.mk_ι_app, Functor.const_map_app] split · subst ‹k = i›; rfl · simp · refine mkCofanColimit _ (fun t ↦ (eqToHom (if_pos rfl).symm) ≫ t.inj i) ?_ ?_ · intro t j simp only [Cofan.mk_pt, cofan_mk_inj] split · subst ‹j = i›; simp · rw [Category.assoc, ← IsIso.eq_inv_comp] exact initialIsInitial.hom_ext _ _ · intro t m hm simp [← hm i] theorem isPullback_initial_to_of_cofan_isVanKampen [HasInitial C] {ι : Type} {F : Discrete ι ⥤ C} {c : Cocone F} (hc : IsVanKampenColimit c) (i j : Discrete ι) (hi : i ≠ j) : IsPullback (initial.to _) (initial.to _) (c.ι.app i) (c.ι.app j) := by classical let f : ι → C := F.obj ∘ Discrete.mk have : F = Discrete.functor f := Functor.hext (fun i ↦ rfl) (by rintro ⟨i⟩ ⟨j⟩ ⟨⟨rfl : i = j⟩⟩; simp [f]) clear_value f subst this have : ∀ i, Subsingleton (⊥_ C ⟶ (Discrete.functor f).obj i) := inferInstance convert isPullback_of_cofan_isVanKampen hc i.as j.as exact (if_neg (mt Discrete.ext hi.symm)).symm theorem mono_of_cofan_isVanKampen [HasInitial C] {ι : Type*} {F : Discrete ι ⥤ C} {c : Cocone F} (hc : IsVanKampenColimit c) (i : Discrete ι) : Mono (c.ι.app i) := by classical let f : ι → C := F.obj ∘ Discrete.mk have : F = Discrete.functor f := Functor.hext (fun i ↦ rfl) (by rintro ⟨i⟩ ⟨j⟩ ⟨⟨rfl : i = j⟩⟩; simp [f]) clear_value f subst this refine PullbackCone.mono_of_isLimitMkIdId _ (IsPullback.isLimit ?_) nth_rw 1 [← Category.id_comp (c.ι.app i)] convert IsPullback.paste_vert _ (isPullback_of_cofan_isVanKampen hc i.as i.as) swap · exact (eqToHom (if_pos rfl).symm) · simp · exact IsPullback.of_vert_isIso ⟨by simp⟩ end FiniteCoproducts end CategoryTheory		Mathlib/CategoryTheory/Limits/VanKampen.lean	770	784
/- Copyright (c) 2024 Christian Merten. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Christian Merten -/ import Mathlib.CategoryTheory.Limits.Constructions.LimitsOfProductsAndEqualizers import Mathlib.CategoryTheory.Limits.FintypeCat import Mathlib.CategoryTheory.Limits.MonoCoprod import Mathlib.CategoryTheory.Limits.Shapes.ConcreteCategory import Mathlib.CategoryTheory.Limits.Shapes.Diagonal import Mathlib.CategoryTheory.SingleObj import Mathlib.Data.Finite.Card import Mathlib.Algebra.Equiv.TransferInstance /-! # Definition and basic properties of Galois categories We define the notion of a Galois category and a fiber functor as in SGA1, following the definitions in Lenstras notes (see below for a reference). ## Main definitions * `PreGaloisCategory` : defining properties of Galois categories not involving a fiber functor * `FiberFunctor` : a fiber functor from a `PreGaloisCategory` to `FintypeCat` * `GaloisCategory` : a `PreGaloisCategory` that admits a `FiberFunctor` * `IsConnected` : an object of a category is connected if it is not initial and does not have non-trivial subobjects ## Implementation details We mostly follow Def 3.1 in Lenstras notes. In axiom (G3) we omit the factorisation of morphisms in epimorphisms and monomorphisms as this is not needed for the proof of the fundamental theorem on Galois categories (and then follows from it). ## References * [lenstraGSchemes]: H. W. Lenstra. Galois theory for schemes. -/ universe u₁ u₂ v₁ v₂ w t namespace CategoryTheory open Limits Functor /-! A category `C` is a PreGalois category if it satisfies all properties of a Galois category in the sense of SGA1 that do not involve a fiber functor. A Galois category should furthermore admit a fiber functor. The only difference between `[PreGaloisCategory C] (F : C ⥤ FintypeCat) [FiberFunctor F]` and `[GaloisCategory C]` is that the former fixes one fiber functor `F`. -/ /-- Definition of a (Pre)Galois category. Lenstra, Def 3.1, (G1)-(G3) -/ class PreGaloisCategory (C : Type u₁) [Category.{u₂, u₁} C] : Prop where /-- `C` has a terminal object (G1). -/ hasTerminal : HasTerminal C := by infer_instance /-- `C` has pullbacks (G1). -/ hasPullbacks : HasPullbacks C := by infer_instance /-- `C` has finite coproducts (G2). -/ hasFiniteCoproducts : HasFiniteCoproducts C := by infer_instance /-- `C` has quotients by finite groups (G2). -/ hasQuotientsByFiniteGroups (G : Type u₂) [Group G] [Finite G] : HasColimitsOfShape (SingleObj G) C := by infer_instance /-- Every monomorphism in `C` induces an isomorphism on a direct summand (G3). -/ monoInducesIsoOnDirectSummand {X Y : C} (i : X ⟶ Y) [Mono i] : ∃ (Z : C) (u : Z ⟶ Y), Nonempty (IsColimit (BinaryCofan.mk i u)) namespace PreGaloisCategory /-- Definition of a fiber functor from a Galois category. Lenstra, Def 3.1, (G4)-(G6) -/ class FiberFunctor {C : Type u₁} [Category.{u₂, u₁} C] [PreGaloisCategory C] (F : C ⥤ FintypeCat.{w}) where /-- `F` preserves terminal objects (G4). -/ preservesTerminalObjects : PreservesLimitsOfShape (CategoryTheory.Discrete PEmpty.{1}) F := by infer_instance /-- `F` preserves pullbacks (G4). -/ preservesPullbacks : PreservesLimitsOfShape WalkingCospan F := by infer_instance /-- `F` preserves finite coproducts (G5). -/ preservesFiniteCoproducts : PreservesFiniteCoproducts F := by infer_instance /-- `F` preserves epimorphisms (G5). -/ preservesEpis : Functor.PreservesEpimorphisms F := by infer_instance /-- `F` preserves quotients by finite groups (G5). -/ preservesQuotientsByFiniteGroups (G : Type u₂) [Group G] [Finite G] : PreservesColimitsOfShape (SingleObj G) F := by infer_instance /-- `F` reflects isomorphisms (G6). -/ reflectsIsos : F.ReflectsIsomorphisms := by infer_instance /-- An object of a category `C` is connected if it is not initial and has no non-trivial subobjects. Lenstra, 3.12. -/ class IsConnected {C : Type u₁} [Category.{u₂, u₁} C] (X : C) : Prop where /-- `X` is not an initial object. -/ notInitial : IsInitial X → False /-- `X` has no non-trivial subobjects. -/ noTrivialComponent (Y : C) (i : Y ⟶ X) [Mono i] : (IsInitial Y → False) → IsIso i /-- A functor is said to preserve connectedness if whenever `X : C` is connected, also `F.obj X` is connected. -/ class PreservesIsConnected {C : Type u₁} [Category.{u₂, u₁} C] {D : Type v₁} [Category.{v₂, v₁} D] (F : C ⥤ D) : Prop where /-- `F.obj X` is connected if `X` is connected. -/ preserves : ∀ {X : C} [IsConnected X], IsConnected (F.obj X) section variable {C : Type u₁} [Category.{u₂, u₁} C] [PreGaloisCategory C] attribute [instance] hasTerminal hasPullbacks hasFiniteCoproducts hasQuotientsByFiniteGroups instance : HasFiniteLimits C := hasFiniteLimits_of_hasTerminal_and_pullbacks instance : HasBinaryProducts C := hasBinaryProducts_of_hasTerminal_and_pullbacks C instance : HasEqualizers C := hasEqualizers_of_hasPullbacks_and_binary_products -- A `PreGaloisCategory` has quotients by finite groups in arbitrary universes. -/ instance {G : Type} [Group G] [Finite G] : HasColimitsOfShape (SingleObj G) C := by obtain ⟨G', hg, hf, ⟨e⟩⟩ := Finite.exists_type_univ_nonempty_mulEquiv G exact Limits.hasColimitsOfShape_of_equivalence e.toSingleObjEquiv.symm end namespace FiberFunctor variable {C : Type u₁} [Category.{u₂, u₁} C] {F : C ⥤ FintypeCat.{w}} [PreGaloisCategory C] [FiberFunctor F] attribute [instance] preservesTerminalObjects preservesPullbacks preservesEpis preservesFiniteCoproducts reflectsIsos preservesQuotientsByFiniteGroups noncomputable instance : ReflectsLimitsOfShape (Discrete PEmpty.{1}) F := reflectsLimitsOfShape_of_reflectsIsomorphisms noncomputable instance : ReflectsColimitsOfShape (Discrete PEmpty.{1}) F := reflectsColimitsOfShape_of_reflectsIsomorphisms noncomputable instance : PreservesFiniteLimits F := preservesFiniteLimits_of_preservesTerminal_and_pullbacks F /-- Fiber functors preserve quotients by finite groups in arbitrary universes. -/ instance {G : Type} [Group G] [Finite G] : PreservesColimitsOfShape (SingleObj G) F := by choose G' hg hf he using Finite.exists_type_univ_nonempty_mulEquiv G exact Limits.preservesColimitsOfShape_of_equiv he.some.toSingleObjEquiv.symm F /-- Fiber functors reflect monomorphisms. -/ instance : ReflectsMonomorphisms F := ReflectsMonomorphisms.mk <\| by intro X Y f _ haveI : IsIso (pullback.fst (F.map f) (F.map f)) := isIso_fst_of_mono (F.map f) haveI : IsIso (F.map (pullback.fst f f)) := by rw [← PreservesPullback.iso_hom_fst] exact IsIso.comp_isIso haveI : IsIso (pullback.fst f f) := isIso_of_reflects_iso (pullback.fst _ _) F exact (pullback.diagonal_isKernelPair f).mono_of_isIso_fst /-- Fiber functors are faithful. -/ instance : F.Faithful where map_injective {X Y} f g h := by haveI : IsIso (equalizer.ι (F.map f) (F.map g)) := equalizer.ι_of_eq h haveI : IsIso (F.map (equalizer.ι f g)) := by rw [← equalizerComparison_comp_π f g F] exact IsIso.comp_isIso haveI : IsIso (equalizer.ι f g) := isIso_of_reflects_iso _ F exact eq_of_epi_equalizer section /-- If `F` is a fiber functor and `E` is an equivalence between categories of finite types, then `F ⋙ E` is again a fiber functor. -/ lemma comp_right (E : FintypeCat.{w} ⥤ FintypeCat.{t}) [E.IsEquivalence] : FiberFunctor (F ⋙ E) where preservesQuotientsByFiniteGroups _ := comp_preservesColimitsOfShape F E end end FiberFunctor variable {C : Type u₁} [Category.{u₂, u₁} C] (F : C ⥤ FintypeCat.{w}) /-- The canonical action of `Aut F` on the fiber of each object. -/ instance (X : C) : MulAction (Aut F) (F.obj X) where smul σ x := σ.hom.app X x one_smul _ := rfl mul_smul _ _ _ := rfl lemma mulAction_def {X : C} (σ : Aut F) (x : F.obj X) : σ • x = σ.hom.app X x := rfl lemma mulAction_naturality {X Y : C} (σ : Aut F) (f : X ⟶ Y) (x : F.obj X) : σ • F.map f x = F.map f (σ • x) := FunctorToFintypeCat.naturality F F σ.hom f x /-- An object that is neither initial or connected has a non-trivial subobject. -/ lemma has_non_trivial_subobject_of_not_isConnected_of_not_initial (X : C) (hc : ¬ IsConnected X) (hi : IsInitial X → False) : ∃ (Y : C) (v : Y ⟶ X), (IsInitial Y → False) ∧ Mono v ∧ (¬ IsIso v) := by contrapose! hc exact ⟨hi, fun Y i hm hni ↦ hc Y i hni hm⟩ /-- The cardinality of the fiber is preserved under isomorphisms. -/ lemma card_fiber_eq_of_iso {X Y : C} (i : X ≅ Y) : Nat.card (F.obj X) = Nat.card (F.obj Y) := by have e : F.obj X ≃ F.obj Y := Iso.toEquiv (mapIso (F ⋙ FintypeCat.incl) i) exact Nat.card_eq_of_bijective e (Equiv.bijective e) variable [PreGaloisCategory C] [FiberFunctor F] /-- An object is initial if and only if its fiber is empty. -/ lemma initial_iff_fiber_empty (X : C) : Nonempty (IsInitial X) ↔ IsEmpty (F.obj X) := by rw [(IsInitial.isInitialIffObj F X).nonempty_congr] haveI : PreservesFiniteColimits (forget FintypeCat) := by show PreservesFiniteColimits FintypeCat.incl infer_instance haveI : ReflectsColimit (Functor.empty.{0} _) (forget FintypeCat) := by show ReflectsColimit (Functor.empty.{0} _) FintypeCat.incl infer_instance exact Concrete.initial_iff_empty_of_preserves_of_reflects (F.obj X) /-- An object is not initial if and only if its fiber is nonempty. -/ lemma not_initial_iff_fiber_nonempty (X : C) : (IsInitial X → False) ↔ Nonempty (F.obj X) := by rw [← not_isEmpty_iff] refine ⟨fun h he ↦ ?_, fun h hin ↦ h <\| (initial_iff_fiber_empty F X).mp ⟨hin⟩⟩ exact Nonempty.elim ((initial_iff_fiber_empty F X).mpr he) h /-- An object whose fiber is inhabited is not initial. -/ lemma not_initial_of_inhabited {X : C} (x : F.obj X) (h : IsInitial X) : False := ((initial_iff_fiber_empty F X).mp ⟨h⟩).false x /-- The fiber of a connected object is nonempty. -/ instance nonempty_fiber_of_isConnected (X : C) [IsConnected X] : Nonempty (F.obj X) := by by_contra h have ⟨hin⟩ : Nonempty (IsInitial X) := (initial_iff_fiber_empty F X).mpr (not_nonempty_iff.mp h) exact IsConnected.notInitial hin /-- The fiber of the equalizer of `f g : X ⟶ Y` is equivalent to the set of agreement of `f` and `g`. -/ noncomputable def fiberEqualizerEquiv {X Y : C} (f g : X ⟶ Y) : F.obj (equalizer f g) ≃ { x : F.obj X // F.map f x = F.map g x } := (PreservesEqualizer.iso (F ⋙ FintypeCat.incl) f g ≪≫ Types.equalizerIso (F.map f) (F.map g)).toEquiv @[simp] lemma fiberEqualizerEquiv_symm_ι_apply {X Y : C} {f g : X ⟶ Y} (x : F.obj X) (h : F.map f x = F.map g x) : F.map (equalizer.ι f g) ((fiberEqualizerEquiv F f g).symm ⟨x, h⟩) = x := by simp [fiberEqualizerEquiv] change ((Types.equalizerIso _ _).inv ≫ _ ≫ (F ⋙ FintypeCat.incl).map (equalizer.ι f g)) _ = _ erw [PreservesEqualizer.iso_inv_ι, Types.equalizerIso_inv_comp_ι] /-- The fiber of the pullback is the fiber product of the fibers. -/ noncomputable def fiberPullbackEquiv {X A B : C} (f : A ⟶ X) (g : B ⟶ X) : F.obj (pullback f g) ≃ { p : F.obj A × F.obj B // F.map f p.1 = F.map g p.2 } := (PreservesPullback.iso (F ⋙ FintypeCat.incl) f g ≪≫ Types.pullbackIsoPullback (F.map f) (F.map g)).toEquiv @[simp] lemma fiberPullbackEquiv_symm_fst_apply {X A B : C} {f : A ⟶ X} {g : B ⟶ X} (a : F.obj A) (b : F.obj B) (h : F.map f a = F.map g b) : F.map (pullback.fst f g) ((fiberPullbackEquiv F f g).symm ⟨(a, b), h⟩) = a := by simp [fiberPullbackEquiv] change ((Types.pullbackIsoPullback _ _).inv ≫ _ ≫ (F ⋙ FintypeCat.incl).map (pullback.fst f g)) _ = _ erw [PreservesPullback.iso_inv_fst, Types.pullbackIsoPullback_inv_fst] @[simp] lemma fiberPullbackEquiv_symm_snd_apply {X A B : C} {f : A ⟶ X} {g : B ⟶ X} (a : F.obj A) (b : F.obj B) (h : F.map f a = F.map g b) : F.map (pullback.snd f g) ((fiberPullbackEquiv F f g).symm ⟨(a, b), h⟩) = b := by simp [fiberPullbackEquiv] change ((Types.pullbackIsoPullback _ _).inv ≫ _ ≫ (F ⋙ FintypeCat.incl).map (pullback.snd f g)) _ = _ erw [PreservesPullback.iso_inv_snd, Types.pullbackIsoPullback_inv_snd] /-- The fiber of the binary product is the binary product of the fibers. -/ noncomputable def fiberBinaryProductEquiv (X Y : C) : F.obj (X ⨯ Y) ≃ F.obj X × F.obj Y := (PreservesLimitPair.iso (F ⋙ FintypeCat.incl) X Y ≪≫ Types.binaryProductIso (F.obj X) (F.obj Y)).toEquiv @[simp] lemma fiberBinaryProductEquiv_symm_fst_apply {X Y : C} (x : F.obj X) (y : F.obj Y) : F.map prod.fst ((fiberBinaryProductEquiv F X Y).symm (x, y)) = x := by simp only [fiberBinaryProductEquiv, comp_obj, FintypeCat.incl_obj, Iso.toEquiv_comp, Equiv.symm_trans_apply, Iso.toEquiv_symm_fun] change ((Types.binaryProductIso _ _).inv ≫ _ ≫ (F ⋙ FintypeCat.incl).map prod.fst) _ = _ erw [PreservesLimitPair.iso_inv_fst, Types.binaryProductIso_inv_comp_fst] @[simp] lemma fiberBinaryProductEquiv_symm_snd_apply {X Y : C} (x : F.obj X) (y : F.obj Y) : F.map prod.snd ((fiberBinaryProductEquiv F X Y).symm (x, y)) = y := by simp only [fiberBinaryProductEquiv, comp_obj, FintypeCat.incl_obj, Iso.toEquiv_comp, Equiv.symm_trans_apply, Iso.toEquiv_symm_fun] change ((Types.binaryProductIso _ _).inv ≫ _ ≫ (F ⋙ FintypeCat.incl).map prod.snd) _ = _ erw [PreservesLimitPair.iso_inv_snd, Types.binaryProductIso_inv_comp_snd] /-- The evaluation map is injective for connected objects. -/ lemma evaluation_injective_of_isConnected (A X : C) [IsConnected A] (a : F.obj A) : Function.Injective (fun (f : A ⟶ X) ↦ F.map f a) := by intro f g (h : F.map f a = F.map g a) haveI : IsIso (equalizer.ι f g) := by apply IsConnected.noTrivialComponent _ (equalizer.ι f g) exact not_initial_of_inhabited F ((fiberEqualizerEquiv F f g).symm ⟨a, h⟩) exact eq_of_epi_equalizer /-- The evaluation map on automorphisms is injective for connected objects. -/ lemma evaluation_aut_injective_of_isConnected (A : C) [IsConnected A] (a : F.obj A) : Function.Injective (fun f : Aut A ↦ F.map (f.hom) a) := by show Function.Injective ((fun f : A ⟶ A ↦ F.map f a) ∘ (fun f : Aut A ↦ f.hom)) apply Function.Injective.comp · exact evaluation_injective_of_isConnected F A A a · exact @Aut.ext _ _ A /-- A morphism from an object `X` with non-empty fiber to a connected object `A` is an epimorphism. -/ lemma epi_of_nonempty_of_isConnected {X A : C} [IsConnected A] [h : Nonempty (F.obj X)] (f : X ⟶ A) : Epi f := Epi.mk <\| fun {Z} u v huv ↦ by apply evaluation_injective_of_isConnected F A Z (F.map f (Classical.arbitrary _)) simpa using congr_fun (F.congr_map huv) _ /-- An epimorphism induces a surjective map on fibers. -/ lemma surjective_on_fiber_of_epi {X Y : C} (f : X ⟶ Y) [Epi f] : Function.Surjective (F.map f) := surjective_of_epi (FintypeCat.incl.map (F.map f)) /- A morphism from an object with non-empty fiber to a connected object is surjective on fibers. -/ lemma surjective_of_nonempty_fiber_of_isConnected {X A : C} [Nonempty (F.obj X)] [IsConnected A] (f : X ⟶ A) : Function.Surjective (F.map f) := by have : Epi f := epi_of_nonempty_of_isConnected F f exact surjective_on_fiber_of_epi F f /-- If `X : ι → C` is a finite family of objects with non-empty fiber, then also `∏ᶜ X` has non-empty fiber. -/ instance nonempty_fiber_pi_of_nonempty_of_finite {ι : Type*} [Finite ι] (X : ι → C) [∀ i, Nonempty (F.obj (X i))] : Nonempty (F.obj (∏ᶜ X)) := by cases nonempty_fintype ι	let f (i : ι) : FintypeCat.{w} := F.obj (X i) let i : F.obj (∏ᶜ X) ≅ ∏ᶜ f := PreservesProduct.iso F _ exact Nonempty.elim inferInstance fun x : (∏ᶜ f : FintypeCat.{w}) ↦ ⟨i.inv x⟩	Mathlib/CategoryTheory/Galois/Basic.lean	340	343
/- Copyright (c) 2014 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Leonardo de Moura, Jeremy Avigad -/ import Mathlib.Logic.Basic import Mathlib.Logic.Function.Defs import Mathlib.Order.Defs.LinearOrder /-! # Booleans This file proves various trivial lemmas about booleans and their relation to decidable propositions. ## Tags bool, boolean, Bool, De Morgan -/ namespace Bool section /-! This section contains lemmas about booleans which were present in core Lean 3. The remainder of this file contains lemmas about booleans from mathlib 3. -/ theorem true_eq_false_eq_False : ¬true = false := by decide theorem false_eq_true_eq_False : ¬false = true := by decide theorem eq_false_eq_not_eq_true (b : Bool) : (¬b = true) = (b = false) := by simp theorem eq_true_eq_not_eq_false (b : Bool) : (¬b = false) = (b = true) := by simp theorem eq_false_of_not_eq_true {b : Bool} : ¬b = true → b = false := Eq.mp (eq_false_eq_not_eq_true b) theorem eq_true_of_not_eq_false {b : Bool} : ¬b = false → b = true := Eq.mp (eq_true_eq_not_eq_false b) theorem and_eq_true_eq_eq_true_and_eq_true (a b : Bool) : ((a && b) = true) = (a = true ∧ b = true) := by simp theorem or_eq_true_eq_eq_true_or_eq_true (a b : Bool) : ((a \|\| b) = true) = (a = true ∨ b = true) := by simp theorem not_eq_true_eq_eq_false (a : Bool) : (not a = true) = (a = false) := by cases a <;> simp #adaptation_note /-- nightly-2024-03-05 this is no longer a simp lemma, as the LHS simplifies. -/ theorem and_eq_false_eq_eq_false_or_eq_false (a b : Bool) : ((a && b) = false) = (a = false ∨ b = false) := by cases a <;> cases b <;> simp		Mathlib/Data/Bool/Basic.lean	57	57
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl -/ import Mathlib.Data.Fintype.Card import Mathlib.Algebra.Order.BigOperators.Group.Multiset import Mathlib.Algebra.Order.Group.Nat import Mathlib.Data.Multiset.OrderedMonoid import Mathlib.Tactic.Bound.Attribute import Mathlib.Algebra.BigOperators.Group.Finset.Sigma import Mathlib.Data.Multiset.Powerset /-! # Big operators on a finset in ordered groups This file contains the results concerning the interaction of multiset big operators with ordered groups/monoids. -/ assert_not_exists Ring open Function variable {ι α β M N G k R : Type} namespace Finset section OrderedCommMonoid variable [CommMonoid M] [CommMonoid N] [PartialOrder N] [IsOrderedMonoid N] /-- Let `{x \| p x}` be a subsemigroup of a commutative monoid `M`. Let `f : M → N` be a map submultiplicative on `{x \| p x}`, i.e., `p x → p y → f (x y) ≤ f x * f y`. Let `g i`, `i ∈ s`, be a nonempty finite family of elements of `M` such that `∀ i ∈ s, p (g i)`. Then `f (∏ x ∈ s, g x) ≤ ∏ x ∈ s, f (g x)`. -/ @[to_additive le_sum_nonempty_of_subadditive_on_pred] theorem le_prod_nonempty_of_submultiplicative_on_pred (f : M → N) (p : M → Prop) (h_mul : ∀ x y, p x → p y → f (x * y) ≤ f x * f y) (hp_mul : ∀ x y, p x → p y → p (x * y)) (g : ι → M) (s : Finset ι) (hs_nonempty : s.Nonempty) (hs : ∀ i ∈ s, p (g i)) : f (∏ i ∈ s, g i) ≤ ∏ i ∈ s, f (g i) := by refine le_trans (Multiset.le_prod_nonempty_of_submultiplicative_on_pred f p h_mul hp_mul _ ?_ ?_) ?_ · simp [hs_nonempty.ne_empty] · exact Multiset.forall_mem_map_iff.mpr hs rw [Multiset.map_map] rfl /-- Let `{x \| p x}` be an additive subsemigroup of an additive commutative monoid `M`. Let `f : M → N` be a map subadditive on `{x \| p x}`, i.e., `p x → p y → f (x + y) ≤ f x + f y`. Let `g i`, `i ∈ s`, be a nonempty finite family of elements of `M` such that `∀ i ∈ s, p (g i)`. Then `f (∑ i ∈ s, g i) ≤ ∑ i ∈ s, f (g i)`. -/ add_decl_doc le_sum_nonempty_of_subadditive_on_pred /-- If `f : M → N` is a submultiplicative function, `f (x * y) ≤ f x * f y` and `g i`, `i ∈ s`, is a nonempty finite family of elements of `M`, then `f (∏ i ∈ s, g i) ≤ ∏ i ∈ s, f (g i)`. -/ @[to_additive le_sum_nonempty_of_subadditive] theorem le_prod_nonempty_of_submultiplicative (f : M → N) (h_mul : ∀ x y, f (x * y) ≤ f x * f y) {s : Finset ι} (hs : s.Nonempty) (g : ι → M) : f (∏ i ∈ s, g i) ≤ ∏ i ∈ s, f (g i) := le_prod_nonempty_of_submultiplicative_on_pred f (fun _ ↦ True) (fun x y _ _ ↦ h_mul x y) (fun _ _ _ _ ↦ trivial) g s hs fun _ _ ↦ trivial /-- If `f : M → N` is a subadditive function, `f (x + y) ≤ f x + f y` and `g i`, `i ∈ s`, is a nonempty finite family of elements of `M`, then `f (∑ i ∈ s, g i) ≤ ∑ i ∈ s, f (g i)`. -/ add_decl_doc le_sum_nonempty_of_subadditive /-- Let `{x \| p x}` be a subsemigroup of a commutative monoid `M`. Let `f : M → N` be a map such that `f 1 = 1` and `f` is submultiplicative on `{x \| p x}`, i.e., `p x → p y → f (x * y) ≤ f x * f y`. Let `g i`, `i ∈ s`, be a finite family of elements of `M` such that `∀ i ∈ s, p (g i)`. Then `f (∏ i ∈ s, g i) ≤ ∏ i ∈ s, f (g i)`. -/ @[to_additive le_sum_of_subadditive_on_pred] theorem le_prod_of_submultiplicative_on_pred (f : M → N) (p : M → Prop) (h_one : f 1 = 1) (h_mul : ∀ x y, p x → p y → f (x * y) ≤ f x * f y) (hp_mul : ∀ x y, p x → p y → p (x * y)) (g : ι → M) {s : Finset ι} (hs : ∀ i ∈ s, p (g i)) : f (∏ i ∈ s, g i) ≤ ∏ i ∈ s, f (g i) := by rcases eq_empty_or_nonempty s with (rfl \| hs_nonempty) · simp [h_one] · exact le_prod_nonempty_of_submultiplicative_on_pred f p h_mul hp_mul g s hs_nonempty hs /-- Let `{x \| p x}` be a subsemigroup of a commutative additive monoid `M`. Let `f : M → N` be a map such that `f 0 = 0` and `f` is subadditive on `{x \| p x}`, i.e. `p x → p y → f (x + y) ≤ f x + f y`. Let `g i`, `i ∈ s`, be a finite family of elements of `M` such that `∀ i ∈ s, p (g i)`. Then `f (∑ x ∈ s, g x) ≤ ∑ x ∈ s, f (g x)`. -/ add_decl_doc le_sum_of_subadditive_on_pred /-- If `f : M → N` is a submultiplicative function, `f (x * y) ≤ f x * f y`, `f 1 = 1`, and `g i`, `i ∈ s`, is a finite family of elements of `M`, then `f (∏ i ∈ s, g i) ≤ ∏ i ∈ s, f (g i)`. -/ @[to_additive le_sum_of_subadditive] theorem le_prod_of_submultiplicative (f : M → N) (h_one : f 1 = 1) (h_mul : ∀ x y, f (x * y) ≤ f x * f y) (s : Finset ι) (g : ι → M) : f (∏ i ∈ s, g i) ≤ ∏ i ∈ s, f (g i) := by refine le_trans (Multiset.le_prod_of_submultiplicative f h_one h_mul _) ?_ rw [Multiset.map_map] rfl /-- If `f : M → N` is a subadditive function, `f (x + y) ≤ f x + f y`, `f 0 = 0`, and `g i`, `i ∈ s`, is a finite family of elements of `M`, then `f (∑ i ∈ s, g i) ≤ ∑ i ∈ s, f (g i)`. -/ add_decl_doc le_sum_of_subadditive variable {f g : ι → N} {s t : Finset ι} /-- In an ordered commutative monoid, if each factor `f i` of one finite product is less than or equal to the corresponding factor `g i` of another finite product, then `∏ i ∈ s, f i ≤ ∏ i ∈ s, g i`. -/ @[to_additive (attr := gcongr) sum_le_sum] theorem prod_le_prod' (h : ∀ i ∈ s, f i ≤ g i) : ∏ i ∈ s, f i ≤ ∏ i ∈ s, g i := Multiset.prod_map_le_prod_map f g h attribute [bound] sum_le_sum /-- In an ordered additive commutative monoid, if each summand `f i` of one finite sum is less than or equal to the corresponding summand `g i` of another finite sum, then `∑ i ∈ s, f i ≤ ∑ i ∈ s, g i`. -/ add_decl_doc sum_le_sum @[to_additive sum_nonneg] theorem one_le_prod' (h : ∀ i ∈ s, 1 ≤ f i) : 1 ≤ ∏ i ∈ s, f i := le_trans (by rw [prod_const_one]) (prod_le_prod' h) @[to_additive Finset.sum_nonneg'] theorem one_le_prod'' (h : ∀ i : ι, 1 ≤ f i) : 1 ≤ ∏ i ∈ s, f i := Finset.one_le_prod' fun i _ ↦ h i @[to_additive sum_nonpos] theorem prod_le_one' (h : ∀ i ∈ s, f i ≤ 1) : ∏ i ∈ s, f i ≤ 1 := (prod_le_prod' h).trans_eq (by rw [prod_const_one]) @[to_additive (attr := gcongr) sum_le_sum_of_subset_of_nonneg] theorem prod_le_prod_of_subset_of_one_le' (h : s ⊆ t) (hf : ∀ i ∈ t, i ∉ s → 1 ≤ f i) : ∏ i ∈ s, f i ≤ ∏ i ∈ t, f i := by classical calc ∏ i ∈ s, f i ≤ (∏ i ∈ t \ s, f i) * ∏ i ∈ s, f i := le_mul_of_one_le_left' <\| one_le_prod' <\| by simpa only [mem_sdiff, and_imp] _ = ∏ i ∈ t \ s ∪ s, f i := (prod_union sdiff_disjoint).symm _ = ∏ i ∈ t, f i := by rw [sdiff_union_of_subset h] @[to_additive sum_mono_set_of_nonneg] theorem prod_mono_set_of_one_le' (hf : ∀ x, 1 ≤ f x) : Monotone fun s ↦ ∏ x ∈ s, f x := fun _ _ hst ↦ prod_le_prod_of_subset_of_one_le' hst fun x _ _ ↦ hf x @[to_additive sum_le_univ_sum_of_nonneg] theorem prod_le_univ_prod_of_one_le' [Fintype ι] {s : Finset ι} (w : ∀ x, 1 ≤ f x) : ∏ x ∈ s, f x ≤ ∏ x, f x := prod_le_prod_of_subset_of_one_le' (subset_univ s) fun a _ _ ↦ w a @[to_additive sum_eq_zero_iff_of_nonneg] theorem prod_eq_one_iff_of_one_le' : (∀ i ∈ s, 1 ≤ f i) → ((∏ i ∈ s, f i) = 1 ↔ ∀ i ∈ s, f i = 1) := by classical refine Finset.induction_on s (fun _ ↦ ⟨fun _ _ h ↦ False.elim (Finset.not_mem_empty _ h), fun _ ↦ rfl⟩) ?_ intro a s ha ih H have : ∀ i ∈ s, 1 ≤ f i := fun _ ↦ H _ ∘ mem_insert_of_mem rw [prod_insert ha, mul_eq_one_iff_of_one_le (H _ <\| mem_insert_self _ _) (one_le_prod' this), forall_mem_insert, ih this] @[to_additive sum_eq_zero_iff_of_nonpos] theorem prod_eq_one_iff_of_le_one' : (∀ i ∈ s, f i ≤ 1) → ((∏ i ∈ s, f i) = 1 ↔ ∀ i ∈ s, f i = 1) := prod_eq_one_iff_of_one_le' (N := Nᵒᵈ) @[to_additive single_le_sum] theorem single_le_prod' (hf : ∀ i ∈ s, 1 ≤ f i) {a} (h : a ∈ s) : f a ≤ ∏ x ∈ s, f x := calc f a = ∏ i ∈ {a}, f i := (prod_singleton _ _).symm _ ≤ ∏ i ∈ s, f i := prod_le_prod_of_subset_of_one_le' (singleton_subset_iff.2 h) fun i hi _ ↦ hf i hi @[to_additive] lemma mul_le_prod {i j : ι} (hf : ∀ i ∈ s, 1 ≤ f i) (hi : i ∈ s) (hj : j ∈ s) (hne : i ≠ j) : f i * f j ≤ ∏ k ∈ s, f k := calc f i * f j = ∏ k ∈ .cons i {j} (by simpa), f k := by rw [prod_cons, prod_singleton] _ ≤ ∏ k ∈ s, f k := by refine prod_le_prod_of_subset_of_one_le' ?_ fun k hk _ ↦ hf k hk simp [cons_subset, ] @[to_additive sum_le_card_nsmul] theorem prod_le_pow_card (s : Finset ι) (f : ι → N) (n : N) (h : ∀ x ∈ s, f x ≤ n) : s.prod f ≤ n ^ #s := by refine (Multiset.prod_le_pow_card (s.val.map f) n ?_).trans ?_ · simpa using h · simp @[to_additive card_nsmul_le_sum] theorem pow_card_le_prod (s : Finset ι) (f : ι → N) (n : N) (h : ∀ x ∈ s, n ≤ f x) : n ^ #s ≤ s.prod f := Finset.prod_le_pow_card (N := Nᵒᵈ) _ _ _ h theorem card_biUnion_le_card_mul [DecidableEq β] (s : Finset ι) (f : ι → Finset β) (n : ℕ) (h : ∀ a ∈ s, #(f a) ≤ n) : #(s.biUnion f) ≤ #s n := card_biUnion_le.trans <\| sum_le_card_nsmul _ _ _ h variable {ι' : Type} [DecidableEq ι'] @[to_additive sum_fiberwise_le_sum_of_sum_fiber_nonneg] theorem prod_fiberwise_le_prod_of_one_le_prod_fiber' {t : Finset ι'} {g : ι → ι'} {f : ι → N} (h : ∀ y ∉ t, (1 : N) ≤ ∏ x ∈ s with g x = y, f x) : (∏ y ∈ t, ∏ x ∈ s with g x = y, f x) ≤ ∏ x ∈ s, f x := calc (∏ y ∈ t, ∏ x ∈ s with g x = y, f x) ≤ ∏ y ∈ t ∪ s.image g, ∏ x ∈ s with g x = y, f x := prod_le_prod_of_subset_of_one_le' subset_union_left fun y _ ↦ h y _ = ∏ x ∈ s, f x := prod_fiberwise_of_maps_to (fun _ hx ↦ mem_union.2 <\| Or.inr <\| mem_image_of_mem _ hx) _ @[to_additive sum_le_sum_fiberwise_of_sum_fiber_nonpos] theorem prod_le_prod_fiberwise_of_prod_fiber_le_one' {t : Finset ι'} {g : ι → ι'} {f : ι → N} (h : ∀ y ∉ t, ∏ x ∈ s with g x = y, f x ≤ 1) : ∏ x ∈ s, f x ≤ ∏ y ∈ t, ∏ x ∈ s with g x = y, f x := prod_fiberwise_le_prod_of_one_le_prod_fiber' (N := Nᵒᵈ) h @[to_additive] lemma prod_image_le_of_one_le {g : ι → ι'} {f : ι' → N} (hf : ∀ u ∈ s.image g, 1 ≤ f u) : ∏ u ∈ s.image g, f u ≤ ∏ u ∈ s, f (g u) := by rw [prod_comp f g] refine prod_le_prod' fun a hag ↦ ?_ obtain ⟨i, hi, hig⟩ := Finset.mem_image.mp hag apply le_self_pow (hf a hag) rw [← Nat.pos_iff_ne_zero, card_pos] exact ⟨i, mem_filter.mpr ⟨hi, hig⟩⟩ end OrderedCommMonoid @[to_additive] lemma max_prod_le [CommMonoid M] [LinearOrder M] [IsOrderedMonoid M] {f g : ι → M} {s : Finset ι} : max (s.prod f) (s.prod g) ≤ s.prod (fun i ↦ max (f i) (g i)) := Multiset.max_prod_le @[to_additive] lemma prod_min_le [CommMonoid M] [LinearOrder M] [IsOrderedMonoid M] {f g : ι → M} {s : Finset ι} : s.prod (fun i ↦ min (f i) (g i)) ≤ min (s.prod f) (s.prod g) := Multiset.prod_min_le theorem abs_sum_le_sum_abs {G : Type} [AddCommGroup G] [LinearOrder G] [IsOrderedAddMonoid G] (f : ι → G) (s : Finset ι) : \|∑ i ∈ s, f i\| ≤ ∑ i ∈ s, \|f i\| := le_sum_of_subadditive _ abs_zero abs_add s f theorem abs_sum_of_nonneg {G : Type} [AddCommGroup G] [LinearOrder G] [IsOrderedAddMonoid G] {f : ι → G} {s : Finset ι} (hf : ∀ i ∈ s, 0 ≤ f i) : \|∑ i ∈ s, f i\| = ∑ i ∈ s, f i := by rw [abs_of_nonneg (Finset.sum_nonneg hf)] theorem abs_sum_of_nonneg' {G : Type} [AddCommGroup G] [LinearOrder G] [IsOrderedAddMonoid G] {f : ι → G} {s : Finset ι} (hf : ∀ i, 0 ≤ f i) : \|∑ i ∈ s, f i\| = ∑ i ∈ s, f i := by rw [abs_of_nonneg (Finset.sum_nonneg' hf)] section CommMonoid variable [CommMonoid α] [LE α] [MulLeftMono α] {s : Finset ι} {f : ι → α} @[to_additive (attr := simp)] lemma mulLECancellable_prod : MulLECancellable (∏ i ∈ s, f i) ↔ ∀ ⦃i⦄, i ∈ s → MulLECancellable (f i) := by induction' s using Finset.cons_induction with i s hi ih <;> simp [] end CommMonoid section Pigeonhole variable [DecidableEq β] theorem card_le_mul_card_image_of_maps_to {f : α → β} {s : Finset α} {t : Finset β} (Hf : ∀ a ∈ s, f a ∈ t) (n : ℕ) (hn : ∀ b ∈ t, #{a ∈ s \| f a = b} ≤ n) : #s ≤ n #t := calc #s = ∑ b ∈ t, #{a ∈ s \| f a = b} := card_eq_sum_card_fiberwise Hf _ ≤ ∑ _b ∈ t, n := sum_le_sum hn _ = _ := by simp [mul_comm] theorem card_le_mul_card_image {f : α → β} (s : Finset α) (n : ℕ) (hn : ∀ b ∈ s.image f, #{a ∈ s \| f a = b} ≤ n) : #s ≤ n * #(s.image f) := card_le_mul_card_image_of_maps_to (fun _ ↦ mem_image_of_mem _) n hn theorem mul_card_image_le_card_of_maps_to {f : α → β} {s : Finset α} {t : Finset β} (Hf : ∀ a ∈ s, f a ∈ t) (n : ℕ) (hn : ∀ b ∈ t, n ≤ #{a ∈ s \| f a = b}) : n * #t ≤ #s := calc n * #t = ∑ _a ∈ t, n := by simp [mul_comm] _ ≤ ∑ b ∈ t, #{a ∈ s \| f a = b} := sum_le_sum hn _ = #s := by rw [← card_eq_sum_card_fiberwise Hf] theorem mul_card_image_le_card {f : α → β} (s : Finset α) (n : ℕ) (hn : ∀ b ∈ s.image f, n ≤ #{a ∈ s \| f a = b}) : n * #(s.image f) ≤ #s := mul_card_image_le_card_of_maps_to (fun _ ↦ mem_image_of_mem _) n hn end Pigeonhole section DoubleCounting variable [DecidableEq α] {s : Finset α} {B : Finset (Finset α)} {n : ℕ} /-- If every element belongs to at most `n` Finsets, then the sum of their sizes is at most `n` times how many they are. -/ theorem sum_card_inter_le (h : ∀ a ∈ s, #{b ∈ B \| a ∈ b} ≤ n) : (∑ t ∈ B, #(s ∩ t)) ≤ #s * n := by refine le_trans ?_ (s.sum_le_card_nsmul _ _ h) simp_rw [← filter_mem_eq_inter, card_eq_sum_ones, sum_filter] exact sum_comm.le /-- If every element belongs to at most `n` Finsets, then the sum of their sizes is at most `n` times how many they are. -/ lemma sum_card_le [Fintype α] (h : ∀ a, #{b ∈ B \| a ∈ b} ≤ n) : ∑ s ∈ B, #s ≤ Fintype.card α * n := calc ∑ s ∈ B, #s = ∑ s ∈ B, #(univ ∩ s) := by simp_rw [univ_inter] _ ≤ Fintype.card α * n := sum_card_inter_le fun a _ ↦ h a /-- If every element belongs to at least `n` Finsets, then the sum of their sizes is at least `n` times how many they are. -/ theorem le_sum_card_inter (h : ∀ a ∈ s, n ≤ #{b ∈ B \| a ∈ b}) : #s * n ≤ ∑ t ∈ B, #(s ∩ t) := by apply (s.card_nsmul_le_sum _ _ h).trans simp_rw [← filter_mem_eq_inter, card_eq_sum_ones, sum_filter] exact sum_comm.le /-- If every element belongs to at least `n` Finsets, then the sum of their sizes is at least `n` times how many they are. -/ theorem le_sum_card [Fintype α] (h : ∀ a, n ≤ #{b ∈ B \| a ∈ b}) : Fintype.card α * n ≤ ∑ s ∈ B, #s := calc Fintype.card α * n ≤ ∑ s ∈ B, #(univ ∩ s) := le_sum_card_inter fun a _ ↦ h a _ = ∑ s ∈ B, #s := by simp_rw [univ_inter] /-- If every element belongs to exactly `n` Finsets, then the sum of their sizes is `n` times how many they are. -/ theorem sum_card_inter (h : ∀ a ∈ s, #{b ∈ B \| a ∈ b} = n) : (∑ t ∈ B, #(s ∩ t)) = #s * n := (sum_card_inter_le fun a ha ↦ (h a ha).le).antisymm (le_sum_card_inter fun a ha ↦ (h a ha).ge) /-- If every element belongs to exactly `n` Finsets, then the sum of their sizes is `n` times how many they are. -/ theorem sum_card [Fintype α] (h : ∀ a, #{b ∈ B \| a ∈ b} = n) : ∑ s ∈ B, #s = Fintype.card α * n := by simp_rw [Fintype.card, ← sum_card_inter fun a _ ↦ h a, univ_inter] theorem card_le_card_biUnion {s : Finset ι} {f : ι → Finset α} (hs : (s : Set ι).PairwiseDisjoint f) (hf : ∀ i ∈ s, (f i).Nonempty) : #s ≤ #(s.biUnion f) := by rw [card_biUnion hs, card_eq_sum_ones] exact sum_le_sum fun i hi ↦ (hf i hi).card_pos theorem card_le_card_biUnion_add_card_fiber {s : Finset ι} {f : ι → Finset α} (hs : (s : Set ι).PairwiseDisjoint f) : #s ≤ #(s.biUnion f) + #{i ∈ s \| f i = ∅} := by rw [← Finset.filter_card_add_filter_neg_card_eq_card fun i ↦ f i = ∅, add_comm] exact add_le_add_right ((card_le_card_biUnion (hs.subset <\| filter_subset _ _) fun i hi ↦ nonempty_of_ne_empty <\| (mem_filter.1 hi).2).trans <\| card_le_card <\| biUnion_subset_biUnion_of_subset_left _ <\| filter_subset _ _) _ theorem card_le_card_biUnion_add_one {s : Finset ι} {f : ι → Finset α} (hf : Injective f) (hs : (s : Set ι).PairwiseDisjoint f) : #s ≤ #(s.biUnion f) + 1 := (card_le_card_biUnion_add_card_fiber hs).trans <\| add_le_add_left (card_le_one.2 fun _ hi _ hj ↦ hf <\| (mem_filter.1 hi).2.trans (mem_filter.1 hj).2.symm) _ end DoubleCounting section CanonicallyOrderedMul variable [CommMonoid M] [PartialOrder M] [IsOrderedMonoid M] [CanonicallyOrderedMul M] {f : ι → M} {s t : Finset ι} /-- In a canonically-ordered monoid, a product bounds each of its terms. See also `Finset.single_le_prod'`. -/ @[to_additive "In a canonically-ordered additive monoid, a sum bounds each of its terms. See also `Finset.single_le_sum`."] lemma _root_.CanonicallyOrderedCommMonoid.single_le_prod {i : ι} (hi : i ∈ s) : f i ≤ ∏ j ∈ s, f j := single_le_prod' (fun _ _ ↦ one_le _) hi @[to_additive sum_le_sum_of_subset]	theorem prod_le_prod_of_subset' (h : s ⊆ t) : ∏ x ∈ s, f x ≤ ∏ x ∈ t, f x := prod_le_prod_of_subset_of_one_le' h fun _ _ _ ↦ one_le _ @[to_additive sum_mono_set] theorem prod_mono_set' (f : ι → M) : Monotone fun s ↦ ∏ x ∈ s, f x := fun _ _ hs ↦ prod_le_prod_of_subset' hs @[to_additive sum_le_sum_of_ne_zero] theorem prod_le_prod_of_ne_one' (h : ∀ x ∈ s, f x ≠ 1 → x ∈ t) : ∏ x ∈ s, f x ≤ ∏ x ∈ t, f x := by	Mathlib/Algebra/Order/BigOperators/Group/Finset.lean	371	380
/- Copyright (c) 2022 Yaël Dillies, Bhavik Mehta. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yaël Dillies, Bhavik Mehta -/ import Mathlib.Combinatorics.SimpleGraph.Regularity.Bound import Mathlib.Combinatorics.SimpleGraph.Regularity.Equitabilise import Mathlib.Combinatorics.SimpleGraph.Regularity.Uniform /-! # Chunk of the increment partition for Szemerédi Regularity Lemma In the proof of Szemerédi Regularity Lemma, we need to partition each part of a starting partition to increase the energy. This file defines those partitions of parts and shows that they locally increase the energy. This entire file is internal to the proof of Szemerédi Regularity Lemma. ## Main declarations * `SzemerediRegularity.chunk`: The partition of a part of the starting partition. * `SzemerediRegularity.edgeDensity_chunk_uniform`: `chunk` does not locally decrease the edge density between uniform parts too much. * `SzemerediRegularity.edgeDensity_chunk_not_uniform`: `chunk` locally increases the edge density between non-uniform parts. ## TODO Once ported to mathlib4, this file will be a great golfing ground for Heather's new tactic `gcongr`. ## References [Yaël Dillies, Bhavik Mehta, Formalising Szemerédi’s Regularity Lemma in Lean][srl_itp] -/ open Finpartition Finset Fintype Rel Nat open scoped SzemerediRegularity.Positivity namespace SzemerediRegularity variable {α : Type} [Fintype α] [DecidableEq α] {P : Finpartition (univ : Finset α)} (hP : P.IsEquipartition) (G : SimpleGraph α) [DecidableRel G.Adj] (ε : ℝ) {U : Finset α} (hU : U ∈ P.parts) (V : Finset α) local notation3 "m" => (card α / stepBound #P.parts : ℕ) /-! ### Definitions We define `chunk`, the partition of a part, and `star`, the sets of parts of `chunk` that are contained in the corresponding witness of non-uniformity. -/ /-- The portion of `SzemerediRegularity.increment` which partitions `U`. -/ noncomputable def chunk : Finpartition U := if hUcard : #U = m 4 ^ #P.parts + (card α / #P.parts - m * 4 ^ #P.parts) then (atomise U <\| P.nonuniformWitnesses G ε U).equitabilise <\| card_aux₁ hUcard else (atomise U <\| P.nonuniformWitnesses G ε U).equitabilise <\| card_aux₂ hP hU hUcard -- `hP` and `hU` are used to get that `U` has size -- `m * 4 ^ #P.parts + a or m * 4 ^ #P.parts + a + 1` /-- The portion of `SzemerediRegularity.chunk` which is contained in the witness of non-uniformity of `U` and `V`. -/ noncomputable def star (V : Finset α) : Finset (Finset α) := {A ∈ (chunk hP G ε hU).parts \| A ⊆ G.nonuniformWitness ε U V} /-! ### Density estimates We estimate the density between parts of `chunk`. -/ theorem biUnion_star_subset_nonuniformWitness : (star hP G ε hU V).biUnion id ⊆ G.nonuniformWitness ε U V := biUnion_subset_iff_forall_subset.2 fun _ hA => (mem_filter.1 hA).2 variable {hP G ε hU V} {𝒜 : Finset (Finset α)} {s : Finset α} theorem star_subset_chunk : star hP G ε hU V ⊆ (chunk hP G ε hU).parts := filter_subset _ _ private theorem card_nonuniformWitness_sdiff_biUnion_star (hV : V ∈ P.parts) (hUV : U ≠ V) (h₂ : ¬G.IsUniform ε U V) : #(G.nonuniformWitness ε U V \ (star hP G ε hU V).biUnion id) ≤ 2 ^ (#P.parts - 1) * m := by have hX : G.nonuniformWitness ε U V ∈ P.nonuniformWitnesses G ε U := nonuniformWitness_mem_nonuniformWitnesses h₂ hV hUV have q : G.nonuniformWitness ε U V \ (star hP G ε hU V).biUnion id ⊆ {B ∈ (atomise U <\| P.nonuniformWitnesses G ε U).parts \| B ⊆ G.nonuniformWitness ε U V ∧ B.Nonempty}.biUnion fun B => B \ {A ∈ (chunk hP G ε hU).parts \| A ⊆ B}.biUnion id := by intro x hx rw [← biUnion_filter_atomise hX (G.nonuniformWitness_subset h₂), star, mem_sdiff, mem_biUnion] at hx simp only [not_exists, mem_biUnion, and_imp, exists_prop, mem_filter, not_and, mem_sdiff, id, mem_sdiff] at hx ⊢ obtain ⟨⟨B, hB₁, hB₂⟩, hx⟩ := hx exact ⟨B, hB₁, hB₂, fun A hA AB => hx A hA <\| AB.trans hB₁.2.1⟩ apply (card_le_card q).trans (card_biUnion_le.trans _) trans ∑ B ∈ (atomise U <\| P.nonuniformWitnesses G ε U).parts with B ⊆ G.nonuniformWitness ε U V ∧ B.Nonempty, m · suffices ∀ B ∈ (atomise U <\| P.nonuniformWitnesses G ε U).parts, #(B \ {A ∈ (chunk hP G ε hU).parts \| A ⊆ B}.biUnion id) ≤ m by exact sum_le_sum fun B hB => this B <\| filter_subset _ _ hB intro B hB unfold chunk split_ifs with h₁ · convert card_parts_equitabilise_subset_le _ (card_aux₁ h₁) hB · convert card_parts_equitabilise_subset_le _ (card_aux₂ hP hU h₁) hB rw [sum_const] refine mul_le_mul_right' ?_ _ have t := card_filter_atomise_le_two_pow (s := U) hX refine t.trans (pow_right_mono₀ (by norm_num) <\| tsub_le_tsub_right ?_ _) exact card_image_le.trans (card_le_card <\| filter_subset _ _) private theorem one_sub_eps_mul_card_nonuniformWitness_le_card_star (hV : V ∈ P.parts) (hUV : U ≠ V) (hunif : ¬G.IsUniform ε U V) (hPε : ↑100 ≤ ↑4 ^ #P.parts * ε ^ 5) (hε₁ : ε ≤ 1) : (1 - ε / 10) * #(G.nonuniformWitness ε U V) ≤ #((star hP G ε hU V).biUnion id) := by have hP₁ : 0 < #P.parts := Finset.card_pos.2 ⟨_, hU⟩ have : (↑2 ^ #P.parts : ℝ) * m / (#U * ε) ≤ ε / 10 := by rw [← div_div, div_le_iff₀'] swap · sz_positivity refine le_of_mul_le_mul_left ?_ (pow_pos zero_lt_two #P.parts) calc ↑2 ^ #P.parts * ((↑2 ^ #P.parts * m : ℝ) / #U) = ((2 : ℝ) * 2) ^ #P.parts * m / #U := by rw [mul_pow, ← mul_div_assoc, mul_assoc] _ = ↑4 ^ #P.parts * m / #U := by norm_num _ ≤ 1 := div_le_one_of_le₀ (pow_mul_m_le_card_part hP hU) (cast_nonneg _) _ ≤ ↑2 ^ #P.parts * ε ^ 2 / 10 := by refine (one_le_sq_iff₀ <\| by positivity).1 ?_ rw [div_pow, mul_pow, pow_right_comm, ← pow_mul ε, one_le_div (sq_pos_of_ne_zero <\| by norm_num)] calc (↑10 ^ 2) = 100 := by norm_num _ ≤ ↑4 ^ #P.parts * ε ^ 5 := hPε _ ≤ ↑4 ^ #P.parts * ε ^ 4 := (mul_le_mul_of_nonneg_left (pow_le_pow_of_le_one (by sz_positivity) hε₁ <\| le_succ _) (by positivity)) _ = (↑2 ^ 2) ^ #P.parts * ε ^ (2 * 2) := by norm_num _ = ↑2 ^ #P.parts * (ε * (ε / 10)) := by rw [mul_div_assoc, sq, mul_div_assoc] calc (↑1 - ε / 10) * #(G.nonuniformWitness ε U V) ≤ (↑1 - ↑2 ^ #P.parts * m / (#U * ε)) * #(G.nonuniformWitness ε U V) := mul_le_mul_of_nonneg_right (sub_le_sub_left this _) (cast_nonneg _) _ = #(G.nonuniformWitness ε U V) - ↑2 ^ #P.parts * m / (#U * ε) * #(G.nonuniformWitness ε U V) := by rw [sub_mul, one_mul] _ ≤ #(G.nonuniformWitness ε U V) - ↑2 ^ (#P.parts - 1) * m := by refine sub_le_sub_left ?_ _ have : (2 : ℝ) ^ #P.parts = ↑2 ^ (#P.parts - 1) * 2 := by rw [← _root_.pow_succ, tsub_add_cancel_of_le (succ_le_iff.2 hP₁)] rw [← mul_div_right_comm, this, mul_right_comm _ (2 : ℝ), mul_assoc, le_div_iff₀] · refine mul_le_mul_of_nonneg_left ?_ (by positivity) exact (G.le_card_nonuniformWitness hunif).trans (le_mul_of_one_le_left (cast_nonneg _) one_le_two) have := Finset.card_pos.mpr (P.nonempty_of_mem_parts hU) sz_positivity _ ≤ #((star hP G ε hU V).biUnion id) := by rw [sub_le_comm, ← cast_sub (card_le_card <\| biUnion_star_subset_nonuniformWitness hP G ε hU V), ← card_sdiff (biUnion_star_subset_nonuniformWitness hP G ε hU V)] exact mod_cast card_nonuniformWitness_sdiff_biUnion_star hV hUV hunif /-! ### `chunk` -/ theorem card_chunk (hm : m ≠ 0) : #(chunk hP G ε hU).parts = 4 ^ #P.parts := by unfold chunk split_ifs · rw [card_parts_equitabilise _ _ hm, tsub_add_cancel_of_le] exact le_of_lt a_add_one_le_four_pow_parts_card · rw [card_parts_equitabilise _ _ hm, tsub_add_cancel_of_le a_add_one_le_four_pow_parts_card] theorem card_eq_of_mem_parts_chunk (hs : s ∈ (chunk hP G ε hU).parts) : #s = m ∨ #s = m + 1 := by unfold chunk at hs split_ifs at hs <;> exact card_eq_of_mem_parts_equitabilise hs theorem m_le_card_of_mem_chunk_parts (hs : s ∈ (chunk hP G ε hU).parts) : m ≤ #s := (card_eq_of_mem_parts_chunk hs).elim ge_of_eq fun i => by simp [i] theorem card_le_m_add_one_of_mem_chunk_parts (hs : s ∈ (chunk hP G ε hU).parts) : #s ≤ m + 1 := (card_eq_of_mem_parts_chunk hs).elim (fun i => by simp [i]) fun i => i.le theorem card_biUnion_star_le_m_add_one_card_star_mul : (#((star hP G ε hU V).biUnion id) : ℝ) ≤ #(star hP G ε hU V) * (m + 1) := mod_cast card_biUnion_le_card_mul _ _ _ fun _ hs => card_le_m_add_one_of_mem_chunk_parts <\| star_subset_chunk hs private theorem le_sum_card_subset_chunk_parts (h𝒜 : 𝒜 ⊆ (chunk hP G ε hU).parts) (hs : s ∈ 𝒜) : (#𝒜 : ℝ) * #s * (m / (m + 1)) ≤ #(𝒜.sup id) := by rw [mul_div_assoc', div_le_iff₀ coe_m_add_one_pos, mul_right_comm] refine mul_le_mul ?_ ?_ (cast_nonneg _) (cast_nonneg _) · rw [← (ofSubset _ h𝒜 rfl).sum_card_parts, ofSubset_parts, ← cast_mul, cast_le] exact card_nsmul_le_sum _ _ _ fun x hx => m_le_card_of_mem_chunk_parts <\| h𝒜 hx · exact mod_cast card_le_m_add_one_of_mem_chunk_parts (h𝒜 hs) private theorem sum_card_subset_chunk_parts_le (m_pos : (0 : ℝ) < m) (h𝒜 : 𝒜 ⊆ (chunk hP G ε hU).parts) (hs : s ∈ 𝒜) : (#(𝒜.sup id) : ℝ) ≤ #𝒜 * #s * ((m + 1) / m) := by rw [sup_eq_biUnion, mul_div_assoc', le_div_iff₀ m_pos, mul_right_comm] refine mul_le_mul ?_ ?_ (cast_nonneg _) (by positivity) · norm_cast refine card_biUnion_le_card_mul _ _ _ fun x hx => ?_ apply card_le_m_add_one_of_mem_chunk_parts (h𝒜 hx) · exact mod_cast m_le_card_of_mem_chunk_parts (h𝒜 hs) private theorem one_sub_le_m_div_m_add_one_sq [Nonempty α] (hPα : #P.parts * 16 ^ #P.parts ≤ card α) (hPε : ↑100 ≤ ↑4 ^ #P.parts * ε ^ 5) :	↑1 - ε ^ 5 / ↑50 ≤ (m / (m + 1 : ℝ)) ^ 2 := by have : (m : ℝ) / (m + 1) = 1 - 1 / (m + 1) := by rw [one_sub_div coe_m_add_one_pos.ne', add_sub_cancel_right] rw [this, sub_sq, one_pow, mul_one] refine le_trans ?_ (le_add_of_nonneg_right <\| sq_nonneg _) rw [sub_le_sub_iff_left, ← le_div_iff₀' (show (0 : ℝ) < 2 by norm_num), div_div, one_div_le coe_m_add_one_pos, one_div_div] · refine le_trans ?_ (le_add_of_nonneg_right zero_le_one) norm_num	Mathlib/Combinatorics/SimpleGraph/Regularity/Chunk.lean	216	224
/- Copyright (c) 2022 Jakob von Raumer. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jakob von Raumer, Kevin Klinge, Andrew Yang -/ import Mathlib.Algebra.Group.Submonoid.DistribMulAction import Mathlib.GroupTheory.OreLocalization.Basic import Mathlib.Algebra.GroupWithZero.Defs /-! # Localization over left Ore sets. This file proves results on the localization of rings (monoids with zeros) over a left Ore set. ## References * <https://ncatlab.org/nlab/show/Ore+localization> * [Zoran Škoda, Noncommutative localization in noncommutative geometry][skoda2006] ## Tags localization, Ore, non-commutative -/ assert_not_exists RelIso universe u open OreLocalization namespace OreLocalization section MonoidWithZero variable {R : Type} [MonoidWithZero R] {S : Submonoid R} [OreSet S] @[simp] theorem zero_oreDiv' (s : S) : (0 : R) /ₒ s = 0 := by rw [OreLocalization.zero_def, oreDiv_eq_iff] exact ⟨s, 1, by simp [Submonoid.smul_def]⟩ instance : MonoidWithZero R[S⁻¹] where zero_mul x := by induction' x using OreLocalization.ind with r s rw [OreLocalization.zero_def, oreDiv_mul_char 0 r 1 s 0 1 (by simp), zero_mul, one_mul] mul_zero x := by induction' x using OreLocalization.ind with r s rw [OreLocalization.zero_def, mul_div_one, mul_zero, zero_oreDiv', zero_oreDiv'] end MonoidWithZero section CommMonoidWithZero variable {R : Type} [CommMonoidWithZero R] {S : Submonoid R} [OreSet S] instance : CommMonoidWithZero R[S⁻¹] where __ := inferInstanceAs (MonoidWithZero R[S⁻¹]) __ := inferInstanceAs (CommMonoid R[S⁻¹]) end CommMonoidWithZero section DistribMulAction variable {R : Type} [Monoid R] {S : Submonoid R} [OreSet S] {X : Type} [AddMonoid X] variable [DistribMulAction R X] private def add'' (r₁ : X) (s₁ : S) (r₂ : X) (s₂ : S) : X[S⁻¹] := (oreDenom (s₁ : R) s₂ • r₁ + oreNum (s₁ : R) s₂ • r₂) /ₒ (oreDenom (s₁ : R) s₂ * s₁) private theorem add''_char (r₁ : X) (s₁ : S) (r₂ : X) (s₂ : S) (rb : R) (sb : R) (hb : sb * s₁ = rb * s₂) (h : sb * s₁ ∈ S) : add'' r₁ s₁ r₂ s₂ = (sb • r₁ + rb • r₂) /ₒ ⟨sb * s₁, h⟩ := by simp only [add''] have ha := ore_eq (s₁ : R) s₂ generalize oreNum (s₁ : R) s₂ = ra at * generalize oreDenom (s₁ : R) s₂ = sa at * rw [oreDiv_eq_iff] rcases oreCondition sb sa with ⟨rc, sc, hc⟩ have : sc * rb * s₂ = rc * ra * s₂ := by rw [mul_assoc rc, ← ha, ← mul_assoc, ← hc, mul_assoc, mul_assoc, hb] rcases ore_right_cancel _ _ s₂ this with ⟨sd, hd⟩ use sd * sc use sd * rc simp only [smul_add, smul_smul, Submonoid.smul_def, Submonoid.coe_mul] constructor · rw [mul_assoc _ _ rb, hd, mul_assoc, hc, mul_assoc, mul_assoc] · rw [mul_assoc, ← mul_assoc (sc : R), hc, mul_assoc, mul_assoc] attribute [local instance] OreLocalization.oreEqv private def add' (r₂ : X) (s₂ : S) : X[S⁻¹] → X[S⁻¹] := (--plus tilde Quotient.lift fun r₁s₁ : X × S => add'' r₁s₁.1 r₁s₁.2 r₂ s₂) <\| by -- Porting note: `assoc_rw` & `noncomm_ring` were not ported yet rintro ⟨r₁', s₁'⟩ ⟨r₁, s₁⟩ ⟨sb, rb, hb, hb'⟩ -- s, r rcases oreCondition (s₁' : R) s₂ with ⟨rc, sc, hc⟩ --s~~, r~~ rcases oreCondition rb sc with ⟨rd, sd, hd⟩ -- s#, r# dsimp at * rw [add''_char _ _ _ _ rc sc hc (sc * s₁').2] have : sd * sb * s₁ = rd * rc * s₂ := by rw [mul_assoc, hb', ← mul_assoc, hd, mul_assoc, hc, ← mul_assoc] rw [add''_char _ _ _ _ (rd * rc : R) (sd * sb) this (sd * sb * s₁).2] rw [mul_smul, ← Submonoid.smul_def sb, hb, smul_smul, hd, oreDiv_eq_iff] use 1 use rd simp only [mul_smul, smul_add, one_smul, OneMemClass.coe_one, one_mul, true_and] rw [this, hc, mul_assoc] /-- The addition on the Ore localization. -/ @[irreducible] private def add : X[S⁻¹] → X[S⁻¹] → X[S⁻¹] := fun x => Quotient.lift (fun rs : X × S => add' rs.1 rs.2 x) (by rintro ⟨r₁, s₁⟩ ⟨r₂, s₂⟩ ⟨sb, rb, hb, hb'⟩ induction' x with r₃ s₃ show add'' _ _ _ _ = add'' _ _ _ _ dsimp only at * rcases oreCondition (s₃ : R) s₂ with ⟨rc, sc, hc⟩ rcases oreCondition rc sb with ⟨rd, sd, hd⟩ have : rd * rb * s₁ = sd * sc * s₃ := by rw [mul_assoc, ← hb', ← mul_assoc, ← hd, mul_assoc, ← hc, mul_assoc] rw [add''_char _ _ _ _ rc sc hc (sc * s₃).2] rw [add''_char _ _ _ _ _ _ this.symm (sd * sc * s₃).2] refine oreDiv_eq_iff.mpr ?_ simp only [Submonoid.mk_smul, smul_add] use sd, 1 simp only [one_smul, one_mul, mul_smul, ← hb, Submonoid.smul_def, ← mul_assoc, and_true] simp only [smul_smul, hd]) instance : Add X[S⁻¹] := ⟨add⟩ theorem oreDiv_add_oreDiv {r r' : X} {s s' : S} : r /ₒ s + r' /ₒ s' = (oreDenom (s : R) s' • r + oreNum (s : R) s' • r') /ₒ (oreDenom (s : R) s' * s) := by with_unfolding_all rfl theorem oreDiv_add_char' {r r' : X} (s s' : S) (rb : R) (sb : R) (h : sb * s = rb * s') (h' : sb * s ∈ S) : r /ₒ s + r' /ₒ s' = (sb • r + rb • r') /ₒ ⟨sb * s, h'⟩ := by with_unfolding_all exact add''_char r s r' s' rb sb h h' /-- A characterization of the addition on the Ore localizaion, allowing for arbitrary Ore numerator and Ore denominator. -/ theorem oreDiv_add_char {r r' : X} (s s' : S) (rb : R) (sb : S) (h : sb * s = rb * s') : r /ₒ s + r' /ₒ s' = (sb • r + rb • r') /ₒ (sb * s) := oreDiv_add_char' s s' rb sb h (sb * s).2 /-- Another characterization of the addition on the Ore localization, bundling up all witnesses and conditions into a sigma type. -/ def oreDivAddChar' (r r' : X) (s s' : S) : Σ'r'' : R, Σ's'' : S, s'' * s = r'' * s' ∧ r /ₒ s + r' /ₒ s' = (s'' • r + r'' • r') /ₒ (s'' * s) := ⟨oreNum (s : R) s', oreDenom (s : R) s', ore_eq (s : R) s', oreDiv_add_oreDiv⟩ @[simp] theorem add_oreDiv {r r' : X} {s : S} : r /ₒ s + r' /ₒ s = (r + r') /ₒ s := by simp [oreDiv_add_char s s 1 1 (by simp)] protected theorem add_assoc (x y z : X[S⁻¹]) : x + y + z = x + (y + z) := by induction' x with r₁ s₁ induction' y with r₂ s₂ induction' z with r₃ s₃ rcases oreDivAddChar' r₁ r₂ s₁ s₂ with ⟨ra, sa, ha, ha'⟩; rw [ha']; clear ha' rcases oreDivAddChar' (sa • r₁ + ra • r₂) r₃ (sa * s₁) s₃ with ⟨rc, sc, hc, q⟩; rw [q]; clear q simp only [smul_add, mul_assoc, add_assoc] simp_rw [← add_oreDiv, ← OreLocalization.expand'] congr 2 · rw [OreLocalization.expand r₂ s₂ ra (ha.symm ▸ (sa * s₁).2)]; congr; ext; exact ha · rw [OreLocalization.expand r₃ s₃ rc (hc.symm ▸ (sc * (sa * s₁)).2)]; congr; ext; exact hc @[simp] theorem zero_oreDiv (s : S) : (0 : X) /ₒ s = 0 := by rw [OreLocalization.zero_def, oreDiv_eq_iff] exact ⟨s, 1, by simp⟩ protected theorem zero_add (x : X[S⁻¹]) : 0 + x = x := by induction x rw [← zero_oreDiv, add_oreDiv]; simp protected theorem add_zero (x : X[S⁻¹]) : x + 0 = x := by induction x rw [← zero_oreDiv, add_oreDiv]; simp @[irreducible] private def nsmul : ℕ → X[S⁻¹] → X[S⁻¹] := nsmulRec instance : AddMonoid X[S⁻¹] where add_assoc := OreLocalization.add_assoc zero_add := OreLocalization.zero_add add_zero := OreLocalization.add_zero nsmul := nsmul nsmul_zero _ := by with_unfolding_all rfl nsmul_succ _ _ := by with_unfolding_all rfl protected theorem smul_zero (x : R[S⁻¹]) : x • (0 : X[S⁻¹]) = 0 := by induction' x with r s rw [OreLocalization.zero_def, smul_div_one, smul_zero, zero_oreDiv, zero_oreDiv] protected theorem smul_add (z : R[S⁻¹]) (x y : X[S⁻¹]) : z • (x + y) = z • x + z • y := by induction' x with r₁ s₁ induction' y with r₂ s₂ induction' z with r₃ s₃ rcases oreDivAddChar' r₁ r₂ s₁ s₂ with ⟨ra, sa, ha, ha'⟩; rw [ha']; clear ha'; norm_cast at ha rw [OreLocalization.expand' r₁ s₁ sa] rw [OreLocalization.expand r₂ s₂ ra (by rw [← ha]; apply SetLike.coe_mem)] rw [← Subtype.coe_eq_of_eq_mk ha] repeat rw [oreDiv_smul_oreDiv] simp only [smul_add, add_oreDiv] instance : DistribMulAction R[S⁻¹] X[S⁻¹] where smul_zero := OreLocalization.smul_zero smul_add := OreLocalization.smul_add instance {R₀} [Monoid R₀] [MulAction R₀ X] [MulAction R₀ R] [IsScalarTower R₀ R X] [IsScalarTower R₀ R R] : DistribMulAction R₀ X[S⁻¹] where smul_zero _ := by rw [← smul_one_oreDiv_one_smul, smul_zero] smul_add _ _ _ := by simp only [← smul_one_oreDiv_one_smul, smul_add] end DistribMulAction section AddCommMonoid variable {R : Type} [Monoid R] {S : Submonoid R} [OreSet S] variable {X : Type} [AddCommMonoid X] [DistribMulAction R X] protected theorem add_comm (x y : X[S⁻¹]) : x + y = y + x := by induction' x with r s induction' y with r' s' rcases oreDivAddChar' r r' s s' with ⟨ra, sa, ha, ha'⟩ rw [ha', oreDiv_add_char' s' s _ _ ha.symm (ha ▸ (sa * s).2), add_comm] congr; ext; exact ha instance instAddCommMonoidOreLocalization : AddCommMonoid X[S⁻¹] where add_comm := OreLocalization.add_comm end AddCommMonoid section AddGroup variable {R : Type} [Monoid R] {S : Submonoid R} [OreSet S] variable {X : Type} [AddGroup X] [DistribMulAction R X] /-- Negation on the Ore localization is defined via negation on the numerator. -/ @[irreducible] protected def neg : X[S⁻¹] → X[S⁻¹] := liftExpand (fun (r : X) (s : S) => -r /ₒ s) fun r t s ht => by -- Porting note (https://github.com/leanprover-community/mathlib4/issues/12129): additional beta reduction needed beta_reduce rw [← smul_neg, ← OreLocalization.expand] instance instNegOreLocalization : Neg X[S⁻¹] := ⟨OreLocalization.neg⟩ @[simp] protected theorem neg_def (r : X) (s : S) : -(r /ₒ s) = -r /ₒ s := by with_unfolding_all rfl protected theorem neg_add_cancel (x : X[S⁻¹]) : -x + x = 0 := by induction' x with r s; simp /-- `zsmul` of `OreLocalization` -/ @[irreducible] protected def zsmul : ℤ → X[S⁻¹] → X[S⁻¹] := zsmulRec unseal OreLocalization.zsmul in instance instAddGroupOreLocalization : AddGroup X[S⁻¹] where neg_add_cancel := OreLocalization.neg_add_cancel zsmul := OreLocalization.zsmul end AddGroup section AddCommGroup variable {R : Type} [Monoid R] {S : Submonoid R} [OreSet S] variable {X : Type} [AddCommGroup X] [DistribMulAction R X] instance : AddCommGroup X[S⁻¹] where __ := inferInstanceAs (AddGroup X[S⁻¹]) __ := inferInstanceAs (AddCommMonoid X[S⁻¹]) end AddCommGroup end OreLocalization		Mathlib/RingTheory/OreLocalization/Basic.lean	595	612
/- Copyright (c) 2020 Aaron Anderson. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Aaron Anderson -/ import Mathlib.FieldTheory.SplittingField.Construction import Mathlib.RingTheory.Localization.Integral import Mathlib.RingTheory.IntegralClosure.IntegrallyClosed import Mathlib.RingTheory.Polynomial.Content /-! # Gauss's Lemma Gauss's Lemma is one of a few results pertaining to irreducibility of primitive polynomials. ## Main Results - `IsIntegrallyClosed.eq_map_mul_C_of_dvd`: if `R` is integrally closed, `K = Frac(R)` and `g : K[X]` divides a monic polynomial with coefficients in `R`, then `g * (C g.leadingCoeff⁻¹)` has coefficients in `R` - `Polynomial.Monic.irreducible_iff_irreducible_map_fraction_map`: A monic polynomial over an integrally closed domain is irreducible iff it is irreducible in a fraction field - `isIntegrallyClosed_iff'`: Integrally closed domains are precisely the domains for in which Gauss's lemma holds for monic polynomials - `Polynomial.IsPrimitive.irreducible_iff_irreducible_map_fraction_map`: A primitive polynomial over a GCD domain is irreducible iff it is irreducible in a fraction field - `Polynomial.IsPrimitive.Int.irreducible_iff_irreducible_map_cast`: A primitive polynomial over `ℤ` is irreducible iff it is irreducible over `ℚ`. - `Polynomial.IsPrimitive.dvd_iff_fraction_map_dvd_fraction_map`: Two primitive polynomials over a GCD domain divide each other iff they do in a fraction field. - `Polynomial.IsPrimitive.Int.dvd_iff_map_cast_dvd_map_cast`: Two primitive polynomials over `ℤ` divide each other if they do in `ℚ`. -/ open scoped nonZeroDivisors Polynomial variable {R : Type} [CommRing R] section IsIntegrallyClosed open Polynomial open integralClosure open IsIntegrallyClosed variable (K : Type) [Field K] [Algebra R K] theorem integralClosure.mem_lifts_of_monic_of_dvd_map {f : R[X]} (hf : f.Monic) {g : K[X]} (hg : g.Monic) (hd : g ∣ f.map (algebraMap R K)) : g ∈ lifts (algebraMap (integralClosure R K) K) := by have := mem_lift_of_splits_of_roots_mem_range (integralClosure R g.SplittingField) ((splits_id_iff_splits _).2 <\| SplittingField.splits g) (hg.map _) fun a ha => (SetLike.ext_iff.mp (integralClosure R g.SplittingField).range_algebraMap _).mpr <\| roots_mem_integralClosure hf ?_ · rw [lifts_iff_coeff_lifts, ← RingHom.coe_range, Subalgebra.range_algebraMap] at this refine (lifts_iff_coeff_lifts _).2 fun n => ?_ rw [← RingHom.coe_range, Subalgebra.range_algebraMap] obtain ⟨p, hp, he⟩ := SetLike.mem_coe.mp (this n); use p, hp rw [IsScalarTower.algebraMap_eq R K, coeff_map, ← eval₂_map, eval₂_at_apply] at he rw [eval₂_eq_eval_map]; apply (injective_iff_map_eq_zero _).1 _ _ he apply RingHom.injective rw [aroots_def, IsScalarTower.algebraMap_eq R K _, ← map_map] refine Multiset.mem_of_le (roots.le_of_dvd ((hf.map _).map _).ne_zero ?_) ha exact map_dvd (algebraMap K g.SplittingField) hd variable [IsFractionRing R K] /-- If `K = Frac(R)` and `g : K[X]` divides a monic polynomial with coefficients in `R`, then `g * (C g.leadingCoeff⁻¹)` has coefficients in `R` -/ theorem IsIntegrallyClosed.eq_map_mul_C_of_dvd [IsIntegrallyClosed R] {f : R[X]} (hf : f.Monic) {g : K[X]} (hg : g ∣ f.map (algebraMap R K)) : ∃ g' : R[X], g'.map (algebraMap R K) * (C <\| leadingCoeff g) = g := by have g_ne_0 : g ≠ 0 := ne_zero_of_dvd_ne_zero (Monic.ne_zero <\| hf.map (algebraMap R K)) hg suffices lem : ∃ g' : R[X], g'.map (algebraMap R K) = g * C g.leadingCoeff⁻¹ by obtain ⟨g', hg'⟩ := lem use g' rw [hg', mul_assoc, ← C_mul, inv_mul_cancel₀ (leadingCoeff_ne_zero.mpr g_ne_0), C_1, mul_one] have g_mul_dvd : g * C g.leadingCoeff⁻¹ ∣ f.map (algebraMap R K) := by rwa [Associated.dvd_iff_dvd_left (show Associated (g * C g.leadingCoeff⁻¹) g from _)] rw [associated_mul_isUnit_left_iff] exact isUnit_C.mpr (inv_ne_zero <\| leadingCoeff_ne_zero.mpr g_ne_0).isUnit let algeq := (Subalgebra.equivOfEq _ _ <\| integralClosure_eq_bot R _).trans (Algebra.botEquivOfInjective <\| IsFractionRing.injective R <\| K) have : (algebraMap R _).comp algeq.toAlgHom.toRingHom = (integralClosure R _).toSubring.subtype := by ext x; (conv_rhs => rw [← algeq.symm_apply_apply x]); rfl have H := (mem_lifts _).1 (integralClosure.mem_lifts_of_monic_of_dvd_map K hf (monic_mul_leadingCoeff_inv g_ne_0) g_mul_dvd) refine ⟨map algeq.toAlgHom.toRingHom ?_, ?_⟩ · use! Classical.choose H · rw [map_map, this] exact Classical.choose_spec H end IsIntegrallyClosed namespace Polynomial section variable {S : Type} [CommRing S] [IsDomain S] variable {φ : R →+ S} (hinj : Function.Injective φ) {f : R[X]} (hf : f.IsPrimitive) include hinj hf theorem IsPrimitive.isUnit_iff_isUnit_map_of_injective : IsUnit f ↔ IsUnit (map φ f) := by refine ⟨(mapRingHom φ).isUnit_map, fun h => ?_⟩ rcases isUnit_iff.1 h with ⟨_, ⟨u, rfl⟩, hu⟩ have hdeg := degree_C u.ne_zero rw [hu, degree_map_eq_of_injective hinj] at hdeg rw [eq_C_of_degree_eq_zero hdeg] at hf ⊢ exact isUnit_C.mpr (isPrimitive_iff_isUnit_of_C_dvd.mp hf (f.coeff 0) dvd_rfl) theorem IsPrimitive.irreducible_of_irreducible_map_of_injective (h_irr : Irreducible (map φ f)) : Irreducible f := by refine ⟨fun h => h_irr.not_isUnit (IsUnit.map (mapRingHom φ) h), fun a b h => (h_irr.isUnit_or_isUnit <\| by rw [h, Polynomial.map_mul]).imp ?_ ?_⟩	all_goals apply ((isPrimitive_of_dvd hf _).isUnit_iff_isUnit_map_of_injective hinj).mpr exacts [Dvd.intro _ h.symm, Dvd.intro_left _ h.symm] end section FractionMap	Mathlib/RingTheory/Polynomial/GaussLemma.lean	124	130
/- Copyright (c) 2014 Jeremy Avigad. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jeremy Avigad, Leonardo de Moura -/ import Batteries.Tactic.Congr import Mathlib.Data.Option.Basic import Mathlib.Data.Prod.Basic import Mathlib.Data.Set.Subsingleton import Mathlib.Data.Set.SymmDiff import Mathlib.Data.Set.Inclusion /-! # Images and preimages of sets ## Main definitions * `preimage f t : Set α` : the preimage f⁻¹(t) (written `f ⁻¹' t` in Lean) of a subset of β. * `range f : Set β` : the image of `univ` under `f`. Also works for `{p : Prop} (f : p → α)` (unlike `image`) ## Notation * `f ⁻¹' t` for `Set.preimage f t` * `f '' s` for `Set.image f s` ## Tags set, sets, image, preimage, pre-image, range -/ assert_not_exists WithTop OrderIso universe u v open Function Set namespace Set variable {α β γ : Type} {ι : Sort} /-! ### Inverse image -/ section Preimage variable {f : α → β} {g : β → γ} @[simp] theorem preimage_empty : f ⁻¹' ∅ = ∅ := rfl theorem preimage_congr {f g : α → β} {s : Set β} (h : ∀ x : α, f x = g x) : f ⁻¹' s = g ⁻¹' s := by congr with x simp [h] @[gcongr] theorem preimage_mono {s t : Set β} (h : s ⊆ t) : f ⁻¹' s ⊆ f ⁻¹' t := fun _ hx => h hx @[simp, mfld_simps] theorem preimage_univ : f ⁻¹' univ = univ := rfl theorem subset_preimage_univ {s : Set α} : s ⊆ f ⁻¹' univ := subset_univ _ @[simp, mfld_simps] theorem preimage_inter {s t : Set β} : f ⁻¹' (s ∩ t) = f ⁻¹' s ∩ f ⁻¹' t := rfl @[simp] theorem preimage_union {s t : Set β} : f ⁻¹' (s ∪ t) = f ⁻¹' s ∪ f ⁻¹' t := rfl @[simp] theorem preimage_compl {s : Set β} : f ⁻¹' sᶜ = (f ⁻¹' s)ᶜ := rfl @[simp] theorem preimage_diff (f : α → β) (s t : Set β) : f ⁻¹' (s \ t) = f ⁻¹' s \ f ⁻¹' t := rfl open scoped symmDiff in @[simp] lemma preimage_symmDiff {f : α → β} (s t : Set β) : f ⁻¹' (s ∆ t) = (f ⁻¹' s) ∆ (f ⁻¹' t) := rfl @[simp] theorem preimage_ite (f : α → β) (s t₁ t₂ : Set β) : f ⁻¹' s.ite t₁ t₂ = (f ⁻¹' s).ite (f ⁻¹' t₁) (f ⁻¹' t₂) := rfl @[simp] theorem preimage_setOf_eq {p : α → Prop} {f : β → α} : f ⁻¹' { a \| p a } = { a \| p (f a) } := rfl @[simp] theorem preimage_id_eq : preimage (id : α → α) = id := rfl @[mfld_simps] theorem preimage_id {s : Set α} : id ⁻¹' s = s := rfl @[simp, mfld_simps] theorem preimage_id' {s : Set α} : (fun x => x) ⁻¹' s = s := rfl @[simp] theorem preimage_const_of_mem {b : β} {s : Set β} (h : b ∈ s) : (fun _ : α => b) ⁻¹' s = univ := eq_univ_of_forall fun _ => h @[simp] theorem preimage_const_of_not_mem {b : β} {s : Set β} (h : b ∉ s) : (fun _ : α => b) ⁻¹' s = ∅ := eq_empty_of_subset_empty fun _ hx => h hx theorem preimage_const (b : β) (s : Set β) [Decidable (b ∈ s)] : (fun _ : α => b) ⁻¹' s = if b ∈ s then univ else ∅ := by split_ifs with hb exacts [preimage_const_of_mem hb, preimage_const_of_not_mem hb] /-- If preimage of each singleton under `f : α → β` is either empty or the whole type, then `f` is a constant. -/ lemma exists_eq_const_of_preimage_singleton [Nonempty β] {f : α → β} (hf : ∀ b : β, f ⁻¹' {b} = ∅ ∨ f ⁻¹' {b} = univ) : ∃ b, f = const α b := by rcases em (∃ b, f ⁻¹' {b} = univ) with ⟨b, hb⟩ \| hf' · exact ⟨b, funext fun x ↦ eq_univ_iff_forall.1 hb x⟩ · have : ∀ x b, f x ≠ b := fun x b ↦ eq_empty_iff_forall_not_mem.1 ((hf b).resolve_right fun h ↦ hf' ⟨b, h⟩) x exact ⟨Classical.arbitrary β, funext fun x ↦ absurd rfl (this x _)⟩ theorem preimage_comp {s : Set γ} : g ∘ f ⁻¹' s = f ⁻¹' (g ⁻¹' s) := rfl theorem preimage_comp_eq : preimage (g ∘ f) = preimage f ∘ preimage g := rfl theorem preimage_iterate_eq {f : α → α} {n : ℕ} : Set.preimage f^[n] = (Set.preimage f)^[n] := by induction n with \| zero => simp \| succ n ih => rw [iterate_succ, iterate_succ', preimage_comp_eq, ih] theorem preimage_preimage {g : β → γ} {f : α → β} {s : Set γ} : f ⁻¹' (g ⁻¹' s) = (fun x => g (f x)) ⁻¹' s := preimage_comp.symm theorem eq_preimage_subtype_val_iff {p : α → Prop} {s : Set (Subtype p)} {t : Set α} : s = Subtype.val ⁻¹' t ↔ ∀ (x) (h : p x), (⟨x, h⟩ : Subtype p) ∈ s ↔ x ∈ t := ⟨fun s_eq x h => by rw [s_eq] simp, fun h => ext fun ⟨x, hx⟩ => by simp [h]⟩ theorem nonempty_of_nonempty_preimage {s : Set β} {f : α → β} (hf : (f ⁻¹' s).Nonempty) : s.Nonempty := let ⟨x, hx⟩ := hf ⟨f x, hx⟩ @[simp] theorem preimage_singleton_true (p : α → Prop) : p ⁻¹' {True} = {a \| p a} := by ext; simp @[simp] theorem preimage_singleton_false (p : α → Prop) : p ⁻¹' {False} = {a \| ¬p a} := by ext; simp theorem preimage_subtype_coe_eq_compl {s u v : Set α} (hsuv : s ⊆ u ∪ v) (H : s ∩ (u ∩ v) = ∅) : ((↑) : s → α) ⁻¹' u = ((↑) ⁻¹' v)ᶜ := by ext ⟨x, x_in_s⟩ constructor · intro x_in_u x_in_v exact eq_empty_iff_forall_not_mem.mp H x ⟨x_in_s, ⟨x_in_u, x_in_v⟩⟩ · intro hx exact Or.elim (hsuv x_in_s) id fun hx' => hx.elim hx' lemma preimage_subset {s t} (hs : s ⊆ f '' t) (hf : Set.InjOn f (f ⁻¹' s)) : f ⁻¹' s ⊆ t := by rintro a ha obtain ⟨b, hb, hba⟩ := hs ha rwa [hf ha _ hba.symm] simpa [hba] end Preimage /-! ### Image of a set under a function -/ section Image variable {f : α → β} {s t : Set α} theorem image_eta (f : α → β) : f '' s = (fun x => f x) '' s := rfl theorem _root_.Function.Injective.mem_set_image {f : α → β} (hf : Injective f) {s : Set α} {a : α} : f a ∈ f '' s ↔ a ∈ s := ⟨fun ⟨_, hb, Eq⟩ => hf Eq ▸ hb, mem_image_of_mem f⟩ lemma preimage_subset_of_surjOn {t : Set β} (hf : Injective f) (h : SurjOn f s t) : f ⁻¹' t ⊆ s := fun _ hx ↦ hf.mem_set_image.1 <\| h hx theorem forall_mem_image {f : α → β} {s : Set α} {p : β → Prop} : (∀ y ∈ f '' s, p y) ↔ ∀ ⦃x⦄, x ∈ s → p (f x) := by simp theorem exists_mem_image {f : α → β} {s : Set α} {p : β → Prop} : (∃ y ∈ f '' s, p y) ↔ ∃ x ∈ s, p (f x) := by simp @[congr] theorem image_congr {f g : α → β} {s : Set α} (h : ∀ a ∈ s, f a = g a) : f '' s = g '' s := by aesop /-- A common special case of `image_congr` -/ theorem image_congr' {f g : α → β} {s : Set α} (h : ∀ x : α, f x = g x) : f '' s = g '' s := image_congr fun x _ => h x @[gcongr] lemma image_mono (h : s ⊆ t) : f '' s ⊆ f '' t := by rintro - ⟨a, ha, rfl⟩; exact mem_image_of_mem f (h ha) theorem image_comp (f : β → γ) (g : α → β) (a : Set α) : f ∘ g '' a = f '' (g '' a) := by aesop theorem image_comp_eq {g : β → γ} : image (g ∘ f) = image g ∘ image f := by ext; simp /-- A variant of `image_comp`, useful for rewriting -/ theorem image_image (g : β → γ) (f : α → β) (s : Set α) : g '' (f '' s) = (fun x => g (f x)) '' s := (image_comp g f s).symm theorem image_comm {β'} {f : β → γ} {g : α → β} {f' : α → β'} {g' : β' → γ} (h_comm : ∀ a, f (g a) = g' (f' a)) : (s.image g).image f = (s.image f').image g' := by simp_rw [image_image, h_comm] theorem _root_.Function.Semiconj.set_image {f : α → β} {ga : α → α} {gb : β → β} (h : Function.Semiconj f ga gb) : Function.Semiconj (image f) (image ga) (image gb) := fun _ => image_comm h theorem _root_.Function.Commute.set_image {f g : α → α} (h : Function.Commute f g) : Function.Commute (image f) (image g) := Function.Semiconj.set_image h /-- Image is monotone with respect to `⊆`. See `Set.monotone_image` for the statement in terms of `≤`. -/ @[gcongr] theorem image_subset {a b : Set α} (f : α → β) (h : a ⊆ b) : f '' a ⊆ f '' b := by simp only [subset_def, mem_image] exact fun x => fun ⟨w, h1, h2⟩ => ⟨w, h h1, h2⟩ /-- `Set.image` is monotone. See `Set.image_subset` for the statement in terms of `⊆`. -/ lemma monotone_image {f : α → β} : Monotone (image f) := fun _ _ => image_subset _ theorem image_union (f : α → β) (s t : Set α) : f '' (s ∪ t) = f '' s ∪ f '' t := ext fun x => ⟨by rintro ⟨a, h \| h, rfl⟩ <;> [left; right] <;> exact ⟨_, h, rfl⟩, by rintro (⟨a, h, rfl⟩ \| ⟨a, h, rfl⟩) <;> refine ⟨_, ?_, rfl⟩ · exact mem_union_left t h · exact mem_union_right s h⟩ @[simp] theorem image_empty (f : α → β) : f '' ∅ = ∅ := by ext simp theorem image_inter_subset (f : α → β) (s t : Set α) : f '' (s ∩ t) ⊆ f '' s ∩ f '' t := subset_inter (image_subset _ inter_subset_left) (image_subset _ inter_subset_right) theorem image_inter_on {f : α → β} {s t : Set α} (h : ∀ x ∈ t, ∀ y ∈ s, f x = f y → x = y) : f '' (s ∩ t) = f '' s ∩ f '' t := (image_inter_subset _ _ _).antisymm fun b ⟨⟨a₁, ha₁, h₁⟩, ⟨a₂, ha₂, h₂⟩⟩ ↦ have : a₂ = a₁ := h _ ha₂ _ ha₁ (by simp []) ⟨a₁, ⟨ha₁, this ▸ ha₂⟩, h₁⟩ theorem image_inter {f : α → β} {s t : Set α} (H : Injective f) : f '' (s ∩ t) = f '' s ∩ f '' t := image_inter_on fun _ _ _ _ h => H h theorem image_univ_of_surjective {ι : Type} {f : ι → β} (H : Surjective f) : f '' univ = univ := eq_univ_of_forall <\| by simpa [image] @[simp] theorem image_singleton {f : α → β} {a : α} : f '' {a} = {f a} := by ext simp [image, eq_comm] @[simp] theorem Nonempty.image_const {s : Set α} (hs : s.Nonempty) (a : β) : (fun _ => a) '' s = {a} := ext fun _ => ⟨fun ⟨_, _, h⟩ => h ▸ mem_singleton _, fun h => (eq_of_mem_singleton h).symm ▸ hs.imp fun _ hy => ⟨hy, rfl⟩⟩ @[simp, mfld_simps] theorem image_eq_empty {α β} {f : α → β} {s : Set α} : f '' s = ∅ ↔ s = ∅ := by simp only [eq_empty_iff_forall_not_mem] exact ⟨fun H a ha => H _ ⟨_, ha, rfl⟩, fun H b ⟨_, ha, _⟩ => H _ ha⟩ theorem preimage_compl_eq_image_compl [BooleanAlgebra α] (S : Set α) : HasCompl.compl ⁻¹' S = HasCompl.compl '' S := Set.ext fun x => ⟨fun h => ⟨xᶜ, h, compl_compl x⟩, fun h => Exists.elim h fun _ hy => (compl_eq_comm.mp hy.2).symm.subst hy.1⟩ theorem mem_compl_image [BooleanAlgebra α] (t : α) (S : Set α) : t ∈ HasCompl.compl '' S ↔ tᶜ ∈ S := by simp [← preimage_compl_eq_image_compl] @[simp] theorem image_id_eq : image (id : α → α) = id := by ext; simp /-- A variant of `image_id` -/ @[simp] theorem image_id' (s : Set α) : (fun x => x) '' s = s := by ext simp theorem image_id (s : Set α) : id '' s = s := by simp lemma image_iterate_eq {f : α → α} {n : ℕ} : image (f^[n]) = (image f)^[n] := by induction n with \| zero => simp \| succ n ih => rw [iterate_succ', iterate_succ', ← ih, image_comp_eq] theorem compl_compl_image [BooleanAlgebra α] (S : Set α) : HasCompl.compl '' (HasCompl.compl '' S) = S := by rw [← image_comp, compl_comp_compl, image_id] theorem image_insert_eq {f : α → β} {a : α} {s : Set α} : f '' insert a s = insert (f a) (f '' s) := by ext simp [and_or_left, exists_or, eq_comm, or_comm, and_comm] theorem image_pair (f : α → β) (a b : α) : f '' {a, b} = {f a, f b} := by simp only [image_insert_eq, image_singleton] theorem image_subset_preimage_of_inverse {f : α → β} {g : β → α} (I : LeftInverse g f) (s : Set α) : f '' s ⊆ g ⁻¹' s := fun _ ⟨a, h, e⟩ => e ▸ ((I a).symm ▸ h : g (f a) ∈ s) theorem preimage_subset_image_of_inverse {f : α → β} {g : β → α} (I : LeftInverse g f) (s : Set β) : f ⁻¹' s ⊆ g '' s := fun b h => ⟨f b, h, I b⟩ theorem range_inter_ssubset_iff_preimage_ssubset {f : α → β} {S S' : Set β} : range f ∩ S ⊂ range f ∩ S' ↔ f ⁻¹' S ⊂ f ⁻¹' S' := by simp only [Set.ssubset_iff_exists] apply and_congr ?_ (by aesop) constructor all_goals intro r x hx simp_all only [subset_inter_iff, inter_subset_left, true_and, mem_preimage, mem_inter_iff, mem_range, true_and] aesop theorem image_eq_preimage_of_inverse {f : α → β} {g : β → α} (h₁ : LeftInverse g f) (h₂ : RightInverse g f) : image f = preimage g := funext fun s => Subset.antisymm (image_subset_preimage_of_inverse h₁ s) (preimage_subset_image_of_inverse h₂ s) theorem mem_image_iff_of_inverse {f : α → β} {g : β → α} {b : β} {s : Set α} (h₁ : LeftInverse g f) (h₂ : RightInverse g f) : b ∈ f '' s ↔ g b ∈ s := by rw [image_eq_preimage_of_inverse h₁ h₂]; rfl theorem image_compl_subset {f : α → β} {s : Set α} (H : Injective f) : f '' sᶜ ⊆ (f '' s)ᶜ := Disjoint.subset_compl_left <\| by simp [disjoint_iff_inf_le, ← image_inter H] theorem subset_image_compl {f : α → β} {s : Set α} (H : Surjective f) : (f '' s)ᶜ ⊆ f '' sᶜ := compl_subset_iff_union.2 <\| by rw [← image_union] simp [image_univ_of_surjective H] theorem image_compl_eq {f : α → β} {s : Set α} (H : Bijective f) : f '' sᶜ = (f '' s)ᶜ := Subset.antisymm (image_compl_subset H.1) (subset_image_compl H.2) theorem subset_image_diff (f : α → β) (s t : Set α) : f '' s \ f '' t ⊆ f '' (s \ t) := by rw [diff_subset_iff, ← image_union, union_diff_self] exact image_subset f subset_union_right open scoped symmDiff in theorem subset_image_symmDiff : (f '' s) ∆ (f '' t) ⊆ f '' s ∆ t := (union_subset_union (subset_image_diff _ _ _) <\| subset_image_diff _ _ _).trans (superset_of_eq (image_union _ _ _)) theorem image_diff {f : α → β} (hf : Injective f) (s t : Set α) : f '' (s \ t) = f '' s \ f '' t := Subset.antisymm (Subset.trans (image_inter_subset _ _ _) <\| inter_subset_inter_right _ <\| image_compl_subset hf) (subset_image_diff f s t) open scoped symmDiff in theorem image_symmDiff (hf : Injective f) (s t : Set α) : f '' s ∆ t = (f '' s) ∆ (f '' t) := by simp_rw [Set.symmDiff_def, image_union, image_diff hf] theorem Nonempty.image (f : α → β) {s : Set α} : s.Nonempty → (f '' s).Nonempty \| ⟨x, hx⟩ => ⟨f x, mem_image_of_mem f hx⟩ theorem Nonempty.of_image {f : α → β} {s : Set α} : (f '' s).Nonempty → s.Nonempty \| ⟨_, x, hx, _⟩ => ⟨x, hx⟩ @[simp] theorem image_nonempty {f : α → β} {s : Set α} : (f '' s).Nonempty ↔ s.Nonempty := ⟨Nonempty.of_image, fun h => h.image f⟩ theorem Nonempty.preimage {s : Set β} (hs : s.Nonempty) {f : α → β} (hf : Surjective f) : (f ⁻¹' s).Nonempty := let ⟨y, hy⟩ := hs let ⟨x, hx⟩ := hf y ⟨x, mem_preimage.2 <\| hx.symm ▸ hy⟩ instance (f : α → β) (s : Set α) [Nonempty s] : Nonempty (f '' s) := (Set.Nonempty.image f .of_subtype).to_subtype /-- image and preimage are a Galois connection -/ @[simp] theorem image_subset_iff {s : Set α} {t : Set β} {f : α → β} : f '' s ⊆ t ↔ s ⊆ f ⁻¹' t := forall_mem_image theorem image_preimage_subset (f : α → β) (s : Set β) : f '' (f ⁻¹' s) ⊆ s := image_subset_iff.2 Subset.rfl theorem subset_preimage_image (f : α → β) (s : Set α) : s ⊆ f ⁻¹' (f '' s) := fun _ => mem_image_of_mem f theorem preimage_image_univ {f : α → β} : f ⁻¹' (f '' univ) = univ := Subset.antisymm (fun _ _ => trivial) (subset_preimage_image f univ) @[simp] theorem preimage_image_eq {f : α → β} (s : Set α) (h : Injective f) : f ⁻¹' (f '' s) = s := Subset.antisymm (fun _ ⟨_, hy, e⟩ => h e ▸ hy) (subset_preimage_image f s) @[simp] theorem image_preimage_eq {f : α → β} (s : Set β) (h : Surjective f) : f '' (f ⁻¹' s) = s := Subset.antisymm (image_preimage_subset f s) fun x hx => let ⟨y, e⟩ := h x ⟨y, (e.symm ▸ hx : f y ∈ s), e⟩ @[simp] theorem Nonempty.subset_preimage_const {s : Set α} (hs : Set.Nonempty s) (t : Set β) (a : β) : s ⊆ (fun _ => a) ⁻¹' t ↔ a ∈ t := by rw [← image_subset_iff, hs.image_const, singleton_subset_iff] -- Note defeq abuse identifying `preimage` with function composition in the following two proofs. @[simp] theorem preimage_injective : Injective (preimage f) ↔ Surjective f := injective_comp_right_iff_surjective @[simp] theorem preimage_surjective : Surjective (preimage f) ↔ Injective f := surjective_comp_right_iff_injective @[simp] theorem preimage_eq_preimage {f : β → α} (hf : Surjective f) : f ⁻¹' s = f ⁻¹' t ↔ s = t := (preimage_injective.mpr hf).eq_iff theorem image_inter_preimage (f : α → β) (s : Set α) (t : Set β) : f '' (s ∩ f ⁻¹' t) = f '' s ∩ t := by apply Subset.antisymm · calc f '' (s ∩ f ⁻¹' t) ⊆ f '' s ∩ f '' (f ⁻¹' t) := image_inter_subset _ _ _ _ ⊆ f '' s ∩ t := inter_subset_inter_right _ (image_preimage_subset f t) · rintro _ ⟨⟨x, h', rfl⟩, h⟩ exact ⟨x, ⟨h', h⟩, rfl⟩ theorem image_preimage_inter (f : α → β) (s : Set α) (t : Set β) : f '' (f ⁻¹' t ∩ s) = t ∩ f '' s := by simp only [inter_comm, image_inter_preimage] @[simp] theorem image_inter_nonempty_iff {f : α → β} {s : Set α} {t : Set β} : (f '' s ∩ t).Nonempty ↔ (s ∩ f ⁻¹' t).Nonempty := by rw [← image_inter_preimage, image_nonempty] theorem image_diff_preimage {f : α → β} {s : Set α} {t : Set β} : f '' (s \ f ⁻¹' t) = f '' s \ t := by simp_rw [diff_eq, ← preimage_compl, image_inter_preimage] theorem compl_image : image (compl : Set α → Set α) = preimage compl := image_eq_preimage_of_inverse compl_compl compl_compl theorem compl_image_set_of {p : Set α → Prop} : compl '' { s \| p s } = { s \| p sᶜ } := congr_fun compl_image p theorem inter_preimage_subset (s : Set α) (t : Set β) (f : α → β) : s ∩ f ⁻¹' t ⊆ f ⁻¹' (f '' s ∩ t) := fun _ h => ⟨mem_image_of_mem _ h.left, h.right⟩ theorem union_preimage_subset (s : Set α) (t : Set β) (f : α → β) : s ∪ f ⁻¹' t ⊆ f ⁻¹' (f '' s ∪ t) := fun _ h => Or.elim h (fun l => Or.inl <\| mem_image_of_mem _ l) fun r => Or.inr r theorem subset_image_union (f : α → β) (s : Set α) (t : Set β) : f '' (s ∪ f ⁻¹' t) ⊆ f '' s ∪ t := image_subset_iff.2 (union_preimage_subset _ _ _) theorem preimage_subset_iff {A : Set α} {B : Set β} {f : α → β} : f ⁻¹' B ⊆ A ↔ ∀ a : α, f a ∈ B → a ∈ A := Iff.rfl theorem image_eq_image {f : α → β} (hf : Injective f) : f '' s = f '' t ↔ s = t := Iff.symm <\| (Iff.intro fun eq => eq ▸ rfl) fun eq => by rw [← preimage_image_eq s hf, ← preimage_image_eq t hf, eq] theorem subset_image_iff {t : Set β} : t ⊆ f '' s ↔ ∃ u, u ⊆ s ∧ f '' u = t := by refine ⟨fun h ↦ ⟨f ⁻¹' t ∩ s, inter_subset_right, ?_⟩, fun ⟨u, hu, hu'⟩ ↦ hu'.symm ▸ image_mono hu⟩ rwa [image_preimage_inter, inter_eq_left] @[simp] lemma exists_subset_image_iff {p : Set β → Prop} : (∃ t ⊆ f '' s, p t) ↔ ∃ t ⊆ s, p (f '' t) := by simp [subset_image_iff] @[simp] lemma forall_subset_image_iff {p : Set β → Prop} : (∀ t ⊆ f '' s, p t) ↔ ∀ t ⊆ s, p (f '' t) := by simp [subset_image_iff] theorem image_subset_image_iff {f : α → β} (hf : Injective f) : f '' s ⊆ f '' t ↔ s ⊆ t := by refine Iff.symm <\| (Iff.intro (image_subset f)) fun h => ?_ rw [← preimage_image_eq s hf, ← preimage_image_eq t hf] exact preimage_mono h theorem prod_quotient_preimage_eq_image [s : Setoid α] (g : Quotient s → β) {h : α → β} (Hh : h = g ∘ Quotient.mk'') (r : Set (β × β)) : { x : Quotient s × Quotient s \| (g x.1, g x.2) ∈ r } = (fun a : α × α => (⟦a.1⟧, ⟦a.2⟧)) '' ((fun a : α × α => (h a.1, h a.2)) ⁻¹' r) := Hh.symm ▸ Set.ext fun ⟨a₁, a₂⟩ => ⟨Quot.induction_on₂ a₁ a₂ fun a₁ a₂ h => ⟨(a₁, a₂), h, rfl⟩, fun ⟨⟨b₁, b₂⟩, h₁, h₂⟩ => show (g a₁, g a₂) ∈ r from have h₃ : ⟦b₁⟧ = a₁ ∧ ⟦b₂⟧ = a₂ := Prod.ext_iff.1 h₂ h₃.1 ▸ h₃.2 ▸ h₁⟩ theorem exists_image_iff (f : α → β) (x : Set α) (P : β → Prop) : (∃ a : f '' x, P a) ↔ ∃ a : x, P (f a) := ⟨fun ⟨a, h⟩ => ⟨⟨_, a.prop.choose_spec.1⟩, a.prop.choose_spec.2.symm ▸ h⟩, fun ⟨a, h⟩ => ⟨⟨_, _, a.prop, rfl⟩, h⟩⟩ theorem imageFactorization_eq {f : α → β} {s : Set α} : Subtype.val ∘ imageFactorization f s = f ∘ Subtype.val := funext fun _ => rfl theorem surjective_onto_image {f : α → β} {s : Set α} : Surjective (imageFactorization f s) := fun ⟨_, ⟨a, ha, rfl⟩⟩ => ⟨⟨a, ha⟩, rfl⟩ /-- If the only elements outside `s` are those left fixed by `σ`, then mapping by `σ` has no effect. -/ theorem image_perm {s : Set α} {σ : Equiv.Perm α} (hs : { a : α \| σ a ≠ a } ⊆ s) : σ '' s = s := by ext i obtain hi \| hi := eq_or_ne (σ i) i · refine ⟨?_, fun h => ⟨i, h, hi⟩⟩ rintro ⟨j, hj, h⟩ rwa [σ.injective (hi.trans h.symm)] · refine iff_of_true ⟨σ.symm i, hs fun h => hi ?_, σ.apply_symm_apply _⟩ (hs hi) convert congr_arg σ h <;> exact (σ.apply_symm_apply _).symm end Image /-! ### Lemmas about the powerset and image. -/ /-- The powerset of `{a} ∪ s` is `𝒫 s` together with `{a} ∪ t` for each `t ∈ 𝒫 s`. -/ theorem powerset_insert (s : Set α) (a : α) : 𝒫 insert a s = 𝒫 s ∪ insert a '' 𝒫 s := by ext t simp_rw [mem_union, mem_image, mem_powerset_iff] constructor · intro h by_cases hs : a ∈ t · right refine ⟨t \ {a}, ?_, ?_⟩ · rw [diff_singleton_subset_iff] assumption · rw [insert_diff_singleton, insert_eq_of_mem hs] · left exact (subset_insert_iff_of_not_mem hs).mp h · rintro (h \| ⟨s', h₁, rfl⟩) · exact subset_trans h (subset_insert a s) · exact insert_subset_insert h₁ /-! ### Lemmas about range of a function. -/ section Range variable {f : ι → α} {s t : Set α} theorem forall_mem_range {p : α → Prop} : (∀ a ∈ range f, p a) ↔ ∀ i, p (f i) := by simp theorem forall_subtype_range_iff {p : range f → Prop} : (∀ a : range f, p a) ↔ ∀ i, p ⟨f i, mem_range_self _⟩ := ⟨fun H _ => H _, fun H ⟨y, i, hi⟩ => by subst hi apply H⟩ theorem exists_range_iff {p : α → Prop} : (∃ a ∈ range f, p a) ↔ ∃ i, p (f i) := by simp theorem exists_subtype_range_iff {p : range f → Prop} : (∃ a : range f, p a) ↔ ∃ i, p ⟨f i, mem_range_self _⟩ := ⟨fun ⟨⟨a, i, hi⟩, ha⟩ => by subst a exact ⟨i, ha⟩, fun ⟨_, hi⟩ => ⟨_, hi⟩⟩ theorem range_eq_univ : range f = univ ↔ Surjective f := eq_univ_iff_forall @[deprecated (since := "2024-11-11")] alias range_iff_surjective := range_eq_univ alias ⟨_, _root_.Function.Surjective.range_eq⟩ := range_eq_univ @[simp] theorem subset_range_of_surjective {f : α → β} (h : Surjective f) (s : Set β) : s ⊆ range f := Surjective.range_eq h ▸ subset_univ s @[simp] theorem image_univ {f : α → β} : f '' univ = range f := by ext simp [image, range] lemma image_compl_eq_range_diff_image {f : α → β} (hf : Injective f) (s : Set α) : f '' sᶜ = range f \ f '' s := by rw [← image_univ, ← image_diff hf, compl_eq_univ_diff] /-- Alias of `Set.image_compl_eq_range_sdiff_image`. -/ lemma range_diff_image {f : α → β} (hf : Injective f) (s : Set α) : range f \ f '' s = f '' sᶜ := by rw [image_compl_eq_range_diff_image hf] @[simp] theorem preimage_eq_univ_iff {f : α → β} {s} : f ⁻¹' s = univ ↔ range f ⊆ s := by rw [← univ_subset_iff, ← image_subset_iff, image_univ] theorem image_subset_range (f : α → β) (s) : f '' s ⊆ range f := by rw [← image_univ]; exact image_subset _ (subset_univ _) theorem mem_range_of_mem_image (f : α → β) (s) {x : β} (h : x ∈ f '' s) : x ∈ range f := image_subset_range f s h theorem _root_.Nat.mem_range_succ (i : ℕ) : i ∈ range Nat.succ ↔ 0 < i := ⟨by rintro ⟨n, rfl⟩ exact Nat.succ_pos n, fun h => ⟨_, Nat.succ_pred_eq_of_pos h⟩⟩ theorem Nonempty.preimage' {s : Set β} (hs : s.Nonempty) {f : α → β} (hf : s ⊆ range f) : (f ⁻¹' s).Nonempty := let ⟨_, hy⟩ := hs let ⟨x, hx⟩ := hf hy ⟨x, Set.mem_preimage.2 <\| hx.symm ▸ hy⟩ theorem range_comp (g : α → β) (f : ι → α) : range (g ∘ f) = g '' range f := by aesop /-- Variant of `range_comp` using a lambda instead of function composition. -/ theorem range_comp' (g : α → β) (f : ι → α) : range (fun x => g (f x)) = g '' range f := range_comp g f theorem range_subset_iff : range f ⊆ s ↔ ∀ y, f y ∈ s := forall_mem_range theorem range_subset_range_iff_exists_comp {f : α → γ} {g : β → γ} : range f ⊆ range g ↔ ∃ h : α → β, f = g ∘ h := by simp only [range_subset_iff, mem_range, Classical.skolem, funext_iff, (· ∘ ·), eq_comm] theorem range_eq_iff (f : α → β) (s : Set β) : range f = s ↔ (∀ a, f a ∈ s) ∧ ∀ b ∈ s, ∃ a, f a = b := by rw [← range_subset_iff] exact le_antisymm_iff theorem range_comp_subset_range (f : α → β) (g : β → γ) : range (g ∘ f) ⊆ range g := by rw [range_comp]; apply image_subset_range theorem range_nonempty_iff_nonempty : (range f).Nonempty ↔ Nonempty ι := ⟨fun ⟨_, x, _⟩ => ⟨x⟩, fun ⟨x⟩ => ⟨f x, mem_range_self x⟩⟩ theorem range_nonempty [h : Nonempty ι] (f : ι → α) : (range f).Nonempty := range_nonempty_iff_nonempty.2 h @[simp] theorem range_eq_empty_iff {f : ι → α} : range f = ∅ ↔ IsEmpty ι := by rw [← not_nonempty_iff, ← range_nonempty_iff_nonempty, not_nonempty_iff_eq_empty] theorem range_eq_empty [IsEmpty ι] (f : ι → α) : range f = ∅ := range_eq_empty_iff.2 ‹_› instance instNonemptyRange [Nonempty ι] (f : ι → α) : Nonempty (range f) := (range_nonempty f).to_subtype @[simp] theorem image_union_image_compl_eq_range (f : α → β) : f '' s ∪ f '' sᶜ = range f := by rw [← image_union, ← image_univ, ← union_compl_self] theorem insert_image_compl_eq_range (f : α → β) (x : α) : insert (f x) (f '' {x}ᶜ) = range f := by rw [← image_insert_eq, insert_eq, union_compl_self, image_univ] theorem image_preimage_eq_range_inter {f : α → β} {t : Set β} : f '' (f ⁻¹' t) = range f ∩ t := ext fun x => ⟨fun ⟨_, hx, HEq⟩ => HEq ▸ ⟨mem_range_self _, hx⟩, fun ⟨⟨y, h_eq⟩, hx⟩ => h_eq ▸ mem_image_of_mem f <\| show y ∈ f ⁻¹' t by rw [preimage, mem_setOf, h_eq]; exact hx⟩ theorem image_preimage_eq_inter_range {f : α → β} {t : Set β} : f '' (f ⁻¹' t) = t ∩ range f := by rw [image_preimage_eq_range_inter, inter_comm] theorem image_preimage_eq_of_subset {f : α → β} {s : Set β} (hs : s ⊆ range f) : f '' (f ⁻¹' s) = s := by rw [image_preimage_eq_range_inter, inter_eq_self_of_subset_right hs] theorem image_preimage_eq_iff {f : α → β} {s : Set β} : f '' (f ⁻¹' s) = s ↔ s ⊆ range f := ⟨by intro h rw [← h] apply image_subset_range, image_preimage_eq_of_subset⟩ theorem subset_range_iff_exists_image_eq {f : α → β} {s : Set β} : s ⊆ range f ↔ ∃ t, f '' t = s := ⟨fun h => ⟨_, image_preimage_eq_iff.2 h⟩, fun ⟨_, ht⟩ => ht ▸ image_subset_range _ _⟩ theorem range_image (f : α → β) : range (image f) = 𝒫 range f := ext fun _ => subset_range_iff_exists_image_eq.symm @[simp] theorem exists_subset_range_and_iff {f : α → β} {p : Set β → Prop} : (∃ s, s ⊆ range f ∧ p s) ↔ ∃ s, p (f '' s) := by rw [← exists_range_iff, range_image]; rfl @[simp] theorem forall_subset_range_iff {f : α → β} {p : Set β → Prop} : (∀ s, s ⊆ range f → p s) ↔ ∀ s, p (f '' s) := by rw [← forall_mem_range, range_image]; simp only [mem_powerset_iff] @[simp] theorem preimage_subset_preimage_iff {s t : Set α} {f : β → α} (hs : s ⊆ range f) : f ⁻¹' s ⊆ f ⁻¹' t ↔ s ⊆ t := by constructor · intro h x hx rcases hs hx with ⟨y, rfl⟩ exact h hx intro h x; apply h theorem preimage_eq_preimage' {s t : Set α} {f : β → α} (hs : s ⊆ range f) (ht : t ⊆ range f) : f ⁻¹' s = f ⁻¹' t ↔ s = t := by constructor · intro h apply Subset.antisymm · rw [← preimage_subset_preimage_iff hs, h] · rw [← preimage_subset_preimage_iff ht, h] rintro rfl; rfl -- Not `@[simp]` since `simp` can prove this. theorem preimage_inter_range {f : α → β} {s : Set β} : f ⁻¹' (s ∩ range f) = f ⁻¹' s := Set.ext fun x => and_iff_left ⟨x, rfl⟩ -- Not `@[simp]` since `simp` can prove this. theorem preimage_range_inter {f : α → β} {s : Set β} : f ⁻¹' (range f ∩ s) = f ⁻¹' s := by rw [inter_comm, preimage_inter_range] theorem preimage_image_preimage {f : α → β} {s : Set β} : f ⁻¹' (f '' (f ⁻¹' s)) = f ⁻¹' s := by rw [image_preimage_eq_range_inter, preimage_range_inter] @[simp, mfld_simps] theorem range_id : range (@id α) = univ := range_eq_univ.2 surjective_id @[simp, mfld_simps] theorem range_id' : (range fun x : α => x) = univ := range_id @[simp] theorem _root_.Prod.range_fst [Nonempty β] : range (Prod.fst : α × β → α) = univ := Prod.fst_surjective.range_eq @[simp] theorem _root_.Prod.range_snd [Nonempty α] : range (Prod.snd : α × β → β) = univ := Prod.snd_surjective.range_eq @[simp] theorem range_eval {α : ι → Sort _} [∀ i, Nonempty (α i)] (i : ι) : range (eval i : (∀ i, α i) → α i) = univ := (surjective_eval i).range_eq theorem range_inl : range (@Sum.inl α β) = {x \| Sum.isLeft x} := by ext (_\|_) <;> simp theorem range_inr : range (@Sum.inr α β) = {x \| Sum.isRight x} := by ext (_\|_) <;> simp theorem isCompl_range_inl_range_inr : IsCompl (range <\| @Sum.inl α β) (range Sum.inr) := IsCompl.of_le (by rintro y ⟨⟨x₁, rfl⟩, ⟨x₂, h⟩⟩ exact Sum.noConfusion h) (by rintro (x \| y) - <;> [left; right] <;> exact mem_range_self _) @[simp] theorem range_inl_union_range_inr : range (Sum.inl : α → α ⊕ β) ∪ range Sum.inr = univ := isCompl_range_inl_range_inr.sup_eq_top @[simp] theorem range_inl_inter_range_inr : range (Sum.inl : α → α ⊕ β) ∩ range Sum.inr = ∅ := isCompl_range_inl_range_inr.inf_eq_bot @[simp] theorem range_inr_union_range_inl : range (Sum.inr : β → α ⊕ β) ∪ range Sum.inl = univ := isCompl_range_inl_range_inr.symm.sup_eq_top @[simp] theorem range_inr_inter_range_inl : range (Sum.inr : β → α ⊕ β) ∩ range Sum.inl = ∅ := isCompl_range_inl_range_inr.symm.inf_eq_bot @[simp] theorem preimage_inl_image_inr (s : Set β) : Sum.inl ⁻¹' (@Sum.inr α β '' s) = ∅ := by ext simp @[simp] theorem preimage_inr_image_inl (s : Set α) : Sum.inr ⁻¹' (@Sum.inl α β '' s) = ∅ := by ext simp @[simp] theorem preimage_inl_range_inr : Sum.inl ⁻¹' range (Sum.inr : β → α ⊕ β) = ∅ := by rw [← image_univ, preimage_inl_image_inr] @[simp] theorem preimage_inr_range_inl : Sum.inr ⁻¹' range (Sum.inl : α → α ⊕ β) = ∅ := by rw [← image_univ, preimage_inr_image_inl] @[simp] theorem compl_range_inl : (range (Sum.inl : α → α ⊕ β))ᶜ = range (Sum.inr : β → α ⊕ β) := IsCompl.compl_eq isCompl_range_inl_range_inr @[simp] theorem compl_range_inr : (range (Sum.inr : β → α ⊕ β))ᶜ = range (Sum.inl : α → α ⊕ β) := IsCompl.compl_eq isCompl_range_inl_range_inr.symm theorem image_preimage_inl_union_image_preimage_inr (s : Set (α ⊕ β)) : Sum.inl '' (Sum.inl ⁻¹' s) ∪ Sum.inr '' (Sum.inr ⁻¹' s) = s := by rw [image_preimage_eq_inter_range, image_preimage_eq_inter_range, ← inter_union_distrib_left, range_inl_union_range_inr, inter_univ] @[simp] theorem range_quot_mk (r : α → α → Prop) : range (Quot.mk r) = univ := Quot.mk_surjective.range_eq @[simp] theorem range_quot_lift {r : ι → ι → Prop} (hf : ∀ x y, r x y → f x = f y) : range (Quot.lift f hf) = range f := ext fun _ => Quot.mk_surjective.exists @[simp] theorem range_quotient_mk {s : Setoid α} : range (Quotient.mk s) = univ := range_quot_mk _ @[simp] theorem range_quotient_lift [s : Setoid ι] (hf) : range (Quotient.lift f hf : Quotient s → α) = range f := range_quot_lift _ @[simp] theorem range_quotient_mk' {s : Setoid α} : range (Quotient.mk' : α → Quotient s) = univ := range_quot_mk _ lemma Quotient.range_mk'' {sa : Setoid α} : range (Quotient.mk'' (s₁ := sa)) = univ := range_quotient_mk @[simp] theorem range_quotient_lift_on' {s : Setoid ι} (hf) : (range fun x : Quotient s => Quotient.liftOn' x f hf) = range f := range_quot_lift _ instance canLift (c) (p) [CanLift α β c p] : CanLift (Set α) (Set β) (c '' ·) fun s => ∀ x ∈ s, p x where prf _ hs := subset_range_iff_exists_image_eq.mp fun x hx => CanLift.prf _ (hs x hx) theorem range_const_subset {c : α} : (range fun _ : ι => c) ⊆ {c} := range_subset_iff.2 fun _ => rfl @[simp] theorem range_const : ∀ [Nonempty ι] {c : α}, (range fun _ : ι => c) = {c} \| ⟨x⟩, _ => (Subset.antisymm range_const_subset) fun _ hy => (mem_singleton_iff.1 hy).symm ▸ mem_range_self x theorem range_subtype_map {p : α → Prop} {q : β → Prop} (f : α → β) (h : ∀ x, p x → q (f x)) : range (Subtype.map f h) = (↑) ⁻¹' (f '' { x \| p x }) := by ext ⟨x, hx⟩ simp_rw [mem_preimage, mem_range, mem_image, Subtype.exists, Subtype.map] simp only [Subtype.mk.injEq, exists_prop, mem_setOf_eq] theorem image_swap_eq_preimage_swap : image (@Prod.swap α β) = preimage Prod.swap := image_eq_preimage_of_inverse Prod.swap_leftInverse Prod.swap_rightInverse theorem preimage_singleton_nonempty {f : α → β} {y : β} : (f ⁻¹' {y}).Nonempty ↔ y ∈ range f := Iff.rfl theorem preimage_singleton_eq_empty {f : α → β} {y : β} : f ⁻¹' {y} = ∅ ↔ y ∉ range f := not_nonempty_iff_eq_empty.symm.trans preimage_singleton_nonempty.not theorem range_subset_singleton {f : ι → α} {x : α} : range f ⊆ {x} ↔ f = const ι x := by simp [range_subset_iff, funext_iff, mem_singleton] theorem image_compl_preimage {f : α → β} {s : Set β} : f '' (f ⁻¹' s)ᶜ = range f \ s := by rw [compl_eq_univ_diff, image_diff_preimage, image_univ] theorem rangeFactorization_eq {f : ι → β} : Subtype.val ∘ rangeFactorization f = f :=	funext fun _ => rfl	Mathlib/Data/Set/Image.lean	888	888
/- Copyright (c) 2018 Mario Carneiro. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro, Aurélien Saue, Anne Baanen -/ import Mathlib.Tactic.NormNum.Inv import Mathlib.Tactic.NormNum.Pow import Mathlib.Util.AtomM /-! # `ring` tactic A tactic for solving equations in commutative (semi)rings, where the exponents can also contain variables. Based on <http://www.cs.ru.nl/~freek/courses/tt-2014/read/10.1.1.61.3041.pdf> . More precisely, expressions of the following form are supported: - constants (non-negative integers) - variables - coefficients (any rational number, embedded into the (semi)ring) - addition of expressions - multiplication of expressions (`a * b`) - scalar multiplication of expressions (`n • a`; the multiplier must have type `ℕ`) - exponentiation of expressions (the exponent must have type `ℕ`) - subtraction and negation of expressions (if the base is a full ring) The extension to exponents means that something like `2 * 2^n * b = b * 2^(n+1)` can be proved, even though it is not strictly speaking an equation in the language of commutative rings. ## Implementation notes The basic approach to prove equalities is to normalise both sides and check for equality. The normalisation is guided by building a value in the type `ExSum` at the meta level, together with a proof (at the base level) that the original value is equal to the normalised version. The outline of the file: - Define a mutual inductive family of types `ExSum`, `ExProd`, `ExBase`, which can represent expressions with `+`, ``, `^` and rational numerals. The mutual induction ensures that associativity and distributivity are applied, by restricting which kinds of subexpressions appear as arguments to the various operators. - Represent addition, multiplication and exponentiation in the `ExSum` type, thus allowing us to map expressions to `ExSum` (the `eval` function drives this). We apply associativity and distributivity of the operators here (helped by `Ex` types) and commutativity as well (by sorting the subterms; unfortunately not helped by anything). Any expression not of the above formats is treated as an atom (the same as a variable). There are some details we glossed over which make the plan more complicated: - The order on atoms is not initially obvious. We construct a list containing them in order of initial appearance in the expression, then use the index into the list as a key to order on. - For `pow`, the exponent must be a natural number, while the base can be any semiring `α`. We swap out operations for the base ring `α` with those for the exponent ring `ℕ` as soon as we deal with exponents. ## Caveats and future work The normalized form of an expression is the one that is useful for the tactic, but not as nice to read. To remedy this, the user-facing normalization calls `ringNFCore`. Subtraction cancels out identical terms, but division does not. That is: `a - a = 0 := by ring` solves the goal, but `a / a := 1 by ring` doesn't. Note that `0 / 0` is generally defined to be `0`, so division cancelling out is not true in general. Multiplication of powers can be simplified a little bit further: `2 ^ n * 2 ^ n = 4 ^ n := by ring` could be implemented in a similar way that `2 * a + 2 * a = 4 * a := by ring` already works. This feature wasn't needed yet, so it's not implemented yet. ## Tags ring, semiring, exponent, power -/ assert_not_exists OrderedAddCommMonoid namespace Mathlib.Tactic namespace Ring open Mathlib.Meta Qq NormNum Lean.Meta AtomM attribute [local instance] monadLiftOptionMetaM open Lean (MetaM Expr mkRawNatLit) /-- A shortcut instance for `CommSemiring ℕ` used by ring. -/ def instCommSemiringNat : CommSemiring ℕ := inferInstance /-- A typed expression of type `CommSemiring ℕ` used when we are working on ring subexpressions of type `ℕ`. -/ def sℕ : Q(CommSemiring ℕ) := q(instCommSemiringNat) mutual /-- The base `e` of a normalized exponent expression. -/ inductive ExBase : ∀ {u : Lean.Level} {α : Q(Type u)}, Q(CommSemiring $α) → (e : Q($α)) → Type /-- An atomic expression `e` with id `id`. Atomic expressions are those which `ring` cannot parse any further. For instance, `a + (a % b)` has `a` and `(a % b)` as atoms. The `ring1` tactic does not normalize the subexpressions in atoms, but `ring_nf` does. Atoms in fact represent equivalence classes of expressions, modulo definitional equality. The field `index : ℕ` should be a unique number for each class, while `value : expr` contains a representative of this class. The function `resolve_atom` determines the appropriate atom for a given expression. -/ \| atom {sα} {e} (id : ℕ) : ExBase sα e /-- A sum of monomials. -/ \| sum {sα} {e} (_ : ExSum sα e) : ExBase sα e /-- A monomial, which is a product of powers of `ExBase` expressions, terminated by a (nonzero) constant coefficient. -/ inductive ExProd : ∀ {u : Lean.Level} {α : Q(Type u)}, Q(CommSemiring $α) → (e : Q($α)) → Type /-- A coefficient `value`, which must not be `0`. `e` is a raw rat cast. If `value` is not an integer, then `hyp` should be a proof of `(value.den : α) ≠ 0`. -/ \| const {sα} {e} (value : ℚ) (hyp : Option Expr := none) : ExProd sα e /-- A product `x ^ e * b` is a monomial if `b` is a monomial. Here `x` is an `ExBase` and `e` is an `ExProd` representing a monomial expression in `ℕ` (it is a monomial instead of a polynomial because we eagerly normalize `x ^ (a + b) = x ^ a * x ^ b`.) -/ \| mul {u : Lean.Level} {α : Q(Type u)} {sα} {x : Q($α)} {e : Q(ℕ)} {b : Q($α)} : ExBase sα x → ExProd sℕ e → ExProd sα b → ExProd sα q($x ^ $e * $b) /-- A polynomial expression, which is a sum of monomials. -/ inductive ExSum : ∀ {u : Lean.Level} {α : Q(Type u)}, Q(CommSemiring $α) → (e : Q($α)) → Type /-- Zero is a polynomial. `e` is the expression `0`. -/ \| zero {u : Lean.Level} {α : Q(Type u)} {sα : Q(CommSemiring $α)} : ExSum sα q(0 : $α) /-- A sum `a + b` is a polynomial if `a` is a monomial and `b` is another polynomial. -/ \| add {u : Lean.Level} {α : Q(Type u)} {sα : Q(CommSemiring $α)} {a b : Q($α)} : ExProd sα a → ExSum sα b → ExSum sα q($a + $b) end mutual -- partial only to speed up compilation /-- Equality test for expressions. This is not a `BEq` instance because it is heterogeneous. -/ partial def ExBase.eq {u : Lean.Level} {α : Q(Type u)} {sα : Q(CommSemiring $α)} {a b : Q($α)} : ExBase sα a → ExBase sα b → Bool \| .atom i, .atom j => i == j \| .sum a, .sum b => a.eq b \| _, _ => false @[inherit_doc ExBase.eq] partial def ExProd.eq {u : Lean.Level} {α : Q(Type u)} {sα : Q(CommSemiring $α)} {a b : Q($α)} : ExProd sα a → ExProd sα b → Bool \| .const i _, .const j _ => i == j \| .mul a₁ a₂ a₃, .mul b₁ b₂ b₃ => a₁.eq b₁ && a₂.eq b₂ && a₃.eq b₃ \| _, _ => false @[inherit_doc ExBase.eq] partial def ExSum.eq {u : Lean.Level} {α : Q(Type u)} {sα : Q(CommSemiring $α)} {a b : Q($α)} : ExSum sα a → ExSum sα b → Bool \| .zero, .zero => true \| .add a₁ a₂, .add b₁ b₂ => a₁.eq b₁ && a₂.eq b₂ \| _, _ => false end mutual -- partial only to speed up compilation /-- A total order on normalized expressions. This is not an `Ord` instance because it is heterogeneous. -/ partial def ExBase.cmp {u : Lean.Level} {α : Q(Type u)} {sα : Q(CommSemiring $α)} {a b : Q($α)} : ExBase sα a → ExBase sα b → Ordering \| .atom i, .atom j => compare i j \| .sum a, .sum b => a.cmp b \| .atom .., .sum .. => .lt \| .sum .., .atom .. => .gt @[inherit_doc ExBase.cmp] partial def ExProd.cmp {u : Lean.Level} {α : Q(Type u)} {sα : Q(CommSemiring $α)} {a b : Q($α)} : ExProd sα a → ExProd sα b → Ordering \| .const i _, .const j _ => compare i j \| .mul a₁ a₂ a₃, .mul b₁ b₂ b₃ => (a₁.cmp b₁).then (a₂.cmp b₂) \|>.then (a₃.cmp b₃) \| .const _ _, .mul .. => .lt \| .mul .., .const _ _ => .gt @[inherit_doc ExBase.cmp] partial def ExSum.cmp {u : Lean.Level} {α : Q(Type u)} {sα : Q(CommSemiring $α)} {a b : Q($α)} : ExSum sα a → ExSum sα b → Ordering \| .zero, .zero => .eq \| .add a₁ a₂, .add b₁ b₂ => (a₁.cmp b₁).then (a₂.cmp b₂) \| .zero, .add .. => .lt \| .add .., .zero => .gt end variable {u : Lean.Level} {α : Q(Type u)} {sα : Q(CommSemiring $α)} instance : Inhabited (Σ e, (ExBase sα) e) := ⟨default, .atom 0⟩ instance : Inhabited (Σ e, (ExSum sα) e) := ⟨_, .zero⟩ instance : Inhabited (Σ e, (ExProd sα) e) := ⟨default, .const 0 none⟩ mutual /-- Converts `ExBase sα` to `ExBase sβ`, assuming `sα` and `sβ` are defeq. -/ partial def ExBase.cast {v : Lean.Level} {β : Q(Type v)} {sβ : Q(CommSemiring $β)} {a : Q($α)} : ExBase sα a → Σ a, ExBase sβ a \| .atom i => ⟨a, .atom i⟩ \| .sum a => let ⟨_, vb⟩ := a.cast; ⟨_, .sum vb⟩ /-- Converts `ExProd sα` to `ExProd sβ`, assuming `sα` and `sβ` are defeq. -/ partial def ExProd.cast {v : Lean.Level} {β : Q(Type v)} {sβ : Q(CommSemiring $β)} {a : Q($α)} : ExProd sα a → Σ a, ExProd sβ a \| .const i h => ⟨a, .const i h⟩ \| .mul a₁ a₂ a₃ => ⟨_, .mul a₁.cast.2 a₂ a₃.cast.2⟩ /-- Converts `ExSum sα` to `ExSum sβ`, assuming `sα` and `sβ` are defeq. -/ partial def ExSum.cast {v : Lean.Level} {β : Q(Type v)} {sβ : Q(CommSemiring $β)} {a : Q($α)} : ExSum sα a → Σ a, ExSum sβ a \| .zero => ⟨_, .zero⟩ \| .add a₁ a₂ => ⟨_, .add a₁.cast.2 a₂.cast.2⟩ end variable {u : Lean.Level} /-- The result of evaluating an (unnormalized) expression `e` into the type family `E` (one of `ExSum`, `ExProd`, `ExBase`) is a (normalized) element `e'` and a representation `E e'` for it, and a proof of `e = e'`. -/ structure Result {α : Q(Type u)} (E : Q($α) → Type) (e : Q($α)) where /-- The normalized result. -/ expr : Q($α) /-- The data associated to the normalization. -/ val : E expr /-- A proof that the original expression is equal to the normalized result. -/ proof : Q($e = $expr) instance {α : Q(Type u)} {E : Q($α) → Type} {e : Q($α)} [Inhabited (Σ e, E e)] : Inhabited (Result E e) := let ⟨e', v⟩ : Σ e, E e := default; ⟨e', v, default⟩ variable {α : Q(Type u)} (sα : Q(CommSemiring $α)) {R : Type} [CommSemiring R] /-- Constructs the expression corresponding to `.const n`. (The `.const` constructor does not check that the expression is correct.) -/ def ExProd.mkNat (n : ℕ) : (e : Q($α)) × ExProd sα e := let lit : Q(ℕ) := mkRawNatLit n ⟨q(($lit).rawCast : $α), .const n none⟩ /-- Constructs the expression corresponding to `.const (-n)`. (The `.const` constructor does not check that the expression is correct.) -/ def ExProd.mkNegNat (_ : Q(Ring $α)) (n : ℕ) : (e : Q($α)) × ExProd sα e := let lit : Q(ℕ) := mkRawNatLit n ⟨q((Int.negOfNat $lit).rawCast : $α), .const (-n) none⟩ /-- Constructs the expression corresponding to `.const q h` for `q = n / d` and `h` a proof that `(d : α) ≠ 0`. (The `.const` constructor does not check that the expression is correct.) -/ def ExProd.mkRat (_ : Q(DivisionRing $α)) (q : ℚ) (n : Q(ℤ)) (d : Q(ℕ)) (h : Expr) : (e : Q($α)) × ExProd sα e := ⟨q(Rat.rawCast $n $d : $α), .const q h⟩ section /-- Embed an exponent (an `ExBase, ExProd` pair) as an `ExProd` by multiplying by 1. -/ def ExBase.toProd {α : Q(Type u)} {sα : Q(CommSemiring $α)} {a : Q($α)} {b : Q(ℕ)} (va : ExBase sα a) (vb : ExProd sℕ b) : ExProd sα q($a ^ $b (nat_lit 1).rawCast) := .mul va vb (.const 1 none) /-- Embed `ExProd` in `ExSum` by adding 0. -/ def ExProd.toSum {sα : Q(CommSemiring $α)} {e : Q($α)} (v : ExProd sα e) : ExSum sα q($e + 0) := .add v .zero /-- Get the leading coefficient of an `ExProd`. -/ def ExProd.coeff {sα : Q(CommSemiring $α)} {e : Q($α)} : ExProd sα e → ℚ \| .const q _ => q \| .mul _ _ v => v.coeff end /-- Two monomials are said to "overlap" if they differ by a constant factor, in which case the constants just add. When this happens, the constant may be either zero (if the monomials cancel) or nonzero (if they add up); the zero case is handled specially. -/ inductive Overlap (e : Q($α)) where /-- The expression `e` (the sum of monomials) is equal to `0`. -/ \| zero (_ : Q(IsNat $e (nat_lit 0))) /-- The expression `e` (the sum of monomials) is equal to another monomial (with nonzero leading coefficient). -/ \| nonzero (_ : Result (ExProd sα) e) variable {a a' a₁ a₂ a₃ b b' b₁ b₂ b₃ c c₁ c₂ : R} theorem add_overlap_pf (x : R) (e) (pq_pf : a + b = c) : x ^ e * a + x ^ e * b = x ^ e * c := by subst_vars; simp [mul_add] theorem add_overlap_pf_zero (x : R) (e) : IsNat (a + b) (nat_lit 0) → IsNat (x ^ e * a + x ^ e * b) (nat_lit 0)	\| ⟨h⟩ => ⟨by simp [h, ← mul_add]⟩	Mathlib/Tactic/Ring/Basic.lean	312	312
/- Copyright (c) 2015 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Leonardo de Moura, Mario Carneiro -/ import Mathlib.Data.Set.Function import Mathlib.Logic.Equiv.Defs import Mathlib.Tactic.Says /-! # Equivalences and sets In this file we provide lemmas linking equivalences to sets. Some notable definitions are: * `Equiv.ofInjective`: an injective function is (noncomputably) equivalent to its range. * `Equiv.setCongr`: two equal sets are equivalent as types. * `Equiv.Set.union`: a disjoint union of sets is equivalent to their `Sum`. This file is separate from `Equiv/Basic` such that we do not require the full lattice structure on sets before defining what an equivalence is. -/ open Function Set universe u v w z variable {α : Sort u} {β : Sort v} {γ : Sort w} namespace EquivLike @[simp] theorem range_eq_univ {α : Type} {β : Type} {E : Type} [EquivLike E α β] (e : E) : range e = univ := eq_univ_of_forall (EquivLike.toEquiv e).surjective end EquivLike namespace Equiv theorem range_eq_univ {α : Type} {β : Type} (e : α ≃ β) : range e = univ := EquivLike.range_eq_univ e protected theorem image_eq_preimage {α β} (e : α ≃ β) (s : Set α) : e '' s = e.symm ⁻¹' s := Set.ext fun _ => mem_image_iff_of_inverse e.left_inv e.right_inv @[simp 1001] theorem _root_.Set.mem_image_equiv {α β} {S : Set α} {f : α ≃ β} {x : β} : x ∈ f '' S ↔ f.symm x ∈ S := Set.ext_iff.mp (f.image_eq_preimage S) x /-- Alias for `Equiv.image_eq_preimage` -/ theorem _root_.Set.image_equiv_eq_preimage_symm {α β} (S : Set α) (f : α ≃ β) : f '' S = f.symm ⁻¹' S := f.image_eq_preimage S /-- Alias for `Equiv.image_eq_preimage` -/ theorem _root_.Set.preimage_equiv_eq_image_symm {α β} (S : Set α) (f : β ≃ α) : f ⁻¹' S = f.symm '' S := (f.symm.image_eq_preimage S).symm -- Increased priority so this fires before `image_subset_iff` @[simp high] protected theorem symm_image_subset {α β} (e : α ≃ β) (s : Set α) (t : Set β) : e.symm '' t ⊆ s ↔ t ⊆ e '' s := by rw [image_subset_iff, e.image_eq_preimage] -- Increased priority so this fires before `image_subset_iff` @[simp high] protected theorem subset_symm_image {α β} (e : α ≃ β) (s : Set α) (t : Set β) : s ⊆ e.symm '' t ↔ e '' s ⊆ t := calc s ⊆ e.symm '' t ↔ e.symm.symm '' s ⊆ t := by rw [e.symm.symm_image_subset] _ ↔ e '' s ⊆ t := by rw [e.symm_symm] @[simp] theorem symm_image_image {α β} (e : α ≃ β) (s : Set α) : e.symm '' (e '' s) = s := e.leftInverse_symm.image_image s theorem eq_image_iff_symm_image_eq {α β} (e : α ≃ β) (s : Set α) (t : Set β) : t = e '' s ↔ e.symm '' t = s := (e.symm.injective.image_injective.eq_iff' (e.symm_image_image s)).symm @[simp] theorem image_symm_image {α β} (e : α ≃ β) (s : Set β) : e '' (e.symm '' s) = s := e.symm.symm_image_image s @[simp] theorem image_preimage {α β} (e : α ≃ β) (s : Set β) : e '' (e ⁻¹' s) = s := e.surjective.image_preimage s @[simp] theorem preimage_image {α β} (e : α ≃ β) (s : Set α) : e ⁻¹' (e '' s) = s := e.injective.preimage_image s protected theorem image_compl {α β} (f : Equiv α β) (s : Set α) : f '' sᶜ = (f '' s)ᶜ := image_compl_eq f.bijective @[simp] theorem symm_preimage_preimage {α β} (e : α ≃ β) (s : Set β) : e.symm ⁻¹' (e ⁻¹' s) = s := e.rightInverse_symm.preimage_preimage s @[simp] theorem preimage_symm_preimage {α β} (e : α ≃ β) (s : Set α) : e ⁻¹' (e.symm ⁻¹' s) = s := e.leftInverse_symm.preimage_preimage s theorem preimage_subset {α β} (e : α ≃ β) (s t : Set β) : e ⁻¹' s ⊆ e ⁻¹' t ↔ s ⊆ t := e.surjective.preimage_subset_preimage_iff theorem image_subset {α β} (e : α ≃ β) (s t : Set α) : e '' s ⊆ e '' t ↔ s ⊆ t := image_subset_image_iff e.injective @[simp] theorem image_eq_iff_eq {α β} (e : α ≃ β) (s t : Set α) : e '' s = e '' t ↔ s = t := image_eq_image e.injective theorem preimage_eq_iff_eq_image {α β} (e : α ≃ β) (s t) : e ⁻¹' s = t ↔ s = e '' t := Set.preimage_eq_iff_eq_image e.bijective theorem eq_preimage_iff_image_eq {α β} (e : α ≃ β) (s t) : s = e ⁻¹' t ↔ e '' s = t := Set.eq_preimage_iff_image_eq e.bijective lemma setOf_apply_symm_eq_image_setOf {α β} (e : α ≃ β) (p : α → Prop) : {b \| p (e.symm b)} = e '' {a \| p a} := by rw [Equiv.image_eq_preimage, preimage_setOf_eq] @[simp] theorem prod_assoc_preimage {α β γ} {s : Set α} {t : Set β} {u : Set γ} : Equiv.prodAssoc α β γ ⁻¹' s ×ˢ t ×ˢ u = (s ×ˢ t) ×ˢ u := by ext simp [and_assoc] @[simp] theorem prod_assoc_symm_preimage {α β γ} {s : Set α} {t : Set β} {u : Set γ} : (Equiv.prodAssoc α β γ).symm ⁻¹' (s ×ˢ t) ×ˢ u = s ×ˢ t ×ˢ u := by ext simp [and_assoc] -- `@[simp]` doesn't like these lemmas, as it uses `Set.image_congr'` to turn `Equiv.prodAssoc` -- into a lambda expression and then unfold it. theorem prod_assoc_image {α β γ} {s : Set α} {t : Set β} {u : Set γ} : Equiv.prodAssoc α β γ '' (s ×ˢ t) ×ˢ u = s ×ˢ t ×ˢ u := by simpa only [Equiv.image_eq_preimage] using prod_assoc_symm_preimage theorem prod_assoc_symm_image {α β γ} {s : Set α} {t : Set β} {u : Set γ} : (Equiv.prodAssoc α β γ).symm '' s ×ˢ t ×ˢ u = (s ×ˢ t) ×ˢ u := by simpa only [Equiv.image_eq_preimage] using prod_assoc_preimage /-- A set `s` in `α × β` is equivalent to the sigma-type `Σ x, {y \| (x, y) ∈ s}`. -/ def setProdEquivSigma {α β : Type} (s : Set (α × β)) : s ≃ Σx : α, { y : β \| (x, y) ∈ s } where toFun x := ⟨x.1.1, x.1.2, by simp⟩ invFun x := ⟨(x.1, x.2.1), x.2.2⟩ left_inv := fun ⟨⟨_, _⟩, _⟩ => rfl right_inv := fun ⟨_, _, _⟩ => rfl /-- The subtypes corresponding to equal sets are equivalent. -/ @[simps! apply symm_apply] def setCongr {α : Type} {s t : Set α} (h : s = t) : s ≃ t := subtypeEquivProp h -- We could construct this using `Equiv.Set.image e s e.injective`, -- but this definition provides an explicit inverse. /-- A set is equivalent to its image under an equivalence. -/ @[simps] def image {α β : Type} (e : α ≃ β) (s : Set α) : s ≃ e '' s where toFun x := ⟨e x.1, by simp⟩ invFun y := ⟨e.symm y.1, by rcases y with ⟨-, ⟨a, ⟨m, rfl⟩⟩⟩ simpa using m⟩ left_inv x := by simp right_inv y := by simp namespace Set /-- `univ α` is equivalent to `α`. -/ @[simps apply symm_apply] protected def univ (α) : @univ α ≃ α := ⟨Subtype.val, fun a => ⟨a, trivial⟩, fun ⟨_, _⟩ => rfl, fun _ => rfl⟩ /-- An empty set is equivalent to the `Empty` type. -/ protected def empty (α) : (∅ : Set α) ≃ Empty := equivEmpty _ /-- An empty set is equivalent to a `PEmpty` type. -/ protected def pempty (α) : (∅ : Set α) ≃ PEmpty := equivPEmpty _ /-- If sets `s` and `t` are separated by a decidable predicate, then `s ∪ t` is equivalent to `s ⊕ t`. -/ protected def union' {α} {s t : Set α} (p : α → Prop) [DecidablePred p] (hs : ∀ x ∈ s, p x) (ht : ∀ x ∈ t, ¬p x) : (s ∪ t : Set α) ≃ s ⊕ t where toFun x := if hp : p x then Sum.inl ⟨_, x.2.resolve_right fun xt => ht _ xt hp⟩ else Sum.inr ⟨_, x.2.resolve_left fun xs => hp (hs _ xs)⟩ invFun o := match o with \| Sum.inl x => ⟨x, Or.inl x.2⟩ \| Sum.inr x => ⟨x, Or.inr x.2⟩ left_inv := fun ⟨x, h'⟩ => by by_cases h : p x <;> simp [h] right_inv o := by rcases o with (⟨x, h⟩ \| ⟨x, h⟩) <;> [simp [hs _ h]; simp [ht _ h]] /-- If sets `s` and `t` are disjoint, then `s ∪ t` is equivalent to `s ⊕ t`. -/ protected def union {α} {s t : Set α} [DecidablePred fun x => x ∈ s] (H : Disjoint s t) : (s ∪ t : Set α) ≃ s ⊕ t := Set.union' (fun x => x ∈ s) (fun _ => id) fun _ xt xs => Set.disjoint_left.mp H xs xt theorem union_apply_left {α} {s t : Set α} [DecidablePred fun x => x ∈ s] (H : Disjoint s t) {a : (s ∪ t : Set α)} (ha : ↑a ∈ s) : Equiv.Set.union H a = Sum.inl ⟨a, ha⟩ := dif_pos ha theorem union_apply_right {α} {s t : Set α} [DecidablePred fun x => x ∈ s] (H : Disjoint s t) {a : (s ∪ t : Set α)} (ha : ↑a ∈ t) : Equiv.Set.union H a = Sum.inr ⟨a, ha⟩ := dif_neg fun h => Set.disjoint_left.mp H h ha @[simp] theorem union_symm_apply_left {α} {s t : Set α} [DecidablePred fun x => x ∈ s] (H : Disjoint s t) (a : s) : (Equiv.Set.union H).symm (Sum.inl a) = ⟨a, by simp⟩ := rfl @[simp] theorem union_symm_apply_right {α} {s t : Set α} [DecidablePred fun x => x ∈ s] (H : Disjoint s t) (a : t) : (Equiv.Set.union H).symm (Sum.inr a) = ⟨a, by simp⟩ := rfl /-- A singleton set is equivalent to a `PUnit` type. -/ protected def singleton {α} (a : α) : ({a} : Set α) ≃ PUnit.{u} := ⟨fun _ => PUnit.unit, fun _ => ⟨a, mem_singleton _⟩, fun ⟨x, h⟩ => by simp? at h says simp only [mem_singleton_iff] at h subst x rfl, fun ⟨⟩ => rfl⟩ @[deprecated (since := "2025-03-19"), simps! apply symm_apply] protected alias ofEq := Equiv.setCongr attribute [deprecated Equiv.setCongr_apply (since := "2025-03-19")] Set.ofEq_apply attribute [deprecated Equiv.setCongr_symm_apply (since := "2025-03-19")] Set.ofEq_symm_apply lemma Equiv.strictMono_setCongr {α : Type} [Preorder α] {S T : Set α} (h : S = T) : StrictMono (setCongr h) := fun _ _ ↦ id /-- If `a ∉ s`, then `insert a s` is equivalent to `s ⊕ PUnit`. -/ protected def insert {α} {s : Set.{u} α} [DecidablePred (· ∈ s)] {a : α} (H : a ∉ s) : (insert a s : Set α) ≃ s ⊕ PUnit.{u + 1} := calc (insert a s : Set α) ≃ ↥(s ∪ {a}) := Equiv.setCongr (by simp) _ ≃ s ⊕ ({a} : Set α) := Equiv.Set.union <\| by simpa _ ≃ s ⊕ PUnit.{u + 1} := sumCongr (Equiv.refl _) (Equiv.Set.singleton _) @[simp] theorem insert_symm_apply_inl {α} {s : Set.{u} α} [DecidablePred (· ∈ s)] {a : α} (H : a ∉ s) (b : s) : (Equiv.Set.insert H).symm (Sum.inl b) = ⟨b, Or.inr b.2⟩ := rfl @[simp] theorem insert_symm_apply_inr {α} {s : Set.{u} α} [DecidablePred (· ∈ s)] {a : α} (H : a ∉ s) (b : PUnit.{u + 1}) : (Equiv.Set.insert H).symm (Sum.inr b) = ⟨a, Or.inl rfl⟩ := rfl @[simp] theorem insert_apply_left {α} {s : Set.{u} α} [DecidablePred (· ∈ s)] {a : α} (H : a ∉ s) : Equiv.Set.insert H ⟨a, Or.inl rfl⟩ = Sum.inr PUnit.unit := (Equiv.Set.insert H).apply_eq_iff_eq_symm_apply.2 rfl @[simp] theorem insert_apply_right {α} {s : Set.{u} α} [DecidablePred (· ∈ s)] {a : α} (H : a ∉ s) (b : s) : Equiv.Set.insert H ⟨b, Or.inr b.2⟩ = Sum.inl b := (Equiv.Set.insert H).apply_eq_iff_eq_symm_apply.2 rfl /-- If `s : Set α` is a set with decidable membership, then `s ⊕ sᶜ` is equivalent to `α`. -/ protected def sumCompl {α} (s : Set α) [DecidablePred (· ∈ s)] : s ⊕ (sᶜ : Set α) ≃ α := calc s ⊕ (sᶜ : Set α) ≃ ↥(s ∪ sᶜ) := (Equiv.Set.union disjoint_compl_right).symm _ ≃ @univ α := Equiv.setCongr (by simp) _ ≃ α := Equiv.Set.univ _ @[simp] theorem sumCompl_apply_inl {α : Type u} (s : Set α) [DecidablePred (· ∈ s)] (x : s) : Equiv.Set.sumCompl s (Sum.inl x) = x := rfl @[simp] theorem sumCompl_apply_inr {α : Type u} (s : Set α) [DecidablePred (· ∈ s)] (x : (sᶜ : Set α)) : Equiv.Set.sumCompl s (Sum.inr x) = x := rfl theorem sumCompl_symm_apply_of_mem {α : Type u} {s : Set α} [DecidablePred (· ∈ s)] {x : α} (hx : x ∈ s) : (Equiv.Set.sumCompl s).symm x = Sum.inl ⟨x, hx⟩ := by simp [Equiv.Set.sumCompl, Equiv.Set.univ, union_apply_left, hx] theorem sumCompl_symm_apply_of_not_mem {α : Type u} {s : Set α} [DecidablePred (· ∈ s)] {x : α} (hx : x ∉ s) : (Equiv.Set.sumCompl s).symm x = Sum.inr ⟨x, hx⟩ := by simp [Equiv.Set.sumCompl, Equiv.Set.univ, union_apply_right, hx] @[simp] theorem sumCompl_symm_apply {α : Type} {s : Set α} [DecidablePred (· ∈ s)] {x : s} : (Equiv.Set.sumCompl s).symm x = Sum.inl x := Set.sumCompl_symm_apply_of_mem x.2 @[simp] theorem sumCompl_symm_apply_compl {α : Type*} {s : Set α} [DecidablePred (· ∈ s)] {x : (sᶜ : Set α)} : (Equiv.Set.sumCompl s).symm x = Sum.inr x := Set.sumCompl_symm_apply_of_not_mem x.2 /-- `sumDiffSubset s t` is the natural equivalence between `s ⊕ (t \ s)` and `t`, where `s` and `t` are two sets. -/ protected def sumDiffSubset {α} {s t : Set α} (h : s ⊆ t) [DecidablePred (· ∈ s)] : s ⊕ (t \ s : Set α) ≃ t := calc s ⊕ (t \ s : Set α) ≃ (s ∪ t \ s : Set α) := (Equiv.Set.union disjoint_sdiff_self_right).symm _ ≃ t := Equiv.setCongr (by simp [union_diff_self, union_eq_self_of_subset_left h]) @[simp] theorem sumDiffSubset_apply_inl {α} {s t : Set α} (h : s ⊆ t) [DecidablePred (· ∈ s)] (x : s) : Equiv.Set.sumDiffSubset h (Sum.inl x) = inclusion h x := rfl @[simp] theorem sumDiffSubset_apply_inr {α} {s t : Set α} (h : s ⊆ t) [DecidablePred (· ∈ s)] (x : (t \ s : Set α)) : Equiv.Set.sumDiffSubset h (Sum.inr x) = inclusion diff_subset x := rfl theorem sumDiffSubset_symm_apply_of_mem {α} {s t : Set α} (h : s ⊆ t) [DecidablePred (· ∈ s)] {x : t} (hx : x.1 ∈ s) : (Equiv.Set.sumDiffSubset h).symm x = Sum.inl ⟨x, hx⟩ := by apply (Equiv.Set.sumDiffSubset h).injective simp only [apply_symm_apply, sumDiffSubset_apply_inl, Set.inclusion_mk] theorem sumDiffSubset_symm_apply_of_not_mem {α} {s t : Set α} (h : s ⊆ t) [DecidablePred (· ∈ s)] {x : t} (hx : x.1 ∉ s) : (Equiv.Set.sumDiffSubset h).symm x = Sum.inr ⟨x, ⟨x.2, hx⟩⟩ := by apply (Equiv.Set.sumDiffSubset h).injective simp only [apply_symm_apply, sumDiffSubset_apply_inr, Set.inclusion_mk] /-- If `s` is a set with decidable membership, then the sum of `s ∪ t` and `s ∩ t` is equivalent to `s ⊕ t`. -/ protected def unionSumInter {α : Type u} (s t : Set α) [DecidablePred (· ∈ s)] : (s ∪ t : Set α) ⊕ (s ∩ t : Set α) ≃ s ⊕ t := calc	(s ∪ t : Set α) ⊕ (s ∩ t : Set α) ≃ (s ∪ t \ s : Set α) ⊕ (s ∩ t : Set α) := by rw [union_diff_self] _ ≃ (s ⊕ (t \ s : Set α)) ⊕ (s ∩ t : Set α) := sumCongr (Set.union disjoint_sdiff_self_right) (Equiv.refl _) _ ≃ s ⊕ ((t \ s : Set α) ⊕ (s ∩ t : Set α)) := sumAssoc _ _ _	Mathlib/Logic/Equiv/Set.lean	345	349
/- Copyright (c) 2019 Kenny Lau. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kenny Lau, Johan Commelin -/ import Mathlib.Algebra.MvPolynomial.Equiv import Mathlib.Algebra.MvPolynomial.CommRing import Mathlib.Logic.Equiv.Functor import Mathlib.RingTheory.FreeRing /-! # Free commutative rings The theory of the free commutative ring generated by a type `α`. It is isomorphic to the polynomial ring over ℤ with variables in `α` ## Main definitions * `FreeCommRing α` : the free commutative ring on a type α * `lift (f : α → R)` : the ring hom `FreeCommRing α →+* R` induced by functoriality from `f`. * `map (f : α → β)` : the ring hom `FreeCommRing α →+ FreeCommRing β` induced by functoriality from f. ## Main results `FreeCommRing` has functorial properties (it is an adjoint to the forgetful functor). In this file we have: `of : α → FreeCommRing α` * `lift (f : α → R) : FreeCommRing α →+* R` * `map (f : α → β) : FreeCommRing α →+* FreeCommRing β` * `freeCommRingEquivMvPolynomialInt : FreeCommRing α ≃+* MvPolynomial α ℤ` : `FreeCommRing α` is isomorphic to a polynomial ring. ## Implementation notes `FreeCommRing α` is implemented not using `MvPolynomial` but directly as the free abelian group on `Multiset α`, the type of monomials in this free commutative ring. ## Tags free commutative ring, free ring -/ noncomputable section open Polynomial universe u v variable (α : Type u) /-- If `α` is a type, then `FreeCommRing α` is the free commutative ring generated by `α`. This is a commutative ring equipped with a function `FreeCommRing.of : α → FreeCommRing α` which has the following universal property: if `R` is any commutative ring, and `f : α → R` is any function, then this function is the composite of `FreeCommRing.of` and a unique ring homomorphism `FreeCommRing.lift f : FreeCommRing α →+* R`. A typical element of `FreeCommRing α` is a `ℤ`-linear combination of formal products of elements of `α`. For example if `x` and `y` are terms of type `α` then `3 * x * x * y - 2 * x * y + 1` is a "typical" element of `FreeCommRing α`. In particular if `α` is empty then `FreeCommRing α` is isomorphic to `ℤ`, and if `α` has one term `t` then `FreeCommRing α` is isomorphic to the polynomial ring `ℤ[t]`. One can think of `FreeRing α` as the free polynomial ring with coefficients in the integers and variables indexed by `α`. -/ def FreeCommRing (α : Type u) : Type u := FreeAbelianGroup <\| Multiplicative <\| Multiset α -- The `CommRing, Inhabited` instances should be constructed by a deriving handler. -- https://github.com/leanprover-community/mathlib4/issues/380 instance FreeCommRing.instCommRing : CommRing (FreeCommRing α) := by delta FreeCommRing; infer_instance instance FreeCommRing.instInhabited : Inhabited (FreeCommRing α) := by delta FreeCommRing; infer_instance namespace FreeCommRing variable {α} /-- The canonical map from `α` to the free commutative ring on `α`. -/ def of (x : α) : FreeCommRing α := FreeAbelianGroup.of <\| Multiplicative.ofAdd ({x} : Multiset α) theorem of_injective : Function.Injective (of : α → FreeCommRing α) := FreeAbelianGroup.of_injective.comp fun _ _ => (Multiset.coe_eq_coe.trans List.singleton_perm_singleton).mp @[simp] theorem of_ne_zero (x : α) : of x ≠ 0 := FreeAbelianGroup.of_ne_zero _ @[simp] theorem zero_ne_of (x : α) : 0 ≠ of x := FreeAbelianGroup.zero_ne_of _ @[simp] theorem of_ne_one (x : α) : of x ≠ 1 := FreeAbelianGroup.of_injective.ne <\| Multiset.singleton_ne_zero _ @[simp] theorem one_ne_of (x : α) : 1 ≠ of x := FreeAbelianGroup.of_injective.ne <\| Multiset.zero_ne_singleton _ -- Porting note: added to ease a proof in `Mathlib.Algebra.Colimit.Ring` lemma of_cons (a : α) (m : Multiset α) : (FreeAbelianGroup.of (Multiplicative.ofAdd (a ::ₘ m))) = @HMul.hMul _ (FreeCommRing α) (FreeCommRing α) _ (of a) (FreeAbelianGroup.of (Multiplicative.ofAdd m)) := by dsimp [FreeCommRing] rw [← Multiset.singleton_add, ofAdd_add, of, FreeAbelianGroup.of_mul_of] @[elab_as_elim, induction_eliminator] protected theorem induction_on {motive : FreeCommRing α → Prop} (z : FreeCommRing α) (neg_one : motive (-1)) (of : ∀ b, motive (of b)) (add : ∀ x y, motive x → motive y → motive (x + y)) (mul : ∀ x y, motive x → motive y → motive (x * y)) : motive z := have neg : ∀ x, motive x → motive (-x) := fun x ih => neg_one_mul x ▸ mul _ _ neg_one ih have one : motive 1 := neg_neg (1 : FreeCommRing α) ▸ neg _ neg_one FreeAbelianGroup.induction_on z (neg_add_cancel (1 : FreeCommRing α) ▸ add _ _ neg_one one) (fun m => Multiset.induction_on m one fun a m ih => by convert mul (FreeCommRing.of a) _ (of a) ih apply of_cons) (fun _ ih => neg _ ih) add section lift variable {R : Type v} [CommRing R] (f : α → R) /-- A helper to implement `lift`. This is essentially `FreeCommMonoid.lift`, but this does not currently exist. -/ private def liftToMultiset : (α → R) ≃ (Multiplicative (Multiset α) →* R) where toFun f := { toFun := fun s => (s.toAdd.map f).prod map_mul' := fun x y => calc _ = Multiset.prod (Multiset.map f x + Multiset.map f y) := by rw [← Multiset.map_add] rfl _ = _ := Multiset.prod_add _ _ map_one' := rfl } invFun F x := F (Multiplicative.ofAdd ({x} : Multiset α)) left_inv f := funext fun x => show (Multiset.map f {x}).prod = _ by simp right_inv F := MonoidHom.ext fun x => let F' := MonoidHom.toAdditive'' F let x' := x.toAdd show (Multiset.map (fun a => F' {a}) x').sum = F' x' by rw [← Function.comp_def (fun x => F' x) (fun x => {x}), ← Multiset.map_map, ← AddMonoidHom.map_multiset_sum] exact DFunLike.congr_arg F (Multiset.sum_map_singleton x') /-- Lift a map `α → R` to an additive group homomorphism `FreeCommRing α → R`. -/ def lift : (α → R) ≃ (FreeCommRing α →+* R) := Equiv.trans liftToMultiset FreeAbelianGroup.liftMonoid @[simp] theorem lift_of (x : α) : lift f (of x) = f x := (FreeAbelianGroup.lift.of _ _).trans <\| mul_one _ @[simp] theorem lift_comp_of (f : FreeCommRing α →+* R) : lift (f ∘ of) = f := RingHom.ext fun x => FreeCommRing.induction_on x (by rw [RingHom.map_neg, RingHom.map_one, f.map_neg, f.map_one]) (lift_of _) (fun x y ihx ihy => by rw [RingHom.map_add, f.map_add, ihx, ihy]) fun x y ihx ihy => by rw [RingHom.map_mul, f.map_mul, ihx, ihy] @[ext 1100] theorem hom_ext ⦃f g : FreeCommRing α →+* R⦄ (h : ∀ x, f (of x) = g (of x)) : f = g := lift.symm.injective (funext h) end lift variable {β : Type v} (f : α → β) /-- A map `f : α → β` produces a ring homomorphism `FreeCommRing α →+* FreeCommRing β`. -/ def map : FreeCommRing α →+* FreeCommRing β := lift <\| of ∘ f @[simp] theorem map_of (x : α) : map f (of x) = of (f x) := lift_of _ _ /-- `is_supported x s` means that all monomials showing up in `x` have variables in `s`. -/ def IsSupported (x : FreeCommRing α) (s : Set α) : Prop := x ∈ Subring.closure (of '' s) section IsSupported variable {x y : FreeCommRing α} {s t : Set α} theorem isSupported_upwards (hs : IsSupported x s) (hst : s ⊆ t) : IsSupported x t := Subring.closure_mono (Set.monotone_image hst) hs theorem isSupported_add (hxs : IsSupported x s) (hys : IsSupported y s) : IsSupported (x + y) s := Subring.add_mem _ hxs hys theorem isSupported_neg (hxs : IsSupported x s) : IsSupported (-x) s := Subring.neg_mem _ hxs theorem isSupported_sub (hxs : IsSupported x s) (hys : IsSupported y s) : IsSupported (x - y) s := Subring.sub_mem _ hxs hys theorem isSupported_mul (hxs : IsSupported x s) (hys : IsSupported y s) : IsSupported (x * y) s := Subring.mul_mem _ hxs hys theorem isSupported_zero : IsSupported 0 s := Subring.zero_mem _ theorem isSupported_one : IsSupported 1 s := Subring.one_mem _ theorem isSupported_int {i : ℤ} {s : Set α} : IsSupported (↑i) s := Int.induction_on i isSupported_zero (fun i hi => by rw [Int.cast_add, Int.cast_one]; exact isSupported_add hi isSupported_one) fun i hi => by rw [Int.cast_sub, Int.cast_one]; exact isSupported_sub hi isSupported_one end IsSupported /-- The restriction map from `FreeCommRing α` to `FreeCommRing s` where `s : Set α`, defined by sending all variables not in `s` to zero. -/ def restriction (s : Set α) [DecidablePred (· ∈ s)] : FreeCommRing α →+* FreeCommRing s := lift (fun a => if H : a ∈ s then of ⟨a, H⟩ else 0) section Restriction variable (s : Set α) [DecidablePred (· ∈ s)] (x y : FreeCommRing α) @[simp] theorem restriction_of (p) : restriction s (of p) = if H : p ∈ s then of ⟨p, H⟩ else 0 := lift_of _ _ end Restriction theorem isSupported_of {p} {s : Set α} : IsSupported (of p) s ↔ p ∈ s := suffices IsSupported (of p) s → p ∈ s from ⟨this, fun hps => Subring.subset_closure ⟨p, hps, rfl⟩⟩ fun hps : IsSupported (of p) s => by classical haveI := Classical.decPred s have : ∀ x, IsSupported x s → ∃ n : ℤ, lift (fun a => if a ∈ s then (0 : ℤ[X]) else Polynomial.X) x = n := by intro x hx refine Subring.InClosure.recOn hx ?_ ?_ ?_ ?_ · use 1 rw [RingHom.map_one] norm_cast · use -1 rw [RingHom.map_neg, RingHom.map_one, Int.cast_neg, Int.cast_one] · rintro _ ⟨z, hzs, rfl⟩ _ _ use 0 rw [RingHom.map_mul, lift_of, if_pos hzs, zero_mul] norm_cast · rintro x y ⟨q, hq⟩ ⟨r, hr⟩ refine ⟨q + r, ?_⟩ rw [RingHom.map_add, hq, hr] norm_cast specialize this (of p) hps rw [lift_of] at this split_ifs at this with h · exact h exfalso apply Ne.symm Int.zero_ne_one rcases this with ⟨w, H⟩ rw [← Polynomial.C_eq_intCast] at H have : Polynomial.X.coeff 1 = (Polynomial.C ↑w).coeff 1 := by rw [H]; rfl rwa [Polynomial.coeff_C, if_neg (one_ne_zero : 1 ≠ 0), Polynomial.coeff_X, if_pos rfl] at this -- Porting note: Changed `(Subtype.val : s → α)` to `(↑)` in the type theorem map_subtype_val_restriction {x} (s : Set α) [DecidablePred (· ∈ s)] (hxs : IsSupported x s) : map (↑) (restriction s x) = x := by refine Subring.InClosure.recOn hxs ?_ ?_ ?_ ?_ · rw [RingHom.map_one] rfl · rw [map_neg, map_one] rfl · rintro _ ⟨p, hps, rfl⟩ n ih rw [RingHom.map_mul, restriction_of, dif_pos hps, RingHom.map_mul, map_of, ih] · intro x y ihx ihy rw [RingHom.map_add, RingHom.map_add, ihx, ihy] theorem exists_finite_support (x : FreeCommRing α) : ∃ s : Set α, Set.Finite s ∧ IsSupported x s := FreeCommRing.induction_on x ⟨∅, Set.finite_empty, isSupported_neg isSupported_one⟩ (fun p => ⟨{p}, Set.finite_singleton p, isSupported_of.2 <\| Set.mem_singleton _⟩) (fun _ _ ⟨s, hfs, hxs⟩ ⟨t, hft, hxt⟩ => ⟨s ∪ t, hfs.union hft, isSupported_add (isSupported_upwards hxs Set.subset_union_left) (isSupported_upwards hxt Set.subset_union_right)⟩) fun _ _ ⟨s, hfs, hxs⟩ ⟨t, hft, hxt⟩ => ⟨s ∪ t, hfs.union hft, isSupported_mul (isSupported_upwards hxs Set.subset_union_left) (isSupported_upwards hxt Set.subset_union_right)⟩ theorem exists_finset_support (x : FreeCommRing α) : ∃ s : Finset α, IsSupported x ↑s := let ⟨s, hfs, hxs⟩ := exists_finite_support x ⟨hfs.toFinset, by rwa [Set.Finite.coe_toFinset]⟩ end FreeCommRing namespace FreeRing open Function /-- The canonical ring homomorphism from the free ring generated by `α` to the free commutative ring generated by `α`. -/ def toFreeCommRing {α} : FreeRing α →+* FreeCommRing α := FreeRing.lift FreeCommRing.of /-- The coercion defined by the canonical ring homomorphism from the free ring generated by `α` to the free commutative ring generated by `α`. -/ @[coe] def castFreeCommRing {α} : FreeRing α → FreeCommRing α := toFreeCommRing instance FreeCommRing.instCoe : Coe (FreeRing α) (FreeCommRing α) := ⟨castFreeCommRing⟩ /-- The natural map `FreeRing α → FreeCommRing α`, as a `RingHom`. -/ def coeRingHom : FreeRing α →+* FreeCommRing α := toFreeCommRing @[simp, norm_cast] protected theorem coe_zero : ↑(0 : FreeRing α) = (0 : FreeCommRing α) := rfl @[simp, norm_cast] protected theorem coe_one : ↑(1 : FreeRing α) = (1 : FreeCommRing α) := rfl variable {α} @[simp] protected theorem coe_of (a : α) : ↑(FreeRing.of a) = FreeCommRing.of a := FreeRing.lift_of _ _ @[simp, norm_cast] protected theorem coe_neg (x : FreeRing α) : ↑(-x) = -(x : FreeCommRing α) := by rw [castFreeCommRing, map_neg] @[simp, norm_cast] protected theorem coe_add (x y : FreeRing α) : ↑(x + y) = (x : FreeCommRing α) + y := (FreeRing.lift _).map_add _ _ @[simp, norm_cast] protected theorem coe_sub (x y : FreeRing α) : ↑(x - y) = (x : FreeCommRing α) - y := by rw [castFreeCommRing, map_sub] @[simp, norm_cast] protected theorem coe_mul (x y : FreeRing α) : ↑(x * y) = (x : FreeCommRing α) * y :=	(FreeRing.lift _).map_mul _ _	Mathlib/RingTheory/FreeCommRing.lean	351	352
/- Copyright (c) 2020 Fox Thomson. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Fox Thomson, Markus Himmel -/ import Mathlib.SetTheory.Game.Birthday import Mathlib.SetTheory.Game.Impartial import Mathlib.SetTheory.Nimber.Basic /-! # Nim and the Sprague-Grundy theorem This file contains the definition for nim for any ordinal `o`. In the game of `nim o₁` both players may move to `nim o₂` for any `o₂ < o₁`. We also define a Grundy value for an impartial game `G` and prove the Sprague-Grundy theorem, that `G` is equivalent to `nim (grundyValue G)`. Finally, we prove that the grundy value of a sum `G + H` corresponds to the nimber sum of the individual grundy values. ## Implementation details The pen-and-paper definition of nim defines the possible moves of `nim o` to be `Set.Iio o`. However, this definition does not work for us because it would make the type of nim `Ordinal.{u} → SetTheory.PGame.{u + 1}`, which would make it impossible for us to state the Sprague-Grundy theorem, since that requires the type of `nim` to be `Ordinal.{u} → SetTheory.PGame.{u}`. For this reason, we instead use `o.toType` for the possible moves. We expose `toLeftMovesNim` and `toRightMovesNim` to conveniently convert an ordinal less than `o` into a left or right move of `nim o`, and vice versa. -/ noncomputable section universe u namespace SetTheory open scoped PGame open Ordinal Nimber namespace PGame /-- The definition of single-heap nim, which can be viewed as a pile of stones where each player can take a positive number of stones from it on their turn. -/ noncomputable def nim (o : Ordinal.{u}) : PGame.{u} := ⟨o.toType, o.toType, fun x => nim ((enumIsoToType o).symm x).val, fun x => nim ((enumIsoToType o).symm x).val⟩ termination_by o decreasing_by all_goals exact ((enumIsoToType o).symm x).prop @[deprecated "you can use `rw [nim]` directly" (since := "2025-01-23")] theorem nim_def (o : Ordinal) : nim o = ⟨o.toType, o.toType, fun x => nim ((enumIsoToType o).symm x).val, fun x => nim ((enumIsoToType o).symm x).val⟩ := by rw [nim] theorem leftMoves_nim (o : Ordinal) : (nim o).LeftMoves = o.toType := by rw [nim]; rfl theorem rightMoves_nim (o : Ordinal) : (nim o).RightMoves = o.toType := by rw [nim]; rfl theorem moveLeft_nim_hEq (o : Ordinal) : HEq (nim o).moveLeft fun i : o.toType => nim ((enumIsoToType o).symm i) := by rw [nim]; rfl theorem moveRight_nim_hEq (o : Ordinal) : HEq (nim o).moveRight fun i : o.toType => nim ((enumIsoToType o).symm i) := by rw [nim]; rfl /-- Turns an ordinal less than `o` into a left move for `nim o` and vice versa. -/ noncomputable def toLeftMovesNim {o : Ordinal} : Set.Iio o ≃ (nim o).LeftMoves := (enumIsoToType o).toEquiv.trans (Equiv.cast (leftMoves_nim o).symm) /-- Turns an ordinal less than `o` into a right move for `nim o` and vice versa. -/ noncomputable def toRightMovesNim {o : Ordinal} : Set.Iio o ≃ (nim o).RightMoves := (enumIsoToType o).toEquiv.trans (Equiv.cast (rightMoves_nim o).symm) @[simp] theorem toLeftMovesNim_symm_lt {o : Ordinal} (i : (nim o).LeftMoves) : toLeftMovesNim.symm i < o := (toLeftMovesNim.symm i).prop @[simp] theorem toRightMovesNim_symm_lt {o : Ordinal} (i : (nim o).RightMoves) : toRightMovesNim.symm i < o := (toRightMovesNim.symm i).prop @[simp] theorem moveLeft_nim {o : Ordinal} (i) : (nim o).moveLeft i = nim (toLeftMovesNim.symm i).val := (congr_heq (moveLeft_nim_hEq o).symm (cast_heq _ i)).symm @[deprecated moveLeft_nim (since := "2024-10-30")] alias moveLeft_nim' := moveLeft_nim theorem moveLeft_toLeftMovesNim {o : Ordinal} (i) : (nim o).moveLeft (toLeftMovesNim i) = nim i := by simp @[simp] theorem moveRight_nim {o : Ordinal} (i) : (nim o).moveRight i = nim (toRightMovesNim.symm i).val := (congr_heq (moveRight_nim_hEq o).symm (cast_heq _ i)).symm @[deprecated moveRight_nim (since := "2024-10-30")] alias moveRight_nim' := moveRight_nim theorem moveRight_toRightMovesNim {o : Ordinal} (i) : (nim o).moveRight (toRightMovesNim i) = nim i := by simp /-- A recursion principle for left moves of a nim game. -/ @[elab_as_elim] def leftMovesNimRecOn {o : Ordinal} {P : (nim o).LeftMoves → Sort} (i : (nim o).LeftMoves) (H : ∀ a (H : a < o), P <\| toLeftMovesNim ⟨a, H⟩) : P i := by rw [← toLeftMovesNim.apply_symm_apply i]; apply H /-- A recursion principle for right moves of a nim game. -/ @[elab_as_elim] def rightMovesNimRecOn {o : Ordinal} {P : (nim o).RightMoves → Sort} (i : (nim o).RightMoves) (H : ∀ a (H : a < o), P <\| toRightMovesNim ⟨a, H⟩) : P i := by rw [← toRightMovesNim.apply_symm_apply i]; apply H instance isEmpty_nim_zero_leftMoves : IsEmpty (nim 0).LeftMoves := by rw [nim] exact isEmpty_toType_zero instance isEmpty_nim_zero_rightMoves : IsEmpty (nim 0).RightMoves := by rw [nim] exact isEmpty_toType_zero /-- `nim 0` has exactly the same moves as `0`. -/ def nimZeroRelabelling : nim 0 ≡r 0 := Relabelling.isEmpty _ theorem nim_zero_equiv : nim 0 ≈ 0 := Equiv.isEmpty _ noncomputable instance uniqueNimOneLeftMoves : Unique (nim 1).LeftMoves := (Equiv.cast <\| leftMoves_nim 1).unique noncomputable instance uniqueNimOneRightMoves : Unique (nim 1).RightMoves := (Equiv.cast <\| rightMoves_nim 1).unique @[simp] theorem default_nim_one_leftMoves_eq : (default : (nim 1).LeftMoves) = @toLeftMovesNim 1 ⟨0, Set.mem_Iio.mpr zero_lt_one⟩ := rfl @[simp] theorem default_nim_one_rightMoves_eq : (default : (nim 1).RightMoves) = @toRightMovesNim 1 ⟨0, Set.mem_Iio.mpr zero_lt_one⟩ := rfl @[simp] theorem toLeftMovesNim_one_symm (i) : (@toLeftMovesNim 1).symm i = ⟨0, Set.mem_Iio.mpr zero_lt_one⟩ := by simp [eq_iff_true_of_subsingleton] @[simp] theorem toRightMovesNim_one_symm (i) : (@toRightMovesNim 1).symm i = ⟨0, Set.mem_Iio.mpr zero_lt_one⟩ := by simp [eq_iff_true_of_subsingleton] theorem nim_one_moveLeft (x) : (nim 1).moveLeft x = nim 0 := by simp theorem nim_one_moveRight (x) : (nim 1).moveRight x = nim 0 := by simp /-- `nim 1` has exactly the same moves as `star`. -/ def nimOneRelabelling : nim 1 ≡r star := by rw [nim] refine ⟨?_, ?_, fun i => ?_, fun j => ?_⟩ any_goals dsimp; apply Equiv.ofUnique all_goals simpa [enumIsoToType] using nimZeroRelabelling theorem nim_one_equiv : nim 1 ≈ star := nimOneRelabelling.equiv @[simp] theorem nim_birthday (o : Ordinal) : (nim o).birthday = o := by induction' o using Ordinal.induction with o IH rw [nim, birthday_def] dsimp rw [max_eq_right le_rfl] convert lsub_typein o with i exact IH _ (typein_lt_self i) @[simp] theorem neg_nim (o : Ordinal) : -nim o = nim o := by induction' o using Ordinal.induction with o IH rw [nim]; dsimp; congr <;> funext i <;> exact IH _ (Ordinal.typein_lt_self i) instance impartial_nim (o : Ordinal) : Impartial (nim o) := by induction' o using Ordinal.induction with o IH rw [impartial_def, neg_nim] refine ⟨equiv_rfl, fun i => ?_, fun i => ?_⟩ <;> simpa using IH _ (typein_lt_self _) theorem nim_fuzzy_zero_of_ne_zero {o : Ordinal} (ho : o ≠ 0) : nim o ‖ 0 := by rw [Impartial.fuzzy_zero_iff_lf, lf_zero_le] use toRightMovesNim ⟨0, Ordinal.pos_iff_ne_zero.2 ho⟩ simp @[simp] theorem nim_add_equiv_zero_iff (o₁ o₂ : Ordinal) : (nim o₁ + nim o₂ ≈ 0) ↔ o₁ = o₂ := by constructor · refine not_imp_not.1 fun hne : _ ≠ _ => (Impartial.not_equiv_zero_iff (nim o₁ + nim o₂)).2 ?_ wlog h : o₁ < o₂ · exact (fuzzy_congr_left add_comm_equiv).1 (this _ _ hne.symm (hne.lt_or_lt.resolve_left h)) rw [Impartial.fuzzy_zero_iff_gf, zero_lf_le] use toLeftMovesAdd (Sum.inr <\| toLeftMovesNim ⟨_, h⟩) · simpa using (Impartial.add_self (nim o₁)).2 · rintro rfl exact Impartial.add_self (nim o₁) @[simp] theorem nim_add_fuzzy_zero_iff {o₁ o₂ : Ordinal} : nim o₁ + nim o₂ ‖ 0 ↔ o₁ ≠ o₂ := by rw [iff_not_comm, Impartial.not_fuzzy_zero_iff, nim_add_equiv_zero_iff] @[simp] theorem nim_equiv_iff_eq {o₁ o₂ : Ordinal} : (nim o₁ ≈ nim o₂) ↔ o₁ = o₂ := by rw [Impartial.equiv_iff_add_equiv_zero, nim_add_equiv_zero_iff] /-- The Grundy value of an impartial game is recursively defined as the minimum excluded value (the infimum of the complement) of the Grundy values of either its left or right options. This is the ordinal which corresponds to the game of nim that the game is equivalent to. This function takes a value in `Nimber`. This is a type synonym for the ordinals which has the same ordering, but addition in `Nimber` is such that it corresponds to the grundy value of the addition of games. See that file for more information on nimbers and their arithmetic. -/ noncomputable def grundyValue (G : PGame.{u}) : Nimber.{u} := sInf (Set.range fun i => grundyValue (G.moveLeft i))ᶜ termination_by G theorem grundyValue_eq_sInf_moveLeft (G : PGame) : grundyValue G = sInf (Set.range (grundyValue ∘ G.moveLeft))ᶜ := by rw [grundyValue]; rfl theorem grundyValue_ne_moveLeft {G : PGame} (i : G.LeftMoves) : grundyValue (G.moveLeft i) ≠ grundyValue G := by conv_rhs => rw [grundyValue_eq_sInf_moveLeft] have := csInf_mem (nonempty_of_not_bddAbove <\| Nimber.not_bddAbove_compl_of_small (Set.range fun i => grundyValue (G.moveLeft i))) rw [Set.mem_compl_iff, Set.mem_range, not_exists] at this exact this _ theorem le_grundyValue_of_Iio_subset_moveLeft {G : PGame} {o : Nimber} (h : Set.Iio o ⊆ Set.range (grundyValue ∘ G.moveLeft)) : o ≤ grundyValue G := by by_contra! ho obtain ⟨i, hi⟩ := h ho exact grundyValue_ne_moveLeft i hi theorem exists_grundyValue_moveLeft_of_lt {G : PGame} {o : Nimber} (h : o < grundyValue G) : ∃ i, grundyValue (G.moveLeft i) = o := by rw [grundyValue_eq_sInf_moveLeft] at h by_contra ha exact h.not_le (csInf_le' ha) theorem grundyValue_le_of_forall_moveLeft {G : PGame} {o : Nimber} (h : ∀ i, grundyValue (G.moveLeft i) ≠ o) : G.grundyValue ≤ o := by contrapose! h exact exists_grundyValue_moveLeft_of_lt h /-- The Sprague-Grundy theorem states that every impartial game is equivalent to a game of nim, namely the game of nim corresponding to the game's Grundy value. -/ theorem equiv_nim_grundyValue (G : PGame.{u}) [G.Impartial] : G ≈ nim (toOrdinal (grundyValue G)) := by rw [Impartial.equiv_iff_add_equiv_zero, ← Impartial.forall_leftMoves_fuzzy_iff_equiv_zero] intro x apply leftMoves_add_cases x <;> intro i · rw [add_moveLeft_inl, ← fuzzy_congr_left (add_congr_left (Equiv.symm (equiv_nim_grundyValue _))), nim_add_fuzzy_zero_iff] exact grundyValue_ne_moveLeft i · rw [add_moveLeft_inr, ← Impartial.exists_left_move_equiv_iff_fuzzy_zero] obtain ⟨j, hj⟩ := exists_grundyValue_moveLeft_of_lt <\| toLeftMovesNim_symm_lt i use toLeftMovesAdd (Sum.inl j) rw [add_moveLeft_inl, moveLeft_nim] exact Equiv.trans (add_congr_left (equiv_nim_grundyValue _)) (hj ▸ Impartial.add_self _) termination_by G theorem grundyValue_eq_iff_equiv_nim {G : PGame} [G.Impartial] {o : Nimber} : grundyValue G = o ↔ G ≈ nim (toOrdinal o) := ⟨by rintro rfl; exact equiv_nim_grundyValue G, by intro h; rw [← nim_equiv_iff_eq]; exact Equiv.trans (Equiv.symm (equiv_nim_grundyValue G)) h⟩ @[simp] theorem nim_grundyValue (o : Ordinal.{u}) : grundyValue (nim o) = ∗o := grundyValue_eq_iff_equiv_nim.2 PGame.equiv_rfl theorem grundyValue_eq_iff_equiv (G H : PGame) [G.Impartial] [H.Impartial] : grundyValue G = grundyValue H ↔ (G ≈ H) := grundyValue_eq_iff_equiv_nim.trans (equiv_congr_left.1 (equiv_nim_grundyValue H) _).symm @[simp] theorem grundyValue_zero : grundyValue 0 = 0 := grundyValue_eq_iff_equiv_nim.2 (Equiv.symm nim_zero_equiv) theorem grundyValue_iff_equiv_zero (G : PGame) [G.Impartial] : grundyValue G = 0 ↔ G ≈ 0 := by rw [← grundyValue_eq_iff_equiv, grundyValue_zero] @[simp] theorem grundyValue_star : grundyValue star = 1 := grundyValue_eq_iff_equiv_nim.2 (Equiv.symm nim_one_equiv) @[simp] theorem grundyValue_neg (G : PGame) [G.Impartial] : grundyValue (-G) = grundyValue G := by rw [grundyValue_eq_iff_equiv_nim, neg_equiv_iff, neg_nim, ← grundyValue_eq_iff_equiv_nim] theorem grundyValue_eq_sInf_moveRight (G : PGame) [G.Impartial] : grundyValue G = sInf (Set.range (grundyValue ∘ G.moveRight))ᶜ := by obtain ⟨l, r, L, R⟩ := G rw [← grundyValue_neg, grundyValue_eq_sInf_moveLeft] iterate 3 apply congr_arg ext i exact @grundyValue_neg _ (@Impartial.moveRight_impartial ⟨l, r, L, R⟩ _ _) theorem grundyValue_ne_moveRight {G : PGame} [G.Impartial] (i : G.RightMoves) : grundyValue (G.moveRight i) ≠ grundyValue G := by convert grundyValue_ne_moveLeft (toLeftMovesNeg i) using 1 <;> simp theorem le_grundyValue_of_Iio_subset_moveRight {G : PGame} [G.Impartial] {o : Nimber} (h : Set.Iio o ⊆ Set.range (grundyValue ∘ G.moveRight)) : o ≤ grundyValue G := by by_contra! ho obtain ⟨i, hi⟩ := h ho exact grundyValue_ne_moveRight i hi theorem exists_grundyValue_moveRight_of_lt {G : PGame} [G.Impartial] {o : Nimber} (h : o < grundyValue G) : ∃ i, grundyValue (G.moveRight i) = o := by rw [← grundyValue_neg] at h obtain ⟨i, hi⟩ := exists_grundyValue_moveLeft_of_lt h use toLeftMovesNeg.symm i rwa [← grundyValue_neg, ← moveLeft_neg] theorem grundyValue_le_of_forall_moveRight {G : PGame} [G.Impartial] {o : Nimber} (h : ∀ i, grundyValue (G.moveRight i) ≠ o) : G.grundyValue ≤ o := by contrapose! h exact exists_grundyValue_moveRight_of_lt h /-- The Grundy value of the sum of two nim games equals their nimber addition. -/ theorem grundyValue_nim_add_nim (x y : Ordinal) : grundyValue (nim x + nim y) = ∗x + ∗y := by apply (grundyValue_le_of_forall_moveLeft _).antisymm (le_grundyValue_of_Iio_subset_moveLeft _) · intro i apply leftMoves_add_cases i <;> intro j <;> have := (toLeftMovesNim_symm_lt j).ne · simpa [grundyValue_nim_add_nim (toLeftMovesNim.symm j) y] · simpa [grundyValue_nim_add_nim x (toLeftMovesNim.symm j)] · intro k hk obtain h \| h := Nimber.lt_add_cases hk · let a := toOrdinal (k + ∗y) use toLeftMovesAdd (Sum.inl (toLeftMovesNim ⟨a, h⟩)) simp [a, grundyValue_nim_add_nim a y] · let a := toOrdinal (k + ∗x) use toLeftMovesAdd (Sum.inr (toLeftMovesNim ⟨a, h⟩)) simp [a, grundyValue_nim_add_nim x a, add_comm (∗x)] termination_by (x, y) theorem nim_add_nim_equiv (x y : Ordinal) : nim x + nim y ≈ nim (toOrdinal (∗x + ∗y)) := by rw [← grundyValue_eq_iff_equiv_nim, grundyValue_nim_add_nim] @[simp] theorem grundyValue_add (G H : PGame) [G.Impartial] [H.Impartial] : grundyValue (G + H) = grundyValue G + grundyValue H := by rw [← (grundyValue G).toOrdinal_toNimber, ← (grundyValue H).toOrdinal_toNimber,	← grundyValue_nim_add_nim, grundyValue_eq_iff_equiv] exact add_congr (equiv_nim_grundyValue G) (equiv_nim_grundyValue H) end PGame end SetTheory	Mathlib/SetTheory/Game/Nim.lean	362	398
/- Copyright (c) 2020 Anne Baanen. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Anne Baanen, Kexing Ying, Eric Wieser -/ import Mathlib.Data.Finset.Sym import Mathlib.LinearAlgebra.BilinearMap import Mathlib.LinearAlgebra.FiniteDimensional.Lemmas import Mathlib.LinearAlgebra.Matrix.Determinant.Basic import Mathlib.LinearAlgebra.Matrix.SesquilinearForm import Mathlib.LinearAlgebra.Matrix.Symmetric /-! # Quadratic maps This file defines quadratic maps on an `R`-module `M`, taking values in an `R`-module `N`. An `N`-valued quadratic map on a module `M` over a commutative ring `R` is a map `Q : M → N` such that: * `QuadraticMap.map_smul`: `Q (a • x) = (a * a) • Q x` * `QuadraticMap.polar_add_left`, `QuadraticMap.polar_add_right`, `QuadraticMap.polar_smul_left`, `QuadraticMap.polar_smul_right`: the map `QuadraticMap.polar Q := fun x y ↦ Q (x + y) - Q x - Q y` is bilinear. This notion generalizes to commutative semirings using the approach in [izhakian2016][] which requires that there be a (possibly non-unique) companion bilinear map `B` such that `∀ x y, Q (x + y) = Q x + Q y + B x y`. Over a ring, this `B` is precisely `QuadraticMap.polar Q`. To build a `QuadraticMap` from the `polar` axioms, use `QuadraticMap.ofPolar`. Quadratic maps come with a scalar multiplication, `(a • Q) x = a • Q x`, and composition with linear maps `f`, `Q.comp f x = Q (f x)`. ## Main definitions * `QuadraticMap.ofPolar`: a more familiar constructor that works on rings * `QuadraticMap.associated`: associated bilinear map * `QuadraticMap.PosDef`: positive definite quadratic maps * `QuadraticMap.Anisotropic`: anisotropic quadratic maps * `QuadraticMap.discr`: discriminant of a quadratic map * `QuadraticMap.IsOrtho`: orthogonality of vectors with respect to a quadratic map. ## Main statements * `QuadraticMap.associated_left_inverse`, * `QuadraticMap.associated_rightInverse`: in a commutative ring where 2 has an inverse, there is a correspondence between quadratic maps and symmetric bilinear forms * `LinearMap.BilinForm.exists_orthogonal_basis`: There exists an orthogonal basis with respect to any nondegenerate, symmetric bilinear map `B`. ## Notation In this file, the variable `R` is used when a `CommSemiring` structure is available. The variable `S` is used when `R` itself has a `•` action. ## Implementation notes While the definition and many results make sense if we drop commutativity assumptions, the correct definition of a quadratic maps in the noncommutative setting would require substantial refactors from the current version, such that $Q(rm) = rQ(m)r^$ for some suitable conjugation $r^$. The [Zulip thread](https://leanprover.zulipchat.com/#narrow/stream/116395-maths/topic/Quadratic.20Maps/near/395529867) has some further discussion. ## References * https://en.wikipedia.org/wiki/Quadratic_form * https://en.wikipedia.org/wiki/Discriminant#Quadratic_forms ## Tags quadratic map, homogeneous polynomial, quadratic polynomial -/ universe u v w variable {S T : Type} variable {R : Type} {M N P A : Type*} open LinearMap (BilinMap BilinForm) section Polar variable [CommRing R] [AddCommGroup M] [AddCommGroup N] namespace QuadraticMap /-- Up to a factor 2, `Q.polar` is the associated bilinear map for a quadratic map `Q`. Source of this name: https://en.wikipedia.org/wiki/Quadratic_form#Generalization -/ def polar (f : M → N) (x y : M) := f (x + y) - f x - f y protected theorem map_add (f : M → N) (x y : M) : f (x + y) = f x + f y + polar f x y := by rw [polar] abel theorem polar_add (f g : M → N) (x y : M) : polar (f + g) x y = polar f x y + polar g x y := by simp only [polar, Pi.add_apply] abel theorem polar_neg (f : M → N) (x y : M) : polar (-f) x y = -polar f x y := by simp only [polar, Pi.neg_apply, sub_eq_add_neg, neg_add] theorem polar_smul [Monoid S] [DistribMulAction S N] (f : M → N) (s : S) (x y : M) : polar (s • f) x y = s • polar f x y := by simp only [polar, Pi.smul_apply, smul_sub] theorem polar_comm (f : M → N) (x y : M) : polar f x y = polar f y x := by rw [polar, polar, add_comm, sub_sub, sub_sub, add_comm (f x) (f y)] /-- Auxiliary lemma to express bilinearity of `QuadraticMap.polar` without subtraction. -/ theorem polar_add_left_iff {f : M → N} {x x' y : M} : polar f (x + x') y = polar f x y + polar f x' y ↔ f (x + x' + y) + (f x + f x' + f y) = f (x + x') + f (x' + y) + f (y + x) := by simp only [← add_assoc] simp only [polar, sub_eq_iff_eq_add, eq_sub_iff_add_eq, sub_add_eq_add_sub, add_sub] simp only [add_right_comm _ (f y) _, add_right_comm _ (f x') (f x)] rw [add_comm y x, add_right_comm _ _ (f (x + y)), add_comm _ (f (x + y)), add_right_comm (f (x + y)), add_left_inj]	theorem polar_comp {F : Type*} [AddCommGroup S] [FunLike F N S] [AddMonoidHomClass F N S] (f : M → N) (g : F) (x y : M) : polar (g ∘ f) x y = g (polar f x y) := by simp only [polar, Pi.smul_apply, Function.comp_apply, map_sub]	Mathlib/LinearAlgebra/QuadraticForm/Basic.lean	126	129
/- Copyright (c) 2021 Rémy Degenne. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Zhouhang Zhou, Yury Kudryashov -/ import Mathlib.MeasureTheory.Function.L1Space.Integrable import Mathlib.MeasureTheory.Function.LpSpace.Indicator /-! # Functions integrable on a set and at a filter We define `IntegrableOn f s μ := Integrable f (μ.restrict s)` and prove theorems like `integrableOn_union : IntegrableOn f (s ∪ t) μ ↔ IntegrableOn f s μ ∧ IntegrableOn f t μ`. Next we define a predicate `IntegrableAtFilter (f : α → E) (l : Filter α) (μ : Measure α)` saying that `f` is integrable at some set `s ∈ l` and prove that a measurable function is integrable at `l` with respect to `μ` provided that `f` is bounded above at `l ⊓ ae μ` and `μ` is finite at `l`. -/ noncomputable section open Set Filter TopologicalSpace MeasureTheory Function open scoped Topology Interval Filter ENNReal MeasureTheory variable {α β ε E F : Type} [MeasurableSpace α] [ENorm ε] [TopologicalSpace ε] section variable [TopologicalSpace β] {l l' : Filter α} {f g : α → β} {μ ν : Measure α} /-- A function `f` is strongly measurable at a filter `l` w.r.t. a measure `μ` if it is ae strongly measurable w.r.t. `μ.restrict s` for some `s ∈ l`. -/ def StronglyMeasurableAtFilter (f : α → β) (l : Filter α) (μ : Measure α := by volume_tac) := ∃ s ∈ l, AEStronglyMeasurable f (μ.restrict s) @[simp] theorem stronglyMeasurableAt_bot {f : α → β} : StronglyMeasurableAtFilter f ⊥ μ := ⟨∅, mem_bot, by simp⟩ protected theorem StronglyMeasurableAtFilter.eventually (h : StronglyMeasurableAtFilter f l μ) : ∀ᶠ s in l.smallSets, AEStronglyMeasurable f (μ.restrict s) := (eventually_smallSets' fun _ _ => AEStronglyMeasurable.mono_set).2 h protected theorem StronglyMeasurableAtFilter.filter_mono (h : StronglyMeasurableAtFilter f l μ) (h' : l' ≤ l) : StronglyMeasurableAtFilter f l' μ := let ⟨s, hsl, hs⟩ := h ⟨s, h' hsl, hs⟩ protected theorem MeasureTheory.AEStronglyMeasurable.stronglyMeasurableAtFilter (h : AEStronglyMeasurable f μ) : StronglyMeasurableAtFilter f l μ := ⟨univ, univ_mem, by rwa [Measure.restrict_univ]⟩ theorem AEStronglyMeasurable.stronglyMeasurableAtFilter_of_mem {s} (h : AEStronglyMeasurable f (μ.restrict s)) (hl : s ∈ l) : StronglyMeasurableAtFilter f l μ := ⟨s, hl, h⟩ @[deprecated (since := "2025-02-12")] alias AeStronglyMeasurable.stronglyMeasurableAtFilter_of_mem := AEStronglyMeasurable.stronglyMeasurableAtFilter_of_mem protected theorem MeasureTheory.StronglyMeasurable.stronglyMeasurableAtFilter (h : StronglyMeasurable f) : StronglyMeasurableAtFilter f l μ := h.aestronglyMeasurable.stronglyMeasurableAtFilter end namespace MeasureTheory section NormedAddCommGroup theorem hasFiniteIntegral_restrict_of_bounded [NormedAddCommGroup E] {f : α → E} {s : Set α} {μ : Measure α} {C} (hs : μ s < ∞) (hf : ∀ᵐ x ∂μ.restrict s, ‖f x‖ ≤ C) : HasFiniteIntegral f (μ.restrict s) := haveI : IsFiniteMeasure (μ.restrict s) := ⟨by rwa [Measure.restrict_apply_univ]⟩ hasFiniteIntegral_of_bounded hf variable [NormedAddCommGroup E] {f g : α → E} {s t : Set α} {μ ν : Measure α} /-- A function is `IntegrableOn` a set `s` if it is almost everywhere strongly measurable on `s` and if the integral of its pointwise norm over `s` is less than infinity. -/ def IntegrableOn (f : α → ε) (s : Set α) (μ : Measure α := by volume_tac) : Prop := Integrable f (μ.restrict s) theorem IntegrableOn.integrable (h : IntegrableOn f s μ) : Integrable f (μ.restrict s) := h @[simp] theorem integrableOn_empty : IntegrableOn f ∅ μ := by simp [IntegrableOn, integrable_zero_measure] @[simp] theorem integrableOn_univ : IntegrableOn f univ μ ↔ Integrable f μ := by rw [IntegrableOn, Measure.restrict_univ] theorem integrableOn_zero : IntegrableOn (fun _ => (0 : E)) s μ := integrable_zero _ _ _ @[simp] theorem integrableOn_const {C : E} : IntegrableOn (fun _ => C) s μ ↔ C = 0 ∨ μ s < ∞ := integrable_const_iff.trans <\| by rw [isFiniteMeasure_restrict, lt_top_iff_ne_top] theorem IntegrableOn.mono (h : IntegrableOn f t ν) (hs : s ⊆ t) (hμ : μ ≤ ν) : IntegrableOn f s μ := h.mono_measure <\| Measure.restrict_mono hs hμ theorem IntegrableOn.mono_set (h : IntegrableOn f t μ) (hst : s ⊆ t) : IntegrableOn f s μ := h.mono hst le_rfl theorem IntegrableOn.mono_measure (h : IntegrableOn f s ν) (hμ : μ ≤ ν) : IntegrableOn f s μ := h.mono (Subset.refl _) hμ theorem IntegrableOn.mono_set_ae (h : IntegrableOn f t μ) (hst : s ≤ᵐ[μ] t) : IntegrableOn f s μ := h.integrable.mono_measure <\| Measure.restrict_mono_ae hst theorem IntegrableOn.congr_set_ae (h : IntegrableOn f t μ) (hst : s =ᵐ[μ] t) : IntegrableOn f s μ := h.mono_set_ae hst.le theorem IntegrableOn.congr_fun_ae (h : IntegrableOn f s μ) (hst : f =ᵐ[μ.restrict s] g) : IntegrableOn g s μ := Integrable.congr h hst theorem integrableOn_congr_fun_ae (hst : f =ᵐ[μ.restrict s] g) : IntegrableOn f s μ ↔ IntegrableOn g s μ := ⟨fun h => h.congr_fun_ae hst, fun h => h.congr_fun_ae hst.symm⟩ theorem IntegrableOn.congr_fun (h : IntegrableOn f s μ) (hst : EqOn f g s) (hs : MeasurableSet s) : IntegrableOn g s μ := h.congr_fun_ae ((ae_restrict_iff' hs).2 (Eventually.of_forall hst)) theorem integrableOn_congr_fun (hst : EqOn f g s) (hs : MeasurableSet s) : IntegrableOn f s μ ↔ IntegrableOn g s μ := ⟨fun h => h.congr_fun hst hs, fun h => h.congr_fun hst.symm hs⟩ theorem Integrable.integrableOn (h : Integrable f μ) : IntegrableOn f s μ := h.restrict theorem IntegrableOn.restrict (h : IntegrableOn f s μ) : IntegrableOn f s (μ.restrict t) := by dsimp only [IntegrableOn] at h ⊢ exact h.mono_measure <\| Measure.restrict_mono_measure Measure.restrict_le_self _ theorem IntegrableOn.inter_of_restrict (h : IntegrableOn f s (μ.restrict t)) : IntegrableOn f (s ∩ t) μ := by have := h.mono_set (inter_subset_left (t := t)) rwa [IntegrableOn, μ.restrict_restrict_of_subset inter_subset_right] at this lemma Integrable.piecewise [DecidablePred (· ∈ s)] (hs : MeasurableSet s) (hf : IntegrableOn f s μ) (hg : IntegrableOn g sᶜ μ) : Integrable (s.piecewise f g) μ := by rw [IntegrableOn] at hf hg rw [← memLp_one_iff_integrable] at hf hg ⊢ exact MemLp.piecewise hs hf hg theorem IntegrableOn.left_of_union (h : IntegrableOn f (s ∪ t) μ) : IntegrableOn f s μ := h.mono_set subset_union_left theorem IntegrableOn.right_of_union (h : IntegrableOn f (s ∪ t) μ) : IntegrableOn f t μ := h.mono_set subset_union_right theorem IntegrableOn.union (hs : IntegrableOn f s μ) (ht : IntegrableOn f t μ) : IntegrableOn f (s ∪ t) μ := (hs.add_measure ht).mono_measure <\| Measure.restrict_union_le _ _ @[simp] theorem integrableOn_union : IntegrableOn f (s ∪ t) μ ↔ IntegrableOn f s μ ∧ IntegrableOn f t μ := ⟨fun h => ⟨h.left_of_union, h.right_of_union⟩, fun h => h.1.union h.2⟩ @[simp] theorem integrableOn_singleton_iff {x : α} [MeasurableSingletonClass α] : IntegrableOn f {x} μ ↔ f x = 0 ∨ μ {x} < ∞ := by have : f =ᵐ[μ.restrict {x}] fun _ => f x := by filter_upwards [ae_restrict_mem (measurableSet_singleton x)] with _ ha simp only [mem_singleton_iff.1 ha] rw [IntegrableOn, integrable_congr this, integrable_const_iff, isFiniteMeasure_restrict, lt_top_iff_ne_top] @[simp] theorem integrableOn_finite_biUnion {s : Set β} (hs : s.Finite) {t : β → Set α} : IntegrableOn f (⋃ i ∈ s, t i) μ ↔ ∀ i ∈ s, IntegrableOn f (t i) μ := by induction s, hs using Set.Finite.induction_on with \| empty => simp \| insert _ _ hf => simp [hf, or_imp, forall_and] @[simp] theorem integrableOn_finset_iUnion {s : Finset β} {t : β → Set α} : IntegrableOn f (⋃ i ∈ s, t i) μ ↔ ∀ i ∈ s, IntegrableOn f (t i) μ := integrableOn_finite_biUnion s.finite_toSet @[simp] theorem integrableOn_finite_iUnion [Finite β] {t : β → Set α} : IntegrableOn f (⋃ i, t i) μ ↔ ∀ i, IntegrableOn f (t i) μ := by cases nonempty_fintype β simpa using @integrableOn_finset_iUnion _ _ _ _ _ f μ Finset.univ t lemma IntegrableOn.finset [MeasurableSingletonClass α] {μ : Measure α} [IsFiniteMeasure μ] {s : Finset α} {f : α → E} : IntegrableOn f s μ := by rw [← s.toSet.biUnion_of_singleton] simp [integrableOn_finset_iUnion, measure_lt_top] lemma IntegrableOn.of_finite [MeasurableSingletonClass α] {μ : Measure α} [IsFiniteMeasure μ] {s : Set α} (hs : s.Finite) {f : α → E} : IntegrableOn f s μ := by simpa using IntegrableOn.finset (s := hs.toFinset) theorem IntegrableOn.add_measure (hμ : IntegrableOn f s μ) (hν : IntegrableOn f s ν) : IntegrableOn f s (μ + ν) := by delta IntegrableOn; rw [Measure.restrict_add]; exact hμ.integrable.add_measure hν @[simp] theorem integrableOn_add_measure : IntegrableOn f s (μ + ν) ↔ IntegrableOn f s μ ∧ IntegrableOn f s ν := ⟨fun h => ⟨h.mono_measure (Measure.le_add_right le_rfl), h.mono_measure (Measure.le_add_left le_rfl)⟩, fun h => h.1.add_measure h.2⟩ theorem _root_.MeasurableEmbedding.integrableOn_map_iff [MeasurableSpace β] {e : α → β} (he : MeasurableEmbedding e) {f : β → E} {μ : Measure α} {s : Set β} : IntegrableOn f s (μ.map e) ↔ IntegrableOn (f ∘ e) (e ⁻¹' s) μ := by simp_rw [IntegrableOn, he.restrict_map, he.integrable_map_iff] theorem _root_.MeasurableEmbedding.integrableOn_iff_comap [MeasurableSpace β] {e : α → β} (he : MeasurableEmbedding e) {f : β → E} {μ : Measure β} {s : Set β} (hs : s ⊆ range e) : IntegrableOn f s μ ↔ IntegrableOn (f ∘ e) (e ⁻¹' s) (μ.comap e) := by simp_rw [← he.integrableOn_map_iff, he.map_comap, IntegrableOn, Measure.restrict_restrict_of_subset hs] theorem _root_.MeasurableEmbedding.integrableOn_range_iff_comap [MeasurableSpace β] {e : α → β} (he : MeasurableEmbedding e) {f : β → E} {μ : Measure β} : IntegrableOn f (range e) μ ↔ Integrable (f ∘ e) (μ.comap e) := by rw [he.integrableOn_iff_comap .rfl, preimage_range, integrableOn_univ] theorem integrableOn_iff_comap_subtypeVal (hs : MeasurableSet s) : IntegrableOn f s μ ↔ Integrable (f ∘ (↑) : s → E) (μ.comap (↑)) := by rw [← (MeasurableEmbedding.subtype_coe hs).integrableOn_range_iff_comap, Subtype.range_val] theorem integrableOn_map_equiv [MeasurableSpace β] (e : α ≃ᵐ β) {f : β → E} {μ : Measure α} {s : Set β} : IntegrableOn f s (μ.map e) ↔ IntegrableOn (f ∘ e) (e ⁻¹' s) μ := by simp only [IntegrableOn, e.restrict_map, integrable_map_equiv e] theorem MeasurePreserving.integrableOn_comp_preimage [MeasurableSpace β] {e : α → β} {ν} (h₁ : MeasurePreserving e μ ν) (h₂ : MeasurableEmbedding e) {f : β → E} {s : Set β} : IntegrableOn (f ∘ e) (e ⁻¹' s) μ ↔ IntegrableOn f s ν := (h₁.restrict_preimage_emb h₂ s).integrable_comp_emb h₂ theorem MeasurePreserving.integrableOn_image [MeasurableSpace β] {e : α → β} {ν} (h₁ : MeasurePreserving e μ ν) (h₂ : MeasurableEmbedding e) {f : β → E} {s : Set α} : IntegrableOn f (e '' s) ν ↔ IntegrableOn (f ∘ e) s μ := ((h₁.restrict_image_emb h₂ s).integrable_comp_emb h₂).symm theorem integrable_indicator_iff (hs : MeasurableSet s) : Integrable (indicator s f) μ ↔ IntegrableOn f s μ := by simp_rw [IntegrableOn, Integrable, hasFiniteIntegral_iff_enorm, enorm_indicator_eq_indicator_enorm, lintegral_indicator hs, aestronglyMeasurable_indicator_iff hs] theorem IntegrableOn.integrable_indicator (h : IntegrableOn f s μ) (hs : MeasurableSet s) : Integrable (indicator s f) μ := (integrable_indicator_iff hs).2 h @[fun_prop] theorem Integrable.indicator (h : Integrable f μ) (hs : MeasurableSet s) : Integrable (indicator s f) μ := h.integrableOn.integrable_indicator hs theorem IntegrableOn.indicator (h : IntegrableOn f s μ) (ht : MeasurableSet t) : IntegrableOn (indicator t f) s μ := Integrable.indicator h ht theorem integrable_indicatorConstLp {E} [NormedAddCommGroup E] {p : ℝ≥0∞} {s : Set α} (hs : MeasurableSet s) (hμs : μ s ≠ ∞) (c : E) : Integrable (indicatorConstLp p hs hμs c) μ := by rw [integrable_congr indicatorConstLp_coeFn, integrable_indicator_iff hs, IntegrableOn, integrable_const_iff, isFiniteMeasure_restrict] exact .inr hμs /-- If a function is integrable on a set `s` and nonzero there, then the measurable hull of `s` is well behaved: the restriction of the measure to `toMeasurable μ s` coincides with its restriction to `s`. -/ theorem IntegrableOn.restrict_toMeasurable (hf : IntegrableOn f s μ) (h's : ∀ x ∈ s, f x ≠ 0) : μ.restrict (toMeasurable μ s) = μ.restrict s := by rcases exists_seq_strictAnti_tendsto (0 : ℝ) with ⟨u, _, u_pos, u_lim⟩ let v n := toMeasurable (μ.restrict s) { x \| u n ≤ ‖f x‖ } have A : ∀ n, μ (s ∩ v n) ≠ ∞ := by intro n rw [inter_comm, ← Measure.restrict_apply (measurableSet_toMeasurable _ _), measure_toMeasurable] exact (hf.measure_norm_ge_lt_top (u_pos n)).ne apply Measure.restrict_toMeasurable_of_cover _ A intro x hx have : 0 < ‖f x‖ := by simp only [h's x hx, norm_pos_iff, Ne, not_false_iff] obtain ⟨n, hn⟩ : ∃ n, u n < ‖f x‖ := ((tendsto_order.1 u_lim).2 _ this).exists exact mem_iUnion.2 ⟨n, subset_toMeasurable _ _ hn.le⟩ /-- If a function is integrable on a set `s`, and vanishes on `t \ s`, then it is integrable on `t` if `t` is null-measurable. -/ theorem IntegrableOn.of_ae_diff_eq_zero (hf : IntegrableOn f s μ) (ht : NullMeasurableSet t μ) (h't : ∀ᵐ x ∂μ, x ∈ t \ s → f x = 0) : IntegrableOn f t μ := by let u := { x ∈ s \| f x ≠ 0 } have hu : IntegrableOn f u μ := hf.mono_set fun x hx => hx.1 let v := toMeasurable μ u have A : IntegrableOn f v μ := by rw [IntegrableOn, hu.restrict_toMeasurable] · exact hu · intro x hx; exact hx.2 have B : IntegrableOn f (t \ v) μ := by apply integrableOn_zero.congr filter_upwards [ae_restrict_of_ae h't, ae_restrict_mem₀ (ht.diff (measurableSet_toMeasurable μ u).nullMeasurableSet)] with x hxt hx by_cases h'x : x ∈ s · by_contra H exact hx.2 (subset_toMeasurable μ u ⟨h'x, Ne.symm H⟩) · exact (hxt ⟨hx.1, h'x⟩).symm apply (A.union B).mono_set _ rw [union_diff_self] exact subset_union_right /-- If a function is integrable on a set `s`, and vanishes on `t \ s`, then it is integrable on `t` if `t` is measurable. -/ theorem IntegrableOn.of_forall_diff_eq_zero (hf : IntegrableOn f s μ) (ht : MeasurableSet t) (h't : ∀ x ∈ t \ s, f x = 0) : IntegrableOn f t μ := hf.of_ae_diff_eq_zero ht.nullMeasurableSet (Eventually.of_forall h't) /-- If a function is integrable on a set `s` and vanishes almost everywhere on its complement, then it is integrable. -/ theorem IntegrableOn.integrable_of_ae_not_mem_eq_zero (hf : IntegrableOn f s μ) (h't : ∀ᵐ x ∂μ, x ∉ s → f x = 0) : Integrable f μ := by rw [← integrableOn_univ] apply hf.of_ae_diff_eq_zero nullMeasurableSet_univ filter_upwards [h't] with x hx h'x using hx h'x.2 /-- If a function is integrable on a set `s` and vanishes everywhere on its complement, then it is integrable. -/ theorem IntegrableOn.integrable_of_forall_not_mem_eq_zero (hf : IntegrableOn f s μ) (h't : ∀ x, x ∉ s → f x = 0) : Integrable f μ := hf.integrable_of_ae_not_mem_eq_zero (Eventually.of_forall fun x hx => h't x hx) theorem integrableOn_iff_integrable_of_support_subset (h1s : support f ⊆ s) : IntegrableOn f s μ ↔ Integrable f μ := by refine ⟨fun h => ?_, fun h => h.integrableOn⟩ refine h.integrable_of_forall_not_mem_eq_zero fun x hx => ?_ contrapose! hx exact h1s (mem_support.2 hx) theorem integrableOn_Lp_of_measure_ne_top {E} [NormedAddCommGroup E] {p : ℝ≥0∞} {s : Set α} (f : Lp E p μ) (hp : 1 ≤ p) (hμs : μ s ≠ ∞) : IntegrableOn f s μ := by refine memLp_one_iff_integrable.mp ?_ have hμ_restrict_univ : (μ.restrict s) Set.univ < ∞ := by simpa only [Set.univ_inter, MeasurableSet.univ, Measure.restrict_apply, lt_top_iff_ne_top] haveI hμ_finite : IsFiniteMeasure (μ.restrict s) := ⟨hμ_restrict_univ⟩ exact ((Lp.memLp _).restrict s).mono_exponent hp theorem Integrable.lintegral_lt_top {f : α → ℝ} (hf : Integrable f μ) : (∫⁻ x, ENNReal.ofReal (f x) ∂μ) < ∞ := calc (∫⁻ x, ENNReal.ofReal (f x) ∂μ) ≤ ∫⁻ x, ↑‖f x‖₊ ∂μ := lintegral_ofReal_le_lintegral_enorm f _ < ∞ := hf.2 theorem IntegrableOn.setLIntegral_lt_top {f : α → ℝ} {s : Set α} (hf : IntegrableOn f s μ) : (∫⁻ x in s, ENNReal.ofReal (f x) ∂μ) < ∞ := Integrable.lintegral_lt_top hf /-- We say that a function `f` is integrable at filter* `l` if it is integrable on some set `s ∈ l`. Equivalently, it is eventually integrable on `s` in `l.smallSets`. -/ def IntegrableAtFilter (f : α → ε) (l : Filter α) (μ : Measure α := by volume_tac) := ∃ s ∈ l, IntegrableOn f s μ variable {l l' : Filter α} theorem _root_.MeasurableEmbedding.integrableAtFilter_map_iff [MeasurableSpace β] {e : α → β} (he : MeasurableEmbedding e) {f : β → E} : IntegrableAtFilter f (l.map e) (μ.map e) ↔ IntegrableAtFilter (f ∘ e) l μ := by simp_rw [IntegrableAtFilter, he.integrableOn_map_iff] constructor <;> rintro ⟨s, hs⟩ · exact ⟨_, hs⟩ · exact ⟨e '' s, by rwa [mem_map, he.injective.preimage_image]⟩ theorem _root_.MeasurableEmbedding.integrableAtFilter_iff_comap [MeasurableSpace β] {e : α → β} (he : MeasurableEmbedding e) {f : β → E} {μ : Measure β} : IntegrableAtFilter f (l.map e) μ ↔ IntegrableAtFilter (f ∘ e) l (μ.comap e) := by simp_rw [← he.integrableAtFilter_map_iff, IntegrableAtFilter, he.map_comap] constructor <;> rintro ⟨s, hs, int⟩ · exact ⟨s, hs, int.mono_measure <\| μ.restrict_le_self⟩ · exact ⟨_, inter_mem hs range_mem_map, int.inter_of_restrict⟩ theorem Integrable.integrableAtFilter (h : Integrable f μ) (l : Filter α) : IntegrableAtFilter f l μ := ⟨univ, Filter.univ_mem, integrableOn_univ.2 h⟩ protected theorem IntegrableAtFilter.eventually (h : IntegrableAtFilter f l μ) : ∀ᶠ s in l.smallSets, IntegrableOn f s μ := Iff.mpr (eventually_smallSets' fun _s _t hst ht => ht.mono_set hst) h theorem integrableAtFilter_atBot_iff [Preorder α] [IsDirected α fun (x1 x2 : α) => x1 ≥ x2] [Nonempty α] : IntegrableAtFilter f atBot μ ↔ ∃ a, IntegrableOn f (Iic a) μ := by refine ⟨fun ⟨s, hs, hi⟩ ↦ ?_, fun ⟨a, ha⟩ ↦ ⟨Iic a, Iic_mem_atBot a, ha⟩⟩ obtain ⟨t, ht⟩ := mem_atBot_sets.mp hs exact ⟨t, hi.mono_set fun _ hx ↦ ht _ hx⟩ theorem integrableAtFilter_atTop_iff [Preorder α] [IsDirected α fun (x1 x2 : α) => x1 ≤ x2] [Nonempty α] : IntegrableAtFilter f atTop μ ↔ ∃ a, IntegrableOn f (Ici a) μ := integrableAtFilter_atBot_iff (α := αᵒᵈ) protected theorem IntegrableAtFilter.add {f g : α → E} (hf : IntegrableAtFilter f l μ) (hg : IntegrableAtFilter g l μ) : IntegrableAtFilter (f + g) l μ := by rcases hf with ⟨s, sl, hs⟩ rcases hg with ⟨t, tl, ht⟩ refine ⟨s ∩ t, inter_mem sl tl, ?_⟩ exact (hs.mono_set inter_subset_left).add (ht.mono_set inter_subset_right) protected theorem IntegrableAtFilter.neg {f : α → E} (hf : IntegrableAtFilter f l μ) : IntegrableAtFilter (-f) l μ := by rcases hf with ⟨s, sl, hs⟩ exact ⟨s, sl, hs.neg⟩ protected theorem IntegrableAtFilter.sub {f g : α → E} (hf : IntegrableAtFilter f l μ) (hg : IntegrableAtFilter g l μ) : IntegrableAtFilter (f - g) l μ := by rw [sub_eq_add_neg] exact hf.add hg.neg protected theorem IntegrableAtFilter.smul {𝕜 : Type*} [NormedAddCommGroup 𝕜] [SMulZeroClass 𝕜 E] [IsBoundedSMul 𝕜 E] {f : α → E} (hf : IntegrableAtFilter f l μ) (c : 𝕜) : IntegrableAtFilter (c • f) l μ := by rcases hf with ⟨s, sl, hs⟩ exact ⟨s, sl, hs.smul c⟩ protected theorem IntegrableAtFilter.norm (hf : IntegrableAtFilter f l μ) : IntegrableAtFilter (fun x => ‖f x‖) l μ := Exists.casesOn hf fun s hs ↦ ⟨s, hs.1, hs.2.norm⟩ theorem IntegrableAtFilter.filter_mono (hl : l ≤ l') (hl' : IntegrableAtFilter f l' μ) : IntegrableAtFilter f l μ := let ⟨s, hs, hsf⟩ := hl' ⟨s, hl hs, hsf⟩ theorem IntegrableAtFilter.inf_of_left (hl : IntegrableAtFilter f l μ) : IntegrableAtFilter f (l ⊓ l') μ := hl.filter_mono inf_le_left theorem IntegrableAtFilter.inf_of_right (hl : IntegrableAtFilter f l μ) : IntegrableAtFilter f (l' ⊓ l) μ := hl.filter_mono inf_le_right @[simp] theorem IntegrableAtFilter.inf_ae_iff {l : Filter α} : IntegrableAtFilter f (l ⊓ ae μ) μ ↔ IntegrableAtFilter f l μ := by refine ⟨?_, fun h ↦ h.filter_mono inf_le_left⟩ rintro ⟨s, ⟨t, ht, u, hu, rfl⟩, hf⟩ refine ⟨t, ht, hf.congr_set_ae <\| eventuallyEq_set.2 ?_⟩ filter_upwards [hu] with x hx using (and_iff_left hx).symm alias ⟨IntegrableAtFilter.of_inf_ae, _⟩ := IntegrableAtFilter.inf_ae_iff @[simp] theorem integrableAtFilter_top : IntegrableAtFilter f ⊤ μ ↔ Integrable f μ := by refine ⟨fun h ↦ ?_, fun h ↦ h.integrableAtFilter ⊤⟩ obtain ⟨s, hsf, hs⟩ := h exact (integrableOn_iff_integrable_of_support_subset fun _ _ ↦ hsf _).mp hs theorem IntegrableAtFilter.sup_iff {l l' : Filter α} : IntegrableAtFilter f (l ⊔ l') μ ↔ IntegrableAtFilter f l μ ∧ IntegrableAtFilter f l' μ := by constructor · exact fun h => ⟨h.filter_mono le_sup_left, h.filter_mono le_sup_right⟩ · exact fun ⟨⟨s, hsl, hs⟩, ⟨t, htl, ht⟩⟩ ↦ ⟨s ∪ t, union_mem_sup hsl htl, hs.union ht⟩ /-- If `μ` is a measure finite at filter `l` and `f` is a function such that its norm is bounded above at `l`, then `f` is integrable at `l`. -/ theorem Measure.FiniteAtFilter.integrableAtFilter {l : Filter α} [IsMeasurablyGenerated l] (hfm : StronglyMeasurableAtFilter f l μ) (hμ : μ.FiniteAtFilter l) (hf : l.IsBoundedUnder (· ≤ ·) (norm ∘ f)) : IntegrableAtFilter f l μ := by obtain ⟨C, hC⟩ : ∃ C, ∀ᶠ s in l.smallSets, ∀ x ∈ s, ‖f x‖ ≤ C := hf.imp fun C hC => eventually_smallSets.2 ⟨_, hC, fun t => id⟩ rcases (hfm.eventually.and (hμ.eventually.and hC)).exists_measurable_mem_of_smallSets with ⟨s, hsl, hsm, hfm, hμ, hC⟩ refine ⟨s, hsl, ⟨hfm, hasFiniteIntegral_restrict_of_bounded hμ (C := C) ?_⟩⟩ rw [ae_restrict_eq hsm, eventually_inf_principal] exact Eventually.of_forall hC theorem Measure.FiniteAtFilter.integrableAtFilter_of_tendsto_ae {l : Filter α} [IsMeasurablyGenerated l] (hfm : StronglyMeasurableAtFilter f l μ) (hμ : μ.FiniteAtFilter l) {b} (hf : Tendsto f (l ⊓ ae μ) (𝓝 b)) : IntegrableAtFilter f l μ := (hμ.inf_of_left.integrableAtFilter (hfm.filter_mono inf_le_left) hf.norm.isBoundedUnder_le).of_inf_ae alias _root_.Filter.Tendsto.integrableAtFilter_ae := Measure.FiniteAtFilter.integrableAtFilter_of_tendsto_ae theorem Measure.FiniteAtFilter.integrableAtFilter_of_tendsto {l : Filter α} [IsMeasurablyGenerated l] (hfm : StronglyMeasurableAtFilter f l μ) (hμ : μ.FiniteAtFilter l) {b} (hf : Tendsto f l (𝓝 b)) : IntegrableAtFilter f l μ := hμ.integrableAtFilter hfm hf.norm.isBoundedUnder_le alias _root_.Filter.Tendsto.integrableAtFilter := Measure.FiniteAtFilter.integrableAtFilter_of_tendsto lemma Measure.integrableOn_of_bounded (s_finite : μ s ≠ ∞) (f_mble : AEStronglyMeasurable f μ) {M : ℝ} (f_bdd : ∀ᵐ a ∂(μ.restrict s), ‖f a‖ ≤ M) : IntegrableOn f s μ := ⟨f_mble.restrict, hasFiniteIntegral_restrict_of_bounded (C := M) s_finite.lt_top f_bdd⟩ theorem integrable_add_of_disjoint {f g : α → E} (h : Disjoint (support f) (support g)) (hf : StronglyMeasurable f) (hg : StronglyMeasurable g) : Integrable (f + g) μ ↔ Integrable f μ ∧ Integrable g μ := by refine ⟨fun hfg => ⟨?_, ?_⟩, fun h => h.1.add h.2⟩ · rw [← indicator_add_eq_left h]; exact hfg.indicator hf.measurableSet_support · rw [← indicator_add_eq_right h]; exact hfg.indicator hg.measurableSet_support /-- If a function converges along a filter to a limit `a`, is integrable along this filter, and all elements of the filter have infinite measure, then the limit has to vanish. -/ lemma IntegrableAtFilter.eq_zero_of_tendsto (h : IntegrableAtFilter f l μ) (h' : ∀ s ∈ l, μ s = ∞) {a : E} (hf : Tendsto f l (𝓝 a)) : a = 0 := by by_contra H obtain ⟨ε, εpos, hε⟩ : ∃ (ε : ℝ), 0 < ε ∧ ε < ‖a‖ := exists_between (norm_pos_iff.mpr H) rcases h with ⟨u, ul, hu⟩ let v := u ∩ {b \| ε < ‖f b‖} have hv : IntegrableOn f v μ := hu.mono_set inter_subset_left have vl : v ∈ l := inter_mem ul ((tendsto_order.1 hf.norm).1 _ hε) have : μ.restrict v v < ∞ := lt_of_le_of_lt (measure_mono inter_subset_right) (Integrable.measure_gt_lt_top hv.norm εpos) have : μ v ≠ ∞ := ne_of_lt (by simpa only [Measure.restrict_apply_self]) exact this (h' v vl) end NormedAddCommGroup end MeasureTheory open MeasureTheory variable [NormedAddCommGroup E] /-- A function which is continuous on a set `s` is almost everywhere measurable with respect to `μ.restrict s`. -/ theorem ContinuousOn.aemeasurable [TopologicalSpace α] [OpensMeasurableSpace α] [MeasurableSpace β] [TopologicalSpace β] [BorelSpace β] {f : α → β} {s : Set α} {μ : Measure α} (hf : ContinuousOn f s) (hs : MeasurableSet s) : AEMeasurable f (μ.restrict s) := by classical nontriviality α; inhabit α have : (Set.piecewise s f fun _ => f default) =ᵐ[μ.restrict s] f := piecewise_ae_eq_restrict hs refine ⟨Set.piecewise s f fun _ => f default, ?_, this.symm⟩ apply measurable_of_isOpen intro t ht obtain ⟨u, u_open, hu⟩ : ∃ u : Set α, IsOpen u ∧ f ⁻¹' t ∩ s = u ∩ s := _root_.continuousOn_iff'.1 hf t ht rw [piecewise_preimage, Set.ite, hu] exact (u_open.measurableSet.inter hs).union ((measurable_const ht.measurableSet).diff hs) /-- A function which is continuous on a separable set `s` is almost everywhere strongly measurable with respect to `μ.restrict s`. -/ theorem ContinuousOn.aestronglyMeasurable_of_isSeparable [TopologicalSpace α] [PseudoMetrizableSpace α] [OpensMeasurableSpace α] [TopologicalSpace β] [PseudoMetrizableSpace β] {f : α → β} {s : Set α} {μ : Measure α} (hf : ContinuousOn f s) (hs : MeasurableSet s) (h's : TopologicalSpace.IsSeparable s) : AEStronglyMeasurable f (μ.restrict s) := by letI := pseudoMetrizableSpacePseudoMetric α borelize β rw [aestronglyMeasurable_iff_aemeasurable_separable] refine ⟨hf.aemeasurable hs, f '' s, hf.isSeparable_image h's, ?_⟩ exact mem_of_superset (self_mem_ae_restrict hs) (subset_preimage_image _ _) /-- A function which is continuous on a set `s` is almost everywhere strongly measurable with respect to `μ.restrict s` when either the source space or the target space is second-countable. -/ theorem ContinuousOn.aestronglyMeasurable [TopologicalSpace α] [TopologicalSpace β] [h : SecondCountableTopologyEither α β] [OpensMeasurableSpace α] [PseudoMetrizableSpace β] {f : α → β} {s : Set α} {μ : Measure α} (hf : ContinuousOn f s) (hs : MeasurableSet s) : AEStronglyMeasurable f (μ.restrict s) := by borelize β refine aestronglyMeasurable_iff_aemeasurable_separable.2 ⟨hf.aemeasurable hs, f '' s, ?_, mem_of_superset (self_mem_ae_restrict hs) (subset_preimage_image _ _)⟩ cases h.out · rw [image_eq_range] exact isSeparable_range <\| continuousOn_iff_continuous_restrict.1 hf · exact .of_separableSpace _ /-- A function which is continuous on a compact set `s` is almost everywhere strongly measurable with respect to `μ.restrict s`. -/ theorem ContinuousOn.aestronglyMeasurable_of_isCompact [TopologicalSpace α] [OpensMeasurableSpace α] [TopologicalSpace β] [PseudoMetrizableSpace β] {f : α → β} {s : Set α} {μ : Measure α} (hf : ContinuousOn f s) (hs : IsCompact s) (h's : MeasurableSet s) : AEStronglyMeasurable f (μ.restrict s) := by letI := pseudoMetrizableSpacePseudoMetric β borelize β rw [aestronglyMeasurable_iff_aemeasurable_separable] refine ⟨hf.aemeasurable h's, f '' s, ?_, ?_⟩ · exact (hs.image_of_continuousOn hf).isSeparable · exact mem_of_superset (self_mem_ae_restrict h's) (subset_preimage_image _ _)	theorem ContinuousOn.integrableAt_nhdsWithin_of_isSeparable [TopologicalSpace α] [PseudoMetrizableSpace α] [OpensMeasurableSpace α] {μ : Measure α} [IsLocallyFiniteMeasure μ] {a : α} {t : Set α} {f : α → E} (hft : ContinuousOn f t) (ht : MeasurableSet t) (h't : TopologicalSpace.IsSeparable t) (ha : a ∈ t) : IntegrableAtFilter f (𝓝[t] a) μ := haveI : (𝓝[t] a).IsMeasurablyGenerated := ht.nhdsWithin_isMeasurablyGenerated _ (hft a ha).integrableAtFilter ⟨_, self_mem_nhdsWithin, hft.aestronglyMeasurable_of_isSeparable ht h't⟩ (μ.finiteAt_nhdsWithin _ _) theorem ContinuousOn.integrableAt_nhdsWithin [TopologicalSpace α]	Mathlib/MeasureTheory/Integral/IntegrableOn.lean	591	600
/- Copyright (c) 2020 Johan Commelin. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johan Commelin -/ import Mathlib.Algebra.Group.Units.Basic import Mathlib.Algebra.GroupWithZero.Basic import Mathlib.Data.Int.Basic import Mathlib.Lean.Meta.CongrTheorems import Mathlib.Tactic.Contrapose import Mathlib.Tactic.Nontriviality import Mathlib.Tactic.Spread import Mathlib.Util.AssertExists /-! # Lemmas about units in a `MonoidWithZero` or a `GroupWithZero`. We also define `Ring.inverse`, a globally defined function on any ring (in fact any `MonoidWithZero`), which inverts units and sends non-units to zero. -/ -- Guard against import creep assert_not_exists DenselyOrdered Equiv Subtype.restrict Multiplicative variable {α M₀ G₀ : Type} variable [MonoidWithZero M₀] namespace Units /-- An element of the unit group of a nonzero monoid with zero represented as an element of the monoid is nonzero. -/ @[simp] theorem ne_zero [Nontrivial M₀] (u : M₀ˣ) : (u : M₀) ≠ 0 := left_ne_zero_of_mul_eq_one u.mul_inv -- We can't use `mul_eq_zero` + `Units.ne_zero` in the next two lemmas because we don't assume -- `Nonzero M₀`. @[simp] theorem mul_left_eq_zero (u : M₀ˣ) {a : M₀} : a u = 0 ↔ a = 0 := ⟨fun h => by simpa using mul_eq_zero_of_left h ↑u⁻¹, fun h => mul_eq_zero_of_left h u⟩ @[simp] theorem mul_right_eq_zero (u : M₀ˣ) {a : M₀} : ↑u * a = 0 ↔ a = 0 := ⟨fun h => by simpa using mul_eq_zero_of_right (↑u⁻¹) h, mul_eq_zero_of_right (u : M₀)⟩ end Units namespace IsUnit theorem ne_zero [Nontrivial M₀] {a : M₀} (ha : IsUnit a) : a ≠ 0 := let ⟨u, hu⟩ := ha hu ▸ u.ne_zero theorem mul_right_eq_zero {a b : M₀} (ha : IsUnit a) : a * b = 0 ↔ b = 0 := let ⟨u, hu⟩ := ha hu ▸ u.mul_right_eq_zero theorem mul_left_eq_zero {a b : M₀} (hb : IsUnit b) : a * b = 0 ↔ a = 0 := let ⟨u, hu⟩ := hb hu ▸ u.mul_left_eq_zero end IsUnit @[simp] theorem isUnit_zero_iff : IsUnit (0 : M₀) ↔ (0 : M₀) = 1 := ⟨fun ⟨⟨_, a, (a0 : 0 * a = 1), _⟩, rfl⟩ => by rwa [zero_mul] at a0, fun h => @isUnit_of_subsingleton _ _ (subsingleton_of_zero_eq_one h) 0⟩ theorem not_isUnit_zero [Nontrivial M₀] : ¬IsUnit (0 : M₀) := mt isUnit_zero_iff.1 zero_ne_one namespace Ring open Classical in /-- Introduce a function `inverse` on a monoid with zero `M₀`, which sends `x` to `x⁻¹` if `x` is invertible and to `0` otherwise. This definition is somewhat ad hoc, but one needs a fully (rather than partially) defined inverse function for some purposes, including for calculus. Note that while this is in the `Ring` namespace for brevity, it requires the weaker assumption `MonoidWithZero M₀` instead of `Ring M₀`. -/ noncomputable def inverse : M₀ → M₀ := fun x => if h : IsUnit x then ((h.unit⁻¹ : M₀ˣ) : M₀) else 0 /-- By definition, if `x` is invertible then `inverse x = x⁻¹`. -/ @[simp] theorem inverse_unit (u : M₀ˣ) : inverse (u : M₀) = (u⁻¹ : M₀ˣ) := by rw [inverse, dif_pos u.isUnit, IsUnit.unit_of_val_units] theorem inverse_of_isUnit {x : M₀} (h : IsUnit x) : inverse x = ((h.unit⁻¹ : M₀ˣ) : M₀) := dif_pos h /-- By definition, if `x` is not invertible then `inverse x = 0`. -/ @[simp] theorem inverse_non_unit (x : M₀) (h : ¬IsUnit x) : inverse x = 0 := dif_neg h theorem mul_inverse_cancel (x : M₀) (h : IsUnit x) : x * inverse x = 1 := by rcases h with ⟨u, rfl⟩ rw [inverse_unit, Units.mul_inv] theorem inverse_mul_cancel (x : M₀) (h : IsUnit x) : inverse x * x = 1 := by rcases h with ⟨u, rfl⟩ rw [inverse_unit, Units.inv_mul] theorem mul_inverse_cancel_right (x y : M₀) (h : IsUnit x) : y * x * inverse x = y := by rw [mul_assoc, mul_inverse_cancel x h, mul_one] theorem inverse_mul_cancel_right (x y : M₀) (h : IsUnit x) : y * inverse x * x = y := by rw [mul_assoc, inverse_mul_cancel x h, mul_one] theorem mul_inverse_cancel_left (x y : M₀) (h : IsUnit x) : x * (inverse x * y) = y := by rw [← mul_assoc, mul_inverse_cancel x h, one_mul] theorem inverse_mul_cancel_left (x y : M₀) (h : IsUnit x) : inverse x * (x * y) = y := by rw [← mul_assoc, inverse_mul_cancel x h, one_mul] theorem inverse_mul_eq_iff_eq_mul (x y z : M₀) (h : IsUnit x) : inverse x * y = z ↔ y = x * z := ⟨fun h1 => by rw [← h1, mul_inverse_cancel_left _ _ h], fun h1 => by rw [h1, inverse_mul_cancel_left _ _ h]⟩ theorem eq_mul_inverse_iff_mul_eq (x y z : M₀) (h : IsUnit z) : x = y * inverse z ↔ x * z = y := ⟨fun h1 => by rw [h1, inverse_mul_cancel_right _ _ h], fun h1 => by rw [← h1, mul_inverse_cancel_right _ _ h]⟩ variable (M₀)	@[simp] theorem inverse_one : inverse (1 : M₀) = 1 :=	Mathlib/Algebra/GroupWithZero/Units/Basic.lean	126	127
/- Copyright (c) 2018 Sébastien Gouëzel. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Sébastien Gouëzel -/ import Mathlib.Data.Finset.Max import Mathlib.Data.Set.Finite.Lattice import Mathlib.Order.ConditionallyCompleteLattice.Indexed /-! # Conditionally complete lattices and finite sets. -/ open Set variable {ι α β γ : Type*} section ConditionallyCompleteLinearOrder variable [ConditionallyCompleteLinearOrder α] {s t : Set α} {a b : α} theorem Finset.Nonempty.csSup_eq_max' {s : Finset α} (h : s.Nonempty) : sSup ↑s = s.max' h := eq_of_forall_ge_iff fun _ => (csSup_le_iff s.bddAbove h.to_set).trans (s.max'_le_iff h).symm theorem Finset.Nonempty.csInf_eq_min' {s : Finset α} (h : s.Nonempty) : sInf ↑s = s.min' h := @Finset.Nonempty.csSup_eq_max' αᵒᵈ _ s h theorem Finset.Nonempty.csSup_mem {s : Finset α} (h : s.Nonempty) : sSup (s : Set α) ∈ s := by rw [h.csSup_eq_max'] exact s.max'_mem _ theorem Finset.Nonempty.csInf_mem {s : Finset α} (h : s.Nonempty) : sInf (s : Set α) ∈ s := @Finset.Nonempty.csSup_mem αᵒᵈ _ _ h theorem Set.Nonempty.csSup_mem (h : s.Nonempty) (hs : s.Finite) : sSup s ∈ s := by lift s to Finset α using hs exact Finset.Nonempty.csSup_mem h theorem Set.Nonempty.csInf_mem (h : s.Nonempty) (hs : s.Finite) : sInf s ∈ s :=	@Set.Nonempty.csSup_mem αᵒᵈ _ _ h hs theorem Set.Finite.csSup_lt_iff (hs : s.Finite) (h : s.Nonempty) : sSup s < a ↔ ∀ x ∈ s, x < a :=	Mathlib/Order/ConditionallyCompleteLattice/Finset.lean	42	44
/- Copyright (c) 2015 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Leonardo de Moura, Jeremy Avigad, Minchao Wu, Mario Carneiro -/ import Mathlib.Data.Finset.Attach import Mathlib.Data.Finset.Disjoint import Mathlib.Data.Finset.Erase import Mathlib.Data.Finset.Filter import Mathlib.Data.Finset.Range import Mathlib.Data.Finset.SDiff import Mathlib.Data.Multiset.Basic import Mathlib.Logic.Equiv.Set import Mathlib.Order.Directed import Mathlib.Order.Interval.Set.Defs import Mathlib.Data.Set.SymmDiff /-! # Basic lemmas on finite sets This file contains lemmas on the interaction of various definitions on the `Finset` type. For an explanation of `Finset` design decisions, please see `Mathlib/Data/Finset/Defs.lean`. ## Main declarations ### Main definitions * `Finset.choose`: Given a proof `h` of existence and uniqueness of a certain element satisfying a predicate, `choose s h` returns the element of `s` satisfying that predicate. ### Equivalences between finsets * The `Mathlib/Logic/Equiv/Defs.lean` file describes a general type of equivalence, so look in there for any lemmas. There is some API for rewriting sums and products from `s` to `t` given that `s ≃ t`. TODO: examples ## Tags finite sets, finset -/ -- Assert that we define `Finset` without the material on `List.sublists`. -- Note that we cannot use `List.sublists` itself as that is defined very early. assert_not_exists List.sublistsLen Multiset.powerset CompleteLattice Monoid open Multiset Subtype Function universe u variable {α : Type} {β : Type} {γ : Type} namespace Finset -- TODO: these should be global attributes, but this will require fixing other files attribute [local trans] Subset.trans Superset.trans set_option linter.deprecated false in @[deprecated "Deprecated without replacement." (since := "2025-02-07")] theorem sizeOf_lt_sizeOf_of_mem [SizeOf α] {x : α} {s : Finset α} (hx : x ∈ s) : SizeOf.sizeOf x < SizeOf.sizeOf s := by cases s dsimp [SizeOf.sizeOf, SizeOf.sizeOf, Multiset.sizeOf] rw [Nat.add_comm] refine lt_trans ?_ (Nat.lt_succ_self _) exact Multiset.sizeOf_lt_sizeOf_of_mem hx /-! ### Lattice structure -/ section Lattice variable [DecidableEq α] {s s₁ s₂ t t₁ t₂ u v : Finset α} {a b : α} /-! #### union -/ @[simp] theorem disjUnion_eq_union (s t h) : @disjUnion α s t h = s ∪ t := ext fun a => by simp @[simp] theorem disjoint_union_left : Disjoint (s ∪ t) u ↔ Disjoint s u ∧ Disjoint t u := by simp only [disjoint_left, mem_union, or_imp, forall_and] @[simp] theorem disjoint_union_right : Disjoint s (t ∪ u) ↔ Disjoint s t ∧ Disjoint s u := by simp only [disjoint_right, mem_union, or_imp, forall_and] /-! #### inter -/ theorem not_disjoint_iff_nonempty_inter : ¬Disjoint s t ↔ (s ∩ t).Nonempty := not_disjoint_iff.trans <\| by simp [Finset.Nonempty] alias ⟨_, Nonempty.not_disjoint⟩ := not_disjoint_iff_nonempty_inter theorem disjoint_or_nonempty_inter (s t : Finset α) : Disjoint s t ∨ (s ∩ t).Nonempty := by rw [← not_disjoint_iff_nonempty_inter] exact em _ omit [DecidableEq α] in theorem disjoint_of_subset_iff_left_eq_empty (h : s ⊆ t) : Disjoint s t ↔ s = ∅ := disjoint_of_le_iff_left_eq_bot h lemma pairwiseDisjoint_iff {ι : Type} {s : Set ι} {f : ι → Finset α} : s.PairwiseDisjoint f ↔ ∀ ⦃i⦄, i ∈ s → ∀ ⦃j⦄, j ∈ s → (f i ∩ f j).Nonempty → i = j := by simp [Set.PairwiseDisjoint, Set.Pairwise, Function.onFun, not_imp_comm (a := _ = _), not_disjoint_iff_nonempty_inter] end Lattice instance isDirected_le : IsDirected (Finset α) (· ≤ ·) := by classical infer_instance instance isDirected_subset : IsDirected (Finset α) (· ⊆ ·) := isDirected_le /-! ### erase -/ section Erase variable [DecidableEq α] {s t u v : Finset α} {a b : α} @[simp] theorem erase_empty (a : α) : erase ∅ a = ∅ := rfl protected lemma Nontrivial.erase_nonempty (hs : s.Nontrivial) : (s.erase a).Nonempty := (hs.exists_ne a).imp <\| by aesop @[simp] lemma erase_nonempty (ha : a ∈ s) : (s.erase a).Nonempty ↔ s.Nontrivial := by simp only [Finset.Nonempty, mem_erase, and_comm (b := _ ∈ _)] refine ⟨?_, fun hs ↦ hs.exists_ne a⟩ rintro ⟨b, hb, hba⟩ exact ⟨_, hb, _, ha, hba⟩ @[simp] theorem erase_singleton (a : α) : ({a} : Finset α).erase a = ∅ := by ext x simp @[simp] theorem erase_insert_eq_erase (s : Finset α) (a : α) : (insert a s).erase a = s.erase a := ext fun x => by simp +contextual only [mem_erase, mem_insert, and_congr_right_iff, false_or, iff_self, imp_true_iff] theorem erase_insert {a : α} {s : Finset α} (h : a ∉ s) : erase (insert a s) a = s := by rw [erase_insert_eq_erase, erase_eq_of_not_mem h] theorem erase_insert_of_ne {a b : α} {s : Finset α} (h : a ≠ b) : erase (insert a s) b = insert a (erase s b) := ext fun x => by have : x ≠ b ∧ x = a ↔ x = a := and_iff_right_of_imp fun hx => hx.symm ▸ h simp only [mem_erase, mem_insert, and_or_left, this] theorem erase_cons_of_ne {a b : α} {s : Finset α} (ha : a ∉ s) (hb : a ≠ b) : erase (cons a s ha) b = cons a (erase s b) fun h => ha <\| erase_subset _ _ h := by simp only [cons_eq_insert, erase_insert_of_ne hb] @[simp] theorem insert_erase (h : a ∈ s) : insert a (erase s a) = s := ext fun x => by simp only [mem_insert, mem_erase, or_and_left, dec_em, true_and] apply or_iff_right_of_imp rintro rfl exact h lemma erase_eq_iff_eq_insert (hs : a ∈ s) (ht : a ∉ t) : erase s a = t ↔ s = insert a t := by aesop lemma insert_erase_invOn : Set.InvOn (insert a) (fun s ↦ erase s a) {s : Finset α \| a ∈ s} {s : Finset α \| a ∉ s} := ⟨fun _s ↦ insert_erase, fun _s ↦ erase_insert⟩ theorem erase_ssubset {a : α} {s : Finset α} (h : a ∈ s) : s.erase a ⊂ s := calc s.erase a ⊂ insert a (s.erase a) := ssubset_insert <\| not_mem_erase _ _ _ = _ := insert_erase h theorem ssubset_iff_exists_subset_erase {s t : Finset α} : s ⊂ t ↔ ∃ a ∈ t, s ⊆ t.erase a := by refine ⟨fun h => ?_, fun ⟨a, ha, h⟩ => ssubset_of_subset_of_ssubset h <\| erase_ssubset ha⟩ obtain ⟨a, ht, hs⟩ := not_subset.1 h.2 exact ⟨a, ht, subset_erase.2 ⟨h.1, hs⟩⟩ theorem erase_ssubset_insert (s : Finset α) (a : α) : s.erase a ⊂ insert a s := ssubset_iff_exists_subset_erase.2 ⟨a, mem_insert_self _ _, erase_subset_erase _ <\| subset_insert _ _⟩ theorem erase_cons {s : Finset α} {a : α} (h : a ∉ s) : (s.cons a h).erase a = s := by rw [cons_eq_insert, erase_insert_eq_erase, erase_eq_of_not_mem h] theorem subset_insert_iff {a : α} {s t : Finset α} : s ⊆ insert a t ↔ erase s a ⊆ t := by simp only [subset_iff, or_iff_not_imp_left, mem_erase, mem_insert, and_imp] exact forall_congr' fun x => forall_swap theorem erase_insert_subset (a : α) (s : Finset α) : erase (insert a s) a ⊆ s := subset_insert_iff.1 <\| Subset.rfl theorem insert_erase_subset (a : α) (s : Finset α) : s ⊆ insert a (erase s a) := subset_insert_iff.2 <\| Subset.rfl theorem subset_insert_iff_of_not_mem (h : a ∉ s) : s ⊆ insert a t ↔ s ⊆ t := by rw [subset_insert_iff, erase_eq_of_not_mem h] theorem erase_subset_iff_of_mem (h : a ∈ t) : s.erase a ⊆ t ↔ s ⊆ t := by rw [← subset_insert_iff, insert_eq_of_mem h] theorem erase_injOn' (a : α) : { s : Finset α \| a ∈ s }.InjOn fun s => erase s a := fun s hs t ht (h : s.erase a = _) => by rw [← insert_erase hs, ← insert_erase ht, h] end Erase lemma Nontrivial.exists_cons_eq {s : Finset α} (hs : s.Nontrivial) : ∃ t a ha b hb hab, (cons b t hb).cons a (mem_cons.not.2 <\| not_or_intro hab ha) = s := by classical obtain ⟨a, ha, b, hb, hab⟩ := hs have : b ∈ s.erase a := mem_erase.2 ⟨hab.symm, hb⟩ refine ⟨(s.erase a).erase b, a, ?_, b, ?_, ?_, ?_⟩ <;> simp [insert_erase this, insert_erase ha, *] /-! ### sdiff -/ section Sdiff variable [DecidableEq α] {s t u v : Finset α} {a b : α} lemma erase_sdiff_erase (hab : a ≠ b) (hb : b ∈ s) : s.erase a \ s.erase b = {b} := by ext; aesop -- TODO: Do we want to delete this lemma and `Finset.disjUnion_singleton`, -- or instead add `Finset.union_singleton`/`Finset.singleton_union`? theorem sdiff_singleton_eq_erase (a : α) (s : Finset α) : s \ {a} = erase s a := by ext rw [mem_erase, mem_sdiff, mem_singleton, and_comm] -- This lemma matches `Finset.insert_eq` in functionality. theorem erase_eq (s : Finset α) (a : α) : s.erase a = s \ {a} := (sdiff_singleton_eq_erase _ _).symm theorem disjoint_erase_comm : Disjoint (s.erase a) t ↔ Disjoint s (t.erase a) := by simp_rw [erase_eq, disjoint_sdiff_comm] lemma disjoint_insert_erase (ha : a ∉ t) : Disjoint (s.erase a) (insert a t) ↔ Disjoint s t := by rw [disjoint_erase_comm, erase_insert ha] lemma disjoint_erase_insert (ha : a ∉ s) : Disjoint (insert a s) (t.erase a) ↔ Disjoint s t := by rw [← disjoint_erase_comm, erase_insert ha] theorem disjoint_of_erase_left (ha : a ∉ t) (hst : Disjoint (s.erase a) t) : Disjoint s t := by rw [← erase_insert ha, ← disjoint_erase_comm, disjoint_insert_right] exact ⟨not_mem_erase _ _, hst⟩ theorem disjoint_of_erase_right (ha : a ∉ s) (hst : Disjoint s (t.erase a)) : Disjoint s t := by rw [← erase_insert ha, disjoint_erase_comm, disjoint_insert_left] exact ⟨not_mem_erase _ _, hst⟩ theorem inter_erase (a : α) (s t : Finset α) : s ∩ t.erase a = (s ∩ t).erase a := by simp only [erase_eq, inter_sdiff_assoc] @[simp] theorem erase_inter (a : α) (s t : Finset α) : s.erase a ∩ t = (s ∩ t).erase a := by simpa only [inter_comm t] using inter_erase a t s theorem erase_sdiff_comm (s t : Finset α) (a : α) : s.erase a \ t = (s \ t).erase a := by simp_rw [erase_eq, sdiff_right_comm] theorem erase_inter_comm (s t : Finset α) (a : α) : s.erase a ∩ t = s ∩ t.erase a := by rw [erase_inter, inter_erase] theorem erase_union_distrib (s t : Finset α) (a : α) : (s ∪ t).erase a = s.erase a ∪ t.erase a := by simp_rw [erase_eq, union_sdiff_distrib] theorem insert_inter_distrib (s t : Finset α) (a : α) : insert a (s ∩ t) = insert a s ∩ insert a t := by simp_rw [insert_eq, union_inter_distrib_left] theorem erase_sdiff_distrib (s t : Finset α) (a : α) : (s \ t).erase a = s.erase a \ t.erase a := by simp_rw [erase_eq, sdiff_sdiff, sup_sdiff_eq_sup le_rfl, sup_comm] theorem erase_union_of_mem (ha : a ∈ t) (s : Finset α) : s.erase a ∪ t = s ∪ t := by rw [← insert_erase (mem_union_right s ha), erase_union_distrib, ← union_insert, insert_erase ha] theorem union_erase_of_mem (ha : a ∈ s) (t : Finset α) : s ∪ t.erase a = s ∪ t := by rw [← insert_erase (mem_union_left t ha), erase_union_distrib, ← insert_union, insert_erase ha] theorem sdiff_union_erase_cancel (hts : t ⊆ s) (ha : a ∈ t) : s \ t ∪ t.erase a = s.erase a := by simp_rw [erase_eq, sdiff_union_sdiff_cancel hts (singleton_subset_iff.2 ha)] theorem sdiff_insert (s t : Finset α) (x : α) : s \ insert x t = (s \ t).erase x := by simp_rw [← sdiff_singleton_eq_erase, insert_eq, sdiff_sdiff_left', sdiff_union_distrib, inter_comm] theorem sdiff_insert_insert_of_mem_of_not_mem {s t : Finset α} {x : α} (hxs : x ∈ s) (hxt : x ∉ t) : insert x (s \ insert x t) = s \ t := by rw [sdiff_insert, insert_erase (mem_sdiff.mpr ⟨hxs, hxt⟩)] theorem sdiff_erase (h : a ∈ s) : s \ t.erase a = insert a (s \ t) := by rw [← sdiff_singleton_eq_erase, sdiff_sdiff_eq_sdiff_union (singleton_subset_iff.2 h), insert_eq, union_comm] theorem sdiff_erase_self (ha : a ∈ s) : s \ s.erase a = {a} := by rw [sdiff_erase ha, Finset.sdiff_self, insert_empty_eq] theorem erase_eq_empty_iff (s : Finset α) (a : α) : s.erase a = ∅ ↔ s = ∅ ∨ s = {a} := by rw [← sdiff_singleton_eq_erase, sdiff_eq_empty_iff_subset, subset_singleton_iff] --TODO@Yaël: Kill lemmas duplicate with `BooleanAlgebra` theorem sdiff_disjoint : Disjoint (t \ s) s := disjoint_left.2 fun _a ha => (mem_sdiff.1 ha).2 theorem disjoint_sdiff : Disjoint s (t \ s) := sdiff_disjoint.symm theorem disjoint_sdiff_inter (s t : Finset α) : Disjoint (s \ t) (s ∩ t) := disjoint_of_subset_right inter_subset_right sdiff_disjoint end Sdiff /-! ### attach -/ @[simp] theorem attach_empty : attach (∅ : Finset α) = ∅ := rfl @[simp] theorem attach_nonempty_iff {s : Finset α} : s.attach.Nonempty ↔ s.Nonempty := by simp [Finset.Nonempty] @[aesop safe apply (rule_sets := [finsetNonempty])] protected alias ⟨_, Nonempty.attach⟩ := attach_nonempty_iff @[simp] theorem attach_eq_empty_iff {s : Finset α} : s.attach = ∅ ↔ s = ∅ := by simp [eq_empty_iff_forall_not_mem] /-! ### filter -/ section Filter variable (p q : α → Prop) [DecidablePred p] [DecidablePred q] {s t : Finset α} theorem filter_singleton (a : α) : filter p {a} = if p a then {a} else ∅ := by classical ext x simp only [mem_singleton, forall_eq, mem_filter] split_ifs with h <;> by_cases h' : x = a <;> simp [h, h'] theorem filter_cons_of_pos (a : α) (s : Finset α) (ha : a ∉ s) (hp : p a) : filter p (cons a s ha) = cons a (filter p s) ((mem_of_mem_filter _).mt ha) := eq_of_veq <\| Multiset.filter_cons_of_pos s.val hp theorem filter_cons_of_neg (a : α) (s : Finset α) (ha : a ∉ s) (hp : ¬p a) : filter p (cons a s ha) = filter p s := eq_of_veq <\| Multiset.filter_cons_of_neg s.val hp theorem disjoint_filter {s : Finset α} {p q : α → Prop} [DecidablePred p] [DecidablePred q] : Disjoint (s.filter p) (s.filter q) ↔ ∀ x ∈ s, p x → ¬q x := by constructor <;> simp +contextual [disjoint_left] theorem disjoint_filter_filter' (s t : Finset α) {p q : α → Prop} [DecidablePred p] [DecidablePred q] (h : Disjoint p q) : Disjoint (s.filter p) (t.filter q) := by simp_rw [disjoint_left, mem_filter] rintro a ⟨_, hp⟩ ⟨_, hq⟩ rw [Pi.disjoint_iff] at h simpa [hp, hq] using h a theorem disjoint_filter_filter_neg (s t : Finset α) (p : α → Prop) [DecidablePred p] [∀ x, Decidable (¬p x)] : Disjoint (s.filter p) (t.filter fun a => ¬p a) := disjoint_filter_filter' s t disjoint_compl_right theorem filter_disj_union (s : Finset α) (t : Finset α) (h : Disjoint s t) : filter p (disjUnion s t h) = (filter p s).disjUnion (filter p t) (disjoint_filter_filter h) := eq_of_veq <\| Multiset.filter_add _ _ _ theorem filter_cons {a : α} (s : Finset α) (ha : a ∉ s) : filter p (cons a s ha) = if p a then cons a (filter p s) ((mem_of_mem_filter _).mt ha) else filter p s := by split_ifs with h · rw [filter_cons_of_pos _ _ _ ha h] · rw [filter_cons_of_neg _ _ _ ha h] section variable [DecidableEq α] theorem filter_union (s₁ s₂ : Finset α) : (s₁ ∪ s₂).filter p = s₁.filter p ∪ s₂.filter p := ext fun _ => by simp only [mem_filter, mem_union, or_and_right] theorem filter_union_right (s : Finset α) : s.filter p ∪ s.filter q = s.filter fun x => p x ∨ q x := ext fun x => by simp [mem_filter, mem_union, ← and_or_left]		Mathlib/Data/Finset/Basic.lean	389	389
/- Copyright (c) 2023 Rémy Degenne. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Rémy Degenne -/ import Mathlib.Probability.ConditionalProbability import Mathlib.Probability.Kernel.Basic import Mathlib.Probability.Kernel.Composition.MeasureComp import Mathlib.Tactic.Peel import Mathlib.MeasureTheory.MeasurableSpace.Pi /-! # Independence with respect to a kernel and a measure A family of sets of sets `π : ι → Set (Set Ω)` is independent with respect to a kernel `κ : Kernel α Ω` and a measure `μ` on `α` if for any finite set of indices `s = {i_1, ..., i_n}`, for any sets `f i_1 ∈ π i_1, ..., f i_n ∈ π i_n`, then for `μ`-almost every `a : α`, `κ a (⋂ i in s, f i) = ∏ i ∈ s, κ a (f i)`. This notion of independence is a generalization of both independence and conditional independence. For conditional independence, `κ` is the conditional kernel `ProbabilityTheory.condExpKernel` and `μ` is the ambient measure. For (non-conditional) independence, `κ = Kernel.const Unit μ` and the measure is the Dirac measure on `Unit`. The main purpose of this file is to prove only once the properties that hold for both conditional and non-conditional independence. ## Main definitions * `ProbabilityTheory.Kernel.iIndepSets`: independence of a family of sets of sets. Variant for two sets of sets: `ProbabilityTheory.Kernel.IndepSets`. * `ProbabilityTheory.Kernel.iIndep`: independence of a family of σ-algebras. Variant for two σ-algebras: `Indep`. * `ProbabilityTheory.Kernel.iIndepSet`: independence of a family of sets. Variant for two sets: `ProbabilityTheory.Kernel.IndepSet`. * `ProbabilityTheory.Kernel.iIndepFun`: independence of a family of functions (random variables). Variant for two functions: `ProbabilityTheory.Kernel.IndepFun`. See the file `Mathlib/Probability/Kernel/Basic.lean` for a more detailed discussion of these definitions in the particular case of the usual independence notion. ## Main statements * `ProbabilityTheory.Kernel.iIndepSets.iIndep`: if π-systems are independent as sets of sets, then the measurable space structures they generate are independent. * `ProbabilityTheory.Kernel.IndepSets.Indep`: variant with two π-systems. -/ open Set MeasureTheory MeasurableSpace open scoped MeasureTheory ENNReal namespace ProbabilityTheory.Kernel variable {α Ω ι : Type} section Definitions variable {_mα : MeasurableSpace α} /-- A family of sets of sets `π : ι → Set (Set Ω)` is independent with respect to a kernel `κ` and a measure `μ` if for any finite set of indices `s = {i_1, ..., i_n}`, for any sets `f i_1 ∈ π i_1, ..., f i_n ∈ π i_n`, then `∀ᵐ a ∂μ, κ a (⋂ i in s, f i) = ∏ i ∈ s, κ a (f i)`. It will be used for families of pi_systems. -/ def iIndepSets {_mΩ : MeasurableSpace Ω} (π : ι → Set (Set Ω)) (κ : Kernel α Ω) (μ : Measure α := by volume_tac) : Prop := ∀ (s : Finset ι) {f : ι → Set Ω} (_H : ∀ i, i ∈ s → f i ∈ π i), ∀ᵐ a ∂μ, κ a (⋂ i ∈ s, f i) = ∏ i ∈ s, κ a (f i) /-- Two sets of sets `s₁, s₂` are independent with respect to a kernel `κ` and a measure `μ` if for any sets `t₁ ∈ s₁, t₂ ∈ s₂`, then `∀ᵐ a ∂μ, κ a (t₁ ∩ t₂) = κ a (t₁) κ a (t₂)` -/ def IndepSets {_mΩ : MeasurableSpace Ω} (s1 s2 : Set (Set Ω)) (κ : Kernel α Ω) (μ : Measure α := by volume_tac) : Prop := ∀ t1 t2 : Set Ω, t1 ∈ s1 → t2 ∈ s2 → (∀ᵐ a ∂μ, κ a (t1 ∩ t2) = κ a t1 * κ a t2) /-- A family of measurable space structures (i.e. of σ-algebras) is independent with respect to a kernel `κ` and a measure `μ` if the family of sets of measurable sets they define is independent. -/ def iIndep (m : ι → MeasurableSpace Ω) {_mΩ : MeasurableSpace Ω} (κ : Kernel α Ω) (μ : Measure α := by volume_tac) : Prop := iIndepSets (fun x ↦ {s \| MeasurableSet[m x] s}) κ μ /-- Two measurable space structures (or σ-algebras) `m₁, m₂` are independent with respect to a kernel `κ` and a measure `μ` if for any sets `t₁ ∈ m₁, t₂ ∈ m₂`, `∀ᵐ a ∂μ, κ a (t₁ ∩ t₂) = κ a (t₁) * κ a (t₂)` -/ def Indep (m₁ m₂ : MeasurableSpace Ω) {_mΩ : MeasurableSpace Ω} (κ : Kernel α Ω) (μ : Measure α := by volume_tac) : Prop := IndepSets {s \| MeasurableSet[m₁] s} {s \| MeasurableSet[m₂] s} κ μ /-- A family of sets is independent if the family of measurable space structures they generate is independent. For a set `s`, the generated measurable space has measurable sets `∅, s, sᶜ, univ`. -/ def iIndepSet {_mΩ : MeasurableSpace Ω} (s : ι → Set Ω) (κ : Kernel α Ω) (μ : Measure α := by volume_tac) : Prop := iIndep (m := fun i ↦ generateFrom {s i}) κ μ /-- Two sets are independent if the two measurable space structures they generate are independent. For a set `s`, the generated measurable space structure has measurable sets `∅, s, sᶜ, univ`. -/ def IndepSet {_mΩ : MeasurableSpace Ω} (s t : Set Ω) (κ : Kernel α Ω) (μ : Measure α := by volume_tac) : Prop := Indep (generateFrom {s}) (generateFrom {t}) κ μ /-- A family of functions defined on the same space `Ω` and taking values in possibly different spaces, each with a measurable space structure, is independent if the family of measurable space structures they generate on `Ω` is independent. For a function `g` with codomain having measurable space structure `m`, the generated measurable space structure is `MeasurableSpace.comap g m`. -/ def iIndepFun {_mΩ : MeasurableSpace Ω} {β : ι → Type} [m : ∀ x : ι, MeasurableSpace (β x)] (f : ∀ x : ι, Ω → β x) (κ : Kernel α Ω) (μ : Measure α := by volume_tac) : Prop := iIndep (m := fun x ↦ MeasurableSpace.comap (f x) (m x)) κ μ /-- Two functions are independent if the two measurable space structures they generate are independent. For a function `f` with codomain having measurable space structure `m`, the generated measurable space structure is `MeasurableSpace.comap f m`. -/ def IndepFun {β γ} {_mΩ : MeasurableSpace Ω} [mβ : MeasurableSpace β] [mγ : MeasurableSpace γ] (f : Ω → β) (g : Ω → γ) (κ : Kernel α Ω) (μ : Measure α := by volume_tac) : Prop := Indep (MeasurableSpace.comap f mβ) (MeasurableSpace.comap g mγ) κ μ end Definitions section ByDefinition variable {β : ι → Type} {mβ : ∀ i, MeasurableSpace (β i)} {_mα : MeasurableSpace α} {m : ι → MeasurableSpace Ω} {_mΩ : MeasurableSpace Ω} {κ η : Kernel α Ω} {μ : Measure α} {π : ι → Set (Set Ω)} {s : ι → Set Ω} {S : Finset ι} {f : ∀ x : ι, Ω → β x} {s1 s2 : Set (Set Ω)} @[simp] lemma iIndepSets_zero_right : iIndepSets π κ 0 := by simp [iIndepSets] @[simp] lemma indepSets_zero_right : IndepSets s1 s2 κ 0 := by simp [IndepSets] @[simp] lemma indepSets_zero_left : IndepSets s1 s2 (0 : Kernel α Ω) μ := by simp [IndepSets] @[simp] lemma iIndep_zero_right : iIndep m κ 0 := by simp [iIndep] @[simp] lemma indep_zero_right {m₁ m₂ : MeasurableSpace Ω} {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} : Indep m₁ m₂ κ 0 := by simp [Indep] @[simp] lemma indep_zero_left {m₁ m₂ : MeasurableSpace Ω} {_mΩ : MeasurableSpace Ω} : Indep m₁ m₂ (0 : Kernel α Ω) μ := by simp [Indep] @[simp] lemma iIndepSet_zero_right : iIndepSet s κ 0 := by simp [iIndepSet] @[simp] lemma indepSet_zero_right {s t : Set Ω} : IndepSet s t κ 0 := by simp [IndepSet] @[simp] lemma indepSet_zero_left {s t : Set Ω} : IndepSet s t (0 : Kernel α Ω) μ := by simp [IndepSet] @[simp] lemma iIndepFun_zero_right {β : ι → Type} {m : ∀ x : ι, MeasurableSpace (β x)} {f : ∀ x : ι, Ω → β x} : iIndepFun f κ 0 := by simp [iIndepFun] @[simp] lemma indepFun_zero_right {β γ} [MeasurableSpace β] [MeasurableSpace γ] {f : Ω → β} {g : Ω → γ} : IndepFun f g κ 0 := by simp [IndepFun] @[simp] lemma indepFun_zero_left {β γ} [MeasurableSpace β] [MeasurableSpace γ] {f : Ω → β} {g : Ω → γ} : IndepFun f g (0 : Kernel α Ω) μ := by simp [IndepFun] lemma iIndepSets_congr (h : κ =ᵐ[μ] η) : iIndepSets π κ μ ↔ iIndepSets π η μ := by peel 3 refine ⟨fun h' ↦ ?_, fun h' ↦ ?_⟩ <;> · filter_upwards [h, h'] with a ha h'a simpa [ha] using h'a alias ⟨iIndepSets.congr, _⟩ := iIndepSets_congr lemma indepSets_congr (h : κ =ᵐ[μ] η) : IndepSets s1 s2 κ μ ↔ IndepSets s1 s2 η μ := by peel 4 refine ⟨fun h' ↦ ?_, fun h' ↦ ?_⟩ <;> · filter_upwards [h, h'] with a ha h'a simpa [ha] using h'a alias ⟨IndepSets.congr, _⟩ := indepSets_congr lemma iIndep_congr (h : κ =ᵐ[μ] η) : iIndep m κ μ ↔ iIndep m η μ := iIndepSets_congr h alias ⟨iIndep.congr, _⟩ := iIndep_congr lemma indep_congr {m₁ m₂ : MeasurableSpace Ω} {_mΩ : MeasurableSpace Ω} {κ η : Kernel α Ω} (h : κ =ᵐ[μ] η) : Indep m₁ m₂ κ μ ↔ Indep m₁ m₂ η μ := indepSets_congr h alias ⟨Indep.congr, _⟩ := indep_congr lemma iIndepSet_congr (h : κ =ᵐ[μ] η) : iIndepSet s κ μ ↔ iIndepSet s η μ := iIndep_congr h alias ⟨iIndepSet.congr, _⟩ := iIndepSet_congr lemma indepSet_congr {s t : Set Ω} (h : κ =ᵐ[μ] η) : IndepSet s t κ μ ↔ IndepSet s t η μ := indep_congr h alias ⟨indepSet.congr, _⟩ := indepSet_congr lemma iIndepFun_congr {β : ι → Type} {m : ∀ x : ι, MeasurableSpace (β x)} {f : ∀ x : ι, Ω → β x} (h : κ =ᵐ[μ] η) : iIndepFun f κ μ ↔ iIndepFun f η μ := iIndep_congr h alias ⟨iIndepFun.congr, _⟩ := iIndepFun_congr lemma indepFun_congr {β γ} [MeasurableSpace β] [MeasurableSpace γ] {f : Ω → β} {g : Ω → γ} (h : κ =ᵐ[μ] η) : IndepFun f g κ μ ↔ IndepFun f g η μ := indep_congr h alias ⟨IndepFun.congr, _⟩ := indepFun_congr lemma iIndepSets.meas_biInter (h : iIndepSets π κ μ) (s : Finset ι) {f : ι → Set Ω} (hf : ∀ i, i ∈ s → f i ∈ π i) : ∀ᵐ a ∂μ, κ a (⋂ i ∈ s, f i) = ∏ i ∈ s, κ a (f i) := h s hf lemma iIndepSets.ae_isProbabilityMeasure (h : iIndepSets π κ μ) : ∀ᵐ a ∂μ, IsProbabilityMeasure (κ a) := by filter_upwards [h.meas_biInter ∅ (f := fun _ ↦ Set.univ) (by simp)] with a ha exact ⟨by simpa using ha⟩ lemma iIndepSets.meas_iInter [Fintype ι] (h : iIndepSets π κ μ) (hs : ∀ i, s i ∈ π i) : ∀ᵐ a ∂μ, κ a (⋂ i, s i) = ∏ i, κ a (s i) := by filter_upwards [h.meas_biInter Finset.univ (fun _i _ ↦ hs _)] with a ha using by simp [← ha] lemma iIndep.iIndepSets' (hμ : iIndep m κ μ) : iIndepSets (fun x ↦ {s \| MeasurableSet[m x] s}) κ μ := hμ lemma iIndep.ae_isProbabilityMeasure (h : iIndep m κ μ) : ∀ᵐ a ∂μ, IsProbabilityMeasure (κ a) := h.iIndepSets'.ae_isProbabilityMeasure lemma iIndep.meas_biInter (hμ : iIndep m κ μ) (hs : ∀ i, i ∈ S → MeasurableSet[m i] (s i)) : ∀ᵐ a ∂μ, κ a (⋂ i ∈ S, s i) = ∏ i ∈ S, κ a (s i) := hμ _ hs lemma iIndep.meas_iInter [Fintype ι] (h : iIndep m κ μ) (hs : ∀ i, MeasurableSet[m i] (s i)) : ∀ᵐ a ∂μ, κ a (⋂ i, s i) = ∏ i, κ a (s i) := by filter_upwards [h.meas_biInter (fun i (_ : i ∈ Finset.univ) ↦ hs _)] with a ha simp [← ha] @[nontriviality, simp] lemma iIndepSets.of_subsingleton [Subsingleton ι] {m : ι → Set (Set Ω)} {κ : Kernel α Ω} [IsMarkovKernel κ] : iIndepSets m κ μ := by rintro s f hf obtain rfl \| ⟨i, rfl⟩ : s = ∅ ∨ ∃ i, s = {i} := by simpa using (subsingleton_of_subsingleton (s := s.toSet)).eq_empty_or_singleton all_goals simp @[nontriviality, simp] lemma iIndep.of_subsingleton [Subsingleton ι] {m : ι → MeasurableSpace Ω} {κ : Kernel α Ω} [IsMarkovKernel κ] : iIndep m κ μ := by simp [iIndep] @[nontriviality, simp] lemma iIndepFun.of_subsingleton [Subsingleton ι] {β : ι → Type} {m : ∀ i, MeasurableSpace (β i)} {f : ∀ i, Ω → β i} [IsMarkovKernel κ] : iIndepFun f κ μ := by simp [iIndepFun] protected lemma iIndepFun.iIndep (hf : iIndepFun f κ μ) : iIndep (fun x ↦ (mβ x).comap (f x)) κ μ := hf lemma iIndepFun.ae_isProbabilityMeasure (h : iIndepFun f κ μ) : ∀ᵐ a ∂μ, IsProbabilityMeasure (κ a) := h.iIndep.ae_isProbabilityMeasure lemma iIndepFun.meas_biInter (hf : iIndepFun f κ μ) (hs : ∀ i, i ∈ S → MeasurableSet[(mβ i).comap (f i)] (s i)) : ∀ᵐ a ∂μ, κ a (⋂ i ∈ S, s i) = ∏ i ∈ S, κ a (s i) := hf.iIndep.meas_biInter hs lemma iIndepFun.meas_iInter [Fintype ι] (hf : iIndepFun f κ μ) (hs : ∀ i, MeasurableSet[(mβ i).comap (f i)] (s i)) : ∀ᵐ a ∂μ, κ a (⋂ i, s i) = ∏ i, κ a (s i) := hf.iIndep.meas_iInter hs lemma IndepFun.meas_inter {β γ : Type} [mβ : MeasurableSpace β] [mγ : MeasurableSpace γ] {f : Ω → β} {g : Ω → γ} (hfg : IndepFun f g κ μ) {s t : Set Ω} (hs : MeasurableSet[mβ.comap f] s) (ht : MeasurableSet[mγ.comap g] t) : ∀ᵐ a ∂μ, κ a (s ∩ t) = κ a s * κ a t := hfg _ _ hs ht end ByDefinition section Indep variable {_mα : MeasurableSpace α} @[symm] theorem IndepSets.symm {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} {s₁ s₂ : Set (Set Ω)} (h : IndepSets s₁ s₂ κ μ) : IndepSets s₂ s₁ κ μ := by intros t1 t2 ht1 ht2 filter_upwards [h t2 t1 ht2 ht1] with a ha rwa [Set.inter_comm, mul_comm] @[symm] theorem Indep.symm {m₁ m₂ : MeasurableSpace Ω} {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} (h : Indep m₁ m₂ κ μ) : Indep m₂ m₁ κ μ := IndepSets.symm h theorem indep_bot_right (m' : MeasurableSpace Ω) {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} [IsZeroOrMarkovKernel κ] : Indep m' ⊥ κ μ := by intros s t _ ht rw [Set.mem_setOf_eq, MeasurableSpace.measurableSet_bot_iff] at ht rcases eq_zero_or_isMarkovKernel κ with rfl\| h · simp refine Filter.Eventually.of_forall (fun a ↦ ?_) rcases ht with ht \| ht · rw [ht, Set.inter_empty, measure_empty, mul_zero] · rw [ht, Set.inter_univ, measure_univ, mul_one] theorem indep_bot_left (m' : MeasurableSpace Ω) {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} [IsZeroOrMarkovKernel κ] : Indep ⊥ m' κ μ := (indep_bot_right m').symm theorem indepSet_empty_right {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} [IsZeroOrMarkovKernel κ] (s : Set Ω) : IndepSet s ∅ κ μ := by simp only [IndepSet, generateFrom_singleton_empty] exact indep_bot_right _ theorem indepSet_empty_left {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} [IsZeroOrMarkovKernel κ] (s : Set Ω) : IndepSet ∅ s κ μ := (indepSet_empty_right s).symm theorem indepSets_of_indepSets_of_le_left {s₁ s₂ s₃ : Set (Set Ω)} {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} (h_indep : IndepSets s₁ s₂ κ μ) (h31 : s₃ ⊆ s₁) : IndepSets s₃ s₂ κ μ := fun t1 t2 ht1 ht2 => h_indep t1 t2 (Set.mem_of_subset_of_mem h31 ht1) ht2 theorem indepSets_of_indepSets_of_le_right {s₁ s₂ s₃ : Set (Set Ω)} {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} (h_indep : IndepSets s₁ s₂ κ μ) (h32 : s₃ ⊆ s₂) : IndepSets s₁ s₃ κ μ := fun t1 t2 ht1 ht2 => h_indep t1 t2 ht1 (Set.mem_of_subset_of_mem h32 ht2) theorem indep_of_indep_of_le_left {m₁ m₂ m₃ : MeasurableSpace Ω} {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} (h_indep : Indep m₁ m₂ κ μ) (h31 : m₃ ≤ m₁) : Indep m₃ m₂ κ μ := fun t1 t2 ht1 ht2 => h_indep t1 t2 (h31 _ ht1) ht2 theorem indep_of_indep_of_le_right {m₁ m₂ m₃ : MeasurableSpace Ω} {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} (h_indep : Indep m₁ m₂ κ μ) (h32 : m₃ ≤ m₂) : Indep m₁ m₃ κ μ := fun t1 t2 ht1 ht2 => h_indep t1 t2 ht1 (h32 _ ht2) theorem IndepSets.union {s₁ s₂ s' : Set (Set Ω)} {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} (h₁ : IndepSets s₁ s' κ μ) (h₂ : IndepSets s₂ s' κ μ) : IndepSets (s₁ ∪ s₂) s' κ μ := by intro t1 t2 ht1 ht2 rcases (Set.mem_union _ _ _).mp ht1 with ht1₁ \| ht1₂ · exact h₁ t1 t2 ht1₁ ht2 · exact h₂ t1 t2 ht1₂ ht2 @[simp] theorem IndepSets.union_iff {s₁ s₂ s' : Set (Set Ω)} {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} : IndepSets (s₁ ∪ s₂) s' κ μ ↔ IndepSets s₁ s' κ μ ∧ IndepSets s₂ s' κ μ := ⟨fun h => ⟨indepSets_of_indepSets_of_le_left h Set.subset_union_left, indepSets_of_indepSets_of_le_left h Set.subset_union_right⟩, fun h => IndepSets.union h.left h.right⟩ theorem IndepSets.iUnion {s : ι → Set (Set Ω)} {s' : Set (Set Ω)} {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} (hyp : ∀ n, IndepSets (s n) s' κ μ) : IndepSets (⋃ n, s n) s' κ μ := by intro t1 t2 ht1 ht2 rw [Set.mem_iUnion] at ht1 obtain ⟨n, ht1⟩ := ht1 exact hyp n t1 t2 ht1 ht2 theorem IndepSets.bUnion {s : ι → Set (Set Ω)} {s' : Set (Set Ω)} {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} {u : Set ι} (hyp : ∀ n ∈ u, IndepSets (s n) s' κ μ) : IndepSets (⋃ n ∈ u, s n) s' κ μ := by intro t1 t2 ht1 ht2 simp_rw [Set.mem_iUnion] at ht1 rcases ht1 with ⟨n, hpn, ht1⟩ exact hyp n hpn t1 t2 ht1 ht2 theorem IndepSets.inter {s₁ s' : Set (Set Ω)} (s₂ : Set (Set Ω)) {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} (h₁ : IndepSets s₁ s' κ μ) : IndepSets (s₁ ∩ s₂) s' κ μ := fun t1 t2 ht1 ht2 => h₁ t1 t2 ((Set.mem_inter_iff _ _ _).mp ht1).left ht2 theorem IndepSets.iInter {s : ι → Set (Set Ω)} {s' : Set (Set Ω)} {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} (h : ∃ n, IndepSets (s n) s' κ μ) : IndepSets (⋂ n, s n) s' κ μ := by intro t1 t2 ht1 ht2; obtain ⟨n, h⟩ := h; exact h t1 t2 (Set.mem_iInter.mp ht1 n) ht2 theorem IndepSets.bInter {s : ι → Set (Set Ω)} {s' : Set (Set Ω)} {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} {u : Set ι} (h : ∃ n ∈ u, IndepSets (s n) s' κ μ) : IndepSets (⋂ n ∈ u, s n) s' κ μ := by intro t1 t2 ht1 ht2 rcases h with ⟨n, hn, h⟩ exact h t1 t2 (Set.biInter_subset_of_mem hn ht1) ht2 theorem iIndep_comap_mem_iff {f : ι → Set Ω} {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} : iIndep (fun i => MeasurableSpace.comap (· ∈ f i) ⊤) κ μ ↔ iIndepSet f κ μ := by simp_rw [← generateFrom_singleton, iIndepSet] theorem iIndepSets_singleton_iff {s : ι → Set Ω} {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} : iIndepSets (fun i ↦ {s i}) κ μ ↔ ∀ S : Finset ι, ∀ᵐ a ∂μ, κ a (⋂ i ∈ S, s i) = ∏ i ∈ S, κ a (s i) := by refine ⟨fun h S ↦ h S (fun i _ ↦ rfl), fun h S f hf ↦ ?_⟩ filter_upwards [h S] with a ha have : ∀ i ∈ S, κ a (f i) = κ a (s i) := fun i hi ↦ by rw [hf i hi] rwa [Finset.prod_congr rfl this, Set.iInter₂_congr hf] theorem indepSets_singleton_iff {s t : Set Ω} {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} : IndepSets {s} {t} κ μ ↔ ∀ᵐ a ∂μ, κ a (s ∩ t) = κ a s * κ a t := ⟨fun h ↦ h s t rfl rfl, fun h s1 t1 hs1 ht1 ↦ by rwa [Set.mem_singleton_iff.mp hs1, Set.mem_singleton_iff.mp ht1]⟩ end Indep /-! ### Deducing `Indep` from `iIndep` -/ section FromiIndepToIndep variable {_mα : MeasurableSpace α} theorem iIndepSets.indepSets {s : ι → Set (Set Ω)} {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} (h_indep : iIndepSets s κ μ) {i j : ι} (hij : i ≠ j) : IndepSets (s i) (s j) κ μ := by classical intro t₁ t₂ ht₁ ht₂ have hf_m : ∀ x : ι, x ∈ ({i, j} : Finset ι) → ite (x = i) t₁ t₂ ∈ s x := by intro x hx rcases Finset.mem_insert.mp hx with hx \| hx · simp [hx, ht₁] · simp [Finset.mem_singleton.mp hx, hij.symm, ht₂] have h1 : t₁ = ite (i = i) t₁ t₂ := by simp only [if_true, eq_self_iff_true] have h2 : t₂ = ite (j = i) t₁ t₂ := by simp only [hij.symm, if_false] have h_inter : ⋂ (t : ι) (_ : t ∈ ({i, j} : Finset ι)), ite (t = i) t₁ t₂ = ite (i = i) t₁ t₂ ∩ ite (j = i) t₁ t₂ := by simp only [Finset.set_biInter_singleton, Finset.set_biInter_insert] filter_upwards [h_indep {i, j} hf_m] with a h_indep' have h_prod : (∏ t ∈ ({i, j} : Finset ι), κ a (ite (t = i) t₁ t₂)) = κ a (ite (i = i) t₁ t₂) * κ a (ite (j = i) t₁ t₂) := by simp only [hij, Finset.prod_singleton, Finset.prod_insert, not_false_iff, Finset.mem_singleton] rw [h1] nth_rw 2 [h2] nth_rw 4 [h2] rw [← h_inter, ← h_prod, h_indep'] theorem iIndep.indep {m : ι → MeasurableSpace Ω} {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} (h_indep : iIndep m κ μ) {i j : ι} (hij : i ≠ j) : Indep (m i) (m j) κ μ := iIndepSets.indepSets h_indep hij theorem iIndepFun.indepFun {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} {β : ι → Type} {m : ∀ x, MeasurableSpace (β x)} {f : ∀ i, Ω → β i} (hf_Indep : iIndepFun f κ μ) {i j : ι} (hij : i ≠ j) : IndepFun (f i) (f j) κ μ := hf_Indep.indep hij end FromiIndepToIndep /-! ## π-system lemma Independence of measurable spaces is equivalent to independence of generating π-systems. -/ section FromMeasurableSpacesToSetsOfSets /-! ### Independence of measurable space structures implies independence of generating π-systems -/ variable {_mα : MeasurableSpace α} theorem iIndep.iIndepSets {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} {m : ι → MeasurableSpace Ω} {s : ι → Set (Set Ω)} (hms : ∀ n, m n = generateFrom (s n)) (h_indep : iIndep m κ μ) : iIndepSets s κ μ := fun S f hfs => h_indep S fun x hxS => ((hms x).symm ▸ measurableSet_generateFrom (hfs x hxS) : MeasurableSet[m x] (f x)) theorem Indep.indepSets {_mΩ : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} {s1 s2 : Set (Set Ω)} (h_indep : Indep (generateFrom s1) (generateFrom s2) κ μ) : IndepSets s1 s2 κ μ := fun t1 t2 ht1 ht2 => h_indep t1 t2 (measurableSet_generateFrom ht1) (measurableSet_generateFrom ht2) end FromMeasurableSpacesToSetsOfSets section FromPiSystemsToMeasurableSpaces /-! ### Independence of generating π-systems implies independence of measurable space structures -/ variable {_mα : MeasurableSpace α} theorem IndepSets.indep_aux {m₂ m : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} [IsZeroOrMarkovKernel κ] {p1 p2 : Set (Set Ω)} (h2 : m₂ ≤ m) (hp2 : IsPiSystem p2) (hpm2 : m₂ = generateFrom p2) (hyp : IndepSets p1 p2 κ μ) {t1 t2 : Set Ω} (ht1 : t1 ∈ p1) (ht1m : MeasurableSet[m] t1) (ht2m : MeasurableSet[m₂] t2) : ∀ᵐ a ∂μ, κ a (t1 ∩ t2) = κ a t1 κ a t2 := by rcases eq_zero_or_isMarkovKernel κ with rfl \| h · simp induction t2, ht2m using induction_on_inter hpm2 hp2 with \| empty => simp \| basic u hu => exact hyp t1 u ht1 hu \| compl u hu ihu => filter_upwards [ihu] with a ha rw [← Set.diff_eq, ← Set.diff_self_inter, measure_diff inter_subset_left (ht1m.inter (h2 _ hu)).nullMeasurableSet (measure_ne_top _ _), ha, measure_compl (h2 _ hu) (measure_ne_top _ _), measure_univ, ENNReal.mul_sub, mul_one] exact fun _ _ ↦ measure_ne_top _ _ \| iUnion f hfd hfm ihf => rw [← ae_all_iff] at ihf filter_upwards [ihf] with a ha rw [inter_iUnion, measure_iUnion, measure_iUnion hfd fun i ↦ h2 _ (hfm i)] · simp only [ENNReal.tsum_mul_left, ha] · exact hfd.mono fun i j h ↦ (h.inter_left' _).inter_right' _ · exact fun i ↦ .inter ht1m (h2 _ <\| hfm i) /-- The measurable space structures generated by independent pi-systems are independent. -/ theorem IndepSets.indep {m1 m2 m : MeasurableSpace Ω} {κ : Kernel α Ω} {μ : Measure α} [IsZeroOrMarkovKernel κ] {p1 p2 : Set (Set Ω)} (h1 : m1 ≤ m) (h2 : m2 ≤ m) (hp1 : IsPiSystem p1) (hp2 : IsPiSystem p2) (hpm1 : m1 = generateFrom p1) (hpm2 : m2 = generateFrom p2)	(hyp : IndepSets p1 p2 κ μ) : Indep m1 m2 κ μ := by rcases eq_zero_or_isMarkovKernel κ with rfl \| h · simp intros t1 t2 ht1 ht2 induction t1, ht1 using induction_on_inter hpm1 hp1 with \| empty => simp only [Set.empty_inter, measure_empty, zero_mul, eq_self_iff_true, Filter.eventually_true] \| basic t ht => refine IndepSets.indep_aux h2 hp2 hpm2 hyp ht (h1 _ ?_) ht2 rw [hpm1] exact measurableSet_generateFrom ht \| compl t ht iht => filter_upwards [iht] with a ha have : tᶜ ∩ t2 = t2 \ (t ∩ t2) := by rw [Set.inter_comm t, Set.diff_self_inter, Set.diff_eq_compl_inter] rw [this, Set.inter_comm t t2, measure_diff Set.inter_subset_left ((h2 _ ht2).inter (h1 _ ht)).nullMeasurableSet (measure_ne_top (κ a) _), Set.inter_comm, ha, measure_compl (h1 _ ht) (measure_ne_top (κ a) t), measure_univ, mul_comm (1 - κ a t), ENNReal.mul_sub (fun _ _ ↦ measure_ne_top (κ a) _), mul_one, mul_comm] \| iUnion f hf_disj hf_meas h =>	Mathlib/Probability/Independence/Kernel.lean	521	542
/- Copyright (c) 2020 Kexing Ying. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kexing Ying -/ import Mathlib.Algebra.Group.Conj import Mathlib.Algebra.Group.Pi.Lemmas import Mathlib.Algebra.Group.Subgroup.Ker /-! # Basic results on subgroups We prove basic results on the definitions of subgroups. The bundled subgroups use bundled monoid homomorphisms. Special thanks goes to Amelia Livingston and Yury Kudryashov for their help and inspiration. ## Main definitions Notation used here: - `G N` are `Group`s - `A` is an `AddGroup` - `H K` are `Subgroup`s of `G` or `AddSubgroup`s of `A` - `x` is an element of type `G` or type `A` - `f g : N →* G` are group homomorphisms - `s k` are sets of elements of type `G` Definitions in the file: * `Subgroup.prod H K` : the product of subgroups `H`, `K` of groups `G`, `N` respectively, `H × K` is a subgroup of `G × N` ## Implementation notes Subgroup inclusion is denoted `≤` rather than `⊆`, although `∈` is defined as membership of a subgroup's underlying set. ## Tags subgroup, subgroups -/ assert_not_exists OrderedAddCommMonoid Multiset Ring open Function open scoped Int variable {G G' G'' : Type} [Group G] [Group G'] [Group G''] variable {A : Type} [AddGroup A] section SubgroupClass variable {M S : Type} [DivInvMonoid M] [SetLike S M] [hSM : SubgroupClass S M] {H K : S} variable [SetLike S G] [SubgroupClass S G] @[to_additive] theorem div_mem_comm_iff {a b : G} : a / b ∈ H ↔ b / a ∈ H := inv_div b a ▸ inv_mem_iff end SubgroupClass namespace Subgroup variable (H K : Subgroup G) @[to_additive] protected theorem div_mem_comm_iff {a b : G} : a / b ∈ H ↔ b / a ∈ H := div_mem_comm_iff variable {k : Set G} open Set variable {N : Type} [Group N] {P : Type} [Group P] /-- Given `Subgroup`s `H`, `K` of groups `G`, `N` respectively, `H × K` as a subgroup of `G × N`. -/ @[to_additive prod "Given `AddSubgroup`s `H`, `K` of `AddGroup`s `A`, `B` respectively, `H × K` as an `AddSubgroup` of `A × B`."] def prod (H : Subgroup G) (K : Subgroup N) : Subgroup (G × N) := { Submonoid.prod H.toSubmonoid K.toSubmonoid with inv_mem' := fun hx => ⟨H.inv_mem' hx.1, K.inv_mem' hx.2⟩ } @[to_additive coe_prod] theorem coe_prod (H : Subgroup G) (K : Subgroup N) : (H.prod K : Set (G × N)) = (H : Set G) ×ˢ (K : Set N) := rfl @[to_additive mem_prod] theorem mem_prod {H : Subgroup G} {K : Subgroup N} {p : G × N} : p ∈ H.prod K ↔ p.1 ∈ H ∧ p.2 ∈ K := Iff.rfl open scoped Relator in @[to_additive prod_mono] theorem prod_mono : ((· ≤ ·) ⇒ (· ≤ ·) ⇒ (· ≤ ·)) (@prod G _ N _) (@prod G _ N _) := fun _s _s' hs _t _t' ht => Set.prod_mono hs ht @[to_additive prod_mono_right] theorem prod_mono_right (K : Subgroup G) : Monotone fun t : Subgroup N => K.prod t := prod_mono (le_refl K) @[to_additive prod_mono_left] theorem prod_mono_left (H : Subgroup N) : Monotone fun K : Subgroup G => K.prod H := fun _ _ hs => prod_mono hs (le_refl H) @[to_additive prod_top] theorem prod_top (K : Subgroup G) : K.prod (⊤ : Subgroup N) = K.comap (MonoidHom.fst G N) := ext fun x => by simp [mem_prod, MonoidHom.coe_fst] @[to_additive top_prod] theorem top_prod (H : Subgroup N) : (⊤ : Subgroup G).prod H = H.comap (MonoidHom.snd G N) := ext fun x => by simp [mem_prod, MonoidHom.coe_snd] @[to_additive (attr := simp) top_prod_top] theorem top_prod_top : (⊤ : Subgroup G).prod (⊤ : Subgroup N) = ⊤ := (top_prod _).trans <\| comap_top _ @[to_additive (attr := simp) bot_prod_bot] theorem bot_prod_bot : (⊥ : Subgroup G).prod (⊥ : Subgroup N) = ⊥ := SetLike.coe_injective <\| by simp [coe_prod] @[deprecated (since := "2025-03-11")] alias _root_.AddSubgroup.bot_sum_bot := AddSubgroup.bot_prod_bot @[to_additive le_prod_iff] theorem le_prod_iff {H : Subgroup G} {K : Subgroup N} {J : Subgroup (G × N)} : J ≤ H.prod K ↔ map (MonoidHom.fst G N) J ≤ H ∧ map (MonoidHom.snd G N) J ≤ K := by simpa only [← Subgroup.toSubmonoid_le] using Submonoid.le_prod_iff @[to_additive prod_le_iff] theorem prod_le_iff {H : Subgroup G} {K : Subgroup N} {J : Subgroup (G × N)} : H.prod K ≤ J ↔ map (MonoidHom.inl G N) H ≤ J ∧ map (MonoidHom.inr G N) K ≤ J := by simpa only [← Subgroup.toSubmonoid_le] using Submonoid.prod_le_iff @[to_additive (attr := simp) prod_eq_bot_iff] theorem prod_eq_bot_iff {H : Subgroup G} {K : Subgroup N} : H.prod K = ⊥ ↔ H = ⊥ ∧ K = ⊥ := by simpa only [← Subgroup.toSubmonoid_inj] using Submonoid.prod_eq_bot_iff @[to_additive closure_prod] theorem closure_prod {s : Set G} {t : Set N} (hs : 1 ∈ s) (ht : 1 ∈ t) : closure (s ×ˢ t) = (closure s).prod (closure t) := le_antisymm (closure_le _ \|>.2 <\| Set.prod_subset_prod_iff.2 <\| .inl ⟨subset_closure, subset_closure⟩) (prod_le_iff.2 ⟨ map_le_iff_le_comap.2 <\| closure_le _ \|>.2 fun _x hx => subset_closure ⟨hx, ht⟩, map_le_iff_le_comap.2 <\| closure_le _ \|>.2 fun _y hy => subset_closure ⟨hs, hy⟩⟩) /-- Product of subgroups is isomorphic to their product as groups. -/ @[to_additive prodEquiv "Product of additive subgroups is isomorphic to their product as additive groups"] def prodEquiv (H : Subgroup G) (K : Subgroup N) : H.prod K ≃ H × K := { Equiv.Set.prod (H : Set G) (K : Set N) with map_mul' := fun _ _ => rfl } section Pi variable {η : Type} {f : η → Type} -- defined here and not in Algebra.Group.Submonoid.Operations to have access to Algebra.Group.Pi /-- A version of `Set.pi` for submonoids. Given an index set `I` and a family of submodules `s : Π i, Submonoid f i`, `pi I s` is the submonoid of dependent functions `f : Π i, f i` such that `f i` belongs to `Pi I s` whenever `i ∈ I`. -/ @[to_additive "A version of `Set.pi` for `AddSubmonoid`s. Given an index set `I` and a family of submodules `s : Π i, AddSubmonoid f i`, `pi I s` is the `AddSubmonoid` of dependent functions `f : Π i, f i` such that `f i` belongs to `pi I s` whenever `i ∈ I`."] def _root_.Submonoid.pi [∀ i, MulOneClass (f i)] (I : Set η) (s : ∀ i, Submonoid (f i)) : Submonoid (∀ i, f i) where carrier := I.pi fun i => (s i).carrier one_mem' i _ := (s i).one_mem mul_mem' hp hq i hI := (s i).mul_mem (hp i hI) (hq i hI) variable [∀ i, Group (f i)] /-- A version of `Set.pi` for subgroups. Given an index set `I` and a family of submodules `s : Π i, Subgroup f i`, `pi I s` is the subgroup of dependent functions `f : Π i, f i` such that `f i` belongs to `pi I s` whenever `i ∈ I`. -/ @[to_additive "A version of `Set.pi` for `AddSubgroup`s. Given an index set `I` and a family of submodules `s : Π i, AddSubgroup f i`, `pi I s` is the `AddSubgroup` of dependent functions `f : Π i, f i` such that `f i` belongs to `pi I s` whenever `i ∈ I`."] def pi (I : Set η) (H : ∀ i, Subgroup (f i)) : Subgroup (∀ i, f i) := { Submonoid.pi I fun i => (H i).toSubmonoid with inv_mem' := fun hp i hI => (H i).inv_mem (hp i hI) } @[to_additive] theorem coe_pi (I : Set η) (H : ∀ i, Subgroup (f i)) : (pi I H : Set (∀ i, f i)) = Set.pi I fun i => (H i : Set (f i)) := rfl @[to_additive] theorem mem_pi (I : Set η) {H : ∀ i, Subgroup (f i)} {p : ∀ i, f i} : p ∈ pi I H ↔ ∀ i : η, i ∈ I → p i ∈ H i := Iff.rfl @[to_additive] theorem pi_top (I : Set η) : (pi I fun i => (⊤ : Subgroup (f i))) = ⊤ := ext fun x => by simp [mem_pi] @[to_additive] theorem pi_empty (H : ∀ i, Subgroup (f i)) : pi ∅ H = ⊤ := ext fun x => by simp [mem_pi] @[to_additive] theorem pi_bot : (pi Set.univ fun i => (⊥ : Subgroup (f i))) = ⊥ := (eq_bot_iff_forall _).mpr fun p hp => by simp only [mem_pi, mem_bot] at * ext j exact hp j trivial @[to_additive] theorem le_pi_iff {I : Set η} {H : ∀ i, Subgroup (f i)} {J : Subgroup (∀ i, f i)} : J ≤ pi I H ↔ ∀ i : η, i ∈ I → map (Pi.evalMonoidHom f i) J ≤ H i := by constructor · intro h i hi rintro _ ⟨x, hx, rfl⟩ exact (h hx) _ hi · intro h x hx i hi exact h i hi ⟨_, hx, rfl⟩ @[to_additive (attr := simp)] theorem mulSingle_mem_pi [DecidableEq η] {I : Set η} {H : ∀ i, Subgroup (f i)} (i : η) (x : f i) : Pi.mulSingle i x ∈ pi I H ↔ i ∈ I → x ∈ H i := by constructor · intro h hi simpa using h i hi · intro h j hj by_cases heq : j = i · subst heq simpa using h hj · simp [heq, one_mem] @[to_additive] theorem pi_eq_bot_iff (H : ∀ i, Subgroup (f i)) : pi Set.univ H = ⊥ ↔ ∀ i, H i = ⊥ := by classical simp only [eq_bot_iff_forall] constructor · intro h i x hx have : MonoidHom.mulSingle f i x = 1 := h (MonoidHom.mulSingle f i x) ((mulSingle_mem_pi i x).mpr fun _ => hx) simpa using congr_fun this i · exact fun h x hx => funext fun i => h _ _ (hx i trivial) end Pi end Subgroup namespace Subgroup variable {H K : Subgroup G} variable (H) /-- A subgroup is characteristic if it is fixed by all automorphisms. Several equivalent conditions are provided by lemmas of the form `Characteristic.iff...` -/ structure Characteristic : Prop where /-- `H` is fixed by all automorphisms -/ fixed : ∀ ϕ : G ≃* G, H.comap ϕ.toMonoidHom = H attribute [class] Characteristic instance (priority := 100) normal_of_characteristic [h : H.Characteristic] : H.Normal := ⟨fun a ha b => (SetLike.ext_iff.mp (h.fixed (MulAut.conj b)) a).mpr ha⟩ end Subgroup namespace AddSubgroup variable (H : AddSubgroup A) /-- An `AddSubgroup` is characteristic if it is fixed by all automorphisms. Several equivalent conditions are provided by lemmas of the form `Characteristic.iff...` -/ structure Characteristic : Prop where /-- `H` is fixed by all automorphisms -/ fixed : ∀ ϕ : A ≃+ A, H.comap ϕ.toAddMonoidHom = H attribute [to_additive] Subgroup.Characteristic attribute [class] Characteristic instance (priority := 100) normal_of_characteristic [h : H.Characteristic] : H.Normal := ⟨fun a ha b => (SetLike.ext_iff.mp (h.fixed (AddAut.conj b)) a).mpr ha⟩ end AddSubgroup namespace Subgroup variable {H K : Subgroup G} @[to_additive] theorem characteristic_iff_comap_eq : H.Characteristic ↔ ∀ ϕ : G ≃* G, H.comap ϕ.toMonoidHom = H := ⟨Characteristic.fixed, Characteristic.mk⟩ @[to_additive] theorem characteristic_iff_comap_le : H.Characteristic ↔ ∀ ϕ : G ≃* G, H.comap ϕ.toMonoidHom ≤ H := characteristic_iff_comap_eq.trans ⟨fun h ϕ => le_of_eq (h ϕ), fun h ϕ => le_antisymm (h ϕ) fun g hg => h ϕ.symm ((congr_arg (· ∈ H) (ϕ.symm_apply_apply g)).mpr hg)⟩ @[to_additive] theorem characteristic_iff_le_comap : H.Characteristic ↔ ∀ ϕ : G ≃* G, H ≤ H.comap ϕ.toMonoidHom := characteristic_iff_comap_eq.trans ⟨fun h ϕ => ge_of_eq (h ϕ), fun h ϕ => le_antisymm (fun g hg => (congr_arg (· ∈ H) (ϕ.symm_apply_apply g)).mp (h ϕ.symm hg)) (h ϕ)⟩ @[to_additive] theorem characteristic_iff_map_eq : H.Characteristic ↔ ∀ ϕ : G ≃* G, H.map ϕ.toMonoidHom = H := by simp_rw [map_equiv_eq_comap_symm'] exact characteristic_iff_comap_eq.trans ⟨fun h ϕ => h ϕ.symm, fun h ϕ => h ϕ.symm⟩ @[to_additive] theorem characteristic_iff_map_le : H.Characteristic ↔ ∀ ϕ : G ≃* G, H.map ϕ.toMonoidHom ≤ H := by simp_rw [map_equiv_eq_comap_symm'] exact characteristic_iff_comap_le.trans ⟨fun h ϕ => h ϕ.symm, fun h ϕ => h ϕ.symm⟩ @[to_additive] theorem characteristic_iff_le_map : H.Characteristic ↔ ∀ ϕ : G ≃* G, H ≤ H.map ϕ.toMonoidHom := by simp_rw [map_equiv_eq_comap_symm'] exact characteristic_iff_le_comap.trans ⟨fun h ϕ => h ϕ.symm, fun h ϕ => h ϕ.symm⟩ @[to_additive] instance botCharacteristic : Characteristic (⊥ : Subgroup G) := characteristic_iff_le_map.mpr fun _ϕ => bot_le @[to_additive] instance topCharacteristic : Characteristic (⊤ : Subgroup G) := characteristic_iff_map_le.mpr fun _ϕ => le_top variable (H) section Normalizer variable {H} @[to_additive] theorem normalizer_eq_top_iff : H.normalizer = ⊤ ↔ H.Normal := eq_top_iff.trans ⟨fun h => ⟨fun a ha b => (h (mem_top b) a).mp ha⟩, fun h a _ha b => ⟨fun hb => h.conj_mem b hb a, fun hb => by rwa [h.mem_comm_iff, inv_mul_cancel_left] at hb⟩⟩ variable (H) in @[to_additive] theorem normalizer_eq_top [h : H.Normal] : H.normalizer = ⊤ := normalizer_eq_top_iff.mpr h variable {N : Type} [Group N] /-- The preimage of the normalizer is contained in the normalizer of the preimage. -/ @[to_additive "The preimage of the normalizer is contained in the normalizer of the preimage."] theorem le_normalizer_comap (f : N → G) : H.normalizer.comap f ≤ (H.comap f).normalizer := fun x => by simp only [mem_normalizer_iff, mem_comap] intro h n simp [h (f n)] /-- The image of the normalizer is contained in the normalizer of the image. -/ @[to_additive "The image of the normalizer is contained in the normalizer of the image."] theorem le_normalizer_map (f : G →* N) : H.normalizer.map f ≤ (H.map f).normalizer := fun _ => by simp only [and_imp, exists_prop, mem_map, exists_imp, mem_normalizer_iff] rintro x hx rfl n constructor · rintro ⟨y, hy, rfl⟩ use x * y * x⁻¹, (hx y).1 hy simp · rintro ⟨y, hyH, hy⟩ use x⁻¹ * y * x rw [hx] simp [hy, hyH, mul_assoc] @[to_additive] theorem comap_normalizer_eq_of_le_range {f : N →* G} (h : H ≤ f.range) : comap f H.normalizer = (comap f H).normalizer := by apply le_antisymm (le_normalizer_comap f) rw [← map_le_iff_le_comap] apply (le_normalizer_map f).trans rw [map_comap_eq_self h] @[to_additive] theorem subgroupOf_normalizer_eq {H N : Subgroup G} (h : H ≤ N) : H.normalizer.subgroupOf N = (H.subgroupOf N).normalizer := comap_normalizer_eq_of_le_range (h.trans_eq N.range_subtype.symm) @[to_additive] theorem normal_subgroupOf_iff_le_normalizer (h : H ≤ K) : (H.subgroupOf K).Normal ↔ K ≤ H.normalizer := by rw [← subgroupOf_eq_top, subgroupOf_normalizer_eq h, normalizer_eq_top_iff] @[to_additive] theorem normal_subgroupOf_iff_le_normalizer_inf : (H.subgroupOf K).Normal ↔ K ≤ (H ⊓ K).normalizer := inf_subgroupOf_right H K ▸ normal_subgroupOf_iff_le_normalizer inf_le_right @[to_additive] instance (priority := 100) normal_in_normalizer : (H.subgroupOf H.normalizer).Normal := (normal_subgroupOf_iff_le_normalizer H.le_normalizer).mpr le_rfl @[to_additive] theorem le_normalizer_of_normal_subgroupOf [hK : (H.subgroupOf K).Normal] (HK : H ≤ K) : K ≤ H.normalizer := (normal_subgroupOf_iff_le_normalizer HK).mp hK @[to_additive] theorem subset_normalizer_of_normal {S : Set G} [hH : H.Normal] : S ⊆ H.normalizer := (@normalizer_eq_top _ _ H hH) ▸ le_top @[to_additive] theorem le_normalizer_of_normal [H.Normal] : K ≤ H.normalizer := subset_normalizer_of_normal @[to_additive] theorem inf_normalizer_le_normalizer_inf : H.normalizer ⊓ K.normalizer ≤ (H ⊓ K).normalizer := fun _ h g ↦ and_congr (h.1 g) (h.2 g) variable (G) in /-- Every proper subgroup `H` of `G` is a proper normal subgroup of the normalizer of `H` in `G`. -/ def _root_.NormalizerCondition := ∀ H : Subgroup G, H < ⊤ → H < normalizer H /-- Alternative phrasing of the normalizer condition: Only the full group is self-normalizing. This may be easier to work with, as it avoids inequalities and negations. -/ theorem _root_.normalizerCondition_iff_only_full_group_self_normalizing : NormalizerCondition G ↔ ∀ H : Subgroup G, H.normalizer = H → H = ⊤ := by apply forall_congr'; intro H simp only [lt_iff_le_and_ne, le_normalizer, le_top, Ne] tauto variable (H) end Normalizer end Subgroup namespace Group variable {s : Set G} /-- Given a set `s`, `conjugatesOfSet s` is the set of all conjugates of the elements of `s`. -/ def conjugatesOfSet (s : Set G) : Set G := ⋃ a ∈ s, conjugatesOf a theorem mem_conjugatesOfSet_iff {x : G} : x ∈ conjugatesOfSet s ↔ ∃ a ∈ s, IsConj a x := by rw [conjugatesOfSet, Set.mem_iUnion₂] simp only [conjugatesOf, isConj_iff, Set.mem_setOf_eq, exists_prop] theorem subset_conjugatesOfSet : s ⊆ conjugatesOfSet s := fun (x : G) (h : x ∈ s) => mem_conjugatesOfSet_iff.2 ⟨x, h, IsConj.refl _⟩ theorem conjugatesOfSet_mono {s t : Set G} (h : s ⊆ t) : conjugatesOfSet s ⊆ conjugatesOfSet t := Set.biUnion_subset_biUnion_left h theorem conjugates_subset_normal {N : Subgroup G} [tn : N.Normal] {a : G} (h : a ∈ N) : conjugatesOf a ⊆ N := by rintro a hc obtain ⟨c, rfl⟩ := isConj_iff.1 hc exact tn.conj_mem a h c theorem conjugatesOfSet_subset {s : Set G} {N : Subgroup G} [N.Normal] (h : s ⊆ N) : conjugatesOfSet s ⊆ N := Set.iUnion₂_subset fun _x H => conjugates_subset_normal (h H) /-- The set of conjugates of `s` is closed under conjugation. -/ theorem conj_mem_conjugatesOfSet {x c : G} : x ∈ conjugatesOfSet s → c * x * c⁻¹ ∈ conjugatesOfSet s := fun H => by rcases mem_conjugatesOfSet_iff.1 H with ⟨a, h₁, h₂⟩ exact mem_conjugatesOfSet_iff.2 ⟨a, h₁, h₂.trans (isConj_iff.2 ⟨c, rfl⟩)⟩ end Group namespace Subgroup open Group variable {s : Set G} /-- The normal closure of a set `s` is the subgroup closure of all the conjugates of elements of `s`. It is the smallest normal subgroup containing `s`. -/ def normalClosure (s : Set G) : Subgroup G := closure (conjugatesOfSet s) theorem conjugatesOfSet_subset_normalClosure : conjugatesOfSet s ⊆ normalClosure s := subset_closure theorem subset_normalClosure : s ⊆ normalClosure s := Set.Subset.trans subset_conjugatesOfSet conjugatesOfSet_subset_normalClosure theorem le_normalClosure {H : Subgroup G} : H ≤ normalClosure ↑H := fun _ h => subset_normalClosure h /-- The normal closure of `s` is a normal subgroup. -/ instance normalClosure_normal : (normalClosure s).Normal := ⟨fun n h g => by refine Subgroup.closure_induction (fun x hx => ?_) ?_ (fun x y _ _ ihx ihy => ?_) (fun x _ ihx => ?_) h · exact conjugatesOfSet_subset_normalClosure (conj_mem_conjugatesOfSet hx) · simpa using (normalClosure s).one_mem · rw [← conj_mul] exact mul_mem ihx ihy · rw [← conj_inv] exact inv_mem ihx⟩ /-- The normal closure of `s` is the smallest normal subgroup containing `s`. -/ theorem normalClosure_le_normal {N : Subgroup G} [N.Normal] (h : s ⊆ N) : normalClosure s ≤ N := by intro a w refine closure_induction (fun x hx => ?_) ?_ (fun x y _ _ ihx ihy => ?_) (fun x _ ihx => ?_) w · exact conjugatesOfSet_subset h hx · exact one_mem _ · exact mul_mem ihx ihy · exact inv_mem ihx theorem normalClosure_subset_iff {N : Subgroup G} [N.Normal] : s ⊆ N ↔ normalClosure s ≤ N := ⟨normalClosure_le_normal, Set.Subset.trans subset_normalClosure⟩ @[gcongr] theorem normalClosure_mono {s t : Set G} (h : s ⊆ t) : normalClosure s ≤ normalClosure t := normalClosure_le_normal (Set.Subset.trans h subset_normalClosure) theorem normalClosure_eq_iInf : normalClosure s = ⨅ (N : Subgroup G) (_ : Normal N) (_ : s ⊆ N), N := le_antisymm (le_iInf fun _ => le_iInf fun _ => le_iInf normalClosure_le_normal) (iInf_le_of_le (normalClosure s) (iInf_le_of_le (by infer_instance) (iInf_le_of_le subset_normalClosure le_rfl))) @[simp] theorem normalClosure_eq_self (H : Subgroup G) [H.Normal] : normalClosure ↑H = H := le_antisymm (normalClosure_le_normal rfl.subset) le_normalClosure theorem normalClosure_idempotent : normalClosure ↑(normalClosure s) = normalClosure s := normalClosure_eq_self _ theorem closure_le_normalClosure {s : Set G} : closure s ≤ normalClosure s := by simp only [subset_normalClosure, closure_le] @[simp] theorem normalClosure_closure_eq_normalClosure {s : Set G} : normalClosure ↑(closure s) = normalClosure s := le_antisymm (normalClosure_le_normal closure_le_normalClosure) (normalClosure_mono subset_closure) /-- The normal core of a subgroup `H` is the largest normal subgroup of `G` contained in `H`, as shown by `Subgroup.normalCore_eq_iSup`. -/ def normalCore (H : Subgroup G) : Subgroup G where carrier := { a : G \| ∀ b : G, b * a * b⁻¹ ∈ H } one_mem' a := by rw [mul_one, mul_inv_cancel]; exact H.one_mem inv_mem' {_} h b := (congr_arg (· ∈ H) conj_inv).mp (H.inv_mem (h b)) mul_mem' {_ _} ha hb c := (congr_arg (· ∈ H) conj_mul).mp (H.mul_mem (ha c) (hb c)) theorem normalCore_le (H : Subgroup G) : H.normalCore ≤ H := fun a h => by rw [← mul_one a, ← inv_one, ← one_mul a] exact h 1 instance normalCore_normal (H : Subgroup G) : H.normalCore.Normal := ⟨fun a h b c => by rw [mul_assoc, mul_assoc, ← mul_inv_rev, ← mul_assoc, ← mul_assoc]; exact h (c * b)⟩ theorem normal_le_normalCore {H : Subgroup G} {N : Subgroup G} [hN : N.Normal] : N ≤ H.normalCore ↔ N ≤ H := ⟨ge_trans H.normalCore_le, fun h_le n hn g => h_le (hN.conj_mem n hn g)⟩ theorem normalCore_mono {H K : Subgroup G} (h : H ≤ K) : H.normalCore ≤ K.normalCore := normal_le_normalCore.mpr (H.normalCore_le.trans h) theorem normalCore_eq_iSup (H : Subgroup G) : H.normalCore = ⨆ (N : Subgroup G) (_ : Normal N) (_ : N ≤ H), N := le_antisymm (le_iSup_of_le H.normalCore (le_iSup_of_le H.normalCore_normal (le_iSup_of_le H.normalCore_le le_rfl))) (iSup_le fun _ => iSup_le fun _ => iSup_le normal_le_normalCore.mpr) @[simp] theorem normalCore_eq_self (H : Subgroup G) [H.Normal] : H.normalCore = H := le_antisymm H.normalCore_le (normal_le_normalCore.mpr le_rfl) theorem normalCore_idempotent (H : Subgroup G) : H.normalCore.normalCore = H.normalCore := H.normalCore.normalCore_eq_self end Subgroup namespace MonoidHom variable {N : Type} {P : Type} [Group N] [Group P] (K : Subgroup G) open Subgroup section Ker variable {M : Type} [MulOneClass M] @[to_additive prodMap_comap_prod] theorem prodMap_comap_prod {G' : Type} {N' : Type} [Group G'] [Group N'] (f : G → N) (g : G' →* N') (S : Subgroup N) (S' : Subgroup N') : (S.prod S').comap (prodMap f g) = (S.comap f).prod (S'.comap g) := SetLike.coe_injective <\| Set.preimage_prod_map_prod f g _ _ @[deprecated (since := "2025-03-11")] alias _root_.AddMonoidHom.sumMap_comap_sum := AddMonoidHom.prodMap_comap_prod @[to_additive ker_prodMap] theorem ker_prodMap {G' : Type} {N' : Type} [Group G'] [Group N'] (f : G →* N) (g : G' →* N') : (prodMap f g).ker = f.ker.prod g.ker := by rw [← comap_bot, ← comap_bot, ← comap_bot, ← prodMap_comap_prod, bot_prod_bot] @[deprecated (since := "2025-03-11")] alias _root_.AddMonoidHom.ker_sumMap := AddMonoidHom.ker_prodMap @[to_additive (attr := simp)] lemma ker_fst : ker (fst G G') = .prod ⊥ ⊤ := SetLike.ext fun _ => (iff_of_eq (and_true _)).symm @[to_additive (attr := simp)] lemma ker_snd : ker (snd G G') = .prod ⊤ ⊥ := SetLike.ext fun _ => (iff_of_eq (true_and _)).symm end Ker end MonoidHom namespace Subgroup variable {N : Type} [Group N] (H : Subgroup G) @[to_additive] theorem Normal.map {H : Subgroup G} (h : H.Normal) (f : G → N) (hf : Function.Surjective f) : (H.map f).Normal := by rw [← normalizer_eq_top_iff, ← top_le_iff, ← f.range_eq_top_of_surjective hf, f.range_eq_map, ← H.normalizer_eq_top] exact le_normalizer_map _ end Subgroup namespace Subgroup open MonoidHom variable {N : Type} [Group N] (f : G → N) /-- The preimage of the normalizer is equal to the normalizer of the preimage of a surjective function. -/ @[to_additive "The preimage of the normalizer is equal to the normalizer of the preimage of a surjective function."] theorem comap_normalizer_eq_of_surjective (H : Subgroup G) {f : N →* G} (hf : Function.Surjective f) : H.normalizer.comap f = (H.comap f).normalizer := comap_normalizer_eq_of_le_range fun x _ ↦ hf x @[deprecated (since := "2025-03-13")] alias comap_normalizer_eq_of_injective_of_le_range := comap_normalizer_eq_of_le_range @[deprecated (since := "2025-03-13")] alias _root_.AddSubgroup.comap_normalizer_eq_of_injective_of_le_range := AddSubgroup.comap_normalizer_eq_of_le_range /-- The image of the normalizer is equal to the normalizer of the image of an isomorphism. -/ @[to_additive "The image of the normalizer is equal to the normalizer of the image of an isomorphism."] theorem map_equiv_normalizer_eq (H : Subgroup G) (f : G ≃* N) : H.normalizer.map f.toMonoidHom = (H.map f.toMonoidHom).normalizer := by ext x simp only [mem_normalizer_iff, mem_map_equiv] rw [f.toEquiv.forall_congr] intro simp /-- The image of the normalizer is equal to the normalizer of the image of a bijective function. -/ @[to_additive "The image of the normalizer is equal to the normalizer of the image of a bijective function."] theorem map_normalizer_eq_of_bijective (H : Subgroup G) {f : G →* N} (hf : Function.Bijective f) : H.normalizer.map f = (H.map f).normalizer := map_equiv_normalizer_eq H (MulEquiv.ofBijective f hf) end Subgroup namespace MonoidHom variable {G₁ G₂ G₃ : Type} [Group G₁] [Group G₂] [Group G₃] variable (f : G₁ → G₂) (f_inv : G₂ → G₁) /-- Auxiliary definition used to define `liftOfRightInverse` -/ @[to_additive "Auxiliary definition used to define `liftOfRightInverse`"] def liftOfRightInverseAux (hf : Function.RightInverse f_inv f) (g : G₁ →* G₃) (hg : f.ker ≤ g.ker) : G₂ →* G₃ where toFun b := g (f_inv b) map_one' := hg (hf 1) map_mul' := by intro x y rw [← g.map_mul, ← mul_inv_eq_one, ← g.map_inv, ← g.map_mul, ← g.mem_ker] apply hg rw [f.mem_ker, f.map_mul, f.map_inv, mul_inv_eq_one, f.map_mul] simp only [hf _] @[to_additive (attr := simp)] theorem liftOfRightInverseAux_comp_apply (hf : Function.RightInverse f_inv f) (g : G₁ →* G₃) (hg : f.ker ≤ g.ker) (x : G₁) : (f.liftOfRightInverseAux f_inv hf g hg) (f x) = g x := by dsimp [liftOfRightInverseAux] rw [← mul_inv_eq_one, ← g.map_inv, ← g.map_mul, ← g.mem_ker] apply hg rw [f.mem_ker, f.map_mul, f.map_inv, mul_inv_eq_one] simp only [hf _] /-- `liftOfRightInverse f hf g hg` is the unique group homomorphism `φ` * such that `φ.comp f = g` (`MonoidHom.liftOfRightInverse_comp`), * where `f : G₁ →+* G₂` has a RightInverse `f_inv` (`hf`), * and `g : G₂ →+* G₃` satisfies `hg : f.ker ≤ g.ker`. See `MonoidHom.eq_liftOfRightInverse` for the uniqueness lemma. ``` G₁. \| \ f \| \ g \| \ v \⌟ G₂----> G₃ ∃!φ ``` -/ @[to_additive "`liftOfRightInverse f f_inv hf g hg` is the unique additive group homomorphism `φ` * such that `φ.comp f = g` (`AddMonoidHom.liftOfRightInverse_comp`), * where `f : G₁ →+ G₂` has a RightInverse `f_inv` (`hf`), * and `g : G₂ →+ G₃` satisfies `hg : f.ker ≤ g.ker`. See `AddMonoidHom.eq_liftOfRightInverse` for the uniqueness lemma. ``` G₁. \| \\ f \| \\ g \| \\ v \\⌟ G₂----> G₃ ∃!φ ```"] def liftOfRightInverse (hf : Function.RightInverse f_inv f) : { g : G₁ →* G₃ // f.ker ≤ g.ker } ≃ (G₂ →* G₃) where toFun g := f.liftOfRightInverseAux f_inv hf g.1 g.2 invFun φ := ⟨φ.comp f, fun x hx ↦ mem_ker.mpr <\| by simp [mem_ker.mp hx]⟩ left_inv g := by ext simp only [comp_apply, liftOfRightInverseAux_comp_apply, Subtype.coe_mk] right_inv φ := by ext b simp [liftOfRightInverseAux, hf b] /-- A non-computable version of `MonoidHom.liftOfRightInverse` for when no computable right inverse is available, that uses `Function.surjInv`. -/ @[to_additive (attr := simp) "A non-computable version of `AddMonoidHom.liftOfRightInverse` for when no computable right inverse is available."] noncomputable abbrev liftOfSurjective (hf : Function.Surjective f) : { g : G₁ →* G₃ // f.ker ≤ g.ker } ≃ (G₂ →* G₃) := f.liftOfRightInverse (Function.surjInv hf) (Function.rightInverse_surjInv hf) @[to_additive (attr := simp)] theorem liftOfRightInverse_comp_apply (hf : Function.RightInverse f_inv f) (g : { g : G₁ →* G₃ // f.ker ≤ g.ker }) (x : G₁) : (f.liftOfRightInverse f_inv hf g) (f x) = g.1 x := f.liftOfRightInverseAux_comp_apply f_inv hf g.1 g.2 x @[to_additive (attr := simp)] theorem liftOfRightInverse_comp (hf : Function.RightInverse f_inv f) (g : { g : G₁ →* G₃ // f.ker ≤ g.ker }) : (f.liftOfRightInverse f_inv hf g).comp f = g := MonoidHom.ext <\| f.liftOfRightInverse_comp_apply f_inv hf g @[to_additive] theorem eq_liftOfRightInverse (hf : Function.RightInverse f_inv f) (g : G₁ →* G₃) (hg : f.ker ≤ g.ker) (h : G₂ →* G₃) (hh : h.comp f = g) : h = f.liftOfRightInverse f_inv hf ⟨g, hg⟩ := by simp_rw [← hh] exact ((f.liftOfRightInverse f_inv hf).apply_symm_apply _).symm end MonoidHom variable {N : Type} [Group N] namespace Subgroup -- Here `H.Normal` is an explicit argument so we can use dot notation with `comap`. @[to_additive] theorem Normal.comap {H : Subgroup N} (hH : H.Normal) (f : G → N) : (H.comap f).Normal := ⟨fun _ => by simp +contextual [Subgroup.mem_comap, hH.conj_mem]⟩ @[to_additive] instance (priority := 100) normal_comap {H : Subgroup N} [nH : H.Normal] (f : G →* N) : (H.comap f).Normal := nH.comap _ -- Here `H.Normal` is an explicit argument so we can use dot notation with `subgroupOf`. @[to_additive] theorem Normal.subgroupOf {H : Subgroup G} (hH : H.Normal) (K : Subgroup G) : (H.subgroupOf K).Normal := hH.comap _ @[to_additive] instance (priority := 100) normal_subgroupOf {H N : Subgroup G} [N.Normal] : (N.subgroupOf H).Normal := Subgroup.normal_comap _ theorem map_normalClosure (s : Set G) (f : G →* N) (hf : Surjective f) : (normalClosure s).map f = normalClosure (f '' s) := by have : Normal (map f (normalClosure s)) := Normal.map inferInstance f hf apply le_antisymm · simp [map_le_iff_le_comap, normalClosure_le_normal, coe_comap, ← Set.image_subset_iff, subset_normalClosure] · exact normalClosure_le_normal (Set.image_subset f subset_normalClosure) theorem comap_normalClosure (s : Set N) (f : G ≃* N) : normalClosure (f ⁻¹' s) = (normalClosure s).comap f := by have := Set.preimage_equiv_eq_image_symm s f.toEquiv simp_all [comap_equiv_eq_map_symm, map_normalClosure s (f.symm : N →* G) f.symm.surjective] lemma Normal.of_map_injective {G H : Type} [Group G] [Group H] {φ : G → H} (hφ : Function.Injective φ) {L : Subgroup G} (n : (L.map φ).Normal) : L.Normal := L.comap_map_eq_self_of_injective hφ ▸ n.comap φ theorem Normal.of_map_subtype {K : Subgroup G} {L : Subgroup K} (n : (Subgroup.map K.subtype L).Normal) : L.Normal := n.of_map_injective K.subtype_injective end Subgroup namespace Subgroup section SubgroupNormal @[to_additive] theorem normal_subgroupOf_iff {H K : Subgroup G} (hHK : H ≤ K) : (H.subgroupOf K).Normal ↔ ∀ h k, h ∈ H → k ∈ K → k * h * k⁻¹ ∈ H := ⟨fun hN h k hH hK => hN.conj_mem ⟨h, hHK hH⟩ hH ⟨k, hK⟩, fun hN => { conj_mem := fun h hm k => hN h.1 k.1 hm k.2 }⟩ @[to_additive prod_addSubgroupOf_prod_normal] instance prod_subgroupOf_prod_normal {H₁ K₁ : Subgroup G} {H₂ K₂ : Subgroup N} [h₁ : (H₁.subgroupOf K₁).Normal] [h₂ : (H₂.subgroupOf K₂).Normal] : ((H₁.prod H₂).subgroupOf (K₁.prod K₂)).Normal where conj_mem n hgHK g := ⟨h₁.conj_mem ⟨(n : G × N).fst, (mem_prod.mp n.2).1⟩ hgHK.1 ⟨(g : G × N).fst, (mem_prod.mp g.2).1⟩, h₂.conj_mem ⟨(n : G × N).snd, (mem_prod.mp n.2).2⟩ hgHK.2 ⟨(g : G × N).snd, (mem_prod.mp g.2).2⟩⟩ @[deprecated (since := "2025-03-11")] alias _root_.AddSubgroup.sum_addSubgroupOf_sum_normal := AddSubgroup.prod_addSubgroupOf_prod_normal @[to_additive prod_normal] instance prod_normal (H : Subgroup G) (K : Subgroup N) [hH : H.Normal] [hK : K.Normal] : (H.prod K).Normal where conj_mem n hg g := ⟨hH.conj_mem n.fst (Subgroup.mem_prod.mp hg).1 g.fst, hK.conj_mem n.snd (Subgroup.mem_prod.mp hg).2 g.snd⟩ @[deprecated (since := "2025-03-11")] alias _root_.AddSubgroup.sum_normal := AddSubgroup.prod_normal @[to_additive] theorem inf_subgroupOf_inf_normal_of_right (A B' B : Subgroup G) [hN : (B'.subgroupOf B).Normal] : ((A ⊓ B').subgroupOf (A ⊓ B)).Normal := by rw [normal_subgroupOf_iff_le_normalizer_inf] at hN ⊢ rw [inf_inf_inf_comm, inf_idem] exact le_trans (inf_le_inf A.le_normalizer hN) (inf_normalizer_le_normalizer_inf) @[to_additive] theorem inf_subgroupOf_inf_normal_of_left {A' A : Subgroup G} (B : Subgroup G) [hN : (A'.subgroupOf A).Normal] : ((A' ⊓ B).subgroupOf (A ⊓ B)).Normal := by rw [normal_subgroupOf_iff_le_normalizer_inf] at hN ⊢ rw [inf_inf_inf_comm, inf_idem] exact le_trans (inf_le_inf hN B.le_normalizer) (inf_normalizer_le_normalizer_inf) @[to_additive] instance normal_inf_normal (H K : Subgroup G) [hH : H.Normal] [hK : K.Normal] : (H ⊓ K).Normal := ⟨fun n hmem g => ⟨hH.conj_mem n hmem.1 g, hK.conj_mem n hmem.2 g⟩⟩ @[to_additive] theorem normal_iInf_normal {ι : Type} {a : ι → Subgroup G} (norm : ∀ i : ι, (a i).Normal) : (iInf a).Normal := by constructor intro g g_in_iInf h rw [Subgroup.mem_iInf] at g_in_iInf ⊢ intro i exact (norm i).conj_mem g (g_in_iInf i) h @[to_additive] theorem SubgroupNormal.mem_comm {H K : Subgroup G} (hK : H ≤ K) [hN : (H.subgroupOf K).Normal] {a b : G} (hb : b ∈ K) (h : a b ∈ H) : b * a ∈ H := by have := (normal_subgroupOf_iff hK).mp hN (a * b) b h hb rwa [mul_assoc, mul_assoc, mul_inv_cancel, mul_one] at this /-- Elements of disjoint, normal subgroups commute. -/ @[to_additive "Elements of disjoint, normal subgroups commute."] theorem commute_of_normal_of_disjoint (H₁ H₂ : Subgroup G) (hH₁ : H₁.Normal) (hH₂ : H₂.Normal) (hdis : Disjoint H₁ H₂) (x y : G) (hx : x ∈ H₁) (hy : y ∈ H₂) : Commute x y := by suffices x * y * x⁻¹ * y⁻¹ = 1 by show x * y = y * x · rw [mul_assoc, mul_eq_one_iff_eq_inv] at this simpa apply hdis.le_bot constructor · suffices x * (y * x⁻¹ * y⁻¹) ∈ H₁ by simpa [mul_assoc] exact H₁.mul_mem hx (hH₁.conj_mem _ (H₁.inv_mem hx) _) · show x * y * x⁻¹ * y⁻¹ ∈ H₂ apply H₂.mul_mem _ (H₂.inv_mem hy) apply hH₂.conj_mem _ hy @[to_additive] theorem normal_subgroupOf_of_le_normalizer {H N : Subgroup G} (hLE : H ≤ N.normalizer) : (N.subgroupOf H).Normal := by rw [normal_subgroupOf_iff_le_normalizer_inf] exact (le_inf hLE H.le_normalizer).trans inf_normalizer_le_normalizer_inf @[to_additive] theorem normal_subgroupOf_sup_of_le_normalizer {H N : Subgroup G} (hLE : H ≤ N.normalizer) : (N.subgroupOf (H ⊔ N)).Normal := by rw [normal_subgroupOf_iff_le_normalizer le_sup_right] exact sup_le hLE le_normalizer end SubgroupNormal end Subgroup namespace IsConj open Subgroup theorem normalClosure_eq_top_of {N : Subgroup G} [hn : N.Normal] {g g' : G} {hg : g ∈ N} {hg' : g' ∈ N} (hc : IsConj g g') (ht : normalClosure ({⟨g, hg⟩} : Set N) = ⊤) : normalClosure ({⟨g', hg'⟩} : Set N) = ⊤ := by obtain ⟨c, rfl⟩ := isConj_iff.1 hc have h : ∀ x : N, (MulAut.conj c) x ∈ N := by rintro ⟨x, hx⟩ exact hn.conj_mem _ hx c have hs : Function.Surjective (((MulAut.conj c).toMonoidHom.restrict N).codRestrict _ h) := by rintro ⟨x, hx⟩ refine ⟨⟨c⁻¹ * x * c, ?_⟩, ?_⟩ · have h := hn.conj_mem _ hx c⁻¹ rwa [inv_inv] at h simp only [MonoidHom.codRestrict_apply, MulEquiv.coe_toMonoidHom, MulAut.conj_apply, coe_mk, MonoidHom.restrict_apply, Subtype.mk_eq_mk, ← mul_assoc, mul_inv_cancel, one_mul] rw [mul_assoc, mul_inv_cancel, mul_one] rw [eq_top_iff, ← MonoidHom.range_eq_top.2 hs, MonoidHom.range_eq_map] refine le_trans (map_mono (eq_top_iff.1 ht)) (map_le_iff_le_comap.2 (normalClosure_le_normal ?_)) rw [Set.singleton_subset_iff, SetLike.mem_coe] simp only [MonoidHom.codRestrict_apply, MulEquiv.coe_toMonoidHom, MulAut.conj_apply, coe_mk, MonoidHom.restrict_apply, mem_comap] exact subset_normalClosure (Set.mem_singleton _) end IsConj namespace ConjClasses /-- The conjugacy classes that are not trivial. -/ def noncenter (G : Type) [Monoid G] : Set (ConjClasses G) := {x \| x.carrier.Nontrivial} @[simp] lemma mem_noncenter {G} [Monoid G] (g : ConjClasses G) : g ∈ noncenter G ↔ g.carrier.Nontrivial := Iff.rfl end ConjClasses /-- Suppose `G` acts on `M` and `I` is a subgroup of `M`. The inertia subgroup of `I` is the subgroup of `G` whose action is trivial mod `I`. -/ def AddSubgroup.inertia {M : Type} [AddGroup M] (I : AddSubgroup M) (G : Type) [Group G] [MulAction G M] : Subgroup G where carrier := { σ \| ∀ x, σ • x - x ∈ I } mul_mem' {a b} ha hb x := by simpa [mul_smul] using add_mem (ha (b • x)) (hb x) one_mem' := by simp [zero_mem] inv_mem' {a} ha x := by simpa using sub_mem_comm_iff.mp (ha (a⁻¹ • x)) @[simp] lemma AddSubgroup.mem_inertia {M : Type} [AddGroup M] {I : AddSubgroup M} {G : Type*} [Group G] [MulAction G M] {σ : G} : σ ∈ I.inertia G ↔ ∀ x, σ • x - x ∈ I := .rfl		Mathlib/Algebra/Group/Subgroup/Basic.lean	3,628	3,629
/- Copyright (c) 2021 Bhavik Mehta. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yaël Dillies, Bhavik Mehta -/ import Mathlib.Combinatorics.SetFamily.Shadow /-! # UV-compressions This file defines UV-compression. It is an operation on a set family that reduces its shadow. UV-compressing `a : α` along `u v : α` means replacing `a` by `(a ⊔ u) \ v` if `a` and `u` are disjoint and `v ≤ a`. In some sense, it's moving `a` from `v` to `u`. UV-compressions are immensely useful to prove the Kruskal-Katona theorem. The idea is that compressing a set family might decrease the size of its shadow, so iterated compressions hopefully minimise the shadow. ## Main declarations * `UV.compress`: `compress u v a` is `a` compressed along `u` and `v`. * `UV.compression`: `compression u v s` is the compression of the set family `s` along `u` and `v`. It is the compressions of the elements of `s` whose compression is not already in `s` along with the element whose compression is already in `s`. This way of splitting into what moves and what does not ensures the compression doesn't squash the set family, which is proved by `UV.card_compression`. * `UV.card_shadow_compression_le`: Compressing reduces the size of the shadow. This is a key fact in the proof of Kruskal-Katona. ## Notation `𝓒` (typed with `\MCC`) is notation for `UV.compression` in locale `FinsetFamily`. ## Notes Even though our emphasis is on `Finset α`, we define UV-compressions more generally in a generalized boolean algebra, so that one can use it for `Set α`. ## References * https://github.com/b-mehta/maths-notes/blob/master/iii/mich/combinatorics.pdf ## Tags compression, UV-compression, shadow -/ open Finset variable {α : Type*} /-- UV-compression is injective on the elements it moves. See `UV.compress`. -/ theorem sup_sdiff_injOn [GeneralizedBooleanAlgebra α] (u v : α) : { x \| Disjoint u x ∧ v ≤ x }.InjOn fun x => (x ⊔ u) \ v := by rintro a ha b hb hab have h : ((a ⊔ u) \ v) \ u ⊔ v = ((b ⊔ u) \ v) \ u ⊔ v := by dsimp at hab rw [hab] rwa [sdiff_sdiff_comm, ha.1.symm.sup_sdiff_cancel_right, sdiff_sdiff_comm, hb.1.symm.sup_sdiff_cancel_right, sdiff_sup_cancel ha.2, sdiff_sup_cancel hb.2] at h -- The namespace is here to distinguish from other compressions. namespace UV /-! ### UV-compression in generalized boolean algebras -/ section GeneralizedBooleanAlgebra variable [GeneralizedBooleanAlgebra α] [DecidableRel (@Disjoint α _ _)] [DecidableLE α] {s : Finset α} {u v a : α} /-- UV-compressing `a` means removing `v` from it and adding `u` if `a` and `u` are disjoint and `v ≤ a` (it replaces the `v` part of `a` by the `u` part). Else, UV-compressing `a` doesn't do anything. This is most useful when `u` and `v` are disjoint finsets of the same size. -/ def compress (u v a : α) : α := if Disjoint u a ∧ v ≤ a then (a ⊔ u) \ v else a theorem compress_of_disjoint_of_le (hua : Disjoint u a) (hva : v ≤ a) : compress u v a = (a ⊔ u) \ v := if_pos ⟨hua, hva⟩ theorem compress_of_disjoint_of_le' (hva : Disjoint v a) (hua : u ≤ a) : compress u v ((a ⊔ v) \ u) = a := by rw [compress_of_disjoint_of_le disjoint_sdiff_self_right (le_sdiff.2 ⟨(le_sup_right : v ≤ a ⊔ v), hva.mono_right hua⟩), sdiff_sup_cancel (le_sup_of_le_left hua), hva.symm.sup_sdiff_cancel_right] @[simp] theorem compress_self (u a : α) : compress u u a = a := by unfold compress split_ifs with h · exact h.1.symm.sup_sdiff_cancel_right · rfl /-- An element can be compressed to any other element by removing/adding the differences. -/ @[simp] theorem compress_sdiff_sdiff (a b : α) : compress (a \ b) (b \ a) b = a := by refine (compress_of_disjoint_of_le disjoint_sdiff_self_left sdiff_le).trans ?_ rw [sup_sdiff_self_right, sup_sdiff, disjoint_sdiff_self_right.sdiff_eq_left, sup_eq_right] exact sdiff_sdiff_le /-- Compressing an element is idempotent. -/ @[simp] theorem compress_idem (u v a : α) : compress u v (compress u v a) = compress u v a := by unfold compress split_ifs with h h' · rw [le_sdiff_right.1 h'.2, sdiff_bot, sdiff_bot, sup_assoc, sup_idem] · rfl · rfl variable [DecidableEq α] /-- To UV-compress a set family, we compress each of its elements, except that we don't want to reduce the cardinality, so we keep all elements whose compression is already present. -/ def compression (u v : α) (s : Finset α) := {a ∈ s \| compress u v a ∈ s} ∪ {a ∈ s.image <\| compress u v \| a ∉ s} @[inherit_doc] scoped[FinsetFamily] notation "𝓒 " => UV.compression open scoped FinsetFamily /-- `IsCompressed u v s` expresses that `s` is UV-compressed. -/ def IsCompressed (u v : α) (s : Finset α) := 𝓒 u v s = s /-- UV-compression is injective on the sets that are not UV-compressed. -/ theorem compress_injOn : Set.InjOn (compress u v) ↑{a ∈ s \| compress u v a ∉ s} := by intro a ha b hb hab rw [mem_coe, mem_filter] at ha hb rw [compress] at ha hab split_ifs at ha hab with has · rw [compress] at hb hab split_ifs at hb hab with hbs · exact sup_sdiff_injOn u v has hbs hab · exact (hb.2 hb.1).elim · exact (ha.2 ha.1).elim	/-- `a` is in the UV-compressed family iff it's in the original and its compression is in the original, or it's not in the original but it's the compression of something in the original. -/ theorem mem_compression : a ∈ 𝓒 u v s ↔ a ∈ s ∧ compress u v a ∈ s ∨ a ∉ s ∧ ∃ b ∈ s, compress u v b = a := by simp_rw [compression, mem_union, mem_filter, mem_image, and_comm] protected theorem IsCompressed.eq (h : IsCompressed u v s) : 𝓒 u v s = s := h @[simp] theorem compression_self (u : α) (s : Finset α) : 𝓒 u u s = s := by	Mathlib/Combinatorics/SetFamily/Compression/UV.lean	142	151
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Mario Carneiro -/ import Mathlib.MeasureTheory.OuterMeasure.Operations import Mathlib.Analysis.SpecificLimits.Basic /-! # Outer measures from functions Given an arbitrary function `m : Set α → ℝ≥0∞` that sends `∅` to `0` we can define an outer measure on `α` that on `s` is defined to be the infimum of `∑ᵢ, m (sᵢ)` for all collections of sets `sᵢ` that cover `s`. This is the unique maximal outer measure that is at most the given function. Given an outer measure `m`, the Carathéodory-measurable sets are the sets `s` such that for all sets `t` we have `m t = m (t ∩ s) + m (t \ s)`. This forms a measurable space. ## Main definitions and statements * `OuterMeasure.boundedBy` is the greatest outer measure that is at most the given function. If you know that the given function sends `∅` to `0`, then `OuterMeasure.ofFunction` is a special case. * `sInf_eq_boundedBy_sInfGen` is a characterization of the infimum of outer measures. ## References * <https://en.wikipedia.org/wiki/Outer_measure> * <https://en.wikipedia.org/wiki/Carath%C3%A9odory%27s_criterion> ## Tags outer measure, Carathéodory-measurable, Carathéodory's criterion -/ assert_not_exists Basis noncomputable section open Set Function Filter open scoped NNReal Topology ENNReal namespace MeasureTheory namespace OuterMeasure section OfFunction variable {α : Type*} /-- Given any function `m` assigning measures to sets satisfying `m ∅ = 0`, there is a unique maximal outer measure `μ` satisfying `μ s ≤ m s` for all `s : Set α`. -/ protected def ofFunction (m : Set α → ℝ≥0∞) (m_empty : m ∅ = 0) : OuterMeasure α := let μ s := ⨅ (f : ℕ → Set α) (_ : s ⊆ ⋃ i, f i), ∑' i, m (f i) { measureOf := μ empty := le_antisymm ((iInf_le_of_le fun _ => ∅) <\| iInf_le_of_le (empty_subset _) <\| by simp [m_empty]) (zero_le _) mono := fun {_ _} hs => iInf_mono fun _ => iInf_mono' fun hb => ⟨hs.trans hb, le_rfl⟩ iUnion_nat := fun s _ => ENNReal.le_of_forall_pos_le_add <\| by intro ε hε (hb : (∑' i, μ (s i)) < ∞) rcases ENNReal.exists_pos_sum_of_countable (ENNReal.coe_pos.2 hε).ne' ℕ with ⟨ε', hε', hl⟩ refine le_trans ?_ (add_le_add_left (le_of_lt hl) _) rw [← ENNReal.tsum_add] choose f hf using show ∀ i, ∃ f : ℕ → Set α, (s i ⊆ ⋃ i, f i) ∧ (∑' i, m (f i)) < μ (s i) + ε' i by intro i have : μ (s i) < μ (s i) + ε' i := ENNReal.lt_add_right (ne_top_of_le_ne_top hb.ne <\| ENNReal.le_tsum _) (by simpa using (hε' i).ne') rcases iInf_lt_iff.mp this with ⟨t, ht⟩ exists t contrapose! ht exact le_iInf ht refine le_trans ?_ (ENNReal.tsum_le_tsum fun i => le_of_lt (hf i).2) rw [← ENNReal.tsum_prod, ← Nat.pairEquiv.symm.tsum_eq] refine iInf_le_of_le _ (iInf_le _ ?_) apply iUnion_subset intro i apply Subset.trans (hf i).1 apply iUnion_subset simp only [Nat.pairEquiv_symm_apply] rw [iUnion_unpair] intro j apply subset_iUnion₂ i } variable (m : Set α → ℝ≥0∞) (m_empty : m ∅ = 0) /-- `ofFunction` of a set `s` is the infimum of `∑ᵢ, m (tᵢ)` for all collections of sets `tᵢ` that cover `s`. -/ theorem ofFunction_apply (s : Set α) : OuterMeasure.ofFunction m m_empty s = ⨅ (t : ℕ → Set α) (_ : s ⊆ iUnion t), ∑' n, m (t n) := rfl /-- `ofFunction` of a set `s` is the infimum of `∑ᵢ, m (tᵢ)` for all collections of sets `tᵢ` that cover `s`, with all `tᵢ` satisfying a predicate `P` such that `m` is infinite for sets that don't satisfy `P`. This is similar to `ofFunction_apply`, except that the sets `tᵢ` satisfy `P`. The hypothesis `m_top` applies in particular to a function of the form `extend m'`. -/ theorem ofFunction_eq_iInf_mem {P : Set α → Prop} (m_top : ∀ s, ¬ P s → m s = ∞) (s : Set α) : OuterMeasure.ofFunction m m_empty s = ⨅ (t : ℕ → Set α) (_ : ∀ i, P (t i)) (_ : s ⊆ ⋃ i, t i), ∑' i, m (t i) := by rw [OuterMeasure.ofFunction_apply] apply le_antisymm · exact le_iInf fun t ↦ le_iInf fun _ ↦ le_iInf fun h ↦ iInf₂_le _ (by exact h) · simp_rw [le_iInf_iff] refine fun t ht_subset ↦ iInf_le_of_le t ?_ by_cases ht : ∀ i, P (t i) · exact iInf_le_of_le ht (iInf_le_of_le ht_subset le_rfl) · simp only [ht, not_false_eq_true, iInf_neg, top_le_iff] push_neg at ht obtain ⟨i, hti_not_mem⟩ := ht have hfi_top : m (t i) = ∞ := m_top _ hti_not_mem exact ENNReal.tsum_eq_top_of_eq_top ⟨i, hfi_top⟩ variable {m m_empty} theorem ofFunction_le (s : Set α) : OuterMeasure.ofFunction m m_empty s ≤ m s := let f : ℕ → Set α := fun i => Nat.casesOn i s fun _ => ∅ iInf_le_of_le f <\| iInf_le_of_le (subset_iUnion f 0) <\| le_of_eq <\| tsum_eq_single 0 <\| by rintro (_ \| i) · simp · simp [f, m_empty] theorem ofFunction_eq (s : Set α) (m_mono : ∀ ⦃t : Set α⦄, s ⊆ t → m s ≤ m t) (m_subadd : ∀ s : ℕ → Set α, m (⋃ i, s i) ≤ ∑' i, m (s i)) : OuterMeasure.ofFunction m m_empty s = m s := le_antisymm (ofFunction_le s) <\| le_iInf fun f => le_iInf fun hf => le_trans (m_mono hf) (m_subadd f) theorem le_ofFunction {μ : OuterMeasure α} : μ ≤ OuterMeasure.ofFunction m m_empty ↔ ∀ s, μ s ≤ m s := ⟨fun H s => le_trans (H s) (ofFunction_le s), fun H _ => le_iInf fun f => le_iInf fun hs => le_trans (μ.mono hs) <\| le_trans (measure_iUnion_le f) <\| ENNReal.tsum_le_tsum fun _ => H _⟩ theorem isGreatest_ofFunction : IsGreatest { μ : OuterMeasure α \| ∀ s, μ s ≤ m s } (OuterMeasure.ofFunction m m_empty) := ⟨fun _ => ofFunction_le _, fun _ => le_ofFunction.2⟩ theorem ofFunction_eq_sSup : OuterMeasure.ofFunction m m_empty = sSup { μ \| ∀ s, μ s ≤ m s } := (@isGreatest_ofFunction α m m_empty).isLUB.sSup_eq.symm /-- If `m u = ∞` for any set `u` that has nonempty intersection both with `s` and `t`, then `μ (s ∪ t) = μ s + μ t`, where `μ = MeasureTheory.OuterMeasure.ofFunction m m_empty`. E.g., if `α` is an (e)metric space and `m u = ∞` on any set of diameter `≥ r`, then this lemma implies that `μ (s ∪ t) = μ s + μ t` on any two sets such that `r ≤ edist x y` for all `x ∈ s` and `y ∈ t`. -/ theorem ofFunction_union_of_top_of_nonempty_inter {s t : Set α} (h : ∀ u, (s ∩ u).Nonempty → (t ∩ u).Nonempty → m u = ∞) : OuterMeasure.ofFunction m m_empty (s ∪ t) = OuterMeasure.ofFunction m m_empty s + OuterMeasure.ofFunction m m_empty t := by refine le_antisymm (measure_union_le _ _) (le_iInf₂ fun f hf ↦ ?_) set μ := OuterMeasure.ofFunction m m_empty rcases Classical.em (∃ i, (s ∩ f i).Nonempty ∧ (t ∩ f i).Nonempty) with (⟨i, hs, ht⟩ \| he) · calc μ s + μ t ≤ ∞ := le_top _ = m (f i) := (h (f i) hs ht).symm _ ≤ ∑' i, m (f i) := ENNReal.le_tsum i set I := fun s => { i : ℕ \| (s ∩ f i).Nonempty } have hd : Disjoint (I s) (I t) := disjoint_iff_inf_le.mpr fun i hi => he ⟨i, hi⟩ have hI : ∀ u ⊆ s ∪ t, μ u ≤ ∑' i : I u, μ (f i) := fun u hu => calc μ u ≤ μ (⋃ i : I u, f i) := μ.mono fun x hx => let ⟨i, hi⟩ := mem_iUnion.1 (hf (hu hx)) mem_iUnion.2 ⟨⟨i, ⟨x, hx, hi⟩⟩, hi⟩ _ ≤ ∑' i : I u, μ (f i) := measure_iUnion_le _ calc μ s + μ t ≤ (∑' i : I s, μ (f i)) + ∑' i : I t, μ (f i) := add_le_add (hI _ subset_union_left) (hI _ subset_union_right) _ = ∑' i : ↑(I s ∪ I t), μ (f i) := (ENNReal.summable.tsum_union_disjoint (f := fun i => μ (f i)) hd ENNReal.summable).symm _ ≤ ∑' i, μ (f i) := (ENNReal.summable.tsum_le_tsum_of_inj (↑) Subtype.coe_injective (fun _ _ => zero_le _) (fun _ => le_rfl) ENNReal.summable) _ ≤ ∑' i, m (f i) := ENNReal.tsum_le_tsum fun i => ofFunction_le _ theorem comap_ofFunction {β} (f : β → α) (h : Monotone m ∨ Surjective f) : comap f (OuterMeasure.ofFunction m m_empty) = OuterMeasure.ofFunction (fun s => m (f '' s)) (by simp; simp [m_empty]) := by refine le_antisymm (le_ofFunction.2 fun s => ?_) fun s => ?_ · rw [comap_apply] apply ofFunction_le · rw [comap_apply, ofFunction_apply, ofFunction_apply] refine iInf_mono' fun t => ⟨fun k => f ⁻¹' t k, ?_⟩	refine iInf_mono' fun ht => ?_ rw [Set.image_subset_iff, preimage_iUnion] at ht refine ⟨ht, ENNReal.tsum_le_tsum fun n => ?_⟩ rcases h with hl \| hr exacts [hl (image_preimage_subset _ _), (congr_arg m (hr.image_preimage (t n))).le] theorem map_ofFunction_le {β} (f : α → β) : map f (OuterMeasure.ofFunction m m_empty) ≤ OuterMeasure.ofFunction (fun s => m (f ⁻¹' s)) m_empty := le_ofFunction.2 fun s => by rw [map_apply]	Mathlib/MeasureTheory/OuterMeasure/OfFunction.lean	195	205
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro, Floris van Doorn, Violeta Hernández Palacios -/ import Mathlib.Algebra.GroupWithZero.Divisibility import Mathlib.Data.Nat.SuccPred import Mathlib.Order.SuccPred.InitialSeg import Mathlib.SetTheory.Ordinal.Basic /-! # Ordinal arithmetic Ordinals have an addition (corresponding to disjoint union) that turns them into an additive monoid, and a multiplication (corresponding to the lexicographic order on the product) that turns them into a monoid. One can also define correspondingly a subtraction, a division, a successor function, a power function and a logarithm function. We also define limit ordinals and prove the basic induction principle on ordinals separating successor ordinals and limit ordinals, in `limitRecOn`. ## Main definitions and results * `o₁ + o₂` is the order on the disjoint union of `o₁` and `o₂` obtained by declaring that every element of `o₁` is smaller than every element of `o₂`. * `o₁ - o₂` is the unique ordinal `o` such that `o₂ + o = o₁`, when `o₂ ≤ o₁`. * `o₁ * o₂` is the lexicographic order on `o₂ × o₁`. * `o₁ / o₂` is the ordinal `o` such that `o₁ = o₂ * o + o'` with `o' < o₂`. We also define the divisibility predicate, and a modulo operation. * `Order.succ o = o + 1` is the successor of `o`. * `pred o` if the predecessor of `o`. If `o` is not a successor, we set `pred o = o`. We discuss the properties of casts of natural numbers of and of `ω` with respect to these operations. Some properties of the operations are also used to discuss general tools on ordinals: * `IsLimit o`: an ordinal is a limit ordinal if it is neither `0` nor a successor. * `limitRecOn` is the main induction principle of ordinals: if one can prove a property by induction at successor ordinals and at limit ordinals, then it holds for all ordinals. * `IsNormal`: a function `f : Ordinal → Ordinal` satisfies `IsNormal` if it is strictly increasing and order-continuous, i.e., the image `f o` of a limit ordinal `o` is the sup of `f a` for `a < o`. Various other basic arithmetic results are given in `Principal.lean` instead. -/ assert_not_exists Field Module noncomputable section open Function Cardinal Set Equiv Order open scoped Ordinal universe u v w namespace Ordinal variable {α β γ : Type} {r : α → α → Prop} {s : β → β → Prop} {t : γ → γ → Prop} /-! ### Further properties of addition on ordinals -/ @[simp] theorem lift_add (a b : Ordinal.{v}) : lift.{u} (a + b) = lift.{u} a + lift.{u} b := Quotient.inductionOn₂ a b fun ⟨_α, _r, _⟩ ⟨_β, _s, _⟩ => Quotient.sound ⟨(RelIso.preimage Equiv.ulift _).trans (RelIso.sumLexCongr (RelIso.preimage Equiv.ulift _) (RelIso.preimage Equiv.ulift _)).symm⟩ @[simp] theorem lift_succ (a : Ordinal.{v}) : lift.{u} (succ a) = succ (lift.{u} a) := by rw [← add_one_eq_succ, lift_add, lift_one] rfl instance instAddLeftReflectLE : AddLeftReflectLE Ordinal.{u} where elim c a b := by refine inductionOn₃ a b c fun α r _ β s _ γ t _ ⟨f⟩ ↦ ?_ have H₁ a : f (Sum.inl a) = Sum.inl a := by simpa using ((InitialSeg.leAdd t r).trans f).eq (InitialSeg.leAdd t s) a have H₂ a : ∃ b, f (Sum.inr a) = Sum.inr b := by generalize hx : f (Sum.inr a) = x obtain x \| x := x · rw [← H₁, f.inj] at hx contradiction · exact ⟨x, rfl⟩ choose g hg using H₂ refine (RelEmbedding.ofMonotone g fun _ _ h ↦ ?_).ordinal_type_le rwa [← @Sum.lex_inr_inr _ t _ s, ← hg, ← hg, f.map_rel_iff, Sum.lex_inr_inr] instance : IsLeftCancelAdd Ordinal where add_left_cancel a b c h := by simpa only [le_antisymm_iff, add_le_add_iff_left] using h @[deprecated add_left_cancel_iff (since := "2024-12-11")] protected theorem add_left_cancel (a) {b c : Ordinal} : a + b = a + c ↔ b = c := add_left_cancel_iff private theorem add_lt_add_iff_left' (a) {b c : Ordinal} : a + b < a + c ↔ b < c := by rw [← not_le, ← not_le, add_le_add_iff_left] instance instAddLeftStrictMono : AddLeftStrictMono Ordinal.{u} := ⟨fun a _b _c ↦ (add_lt_add_iff_left' a).2⟩ instance instAddLeftReflectLT : AddLeftReflectLT Ordinal.{u} := ⟨fun a _b _c ↦ (add_lt_add_iff_left' a).1⟩ instance instAddRightReflectLT : AddRightReflectLT Ordinal.{u} := ⟨fun _a _b _c ↦ lt_imp_lt_of_le_imp_le fun h => add_le_add_right h _⟩ theorem add_le_add_iff_right {a b : Ordinal} : ∀ n : ℕ, a + n ≤ b + n ↔ a ≤ b \| 0 => by simp \| n + 1 => by simp only [natCast_succ, add_succ, add_succ, succ_le_succ_iff, add_le_add_iff_right] theorem add_right_cancel {a b : Ordinal} (n : ℕ) : a + n = b + n ↔ a = b := by simp only [le_antisymm_iff, add_le_add_iff_right] theorem add_eq_zero_iff {a b : Ordinal} : a + b = 0 ↔ a = 0 ∧ b = 0 := inductionOn₂ a b fun α r _ β s _ => by simp_rw [← type_sum_lex, type_eq_zero_iff_isEmpty] exact isEmpty_sum theorem left_eq_zero_of_add_eq_zero {a b : Ordinal} (h : a + b = 0) : a = 0 := (add_eq_zero_iff.1 h).1 theorem right_eq_zero_of_add_eq_zero {a b : Ordinal} (h : a + b = 0) : b = 0 := (add_eq_zero_iff.1 h).2 /-! ### The predecessor of an ordinal -/ open Classical in /-- The ordinal predecessor of `o` is `o'` if `o = succ o'`, and `o` otherwise. -/ def pred (o : Ordinal) : Ordinal := if h : ∃ a, o = succ a then Classical.choose h else o @[simp] theorem pred_succ (o) : pred (succ o) = o := by have h : ∃ a, succ o = succ a := ⟨_, rfl⟩ simpa only [pred, dif_pos h] using (succ_injective <\| Classical.choose_spec h).symm theorem pred_le_self (o) : pred o ≤ o := by classical exact if h : ∃ a, o = succ a then by let ⟨a, e⟩ := h rw [e, pred_succ]; exact le_succ a else by rw [pred, dif_neg h] theorem pred_eq_iff_not_succ {o} : pred o = o ↔ ¬∃ a, o = succ a := ⟨fun e ⟨a, e'⟩ => by rw [e', pred_succ] at e; exact (lt_succ a).ne e, fun h => dif_neg h⟩ theorem pred_eq_iff_not_succ' {o} : pred o = o ↔ ∀ a, o ≠ succ a := by simpa using pred_eq_iff_not_succ theorem pred_lt_iff_is_succ {o} : pred o < o ↔ ∃ a, o = succ a := Iff.trans (by simp only [le_antisymm_iff, pred_le_self, true_and, not_le]) (iff_not_comm.1 pred_eq_iff_not_succ).symm @[simp] theorem pred_zero : pred 0 = 0 := pred_eq_iff_not_succ'.2 fun a => (succ_ne_zero a).symm theorem succ_pred_iff_is_succ {o} : succ (pred o) = o ↔ ∃ a, o = succ a := ⟨fun e => ⟨_, e.symm⟩, fun ⟨a, e⟩ => by simp only [e, pred_succ]⟩ theorem succ_lt_of_not_succ {o b : Ordinal} (h : ¬∃ a, o = succ a) : succ b < o ↔ b < o := ⟨(lt_succ b).trans, fun l => lt_of_le_of_ne (succ_le_of_lt l) fun e => h ⟨_, e.symm⟩⟩ theorem lt_pred {a b} : a < pred b ↔ succ a < b := by classical exact if h : ∃ a, b = succ a then by let ⟨c, e⟩ := h rw [e, pred_succ, succ_lt_succ_iff] else by simp only [pred, dif_neg h, succ_lt_of_not_succ h] theorem pred_le {a b} : pred a ≤ b ↔ a ≤ succ b := le_iff_le_iff_lt_iff_lt.2 lt_pred @[simp] theorem lift_is_succ {o : Ordinal.{v}} : (∃ a, lift.{u} o = succ a) ↔ ∃ a, o = succ a := ⟨fun ⟨a, h⟩ => let ⟨b, e⟩ := mem_range_lift_of_le <\| show a ≤ lift.{u} o from le_of_lt <\| h.symm ▸ lt_succ a ⟨b, (lift_inj.{u,v}).1 <\| by rw [h, ← e, lift_succ]⟩, fun ⟨a, h⟩ => ⟨lift.{u} a, by simp only [h, lift_succ]⟩⟩ @[simp] theorem lift_pred (o : Ordinal.{v}) : lift.{u} (pred o) = pred (lift.{u} o) := by classical exact if h : ∃ a, o = succ a then by obtain ⟨a, e⟩ := h; simp only [e, pred_succ, lift_succ] else by rw [pred_eq_iff_not_succ.2 h, pred_eq_iff_not_succ.2 (mt lift_is_succ.1 h)] /-! ### Limit ordinals -/ /-- A limit ordinal is an ordinal which is not zero and not a successor. TODO: deprecate this in favor of `Order.IsSuccLimit`. -/ def IsLimit (o : Ordinal) : Prop := IsSuccLimit o theorem isLimit_iff {o} : IsLimit o ↔ o ≠ 0 ∧ IsSuccPrelimit o := by simp [IsLimit, IsSuccLimit] theorem IsLimit.isSuccPrelimit {o} (h : IsLimit o) : IsSuccPrelimit o := IsSuccLimit.isSuccPrelimit h theorem IsLimit.succ_lt {o a : Ordinal} (h : IsLimit o) : a < o → succ a < o := IsSuccLimit.succ_lt h theorem isSuccPrelimit_zero : IsSuccPrelimit (0 : Ordinal) := isSuccPrelimit_bot theorem not_zero_isLimit : ¬IsLimit 0 := not_isSuccLimit_bot theorem not_succ_isLimit (o) : ¬IsLimit (succ o) := not_isSuccLimit_succ o theorem not_succ_of_isLimit {o} (h : IsLimit o) : ¬∃ a, o = succ a \| ⟨a, e⟩ => not_succ_isLimit a (e ▸ h) theorem succ_lt_of_isLimit {o a : Ordinal} (h : IsLimit o) : succ a < o ↔ a < o := IsSuccLimit.succ_lt_iff h theorem le_succ_of_isLimit {o} (h : IsLimit o) {a} : o ≤ succ a ↔ o ≤ a := le_iff_le_iff_lt_iff_lt.2 <\| succ_lt_of_isLimit h theorem limit_le {o} (h : IsLimit o) {a} : o ≤ a ↔ ∀ x < o, x ≤ a := ⟨fun h _x l => l.le.trans h, fun H => (le_succ_of_isLimit h).1 <\| le_of_not_lt fun hn => not_lt_of_le (H _ hn) (lt_succ a)⟩ theorem lt_limit {o} (h : IsLimit o) {a} : a < o ↔ ∃ x < o, a < x := by -- Porting note: `bex_def` is required. simpa only [not_forall₂, not_le, bex_def] using not_congr (@limit_le _ h a) @[simp] theorem lift_isLimit (o : Ordinal.{v}) : IsLimit (lift.{u,v} o) ↔ IsLimit o := liftInitialSeg.isSuccLimit_apply_iff theorem IsLimit.pos {o : Ordinal} (h : IsLimit o) : 0 < o := IsSuccLimit.bot_lt h theorem IsLimit.ne_zero {o : Ordinal} (h : IsLimit o) : o ≠ 0 := h.pos.ne' theorem IsLimit.one_lt {o : Ordinal} (h : IsLimit o) : 1 < o := by simpa only [succ_zero] using h.succ_lt h.pos theorem IsLimit.nat_lt {o : Ordinal} (h : IsLimit o) : ∀ n : ℕ, (n : Ordinal) < o \| 0 => h.pos \| n + 1 => h.succ_lt (IsLimit.nat_lt h n) theorem zero_or_succ_or_limit (o : Ordinal) : o = 0 ∨ (∃ a, o = succ a) ∨ IsLimit o := by simpa [eq_comm] using isMin_or_mem_range_succ_or_isSuccLimit o theorem isLimit_of_not_succ_of_ne_zero {o : Ordinal} (h : ¬∃ a, o = succ a) (h' : o ≠ 0) : IsLimit o := ((zero_or_succ_or_limit o).resolve_left h').resolve_left h -- TODO: this is an iff with `IsSuccPrelimit` theorem IsLimit.sSup_Iio {o : Ordinal} (h : IsLimit o) : sSup (Iio o) = o := by apply (csSup_le' (fun a ha ↦ le_of_lt ha)).antisymm apply le_of_forall_lt intro a ha exact (lt_succ a).trans_le (le_csSup bddAbove_Iio (h.succ_lt ha)) theorem IsLimit.iSup_Iio {o : Ordinal} (h : IsLimit o) : ⨆ a : Iio o, a.1 = o := by rw [← sSup_eq_iSup', h.sSup_Iio] /-- Main induction principle of ordinals: if one can prove a property by induction at successor ordinals and at limit ordinals, then it holds for all ordinals. -/ @[elab_as_elim] def limitRecOn {motive : Ordinal → Sort} (o : Ordinal) (zero : motive 0) (succ : ∀ o, motive o → motive (succ o)) (isLimit : ∀ o, IsLimit o → (∀ o' < o, motive o') → motive o) : motive o := by refine SuccOrder.limitRecOn o (fun a ha ↦ ?_) (fun a _ ↦ succ a) isLimit convert zero simpa using ha @[simp] theorem limitRecOn_zero {motive} (H₁ H₂ H₃) : @limitRecOn motive 0 H₁ H₂ H₃ = H₁ := SuccOrder.limitRecOn_isMin _ _ _ isMin_bot @[simp] theorem limitRecOn_succ {motive} (o H₁ H₂ H₃) : @limitRecOn motive (succ o) H₁ H₂ H₃ = H₂ o (@limitRecOn motive o H₁ H₂ H₃) := SuccOrder.limitRecOn_succ .. @[simp] theorem limitRecOn_limit {motive} (o H₁ H₂ H₃ h) : @limitRecOn motive o H₁ H₂ H₃ = H₃ o h fun x _h => @limitRecOn motive x H₁ H₂ H₃ := SuccOrder.limitRecOn_of_isSuccLimit .. /-- Bounded recursion on ordinals. Similar to `limitRecOn`, with the assumption `o < l` added to all cases. The final term's domain is the ordinals below `l`. -/ @[elab_as_elim] def boundedLimitRecOn {l : Ordinal} (lLim : l.IsLimit) {motive : Iio l → Sort} (o : Iio l) (zero : motive ⟨0, lLim.pos⟩) (succ : (o : Iio l) → motive o → motive ⟨succ o, lLim.succ_lt o.2⟩) (isLimit : (o : Iio l) → IsLimit o → (Π o' < o, motive o') → motive o) : motive o := limitRecOn (motive := fun p ↦ (h : p < l) → motive ⟨p, h⟩) o.1 (fun _ ↦ zero) (fun o ih h ↦ succ ⟨o, _⟩ <\| ih <\| (lt_succ o).trans h) (fun _o ho ih _ ↦ isLimit _ ho fun _o' h ↦ ih _ h _) o.2 @[simp] theorem boundedLimitRec_zero {l} (lLim : l.IsLimit) {motive} (H₁ H₂ H₃) : @boundedLimitRecOn l lLim motive ⟨0, lLim.pos⟩ H₁ H₂ H₃ = H₁ := by rw [boundedLimitRecOn, limitRecOn_zero] @[simp] theorem boundedLimitRec_succ {l} (lLim : l.IsLimit) {motive} (o H₁ H₂ H₃) : @boundedLimitRecOn l lLim motive ⟨succ o.1, lLim.succ_lt o.2⟩ H₁ H₂ H₃ = H₂ o (@boundedLimitRecOn l lLim motive o H₁ H₂ H₃) := by rw [boundedLimitRecOn, limitRecOn_succ] rfl theorem boundedLimitRec_limit {l} (lLim : l.IsLimit) {motive} (o H₁ H₂ H₃ oLim) : @boundedLimitRecOn l lLim motive o H₁ H₂ H₃ = H₃ o oLim (fun x _ ↦ @boundedLimitRecOn l lLim motive x H₁ H₂ H₃) := by rw [boundedLimitRecOn, limitRecOn_limit] rfl instance orderTopToTypeSucc (o : Ordinal) : OrderTop (succ o).toType := @OrderTop.mk _ _ (Top.mk _) le_enum_succ theorem enum_succ_eq_top {o : Ordinal} : enum (α := (succ o).toType) (· < ·) ⟨o, type_toType _ ▸ lt_succ o⟩ = ⊤ := rfl theorem has_succ_of_type_succ_lt {α} {r : α → α → Prop} [wo : IsWellOrder α r] (h : ∀ a < type r, succ a < type r) (x : α) : ∃ y, r x y := by use enum r ⟨succ (typein r x), h _ (typein_lt_type r x)⟩ convert enum_lt_enum.mpr _ · rw [enum_typein] · rw [Subtype.mk_lt_mk, lt_succ_iff] theorem toType_noMax_of_succ_lt {o : Ordinal} (ho : ∀ a < o, succ a < o) : NoMaxOrder o.toType := ⟨has_succ_of_type_succ_lt (type_toType _ ▸ ho)⟩ theorem bounded_singleton {r : α → α → Prop} [IsWellOrder α r] (hr : (type r).IsLimit) (x) : Bounded r {x} := by refine ⟨enum r ⟨succ (typein r x), hr.succ_lt (typein_lt_type r x)⟩, ?_⟩ intro b hb rw [mem_singleton_iff.1 hb] nth_rw 1 [← enum_typein r x] rw [@enum_lt_enum _ r, Subtype.mk_lt_mk] apply lt_succ @[simp] theorem typein_ordinal (o : Ordinal.{u}) : @typein Ordinal (· < ·) _ o = Ordinal.lift.{u + 1} o := by refine Quotient.inductionOn o ?_ rintro ⟨α, r, wo⟩; apply Quotient.sound constructor; refine ((RelIso.preimage Equiv.ulift r).trans (enum r).symm).symm theorem mk_Iio_ordinal (o : Ordinal.{u}) : #(Iio o) = Cardinal.lift.{u + 1} o.card := by rw [lift_card, ← typein_ordinal] rfl /-! ### Normal ordinal functions -/ /-- A normal ordinal function is a strictly increasing function which is order-continuous, i.e., the image `f o` of a limit ordinal `o` is the sup of `f a` for `a < o`. -/ def IsNormal (f : Ordinal → Ordinal) : Prop := (∀ o, f o < f (succ o)) ∧ ∀ o, IsLimit o → ∀ a, f o ≤ a ↔ ∀ b < o, f b ≤ a theorem IsNormal.limit_le {f} (H : IsNormal f) : ∀ {o}, IsLimit o → ∀ {a}, f o ≤ a ↔ ∀ b < o, f b ≤ a := @H.2 theorem IsNormal.limit_lt {f} (H : IsNormal f) {o} (h : IsLimit o) {a} : a < f o ↔ ∃ b < o, a < f b := not_iff_not.1 <\| by simpa only [exists_prop, not_exists, not_and, not_lt] using H.2 _ h a theorem IsNormal.strictMono {f} (H : IsNormal f) : StrictMono f := fun a b => limitRecOn b (Not.elim (not_lt_of_le <\| Ordinal.zero_le _)) (fun _b IH h => (lt_or_eq_of_le (le_of_lt_succ h)).elim (fun h => (IH h).trans (H.1 _)) fun e => e ▸ H.1 _) fun _b l _IH h => lt_of_lt_of_le (H.1 a) ((H.2 _ l _).1 le_rfl _ (l.succ_lt h)) theorem IsNormal.monotone {f} (H : IsNormal f) : Monotone f := H.strictMono.monotone theorem isNormal_iff_strictMono_limit (f : Ordinal → Ordinal) : IsNormal f ↔ StrictMono f ∧ ∀ o, IsLimit o → ∀ a, (∀ b < o, f b ≤ a) → f o ≤ a := ⟨fun hf => ⟨hf.strictMono, fun a ha c => (hf.2 a ha c).2⟩, fun ⟨hs, hl⟩ => ⟨fun a => hs (lt_succ a), fun a ha c => ⟨fun hac _b hba => ((hs hba).trans_le hac).le, hl a ha c⟩⟩⟩ theorem IsNormal.lt_iff {f} (H : IsNormal f) {a b} : f a < f b ↔ a < b := StrictMono.lt_iff_lt <\| H.strictMono theorem IsNormal.le_iff {f} (H : IsNormal f) {a b} : f a ≤ f b ↔ a ≤ b := le_iff_le_iff_lt_iff_lt.2 H.lt_iff theorem IsNormal.inj {f} (H : IsNormal f) {a b} : f a = f b ↔ a = b := by simp only [le_antisymm_iff, H.le_iff] theorem IsNormal.id_le {f} (H : IsNormal f) : id ≤ f := H.strictMono.id_le theorem IsNormal.le_apply {f} (H : IsNormal f) {a} : a ≤ f a := H.strictMono.le_apply theorem IsNormal.le_iff_eq {f} (H : IsNormal f) {a} : f a ≤ a ↔ f a = a := H.le_apply.le_iff_eq theorem IsNormal.le_set {f o} (H : IsNormal f) (p : Set Ordinal) (p0 : p.Nonempty) (b) (H₂ : ∀ o, b ≤ o ↔ ∀ a ∈ p, a ≤ o) : f b ≤ o ↔ ∀ a ∈ p, f a ≤ o := ⟨fun h _ pa => (H.le_iff.2 ((H₂ _).1 le_rfl _ pa)).trans h, fun h => by induction b using limitRecOn with \| zero => obtain ⟨x, px⟩ := p0 have := Ordinal.le_zero.1 ((H₂ _).1 (Ordinal.zero_le _) _ px) rw [this] at px exact h _ px \| succ S _ => rcases not_forall₂.1 (mt (H₂ S).2 <\| (lt_succ S).not_le) with ⟨a, h₁, h₂⟩ exact (H.le_iff.2 <\| succ_le_of_lt <\| not_le.1 h₂).trans (h _ h₁) \| isLimit S L _ => refine (H.2 _ L _).2 fun a h' => ?_ rcases not_forall₂.1 (mt (H₂ a).2 h'.not_le) with ⟨b, h₁, h₂⟩ exact (H.le_iff.2 <\| (not_le.1 h₂).le).trans (h _ h₁)⟩ theorem IsNormal.le_set' {f o} (H : IsNormal f) (p : Set α) (p0 : p.Nonempty) (g : α → Ordinal) (b) (H₂ : ∀ o, b ≤ o ↔ ∀ a ∈ p, g a ≤ o) : f b ≤ o ↔ ∀ a ∈ p, f (g a) ≤ o := by simpa [H₂] using H.le_set (g '' p) (p0.image g) b theorem IsNormal.refl : IsNormal id := ⟨lt_succ, fun _o l _a => Ordinal.limit_le l⟩ theorem IsNormal.trans {f g} (H₁ : IsNormal f) (H₂ : IsNormal g) : IsNormal (f ∘ g) := ⟨fun _x => H₁.lt_iff.2 (H₂.1 _), fun o l _a => H₁.le_set' (· < o) ⟨0, l.pos⟩ g _ fun _c => H₂.2 _ l _⟩ theorem IsNormal.isLimit {f} (H : IsNormal f) {o} (ho : IsLimit o) : IsLimit (f o) := by rw [isLimit_iff, isSuccPrelimit_iff_succ_lt] use (H.lt_iff.2 ho.pos).ne_bot intro a ha obtain ⟨b, hb, hab⟩ := (H.limit_lt ho).1 ha rw [← succ_le_iff] at hab apply hab.trans_lt rwa [H.lt_iff] theorem add_le_of_limit {a b c : Ordinal} (h : IsLimit b) : a + b ≤ c ↔ ∀ b' < b, a + b' ≤ c := ⟨fun h _ l => (add_le_add_left l.le _).trans h, fun H => le_of_not_lt <\| by -- Porting note: `induction` tactics are required because of the parser bug. induction a using inductionOn with \| H α r => induction b using inductionOn with \| H β s => intro l suffices ∀ x : β, Sum.Lex r s (Sum.inr x) (enum _ ⟨_, l⟩) by -- Porting note: `revert` & `intro` is required because `cases'` doesn't replace -- `enum _ _ l` in `this`. revert this; rcases enum _ ⟨_, l⟩ with x \| x <;> intro this · cases this (enum s ⟨0, h.pos⟩) · exact irrefl _ (this _) intro x rw [← typein_lt_typein (Sum.Lex r s), typein_enum] have := H _ (h.succ_lt (typein_lt_type s x)) rw [add_succ, succ_le_iff] at this refine (RelEmbedding.ofMonotone (fun a => ?_) fun a b => ?_).ordinal_type_le.trans_lt this · rcases a with ⟨a \| b, h⟩ · exact Sum.inl a · exact Sum.inr ⟨b, by cases h; assumption⟩ · rcases a with ⟨a \| a, h₁⟩ <;> rcases b with ⟨b \| b, h₂⟩ <;> cases h₁ <;> cases h₂ <;> rintro ⟨⟩ <;> constructor <;> assumption⟩ theorem isNormal_add_right (a : Ordinal) : IsNormal (a + ·) := ⟨fun b => (add_lt_add_iff_left a).2 (lt_succ b), fun _b l _c => add_le_of_limit l⟩ theorem isLimit_add (a) {b} : IsLimit b → IsLimit (a + b) := (isNormal_add_right a).isLimit alias IsLimit.add := isLimit_add /-! ### Subtraction on ordinals -/ /-- The set in the definition of subtraction is nonempty. -/ private theorem sub_nonempty {a b : Ordinal} : { o \| a ≤ b + o }.Nonempty := ⟨a, le_add_left _ _⟩ /-- `a - b` is the unique ordinal satisfying `b + (a - b) = a` when `b ≤ a`. -/ instance sub : Sub Ordinal := ⟨fun a b => sInf { o \| a ≤ b + o }⟩ theorem le_add_sub (a b : Ordinal) : a ≤ b + (a - b) := csInf_mem sub_nonempty theorem sub_le {a b c : Ordinal} : a - b ≤ c ↔ a ≤ b + c := ⟨fun h => (le_add_sub a b).trans (add_le_add_left h _), fun h => csInf_le' h⟩ theorem lt_sub {a b c : Ordinal} : a < b - c ↔ c + a < b := lt_iff_lt_of_le_iff_le sub_le theorem add_sub_cancel (a b : Ordinal) : a + b - a = b := le_antisymm (sub_le.2 <\| le_rfl) ((add_le_add_iff_left a).1 <\| le_add_sub _ _) theorem sub_eq_of_add_eq {a b c : Ordinal} (h : a + b = c) : c - a = b := h ▸ add_sub_cancel _ _ theorem sub_le_self (a b : Ordinal) : a - b ≤ a := sub_le.2 <\| le_add_left _ _ protected theorem add_sub_cancel_of_le {a b : Ordinal} (h : b ≤ a) : b + (a - b) = a := (le_add_sub a b).antisymm' (by rcases zero_or_succ_or_limit (a - b) with (e \| ⟨c, e⟩ \| l) · simp only [e, add_zero, h] · rw [e, add_succ, succ_le_iff, ← lt_sub, e] exact lt_succ c · exact (add_le_of_limit l).2 fun c l => (lt_sub.1 l).le) theorem le_sub_of_le {a b c : Ordinal} (h : b ≤ a) : c ≤ a - b ↔ b + c ≤ a := by rw [← add_le_add_iff_left b, Ordinal.add_sub_cancel_of_le h] theorem sub_lt_of_le {a b c : Ordinal} (h : b ≤ a) : a - b < c ↔ a < b + c := lt_iff_lt_of_le_iff_le (le_sub_of_le h) instance existsAddOfLE : ExistsAddOfLE Ordinal := ⟨fun h => ⟨_, (Ordinal.add_sub_cancel_of_le h).symm⟩⟩ @[simp] theorem sub_zero (a : Ordinal) : a - 0 = a := by simpa only [zero_add] using add_sub_cancel 0 a @[simp] theorem zero_sub (a : Ordinal) : 0 - a = 0 := by rw [← Ordinal.le_zero]; apply sub_le_self @[simp] theorem sub_self (a : Ordinal) : a - a = 0 := by simpa only [add_zero] using add_sub_cancel a 0 protected theorem sub_eq_zero_iff_le {a b : Ordinal} : a - b = 0 ↔ a ≤ b := ⟨fun h => by simpa only [h, add_zero] using le_add_sub a b, fun h => by rwa [← Ordinal.le_zero, sub_le, add_zero]⟩ protected theorem sub_ne_zero_iff_lt {a b : Ordinal} : a - b ≠ 0 ↔ b < a := by simpa using Ordinal.sub_eq_zero_iff_le.not theorem sub_sub (a b c : Ordinal) : a - b - c = a - (b + c) := eq_of_forall_ge_iff fun d => by rw [sub_le, sub_le, sub_le, add_assoc] @[simp] theorem add_sub_add_cancel (a b c : Ordinal) : a + b - (a + c) = b - c := by rw [← sub_sub, add_sub_cancel] theorem le_sub_of_add_le {a b c : Ordinal} (h : b + c ≤ a) : c ≤ a - b := by rw [← add_le_add_iff_left b] exact h.trans (le_add_sub a b) theorem sub_lt_of_lt_add {a b c : Ordinal} (h : a < b + c) (hc : 0 < c) : a - b < c := by obtain hab \| hba := lt_or_le a b · rwa [Ordinal.sub_eq_zero_iff_le.2 hab.le] · rwa [sub_lt_of_le hba] theorem lt_add_iff {a b c : Ordinal} (hc : c ≠ 0) : a < b + c ↔ ∃ d < c, a ≤ b + d := by use fun h ↦ ⟨_, sub_lt_of_lt_add h hc.bot_lt, le_add_sub a b⟩ rintro ⟨d, hd, ha⟩ exact ha.trans_lt (add_lt_add_left hd b) theorem add_le_iff {a b c : Ordinal} (hb : b ≠ 0) : a + b ≤ c ↔ ∀ d < b, a + d < c := by simpa using (lt_add_iff hb).not @[deprecated add_le_iff (since := "2024-12-08")] theorem add_le_of_forall_add_lt {a b c : Ordinal} (hb : 0 < b) (h : ∀ d < b, a + d < c) : a + b ≤ c := (add_le_iff hb.ne').2 h theorem isLimit_sub {a b} (ha : IsLimit a) (h : b < a) : IsLimit (a - b) := by rw [isLimit_iff, Ordinal.sub_ne_zero_iff_lt, isSuccPrelimit_iff_succ_lt] refine ⟨h, fun c hc ↦ ?_⟩ rw [lt_sub] at hc ⊢ rw [add_succ] exact ha.succ_lt hc /-! ### Multiplication of ordinals -/ /-- The multiplication of ordinals `o₁` and `o₂` is the (well founded) lexicographic order on `o₂ × o₁`. -/ instance monoid : Monoid Ordinal.{u} where mul a b := Quotient.liftOn₂ a b (fun ⟨α, r, _⟩ ⟨β, s, _⟩ => ⟦⟨β × α, Prod.Lex s r, inferInstance⟩⟧ : WellOrder → WellOrder → Ordinal) fun ⟨_, _, _⟩ _ _ _ ⟨f⟩ ⟨g⟩ => Quot.sound ⟨RelIso.prodLexCongr g f⟩ one := 1 mul_assoc a b c := Quotient.inductionOn₃ a b c fun ⟨α, r, _⟩ ⟨β, s, _⟩ ⟨γ, t, _⟩ => Eq.symm <\| Quotient.sound ⟨⟨prodAssoc _ _ _, @fun a b => by rcases a with ⟨⟨a₁, a₂⟩, a₃⟩ rcases b with ⟨⟨b₁, b₂⟩, b₃⟩ simp [Prod.lex_def, and_or_left, or_assoc, and_assoc]⟩⟩ mul_one a := inductionOn a fun α r _ => Quotient.sound ⟨⟨punitProd _, @fun a b => by rcases a with ⟨⟨⟨⟩⟩, a⟩; rcases b with ⟨⟨⟨⟩⟩, b⟩ simp only [Prod.lex_def, EmptyRelation, false_or] simp only [eq_self_iff_true, true_and] rfl⟩⟩ one_mul a := inductionOn a fun α r _ => Quotient.sound ⟨⟨prodPUnit _, @fun a b => by rcases a with ⟨a, ⟨⟨⟩⟩⟩; rcases b with ⟨b, ⟨⟨⟩⟩⟩ simp only [Prod.lex_def, EmptyRelation, and_false, or_false] rfl⟩⟩ @[simp] theorem type_prod_lex {α β : Type u} (r : α → α → Prop) (s : β → β → Prop) [IsWellOrder α r] [IsWellOrder β s] : type (Prod.Lex s r) = type r type s := rfl private theorem mul_eq_zero' {a b : Ordinal} : a * b = 0 ↔ a = 0 ∨ b = 0 := inductionOn a fun α _ _ => inductionOn b fun β _ _ => by simp_rw [← type_prod_lex, type_eq_zero_iff_isEmpty] rw [or_comm] exact isEmpty_prod instance monoidWithZero : MonoidWithZero Ordinal := { Ordinal.monoid with zero := 0 mul_zero := fun _a => mul_eq_zero'.2 <\| Or.inr rfl zero_mul := fun _a => mul_eq_zero'.2 <\| Or.inl rfl } instance noZeroDivisors : NoZeroDivisors Ordinal := ⟨fun {_ _} => mul_eq_zero'.1⟩ @[simp] theorem lift_mul (a b : Ordinal.{v}) : lift.{u} (a * b) = lift.{u} a * lift.{u} b := Quotient.inductionOn₂ a b fun ⟨_α, _r, _⟩ ⟨_β, _s, _⟩ => Quotient.sound ⟨(RelIso.preimage Equiv.ulift _).trans (RelIso.prodLexCongr (RelIso.preimage Equiv.ulift _) (RelIso.preimage Equiv.ulift _)).symm⟩ @[simp] theorem card_mul (a b) : card (a * b) = card a * card b := Quotient.inductionOn₂ a b fun ⟨α, _r, _⟩ ⟨β, _s, _⟩ => mul_comm #β #α instance leftDistribClass : LeftDistribClass Ordinal.{u} := ⟨fun a b c => Quotient.inductionOn₃ a b c fun ⟨α, r, _⟩ ⟨β, s, _⟩ ⟨γ, t, _⟩ => Quotient.sound ⟨⟨sumProdDistrib _ _ _, by rintro ⟨a₁ \| a₁, a₂⟩ ⟨b₁ \| b₁, b₂⟩ <;> simp only [Prod.lex_def, Sum.lex_inl_inl, Sum.Lex.sep, Sum.lex_inr_inl, Sum.lex_inr_inr, sumProdDistrib_apply_left, sumProdDistrib_apply_right, reduceCtorEq] <;> -- Porting note: `Sum.inr.inj_iff` is required. simp only [Sum.inl.inj_iff, Sum.inr.inj_iff, true_or, false_and, false_or]⟩⟩⟩ theorem mul_succ (a b : Ordinal) : a * succ b = a * b + a := mul_add_one a b instance mulLeftMono : MulLeftMono Ordinal.{u} := ⟨fun c a b => Quotient.inductionOn₃ a b c fun ⟨α, r, _⟩ ⟨β, s, _⟩ ⟨γ, t, _⟩ ⟨f⟩ => by refine (RelEmbedding.ofMonotone (fun a : α × γ => (f a.1, a.2)) fun a b h => ?_).ordinal_type_le obtain ⟨-, -, h'⟩ \| ⟨-, h'⟩ := h · exact Prod.Lex.left _ _ (f.toRelEmbedding.map_rel_iff.2 h') · exact Prod.Lex.right _ h'⟩ instance mulRightMono : MulRightMono Ordinal.{u} := ⟨fun c a b => Quotient.inductionOn₃ a b c fun ⟨α, r, _⟩ ⟨β, s, _⟩ ⟨γ, t, _⟩ ⟨f⟩ => by refine (RelEmbedding.ofMonotone (fun a : γ × α => (a.1, f a.2)) fun a b h => ?_).ordinal_type_le obtain ⟨-, -, h'⟩ \| ⟨-, h'⟩ := h · exact Prod.Lex.left _ _ h' · exact Prod.Lex.right _ (f.toRelEmbedding.map_rel_iff.2 h')⟩ theorem le_mul_left (a : Ordinal) {b : Ordinal} (hb : 0 < b) : a ≤ a * b := by convert mul_le_mul_left' (one_le_iff_pos.2 hb) a rw [mul_one a] theorem le_mul_right (a : Ordinal) {b : Ordinal} (hb : 0 < b) : a ≤ b * a := by convert mul_le_mul_right' (one_le_iff_pos.2 hb) a rw [one_mul a] private theorem mul_le_of_limit_aux {α β r s} [IsWellOrder α r] [IsWellOrder β s] {c} (h : IsLimit (type s)) (H : ∀ b' < type s, type r * b' ≤ c) (l : c < type r * type s) : False := by suffices ∀ a b, Prod.Lex s r (b, a) (enum _ ⟨_, l⟩) by obtain ⟨b, a⟩ := enum _ ⟨_, l⟩ exact irrefl _ (this _ _) intro a b rw [← typein_lt_typein (Prod.Lex s r), typein_enum] have := H _ (h.succ_lt (typein_lt_type s b)) rw [mul_succ] at this have := ((add_lt_add_iff_left _).2 (typein_lt_type _ a)).trans_le this refine (RelEmbedding.ofMonotone (fun a => ?_) fun a b => ?_).ordinal_type_le.trans_lt this · rcases a with ⟨⟨b', a'⟩, h⟩ by_cases e : b = b' · refine Sum.inr ⟨a', ?_⟩ subst e obtain ⟨-, -, h⟩ \| ⟨-, h⟩ := h · exact (irrefl _ h).elim · exact h · refine Sum.inl (⟨b', ?_⟩, a') obtain ⟨-, -, h⟩ \| ⟨e, h⟩ := h · exact h · exact (e rfl).elim · rcases a with ⟨⟨b₁, a₁⟩, h₁⟩ rcases b with ⟨⟨b₂, a₂⟩, h₂⟩ intro h by_cases e₁ : b = b₁ <;> by_cases e₂ : b = b₂ · substs b₁ b₂ simpa only [subrel_val, Prod.lex_def, @irrefl _ s _ b, true_and, false_or, eq_self_iff_true, dif_pos, Sum.lex_inr_inr] using h · subst b₁ simp only [subrel_val, Prod.lex_def, e₂, Prod.lex_def, dif_pos, subrel_val, eq_self_iff_true, or_false, dif_neg, not_false_iff, Sum.lex_inr_inl, false_and] at h ⊢ obtain ⟨-, -, h₂_h⟩ \| e₂ := h₂ <;> [exact asymm h h₂_h; exact e₂ rfl] · simp [e₂, dif_neg e₁, show b₂ ≠ b₁ from e₂ ▸ e₁] · simpa only [dif_neg e₁, dif_neg e₂, Prod.lex_def, subrel_val, Subtype.mk_eq_mk, Sum.lex_inl_inl] using h theorem mul_le_of_limit {a b c : Ordinal} (h : IsLimit b) : a * b ≤ c ↔ ∀ b' < b, a * b' ≤ c := ⟨fun h _ l => (mul_le_mul_left' l.le _).trans h, fun H => -- Porting note: `induction` tactics are required because of the parser bug. le_of_not_lt <\| by induction a using inductionOn with \| H α r => induction b using inductionOn with \| H β s => exact mul_le_of_limit_aux h H⟩ theorem isNormal_mul_right {a : Ordinal} (h : 0 < a) : IsNormal (a * ·) := -- Porting note (https://github.com/leanprover-community/mathlib4/issues/12129): additional beta reduction needed ⟨fun b => by beta_reduce rw [mul_succ] simpa only [add_zero] using (add_lt_add_iff_left (a * b)).2 h, fun _ l _ => mul_le_of_limit l⟩ theorem lt_mul_of_limit {a b c : Ordinal} (h : IsLimit c) : a < b * c ↔ ∃ c' < c, a < b * c' := by -- Porting note: `bex_def` is required. simpa only [not_forall₂, not_le, bex_def] using not_congr (@mul_le_of_limit b c a h) theorem mul_lt_mul_iff_left {a b c : Ordinal} (a0 : 0 < a) : a * b < a * c ↔ b < c := (isNormal_mul_right a0).lt_iff theorem mul_le_mul_iff_left {a b c : Ordinal} (a0 : 0 < a) : a * b ≤ a * c ↔ b ≤ c := (isNormal_mul_right a0).le_iff theorem mul_lt_mul_of_pos_left {a b c : Ordinal} (h : a < b) (c0 : 0 < c) : c * a < c * b := (mul_lt_mul_iff_left c0).2 h theorem mul_pos {a b : Ordinal} (h₁ : 0 < a) (h₂ : 0 < b) : 0 < a * b := by simpa only [mul_zero] using mul_lt_mul_of_pos_left h₂ h₁ theorem mul_ne_zero {a b : Ordinal} : a ≠ 0 → b ≠ 0 → a * b ≠ 0 := by simpa only [Ordinal.pos_iff_ne_zero] using mul_pos theorem le_of_mul_le_mul_left {a b c : Ordinal} (h : c * a ≤ c * b) (h0 : 0 < c) : a ≤ b := le_imp_le_of_lt_imp_lt (fun h' => mul_lt_mul_of_pos_left h' h0) h theorem mul_right_inj {a b c : Ordinal} (a0 : 0 < a) : a * b = a * c ↔ b = c := (isNormal_mul_right a0).inj theorem isLimit_mul {a b : Ordinal} (a0 : 0 < a) : IsLimit b → IsLimit (a * b) := (isNormal_mul_right a0).isLimit theorem isLimit_mul_left {a b : Ordinal} (l : IsLimit a) (b0 : 0 < b) : IsLimit (a * b) := by rcases zero_or_succ_or_limit b with (rfl \| ⟨b, rfl⟩ \| lb) · exact b0.false.elim · rw [mul_succ] exact isLimit_add _ l · exact isLimit_mul l.pos lb theorem smul_eq_mul : ∀ (n : ℕ) (a : Ordinal), n • a = a * n \| 0, a => by rw [zero_nsmul, Nat.cast_zero, mul_zero] \| n + 1, a => by rw [succ_nsmul, Nat.cast_add, mul_add, Nat.cast_one, mul_one, smul_eq_mul n] private theorem add_mul_limit_aux {a b c : Ordinal} (ba : b + a = a) (l : IsLimit c) (IH : ∀ c' < c, (a + b) * succ c' = a * succ c' + b) : (a + b) * c = a * c := le_antisymm ((mul_le_of_limit l).2 fun c' h => by apply (mul_le_mul_left' (le_succ c') _).trans rw [IH _ h] apply (add_le_add_left _ _).trans · rw [← mul_succ] exact mul_le_mul_left' (succ_le_of_lt <\| l.succ_lt h) _ · rw [← ba] exact le_add_right _ _) (mul_le_mul_right' (le_add_right _ _) _) theorem add_mul_succ {a b : Ordinal} (c) (ba : b + a = a) : (a + b) * succ c = a * succ c + b := by induction c using limitRecOn with \| zero => simp only [succ_zero, mul_one] \| succ c IH => rw [mul_succ, IH, ← add_assoc, add_assoc _ b, ba, ← mul_succ] \| isLimit c l IH => rw [mul_succ, add_mul_limit_aux ba l IH, mul_succ, add_assoc] theorem add_mul_limit {a b c : Ordinal} (ba : b + a = a) (l : IsLimit c) : (a + b) * c = a * c := add_mul_limit_aux ba l fun c' _ => add_mul_succ c' ba /-! ### Division on ordinals -/ /-- The set in the definition of division is nonempty. -/ private theorem div_nonempty {a b : Ordinal} (h : b ≠ 0) : { o \| a < b * succ o }.Nonempty := ⟨a, (succ_le_iff (a := a) (b := b * succ a)).1 <\| by simpa only [succ_zero, one_mul] using mul_le_mul_right' (succ_le_of_lt (Ordinal.pos_iff_ne_zero.2 h)) (succ a)⟩ /-- `a / b` is the unique ordinal `o` satisfying `a = b * o + o'` with `o' < b`. -/ instance div : Div Ordinal := ⟨fun a b => if b = 0 then 0 else sInf { o \| a < b * succ o }⟩ @[simp] theorem div_zero (a : Ordinal) : a / 0 = 0 := dif_pos rfl private theorem div_def (a) {b : Ordinal} (h : b ≠ 0) : a / b = sInf { o \| a < b * succ o } := dif_neg h theorem lt_mul_succ_div (a) {b : Ordinal} (h : b ≠ 0) : a < b * succ (a / b) := by rw [div_def a h]; exact csInf_mem (div_nonempty h) theorem lt_mul_div_add (a) {b : Ordinal} (h : b ≠ 0) : a < b * (a / b) + b := by simpa only [mul_succ] using lt_mul_succ_div a h theorem div_le {a b c : Ordinal} (b0 : b ≠ 0) : a / b ≤ c ↔ a < b * succ c := ⟨fun h => (lt_mul_succ_div a b0).trans_le (mul_le_mul_left' (succ_le_succ_iff.2 h) _), fun h => by rw [div_def a b0]; exact csInf_le' h⟩ theorem lt_div {a b c : Ordinal} (h : c ≠ 0) : a < b / c ↔ c * succ a ≤ b := by rw [← not_le, div_le h, not_lt] theorem div_pos {b c : Ordinal} (h : c ≠ 0) : 0 < b / c ↔ c ≤ b := by simp [lt_div h] theorem le_div {a b c : Ordinal} (c0 : c ≠ 0) : a ≤ b / c ↔ c * a ≤ b := by induction a using limitRecOn with \| zero => simp only [mul_zero, Ordinal.zero_le] \| succ _ _ => rw [succ_le_iff, lt_div c0] \| isLimit _ h₁ h₂ => revert h₁ h₂ simp +contextual only [mul_le_of_limit, limit_le, forall_true_iff] theorem div_lt {a b c : Ordinal} (b0 : b ≠ 0) : a / b < c ↔ a < b * c := lt_iff_lt_of_le_iff_le <\| le_div b0 theorem div_le_of_le_mul {a b c : Ordinal} (h : a ≤ b * c) : a / b ≤ c := if b0 : b = 0 then by simp only [b0, div_zero, Ordinal.zero_le] else (div_le b0).2 <\| h.trans_lt <\| mul_lt_mul_of_pos_left (lt_succ c) (Ordinal.pos_iff_ne_zero.2 b0) theorem mul_lt_of_lt_div {a b c : Ordinal} : a < b / c → c * a < b := lt_imp_lt_of_le_imp_le div_le_of_le_mul @[simp] theorem zero_div (a : Ordinal) : 0 / a = 0 := Ordinal.le_zero.1 <\| div_le_of_le_mul <\| Ordinal.zero_le _ theorem mul_div_le (a b : Ordinal) : b * (a / b) ≤ a := if b0 : b = 0 then by simp only [b0, zero_mul, Ordinal.zero_le] else (le_div b0).1 le_rfl theorem div_le_left {a b : Ordinal} (h : a ≤ b) (c : Ordinal) : a / c ≤ b / c := by obtain rfl \| hc := eq_or_ne c 0 · rw [div_zero, div_zero] · rw [le_div hc] exact (mul_div_le a c).trans h theorem mul_add_div (a) {b : Ordinal} (b0 : b ≠ 0) (c) : (b * a + c) / b = a + c / b := by apply le_antisymm · apply (div_le b0).2 rw [mul_succ, mul_add, add_assoc, add_lt_add_iff_left] apply lt_mul_div_add _ b0 · rw [le_div b0, mul_add, add_le_add_iff_left] apply mul_div_le theorem div_eq_zero_of_lt {a b : Ordinal} (h : a < b) : a / b = 0 := by rw [← Ordinal.le_zero, div_le <\| Ordinal.pos_iff_ne_zero.1 <\| (Ordinal.zero_le _).trans_lt h] simpa only [succ_zero, mul_one] using h @[simp] theorem mul_div_cancel (a) {b : Ordinal} (b0 : b ≠ 0) : b * a / b = a := by simpa only [add_zero, zero_div] using mul_add_div a b0 0 theorem mul_add_div_mul {a c : Ordinal} (hc : c < a) (b d : Ordinal) : (a * b + c) / (a * d) = b / d := by have ha : a ≠ 0 := ((Ordinal.zero_le c).trans_lt hc).ne' obtain rfl \| hd := eq_or_ne d 0 · rw [mul_zero, div_zero, div_zero] · have H := mul_ne_zero ha hd apply le_antisymm · rw [← lt_succ_iff, div_lt H, mul_assoc] · apply (add_lt_add_left hc _).trans_le rw [← mul_succ] apply mul_le_mul_left' rw [succ_le_iff] exact lt_mul_succ_div b hd · rw [le_div H, mul_assoc] exact (mul_le_mul_left' (mul_div_le b d) a).trans (le_add_right _ c) theorem mul_div_mul_cancel {a : Ordinal} (ha : a ≠ 0) (b c) : a * b / (a * c) = b / c := by convert mul_add_div_mul (Ordinal.pos_iff_ne_zero.2 ha) b c using 1 rw [add_zero] @[simp] theorem div_one (a : Ordinal) : a / 1 = a := by simpa only [one_mul] using mul_div_cancel a Ordinal.one_ne_zero @[simp] theorem div_self {a : Ordinal} (h : a ≠ 0) : a / a = 1 := by simpa only [mul_one] using mul_div_cancel 1 h theorem mul_sub (a b c : Ordinal) : a * (b - c) = a * b - a * c := if a0 : a = 0 then by simp only [a0, zero_mul, sub_self] else eq_of_forall_ge_iff fun d => by rw [sub_le, ← le_div a0, sub_le, ← le_div a0, mul_add_div _ a0] theorem isLimit_add_iff {a b} : IsLimit (a + b) ↔ IsLimit b ∨ b = 0 ∧ IsLimit a := by constructor <;> intro h · by_cases h' : b = 0 · rw [h', add_zero] at h right exact ⟨h', h⟩ left rw [← add_sub_cancel a b] apply isLimit_sub h suffices a + 0 < a + b by simpa only [add_zero] using this rwa [add_lt_add_iff_left, Ordinal.pos_iff_ne_zero] rcases h with (h \| ⟨rfl, h⟩) · exact isLimit_add a h · simpa only [add_zero] theorem dvd_add_iff : ∀ {a b c : Ordinal}, a ∣ b → (a ∣ b + c ↔ a ∣ c) \| a, _, c, ⟨b, rfl⟩ => ⟨fun ⟨d, e⟩ => ⟨d - b, by rw [mul_sub, ← e, add_sub_cancel]⟩, fun ⟨d, e⟩ => by rw [e, ← mul_add] apply dvd_mul_right⟩ theorem div_mul_cancel : ∀ {a b : Ordinal}, a ≠ 0 → a ∣ b → a * (b / a) = b \| a, _, a0, ⟨b, rfl⟩ => by rw [mul_div_cancel _ a0] theorem le_of_dvd : ∀ {a b : Ordinal}, b ≠ 0 → a ∣ b → a ≤ b -- Porting note: `⟨b, rfl⟩ => by` → `⟨b, e⟩ => by subst e` \| a, _, b0, ⟨b, e⟩ => by subst e -- Porting note: `Ne` is required. simpa only [mul_one] using mul_le_mul_left' (one_le_iff_ne_zero.2 fun h : b = 0 => by simp only [h, mul_zero, Ne, not_true_eq_false] at b0) a theorem dvd_antisymm {a b : Ordinal} (h₁ : a ∣ b) (h₂ : b ∣ a) : a = b := if a0 : a = 0 then by subst a; exact (eq_zero_of_zero_dvd h₁).symm else if b0 : b = 0 then by subst b; exact eq_zero_of_zero_dvd h₂ else (le_of_dvd b0 h₁).antisymm (le_of_dvd a0 h₂) instance isAntisymm : IsAntisymm Ordinal (· ∣ ·) := ⟨@dvd_antisymm⟩ /-- `a % b` is the unique ordinal `o'` satisfying `a = b * o + o'` with `o' < b`. -/ instance mod : Mod Ordinal := ⟨fun a b => a - b * (a / b)⟩ theorem mod_def (a b : Ordinal) : a % b = a - b * (a / b) := rfl theorem mod_le (a b : Ordinal) : a % b ≤ a := sub_le_self a _ @[simp] theorem mod_zero (a : Ordinal) : a % 0 = a := by simp only [mod_def, div_zero, zero_mul, sub_zero] theorem mod_eq_of_lt {a b : Ordinal} (h : a < b) : a % b = a := by simp only [mod_def, div_eq_zero_of_lt h, mul_zero, sub_zero] @[simp] theorem zero_mod (b : Ordinal) : 0 % b = 0 := by simp only [mod_def, zero_div, mul_zero, sub_self] theorem div_add_mod (a b : Ordinal) : b * (a / b) + a % b = a := Ordinal.add_sub_cancel_of_le <\| mul_div_le _ _ theorem mod_lt (a) {b : Ordinal} (h : b ≠ 0) : a % b < b := (add_lt_add_iff_left (b * (a / b))).1 <\| by rw [div_add_mod]; exact lt_mul_div_add a h @[simp] theorem mod_self (a : Ordinal) : a % a = 0 := if a0 : a = 0 then by simp only [a0, zero_mod] else by simp only [mod_def, div_self a0, mul_one, sub_self] @[simp] theorem mod_one (a : Ordinal) : a % 1 = 0 := by simp only [mod_def, div_one, one_mul, sub_self] theorem dvd_of_mod_eq_zero {a b : Ordinal} (H : a % b = 0) : b ∣ a := ⟨a / b, by simpa [H] using (div_add_mod a b).symm⟩ theorem mod_eq_zero_of_dvd {a b : Ordinal} (H : b ∣ a) : a % b = 0 := by rcases H with ⟨c, rfl⟩ rcases eq_or_ne b 0 with (rfl \| hb) · simp · simp [mod_def, hb] theorem dvd_iff_mod_eq_zero {a b : Ordinal} : b ∣ a ↔ a % b = 0 := ⟨mod_eq_zero_of_dvd, dvd_of_mod_eq_zero⟩ @[simp] theorem mul_add_mod_self (x y z : Ordinal) : (x * y + z) % x = z % x := by rcases eq_or_ne x 0 with rfl \| hx · simp · rwa [mod_def, mul_add_div, mul_add, ← sub_sub, add_sub_cancel, mod_def] @[simp] theorem mul_mod (x y : Ordinal) : x * y % x = 0 := by simpa using mul_add_mod_self x y 0 theorem mul_add_mod_mul {w x : Ordinal} (hw : w < x) (y z : Ordinal) : (x * y + w) % (x * z) = x * (y % z) + w := by rw [mod_def, mul_add_div_mul hw] apply sub_eq_of_add_eq rw [← add_assoc, mul_assoc, ← mul_add, div_add_mod] theorem mul_mod_mul (x y z : Ordinal) : (x * y) % (x * z) = x * (y % z) := by obtain rfl \| hx := Ordinal.eq_zero_or_pos x · simp · convert mul_add_mod_mul hx y z using 1 <;> rw [add_zero] theorem mod_mod_of_dvd (a : Ordinal) {b c : Ordinal} (h : c ∣ b) : a % b % c = a % c := by nth_rw 2 [← div_add_mod a b] rcases h with ⟨d, rfl⟩ rw [mul_assoc, mul_add_mod_self] @[simp] theorem mod_mod (a b : Ordinal) : a % b % b = a % b := mod_mod_of_dvd a dvd_rfl /-! ### Casting naturals into ordinals, compatibility with operations -/ instance instCharZero : CharZero Ordinal := by refine ⟨fun a b h ↦ ?_⟩ rwa [← Cardinal.ord_nat, ← Cardinal.ord_nat, Cardinal.ord_inj, Nat.cast_inj] at h @[simp] theorem one_add_natCast (m : ℕ) : 1 + (m : Ordinal) = succ m := by rw [← Nat.cast_one, ← Nat.cast_add, add_comm] rfl @[simp] theorem one_add_ofNat (m : ℕ) [m.AtLeastTwo] : 1 + (ofNat(m) : Ordinal) = Order.succ (OfNat.ofNat m : Ordinal) := one_add_natCast m @[simp, norm_cast] theorem natCast_mul (m : ℕ) : ∀ n : ℕ, ((m * n : ℕ) : Ordinal) = m * n \| 0 => by simp \| n + 1 => by rw [Nat.mul_succ, Nat.cast_add, natCast_mul m n, Nat.cast_succ, mul_add_one] @[simp, norm_cast] theorem natCast_sub (m n : ℕ) : ((m - n : ℕ) : Ordinal) = m - n := by rcases le_total m n with h \| h · rw [tsub_eq_zero_iff_le.2 h, Ordinal.sub_eq_zero_iff_le.2 (Nat.cast_le.2 h), Nat.cast_zero] · rw [← add_left_cancel_iff (a := ↑n), ← Nat.cast_add, add_tsub_cancel_of_le h, Ordinal.add_sub_cancel_of_le (Nat.cast_le.2 h)] @[simp, norm_cast] theorem natCast_div (m n : ℕ) : ((m / n : ℕ) : Ordinal) = m / n := by rcases eq_or_ne n 0 with (rfl \| hn) · simp · have hn' : (n : Ordinal) ≠ 0 := Nat.cast_ne_zero.2 hn apply le_antisymm · rw [le_div hn', ← natCast_mul, Nat.cast_le, mul_comm] apply Nat.div_mul_le_self · rw [div_le hn', ← add_one_eq_succ, ← Nat.cast_succ, ← natCast_mul, Nat.cast_lt, mul_comm, ← Nat.div_lt_iff_lt_mul (Nat.pos_of_ne_zero hn)] apply Nat.lt_succ_self @[simp, norm_cast] theorem natCast_mod (m n : ℕ) : ((m % n : ℕ) : Ordinal) = m % n := by rw [← add_left_cancel_iff, div_add_mod, ← natCast_div, ← natCast_mul, ← Nat.cast_add, Nat.div_add_mod] @[simp] theorem lift_natCast : ∀ n : ℕ, lift.{u, v} n = n \| 0 => by simp \| n + 1 => by simp [lift_natCast n] @[simp] theorem lift_ofNat (n : ℕ) [n.AtLeastTwo] : lift.{u, v} ofNat(n) = OfNat.ofNat n := lift_natCast n theorem lt_omega0 {o : Ordinal} : o < ω ↔ ∃ n : ℕ, o = n := by simp_rw [← Cardinal.ord_aleph0, Cardinal.lt_ord, lt_aleph0, card_eq_nat] theorem nat_lt_omega0 (n : ℕ) : ↑n < ω := lt_omega0.2 ⟨_, rfl⟩ theorem eq_nat_or_omega0_le (o : Ordinal) : (∃ n : ℕ, o = n) ∨ ω ≤ o := by obtain ho \| ho := lt_or_le o ω · exact Or.inl <\| lt_omega0.1 ho · exact Or.inr ho theorem omega0_pos : 0 < ω := nat_lt_omega0 0 theorem omega0_ne_zero : ω ≠ 0 := omega0_pos.ne' theorem one_lt_omega0 : 1 < ω := by simpa only [Nat.cast_one] using nat_lt_omega0 1 theorem isLimit_omega0 : IsLimit ω := by rw [isLimit_iff, isSuccPrelimit_iff_succ_lt] refine ⟨omega0_ne_zero, fun o h => ?_⟩ obtain ⟨n, rfl⟩ := lt_omega0.1 h exact nat_lt_omega0 (n + 1) theorem omega0_le {o : Ordinal} : ω ≤ o ↔ ∀ n : ℕ, ↑n ≤ o := ⟨fun h n => (nat_lt_omega0 _).le.trans h, fun H => le_of_forall_lt fun a h => by let ⟨n, e⟩ := lt_omega0.1 h rw [e, ← succ_le_iff]; exact H (n + 1)⟩ theorem nat_lt_limit {o} (h : IsLimit o) : ∀ n : ℕ, ↑n < o \| 0 => h.pos \| n + 1 => h.succ_lt (nat_lt_limit h n) theorem omega0_le_of_isLimit {o} (h : IsLimit o) : ω ≤ o := omega0_le.2 fun n => le_of_lt <\| nat_lt_limit h n theorem natCast_add_omega0 (n : ℕ) : n + ω = ω := by refine le_antisymm (le_of_forall_lt fun a ha ↦ ?_) (le_add_left _ _) obtain ⟨b, hb', hb⟩ := (lt_add_iff omega0_ne_zero).1 ha obtain ⟨m, rfl⟩ := lt_omega0.1 hb' apply hb.trans_lt exact_mod_cast nat_lt_omega0 (n + m) theorem one_add_omega0 : 1 + ω = ω := mod_cast natCast_add_omega0 1 theorem add_omega0 {a : Ordinal} (h : a < ω) : a + ω = ω := by obtain ⟨n, rfl⟩ := lt_omega0.1 h exact natCast_add_omega0 n @[simp] theorem natCast_add_of_omega0_le {o} (h : ω ≤ o) (n : ℕ) : n + o = o := by rw [← Ordinal.add_sub_cancel_of_le h, ← add_assoc, natCast_add_omega0] @[simp] theorem one_add_of_omega0_le {o} (h : ω ≤ o) : 1 + o = o := mod_cast natCast_add_of_omega0_le h 1 open Ordinal theorem isLimit_iff_omega0_dvd {a : Ordinal} : IsLimit a ↔ a ≠ 0 ∧ ω ∣ a := by refine ⟨fun l => ⟨l.ne_zero, ⟨a / ω, le_antisymm ?_ (mul_div_le _ _)⟩⟩, fun h => ?_⟩ · refine (limit_le l).2 fun x hx => le_of_lt ?_ rw [← div_lt omega0_ne_zero, ← succ_le_iff, le_div omega0_ne_zero, mul_succ, add_le_of_limit isLimit_omega0] intro b hb rcases lt_omega0.1 hb with ⟨n, rfl⟩ exact (add_le_add_right (mul_div_le _ _) _).trans (lt_sub.1 <\| nat_lt_limit (isLimit_sub l hx) _).le · rcases h with ⟨a0, b, rfl⟩ refine isLimit_mul_left isLimit_omega0 (Ordinal.pos_iff_ne_zero.2 <\| mt ?_ a0) intro e simp only [e, mul_zero] @[simp] theorem natCast_mod_omega0 (n : ℕ) : n % ω = n := mod_eq_of_lt (nat_lt_omega0 n) end Ordinal namespace Cardinal open Ordinal @[simp] theorem add_one_of_aleph0_le {c} (h : ℵ₀ ≤ c) : c + 1 = c := by rw [add_comm, ← card_ord c, ← card_one, ← card_add, one_add_of_omega0_le] rwa [← ord_aleph0, ord_le_ord] theorem isLimit_ord {c} (co : ℵ₀ ≤ c) : (ord c).IsLimit := by rw [isLimit_iff, isSuccPrelimit_iff_succ_lt] refine ⟨fun h => aleph0_ne_zero ?_, fun a => lt_imp_lt_of_le_imp_le fun h => ?_⟩ · rw [← Ordinal.le_zero, ord_le] at h simpa only [card_zero, nonpos_iff_eq_zero] using co.trans h · rw [ord_le] at h ⊢ rwa [← @add_one_of_aleph0_le (card a), ← card_succ] rw [← ord_le, ← le_succ_of_isLimit, ord_le] · exact co.trans h · rw [ord_aleph0] exact Ordinal.isLimit_omega0 theorem noMaxOrder {c} (h : ℵ₀ ≤ c) : NoMaxOrder c.ord.toType := toType_noMax_of_succ_lt fun _ ↦ (isLimit_ord h).succ_lt end Cardinal		Mathlib/SetTheory/Ordinal/Arithmetic.lean	2,327	2,328
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Mario Carneiro, Patrick Massot -/ import Mathlib.Algebra.Group.TypeTags.Basic import Mathlib.Data.Fin.VecNotation import Mathlib.Data.Finset.Piecewise import Mathlib.Order.Filter.Cofinite import Mathlib.Order.Filter.Curry import Mathlib.Topology.Constructions.SumProd import Mathlib.Topology.NhdsSet /-! # Constructions of new topological spaces from old ones This file constructs pi types, subtypes and quotients of topological spaces and sets up their basic theory, such as criteria for maps into or out of these constructions to be continuous; descriptions of the open sets, neighborhood filters, and generators of these constructions; and their behavior with respect to embeddings and other specific classes of maps. ## Implementation note The constructed topologies are defined using induced and coinduced topologies along with the complete lattice structure on topologies. Their universal properties (for example, a map `X → Y × Z` is continuous if and only if both projections `X → Y`, `X → Z` are) follow easily using order-theoretic descriptions of continuity. With more work we can also extract descriptions of the open sets, neighborhood filters and so on. ## Tags product, subspace, quotient space -/ noncomputable section open Topology TopologicalSpace Set Filter Function open scoped Set.Notation universe u v u' v' variable {X : Type u} {Y : Type v} {Z W ε ζ : Type} section Constructions instance {r : X → X → Prop} [t : TopologicalSpace X] : TopologicalSpace (Quot r) := coinduced (Quot.mk r) t instance instTopologicalSpaceQuotient {s : Setoid X} [t : TopologicalSpace X] : TopologicalSpace (Quotient s) := coinduced Quotient.mk' t instance instTopologicalSpaceSigma {ι : Type} {X : ι → Type v} [t₂ : ∀ i, TopologicalSpace (X i)] : TopologicalSpace (Sigma X) := ⨆ i, coinduced (Sigma.mk i) (t₂ i) instance Pi.topologicalSpace {ι : Type} {Y : ι → Type v} [t₂ : (i : ι) → TopologicalSpace (Y i)] : TopologicalSpace ((i : ι) → Y i) := ⨅ i, induced (fun f => f i) (t₂ i) instance ULift.topologicalSpace [t : TopologicalSpace X] : TopologicalSpace (ULift.{v, u} X) := t.induced ULift.down /-! ### `Additive`, `Multiplicative` The topology on those type synonyms is inherited without change. -/ section variable [TopologicalSpace X] open Additive Multiplicative instance : TopologicalSpace (Additive X) := ‹TopologicalSpace X› instance : TopologicalSpace (Multiplicative X) := ‹TopologicalSpace X› instance [DiscreteTopology X] : DiscreteTopology (Additive X) := ‹DiscreteTopology X› instance [DiscreteTopology X] : DiscreteTopology (Multiplicative X) := ‹DiscreteTopology X› theorem continuous_ofMul : Continuous (ofMul : X → Additive X) := continuous_id theorem continuous_toMul : Continuous (toMul : Additive X → X) := continuous_id theorem continuous_ofAdd : Continuous (ofAdd : X → Multiplicative X) := continuous_id theorem continuous_toAdd : Continuous (toAdd : Multiplicative X → X) := continuous_id theorem isOpenMap_ofMul : IsOpenMap (ofMul : X → Additive X) := IsOpenMap.id theorem isOpenMap_toMul : IsOpenMap (toMul : Additive X → X) := IsOpenMap.id theorem isOpenMap_ofAdd : IsOpenMap (ofAdd : X → Multiplicative X) := IsOpenMap.id theorem isOpenMap_toAdd : IsOpenMap (toAdd : Multiplicative X → X) := IsOpenMap.id theorem isClosedMap_ofMul : IsClosedMap (ofMul : X → Additive X) := IsClosedMap.id theorem isClosedMap_toMul : IsClosedMap (toMul : Additive X → X) := IsClosedMap.id theorem isClosedMap_ofAdd : IsClosedMap (ofAdd : X → Multiplicative X) := IsClosedMap.id theorem isClosedMap_toAdd : IsClosedMap (toAdd : Multiplicative X → X) := IsClosedMap.id theorem nhds_ofMul (x : X) : 𝓝 (ofMul x) = map ofMul (𝓝 x) := rfl theorem nhds_ofAdd (x : X) : 𝓝 (ofAdd x) = map ofAdd (𝓝 x) := rfl theorem nhds_toMul (x : Additive X) : 𝓝 x.toMul = map toMul (𝓝 x) := rfl theorem nhds_toAdd (x : Multiplicative X) : 𝓝 x.toAdd = map toAdd (𝓝 x) := rfl end /-! ### Order dual The topology on this type synonym is inherited without change. -/ section variable [TopologicalSpace X] open OrderDual instance OrderDual.instTopologicalSpace : TopologicalSpace Xᵒᵈ := ‹_› instance OrderDual.instDiscreteTopology [DiscreteTopology X] : DiscreteTopology Xᵒᵈ := ‹_› theorem continuous_toDual : Continuous (toDual : X → Xᵒᵈ) := continuous_id theorem continuous_ofDual : Continuous (ofDual : Xᵒᵈ → X) := continuous_id theorem isOpenMap_toDual : IsOpenMap (toDual : X → Xᵒᵈ) := IsOpenMap.id theorem isOpenMap_ofDual : IsOpenMap (ofDual : Xᵒᵈ → X) := IsOpenMap.id theorem isClosedMap_toDual : IsClosedMap (toDual : X → Xᵒᵈ) := IsClosedMap.id theorem isClosedMap_ofDual : IsClosedMap (ofDual : Xᵒᵈ → X) := IsClosedMap.id theorem nhds_toDual (x : X) : 𝓝 (toDual x) = map toDual (𝓝 x) := rfl theorem nhds_ofDual (x : X) : 𝓝 (ofDual x) = map ofDual (𝓝 x) := rfl variable [Preorder X] {x : X} instance OrderDual.instNeBotNhdsWithinIoi [(𝓝[<] x).NeBot] : (𝓝[>] toDual x).NeBot := ‹_› instance OrderDual.instNeBotNhdsWithinIio [(𝓝[>] x).NeBot] : (𝓝[<] toDual x).NeBot := ‹_› end theorem Quotient.preimage_mem_nhds [TopologicalSpace X] [s : Setoid X] {V : Set <\| Quotient s} {x : X} (hs : V ∈ 𝓝 (Quotient.mk' x)) : Quotient.mk' ⁻¹' V ∈ 𝓝 x := preimage_nhds_coinduced hs /-- The image of a dense set under `Quotient.mk'` is a dense set. -/ theorem Dense.quotient [Setoid X] [TopologicalSpace X] {s : Set X} (H : Dense s) : Dense (Quotient.mk' '' s) := Quotient.mk''_surjective.denseRange.dense_image continuous_coinduced_rng H /-- The composition of `Quotient.mk'` and a function with dense range has dense range. -/ theorem DenseRange.quotient [Setoid X] [TopologicalSpace X] {f : Y → X} (hf : DenseRange f) : DenseRange (Quotient.mk' ∘ f) := Quotient.mk''_surjective.denseRange.comp hf continuous_coinduced_rng theorem continuous_map_of_le {α : Type} [TopologicalSpace α] {s t : Setoid α} (h : s ≤ t) : Continuous (Setoid.map_of_le h) := continuous_coinduced_rng theorem continuous_map_sInf {α : Type} [TopologicalSpace α] {S : Set (Setoid α)} {s : Setoid α} (h : s ∈ S) : Continuous (Setoid.map_sInf h) := continuous_coinduced_rng instance {p : X → Prop} [TopologicalSpace X] [DiscreteTopology X] : DiscreteTopology (Subtype p) := ⟨bot_unique fun s _ => ⟨(↑) '' s, isOpen_discrete _, preimage_image_eq _ Subtype.val_injective⟩⟩ instance Sum.discreteTopology [TopologicalSpace X] [TopologicalSpace Y] [h : DiscreteTopology X] [hY : DiscreteTopology Y] : DiscreteTopology (X ⊕ Y) := ⟨sup_eq_bot_iff.2 <\| by simp [h.eq_bot, hY.eq_bot]⟩ instance Sigma.discreteTopology {ι : Type} {Y : ι → Type v} [∀ i, TopologicalSpace (Y i)] [h : ∀ i, DiscreteTopology (Y i)] : DiscreteTopology (Sigma Y) := ⟨iSup_eq_bot.2 fun _ => by simp only [(h _).eq_bot, coinduced_bot]⟩ @[simp] lemma comap_nhdsWithin_range {α β} [TopologicalSpace β] (f : α → β) (y : β) : comap f (𝓝[range f] y) = comap f (𝓝 y) := comap_inf_principal_range section Top variable [TopologicalSpace X] /- The 𝓝 filter and the subspace topology. -/ theorem mem_nhds_subtype (s : Set X) (x : { x // x ∈ s }) (t : Set { x // x ∈ s }) : t ∈ 𝓝 x ↔ ∃ u ∈ 𝓝 (x : X), Subtype.val ⁻¹' u ⊆ t := mem_nhds_induced _ x t theorem nhds_subtype (s : Set X) (x : { x // x ∈ s }) : 𝓝 x = comap (↑) (𝓝 (x : X)) := nhds_induced _ x lemma nhds_subtype_eq_comap_nhdsWithin (s : Set X) (x : { x // x ∈ s }) : 𝓝 x = comap (↑) (𝓝[s] (x : X)) := by rw [nhds_subtype, ← comap_nhdsWithin_range, Subtype.range_val] theorem nhdsWithin_subtype_eq_bot_iff {s t : Set X} {x : s} : 𝓝[((↑) : s → X) ⁻¹' t] x = ⊥ ↔ 𝓝[t] (x : X) ⊓ 𝓟 s = ⊥ := by rw [inf_principal_eq_bot_iff_comap, nhdsWithin, nhdsWithin, comap_inf, comap_principal, nhds_induced] theorem nhds_ne_subtype_eq_bot_iff {S : Set X} {x : S} : 𝓝[≠] x = ⊥ ↔ 𝓝[≠] (x : X) ⊓ 𝓟 S = ⊥ := by rw [← nhdsWithin_subtype_eq_bot_iff, preimage_compl, ← image_singleton, Subtype.coe_injective.preimage_image] theorem nhds_ne_subtype_neBot_iff {S : Set X} {x : S} : (𝓝[≠] x).NeBot ↔ (𝓝[≠] (x : X) ⊓ 𝓟 S).NeBot := by rw [neBot_iff, neBot_iff, not_iff_not, nhds_ne_subtype_eq_bot_iff] theorem discreteTopology_subtype_iff {S : Set X} : DiscreteTopology S ↔ ∀ x ∈ S, 𝓝[≠] x ⊓ 𝓟 S = ⊥ := by simp_rw [discreteTopology_iff_nhds_ne, SetCoe.forall', nhds_ne_subtype_eq_bot_iff] end Top /-- A type synonym equipped with the topology whose open sets are the empty set and the sets with finite complements. -/ def CofiniteTopology (X : Type) := X namespace CofiniteTopology /-- The identity equivalence between `` and `CofiniteTopology `. -/ def of : X ≃ CofiniteTopology X := Equiv.refl X instance [Inhabited X] : Inhabited (CofiniteTopology X) where default := of default instance : TopologicalSpace (CofiniteTopology X) where IsOpen s := s.Nonempty → Set.Finite sᶜ isOpen_univ := by simp isOpen_inter s t := by rintro hs ht ⟨x, hxs, hxt⟩ rw [compl_inter] exact (hs ⟨x, hxs⟩).union (ht ⟨x, hxt⟩) isOpen_sUnion := by rintro s h ⟨x, t, hts, hzt⟩ rw [compl_sUnion] exact Finite.sInter (mem_image_of_mem _ hts) (h t hts ⟨x, hzt⟩) theorem isOpen_iff {s : Set (CofiniteTopology X)} : IsOpen s ↔ s.Nonempty → sᶜ.Finite := Iff.rfl theorem isOpen_iff' {s : Set (CofiniteTopology X)} : IsOpen s ↔ s = ∅ ∨ sᶜ.Finite := by simp only [isOpen_iff, nonempty_iff_ne_empty, or_iff_not_imp_left] theorem isClosed_iff {s : Set (CofiniteTopology X)} : IsClosed s ↔ s = univ ∨ s.Finite := by simp only [← isOpen_compl_iff, isOpen_iff', compl_compl, compl_empty_iff] theorem nhds_eq (x : CofiniteTopology X) : 𝓝 x = pure x ⊔ cofinite := by ext U rw [mem_nhds_iff] constructor · rintro ⟨V, hVU, V_op, haV⟩ exact mem_sup.mpr ⟨hVU haV, mem_of_superset (V_op ⟨_, haV⟩) hVU⟩ · rintro ⟨hU : x ∈ U, hU' : Uᶜ.Finite⟩ exact ⟨U, Subset.rfl, fun _ => hU', hU⟩ theorem mem_nhds_iff {x : CofiniteTopology X} {s : Set (CofiniteTopology X)} : s ∈ 𝓝 x ↔ x ∈ s ∧ sᶜ.Finite := by simp [nhds_eq] end CofiniteTopology end Constructions section Prod variable [TopologicalSpace X] [TopologicalSpace Y] theorem MapClusterPt.curry_prodMap {α β : Type} {f : α → X} {g : β → Y} {la : Filter α} {lb : Filter β} {x : X} {y : Y} (hf : MapClusterPt x la f) (hg : MapClusterPt y lb g) : MapClusterPt (x, y) (la.curry lb) (.map f g) := by rw [mapClusterPt_iff_frequently] at hf hg rw [((𝓝 x).basis_sets.prod_nhds (𝓝 y).basis_sets).mapClusterPt_iff_frequently] rintro ⟨s, t⟩ ⟨hs, ht⟩ rw [frequently_curry_iff] exact (hf s hs).mono fun x hx ↦ (hg t ht).mono fun y hy ↦ ⟨hx, hy⟩ theorem MapClusterPt.prodMap {α β : Type} {f : α → X} {g : β → Y} {la : Filter α} {lb : Filter β} {x : X} {y : Y} (hf : MapClusterPt x la f) (hg : MapClusterPt y lb g) : MapClusterPt (x, y) (la ×ˢ lb) (.map f g) := (hf.curry_prodMap hg).mono <\| map_mono curry_le_prod end Prod section Bool lemma continuous_bool_rng [TopologicalSpace X] {f : X → Bool} (b : Bool) : Continuous f ↔ IsClopen (f ⁻¹' {b}) := by rw [continuous_discrete_rng, Bool.forall_bool' b, IsClopen, ← isOpen_compl_iff, ← preimage_compl, Bool.compl_singleton, and_comm] end Bool section Subtype variable [TopologicalSpace X] [TopologicalSpace Y] {p : X → Prop} lemma Topology.IsInducing.subtypeVal {t : Set Y} : IsInducing ((↑) : t → Y) := ⟨rfl⟩ @[deprecated (since := "2024-10-28")] alias inducing_subtype_val := IsInducing.subtypeVal lemma Topology.IsInducing.of_codRestrict {f : X → Y} {t : Set Y} (ht : ∀ x, f x ∈ t) (h : IsInducing (t.codRestrict f ht)) : IsInducing f := subtypeVal.comp h @[deprecated (since := "2024-10-28")] alias Inducing.of_codRestrict := IsInducing.of_codRestrict lemma Topology.IsEmbedding.subtypeVal : IsEmbedding ((↑) : Subtype p → X) := ⟨.subtypeVal, Subtype.coe_injective⟩ @[deprecated (since := "2024-10-26")] alias embedding_subtype_val := IsEmbedding.subtypeVal theorem Topology.IsClosedEmbedding.subtypeVal (h : IsClosed {a \| p a}) : IsClosedEmbedding ((↑) : Subtype p → X) := ⟨.subtypeVal, by rwa [Subtype.range_coe_subtype]⟩ @[continuity, fun_prop] theorem continuous_subtype_val : Continuous (@Subtype.val X p) := continuous_induced_dom theorem Continuous.subtype_val {f : Y → Subtype p} (hf : Continuous f) : Continuous fun x => (f x : X) := continuous_subtype_val.comp hf theorem IsOpen.isOpenEmbedding_subtypeVal {s : Set X} (hs : IsOpen s) : IsOpenEmbedding ((↑) : s → X) := ⟨.subtypeVal, (@Subtype.range_coe _ s).symm ▸ hs⟩ theorem IsOpen.isOpenMap_subtype_val {s : Set X} (hs : IsOpen s) : IsOpenMap ((↑) : s → X) := hs.isOpenEmbedding_subtypeVal.isOpenMap theorem IsOpenMap.restrict {f : X → Y} (hf : IsOpenMap f) {s : Set X} (hs : IsOpen s) : IsOpenMap (s.restrict f) := hf.comp hs.isOpenMap_subtype_val lemma IsClosed.isClosedEmbedding_subtypeVal {s : Set X} (hs : IsClosed s) : IsClosedEmbedding ((↑) : s → X) := .subtypeVal hs theorem IsClosed.isClosedMap_subtype_val {s : Set X} (hs : IsClosed s) : IsClosedMap ((↑) : s → X) := hs.isClosedEmbedding_subtypeVal.isClosedMap @[continuity, fun_prop] theorem Continuous.subtype_mk {f : Y → X} (h : Continuous f) (hp : ∀ x, p (f x)) : Continuous fun x => (⟨f x, hp x⟩ : Subtype p) := continuous_induced_rng.2 h theorem Continuous.subtype_map {f : X → Y} (h : Continuous f) {q : Y → Prop} (hpq : ∀ x, p x → q (f x)) : Continuous (Subtype.map f hpq) := (h.comp continuous_subtype_val).subtype_mk _ theorem continuous_inclusion {s t : Set X} (h : s ⊆ t) : Continuous (inclusion h) := continuous_id.subtype_map h theorem continuousAt_subtype_val {p : X → Prop} {x : Subtype p} : ContinuousAt ((↑) : Subtype p → X) x := continuous_subtype_val.continuousAt theorem Subtype.dense_iff {s : Set X} {t : Set s} : Dense t ↔ s ⊆ closure ((↑) '' t) := by rw [IsInducing.subtypeVal.dense_iff, SetCoe.forall] rfl theorem map_nhds_subtype_val {s : Set X} (x : s) : map ((↑) : s → X) (𝓝 x) = 𝓝[s] ↑x := by rw [IsInducing.subtypeVal.map_nhds_eq, Subtype.range_val] theorem map_nhds_subtype_coe_eq_nhds {x : X} (hx : p x) (h : ∀ᶠ x in 𝓝 x, p x) : map ((↑) : Subtype p → X) (𝓝 ⟨x, hx⟩) = 𝓝 x := map_nhds_induced_of_mem <\| by rw [Subtype.range_val]; exact h theorem nhds_subtype_eq_comap {x : X} {h : p x} : 𝓝 (⟨x, h⟩ : Subtype p) = comap (↑) (𝓝 x) := nhds_induced _ _ theorem tendsto_subtype_rng {Y : Type} {p : X → Prop} {l : Filter Y} {f : Y → Subtype p} : ∀ {x : Subtype p}, Tendsto f l (𝓝 x) ↔ Tendsto (fun x => (f x : X)) l (𝓝 (x : X)) \| ⟨a, ha⟩ => by rw [nhds_subtype_eq_comap, tendsto_comap_iff]; rfl theorem closure_subtype {x : { a // p a }} {s : Set { a // p a }} : x ∈ closure s ↔ (x : X) ∈ closure (((↑) : _ → X) '' s) := closure_induced @[simp] theorem continuousAt_codRestrict_iff {f : X → Y} {t : Set Y} (h1 : ∀ x, f x ∈ t) {x : X} : ContinuousAt (codRestrict f t h1) x ↔ ContinuousAt f x := IsInducing.subtypeVal.continuousAt_iff alias ⟨_, ContinuousAt.codRestrict⟩ := continuousAt_codRestrict_iff theorem ContinuousAt.restrict {f : X → Y} {s : Set X} {t : Set Y} (h1 : MapsTo f s t) {x : s} (h2 : ContinuousAt f x) : ContinuousAt (h1.restrict f s t) x := (h2.comp continuousAt_subtype_val).codRestrict _ theorem ContinuousAt.restrictPreimage {f : X → Y} {s : Set Y} {x : f ⁻¹' s} (h : ContinuousAt f x) : ContinuousAt (s.restrictPreimage f) x := h.restrict _ @[continuity, fun_prop] theorem Continuous.codRestrict {f : X → Y} {s : Set Y} (hf : Continuous f) (hs : ∀ a, f a ∈ s) : Continuous (s.codRestrict f hs) := hf.subtype_mk hs @[continuity, fun_prop] theorem Continuous.restrict {f : X → Y} {s : Set X} {t : Set Y} (h1 : MapsTo f s t) (h2 : Continuous f) : Continuous (h1.restrict f s t) := (h2.comp continuous_subtype_val).codRestrict _ @[continuity, fun_prop] theorem Continuous.restrictPreimage {f : X → Y} {s : Set Y} (h : Continuous f) : Continuous (s.restrictPreimage f) := h.restrict _ lemma Topology.IsEmbedding.restrict {f : X → Y} (hf : IsEmbedding f) {s : Set X} {t : Set Y} (H : s.MapsTo f t) : IsEmbedding H.restrict := .of_comp (hf.continuous.restrict H) continuous_subtype_val (hf.comp .subtypeVal) lemma Topology.IsOpenEmbedding.restrict {f : X → Y} (hf : IsOpenEmbedding f) {s : Set X} {t : Set Y} (H : s.MapsTo f t) (hs : IsOpen s) : IsOpenEmbedding H.restrict := ⟨hf.isEmbedding.restrict H, (by rw [MapsTo.range_restrict] exact continuous_subtype_val.1 _ (hf.isOpenMap _ hs))⟩ theorem Topology.IsInducing.codRestrict {e : X → Y} (he : IsInducing e) {s : Set Y} (hs : ∀ x, e x ∈ s) : IsInducing (codRestrict e s hs) := he.of_comp (he.continuous.codRestrict hs) continuous_subtype_val @[deprecated (since := "2024-10-28")] alias Inducing.codRestrict := IsInducing.codRestrict protected lemma Topology.IsEmbedding.codRestrict {e : X → Y} (he : IsEmbedding e) (s : Set Y) (hs : ∀ x, e x ∈ s) : IsEmbedding (codRestrict e s hs) := he.of_comp (he.continuous.codRestrict hs) continuous_subtype_val @[deprecated (since := "2024-10-26")] alias Embedding.codRestrict := IsEmbedding.codRestrict variable {s t : Set X} protected lemma Topology.IsEmbedding.inclusion (h : s ⊆ t) : IsEmbedding (inclusion h) := IsEmbedding.subtypeVal.codRestrict _ _ protected lemma Topology.IsOpenEmbedding.inclusion (hst : s ⊆ t) (hs : IsOpen (t ↓∩ s)) : IsOpenEmbedding (inclusion hst) where toIsEmbedding := .inclusion _ isOpen_range := by rwa [range_inclusion] protected lemma Topology.IsClosedEmbedding.inclusion (hst : s ⊆ t) (hs : IsClosed (t ↓∩ s)) : IsClosedEmbedding (inclusion hst) where toIsEmbedding := .inclusion _ isClosed_range := by rwa [range_inclusion] @[deprecated (since := "2024-10-26")] alias embedding_inclusion := IsEmbedding.inclusion /-- Let `s, t ⊆ X` be two subsets of a topological space `X`. If `t ⊆ s` and the topology induced by `X`on `s` is discrete, then also the topology induces on `t` is discrete. -/ theorem DiscreteTopology.of_subset {X : Type} [TopologicalSpace X] {s t : Set X} (_ : DiscreteTopology s) (ts : t ⊆ s) : DiscreteTopology t := (IsEmbedding.inclusion ts).discreteTopology /-- Let `s` be a discrete subset of a topological space. Then the preimage of `s` by a continuous injective map is also discrete. -/ theorem DiscreteTopology.preimage_of_continuous_injective {X Y : Type} [TopologicalSpace X] [TopologicalSpace Y] (s : Set Y) [DiscreteTopology s] {f : X → Y} (hc : Continuous f) (hinj : Function.Injective f) : DiscreteTopology (f ⁻¹' s) := DiscreteTopology.of_continuous_injective (β := s) (Continuous.restrict (by exact fun _ x ↦ x) hc) ((MapsTo.restrict_inj _).mpr hinj.injOn) /-- If `f : X → Y` is a quotient map, then its restriction to the preimage of an open set is a quotient map too. -/ theorem Topology.IsQuotientMap.restrictPreimage_isOpen {f : X → Y} (hf : IsQuotientMap f) {s : Set Y} (hs : IsOpen s) : IsQuotientMap (s.restrictPreimage f) := by refine isQuotientMap_iff.2 ⟨hf.surjective.restrictPreimage _, fun U ↦ ?_⟩ rw [hs.isOpenEmbedding_subtypeVal.isOpen_iff_image_isOpen, ← hf.isOpen_preimage, (hs.preimage hf.continuous).isOpenEmbedding_subtypeVal.isOpen_iff_image_isOpen, image_val_preimage_restrictPreimage] @[deprecated (since := "2024-10-22")] alias QuotientMap.restrictPreimage_isOpen := IsQuotientMap.restrictPreimage_isOpen open scoped Set.Notation in lemma isClosed_preimage_val {s t : Set X} : IsClosed (s ↓∩ t) ↔ s ∩ closure (s ∩ t) ⊆ t := by rw [← closure_eq_iff_isClosed, IsEmbedding.subtypeVal.closure_eq_preimage_closure_image, ← Subtype.val_injective.image_injective.eq_iff, Subtype.image_preimage_coe, Subtype.image_preimage_coe, subset_antisymm_iff, and_iff_left, Set.subset_inter_iff, and_iff_right] exacts [Set.inter_subset_left, Set.subset_inter Set.inter_subset_left subset_closure] theorem frontier_inter_open_inter {s t : Set X} (ht : IsOpen t) : frontier (s ∩ t) ∩ t = frontier s ∩ t := by simp only [Set.inter_comm _ t, ← Subtype.preimage_coe_eq_preimage_coe_iff, ht.isOpenMap_subtype_val.preimage_frontier_eq_frontier_preimage continuous_subtype_val, Subtype.preimage_coe_self_inter] section SetNotation open scoped Set.Notation lemma IsOpen.preimage_val {s t : Set X} (ht : IsOpen t) : IsOpen (s ↓∩ t) := ht.preimage continuous_subtype_val lemma IsClosed.preimage_val {s t : Set X} (ht : IsClosed t) : IsClosed (s ↓∩ t) := ht.preimage continuous_subtype_val @[simp] lemma IsOpen.inter_preimage_val_iff {s t : Set X} (hs : IsOpen s) : IsOpen (s ↓∩ t) ↔ IsOpen (s ∩ t) := ⟨fun h ↦ by simpa using hs.isOpenMap_subtype_val _ h, fun h ↦ (Subtype.preimage_coe_self_inter _ _).symm ▸ h.preimage_val⟩ @[simp] lemma IsClosed.inter_preimage_val_iff {s t : Set X} (hs : IsClosed s) : IsClosed (s ↓∩ t) ↔ IsClosed (s ∩ t) := ⟨fun h ↦ by simpa using hs.isClosedMap_subtype_val _ h, fun h ↦ (Subtype.preimage_coe_self_inter _ _).symm ▸ h.preimage_val⟩ end SetNotation end Subtype section Quotient variable [TopologicalSpace X] [TopologicalSpace Y] variable {r : X → X → Prop} {s : Setoid X} theorem isQuotientMap_quot_mk : IsQuotientMap (@Quot.mk X r) := ⟨Quot.exists_rep, rfl⟩ @[deprecated (since := "2024-10-22")] alias quotientMap_quot_mk := isQuotientMap_quot_mk @[continuity, fun_prop] theorem continuous_quot_mk : Continuous (@Quot.mk X r) := continuous_coinduced_rng @[continuity, fun_prop] theorem continuous_quot_lift {f : X → Y} (hr : ∀ a b, r a b → f a = f b) (h : Continuous f) : Continuous (Quot.lift f hr : Quot r → Y) := continuous_coinduced_dom.2 h theorem isQuotientMap_quotient_mk' : IsQuotientMap (@Quotient.mk' X s) := isQuotientMap_quot_mk @[deprecated (since := "2024-10-22")] alias quotientMap_quotient_mk' := isQuotientMap_quotient_mk' theorem continuous_quotient_mk' : Continuous (@Quotient.mk' X s) := continuous_coinduced_rng theorem Continuous.quotient_lift {f : X → Y} (h : Continuous f) (hs : ∀ a b, a ≈ b → f a = f b) : Continuous (Quotient.lift f hs : Quotient s → Y) := continuous_coinduced_dom.2 h theorem Continuous.quotient_liftOn' {f : X → Y} (h : Continuous f) (hs : ∀ a b, s a b → f a = f b) : Continuous (fun x => Quotient.liftOn' x f hs : Quotient s → Y) := h.quotient_lift hs open scoped Relator in @[continuity, fun_prop] theorem Continuous.quotient_map' {t : Setoid Y} {f : X → Y} (hf : Continuous f) (H : (s.r ⇒ t.r) f f) : Continuous (Quotient.map' f H) := (continuous_quotient_mk'.comp hf).quotient_lift _ end Quotient section Pi variable {ι : Type} {π : ι → Type} {κ : Type} [TopologicalSpace X] [T : ∀ i, TopologicalSpace (π i)] {f : X → ∀ i : ι, π i} theorem continuous_pi_iff : Continuous f ↔ ∀ i, Continuous fun a => f a i := by simp only [continuous_iInf_rng, continuous_induced_rng, comp_def] @[continuity, fun_prop] theorem continuous_pi (h : ∀ i, Continuous fun a => f a i) : Continuous f := continuous_pi_iff.2 h @[continuity, fun_prop] theorem continuous_apply (i : ι) : Continuous fun p : ∀ i, π i => p i := continuous_iInf_dom continuous_induced_dom @[continuity] theorem continuous_apply_apply {ρ : κ → ι → Type} [∀ j i, TopologicalSpace (ρ j i)] (j : κ) (i : ι) : Continuous fun p : ∀ j, ∀ i, ρ j i => p j i := (continuous_apply i).comp (continuous_apply j) theorem continuousAt_apply (i : ι) (x : ∀ i, π i) : ContinuousAt (fun p : ∀ i, π i => p i) x := (continuous_apply i).continuousAt theorem Filter.Tendsto.apply_nhds {l : Filter Y} {f : Y → ∀ i, π i} {x : ∀ i, π i} (h : Tendsto f l (𝓝 x)) (i : ι) : Tendsto (fun a => f a i) l (𝓝 <\| x i) := (continuousAt_apply i _).tendsto.comp h @[fun_prop] protected theorem Continuous.piMap {Y : ι → Type} [∀ i, TopologicalSpace (Y i)] {f : ∀ i, π i → Y i} (hf : ∀ i, Continuous (f i)) : Continuous (Pi.map f) := continuous_pi fun i ↦ (hf i).comp (continuous_apply i) theorem nhds_pi {a : ∀ i, π i} : 𝓝 a = pi fun i => 𝓝 (a i) := by simp only [nhds_iInf, nhds_induced, Filter.pi] protected theorem IsOpenMap.piMap {Y : ι → Type} [∀ i, TopologicalSpace (Y i)] {f : ∀ i, π i → Y i} (hfo : ∀ i, IsOpenMap (f i)) (hsurj : ∀ᶠ i in cofinite, Surjective (f i)) : IsOpenMap (Pi.map f) := by refine IsOpenMap.of_nhds_le fun x ↦ ?_ rw [nhds_pi, nhds_pi, map_piMap_pi hsurj] exact Filter.pi_mono fun i ↦ (hfo i).nhds_le _ protected theorem IsOpenQuotientMap.piMap {Y : ι → Type} [∀ i, TopologicalSpace (Y i)] {f : ∀ i, π i → Y i} (hf : ∀ i, IsOpenQuotientMap (f i)) : IsOpenQuotientMap (Pi.map f) := ⟨.piMap fun i ↦ (hf i).1, .piMap fun i ↦ (hf i).2, .piMap (fun i ↦ (hf i).3) <\| .of_forall fun i ↦ (hf i).1⟩ theorem tendsto_pi_nhds {f : Y → ∀ i, π i} {g : ∀ i, π i} {u : Filter Y} : Tendsto f u (𝓝 g) ↔ ∀ x, Tendsto (fun i => f i x) u (𝓝 (g x)) := by rw [nhds_pi, Filter.tendsto_pi] theorem continuousAt_pi {f : X → ∀ i, π i} {x : X} : ContinuousAt f x ↔ ∀ i, ContinuousAt (fun y => f y i) x := tendsto_pi_nhds @[fun_prop] theorem continuousAt_pi' {f : X → ∀ i, π i} {x : X} (hf : ∀ i, ContinuousAt (fun y => f y i) x) : ContinuousAt f x := continuousAt_pi.2 hf @[fun_prop] protected theorem ContinuousAt.piMap {Y : ι → Type} [∀ i, TopologicalSpace (Y i)] {f : ∀ i, π i → Y i} {x : ∀ i, π i} (hf : ∀ i, ContinuousAt (f i) (x i)) : ContinuousAt (Pi.map f) x := continuousAt_pi.2 fun i ↦ (hf i).comp (continuousAt_apply i x) theorem Pi.continuous_precomp' {ι' : Type} (φ : ι' → ι) : Continuous (fun (f : (∀ i, π i)) (j : ι') ↦ f (φ j)) := continuous_pi fun j ↦ continuous_apply (φ j) theorem Pi.continuous_precomp {ι' : Type} (φ : ι' → ι) : Continuous (· ∘ φ : (ι → X) → (ι' → X)) := Pi.continuous_precomp' φ theorem Pi.continuous_postcomp' {X : ι → Type} [∀ i, TopologicalSpace (X i)] {g : ∀ i, π i → X i} (hg : ∀ i, Continuous (g i)) : Continuous (fun (f : (∀ i, π i)) (i : ι) ↦ g i (f i)) := continuous_pi fun i ↦ (hg i).comp <\| continuous_apply i theorem Pi.continuous_postcomp [TopologicalSpace Y] {g : X → Y} (hg : Continuous g) : Continuous (g ∘ · : (ι → X) → (ι → Y)) := Pi.continuous_postcomp' fun _ ↦ hg lemma Pi.induced_precomp' {ι' : Type} (φ : ι' → ι) : induced (fun (f : (∀ i, π i)) (j : ι') ↦ f (φ j)) Pi.topologicalSpace = ⨅ i', induced (eval (φ i')) (T (φ i')) := by simp [Pi.topologicalSpace, induced_iInf, induced_compose, comp_def] lemma Pi.induced_precomp [TopologicalSpace Y] {ι' : Type} (φ : ι' → ι) : induced (· ∘ φ) Pi.topologicalSpace = ⨅ i', induced (eval (φ i')) ‹TopologicalSpace Y› := induced_precomp' φ @[continuity, fun_prop] lemma Pi.continuous_restrict (S : Set ι) : Continuous (S.restrict : (∀ i : ι, π i) → (∀ i : S, π i)) := Pi.continuous_precomp' ((↑) : S → ι) @[continuity, fun_prop] lemma Pi.continuous_restrict₂ {s t : Set ι} (hst : s ⊆ t) : Continuous (restrict₂ (π := π) hst) := continuous_pi fun _ ↦ continuous_apply _ @[continuity, fun_prop] theorem Finset.continuous_restrict (s : Finset ι) : Continuous (s.restrict (π := π)) := continuous_pi fun _ ↦ continuous_apply _ @[continuity, fun_prop] theorem Finset.continuous_restrict₂ {s t : Finset ι} (hst : s ⊆ t) : Continuous (Finset.restrict₂ (π := π) hst) := continuous_pi fun _ ↦ continuous_apply _ variable [TopologicalSpace Z] @[continuity, fun_prop] theorem Pi.continuous_restrict_apply (s : Set X) {f : X → Z} (hf : Continuous f) : Continuous (s.restrict f) := hf.comp continuous_subtype_val @[continuity, fun_prop] theorem Pi.continuous_restrict₂_apply {s t : Set X} (hst : s ⊆ t) {f : t → Z} (hf : Continuous f) : Continuous (restrict₂ (π := fun _ ↦ Z) hst f) := hf.comp (continuous_inclusion hst) @[continuity, fun_prop] theorem Finset.continuous_restrict_apply (s : Finset X) {f : X → Z} (hf : Continuous f) : Continuous (s.restrict f) := hf.comp continuous_subtype_val @[continuity, fun_prop] theorem Finset.continuous_restrict₂_apply {s t : Finset X} (hst : s ⊆ t) {f : t → Z} (hf : Continuous f) : Continuous (restrict₂ (π := fun _ ↦ Z) hst f) := hf.comp (continuous_inclusion hst) lemma Pi.induced_restrict (S : Set ι) : induced (S.restrict) Pi.topologicalSpace = ⨅ i ∈ S, induced (eval i) (T i) := by simp +unfoldPartialApp [← iInf_subtype'', ← induced_precomp' ((↑) : S → ι), restrict] lemma Pi.induced_restrict_sUnion (𝔖 : Set (Set ι)) : induced (⋃₀ 𝔖).restrict (Pi.topologicalSpace (Y := fun i : (⋃₀ 𝔖) ↦ π i)) = ⨅ S ∈ 𝔖, induced S.restrict Pi.topologicalSpace := by simp_rw [Pi.induced_restrict, iInf_sUnion] theorem Filter.Tendsto.update [DecidableEq ι] {l : Filter Y} {f : Y → ∀ i, π i} {x : ∀ i, π i} (hf : Tendsto f l (𝓝 x)) (i : ι) {g : Y → π i} {xi : π i} (hg : Tendsto g l (𝓝 xi)) : Tendsto (fun a => update (f a) i (g a)) l (𝓝 <\| update x i xi) := tendsto_pi_nhds.2 fun j => by rcases eq_or_ne j i with (rfl \| hj) <;> simp [, hf.apply_nhds] theorem ContinuousAt.update [DecidableEq ι] {x : X} (hf : ContinuousAt f x) (i : ι) {g : X → π i} (hg : ContinuousAt g x) : ContinuousAt (fun a => update (f a) i (g a)) x := hf.tendsto.update i hg theorem Continuous.update [DecidableEq ι] (hf : Continuous f) (i : ι) {g : X → π i} (hg : Continuous g) : Continuous fun a => update (f a) i (g a) := continuous_iff_continuousAt.2 fun _ => hf.continuousAt.update i hg.continuousAt /-- `Function.update f i x` is continuous in `(f, x)`. -/ @[continuity, fun_prop] theorem continuous_update [DecidableEq ι] (i : ι) : Continuous fun f : (∀ j, π j) × π i => update f.1 i f.2 := continuous_fst.update i continuous_snd /-- `Pi.mulSingle i x` is continuous in `x`. -/ @[to_additive (attr := continuity) "`Pi.single i x` is continuous in `x`."] theorem continuous_mulSingle [∀ i, One (π i)] [DecidableEq ι] (i : ι) : Continuous fun x => (Pi.mulSingle i x : ∀ i, π i) := continuous_const.update _ continuous_id section Fin variable {n : ℕ} {π : Fin (n + 1) → Type} [∀ i, TopologicalSpace (π i)] theorem Filter.Tendsto.finCons {f : Y → π 0} {g : Y → ∀ j : Fin n, π j.succ} {l : Filter Y} {x : π 0} {y : ∀ j, π (Fin.succ j)} (hf : Tendsto f l (𝓝 x)) (hg : Tendsto g l (𝓝 y)) : Tendsto (fun a => Fin.cons (f a) (g a)) l (𝓝 <\| Fin.cons x y) := tendsto_pi_nhds.2 fun j => Fin.cases (by simpa) (by simpa using tendsto_pi_nhds.1 hg) j theorem ContinuousAt.finCons {f : X → π 0} {g : X → ∀ j : Fin n, π (Fin.succ j)} {x : X} (hf : ContinuousAt f x) (hg : ContinuousAt g x) : ContinuousAt (fun a => Fin.cons (f a) (g a)) x := hf.tendsto.finCons hg theorem Continuous.finCons {f : X → π 0} {g : X → ∀ j : Fin n, π (Fin.succ j)} (hf : Continuous f) (hg : Continuous g) : Continuous fun a => Fin.cons (f a) (g a) := continuous_iff_continuousAt.2 fun _ => hf.continuousAt.finCons hg.continuousAt theorem Filter.Tendsto.matrixVecCons {f : Y → Z} {g : Y → Fin n → Z} {l : Filter Y} {x : Z} {y : Fin n → Z} (hf : Tendsto f l (𝓝 x)) (hg : Tendsto g l (𝓝 y)) : Tendsto (fun a => Matrix.vecCons (f a) (g a)) l (𝓝 <\| Matrix.vecCons x y) := hf.finCons hg theorem ContinuousAt.matrixVecCons {f : X → Z} {g : X → Fin n → Z} {x : X} (hf : ContinuousAt f x) (hg : ContinuousAt g x) : ContinuousAt (fun a => Matrix.vecCons (f a) (g a)) x := hf.finCons hg theorem Continuous.matrixVecCons {f : X → Z} {g : X → Fin n → Z} (hf : Continuous f) (hg : Continuous g) : Continuous fun a => Matrix.vecCons (f a) (g a) := hf.finCons hg theorem Filter.Tendsto.finSnoc {f : Y → ∀ j : Fin n, π j.castSucc} {g : Y → π (Fin.last _)} {l : Filter Y} {x : ∀ j, π (Fin.castSucc j)} {y : π (Fin.last _)} (hf : Tendsto f l (𝓝 x)) (hg : Tendsto g l (𝓝 y)) : Tendsto (fun a => Fin.snoc (f a) (g a)) l (𝓝 <\| Fin.snoc x y) := tendsto_pi_nhds.2 fun j => Fin.lastCases (by simpa) (by simpa using tendsto_pi_nhds.1 hf) j theorem ContinuousAt.finSnoc {f : X → ∀ j : Fin n, π j.castSucc} {g : X → π (Fin.last _)} {x : X} (hf : ContinuousAt f x) (hg : ContinuousAt g x) : ContinuousAt (fun a => Fin.snoc (f a) (g a)) x := hf.tendsto.finSnoc hg theorem Continuous.finSnoc {f : X → ∀ j : Fin n, π j.castSucc} {g : X → π (Fin.last _)} (hf : Continuous f) (hg : Continuous g) : Continuous fun a => Fin.snoc (f a) (g a) := continuous_iff_continuousAt.2 fun _ => hf.continuousAt.finSnoc hg.continuousAt theorem Filter.Tendsto.finInsertNth (i : Fin (n + 1)) {f : Y → π i} {g : Y → ∀ j : Fin n, π (i.succAbove j)} {l : Filter Y} {x : π i} {y : ∀ j, π (i.succAbove j)} (hf : Tendsto f l (𝓝 x)) (hg : Tendsto g l (𝓝 y)) : Tendsto (fun a => i.insertNth (f a) (g a)) l (𝓝 <\| i.insertNth x y) := tendsto_pi_nhds.2 fun j => Fin.succAboveCases i (by simpa) (by simpa using tendsto_pi_nhds.1 hg) j @[deprecated (since := "2025-01-02")] alias Filter.Tendsto.fin_insertNth := Filter.Tendsto.finInsertNth theorem ContinuousAt.finInsertNth (i : Fin (n + 1)) {f : X → π i} {g : X → ∀ j : Fin n, π (i.succAbove j)} {x : X} (hf : ContinuousAt f x) (hg : ContinuousAt g x) : ContinuousAt (fun a => i.insertNth (f a) (g a)) x := hf.tendsto.finInsertNth i hg @[deprecated (since := "2025-01-02")] alias ContinuousAt.fin_insertNth := ContinuousAt.finInsertNth theorem Continuous.finInsertNth (i : Fin (n + 1)) {f : X → π i} {g : X → ∀ j : Fin n, π (i.succAbove j)} (hf : Continuous f) (hg : Continuous g) : Continuous fun a => i.insertNth (f a) (g a) := continuous_iff_continuousAt.2 fun _ => hf.continuousAt.finInsertNth i hg.continuousAt @[deprecated (since := "2025-01-02")] alias Continuous.fin_insertNth := Continuous.finInsertNth theorem Filter.Tendsto.finInit {f : Y → ∀ j : Fin (n + 1), π j} {l : Filter Y} {x : ∀ j, π j} (hg : Tendsto f l (𝓝 x)) : Tendsto (fun a ↦ Fin.init (f a)) l (𝓝 <\| Fin.init x) := tendsto_pi_nhds.2 fun j ↦ apply_nhds hg j.castSucc @[fun_prop] theorem ContinuousAt.finInit {f : X → ∀ j : Fin (n + 1), π j} {x : X} (hf : ContinuousAt f x) : ContinuousAt (fun a ↦ Fin.init (f a)) x := hf.tendsto.finInit @[fun_prop] theorem Continuous.finInit {f : X → ∀ j : Fin (n + 1), π j} (hf : Continuous f) : Continuous fun a ↦ Fin.init (f a) := continuous_iff_continuousAt.2 fun _ ↦ hf.continuousAt.finInit theorem Filter.Tendsto.finTail {f : Y → ∀ j : Fin (n + 1), π j} {l : Filter Y} {x : ∀ j, π j} (hg : Tendsto f l (𝓝 x)) : Tendsto (fun a ↦ Fin.tail (f a)) l (𝓝 <\| Fin.tail x) := tendsto_pi_nhds.2 fun j ↦ apply_nhds hg j.succ @[fun_prop] theorem ContinuousAt.finTail {f : X → ∀ j : Fin (n + 1), π j} {x : X} (hf : ContinuousAt f x) : ContinuousAt (fun a ↦ Fin.tail (f a)) x := hf.tendsto.finTail @[fun_prop] theorem Continuous.finTail {f : X → ∀ j : Fin (n + 1), π j} (hf : Continuous f) : Continuous fun a ↦ Fin.tail (f a) := continuous_iff_continuousAt.2 fun _ ↦ hf.continuousAt.finTail end Fin theorem isOpen_set_pi {i : Set ι} {s : ∀ a, Set (π a)} (hi : i.Finite) (hs : ∀ a ∈ i, IsOpen (s a)) : IsOpen (pi i s) := by rw [pi_def]; exact hi.isOpen_biInter fun a ha => (hs _ ha).preimage (continuous_apply _) theorem isOpen_pi_iff {s : Set (∀ a, π a)} : IsOpen s ↔ ∀ f, f ∈ s → ∃ (I : Finset ι) (u : ∀ a, Set (π a)), (∀ a, a ∈ I → IsOpen (u a) ∧ f a ∈ u a) ∧ (I : Set ι).pi u ⊆ s := by rw [isOpen_iff_nhds] simp_rw [le_principal_iff, nhds_pi, Filter.mem_pi', mem_nhds_iff] refine forall₂_congr fun a _ => ⟨?_, ?_⟩ · rintro ⟨I, t, ⟨h1, h2⟩⟩ refine ⟨I, fun a => eval a '' (I : Set ι).pi fun a => (h1 a).choose, fun i hi => ?_, ?_⟩ · simp_rw [eval_image_pi (Finset.mem_coe.mpr hi) (pi_nonempty_iff.mpr fun i => ⟨_, fun _ => (h1 i).choose_spec.2.2⟩)] exact (h1 i).choose_spec.2 · exact Subset.trans (pi_mono fun i hi => (eval_image_pi_subset hi).trans (h1 i).choose_spec.1) h2 · rintro ⟨I, t, ⟨h1, h2⟩⟩ classical refine ⟨I, fun a => ite (a ∈ I) (t a) univ, fun i => ?_, ?_⟩ · by_cases hi : i ∈ I · use t i simp_rw [if_pos hi] exact ⟨Subset.rfl, (h1 i) hi⟩ · use univ simp_rw [if_neg hi] exact ⟨Subset.rfl, isOpen_univ, mem_univ _⟩ · rw [← univ_pi_ite] simp only [← ite_and, ← Finset.mem_coe, and_self_iff, univ_pi_ite, h2] theorem isOpen_pi_iff' [Finite ι] {s : Set (∀ a, π a)} : IsOpen s ↔ ∀ f, f ∈ s → ∃ u : ∀ a, Set (π a), (∀ a, IsOpen (u a) ∧ f a ∈ u a) ∧ univ.pi u ⊆ s := by cases nonempty_fintype ι rw [isOpen_iff_nhds] simp_rw [le_principal_iff, nhds_pi, Filter.mem_pi', mem_nhds_iff] refine forall₂_congr fun a _ => ⟨?_, ?_⟩ · rintro ⟨I, t, ⟨h1, h2⟩⟩ refine ⟨fun i => (h1 i).choose, ⟨fun i => (h1 i).choose_spec.2, (pi_mono fun i _ => (h1 i).choose_spec.1).trans (Subset.trans ?_ h2)⟩⟩ rw [← pi_inter_compl (I : Set ι)] exact inter_subset_left · exact fun ⟨u, ⟨h1, _⟩⟩ => ⟨Finset.univ, u, ⟨fun i => ⟨u i, ⟨rfl.subset, h1 i⟩⟩, by rwa [Finset.coe_univ]⟩⟩ theorem isClosed_set_pi {i : Set ι} {s : ∀ a, Set (π a)} (hs : ∀ a ∈ i, IsClosed (s a)) : IsClosed (pi i s) := by rw [pi_def]; exact isClosed_biInter fun a ha => (hs _ ha).preimage (continuous_apply _) theorem mem_nhds_of_pi_mem_nhds {I : Set ι} {s : ∀ i, Set (π i)} (a : ∀ i, π i) (hs : I.pi s ∈ 𝓝 a) {i : ι} (hi : i ∈ I) : s i ∈ 𝓝 (a i) := by rw [nhds_pi] at hs; exact mem_of_pi_mem_pi hs hi theorem set_pi_mem_nhds {i : Set ι} {s : ∀ a, Set (π a)} {x : ∀ a, π a} (hi : i.Finite) (hs : ∀ a ∈ i, s a ∈ 𝓝 (x a)) : pi i s ∈ 𝓝 x := by rw [pi_def, biInter_mem hi] exact fun a ha => (continuous_apply a).continuousAt (hs a ha) theorem set_pi_mem_nhds_iff {I : Set ι} (hI : I.Finite) {s : ∀ i, Set (π i)} (a : ∀ i, π i) : I.pi s ∈ 𝓝 a ↔ ∀ i : ι, i ∈ I → s i ∈ 𝓝 (a i) := by rw [nhds_pi, pi_mem_pi_iff hI] theorem interior_pi_set {I : Set ι} (hI : I.Finite) {s : ∀ i, Set (π i)} : interior (pi I s) = I.pi fun i => interior (s i) := by ext a simp only [Set.mem_pi, mem_interior_iff_mem_nhds, set_pi_mem_nhds_iff hI] theorem exists_finset_piecewise_mem_of_mem_nhds [DecidableEq ι] {s : Set (∀ a, π a)} {x : ∀ a, π a} (hs : s ∈ 𝓝 x) (y : ∀ a, π a) : ∃ I : Finset ι, I.piecewise x y ∈ s := by simp only [nhds_pi, Filter.mem_pi'] at hs rcases hs with ⟨I, t, htx, hts⟩ refine ⟨I, hts fun i hi => ?_⟩ simpa [Finset.mem_coe.1 hi] using mem_of_mem_nhds (htx i) theorem pi_generateFrom_eq {π : ι → Type} {g : ∀ a, Set (Set (π a))} : (@Pi.topologicalSpace ι π fun a => generateFrom (g a)) = generateFrom { t \| ∃ (s : ∀ a, Set (π a)) (i : Finset ι), (∀ a ∈ i, s a ∈ g a) ∧ t = pi (↑i) s } := by refine le_antisymm ?_ ?_ · apply le_generateFrom rintro _ ⟨s, i, hi, rfl⟩ letI := fun a => generateFrom (g a) exact isOpen_set_pi i.finite_toSet (fun a ha => GenerateOpen.basic _ (hi a ha)) · classical refine le_iInf fun i => coinduced_le_iff_le_induced.1 <\| le_generateFrom fun s hs => ?_ refine GenerateOpen.basic _ ⟨update (fun i => univ) i s, {i}, ?_⟩ simp [hs] theorem pi_eq_generateFrom : Pi.topologicalSpace = generateFrom { g \| ∃ (s : ∀ a, Set (π a)) (i : Finset ι), (∀ a ∈ i, IsOpen (s a)) ∧ g = pi (↑i) s } := calc Pi.topologicalSpace _ = @Pi.topologicalSpace ι π fun _ => generateFrom { s \| IsOpen s } := by simp only [generateFrom_setOf_isOpen] _ = _ := pi_generateFrom_eq theorem pi_generateFrom_eq_finite {π : ι → Type} {g : ∀ a, Set (Set (π a))} [Finite ι] (hg : ∀ a, ⋃₀ g a = univ) : (@Pi.topologicalSpace ι π fun a => generateFrom (g a)) = generateFrom { t \| ∃ s : ∀ a, Set (π a), (∀ a, s a ∈ g a) ∧ t = pi univ s } := by cases nonempty_fintype ι rw [pi_generateFrom_eq] refine le_antisymm (generateFrom_anti ?_) (le_generateFrom ?_) · exact fun s ⟨t, ht, Eq⟩ => ⟨t, Finset.univ, by simp [ht, Eq]⟩ · rintro s ⟨t, i, ht, rfl⟩ letI := generateFrom { t \| ∃ s : ∀ a, Set (π a), (∀ a, s a ∈ g a) ∧ t = pi univ s } refine isOpen_iff_forall_mem_open.2 fun f hf => ?_ choose c hcg hfc using fun a => sUnion_eq_univ_iff.1 (hg a) (f a) refine ⟨pi i t ∩ pi ((↑i)ᶜ : Set ι) c, inter_subset_left, ?_, ⟨hf, fun a _ => hfc a⟩⟩ classical rw [← univ_pi_piecewise] refine GenerateOpen.basic _ ⟨_, fun a => ?_, rfl⟩ by_cases a ∈ i <;> simp [] theorem induced_to_pi {X : Type} (f : X → ∀ i, π i) : induced f Pi.topologicalSpace = ⨅ i, induced (f · i) inferInstance := by simp_rw [Pi.topologicalSpace, induced_iInf, induced_compose, Function.comp_def] /-- Suppose `π i` is a family of topological spaces indexed by `i : ι`, and `X` is a type endowed with a family of maps `f i : X → π i` for every `i : ι`, hence inducing a map `g : X → Π i, π i`. This lemma shows that infimum of the topologies on `X` induced by the `f i` as `i : ι` varies is simply the topology on `X` induced by `g : X → Π i, π i` where `Π i, π i` is endowed with the usual product topology. -/ theorem inducing_iInf_to_pi {X : Type} (f : ∀ i, X → π i) : @IsInducing X (∀ i, π i) (⨅ i, induced (f i) inferInstance) _ fun x i => f i x := letI := ⨅ i, induced (f i) inferInstance; ⟨(induced_to_pi _).symm⟩ variable [Finite ι] [∀ i, DiscreteTopology (π i)] /-- A finite product of discrete spaces is discrete. -/ instance Pi.discreteTopology : DiscreteTopology (∀ i, π i) := singletons_open_iff_discrete.mp fun x => by rw [← univ_pi_singleton] exact isOpen_set_pi finite_univ fun i _ => (isOpen_discrete {x i}) end Pi section Sigma variable {ι κ : Type} {σ : ι → Type} {τ : κ → Type*} [∀ i, TopologicalSpace (σ i)] [∀ k, TopologicalSpace (τ k)] [TopologicalSpace X] @[continuity, fun_prop] theorem continuous_sigmaMk {i : ι} : Continuous (@Sigma.mk ι σ i) := continuous_iSup_rng continuous_coinduced_rng theorem isOpen_sigma_iff {s : Set (Sigma σ)} : IsOpen s ↔ ∀ i, IsOpen (Sigma.mk i ⁻¹' s) := by rw [isOpen_iSup_iff] rfl theorem isClosed_sigma_iff {s : Set (Sigma σ)} : IsClosed s ↔ ∀ i, IsClosed (Sigma.mk i ⁻¹' s) := by simp only [← isOpen_compl_iff, isOpen_sigma_iff, preimage_compl] theorem isOpenMap_sigmaMk {i : ι} : IsOpenMap (@Sigma.mk ι σ i) := by intro s hs rw [isOpen_sigma_iff] intro j rcases eq_or_ne j i with (rfl \| hne) · rwa [preimage_image_eq _ sigma_mk_injective] · rw [preimage_image_sigmaMk_of_ne hne] exact isOpen_empty theorem isOpen_range_sigmaMk {i : ι} : IsOpen (range (@Sigma.mk ι σ i)) := isOpenMap_sigmaMk.isOpen_range theorem isClosedMap_sigmaMk {i : ι} : IsClosedMap (@Sigma.mk ι σ i) := by intro s hs rw [isClosed_sigma_iff] intro j rcases eq_or_ne j i with (rfl \| hne) · rwa [preimage_image_eq _ sigma_mk_injective] · rw [preimage_image_sigmaMk_of_ne hne] exact isClosed_empty theorem isClosed_range_sigmaMk {i : ι} : IsClosed (range (@Sigma.mk ι σ i)) := isClosedMap_sigmaMk.isClosed_range lemma Topology.IsOpenEmbedding.sigmaMk {i : ι} : IsOpenEmbedding (@Sigma.mk ι σ i) := .of_continuous_injective_isOpenMap continuous_sigmaMk sigma_mk_injective isOpenMap_sigmaMk @[deprecated (since := "2024-10-30")] alias isOpenEmbedding_sigmaMk := IsOpenEmbedding.sigmaMk lemma Topology.IsClosedEmbedding.sigmaMk {i : ι} : IsClosedEmbedding (@Sigma.mk ι σ i) := .of_continuous_injective_isClosedMap continuous_sigmaMk sigma_mk_injective isClosedMap_sigmaMk @[deprecated (since := "2024-10-30")] alias isClosedEmbedding_sigmaMk := IsClosedEmbedding.sigmaMk lemma Topology.IsEmbedding.sigmaMk {i : ι} : IsEmbedding (@Sigma.mk ι σ i) := IsClosedEmbedding.sigmaMk.1 @[deprecated (since := "2024-10-26")] alias embedding_sigmaMk := IsEmbedding.sigmaMk theorem Sigma.nhds_mk (i : ι) (x : σ i) : 𝓝 (⟨i, x⟩ : Sigma σ) = Filter.map (Sigma.mk i) (𝓝 x) := (IsOpenEmbedding.sigmaMk.map_nhds_eq x).symm theorem Sigma.nhds_eq (x : Sigma σ) : 𝓝 x = Filter.map (Sigma.mk x.1) (𝓝 x.2) := by cases x apply Sigma.nhds_mk theorem comap_sigmaMk_nhds (i : ι) (x : σ i) : comap (Sigma.mk i) (𝓝 ⟨i, x⟩) = 𝓝 x := (IsEmbedding.sigmaMk.nhds_eq_comap _).symm theorem isOpen_sigma_fst_preimage (s : Set ι) : IsOpen (Sigma.fst ⁻¹' s : Set (Σ a, σ a)) := by rw [← biUnion_of_singleton s, preimage_iUnion₂] simp only [← range_sigmaMk] exact isOpen_biUnion fun _ _ => isOpen_range_sigmaMk /-- A map out of a sum type is continuous iff its restriction to each summand is. -/ @[simp] theorem continuous_sigma_iff {f : Sigma σ → X} : Continuous f ↔ ∀ i, Continuous fun a => f ⟨i, a⟩ := by delta instTopologicalSpaceSigma rw [continuous_iSup_dom] exact forall_congr' fun _ => continuous_coinduced_dom /-- A map out of a sum type is continuous if its restriction to each summand is. -/ @[continuity, fun_prop] theorem continuous_sigma {f : Sigma σ → X} (hf : ∀ i, Continuous fun a => f ⟨i, a⟩) : Continuous f := continuous_sigma_iff.2 hf /-- A map defined on a sigma type (a.k.a. the disjoint union of an indexed family of topological spaces) is inducing iff its restriction to each component is inducing and each the image of each component under `f` can be separated from the images of all other components by an open set. -/ theorem inducing_sigma {f : Sigma σ → X} : IsInducing f ↔ (∀ i, IsInducing (f ∘ Sigma.mk i)) ∧ (∀ i, ∃ U, IsOpen U ∧ ∀ x, f x ∈ U ↔ x.1 = i) := by refine ⟨fun h ↦ ⟨fun i ↦ h.comp IsEmbedding.sigmaMk.1, fun i ↦ ?_⟩, ?_⟩ · rcases h.isOpen_iff.1 (isOpen_range_sigmaMk (i := i)) with ⟨U, hUo, hU⟩ refine ⟨U, hUo, ?_⟩ simpa [Set.ext_iff] using hU · refine fun ⟨h₁, h₂⟩ ↦ isInducing_iff_nhds.2 fun ⟨i, x⟩ ↦ ?_ rw [Sigma.nhds_mk, (h₁ i).nhds_eq_comap, comp_apply, ← comap_comap, map_comap_of_mem] rcases h₂ i with ⟨U, hUo, hU⟩ filter_upwards [preimage_mem_comap <\| hUo.mem_nhds <\| (hU _).2 rfl] with y hy simpa [hU] using hy @[simp 1100] theorem continuous_sigma_map {f₁ : ι → κ} {f₂ : ∀ i, σ i → τ (f₁ i)} : Continuous (Sigma.map f₁ f₂) ↔ ∀ i, Continuous (f₂ i) := continuous_sigma_iff.trans <\| by simp only [Sigma.map, IsEmbedding.sigmaMk.continuous_iff, comp_def] @[continuity, fun_prop] theorem Continuous.sigma_map {f₁ : ι → κ} {f₂ : ∀ i, σ i → τ (f₁ i)} (hf : ∀ i, Continuous (f₂ i)) : Continuous (Sigma.map f₁ f₂) := continuous_sigma_map.2 hf theorem isOpenMap_sigma {f : Sigma σ → X} : IsOpenMap f ↔ ∀ i, IsOpenMap fun a => f ⟨i, a⟩ := by simp only [isOpenMap_iff_nhds_le, Sigma.forall, Sigma.nhds_eq, map_map, comp_def] theorem isOpenMap_sigma_map {f₁ : ι → κ} {f₂ : ∀ i, σ i → τ (f₁ i)} : IsOpenMap (Sigma.map f₁ f₂) ↔ ∀ i, IsOpenMap (f₂ i) := isOpenMap_sigma.trans <\| forall_congr' fun i => (@IsOpenEmbedding.sigmaMk _ _ _ (f₁ i)).isOpenMap_iff.symm lemma Topology.isInducing_sigmaMap {f₁ : ι → κ} {f₂ : ∀ i, σ i → τ (f₁ i)} (h₁ : Injective f₁) : IsInducing (Sigma.map f₁ f₂) ↔ ∀ i, IsInducing (f₂ i) := by simp only [isInducing_iff_nhds, Sigma.forall, Sigma.nhds_mk, Sigma.map_mk, ← map_sigma_mk_comap h₁, map_inj sigma_mk_injective] @[deprecated (since := "2024-10-28")] alias inducing_sigma_map := isInducing_sigmaMap lemma Topology.isEmbedding_sigmaMap {f₁ : ι → κ} {f₂ : ∀ i, σ i → τ (f₁ i)} (h : Injective f₁) : IsEmbedding (Sigma.map f₁ f₂) ↔ ∀ i, IsEmbedding (f₂ i) := by simp only [isEmbedding_iff, Injective.sigma_map, isInducing_sigmaMap h, forall_and, h.sigma_map_iff] @[deprecated (since := "2024-10-26")] alias embedding_sigma_map := isEmbedding_sigmaMap lemma Topology.isOpenEmbedding_sigmaMap {f₁ : ι → κ} {f₂ : ∀ i, σ i → τ (f₁ i)} (h : Injective f₁) : IsOpenEmbedding (Sigma.map f₁ f₂) ↔ ∀ i, IsOpenEmbedding (f₂ i) := by simp only [isOpenEmbedding_iff_isEmbedding_isOpenMap, isOpenMap_sigma_map, isEmbedding_sigmaMap h, forall_and] @[deprecated (since := "2024-10-30")] alias isOpenEmbedding_sigma_map := isOpenEmbedding_sigmaMap end Sigma section ULift theorem ULift.isOpen_iff [TopologicalSpace X] {s : Set (ULift.{v} X)} : IsOpen s ↔ IsOpen (ULift.up ⁻¹' s) := by rw [ULift.topologicalSpace, ← Equiv.ulift_apply, ← Equiv.ulift.coinduced_symm, ← isOpen_coinduced] theorem ULift.isClosed_iff [TopologicalSpace X] {s : Set (ULift.{v} X)} : IsClosed s ↔ IsClosed (ULift.up ⁻¹' s) := by rw [← isOpen_compl_iff, ← isOpen_compl_iff, isOpen_iff, preimage_compl] @[continuity, fun_prop] theorem continuous_uliftDown [TopologicalSpace X] : Continuous (ULift.down : ULift.{v, u} X → X) := continuous_induced_dom @[continuity, fun_prop] theorem continuous_uliftUp [TopologicalSpace X] : Continuous (ULift.up : X → ULift.{v, u} X) := continuous_induced_rng.2 continuous_id @[deprecated (since := "2025-02-10")] alias continuous_uLift_down := continuous_uliftDown @[deprecated (since := "2025-02-10")] alias continuous_uLift_up := continuous_uliftUp @[continuity, fun_prop] theorem continuous_uliftMap [TopologicalSpace X] [TopologicalSpace Y] (f : X → Y) (hf : Continuous f) : Continuous (ULift.map f : ULift.{u'} X → ULift.{v'} Y) := by change Continuous (ULift.up ∘ f ∘ ULift.down) fun_prop lemma Topology.IsEmbedding.uliftDown [TopologicalSpace X] : IsEmbedding (ULift.down : ULift.{v, u} X → X) := ⟨⟨rfl⟩, ULift.down_injective⟩ @[deprecated (since := "2024-10-26")] alias embedding_uLift_down := IsEmbedding.uliftDown lemma Topology.IsClosedEmbedding.uliftDown [TopologicalSpace X] : IsClosedEmbedding (ULift.down : ULift.{v, u} X → X) := ⟨.uliftDown, by simp only [ULift.down_surjective.range_eq, isClosed_univ]⟩ @[deprecated (since := "2024-10-30")] alias ULift.isClosedEmbedding_down := IsClosedEmbedding.uliftDown instance [TopologicalSpace X] [DiscreteTopology X] : DiscreteTopology (ULift X) := IsEmbedding.uliftDown.discreteTopology end ULift section Monad variable [TopologicalSpace X] {s : Set X} {t : Set s} theorem IsOpen.trans (ht : IsOpen t) (hs : IsOpen s) : IsOpen (t : Set X) := by rcases isOpen_induced_iff.mp ht with ⟨s', hs', rfl⟩ rw [Subtype.image_preimage_coe] exact hs.inter hs' theorem IsClosed.trans (ht : IsClosed t) (hs : IsClosed s) : IsClosed (t : Set X) := by rcases isClosed_induced_iff.mp ht with ⟨s', hs', rfl⟩ rw [Subtype.image_preimage_coe] exact hs.inter hs' end Monad section NhdsSet variable [TopologicalSpace X] [TopologicalSpace Y] {s : Set X} {t : Set Y} /-- The product of a neighborhood of `s` and a neighborhood of `t` is a neighborhood of `s ×ˢ t`, formulated in terms of a filter inequality. -/ theorem nhdsSet_prod_le (s : Set X) (t : Set Y) : 𝓝ˢ (s ×ˢ t) ≤ 𝓝ˢ s ×ˢ 𝓝ˢ t := ((hasBasis_nhdsSet _).prod (hasBasis_nhdsSet _)).ge_iff.2 fun (_u, _v) ⟨⟨huo, hsu⟩, hvo, htv⟩ ↦ (huo.prod hvo).mem_nhdsSet.2 <\| prod_mono hsu htv theorem Filter.eventually_nhdsSet_prod_iff {p : X × Y → Prop} : (∀ᶠ q in 𝓝ˢ (s ×ˢ t), p q) ↔ ∀ x ∈ s, ∀ y ∈ t, ∃ px : X → Prop, (∀ᶠ x' in 𝓝 x, px x') ∧ ∃ py : Y → Prop, (∀ᶠ y' in 𝓝 y, py y') ∧ ∀ {x : X}, px x → ∀ {y : Y}, py y → p (x, y) := by simp_rw [eventually_nhdsSet_iff_forall, forall_prod_set, nhds_prod_eq, eventually_prod_iff] theorem Filter.Eventually.prod_nhdsSet {p : X × Y → Prop} {px : X → Prop} {py : Y → Prop} (hp : ∀ {x : X}, px x → ∀ {y : Y}, py y → p (x, y)) (hs : ∀ᶠ x in 𝓝ˢ s, px x) (ht : ∀ᶠ y in 𝓝ˢ t, py y) : ∀ᶠ q in 𝓝ˢ (s ×ˢ t), p q := nhdsSet_prod_le _ _ (mem_of_superset (prod_mem_prod hs ht) fun _ ⟨hx, hy⟩ ↦ hp hx hy) end NhdsSet		Mathlib/Topology/Constructions.lean	1,315	1,316
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro, Floris van Doorn -/ import Mathlib.Algebra.Order.SuccPred import Mathlib.Data.Sum.Order import Mathlib.SetTheory.Cardinal.Basic import Mathlib.Tactic.PPWithUniv /-! # Ordinals Ordinals are defined as equivalences of well-ordered sets under order isomorphism. They are endowed with a total order, where an ordinal is smaller than another one if it embeds into it as an initial segment (or, equivalently, in any way). This total order is well founded. ## Main definitions * `Ordinal`: the type of ordinals (in a given universe) * `Ordinal.type r`: given a well-founded order `r`, this is the corresponding ordinal * `Ordinal.typein r a`: given a well-founded order `r` on a type `α`, and `a : α`, the ordinal corresponding to all elements smaller than `a`. * `enum r ⟨o, h⟩`: given a well-order `r` on a type `α`, and an ordinal `o` strictly smaller than the ordinal corresponding to `r` (this is the assumption `h`), returns the `o`-th element of `α`. In other words, the elements of `α` can be enumerated using ordinals up to `type r`. * `Ordinal.card o`: the cardinality of an ordinal `o`. * `Ordinal.lift` lifts an ordinal in universe `u` to an ordinal in universe `max u v`. For a version registering additionally that this is an initial segment embedding, see `Ordinal.liftInitialSeg`. For a version registering that it is a principal segment embedding if `u < v`, see `Ordinal.liftPrincipalSeg`. * `Ordinal.omega0` or `ω` is the order type of `ℕ`. It is called this to match `Cardinal.aleph0` and so that the omega function can be named `Ordinal.omega`. This definition is universe polymorphic: `Ordinal.omega0.{u} : Ordinal.{u}` (contrast with `ℕ : Type`, which lives in a specific universe). In some cases the universe level has to be given explicitly. * `o₁ + o₂` is the order on the disjoint union of `o₁` and `o₂` obtained by declaring that every element of `o₁` is smaller than every element of `o₂`. The main properties of addition (and the other operations on ordinals) are stated and proved in `Mathlib/SetTheory/Ordinal/Arithmetic.lean`. Here, we only introduce it and prove its basic properties to deduce the fact that the order on ordinals is total (and well founded). * `succ o` is the successor of the ordinal `o`. * `Cardinal.ord c`: when `c` is a cardinal, `ord c` is the smallest ordinal with this cardinality. It is the canonical way to represent a cardinal with an ordinal. A conditionally complete linear order with bot structure is registered on ordinals, where `⊥` is `0`, the ordinal corresponding to the empty type, and `Inf` is the minimum for nonempty sets and `0` for the empty set by convention. ## Notations * `ω` is a notation for the first infinite ordinal in the locale `Ordinal`. -/ assert_not_exists Module Field noncomputable section open Function Cardinal Set Equiv Order open scoped Cardinal InitialSeg universe u v w variable {α : Type u} {β : Type v} {γ : Type w} {r : α → α → Prop} {s : β → β → Prop} {t : γ → γ → Prop} /-! ### Definition of ordinals -/ /-- Bundled structure registering a well order on a type. Ordinals will be defined as a quotient of this type. -/ structure WellOrder : Type (u + 1) where /-- The underlying type of the order. -/ α : Type u /-- The underlying relation of the order. -/ r : α → α → Prop /-- The proposition that `r` is a well-ordering for `α`. -/ wo : IsWellOrder α r attribute [instance] WellOrder.wo namespace WellOrder instance inhabited : Inhabited WellOrder := ⟨⟨PEmpty, _, inferInstanceAs (IsWellOrder PEmpty EmptyRelation)⟩⟩ end WellOrder /-- Equivalence relation on well orders on arbitrary types in universe `u`, given by order isomorphism. -/ instance Ordinal.isEquivalent : Setoid WellOrder where r := fun ⟨_, r, _⟩ ⟨_, s, _⟩ => Nonempty (r ≃r s) iseqv := ⟨fun _ => ⟨RelIso.refl _⟩, fun ⟨e⟩ => ⟨e.symm⟩, fun ⟨e₁⟩ ⟨e₂⟩ => ⟨e₁.trans e₂⟩⟩ /-- `Ordinal.{u}` is the type of well orders in `Type u`, up to order isomorphism. -/ @[pp_with_univ] def Ordinal : Type (u + 1) := Quotient Ordinal.isEquivalent /-- A "canonical" type order-isomorphic to the ordinal `o`, living in the same universe. This is defined through the axiom of choice. Use this over `Iio o` only when it is paramount to have a `Type u` rather than a `Type (u + 1)`. -/ def Ordinal.toType (o : Ordinal.{u}) : Type u := o.out.α instance hasWellFounded_toType (o : Ordinal) : WellFoundedRelation o.toType := ⟨o.out.r, o.out.wo.wf⟩ instance linearOrder_toType (o : Ordinal) : LinearOrder o.toType := @IsWellOrder.linearOrder _ o.out.r o.out.wo instance wellFoundedLT_toType_lt (o : Ordinal) : WellFoundedLT o.toType := o.out.wo.toIsWellFounded namespace Ordinal noncomputable instance (o : Ordinal) : SuccOrder o.toType := SuccOrder.ofLinearWellFoundedLT o.toType /-! ### Basic properties of the order type -/ /-- The order type of a well order is an ordinal. -/ def type (r : α → α → Prop) [wo : IsWellOrder α r] : Ordinal := ⟦⟨α, r, wo⟩⟧ /-- `typeLT α` is an abbreviation for the order type of the `<` relation of `α`. -/ scoped notation "typeLT " α:70 => @Ordinal.type α (· < ·) inferInstance instance zero : Zero Ordinal := ⟨type <\| @EmptyRelation PEmpty⟩ instance inhabited : Inhabited Ordinal := ⟨0⟩ instance one : One Ordinal := ⟨type <\| @EmptyRelation PUnit⟩ @[simp] theorem type_toType (o : Ordinal) : typeLT o.toType = o := o.out_eq theorem type_eq {α β} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r] [IsWellOrder β s] : type r = type s ↔ Nonempty (r ≃r s) := Quotient.eq' theorem _root_.RelIso.ordinal_type_eq {α β} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r] [IsWellOrder β s] (h : r ≃r s) : type r = type s := type_eq.2 ⟨h⟩ theorem type_eq_zero_of_empty (r) [IsWellOrder α r] [IsEmpty α] : type r = 0 := (RelIso.relIsoOfIsEmpty r _).ordinal_type_eq @[simp] theorem type_eq_zero_iff_isEmpty [IsWellOrder α r] : type r = 0 ↔ IsEmpty α := ⟨fun h => let ⟨s⟩ := type_eq.1 h s.toEquiv.isEmpty, @type_eq_zero_of_empty α r _⟩ theorem type_ne_zero_iff_nonempty [IsWellOrder α r] : type r ≠ 0 ↔ Nonempty α := by simp theorem type_ne_zero_of_nonempty (r) [IsWellOrder α r] [h : Nonempty α] : type r ≠ 0 := type_ne_zero_iff_nonempty.2 h theorem type_pEmpty : type (@EmptyRelation PEmpty) = 0 := rfl theorem type_empty : type (@EmptyRelation Empty) = 0 := type_eq_zero_of_empty _ theorem type_eq_one_of_unique (r) [IsWellOrder α r] [Nonempty α] [Subsingleton α] : type r = 1 := by cases nonempty_unique α exact (RelIso.ofUniqueOfIrrefl r _).ordinal_type_eq @[simp] theorem type_eq_one_iff_unique [IsWellOrder α r] : type r = 1 ↔ Nonempty (Unique α) := ⟨fun h ↦ let ⟨s⟩ := type_eq.1 h; ⟨s.toEquiv.unique⟩, fun ⟨_⟩ ↦ type_eq_one_of_unique r⟩ theorem type_pUnit : type (@EmptyRelation PUnit) = 1 := rfl theorem type_unit : type (@EmptyRelation Unit) = 1 := rfl @[simp] theorem toType_empty_iff_eq_zero {o : Ordinal} : IsEmpty o.toType ↔ o = 0 := by rw [← @type_eq_zero_iff_isEmpty o.toType (· < ·), type_toType] instance isEmpty_toType_zero : IsEmpty (toType 0) := toType_empty_iff_eq_zero.2 rfl @[simp] theorem toType_nonempty_iff_ne_zero {o : Ordinal} : Nonempty o.toType ↔ o ≠ 0 := by rw [← @type_ne_zero_iff_nonempty o.toType (· < ·), type_toType] protected theorem one_ne_zero : (1 : Ordinal) ≠ 0 := type_ne_zero_of_nonempty _ instance nontrivial : Nontrivial Ordinal.{u} := ⟨⟨1, 0, Ordinal.one_ne_zero⟩⟩ /-- `Quotient.inductionOn` specialized to ordinals. Not to be confused with well-founded recursion `Ordinal.induction`. -/ @[elab_as_elim] theorem inductionOn {C : Ordinal → Prop} (o : Ordinal) (H : ∀ (α r) [IsWellOrder α r], C (type r)) : C o := Quot.inductionOn o fun ⟨α, r, wo⟩ => @H α r wo /-- `Quotient.inductionOn₂` specialized to ordinals. Not to be confused with well-founded recursion `Ordinal.induction`. -/ @[elab_as_elim] theorem inductionOn₂ {C : Ordinal → Ordinal → Prop} (o₁ o₂ : Ordinal) (H : ∀ (α r) [IsWellOrder α r] (β s) [IsWellOrder β s], C (type r) (type s)) : C o₁ o₂ := Quotient.inductionOn₂ o₁ o₂ fun ⟨α, r, wo₁⟩ ⟨β, s, wo₂⟩ => @H α r wo₁ β s wo₂ /-- `Quotient.inductionOn₃` specialized to ordinals. Not to be confused with well-founded recursion `Ordinal.induction`. -/ @[elab_as_elim] theorem inductionOn₃ {C : Ordinal → Ordinal → Ordinal → Prop} (o₁ o₂ o₃ : Ordinal) (H : ∀ (α r) [IsWellOrder α r] (β s) [IsWellOrder β s] (γ t) [IsWellOrder γ t], C (type r) (type s) (type t)) : C o₁ o₂ o₃ := Quotient.inductionOn₃ o₁ o₂ o₃ fun ⟨α, r, wo₁⟩ ⟨β, s, wo₂⟩ ⟨γ, t, wo₃⟩ => @H α r wo₁ β s wo₂ γ t wo₃ open Classical in /-- To prove a result on ordinals, it suffices to prove it for order types of well-orders. -/ @[elab_as_elim] theorem inductionOnWellOrder {C : Ordinal → Prop} (o : Ordinal) (H : ∀ (α) [LinearOrder α] [WellFoundedLT α], C (typeLT α)) : C o := inductionOn o fun α r wo ↦ @H α (linearOrderOfSTO r) wo.toIsWellFounded open Classical in /-- To define a function on ordinals, it suffices to define them on order types of well-orders. Since `LinearOrder` is data-carrying, `liftOnWellOrder_type` is not a definitional equality, unlike `Quotient.liftOn_mk` which is always def-eq. -/ def liftOnWellOrder {δ : Sort v} (o : Ordinal) (f : ∀ (α) [LinearOrder α] [WellFoundedLT α], δ) (c : ∀ (α) [LinearOrder α] [WellFoundedLT α] (β) [LinearOrder β] [WellFoundedLT β], typeLT α = typeLT β → f α = f β) : δ := Quotient.liftOn o (fun w ↦ @f w.α (linearOrderOfSTO w.r) w.wo.toIsWellFounded) fun w₁ w₂ h ↦ @c w₁.α (linearOrderOfSTO w₁.r) w₁.wo.toIsWellFounded w₂.α (linearOrderOfSTO w₂.r) w₂.wo.toIsWellFounded (Quotient.sound h) @[simp] theorem liftOnWellOrder_type {δ : Sort v} (f : ∀ (α) [LinearOrder α] [WellFoundedLT α], δ) (c : ∀ (α) [LinearOrder α] [WellFoundedLT α] (β) [LinearOrder β] [WellFoundedLT β], typeLT α = typeLT β → f α = f β) {γ} [LinearOrder γ] [WellFoundedLT γ] : liftOnWellOrder (typeLT γ) f c = f γ := by change Quotient.liftOn' ⟦_⟧ _ _ = _ rw [Quotient.liftOn'_mk] congr exact LinearOrder.ext_lt fun _ _ ↦ Iff.rfl /-! ### The order on ordinals -/ /-- For `Ordinal`: * less-equal is defined such that well orders `r` and `s` satisfy `type r ≤ type s` if there exists a function embedding `r` as an initial segment of `s`. * less-than is defined such that well orders `r` and `s` satisfy `type r < type s` if there exists a function embedding `r` as a principal segment of `s`. Note that most of the relevant results on initial and principal segments are proved in the `Order.InitialSeg` file. -/ instance partialOrder : PartialOrder Ordinal where le a b := Quotient.liftOn₂ a b (fun ⟨_, r, _⟩ ⟨_, s, _⟩ => Nonempty (r ≼i s)) fun _ _ _ _ ⟨f⟩ ⟨g⟩ => propext ⟨fun ⟨h⟩ => ⟨f.symm.toInitialSeg.trans <\| h.trans g.toInitialSeg⟩, fun ⟨h⟩ => ⟨f.toInitialSeg.trans <\| h.trans g.symm.toInitialSeg⟩⟩ lt a b := Quotient.liftOn₂ a b (fun ⟨_, r, _⟩ ⟨_, s, _⟩ => Nonempty (r ≺i s)) fun _ _ _ _ ⟨f⟩ ⟨g⟩ => propext ⟨fun ⟨h⟩ => ⟨PrincipalSeg.relIsoTrans f.symm <\| h.transRelIso g⟩, fun ⟨h⟩ => ⟨PrincipalSeg.relIsoTrans f <\| h.transRelIso g.symm⟩⟩ le_refl := Quot.ind fun ⟨_, _, _⟩ => ⟨InitialSeg.refl _⟩ le_trans a b c := Quotient.inductionOn₃ a b c fun _ _ _ ⟨f⟩ ⟨g⟩ => ⟨f.trans g⟩ lt_iff_le_not_le a b := Quotient.inductionOn₂ a b fun _ _ => ⟨fun ⟨f⟩ => ⟨⟨f⟩, fun ⟨g⟩ => (f.transInitial g).irrefl⟩, fun ⟨⟨f⟩, h⟩ => f.principalSumRelIso.recOn (fun g => ⟨g⟩) fun g => (h ⟨g.symm.toInitialSeg⟩).elim⟩ le_antisymm a b := Quotient.inductionOn₂ a b fun _ _ ⟨h₁⟩ ⟨h₂⟩ => Quot.sound ⟨InitialSeg.antisymm h₁ h₂⟩ instance : LinearOrder Ordinal := {inferInstanceAs (PartialOrder Ordinal) with le_total := fun a b => Quotient.inductionOn₂ a b fun ⟨_, r, _⟩ ⟨_, s, _⟩ => (InitialSeg.total r s).recOn (fun f => Or.inl ⟨f⟩) fun f => Or.inr ⟨f⟩ toDecidableLE := Classical.decRel _ } theorem _root_.InitialSeg.ordinal_type_le {α β} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r] [IsWellOrder β s] (h : r ≼i s) : type r ≤ type s := ⟨h⟩ theorem _root_.RelEmbedding.ordinal_type_le {α β} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r] [IsWellOrder β s] (h : r ↪r s) : type r ≤ type s := ⟨h.collapse⟩ theorem _root_.PrincipalSeg.ordinal_type_lt {α β} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r] [IsWellOrder β s] (h : r ≺i s) : type r < type s := ⟨h⟩ @[simp] protected theorem zero_le (o : Ordinal) : 0 ≤ o := inductionOn o fun _ r _ => (InitialSeg.ofIsEmpty _ r).ordinal_type_le instance : OrderBot Ordinal where bot := 0 bot_le := Ordinal.zero_le @[simp] theorem bot_eq_zero : (⊥ : Ordinal) = 0 := rfl instance instIsEmptyIioZero : IsEmpty (Iio (0 : Ordinal)) := by simp [← bot_eq_zero] @[simp] protected theorem le_zero {o : Ordinal} : o ≤ 0 ↔ o = 0 := le_bot_iff protected theorem pos_iff_ne_zero {o : Ordinal} : 0 < o ↔ o ≠ 0 := bot_lt_iff_ne_bot protected theorem not_lt_zero (o : Ordinal) : ¬o < 0 := not_lt_bot theorem eq_zero_or_pos : ∀ a : Ordinal, a = 0 ∨ 0 < a := eq_bot_or_bot_lt instance : ZeroLEOneClass Ordinal := ⟨Ordinal.zero_le _⟩ instance instNeZeroOne : NeZero (1 : Ordinal) := ⟨Ordinal.one_ne_zero⟩ theorem type_le_iff {α β} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r] [IsWellOrder β s] : type r ≤ type s ↔ Nonempty (r ≼i s) := Iff.rfl theorem type_le_iff' {α β} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r] [IsWellOrder β s] : type r ≤ type s ↔ Nonempty (r ↪r s) := ⟨fun ⟨f⟩ => ⟨f⟩, fun ⟨f⟩ => ⟨f.collapse⟩⟩ theorem type_lt_iff {α β} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r] [IsWellOrder β s] : type r < type s ↔ Nonempty (r ≺i s) := Iff.rfl /-- Given two ordinals `α ≤ β`, then `initialSegToType α β` is the initial segment embedding of `α.toType` into `β.toType`. -/ def initialSegToType {α β : Ordinal} (h : α ≤ β) : α.toType ≤i β.toType := by apply Classical.choice (type_le_iff.mp _) rwa [type_toType, type_toType] /-- Given two ordinals `α < β`, then `principalSegToType α β` is the principal segment embedding of `α.toType` into `β.toType`. -/ def principalSegToType {α β : Ordinal} (h : α < β) : α.toType <i β.toType := by apply Classical.choice (type_lt_iff.mp _) rwa [type_toType, type_toType] /-! ### Enumerating elements in a well-order with ordinals -/ /-- The order type of an element inside a well order. This is registered as a principal segment embedding into the ordinals, with top `type r`. -/ def typein (r : α → α → Prop) [IsWellOrder α r] : @PrincipalSeg α Ordinal.{u} r (· < ·) := by refine ⟨RelEmbedding.ofMonotone _ fun a b ha ↦ ((PrincipalSeg.ofElement r a).codRestrict _ ?_ ?_).ordinal_type_lt, type r, fun a ↦ ⟨?_, ?_⟩⟩ · rintro ⟨c, hc⟩ exact trans hc ha · exact ha · rintro ⟨b, rfl⟩ exact (PrincipalSeg.ofElement _ _).ordinal_type_lt · refine inductionOn a ?_ rintro β s wo ⟨g⟩ exact ⟨_, g.subrelIso.ordinal_type_eq⟩ @[simp] theorem type_subrel (r : α → α → Prop) [IsWellOrder α r] (a : α) : type (Subrel r (r · a)) = typein r a := rfl @[simp] theorem top_typein (r : α → α → Prop) [IsWellOrder α r] : (typein r).top = type r := rfl theorem typein_lt_type (r : α → α → Prop) [IsWellOrder α r] (a : α) : typein r a < type r := (typein r).lt_top a theorem typein_lt_self {o : Ordinal} (i : o.toType) : typein (α := o.toType) (· < ·) i < o := by simp_rw [← type_toType o] apply typein_lt_type @[simp] theorem typein_top {α β} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r] [IsWellOrder β s] (f : r ≺i s) : typein s f.top = type r := f.subrelIso.ordinal_type_eq @[simp] theorem typein_lt_typein (r : α → α → Prop) [IsWellOrder α r] {a b : α} : typein r a < typein r b ↔ r a b := (typein r).map_rel_iff @[simp] theorem typein_le_typein (r : α → α → Prop) [IsWellOrder α r] {a b : α} : typein r a ≤ typein r b ↔ ¬r b a := by rw [← not_lt, typein_lt_typein] theorem typein_injective (r : α → α → Prop) [IsWellOrder α r] : Injective (typein r) := (typein r).injective theorem typein_inj (r : α → α → Prop) [IsWellOrder α r] {a b} : typein r a = typein r b ↔ a = b := (typein_injective r).eq_iff theorem mem_range_typein_iff (r : α → α → Prop) [IsWellOrder α r] {o} : o ∈ Set.range (typein r) ↔ o < type r := (typein r).mem_range_iff_rel theorem typein_surj (r : α → α → Prop) [IsWellOrder α r] {o} (h : o < type r) : o ∈ Set.range (typein r) := (typein r).mem_range_of_rel_top h theorem typein_surjOn (r : α → α → Prop) [IsWellOrder α r] : Set.SurjOn (typein r) Set.univ (Set.Iio (type r)) := (typein r).surjOn /-- A well order `r` is order-isomorphic to the set of ordinals smaller than `type r`. `enum r ⟨o, h⟩` is the `o`-th element of `α` ordered by `r`. That is, `enum` maps an initial segment of the ordinals, those less than the order type of `r`, to the elements of `α`. -/ @[simps! symm_apply_coe] def enum (r : α → α → Prop) [IsWellOrder α r] : (· < · : Iio (type r) → Iio (type r) → Prop) ≃r r := (typein r).subrelIso @[simp] theorem typein_enum (r : α → α → Prop) [IsWellOrder α r] {o} (h : o < type r) : typein r (enum r ⟨o, h⟩) = o := (typein r).apply_subrelIso _ theorem enum_type {α β} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r] [IsWellOrder β s] (f : s ≺i r) {h : type s < type r} : enum r ⟨type s, h⟩ = f.top := (typein r).injective <\| (typein_enum _ _).trans (typein_top _).symm @[simp] theorem enum_typein (r : α → α → Prop) [IsWellOrder α r] (a : α) : enum r ⟨typein r a, typein_lt_type r a⟩ = a := enum_type (PrincipalSeg.ofElement r a) theorem enum_lt_enum {r : α → α → Prop} [IsWellOrder α r] {o₁ o₂ : Iio (type r)} : r (enum r o₁) (enum r o₂) ↔ o₁ < o₂ := (enum _).map_rel_iff theorem enum_le_enum (r : α → α → Prop) [IsWellOrder α r] {o₁ o₂ : Iio (type r)} : ¬r (enum r o₁) (enum r o₂) ↔ o₂ ≤ o₁ := by rw [enum_lt_enum (r := r), not_lt] -- TODO: generalize to other well-orders @[simp] theorem enum_le_enum' (a : Ordinal) {o₁ o₂ : Iio (type (· < ·))} : enum (· < ·) o₁ ≤ enum (α := a.toType) (· < ·) o₂ ↔ o₁ ≤ o₂ := by rw [← enum_le_enum, not_lt] theorem enum_inj {r : α → α → Prop} [IsWellOrder α r] {o₁ o₂ : Iio (type r)} : enum r o₁ = enum r o₂ ↔ o₁ = o₂ := EmbeddingLike.apply_eq_iff_eq _ theorem enum_zero_le {r : α → α → Prop} [IsWellOrder α r] (h0 : 0 < type r) (a : α) : ¬r a (enum r ⟨0, h0⟩) := by rw [← enum_typein r a, enum_le_enum r] apply Ordinal.zero_le theorem enum_zero_le' {o : Ordinal} (h0 : 0 < o) (a : o.toType) : enum (α := o.toType) (· < ·) ⟨0, type_toType _ ▸ h0⟩ ≤ a := by rw [← not_lt] apply enum_zero_le theorem relIso_enum' {α β : Type u} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r] [IsWellOrder β s] (f : r ≃r s) (o : Ordinal) : ∀ (hr : o < type r) (hs : o < type s), f (enum r ⟨o, hr⟩) = enum s ⟨o, hs⟩ := by refine inductionOn o ?_; rintro γ t wo ⟨g⟩ ⟨h⟩ rw [enum_type g, enum_type (g.transRelIso f)]; rfl theorem relIso_enum {α β : Type u} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r] [IsWellOrder β s] (f : r ≃r s) (o : Ordinal) (hr : o < type r) : f (enum r ⟨o, hr⟩) = enum s ⟨o, hr.trans_eq (Quotient.sound ⟨f⟩)⟩ := relIso_enum' _ _ _ _ /-- The order isomorphism between ordinals less than `o` and `o.toType`. -/ @[simps! -isSimp] noncomputable def enumIsoToType (o : Ordinal) : Set.Iio o ≃o o.toType where toFun x := enum (α := o.toType) (· < ·) ⟨x.1, type_toType _ ▸ x.2⟩ invFun x := ⟨typein (α := o.toType) (· < ·) x, typein_lt_self x⟩ left_inv _ := Subtype.ext_val (typein_enum _ _) right_inv _ := enum_typein _ _ map_rel_iff' := enum_le_enum' _ instance small_Iio (o : Ordinal.{u}) : Small.{u} (Iio o) := ⟨_, ⟨(enumIsoToType _).toEquiv⟩⟩ instance small_Iic (o : Ordinal.{u}) : Small.{u} (Iic o) := by rw [← Iio_union_right] infer_instance instance small_Ico (a b : Ordinal.{u}) : Small.{u} (Ico a b) := small_subset Ico_subset_Iio_self instance small_Icc (a b : Ordinal.{u}) : Small.{u} (Icc a b) := small_subset Icc_subset_Iic_self instance small_Ioo (a b : Ordinal.{u}) : Small.{u} (Ioo a b) := small_subset Ioo_subset_Iio_self instance small_Ioc (a b : Ordinal.{u}) : Small.{u} (Ioc a b) := small_subset Ioc_subset_Iic_self /-- `o.toType` is an `OrderBot` whenever `o ≠ 0`. -/ def toTypeOrderBot {o : Ordinal} (ho : o ≠ 0) : OrderBot o.toType where bot := (enum (· < ·)) ⟨0, _⟩ bot_le := enum_zero_le' (by rwa [Ordinal.pos_iff_ne_zero]) /-- `o.toType` is an `OrderBot` whenever `0 < o`. -/ @[deprecated "use toTypeOrderBot" (since := "2025-02-13")] def toTypeOrderBotOfPos {o : Ordinal} (ho : 0 < o) : OrderBot o.toType where bot := (enum (· < ·)) ⟨0, _⟩ bot_le := enum_zero_le' ho theorem enum_zero_eq_bot {o : Ordinal} (ho : 0 < o) : enum (α := o.toType) (· < ·) ⟨0, by rwa [type_toType]⟩ = have H := toTypeOrderBot (o := o) (by rintro rfl; simp at ho) (⊥ : o.toType) := rfl theorem lt_wf : @WellFounded Ordinal (· < ·) := wellFounded_iff_wellFounded_subrel.mpr (·.induction_on fun ⟨_, _, wo⟩ ↦ RelHomClass.wellFounded (enum _) wo.wf) instance wellFoundedRelation : WellFoundedRelation Ordinal := ⟨(· < ·), lt_wf⟩ instance wellFoundedLT : WellFoundedLT Ordinal := ⟨lt_wf⟩ instance : ConditionallyCompleteLinearOrderBot Ordinal := WellFoundedLT.conditionallyCompleteLinearOrderBot _ /-- Reformulation of well founded induction on ordinals as a lemma that works with the `induction` tactic, as in `induction i using Ordinal.induction with \| h i IH => ?_`. -/ theorem induction {p : Ordinal.{u} → Prop} (i : Ordinal.{u}) (h : ∀ j, (∀ k, k < j → p k) → p j) : p i := lt_wf.induction i h theorem typein_apply {α β} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r] [IsWellOrder β s] (f : r ≼i s) (a : α) : typein s (f a) = typein r a := by rw [← f.transPrincipal_apply _ a, (f.transPrincipal _).eq] /-! ### Cardinality of ordinals -/ /-- The cardinal of an ordinal is the cardinality of any type on which a relation with that order type is defined. -/ def card : Ordinal → Cardinal := Quotient.map WellOrder.α fun _ _ ⟨e⟩ => ⟨e.toEquiv⟩ @[simp] theorem card_type (r : α → α → Prop) [IsWellOrder α r] : card (type r) = #α := rfl @[simp] theorem card_typein {r : α → α → Prop} [IsWellOrder α r] (x : α) : #{ y // r y x } = (typein r x).card := rfl theorem card_le_card {o₁ o₂ : Ordinal} : o₁ ≤ o₂ → card o₁ ≤ card o₂ := inductionOn o₁ fun _ _ _ => inductionOn o₂ fun _ _ _ ⟨⟨⟨f, _⟩, _⟩⟩ => ⟨f⟩ @[simp] theorem card_zero : card 0 = 0 := mk_eq_zero _ @[simp] theorem card_one : card 1 = 1 := mk_eq_one _ /-! ### Lifting ordinals to a higher universe -/ -- Porting note: Needed to add universe hint .{u} below /-- The universe lift operation for ordinals, which embeds `Ordinal.{u}` as a proper initial segment of `Ordinal.{v}` for `v > u`. For the initial segment version, see `liftInitialSeg`. -/ @[pp_with_univ] def lift (o : Ordinal.{v}) : Ordinal.{max v u} := Quotient.liftOn o (fun w => type <\| ULift.down.{u} ⁻¹'o w.r) fun ⟨_, r, _⟩ ⟨_, s, _⟩ ⟨f⟩ => Quot.sound ⟨(RelIso.preimage Equiv.ulift r).trans <\| f.trans (RelIso.preimage Equiv.ulift s).symm⟩ @[simp] theorem type_uLift (r : α → α → Prop) [IsWellOrder α r] : type (ULift.down ⁻¹'o r) = lift.{v} (type r) := rfl theorem _root_.RelIso.ordinal_lift_type_eq {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r] [IsWellOrder β s] (f : r ≃r s) : lift.{v} (type r) = lift.{u} (type s) := ((RelIso.preimage Equiv.ulift r).trans <\| f.trans (RelIso.preimage Equiv.ulift s).symm).ordinal_type_eq @[simp] theorem type_preimage {α β : Type u} (r : α → α → Prop) [IsWellOrder α r] (f : β ≃ α) : type (f ⁻¹'o r) = type r := (RelIso.preimage f r).ordinal_type_eq @[simp] theorem type_lift_preimage (r : α → α → Prop) [IsWellOrder α r] (f : β ≃ α) : lift.{u} (type (f ⁻¹'o r)) = lift.{v} (type r) := (RelIso.preimage f r).ordinal_lift_type_eq /-- `lift.{max u v, u}` equals `lift.{v, u}`. Unfortunately, the simp lemma doesn't seem to work. -/ theorem lift_umax : lift.{max u v, u} = lift.{v, u} := funext fun a => inductionOn a fun _ r _ => Quotient.sound ⟨(RelIso.preimage Equiv.ulift r).trans (RelIso.preimage Equiv.ulift r).symm⟩ /-- An ordinal lifted to a lower or equal universe equals itself. Unfortunately, the simp lemma doesn't work. -/ theorem lift_id' (a : Ordinal) : lift a = a := inductionOn a fun _ r _ => Quotient.sound ⟨RelIso.preimage Equiv.ulift r⟩ /-- An ordinal lifted to the same universe equals itself. -/ @[simp] theorem lift_id : ∀ a, lift.{u, u} a = a := lift_id'.{u, u} /-- An ordinal lifted to the zero universe equals itself. -/ @[simp] theorem lift_uzero (a : Ordinal.{u}) : lift.{0} a = a := lift_id' a theorem lift_type_le {α : Type u} {β : Type v} {r s} [IsWellOrder α r] [IsWellOrder β s] : lift.{max v w} (type r) ≤ lift.{max u w} (type s) ↔ Nonempty (r ≼i s) := by constructor <;> refine fun ⟨f⟩ ↦ ⟨?_⟩ · exact (RelIso.preimage Equiv.ulift r).symm.toInitialSeg.trans (f.trans (RelIso.preimage Equiv.ulift s).toInitialSeg) · exact (RelIso.preimage Equiv.ulift r).toInitialSeg.trans (f.trans (RelIso.preimage Equiv.ulift s).symm.toInitialSeg) theorem lift_type_eq {α : Type u} {β : Type v} {r s} [IsWellOrder α r] [IsWellOrder β s] : lift.{max v w} (type r) = lift.{max u w} (type s) ↔ Nonempty (r ≃r s) := by refine Quotient.eq'.trans ⟨?_, ?_⟩ <;> refine fun ⟨f⟩ ↦ ⟨?_⟩ · exact (RelIso.preimage Equiv.ulift r).symm.trans <\| f.trans (RelIso.preimage Equiv.ulift s) · exact (RelIso.preimage Equiv.ulift r).trans <\| f.trans (RelIso.preimage Equiv.ulift s).symm theorem lift_type_lt {α : Type u} {β : Type v} {r s} [IsWellOrder α r] [IsWellOrder β s] : lift.{max v w} (type r) < lift.{max u w} (type s) ↔ Nonempty (r ≺i s) := by constructor <;> refine fun ⟨f⟩ ↦ ⟨?_⟩ · exact (f.relIsoTrans (RelIso.preimage Equiv.ulift r).symm).transInitial (RelIso.preimage Equiv.ulift s).toInitialSeg · exact (f.relIsoTrans (RelIso.preimage Equiv.ulift r)).transInitial (RelIso.preimage Equiv.ulift s).symm.toInitialSeg @[simp] theorem lift_le {a b : Ordinal} : lift.{u, v} a ≤ lift.{u, v} b ↔ a ≤ b := inductionOn₂ a b fun α r _ β s _ => by rw [← lift_umax] exact lift_type_le.{_,_,u} @[simp] theorem lift_inj {a b : Ordinal} : lift.{u, v} a = lift.{u, v} b ↔ a = b := by simp_rw [le_antisymm_iff, lift_le] @[simp] theorem lift_lt {a b : Ordinal} : lift.{u, v} a < lift.{u, v} b ↔ a < b := by simp_rw [lt_iff_le_not_le, lift_le] @[simp] theorem lift_typein_top {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r] [IsWellOrder β s] (f : r ≺i s) : lift.{u} (typein s f.top) = lift (type r) := f.subrelIso.ordinal_lift_type_eq /-- Initial segment version of the lift operation on ordinals, embedding `Ordinal.{u}` in `Ordinal.{v}` as an initial segment when `u ≤ v`. -/ def liftInitialSeg : Ordinal.{v} ≤i Ordinal.{max u v} := by refine ⟨RelEmbedding.ofMonotone lift.{u} (by simp), fun a b ↦ Ordinal.inductionOn₂ a b fun α r _ β s _ h ↦ ?_⟩ rw [RelEmbedding.ofMonotone_coe, ← lift_id'.{max u v} (type s), ← lift_umax.{v, u}, lift_type_lt] at h obtain ⟨f⟩ := h use typein r f.top rw [RelEmbedding.ofMonotone_coe, ← lift_umax, lift_typein_top, lift_id'] @[simp] theorem liftInitialSeg_coe : (liftInitialSeg.{v, u} : Ordinal → Ordinal) = lift.{v, u} := rfl @[simp] theorem lift_lift (a : Ordinal.{u}) : lift.{w} (lift.{v} a) = lift.{max v w} a := (liftInitialSeg.trans liftInitialSeg).eq liftInitialSeg a @[simp] theorem lift_zero : lift 0 = 0 := type_eq_zero_of_empty _ @[simp] theorem lift_one : lift 1 = 1 := type_eq_one_of_unique _ @[simp] theorem lift_card (a) : Cardinal.lift.{u, v} (card a) = card (lift.{u} a) := inductionOn a fun _ _ _ => rfl theorem mem_range_lift_of_le {a : Ordinal.{u}} {b : Ordinal.{max u v}} (h : b ≤ lift.{v} a) : b ∈ Set.range lift.{v} := liftInitialSeg.mem_range_of_le h theorem le_lift_iff {a : Ordinal.{u}} {b : Ordinal.{max u v}} : b ≤ lift.{v} a ↔ ∃ a' ≤ a, lift.{v} a' = b := liftInitialSeg.le_apply_iff theorem lt_lift_iff {a : Ordinal.{u}} {b : Ordinal.{max u v}} : b < lift.{v} a ↔ ∃ a' < a, lift.{v} a' = b := liftInitialSeg.lt_apply_iff /-! ### The first infinite ordinal ω -/ /-- `ω` is the first infinite ordinal, defined as the order type of `ℕ`. -/ def omega0 : Ordinal.{u} := lift (typeLT ℕ) @[inherit_doc] scoped notation "ω" => Ordinal.omega0 /-- Note that the presence of this lemma makes `simp [omega0]` form a loop. -/ @[simp] theorem type_nat_lt : typeLT ℕ = ω := (lift_id _).symm @[simp] theorem card_omega0 : card ω = ℵ₀ := rfl @[simp] theorem lift_omega0 : lift ω = ω := lift_lift _ /-! ### Definition and first properties of addition on ordinals In this paragraph, we introduce the addition on ordinals, and prove just enough properties to deduce that the order on ordinals is total (and therefore well-founded). Further properties of the addition, together with properties of the other operations, are proved in `Mathlib/SetTheory/Ordinal/Arithmetic.lean`. -/ /-- `o₁ + o₂` is the order on the disjoint union of `o₁` and `o₂` obtained by declaring that every element of `o₁` is smaller than every element of `o₂`. -/ instance add : Add Ordinal.{u} := ⟨fun o₁ o₂ => Quotient.liftOn₂ o₁ o₂ (fun ⟨_, r, _⟩ ⟨_, s, _⟩ => type (Sum.Lex r s)) fun _ _ _ _ ⟨f⟩ ⟨g⟩ => (RelIso.sumLexCongr f g).ordinal_type_eq⟩ instance addMonoidWithOne : AddMonoidWithOne Ordinal.{u} where add := (· + ·) zero := 0 one := 1 zero_add o := inductionOn o fun α _ _ => Eq.symm <\| Quotient.sound ⟨⟨(emptySum PEmpty α).symm, Sum.lex_inr_inr⟩⟩ add_zero o := inductionOn o fun α _ _ => Eq.symm <\| Quotient.sound ⟨⟨(sumEmpty α PEmpty).symm, Sum.lex_inl_inl⟩⟩ add_assoc o₁ o₂ o₃ := Quotient.inductionOn₃ o₁ o₂ o₃ fun ⟨α, r, _⟩ ⟨β, s, _⟩ ⟨γ, t, _⟩ => Quot.sound ⟨⟨sumAssoc _ _ _, by intros a b rcases a with (⟨a \| a⟩ \| a) <;> rcases b with (⟨b \| b⟩ \| b) <;> simp only [sumAssoc_apply_inl_inl, sumAssoc_apply_inl_inr, sumAssoc_apply_inr, Sum.lex_inl_inl, Sum.lex_inr_inr, Sum.Lex.sep, Sum.lex_inr_inl]⟩⟩ nsmul := nsmulRec @[simp] theorem card_add (o₁ o₂ : Ordinal) : card (o₁ + o₂) = card o₁ + card o₂ := inductionOn o₁ fun _ __ => inductionOn o₂ fun _ _ _ => rfl @[simp] theorem type_sum_lex {α β : Type u} (r : α → α → Prop) (s : β → β → Prop) [IsWellOrder α r] [IsWellOrder β s] : type (Sum.Lex r s) = type r + type s := rfl @[simp] theorem card_nat (n : ℕ) : card.{u} n = n := by induction n <;> [simp; simp only [card_add, card_one, Nat.cast_succ, *]] @[simp] theorem card_ofNat (n : ℕ) [n.AtLeastTwo] : card.{u} ofNat(n) = OfNat.ofNat n := card_nat n instance instAddLeftMono : AddLeftMono Ordinal.{u} where elim c a b := by refine inductionOn₃ a b c fun α r _ β s _ γ t _ ⟨f⟩ ↦ (RelEmbedding.ofMonotone (Sum.recOn · Sum.inl (Sum.inr ∘ f)) ?_).ordinal_type_le simp [f.map_rel_iff] instance instAddRightMono : AddRightMono Ordinal.{u} where elim c a b := by refine inductionOn₃ a b c fun α r _ β s _ γ t _ ⟨f⟩ ↦ (RelEmbedding.ofMonotone (Sum.recOn · (Sum.inl ∘ f) Sum.inr) ?_).ordinal_type_le simp [f.map_rel_iff] theorem le_add_right (a b : Ordinal) : a ≤ a + b := by simpa only [add_zero] using add_le_add_left (Ordinal.zero_le b) a theorem le_add_left (a b : Ordinal) : a ≤ b + a := by simpa only [zero_add] using add_le_add_right (Ordinal.zero_le b) a theorem max_zero_left : ∀ a : Ordinal, max 0 a = a := max_bot_left theorem max_zero_right : ∀ a : Ordinal, max a 0 = a := max_bot_right @[simp] theorem max_eq_zero {a b : Ordinal} : max a b = 0 ↔ a = 0 ∧ b = 0 := max_eq_bot @[simp] theorem sInf_empty : sInf (∅ : Set Ordinal) = 0 := dif_neg Set.not_nonempty_empty /-! ### Successor order properties -/ private theorem succ_le_iff' {a b : Ordinal} : a + 1 ≤ b ↔ a < b := by refine inductionOn₂ a b fun α r _ β s _ ↦ ⟨?_, ?_⟩ <;> rintro ⟨f⟩ · refine ⟨((InitialSeg.leAdd _ _).trans f).toPrincipalSeg fun h ↦ ?_⟩ simpa using h (f (Sum.inr PUnit.unit)) · apply (RelEmbedding.ofMonotone (Sum.recOn · f fun _ ↦ f.top) ?_).ordinal_type_le simpa [f.map_rel_iff] using f.lt_top instance : NoMaxOrder Ordinal := ⟨fun _ => ⟨_, succ_le_iff'.1 le_rfl⟩⟩ instance : SuccOrder Ordinal.{u} := SuccOrder.ofSuccLeIff (fun o => o + 1) succ_le_iff' instance : SuccAddOrder Ordinal := ⟨fun _ => rfl⟩ @[simp] theorem add_one_eq_succ (o : Ordinal) : o + 1 = succ o := rfl @[simp] theorem succ_zero : succ (0 : Ordinal) = 1 := zero_add 1 -- Porting note: Proof used to be rfl @[simp] theorem succ_one : succ (1 : Ordinal) = 2 := by congr; simp only [Nat.unaryCast, zero_add] theorem add_succ (o₁ o₂ : Ordinal) : o₁ + succ o₂ = succ (o₁ + o₂) := (add_assoc _ _ _).symm theorem one_le_iff_ne_zero {o : Ordinal} : 1 ≤ o ↔ o ≠ 0 := by rw [Order.one_le_iff_pos, Ordinal.pos_iff_ne_zero] theorem succ_pos (o : Ordinal) : 0 < succ o := bot_lt_succ o theorem succ_ne_zero (o : Ordinal) : succ o ≠ 0 := ne_of_gt <\| succ_pos o @[simp] theorem lt_one_iff_zero {a : Ordinal} : a < 1 ↔ a = 0 := by simpa using @lt_succ_bot_iff _ _ _ a _ _ theorem le_one_iff {a : Ordinal} : a ≤ 1 ↔ a = 0 ∨ a = 1 := by simpa using @le_succ_bot_iff _ _ _ a _ @[simp] theorem card_succ (o : Ordinal) : card (succ o) = card o + 1 := by simp only [← add_one_eq_succ, card_add, card_one] theorem natCast_succ (n : ℕ) : ↑n.succ = succ (n : Ordinal) := rfl instance uniqueIioOne : Unique (Iio (1 : Ordinal)) where default := ⟨0, zero_lt_one' Ordinal⟩ uniq a := Subtype.ext <\| lt_one_iff_zero.1 a.2 @[simp] theorem Iio_one_default_eq : (default : Iio (1 : Ordinal)) = ⟨0, zero_lt_one' Ordinal⟩ := rfl instance uniqueToTypeOne : Unique (toType 1) where default := enum (α := toType 1) (· < ·) ⟨0, by simp⟩ uniq a := by rw [← enum_typein (α := toType 1) (· < ·) a] congr rw [← lt_one_iff_zero] apply typein_lt_self theorem one_toType_eq (x : toType 1) : x = enum (· < ·) ⟨0, by simp⟩ := Unique.eq_default x /-! ### Extra properties of typein and enum -/ -- TODO: use `enumIsoToType` for lemmas on `toType` rather than `enum` and `typein`. @[simp] theorem typein_one_toType (x : toType 1) : typein (α := toType 1) (· < ·) x = 0 := by rw [one_toType_eq x, typein_enum] theorem typein_le_typein' (o : Ordinal) {x y : o.toType} : typein (α := o.toType) (· < ·) x ≤ typein (α := o.toType) (· < ·) y ↔ x ≤ y := by simp theorem le_enum_succ {o : Ordinal} (a : (succ o).toType) : a ≤ enum (α := (succ o).toType) (· < ·) ⟨o, (type_toType _ ▸ lt_succ o)⟩ := by rw [← enum_typein (α := (succ o).toType) (· < ·) a, enum_le_enum', Subtype.mk_le_mk, ← lt_succ_iff] apply typein_lt_self /-! ### Universal ordinal -/ -- intended to be used with explicit universe parameters /-- `univ.{u v}` is the order type of the ordinals of `Type u` as a member of `Ordinal.{v}` (when `u < v`). It is an inaccessible cardinal. -/ @[pp_with_univ, nolint checkUnivs] def univ : Ordinal.{max (u + 1) v} := lift.{v, u + 1} (typeLT Ordinal) theorem univ_id : univ.{u, u + 1} = typeLT Ordinal := lift_id _ @[simp] theorem lift_univ : lift.{w} univ.{u, v} = univ.{u, max v w} := lift_lift _ theorem univ_umax : univ.{u, max (u + 1) v} = univ.{u, v} := congr_fun lift_umax _ /-- Principal segment version of the lift operation on ordinals, embedding `Ordinal.{u}` in `Ordinal.{v}` as a principal segment when `u < v`. -/ def liftPrincipalSeg : Ordinal.{u} <i Ordinal.{max (u + 1) v} := ⟨↑liftInitialSeg.{max (u + 1) v, u}, univ.{u, v}, by refine fun b => inductionOn b ?_; intro β s _ rw [univ, ← lift_umax]; constructor <;> intro h · obtain ⟨a, e⟩ := h rw [← e] refine inductionOn a ?_ intro α r _ exact lift_type_lt.{u, u + 1, max (u + 1) v}.2 ⟨typein r⟩ · rw [← lift_id (type s)] at h ⊢ obtain ⟨f⟩ := lift_type_lt.{_,_,v}.1 h obtain ⟨f, a, hf⟩ := f exists a revert hf -- Porting note: apply inductionOn does not work, refine does refine inductionOn a ?_ intro α r _ hf refine lift_type_eq.{u, max (u + 1) v, max (u + 1) v}.2 ⟨(RelIso.ofSurjective (RelEmbedding.ofMonotone ?_ ?_) ?_).symm⟩ · exact fun b => enum r ⟨f b, (hf _).1 ⟨_, rfl⟩⟩ · refine fun a b h => (typein_lt_typein r).1 ?_ rw [typein_enum, typein_enum] exact f.map_rel_iff.2 h · intro a' obtain ⟨b, e⟩ := (hf _).2 (typein_lt_type _ a') exists b simp only [RelEmbedding.ofMonotone_coe] simp [e]⟩ @[simp] theorem liftPrincipalSeg_coe : (liftPrincipalSeg.{u, v} : Ordinal → Ordinal) = lift.{max (u + 1) v} := rfl @[simp] theorem liftPrincipalSeg_top : (liftPrincipalSeg.{u, v}).top = univ.{u, v} := rfl theorem liftPrincipalSeg_top' : liftPrincipalSeg.{u, u + 1}.top = typeLT Ordinal := by simp only [liftPrincipalSeg_top, univ_id] end Ordinal /-! ### Representing a cardinal with an ordinal -/ namespace Cardinal open Ordinal @[simp] theorem mk_toType (o : Ordinal) : #o.toType = o.card := (Ordinal.card_type _).symm.trans <\| by rw [Ordinal.type_toType] /-- The ordinal corresponding to a cardinal `c` is the least ordinal whose cardinal is `c`. For the order-embedding version, see `ord.order_embedding`. -/ def ord (c : Cardinal) : Ordinal := let F := fun α : Type u => ⨅ r : { r // IsWellOrder α r }, @type α r.1 r.2 Quot.liftOn c F (by suffices ∀ {α β}, α ≈ β → F α ≤ F β from fun α β h => (this h).antisymm (this (Setoid.symm h)) rintro α β ⟨f⟩ refine le_ciInf_iff'.2 fun i => ?_ haveI := @RelEmbedding.isWellOrder _ _ (f ⁻¹'o i.1) _ (↑(RelIso.preimage f i.1)) i.2 exact (ciInf_le' _ (Subtype.mk (f ⁻¹'o i.val) (@RelEmbedding.isWellOrder _ _ _ _ (↑(RelIso.preimage f i.1)) i.2))).trans_eq (Quot.sound ⟨RelIso.preimage f i.1⟩)) theorem ord_eq_Inf (α : Type u) : ord #α = ⨅ r : { r // IsWellOrder α r }, @type α r.1 r.2 := rfl theorem ord_eq (α) : ∃ (r : α → α → Prop) (wo : IsWellOrder α r), ord #α = @type α r wo := let ⟨r, wo⟩ := ciInf_mem fun r : { r // IsWellOrder α r } => @type α r.1 r.2 ⟨r.1, r.2, wo.symm⟩ theorem ord_le_type (r : α → α → Prop) [h : IsWellOrder α r] : ord #α ≤ type r := ciInf_le' _ (Subtype.mk r h) theorem ord_le {c o} : ord c ≤ o ↔ c ≤ o.card := inductionOn c fun α => Ordinal.inductionOn o fun β s _ => by let ⟨r, _, e⟩ := ord_eq α simp only [card_type]; constructor <;> intro h · rw [e] at h exact let ⟨f⟩ := h ⟨f.toEmbedding⟩ · obtain ⟨f⟩ := h have g := RelEmbedding.preimage f s haveI := RelEmbedding.isWellOrder g exact le_trans (ord_le_type _) g.ordinal_type_le theorem gc_ord_card : GaloisConnection ord card := fun _ _ => ord_le theorem lt_ord {c o} : o < ord c ↔ o.card < c := gc_ord_card.lt_iff_lt @[simp] theorem card_ord (c) : (ord c).card = c := c.inductionOn fun α ↦ let ⟨r, _, e⟩ := ord_eq α; e ▸ card_type r theorem card_surjective : Function.Surjective card := fun c ↦ ⟨_, card_ord c⟩ /-- Galois coinsertion between `Cardinal.ord` and `Ordinal.card`. -/ def gciOrdCard : GaloisCoinsertion ord card := gc_ord_card.toGaloisCoinsertion fun c => c.card_ord.le theorem ord_card_le (o : Ordinal) : o.card.ord ≤ o := gc_ord_card.l_u_le _ theorem lt_ord_succ_card (o : Ordinal) : o < (succ o.card).ord := lt_ord.2 <\| lt_succ _ theorem card_le_iff {o : Ordinal} {c : Cardinal} : o.card ≤ c ↔ o < (succ c).ord := by rw [lt_ord, lt_succ_iff] /-- A variation on `Cardinal.lt_ord` using `≤`: If `o` is no greater than the initial ordinal of cardinality `c`, then its cardinal is no greater than `c`. The converse, however, is false (for instance, `o = ω+1` and `c = ℵ₀`). -/ lemma card_le_of_le_ord {o : Ordinal} {c : Cardinal} (ho : o ≤ c.ord) : o.card ≤ c := by rw [← card_ord c]; exact Ordinal.card_le_card ho @[mono] theorem ord_strictMono : StrictMono ord := gciOrdCard.strictMono_l @[mono] theorem ord_mono : Monotone ord := gc_ord_card.monotone_l @[simp] theorem ord_le_ord {c₁ c₂} : ord c₁ ≤ ord c₂ ↔ c₁ ≤ c₂ := gciOrdCard.l_le_l_iff @[simp] theorem ord_lt_ord {c₁ c₂} : ord c₁ < ord c₂ ↔ c₁ < c₂ := ord_strictMono.lt_iff_lt @[simp] theorem ord_zero : ord 0 = 0 := gc_ord_card.l_bot @[simp] theorem ord_nat (n : ℕ) : ord n = n := (ord_le.2 (card_nat n).ge).antisymm (by induction' n with n IH · apply Ordinal.zero_le · exact succ_le_of_lt (IH.trans_lt <\| ord_lt_ord.2 <\| Nat.cast_lt.2 (Nat.lt_succ_self n))) @[simp] theorem ord_one : ord 1 = 1 := by simpa using ord_nat 1 @[simp] theorem ord_ofNat (n : ℕ) [n.AtLeastTwo] : ord ofNat(n) = OfNat.ofNat n := ord_nat n @[simp] theorem ord_aleph0 : ord.{u} ℵ₀ = ω := le_antisymm (ord_le.2 le_rfl) <\| le_of_forall_lt fun o h => by rcases Ordinal.lt_lift_iff.1 h with ⟨o, h', rfl⟩ rw [lt_ord, ← lift_card, lift_lt_aleph0, ← typein_enum (· < ·) h'] exact lt_aleph0_iff_fintype.2 ⟨Set.fintypeLTNat _⟩ @[simp] theorem lift_ord (c) : Ordinal.lift.{u,v} (ord c) = ord (lift.{u,v} c) := by refine le_antisymm (le_of_forall_lt fun a ha => ?_) ?_ · rcases Ordinal.lt_lift_iff.1 ha with ⟨a, _, rfl⟩ rwa [lt_ord, ← lift_card, lift_lt, ← lt_ord, ← Ordinal.lift_lt] · rw [ord_le, ← lift_card, card_ord] theorem mk_ord_toType (c : Cardinal) : #c.ord.toType = c := by simp theorem card_typein_lt (r : α → α → Prop) [IsWellOrder α r] (x : α) (h : ord #α = type r) : card (typein r x) < #α := by rw [← lt_ord, h] apply typein_lt_type theorem card_typein_toType_lt (c : Cardinal) (x : c.ord.toType) : card (typein (α := c.ord.toType) (· < ·) x) < c := by rw [← lt_ord] apply typein_lt_self theorem mk_Iio_ord_toType {c : Cardinal} (i : c.ord.toType) : #(Iio i) < c := card_typein_toType_lt c i theorem ord_injective : Injective ord := by intro c c' h rw [← card_ord c, ← card_ord c', h] @[simp] theorem ord_inj {a b : Cardinal} : a.ord = b.ord ↔ a = b := ord_injective.eq_iff @[simp] theorem ord_eq_zero {a : Cardinal} : a.ord = 0 ↔ a = 0 := ord_injective.eq_iff' ord_zero @[simp] theorem ord_eq_one {a : Cardinal} : a.ord = 1 ↔ a = 1 := ord_injective.eq_iff' ord_one @[simp] theorem omega0_le_ord {a : Cardinal} : ω ≤ a.ord ↔ ℵ₀ ≤ a := by rw [← ord_aleph0, ord_le_ord] @[simp] theorem ord_le_omega0 {a : Cardinal} : a.ord ≤ ω ↔ a ≤ ℵ₀ := by rw [← ord_aleph0, ord_le_ord] @[simp] theorem ord_lt_omega0 {a : Cardinal} : a.ord < ω ↔ a < ℵ₀ := le_iff_le_iff_lt_iff_lt.1 omega0_le_ord @[simp] theorem omega0_lt_ord {a : Cardinal} : ω < a.ord ↔ ℵ₀ < a := le_iff_le_iff_lt_iff_lt.1 ord_le_omega0 @[simp] theorem ord_eq_omega0 {a : Cardinal} : a.ord = ω ↔ a = ℵ₀ := ord_injective.eq_iff' ord_aleph0 /-- The ordinal corresponding to a cardinal `c` is the least ordinal whose cardinal is `c`. This is the order-embedding version. For the regular function, see `ord`. -/ def ord.orderEmbedding : Cardinal ↪o Ordinal := RelEmbedding.orderEmbeddingOfLTEmbedding (RelEmbedding.ofMonotone Cardinal.ord fun _ _ => Cardinal.ord_lt_ord.2) @[simp] theorem ord.orderEmbedding_coe : (ord.orderEmbedding : Cardinal → Ordinal) = ord := rfl -- intended to be used with explicit universe parameters /-- The cardinal `univ` is the cardinality of ordinal `univ`, or equivalently the cardinal of `Ordinal.{u}`, or `Cardinal.{u}`, as an element of `Cardinal.{v}` (when `u < v`). -/ @[pp_with_univ, nolint checkUnivs] def univ := lift.{v, u + 1} #Ordinal theorem univ_id : univ.{u, u + 1} = #Ordinal := lift_id _ @[simp] theorem lift_univ : lift.{w} univ.{u, v} = univ.{u, max v w} := lift_lift _ theorem univ_umax : univ.{u, max (u + 1) v} = univ.{u, v} := congr_fun lift_umax _ theorem lift_lt_univ (c : Cardinal) : lift.{u + 1, u} c < univ.{u, u + 1} := by simpa only [liftPrincipalSeg_coe, lift_ord, lift_succ, ord_le, succ_le_iff] using le_of_lt (liftPrincipalSeg.{u, u + 1}.lt_top (succ c).ord) theorem lift_lt_univ' (c : Cardinal) : lift.{max (u + 1) v, u} c < univ.{u, v} := by have := lift_lt.{_, max (u+1) v}.2 (lift_lt_univ c) rw [lift_lift, lift_univ, univ_umax.{u,v}] at this exact this @[simp] theorem ord_univ : ord univ.{u, v} = Ordinal.univ.{u, v} := by refine le_antisymm (ord_card_le _) <\| le_of_forall_lt fun o h => lt_ord.2 ?_ have := liftPrincipalSeg.mem_range_of_rel_top (by simpa only [liftPrincipalSeg_coe] using h) rcases this with ⟨o, h'⟩ rw [← h', liftPrincipalSeg_coe, ← lift_card] apply lift_lt_univ' theorem lt_univ {c} : c < univ.{u, u + 1} ↔ ∃ c', c = lift.{u + 1, u} c' := ⟨fun h => by have := ord_lt_ord.2 h rw [ord_univ] at this obtain ⟨o, e⟩ := liftPrincipalSeg.mem_range_of_rel_top (by simpa only [liftPrincipalSeg_top]) have := card_ord c rw [← e, liftPrincipalSeg_coe, ← lift_card] at this exact ⟨_, this.symm⟩, fun ⟨_, e⟩ => e.symm ▸ lift_lt_univ _⟩ theorem lt_univ' {c} : c < univ.{u, v} ↔ ∃ c', c = lift.{max (u + 1) v, u} c' := ⟨fun h => by let ⟨a, h', e⟩ := lt_lift_iff.1 h rw [← univ_id] at h' rcases lt_univ.{u}.1 h' with ⟨c', rfl⟩ exact ⟨c', by simp only [e.symm, lift_lift]⟩, fun ⟨_, e⟩ => e.symm ▸ lift_lt_univ' _⟩ theorem small_iff_lift_mk_lt_univ {α : Type u} : Small.{v} α ↔ Cardinal.lift.{v+1,_} #α < univ.{v, max u (v + 1)} := by rw [lt_univ'] constructor · rintro ⟨β, e⟩ exact ⟨#β, lift_mk_eq.{u, _, v + 1}.2 e⟩ · rintro ⟨c, hc⟩ exact ⟨⟨c.out, lift_mk_eq.{u, _, v + 1}.1 (hc.trans (congr rfl c.mk_out.symm))⟩⟩ /-- If a cardinal `c` is non zero, then `c.ord.toType` has a least element. -/ noncomputable def toTypeOrderBot {c : Cardinal} (hc : c ≠ 0) : OrderBot c.ord.toType := Ordinal.toTypeOrderBot (fun h ↦ hc (ord_injective (by simpa using h))) end Cardinal namespace Ordinal @[simp] theorem card_univ : card univ.{u,v} = Cardinal.univ.{u,v} := rfl @[simp] theorem nat_le_card {o} {n : ℕ} : (n : Cardinal) ≤ card o ↔ (n : Ordinal) ≤ o := by rw [← Cardinal.ord_le, Cardinal.ord_nat] @[simp] theorem one_le_card {o} : 1 ≤ card o ↔ 1 ≤ o := by simpa using nat_le_card (n := 1) @[simp] theorem ofNat_le_card {o} {n : ℕ} [n.AtLeastTwo] : (ofNat(n) : Cardinal) ≤ card o ↔ (OfNat.ofNat n : Ordinal) ≤ o := nat_le_card @[simp] theorem aleph0_le_card {o} : ℵ₀ ≤ card o ↔ ω ≤ o := by rw [← ord_le, ord_aleph0] @[simp] theorem card_lt_aleph0 {o} : card o < ℵ₀ ↔ o < ω := le_iff_le_iff_lt_iff_lt.1 aleph0_le_card @[simp] theorem nat_lt_card {o} {n : ℕ} : (n : Cardinal) < card o ↔ (n : Ordinal) < o := by rw [← succ_le_iff, ← succ_le_iff, ← nat_succ, nat_le_card] rfl @[simp] theorem zero_lt_card {o} : 0 < card o ↔ 0 < o := by simpa using nat_lt_card (n := 0) @[simp] theorem one_lt_card {o} : 1 < card o ↔ 1 < o := by simpa using nat_lt_card (n := 1) @[simp] theorem ofNat_lt_card {o} {n : ℕ} [n.AtLeastTwo] : (ofNat(n) : Cardinal) < card o ↔ (OfNat.ofNat n : Ordinal) < o := nat_lt_card @[simp] theorem card_lt_nat {o} {n : ℕ} : card o < n ↔ o < n := lt_iff_lt_of_le_iff_le nat_le_card @[simp] theorem card_lt_ofNat {o} {n : ℕ} [n.AtLeastTwo] : card o < ofNat(n) ↔ o < OfNat.ofNat n := card_lt_nat @[simp] theorem card_le_nat {o} {n : ℕ} : card o ≤ n ↔ o ≤ n := le_iff_le_iff_lt_iff_lt.2 nat_lt_card @[simp] theorem card_le_one {o} : card o ≤ 1 ↔ o ≤ 1 := by simpa using card_le_nat (n := 1) @[simp] theorem card_le_ofNat {o} {n : ℕ} [n.AtLeastTwo] : card o ≤ ofNat(n) ↔ o ≤ OfNat.ofNat n := card_le_nat @[simp] theorem card_eq_nat {o} {n : ℕ} : card o = n ↔ o = n := by simp only [le_antisymm_iff, card_le_nat, nat_le_card] @[simp] theorem card_eq_zero {o} : card o = 0 ↔ o = 0 := by simpa using card_eq_nat (n := 0) @[simp] theorem card_eq_one {o} : card o = 1 ↔ o = 1 := by simpa using card_eq_nat (n := 1) theorem mem_range_lift_of_card_le {a : Cardinal.{u}} {b : Ordinal.{max u v}} (h : card b ≤ Cardinal.lift.{v, u} a) : b ∈ Set.range lift.{v, u} := by rw [card_le_iff, ← lift_succ, ← lift_ord] at h exact mem_range_lift_of_le h.le @[simp] theorem card_eq_ofNat {o} {n : ℕ} [n.AtLeastTwo] : card o = ofNat(n) ↔ o = OfNat.ofNat n := card_eq_nat @[simp] theorem type_fintype (r : α → α → Prop) [IsWellOrder α r] [Fintype α] : type r = Fintype.card α := by rw [← card_eq_nat, card_type, mk_fintype] theorem type_fin (n : ℕ) : typeLT (Fin n) = n := by simp end Ordinal /-! ### Sorted lists -/ theorem List.Sorted.lt_ord_of_lt [LinearOrder α] [WellFoundedLT α] {l m : List α} {o : Ordinal} (hl : l.Sorted (· > ·)) (hm : m.Sorted (· > ·)) (hmltl : m < l) (hlt : ∀ i ∈ l, Ordinal.typein (α := α) (· < ·) i < o) : ∀ i ∈ m, Ordinal.typein (α := α) (· < ·) i < o := by replace hmltl : List.Lex (· < ·) m l := hmltl cases l with \| nil => simp at hmltl \| cons a as => cases m with \| nil => intro i hi; simp at hi \| cons b bs => intro i hi suffices h : i ≤ a by refine lt_of_le_of_lt ?_ (hlt a mem_cons_self); simpa cases hi with \| head as => exact List.head_le_of_lt hmltl \| tail b hi => exact le_of_lt (lt_of_lt_of_le (List.rel_of_sorted_cons hm _ hi) (List.head_le_of_lt hmltl))		Mathlib/SetTheory/Ordinal/Basic.lean	1,498	1,500
/- Copyright (c) 2020 Yury Kudryashov. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yury Kudryashov -/ import Mathlib.LinearAlgebra.Quotient.Basic import Mathlib.LinearAlgebra.Prod /-! # Projection to a subspace In this file we define * `Submodule.linearProjOfIsCompl (p q : Submodule R E) (h : IsCompl p q)`: the projection of a module `E` to a submodule `p` along its complement `q`; it is the unique linear map `f : E → p` such that `f x = x` for `x ∈ p` and `f x = 0` for `x ∈ q`. * `Submodule.isComplEquivProj p`: equivalence between submodules `q` such that `IsCompl p q` and projections `f : E → p`, `∀ x ∈ p, f x = x`. We also provide some lemmas justifying correctness of our definitions. ## Tags projection, complement subspace -/ noncomputable section Ring variable {R : Type} [Ring R] {E : Type} [AddCommGroup E] [Module R E] variable {F : Type} [AddCommGroup F] [Module R F] {G : Type} [AddCommGroup G] [Module R G] variable (p q : Submodule R E) variable {S : Type} [Semiring S] {M : Type} [AddCommMonoid M] [Module S M] (m : Submodule S M) namespace LinearMap variable {p} open Submodule theorem ker_id_sub_eq_of_proj {f : E →ₗ[R] p} (hf : ∀ x : p, f x = x) : ker (id - p.subtype.comp f) = p := by ext x simp only [comp_apply, mem_ker, subtype_apply, sub_apply, id_apply, sub_eq_zero] exact ⟨fun h => h.symm ▸ Submodule.coe_mem _, fun hx => by rw [hf ⟨x, hx⟩, Subtype.coe_mk]⟩ theorem range_eq_of_proj {f : E →ₗ[R] p} (hf : ∀ x : p, f x = x) : range f = ⊤ := range_eq_top.2 fun x => ⟨x, hf x⟩ theorem isCompl_of_proj {f : E →ₗ[R] p} (hf : ∀ x : p, f x = x) : IsCompl p (ker f) := by constructor · rw [disjoint_iff_inf_le] rintro x ⟨hpx, hfx⟩ rw [SetLike.mem_coe, mem_ker, hf ⟨x, hpx⟩, mk_eq_zero] at hfx simp only [hfx, SetLike.mem_coe, zero_mem] · rw [codisjoint_iff_le_sup] intro x _ rw [mem_sup'] refine ⟨f x, ⟨x - f x, ?_⟩, add_sub_cancel _ _⟩ rw [mem_ker, LinearMap.map_sub, hf, sub_self] end LinearMap namespace Submodule open LinearMap /-- If `q` is a complement of `p`, then `M/p ≃ q`. -/ def quotientEquivOfIsCompl (h : IsCompl p q) : (E ⧸ p) ≃ₗ[R] q := LinearEquiv.symm <\| LinearEquiv.ofBijective (p.mkQ.comp q.subtype) ⟨by rw [← ker_eq_bot, ker_comp, ker_mkQ, disjoint_iff_comap_eq_bot.1 h.symm.disjoint], by rw [← range_eq_top, range_comp, range_subtype, map_mkQ_eq_top, h.sup_eq_top]⟩ @[simp] theorem quotientEquivOfIsCompl_symm_apply (h : IsCompl p q) (x : q) : -- Porting note: type ascriptions needed on the RHS (quotientEquivOfIsCompl p q h).symm x = (Quotient.mk x : E ⧸ p) := rfl @[simp] theorem quotientEquivOfIsCompl_apply_mk_coe (h : IsCompl p q) (x : q) : quotientEquivOfIsCompl p q h (Quotient.mk x) = x := (quotientEquivOfIsCompl p q h).apply_symm_apply x @[simp] theorem mk_quotientEquivOfIsCompl_apply (h : IsCompl p q) (x : E ⧸ p) : (Quotient.mk (quotientEquivOfIsCompl p q h x) : E ⧸ p) = x := (quotientEquivOfIsCompl p q h).symm_apply_apply x /-- If `q` is a complement of `p`, then `p × q` is isomorphic to `E`. It is the unique linear map `f : E → p` such that `f x = x` for `x ∈ p` and `f x = 0` for `x ∈ q`. -/ def prodEquivOfIsCompl (h : IsCompl p q) : (p × q) ≃ₗ[R] E := by apply LinearEquiv.ofBijective (p.subtype.coprod q.subtype) constructor · rw [← ker_eq_bot, ker_coprod_of_disjoint_range, ker_subtype, ker_subtype, prod_bot] rw [range_subtype, range_subtype] exact h.1 · rw [← range_eq_top, ← sup_eq_range, h.sup_eq_top] @[simp] theorem coe_prodEquivOfIsCompl (h : IsCompl p q) : (prodEquivOfIsCompl p q h : p × q →ₗ[R] E) = p.subtype.coprod q.subtype := rfl @[simp] theorem coe_prodEquivOfIsCompl' (h : IsCompl p q) (x : p × q) : prodEquivOfIsCompl p q h x = x.1 + x.2 := rfl @[simp] theorem prodEquivOfIsCompl_symm_apply_left (h : IsCompl p q) (x : p) : (prodEquivOfIsCompl p q h).symm x = (x, 0) := (prodEquivOfIsCompl p q h).symm_apply_eq.2 <\| by simp @[simp] theorem prodEquivOfIsCompl_symm_apply_right (h : IsCompl p q) (x : q) : (prodEquivOfIsCompl p q h).symm x = (0, x) := (prodEquivOfIsCompl p q h).symm_apply_eq.2 <\| by simp @[simp] theorem prodEquivOfIsCompl_symm_apply_fst_eq_zero (h : IsCompl p q) {x : E} : ((prodEquivOfIsCompl p q h).symm x).1 = 0 ↔ x ∈ q := by conv_rhs => rw [← (prodEquivOfIsCompl p q h).apply_symm_apply x] rw [coe_prodEquivOfIsCompl', Submodule.add_mem_iff_left _ (Submodule.coe_mem _), mem_right_iff_eq_zero_of_disjoint h.disjoint] @[simp] theorem prodEquivOfIsCompl_symm_apply_snd_eq_zero (h : IsCompl p q) {x : E} : ((prodEquivOfIsCompl p q h).symm x).2 = 0 ↔ x ∈ p := by conv_rhs => rw [← (prodEquivOfIsCompl p q h).apply_symm_apply x] rw [coe_prodEquivOfIsCompl', Submodule.add_mem_iff_right _ (Submodule.coe_mem _), mem_left_iff_eq_zero_of_disjoint h.disjoint] @[simp]	theorem prodComm_trans_prodEquivOfIsCompl (h : IsCompl p q) : LinearEquiv.prodComm R q p ≪≫ₗ prodEquivOfIsCompl p q h = prodEquivOfIsCompl q p h.symm := LinearEquiv.ext fun _ => add_comm _ _ /-- Projection to a submodule along a complement.	Mathlib/LinearAlgebra/Projection.lean	131	135
/- Copyright (c) 2018 Kenny Lau. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Anne Baanen -/ import Mathlib.Algebra.Algebra.Bilinear import Mathlib.LinearAlgebra.Basis.Defs import Mathlib.LinearAlgebra.Basis.Submodule import Mathlib.RingTheory.Ideal.Span /-! # The basis of ideals Some results involving `Ideal` and `Basis`. -/ namespace Ideal variable {ι R S : Type} [CommSemiring R] [CommRing S] [IsDomain S] [Algebra R S] /-- A basis on `S` gives a basis on `Ideal.span {x}`, by multiplying everything by `x`. -/ noncomputable def basisSpanSingleton (b : Basis ι R S) {x : S} (hx : x ≠ 0) : Basis ι R (span ({x} : Set S)) := b.map <\| LinearEquiv.ofInjective (LinearMap.mulLeft R x) (mul_right_injective₀ hx) ≪≫ₗ LinearEquiv.ofEq _ _ (by ext simp [mem_span_singleton', mul_comm]) ≪≫ₗ (Submodule.restrictScalarsEquiv R S S (Ideal.span ({x} : Set S))).restrictScalars R @[simp] theorem basisSpanSingleton_apply (b : Basis ι R S) {x : S} (hx : x ≠ 0) (i : ι) : (basisSpanSingleton b hx i : S) = x b i := by simp only [basisSpanSingleton, Basis.map_apply, LinearEquiv.trans_apply, Submodule.restrictScalarsEquiv_apply, LinearEquiv.ofInjective_apply, LinearEquiv.coe_ofEq_apply, LinearEquiv.restrictScalars_apply, LinearMap.mulLeft_apply, LinearMap.mul_apply'] @[simp] theorem constr_basisSpanSingleton {N : Type*} [Semiring N] [Module N S] [SMulCommClass R N S] (b : Basis ι R S) {x : S} (hx : x ≠ 0) : (b.constr N).toFun (((↑) : _ → S) ∘ (basisSpanSingleton b hx)) = Algebra.lmul R S x :=	b.ext fun i => by simp end Ideal -- Porting note: added explicit coercion `(b i : S)`	Mathlib/RingTheory/Ideal/Basis.lean	43	47
/- Copyright (c) 2021 Oliver Nash. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Oliver Nash -/ import Mathlib.Algebra.Lie.Subalgebra import Mathlib.LinearAlgebra.Finsupp.Span /-! # Lie submodules of a Lie algebra In this file we define Lie submodules, we construct the lattice structure on Lie submodules and we use it to define various important operations, notably the Lie span of a subset of a Lie module. ## Main definitions * `LieSubmodule` * `LieSubmodule.wellFounded_of_noetherian` * `LieSubmodule.lieSpan` * `LieSubmodule.map` * `LieSubmodule.comap` ## Tags lie algebra, lie submodule, lie ideal, lattice structure -/ universe u v w w₁ w₂ section LieSubmodule variable (R : Type u) (L : Type v) (M : Type w) variable [CommRing R] [LieRing L] [AddCommGroup M] [Module R M] variable [LieRingModule L M] /-- A Lie submodule of a Lie module is a submodule that is closed under the Lie bracket. This is a sufficient condition for the subset itself to form a Lie module. -/ structure LieSubmodule extends Submodule R M where lie_mem : ∀ {x : L} {m : M}, m ∈ carrier → ⁅x, m⁆ ∈ carrier attribute [nolint docBlame] LieSubmodule.toSubmodule attribute [coe] LieSubmodule.toSubmodule namespace LieSubmodule variable {R L M} variable (N N' : LieSubmodule R L M) instance : SetLike (LieSubmodule R L M) M where coe s := s.carrier coe_injective' N O h := by cases N; cases O; congr; exact SetLike.coe_injective' h instance : AddSubgroupClass (LieSubmodule R L M) M where add_mem {N} _ _ := N.add_mem' zero_mem N := N.zero_mem' neg_mem {N} x hx := show -x ∈ N.toSubmodule from neg_mem hx instance instSMulMemClass : SMulMemClass (LieSubmodule R L M) R M where smul_mem {s} c _ h := s.smul_mem' c h /-- The zero module is a Lie submodule of any Lie module. -/ instance : Zero (LieSubmodule R L M) := ⟨{ (0 : Submodule R M) with lie_mem := fun {x m} h ↦ by rw [(Submodule.mem_bot R).1 h]; apply lie_zero }⟩ instance : Inhabited (LieSubmodule R L M) := ⟨0⟩ instance (priority := high) coeSort : CoeSort (LieSubmodule R L M) (Type w) where coe N := { x : M // x ∈ N } instance (priority := mid) coeSubmodule : CoeOut (LieSubmodule R L M) (Submodule R M) := ⟨toSubmodule⟩ instance : CanLift (Submodule R M) (LieSubmodule R L M) (·) (fun N ↦ ∀ {x : L} {m : M}, m ∈ N → ⁅x, m⁆ ∈ N) where prf N hN := ⟨⟨N, hN⟩, rfl⟩ @[norm_cast] theorem coe_toSubmodule : ((N : Submodule R M) : Set M) = N := rfl theorem mem_carrier {x : M} : x ∈ N.carrier ↔ x ∈ (N : Set M) := Iff.rfl theorem mem_mk_iff (S : Set M) (h₁ h₂ h₃ h₄) {x : M} : x ∈ (⟨⟨⟨⟨S, h₁⟩, h₂⟩, h₃⟩, h₄⟩ : LieSubmodule R L M) ↔ x ∈ S := Iff.rfl @[simp] theorem mem_mk_iff' (p : Submodule R M) (h) {x : M} : x ∈ (⟨p, h⟩ : LieSubmodule R L M) ↔ x ∈ p := Iff.rfl @[simp] theorem mem_toSubmodule {x : M} : x ∈ (N : Submodule R M) ↔ x ∈ N := Iff.rfl @[deprecated (since := "2024-12-30")] alias mem_coeSubmodule := mem_toSubmodule theorem mem_coe {x : M} : x ∈ (N : Set M) ↔ x ∈ N := Iff.rfl @[simp] protected theorem zero_mem : (0 : M) ∈ N := zero_mem N @[simp] theorem mk_eq_zero {x} (h : x ∈ N) : (⟨x, h⟩ : N) = 0 ↔ x = 0 := Subtype.ext_iff_val @[simp] theorem coe_toSet_mk (S : Set M) (h₁ h₂ h₃ h₄) : ((⟨⟨⟨⟨S, h₁⟩, h₂⟩, h₃⟩, h₄⟩ : LieSubmodule R L M) : Set M) = S := rfl theorem toSubmodule_mk (p : Submodule R M) (h) : (({ p with lie_mem := h } : LieSubmodule R L M) : Submodule R M) = p := by cases p; rfl @[deprecated (since := "2024-12-30")] alias coe_toSubmodule_mk := toSubmodule_mk theorem toSubmodule_injective : Function.Injective (toSubmodule : LieSubmodule R L M → Submodule R M) := fun x y h ↦ by cases x; cases y; congr @[deprecated (since := "2024-12-30")] alias coeSubmodule_injective := toSubmodule_injective @[ext] theorem ext (h : ∀ m, m ∈ N ↔ m ∈ N') : N = N' := SetLike.ext h @[simp] theorem toSubmodule_inj : (N : Submodule R M) = (N' : Submodule R M) ↔ N = N' := toSubmodule_injective.eq_iff @[deprecated (since := "2024-12-30")] alias coe_toSubmodule_inj := toSubmodule_inj @[deprecated (since := "2024-12-29")] alias toSubmodule_eq_iff := toSubmodule_inj /-- Copy of a `LieSubmodule` with a new `carrier` equal to the old one. Useful to fix definitional equalities. -/ protected def copy (s : Set M) (hs : s = ↑N) : LieSubmodule R L M where carrier := s zero_mem' := by simp [hs] add_mem' x y := by rw [hs] at x y ⊢; exact N.add_mem' x y smul_mem' := by exact hs.symm ▸ N.smul_mem' lie_mem := by exact hs.symm ▸ N.lie_mem @[simp] theorem coe_copy (S : LieSubmodule R L M) (s : Set M) (hs : s = ↑S) : (S.copy s hs : Set M) = s := rfl theorem copy_eq (S : LieSubmodule R L M) (s : Set M) (hs : s = ↑S) : S.copy s hs = S := SetLike.coe_injective hs instance : LieRingModule L N where bracket (x : L) (m : N) := ⟨⁅x, m.val⁆, N.lie_mem m.property⟩ add_lie := by intro x y m; apply SetCoe.ext; apply add_lie lie_add := by intro x m n; apply SetCoe.ext; apply lie_add leibniz_lie := by intro x y m; apply SetCoe.ext; apply leibniz_lie @[simp, norm_cast] theorem coe_zero : ((0 : N) : M) = (0 : M) := rfl @[simp, norm_cast] theorem coe_add (m m' : N) : (↑(m + m') : M) = (m : M) + (m' : M) := rfl @[simp, norm_cast] theorem coe_neg (m : N) : (↑(-m) : M) = -(m : M) := rfl @[simp, norm_cast] theorem coe_sub (m m' : N) : (↑(m - m') : M) = (m : M) - (m' : M) := rfl @[simp, norm_cast] theorem coe_smul (t : R) (m : N) : (↑(t • m) : M) = t • (m : M) := rfl @[simp, norm_cast] theorem coe_bracket (x : L) (m : N) : (↑⁅x, m⁆ : M) = ⁅x, ↑m⁆ := rfl -- Copying instances from `Submodule` for correct discrimination keys instance [IsNoetherian R M] (N : LieSubmodule R L M) : IsNoetherian R N := inferInstanceAs <\| IsNoetherian R N.toSubmodule instance [IsArtinian R M] (N : LieSubmodule R L M) : IsArtinian R N := inferInstanceAs <\| IsArtinian R N.toSubmodule instance [NoZeroSMulDivisors R M] : NoZeroSMulDivisors R N := inferInstanceAs <\| NoZeroSMulDivisors R N.toSubmodule variable [LieAlgebra R L] [LieModule R L M] instance instLieModule : LieModule R L N where lie_smul := by intro t x y; apply SetCoe.ext; apply lie_smul smul_lie := by intro t x y; apply SetCoe.ext; apply smul_lie instance [Subsingleton M] : Unique (LieSubmodule R L M) := ⟨⟨0⟩, fun _ ↦ (toSubmodule_inj _ _).mp (Subsingleton.elim _ _)⟩ end LieSubmodule variable {R M} theorem Submodule.exists_lieSubmodule_coe_eq_iff (p : Submodule R M) : (∃ N : LieSubmodule R L M, ↑N = p) ↔ ∀ (x : L) (m : M), m ∈ p → ⁅x, m⁆ ∈ p := by constructor · rintro ⟨N, rfl⟩ _ _; exact N.lie_mem · intro h; use { p with lie_mem := @h } namespace LieSubalgebra variable {L} variable [LieAlgebra R L] variable (K : LieSubalgebra R L) /-- Given a Lie subalgebra `K ⊆ L`, if we view `L` as a `K`-module by restriction, it contains a distinguished Lie submodule for the action of `K`, namely `K` itself. -/ def toLieSubmodule : LieSubmodule R K L := { (K : Submodule R L) with lie_mem := fun {x _} hy ↦ K.lie_mem x.property hy } @[simp] theorem coe_toLieSubmodule : (K.toLieSubmodule : Submodule R L) = K := rfl variable {K} @[simp] theorem mem_toLieSubmodule (x : L) : x ∈ K.toLieSubmodule ↔ x ∈ K := Iff.rfl end LieSubalgebra end LieSubmodule namespace LieSubmodule variable {R : Type u} {L : Type v} {M : Type w} variable [CommRing R] [LieRing L] [AddCommGroup M] [Module R M] variable [LieRingModule L M] variable (N N' : LieSubmodule R L M) section LatticeStructure open Set theorem coe_injective : Function.Injective ((↑) : LieSubmodule R L M → Set M) := SetLike.coe_injective @[simp, norm_cast] theorem toSubmodule_le_toSubmodule : (N : Submodule R M) ≤ N' ↔ N ≤ N' := Iff.rfl @[deprecated (since := "2024-12-30")] alias coeSubmodule_le_coeSubmodule := toSubmodule_le_toSubmodule instance : Bot (LieSubmodule R L M) := ⟨0⟩ instance instUniqueBot : Unique (⊥ : LieSubmodule R L M) := inferInstanceAs <\| Unique (⊥ : Submodule R M) @[simp] theorem bot_coe : ((⊥ : LieSubmodule R L M) : Set M) = {0} := rfl @[simp] theorem bot_toSubmodule : ((⊥ : LieSubmodule R L M) : Submodule R M) = ⊥ := rfl @[deprecated (since := "2024-12-30")] alias bot_coeSubmodule := bot_toSubmodule @[simp] theorem toSubmodule_eq_bot : (N : Submodule R M) = ⊥ ↔ N = ⊥ := by rw [← toSubmodule_inj, bot_toSubmodule] @[deprecated (since := "2024-12-30")] alias coeSubmodule_eq_bot_iff := toSubmodule_eq_bot @[simp] theorem mk_eq_bot_iff {N : Submodule R M} {h} : (⟨N, h⟩ : LieSubmodule R L M) = ⊥ ↔ N = ⊥ := by rw [← toSubmodule_inj, bot_toSubmodule] @[simp] theorem mem_bot (x : M) : x ∈ (⊥ : LieSubmodule R L M) ↔ x = 0 := mem_singleton_iff instance : Top (LieSubmodule R L M) := ⟨{ (⊤ : Submodule R M) with lie_mem := fun {x m} _ ↦ mem_univ ⁅x, m⁆ }⟩ @[simp] theorem top_coe : ((⊤ : LieSubmodule R L M) : Set M) = univ := rfl @[simp] theorem top_toSubmodule : ((⊤ : LieSubmodule R L M) : Submodule R M) = ⊤ := rfl @[deprecated (since := "2024-12-30")] alias top_coeSubmodule := top_toSubmodule @[simp] theorem toSubmodule_eq_top : (N : Submodule R M) = ⊤ ↔ N = ⊤ := by rw [← toSubmodule_inj, top_toSubmodule] @[deprecated (since := "2024-12-30")] alias coeSubmodule_eq_top_iff := toSubmodule_eq_top @[simp] theorem mk_eq_top_iff {N : Submodule R M} {h} : (⟨N, h⟩ : LieSubmodule R L M) = ⊤ ↔ N = ⊤ := by rw [← toSubmodule_inj, top_toSubmodule] @[simp] theorem mem_top (x : M) : x ∈ (⊤ : LieSubmodule R L M) := mem_univ x instance : Min (LieSubmodule R L M) := ⟨fun N N' ↦ { (N ⊓ N' : Submodule R M) with lie_mem := fun h ↦ mem_inter (N.lie_mem h.1) (N'.lie_mem h.2) }⟩ instance : InfSet (LieSubmodule R L M) := ⟨fun S ↦ { toSubmodule := sInf {(s : Submodule R M) \| s ∈ S} lie_mem := fun {x m} h ↦ by simp only [Submodule.mem_carrier, mem_iInter, Submodule.sInf_coe, mem_setOf_eq, forall_apply_eq_imp_iff₂, forall_exists_index, and_imp] at h ⊢ intro N hN; apply N.lie_mem (h N hN) }⟩ @[simp] theorem inf_coe : (↑(N ⊓ N') : Set M) = ↑N ∩ ↑N' := rfl @[norm_cast, simp] theorem inf_toSubmodule : (↑(N ⊓ N') : Submodule R M) = (N : Submodule R M) ⊓ (N' : Submodule R M) := rfl @[deprecated (since := "2024-12-30")] alias inf_coe_toSubmodule := inf_toSubmodule @[simp] theorem sInf_toSubmodule (S : Set (LieSubmodule R L M)) : (↑(sInf S) : Submodule R M) = sInf {(s : Submodule R M) \| s ∈ S} := rfl @[deprecated (since := "2024-12-30")] alias sInf_coe_toSubmodule := sInf_toSubmodule theorem sInf_toSubmodule_eq_iInf (S : Set (LieSubmodule R L M)) : (↑(sInf S) : Submodule R M) = ⨅ N ∈ S, (N : Submodule R M) := by rw [sInf_toSubmodule, ← Set.image, sInf_image] @[deprecated (since := "2024-12-30")] alias sInf_coe_toSubmodule' := sInf_toSubmodule_eq_iInf @[simp] theorem iInf_toSubmodule {ι} (p : ι → LieSubmodule R L M) : (↑(⨅ i, p i) : Submodule R M) = ⨅ i, (p i : Submodule R M) := by rw [iInf, sInf_toSubmodule]; ext; simp @[deprecated (since := "2024-12-30")] alias iInf_coe_toSubmodule := iInf_toSubmodule @[simp] theorem sInf_coe (S : Set (LieSubmodule R L M)) : (↑(sInf S) : Set M) = ⋂ s ∈ S, (s : Set M) := by rw [← LieSubmodule.coe_toSubmodule, sInf_toSubmodule, Submodule.sInf_coe] ext m simp only [mem_iInter, mem_setOf_eq, forall_apply_eq_imp_iff₂, exists_imp, and_imp, SetLike.mem_coe, mem_toSubmodule] @[simp] theorem iInf_coe {ι} (p : ι → LieSubmodule R L M) : (↑(⨅ i, p i) : Set M) = ⋂ i, ↑(p i) := by rw [iInf, sInf_coe]; simp only [Set.mem_range, Set.iInter_exists, Set.iInter_iInter_eq'] @[simp] theorem mem_iInf {ι} (p : ι → LieSubmodule R L M) {x} : (x ∈ ⨅ i, p i) ↔ ∀ i, x ∈ p i := by rw [← SetLike.mem_coe, iInf_coe, Set.mem_iInter]; rfl instance : Max (LieSubmodule R L M) where max N N' := { toSubmodule := (N : Submodule R M) ⊔ (N' : Submodule R M) lie_mem := by rintro x m (hm : m ∈ (N : Submodule R M) ⊔ (N' : Submodule R M)) change ⁅x, m⁆ ∈ (N : Submodule R M) ⊔ (N' : Submodule R M) rw [Submodule.mem_sup] at hm ⊢ obtain ⟨y, hy, z, hz, rfl⟩ := hm exact ⟨⁅x, y⁆, N.lie_mem hy, ⁅x, z⁆, N'.lie_mem hz, (lie_add _ _ _).symm⟩ } instance : SupSet (LieSubmodule R L M) where sSup S := { toSubmodule := sSup {(p : Submodule R M) \| p ∈ S} lie_mem := by intro x m (hm : m ∈ sSup {(p : Submodule R M) \| p ∈ S}) change ⁅x, m⁆ ∈ sSup {(p : Submodule R M) \| p ∈ S} obtain ⟨s, hs, hsm⟩ := Submodule.mem_sSup_iff_exists_finset.mp hm clear hm classical induction s using Finset.induction_on generalizing m with \| empty => replace hsm : m = 0 := by simpa using hsm simp [hsm] \| insert q t hqt ih => rw [Finset.iSup_insert] at hsm obtain ⟨m', hm', u, hu, rfl⟩ := Submodule.mem_sup.mp hsm rw [lie_add] refine add_mem ?_ (ih (Subset.trans (by simp) hs) hu) obtain ⟨p, hp, rfl⟩ : ∃ p ∈ S, ↑p = q := hs (Finset.mem_insert_self q t) suffices p ≤ sSup {(p : Submodule R M) \| p ∈ S} by exact this (p.lie_mem hm') exact le_sSup ⟨p, hp, rfl⟩ } @[norm_cast, simp] theorem sup_toSubmodule : (↑(N ⊔ N') : Submodule R M) = (N : Submodule R M) ⊔ (N' : Submodule R M) := by rfl @[deprecated (since := "2024-12-30")] alias sup_coe_toSubmodule := sup_toSubmodule @[simp] theorem sSup_toSubmodule (S : Set (LieSubmodule R L M)) : (↑(sSup S) : Submodule R M) = sSup {(s : Submodule R M) \| s ∈ S} := rfl @[deprecated (since := "2024-12-30")] alias sSup_coe_toSubmodule := sSup_toSubmodule theorem sSup_toSubmodule_eq_iSup (S : Set (LieSubmodule R L M)) : (↑(sSup S) : Submodule R M) = ⨆ N ∈ S, (N : Submodule R M) := by rw [sSup_toSubmodule, ← Set.image, sSup_image] @[deprecated (since := "2024-12-30")] alias sSup_coe_toSubmodule' := sSup_toSubmodule_eq_iSup @[simp] theorem iSup_toSubmodule {ι} (p : ι → LieSubmodule R L M) : (↑(⨆ i, p i) : Submodule R M) = ⨆ i, (p i : Submodule R M) := by rw [iSup, sSup_toSubmodule]; ext; simp [Submodule.mem_sSup, Submodule.mem_iSup] @[deprecated (since := "2024-12-30")] alias iSup_coe_toSubmodule := iSup_toSubmodule /-- The set of Lie submodules of a Lie module form a complete lattice. -/ instance : CompleteLattice (LieSubmodule R L M) := { toSubmodule_injective.completeLattice toSubmodule sup_toSubmodule inf_toSubmodule sSup_toSubmodule_eq_iSup sInf_toSubmodule_eq_iInf rfl rfl with toPartialOrder := SetLike.instPartialOrder } theorem mem_iSup_of_mem {ι} {b : M} {N : ι → LieSubmodule R L M} (i : ι) (h : b ∈ N i) : b ∈ ⨆ i, N i := (le_iSup N i) h @[elab_as_elim] lemma iSup_induction {ι} (N : ι → LieSubmodule R L M) {motive : M → Prop} {x : M} (hx : x ∈ ⨆ i, N i) (mem : ∀ i, ∀ y ∈ N i, motive y) (zero : motive 0) (add : ∀ y z, motive y → motive z → motive (y + z)) : motive x := by rw [← LieSubmodule.mem_toSubmodule, LieSubmodule.iSup_toSubmodule] at hx exact Submodule.iSup_induction (motive := motive) (fun i ↦ (N i : Submodule R M)) hx mem zero add @[elab_as_elim] theorem iSup_induction' {ι} (N : ι → LieSubmodule R L M) {motive : (x : M) → (x ∈ ⨆ i, N i) → Prop} (mem : ∀ (i) (x) (hx : x ∈ N i), motive x (mem_iSup_of_mem i hx)) (zero : motive 0 (zero_mem _)) (add : ∀ x y hx hy, motive x hx → motive y hy → motive (x + y) (add_mem ‹_› ‹_›)) {x : M} (hx : x ∈ ⨆ i, N i) : motive x hx := by refine Exists.elim ?_ fun (hx : x ∈ ⨆ i, N i) (hc : motive x hx) => hc refine iSup_induction N (motive := fun x : M ↦ ∃ (hx : x ∈ ⨆ i, N i), motive x hx) hx (fun i x hx => ?_) ?_ fun x y => ?_ · exact ⟨_, mem _ _ hx⟩ · exact ⟨_, zero⟩ · rintro ⟨_, Cx⟩ ⟨_, Cy⟩ exact ⟨_, add _ _ _ _ Cx Cy⟩ variable {N N'} @[simp] lemma disjoint_toSubmodule : Disjoint (N : Submodule R M) (N' : Submodule R M) ↔ Disjoint N N' := by rw [disjoint_iff, disjoint_iff, ← toSubmodule_inj, inf_toSubmodule, bot_toSubmodule, ← disjoint_iff] @[deprecated disjoint_toSubmodule (since := "2025-04-03")] theorem disjoint_iff_toSubmodule : Disjoint N N' ↔ Disjoint (N : Submodule R M) (N' : Submodule R M) := disjoint_toSubmodule.symm @[deprecated (since := "2024-12-30")] alias disjoint_iff_coe_toSubmodule := disjoint_iff_toSubmodule @[simp] lemma codisjoint_toSubmodule : Codisjoint (N : Submodule R M) (N' : Submodule R M) ↔ Codisjoint N N' := by rw [codisjoint_iff, codisjoint_iff, ← toSubmodule_inj, sup_toSubmodule, top_toSubmodule, ← codisjoint_iff] @[deprecated codisjoint_toSubmodule (since := "2025-04-03")] theorem codisjoint_iff_toSubmodule : Codisjoint N N' ↔ Codisjoint (N : Submodule R M) (N' : Submodule R M) := codisjoint_toSubmodule.symm @[deprecated (since := "2024-12-30")] alias codisjoint_iff_coe_toSubmodule := codisjoint_iff_toSubmodule @[simp] lemma isCompl_toSubmodule : IsCompl (N : Submodule R M) (N' : Submodule R M) ↔ IsCompl N N' := by simp [isCompl_iff] @[deprecated isCompl_toSubmodule (since := "2025-04-03")] theorem isCompl_iff_toSubmodule : IsCompl N N' ↔ IsCompl (N : Submodule R M) (N' : Submodule R M) := isCompl_toSubmodule.symm @[deprecated (since := "2024-12-30")] alias isCompl_iff_coe_toSubmodule := isCompl_iff_toSubmodule @[simp] lemma iSupIndep_toSubmodule {ι : Type} {N : ι → LieSubmodule R L M} : iSupIndep (fun i ↦ (N i : Submodule R M)) ↔ iSupIndep N := by simp [iSupIndep_def, ← disjoint_toSubmodule] @[deprecated iSupIndep_toSubmodule (since := "2025-04-03")] theorem iSupIndep_iff_toSubmodule {ι : Type} {N : ι → LieSubmodule R L M} : iSupIndep N ↔ iSupIndep fun i ↦ (N i : Submodule R M) := iSupIndep_toSubmodule.symm @[deprecated (since := "2024-12-30")] alias iSupIndep_iff_coe_toSubmodule := iSupIndep_iff_toSubmodule @[deprecated (since := "2024-11-24")] alias independent_iff_toSubmodule := iSupIndep_iff_toSubmodule @[deprecated (since := "2024-12-30")] alias independent_iff_coe_toSubmodule := independent_iff_toSubmodule @[simp] lemma iSup_toSubmodule_eq_top {ι : Sort} {N : ι → LieSubmodule R L M} : ⨆ i, (N i : Submodule R M) = ⊤ ↔ ⨆ i, N i = ⊤ := by rw [← iSup_toSubmodule, ← top_toSubmodule (L := L), toSubmodule_inj] @[deprecated iSup_toSubmodule_eq_top (since := "2025-04-03")] theorem iSup_eq_top_iff_toSubmodule {ι : Sort} {N : ι → LieSubmodule R L M} : ⨆ i, N i = ⊤ ↔ ⨆ i, (N i : Submodule R M) = ⊤ := iSup_toSubmodule_eq_top.symm @[deprecated (since := "2024-12-30")] alias iSup_eq_top_iff_coe_toSubmodule := iSup_eq_top_iff_toSubmodule instance : Add (LieSubmodule R L M) where add := max instance : Zero (LieSubmodule R L M) where zero := ⊥ instance : AddCommMonoid (LieSubmodule R L M) where add_assoc := sup_assoc zero_add := bot_sup_eq add_zero := sup_bot_eq add_comm := sup_comm nsmul := nsmulRec variable (N N') @[simp] theorem add_eq_sup : N + N' = N ⊔ N' := rfl @[simp] theorem mem_inf (x : M) : x ∈ N ⊓ N' ↔ x ∈ N ∧ x ∈ N' := by rw [← mem_toSubmodule, ← mem_toSubmodule, ← mem_toSubmodule, inf_toSubmodule, Submodule.mem_inf] theorem mem_sup (x : M) : x ∈ N ⊔ N' ↔ ∃ y ∈ N, ∃ z ∈ N', y + z = x := by rw [← mem_toSubmodule, sup_toSubmodule, Submodule.mem_sup]; exact Iff.rfl nonrec theorem eq_bot_iff : N = ⊥ ↔ ∀ m : M, m ∈ N → m = 0 := by rw [eq_bot_iff]; exact Iff.rfl instance subsingleton_of_bot : Subsingleton (LieSubmodule R L (⊥ : LieSubmodule R L M)) := by apply subsingleton_of_bot_eq_top ext ⟨_, hx⟩ simp only [mem_bot, mk_eq_zero, mem_top, iff_true] exact hx instance : IsModularLattice (LieSubmodule R L M) where sup_inf_le_assoc_of_le _ _ := by simp only [← toSubmodule_le_toSubmodule, sup_toSubmodule, inf_toSubmodule] exact IsModularLattice.sup_inf_le_assoc_of_le _ variable (R L M) /-- The natural functor that forgets the action of `L` as an order embedding. -/ @[simps] def toSubmodule_orderEmbedding : LieSubmodule R L M ↪o Submodule R M := { toFun := (↑) inj' := toSubmodule_injective map_rel_iff' := Iff.rfl } instance wellFoundedGT_of_noetherian [IsNoetherian R M] : WellFoundedGT (LieSubmodule R L M) := RelHomClass.isWellFounded (toSubmodule_orderEmbedding R L M).dual.ltEmbedding theorem wellFoundedLT_of_isArtinian [IsArtinian R M] : WellFoundedLT (LieSubmodule R L M) := RelHomClass.isWellFounded (toSubmodule_orderEmbedding R L M).ltEmbedding instance [IsArtinian R M] : IsAtomic (LieSubmodule R L M) := isAtomic_of_orderBot_wellFounded_lt <\| (wellFoundedLT_of_isArtinian R L M).wf @[simp] theorem subsingleton_iff : Subsingleton (LieSubmodule R L M) ↔ Subsingleton M := have h : Subsingleton (LieSubmodule R L M) ↔ Subsingleton (Submodule R M) := by rw [← subsingleton_iff_bot_eq_top, ← subsingleton_iff_bot_eq_top, ← toSubmodule_inj, top_toSubmodule, bot_toSubmodule] h.trans <\| Submodule.subsingleton_iff R @[simp] theorem nontrivial_iff : Nontrivial (LieSubmodule R L M) ↔ Nontrivial M := not_iff_not.mp ((not_nontrivial_iff_subsingleton.trans <\| subsingleton_iff R L M).trans not_nontrivial_iff_subsingleton.symm) instance [Nontrivial M] : Nontrivial (LieSubmodule R L M) := (nontrivial_iff R L M).mpr ‹_› theorem nontrivial_iff_ne_bot {N : LieSubmodule R L M} : Nontrivial N ↔ N ≠ ⊥ := by constructor <;> contrapose! · rintro rfl ⟨⟨m₁, h₁ : m₁ ∈ (⊥ : LieSubmodule R L M)⟩, ⟨m₂, h₂ : m₂ ∈ (⊥ : LieSubmodule R L M)⟩, h₁₂⟩ simp [(LieSubmodule.mem_bot _).mp h₁, (LieSubmodule.mem_bot _).mp h₂] at h₁₂ · rw [not_nontrivial_iff_subsingleton, LieSubmodule.eq_bot_iff] rintro ⟨h⟩ m hm simpa using h ⟨m, hm⟩ ⟨_, N.zero_mem⟩ variable {R L M} section InclusionMaps /-- The inclusion of a Lie submodule into its ambient space is a morphism of Lie modules. -/ def incl : N →ₗ⁅R,L⁆ M := { Submodule.subtype (N : Submodule R M) with map_lie' := fun {_ _} ↦ rfl } @[simp] theorem incl_coe : (N.incl : N →ₗ[R] M) = (N : Submodule R M).subtype := rfl @[simp] theorem incl_apply (m : N) : N.incl m = m := rfl theorem incl_eq_val : (N.incl : N → M) = Subtype.val := rfl theorem injective_incl : Function.Injective N.incl := Subtype.coe_injective variable {N N'} variable (h : N ≤ N') /-- Given two nested Lie submodules `N ⊆ N'`, the inclusion `N ↪ N'` is a morphism of Lie modules. -/ def inclusion : N →ₗ⁅R,L⁆ N' where __ := Submodule.inclusion (show N.toSubmodule ≤ N'.toSubmodule from h) map_lie' := rfl @[simp] theorem coe_inclusion (m : N) : (inclusion h m : M) = m := rfl theorem inclusion_apply (m : N) : inclusion h m = ⟨m.1, h m.2⟩ := rfl theorem inclusion_injective : Function.Injective (inclusion h) := fun x y ↦ by simp only [inclusion_apply, imp_self, Subtype.mk_eq_mk, SetLike.coe_eq_coe] end InclusionMaps section LieSpan variable (R L) (s : Set M) /-- The `lieSpan` of a set `s ⊆ M` is the smallest Lie submodule of `M` that contains `s`. -/ def lieSpan : LieSubmodule R L M := sInf { N \| s ⊆ N } variable {R L s} theorem mem_lieSpan {x : M} : x ∈ lieSpan R L s ↔ ∀ N : LieSubmodule R L M, s ⊆ N → x ∈ N := by rw [← SetLike.mem_coe, lieSpan, sInf_coe] exact mem_iInter₂ theorem subset_lieSpan : s ⊆ lieSpan R L s := by intro m hm rw [SetLike.mem_coe, mem_lieSpan] intro N hN exact hN hm theorem submodule_span_le_lieSpan : Submodule.span R s ≤ lieSpan R L s := by rw [Submodule.span_le] apply subset_lieSpan @[simp] theorem lieSpan_le {N} : lieSpan R L s ≤ N ↔ s ⊆ N := by constructor · exact Subset.trans subset_lieSpan · intro hs m hm; rw [mem_lieSpan] at hm; exact hm _ hs theorem lieSpan_mono {t : Set M} (h : s ⊆ t) : lieSpan R L s ≤ lieSpan R L t := by rw [lieSpan_le] exact Subset.trans h subset_lieSpan theorem lieSpan_eq (N : LieSubmodule R L M) : lieSpan R L (N : Set M) = N := le_antisymm (lieSpan_le.mpr rfl.subset) subset_lieSpan theorem coe_lieSpan_submodule_eq_iff {p : Submodule R M} : (lieSpan R L (p : Set M) : Submodule R M) = p ↔ ∃ N : LieSubmodule R L M, ↑N = p := by rw [p.exists_lieSubmodule_coe_eq_iff L]; constructor <;> intro h · intro x m hm; rw [← h, mem_toSubmodule]; exact lie_mem _ (subset_lieSpan hm) · rw [← toSubmodule_mk p @h, coe_toSubmodule, toSubmodule_inj, lieSpan_eq] variable (R L M) /-- `lieSpan` forms a Galois insertion with the coercion from `LieSubmodule` to `Set`. -/ protected def gi : GaloisInsertion (lieSpan R L : Set M → LieSubmodule R L M) (↑) where choice s _ := lieSpan R L s gc _ _ := lieSpan_le le_l_u _ := subset_lieSpan choice_eq _ _ := rfl @[simp] theorem span_empty : lieSpan R L (∅ : Set M) = ⊥ := (LieSubmodule.gi R L M).gc.l_bot @[simp] theorem span_univ : lieSpan R L (Set.univ : Set M) = ⊤ := eq_top_iff.2 <\| SetLike.le_def.2 <\| subset_lieSpan theorem lieSpan_eq_bot_iff : lieSpan R L s = ⊥ ↔ ∀ m ∈ s, m = (0 : M) := by rw [_root_.eq_bot_iff, lieSpan_le, bot_coe, subset_singleton_iff] variable {M} theorem span_union (s t : Set M) : lieSpan R L (s ∪ t) = lieSpan R L s ⊔ lieSpan R L t := (LieSubmodule.gi R L M).gc.l_sup theorem span_iUnion {ι} (s : ι → Set M) : lieSpan R L (⋃ i, s i) = ⨆ i, lieSpan R L (s i) := (LieSubmodule.gi R L M).gc.l_iSup /-- An induction principle for span membership. If `p` holds for 0 and all elements of `s`, and is preserved under addition, scalar multiplication and the Lie bracket, then `p` holds for all elements of the Lie submodule spanned by `s`. -/ @[elab_as_elim] theorem lieSpan_induction {p : (x : M) → x ∈ lieSpan R L s → Prop} (mem : ∀ (x) (h : x ∈ s), p x (subset_lieSpan h)) (zero : p 0 (LieSubmodule.zero_mem _)) (add : ∀ x y hx hy, p x hx → p y hy → p (x + y) (add_mem ‹_› ‹_›)) (smul : ∀ (a : R) (x hx), p x hx → p (a • x) (SMulMemClass.smul_mem _ hx)) {x} (lie : ∀ (x : L) (y hy), p y hy → p (⁅x, y⁆) (LieSubmodule.lie_mem _ ‹_›)) (hx : x ∈ lieSpan R L s) : p x hx := by let p : LieSubmodule R L M := { carrier := { x \| ∃ hx, p x hx } add_mem' := fun ⟨_, hpx⟩ ⟨_, hpy⟩ ↦ ⟨_, add _ _ _ _ hpx hpy⟩ zero_mem' := ⟨_, zero⟩ smul_mem' := fun r ↦ fun ⟨_, hpx⟩ ↦ ⟨_, smul r _ _ hpx⟩ lie_mem := fun ⟨_, hpy⟩ ↦ ⟨_, lie _ _ _ hpy⟩ } exact lieSpan_le (N := p) \|>.mpr (fun y hy ↦ ⟨subset_lieSpan hy, mem y hy⟩) hx \|>.elim fun _ ↦ id lemma isCompactElement_lieSpan_singleton (m : M) : CompleteLattice.IsCompactElement (lieSpan R L {m}) := by rw [CompleteLattice.isCompactElement_iff_le_of_directed_sSup_le] intro s hne hdir hsup replace hsup : m ∈ (↑(sSup s) : Set M) := (SetLike.le_def.mp hsup) (subset_lieSpan rfl) suffices (↑(sSup s) : Set M) = ⋃ N ∈ s, ↑N by obtain ⟨N : LieSubmodule R L M, hN : N ∈ s, hN' : m ∈ N⟩ := by simp_rw [this, Set.mem_iUnion, SetLike.mem_coe, exists_prop] at hsup; assumption exact ⟨N, hN, by simpa⟩ replace hne : Nonempty s := Set.nonempty_coe_sort.mpr hne have := Submodule.coe_iSup_of_directed _ hdir.directed_val simp_rw [← iSup_toSubmodule, Set.iUnion_coe_set, coe_toSubmodule] at this rw [← this, SetLike.coe_set_eq, sSup_eq_iSup, iSup_subtype] @[simp] lemma sSup_image_lieSpan_singleton : sSup ((fun x ↦ lieSpan R L {x}) '' N) = N := by refine le_antisymm (sSup_le <\| by simp) ?_ simp_rw [← toSubmodule_le_toSubmodule, sSup_toSubmodule, Set.mem_image, SetLike.mem_coe] refine fun m hm ↦ Submodule.mem_sSup.mpr fun N' hN' ↦ ?_ replace hN' : ∀ m ∈ N, lieSpan R L {m} ≤ N' := by simpa using hN' exact hN' _ hm (subset_lieSpan rfl) instance instIsCompactlyGenerated : IsCompactlyGenerated (LieSubmodule R L M) := ⟨fun N ↦ ⟨(fun x ↦ lieSpan R L {x}) '' N, fun _ ⟨m, _, hm⟩ ↦ hm ▸ isCompactElement_lieSpan_singleton R L m, N.sSup_image_lieSpan_singleton⟩⟩ end LieSpan end LatticeStructure end LieSubmodule section LieSubmoduleMapAndComap variable {R : Type u} {L : Type v} {L' : Type w₂} {M : Type w} {M' : Type w₁} variable [CommRing R] [LieRing L] [LieRing L'] [LieAlgebra R L'] variable [AddCommGroup M] [Module R M] [LieRingModule L M] variable [AddCommGroup M'] [Module R M'] [LieRingModule L M'] namespace LieSubmodule variable (f : M →ₗ⁅R,L⁆ M') (N N₂ : LieSubmodule R L M) (N' : LieSubmodule R L M') /-- A morphism of Lie modules `f : M → M'` pushes forward Lie submodules of `M` to Lie submodules of `M'`. -/ def map : LieSubmodule R L M' := { (N : Submodule R M).map (f : M →ₗ[R] M') with lie_mem := fun {x m'} h ↦ by rcases h with ⟨m, hm, hfm⟩; use ⁅x, m⁆; constructor · apply N.lie_mem hm · norm_cast at hfm; simp [hfm] } @[simp] theorem coe_map : (N.map f : Set M') = f '' N := rfl @[simp] theorem toSubmodule_map : (N.map f : Submodule R M') = (N : Submodule R M).map (f : M →ₗ[R] M') := rfl @[deprecated (since := "2024-12-30")] alias coeSubmodule_map := toSubmodule_map /-- A morphism of Lie modules `f : M → M'` pulls back Lie submodules of `M'` to Lie submodules of `M`. -/ def comap : LieSubmodule R L M := { (N' : Submodule R M').comap (f : M →ₗ[R] M') with lie_mem := fun {x m} h ↦ by suffices ⁅x, f m⁆ ∈ N' by simp [this] apply N'.lie_mem h } @[simp] theorem toSubmodule_comap : (N'.comap f : Submodule R M) = (N' : Submodule R M').comap (f : M →ₗ[R] M') := rfl @[deprecated (since := "2024-12-30")] alias coeSubmodule_comap := toSubmodule_comap variable {f N N₂ N'} theorem map_le_iff_le_comap : map f N ≤ N' ↔ N ≤ comap f N' := Set.image_subset_iff variable (f) in theorem gc_map_comap : GaloisConnection (map f) (comap f) := fun _ _ ↦ map_le_iff_le_comap theorem map_inf_le : (N ⊓ N₂).map f ≤ N.map f ⊓ N₂.map f := Set.image_inter_subset f N N₂ theorem map_inf (hf : Function.Injective f) : (N ⊓ N₂).map f = N.map f ⊓ N₂.map f := SetLike.coe_injective <\| Set.image_inter hf @[simp] theorem map_sup : (N ⊔ N₂).map f = N.map f ⊔ N₂.map f := (gc_map_comap f).l_sup @[simp] theorem comap_inf {N₂' : LieSubmodule R L M'} : (N' ⊓ N₂').comap f = N'.comap f ⊓ N₂'.comap f := rfl @[simp] theorem map_iSup {ι : Sort} (N : ι → LieSubmodule R L M) : (⨆ i, N i).map f = ⨆ i, (N i).map f := (gc_map_comap f : GaloisConnection (map f) (comap f)).l_iSup @[simp] theorem mem_map (m' : M') : m' ∈ N.map f ↔ ∃ m, m ∈ N ∧ f m = m' := Submodule.mem_map theorem mem_map_of_mem {m : M} (h : m ∈ N) : f m ∈ N.map f := Set.mem_image_of_mem _ h @[simp] theorem mem_comap {m : M} : m ∈ comap f N' ↔ f m ∈ N' := Iff.rfl theorem comap_incl_eq_top : N₂.comap N.incl = ⊤ ↔ N ≤ N₂ := by rw [← LieSubmodule.toSubmodule_inj, LieSubmodule.toSubmodule_comap, LieSubmodule.incl_coe, LieSubmodule.top_toSubmodule, Submodule.comap_subtype_eq_top, toSubmodule_le_toSubmodule] theorem comap_incl_eq_bot : N₂.comap N.incl = ⊥ ↔ N ⊓ N₂ = ⊥ := by simp only [← toSubmodule_inj, toSubmodule_comap, incl_coe, bot_toSubmodule, inf_toSubmodule] rw [← Submodule.disjoint_iff_comap_eq_bot, disjoint_iff] @[gcongr, mono] theorem map_mono (h : N ≤ N₂) : N.map f ≤ N₂.map f := Set.image_subset _ h theorem map_comp {M'' : Type} [AddCommGroup M''] [Module R M''] [LieRingModule L M''] {g : M' →ₗ⁅R,L⁆ M''} : N.map (g.comp f) = (N.map f).map g := SetLike.coe_injective <\| by simp only [← Set.image_comp, coe_map, LinearMap.coe_comp, LieModuleHom.coe_comp] @[simp] theorem map_id : N.map LieModuleHom.id = N := by ext; simp @[simp] theorem map_bot : (⊥ : LieSubmodule R L M).map f = ⊥ := by ext m; simp [eq_comm] lemma map_le_map_iff (hf : Function.Injective f) : N.map f ≤ N₂.map f ↔ N ≤ N₂ := Set.image_subset_image_iff hf lemma map_injective_of_injective (hf : Function.Injective f) : Function.Injective (map f) := fun {N N'} h ↦ SetLike.coe_injective <\| hf.image_injective <\| by simp only [← coe_map, h] /-- An injective morphism of Lie modules embeds the lattice of submodules of the domain into that of the target. -/ @[simps] def mapOrderEmbedding {f : M →ₗ⁅R,L⁆ M'} (hf : Function.Injective f) : LieSubmodule R L M ↪o LieSubmodule R L M' where toFun := LieSubmodule.map f inj' := map_injective_of_injective hf map_rel_iff' := Set.image_subset_image_iff hf variable (N) in /-- For an injective morphism of Lie modules, any Lie submodule is equivalent to its image. -/ noncomputable def equivMapOfInjective (hf : Function.Injective f) : N ≃ₗ⁅R,L⁆ N.map f := { Submodule.equivMapOfInjective (f : M →ₗ[R] M') hf N with -- Note: https://github.com/leanprover-community/mathlib4/pull/8386 had to specify `invFun` explicitly this way, otherwise we'd get a type mismatch invFun := by exact DFunLike.coe (Submodule.equivMapOfInjective (f : M →ₗ[R] M') hf N).symm map_lie' := by rintro x ⟨m, hm : m ∈ N⟩; ext; exact f.map_lie x m } /-- An equivalence of Lie modules yields an order-preserving equivalence of their lattices of Lie Submodules. -/ @[simps] def orderIsoMapComap (e : M ≃ₗ⁅R,L⁆ M') : LieSubmodule R L M ≃o LieSubmodule R L M' where toFun := map e invFun := comap e left_inv := fun N ↦ by ext; simp right_inv := fun N ↦ by ext; simp [e.apply_eq_iff_eq_symm_apply] map_rel_iff' := fun {_ _} ↦ Set.image_subset_image_iff e.injective end LieSubmodule end LieSubmoduleMapAndComap namespace LieModuleHom variable {R : Type u} {L : Type v} {M : Type w} {N : Type w₁} variable [CommRing R] [LieRing L] variable [AddCommGroup M] [Module R M] [LieRingModule L M] variable [AddCommGroup N] [Module R N] [LieRingModule L N] variable (f : M →ₗ⁅R,L⁆ N) /-- The kernel of a morphism of Lie algebras, as an ideal in the domain. -/ def ker : LieSubmodule R L M := LieSubmodule.comap f ⊥ @[simp] theorem ker_toSubmodule : (f.ker : Submodule R M) = LinearMap.ker (f : M →ₗ[R] N) := rfl @[deprecated (since := "2024-12-30")] alias ker_coeSubmodule := ker_toSubmodule theorem ker_eq_bot : f.ker = ⊥ ↔ Function.Injective f := by rw [← LieSubmodule.toSubmodule_inj, ker_toSubmodule, LieSubmodule.bot_toSubmodule, LinearMap.ker_eq_bot, coe_toLinearMap] variable {f} @[simp] theorem mem_ker {m : M} : m ∈ f.ker ↔ f m = 0 := Iff.rfl @[simp] theorem ker_id : (LieModuleHom.id : M →ₗ⁅R,L⁆ M).ker = ⊥ := rfl @[simp] theorem comp_ker_incl : f.comp f.ker.incl = 0 := by ext ⟨m, hm⟩; exact mem_ker.mp hm theorem le_ker_iff_map (M' : LieSubmodule R L M) : M' ≤ f.ker ↔ LieSubmodule.map f M' = ⊥ := by rw [ker, eq_bot_iff, LieSubmodule.map_le_iff_le_comap] variable (f) /-- The range of a morphism of Lie modules `f : M → N` is a Lie submodule of `N`. See Note [range copy pattern]. -/ def range : LieSubmodule R L N := (LieSubmodule.map f ⊤).copy (Set.range f) Set.image_univ.symm @[simp] theorem coe_range : f.range = Set.range f := rfl @[simp] theorem toSubmodule_range : f.range = LinearMap.range (f : M →ₗ[R] N) := rfl @[deprecated (since := "2024-12-30")] alias coeSubmodule_range := toSubmodule_range @[simp] theorem mem_range (n : N) : n ∈ f.range ↔ ∃ m, f m = n := Iff.rfl @[simp] theorem map_top : LieSubmodule.map f ⊤ = f.range := by ext; simp [LieSubmodule.mem_map] theorem range_eq_top : f.range = ⊤ ↔ Function.Surjective f := by rw [SetLike.ext'_iff, coe_range, LieSubmodule.top_coe, Set.range_eq_univ] /-- A morphism of Lie modules `f : M → N` whose values lie in a Lie submodule `P ⊆ N` can be restricted to a morphism of Lie modules `M → P`. -/ def codRestrict (P : LieSubmodule R L N) (f : M →ₗ⁅R,L⁆ N) (h : ∀ m, f m ∈ P) : M →ₗ⁅R,L⁆ P where toFun := f.toLinearMap.codRestrict P h __ := f.toLinearMap.codRestrict P h map_lie' {x m} := by ext; simp @[simp] lemma codRestrict_apply (P : LieSubmodule R L N) (f : M →ₗ⁅R,L⁆ N) (h : ∀ m, f m ∈ P) (m : M) : (f.codRestrict P h m : N) = f m := rfl end LieModuleHom namespace LieSubmodule variable {R : Type u} {L : Type v} {M : Type w} variable [CommRing R] [LieRing L] variable [AddCommGroup M] [Module R M] [LieRingModule L M] variable (N : LieSubmodule R L M) @[simp] theorem ker_incl : N.incl.ker = ⊥ := (LieModuleHom.ker_eq_bot N.incl).mpr <\| injective_incl N @[simp] theorem range_incl : N.incl.range = N := by simp only [← toSubmodule_inj, LieModuleHom.toSubmodule_range, incl_coe] rw [Submodule.range_subtype] @[simp] theorem comap_incl_self : comap N.incl N = ⊤ := by simp only [← toSubmodule_inj, toSubmodule_comap, incl_coe, top_toSubmodule] rw [Submodule.comap_subtype_self] theorem map_incl_top : (⊤ : LieSubmodule R L N).map N.incl = N := by simp variable {N} @[simp] lemma map_le_range {M' : Type} [AddCommGroup M'] [Module R M'] [LieRingModule L M'] (f : M →ₗ⁅R,L⁆ M') : N.map f ≤ f.range := by rw [← LieModuleHom.map_top] exact LieSubmodule.map_mono le_top @[simp] lemma map_incl_lt_iff_lt_top {N' : LieSubmodule R L N} : N'.map (LieSubmodule.incl N) < N ↔ N' < ⊤ := by convert (LieSubmodule.mapOrderEmbedding (f := N.incl) Subtype.coe_injective).lt_iff_lt simp @[simp] lemma map_incl_le {N' : LieSubmodule R L N} : N'.map N.incl ≤ N := by conv_rhs => rw [← N.map_incl_top] exact LieSubmodule.map_mono le_top end LieSubmodule section TopEquiv variable (R : Type u) (L : Type v) variable [CommRing R] [LieRing L] variable (M : Type) [AddCommGroup M] [Module R M] [LieRingModule L M] /-- The natural equivalence between the 'top' Lie submodule and the enclosing Lie module. -/ def LieModuleEquiv.ofTop : (⊤ : LieSubmodule R L M) ≃ₗ⁅R,L⁆ M := { LinearEquiv.ofTop ⊤ rfl with map_lie' := rfl } variable {R L} lemma LieModuleEquiv.ofTop_apply (x : (⊤ : LieSubmodule R L M)) : LieModuleEquiv.ofTop R L M x = x := rfl @[simp] lemma LieModuleEquiv.range_coe {M' : Type*} [AddCommGroup M'] [Module R M'] [LieRingModule L M'] (e : M ≃ₗ⁅R,L⁆ M') : LieModuleHom.range (e : M →ₗ⁅R,L⁆ M') = ⊤ := by rw [LieModuleHom.range_eq_top] exact e.surjective variable [LieAlgebra R L] [LieModule R L M] /-- The natural equivalence between the 'top' Lie subalgebra and the enclosing Lie algebra. This is the Lie subalgebra version of `Submodule.topEquiv`. -/ def LieSubalgebra.topEquiv : (⊤ : LieSubalgebra R L) ≃ₗ⁅R⁆ L := { (⊤ : LieSubalgebra R L).incl with invFun := fun x ↦ ⟨x, Set.mem_univ x⟩ left_inv := fun x ↦ by ext; rfl right_inv := fun _ ↦ rfl } @[simp] theorem LieSubalgebra.topEquiv_apply (x : (⊤ : LieSubalgebra R L)) : LieSubalgebra.topEquiv x = x := rfl end TopEquiv		Mathlib/Algebra/Lie/Submodule.lean	1,120	1,123
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Mario Carneiro, Patrick Massot, Yury Kudryashov, Rémy Degenne -/ import Mathlib.Data.Set.Subsingleton import Mathlib.Order.Interval.Set.Defs /-! # Intervals In any preorder, we define intervals (which on each side can be either infinite, open or closed) using the following naming conventions: - `i`: infinite - `o`: open - `c`: closed Each interval has the name `I` + letter for left side + letter for right side. For instance, `Ioc a b` denotes the interval `(a, b]`. The definitions can be found in `Mathlib.Order.Interval.Set.Defs`. This file contains basic facts on inclusion of and set operations on intervals (where the precise statements depend on the order's properties; statements requiring `LinearOrder` are in `Mathlib.Order.Interval.Set.LinearOrder`). TODO: This is just the beginning; a lot of rules are missing -/ assert_not_exists RelIso open Function open OrderDual (toDual ofDual) variable {α : Type} namespace Set section Preorder variable [Preorder α] {a a₁ a₂ b b₁ b₂ c x : α} instance decidableMemIoo [Decidable (a < x ∧ x < b)] : Decidable (x ∈ Ioo a b) := by assumption instance decidableMemIco [Decidable (a ≤ x ∧ x < b)] : Decidable (x ∈ Ico a b) := by assumption instance decidableMemIio [Decidable (x < b)] : Decidable (x ∈ Iio b) := by assumption instance decidableMemIcc [Decidable (a ≤ x ∧ x ≤ b)] : Decidable (x ∈ Icc a b) := by assumption instance decidableMemIic [Decidable (x ≤ b)] : Decidable (x ∈ Iic b) := by assumption instance decidableMemIoc [Decidable (a < x ∧ x ≤ b)] : Decidable (x ∈ Ioc a b) := by assumption instance decidableMemIci [Decidable (a ≤ x)] : Decidable (x ∈ Ici a) := by assumption instance decidableMemIoi [Decidable (a < x)] : Decidable (x ∈ Ioi a) := by assumption theorem left_mem_Ioo : a ∈ Ioo a b ↔ False := by simp [lt_irrefl] theorem left_mem_Ico : a ∈ Ico a b ↔ a < b := by simp [le_refl] theorem left_mem_Icc : a ∈ Icc a b ↔ a ≤ b := by simp [le_refl] theorem left_mem_Ioc : a ∈ Ioc a b ↔ False := by simp [lt_irrefl] theorem left_mem_Ici : a ∈ Ici a := by simp theorem right_mem_Ioo : b ∈ Ioo a b ↔ False := by simp [lt_irrefl] theorem right_mem_Ico : b ∈ Ico a b ↔ False := by simp [lt_irrefl] theorem right_mem_Icc : b ∈ Icc a b ↔ a ≤ b := by simp [le_refl] theorem right_mem_Ioc : b ∈ Ioc a b ↔ a < b := by simp [le_refl] theorem right_mem_Iic : a ∈ Iic a := by simp @[simp] theorem Ici_toDual : Ici (toDual a) = ofDual ⁻¹' Iic a := rfl @[deprecated (since := "2025-03-20")] alias dual_Ici := Ici_toDual @[simp] theorem Iic_toDual : Iic (toDual a) = ofDual ⁻¹' Ici a := rfl @[deprecated (since := "2025-03-20")] alias dual_Iic := Iic_toDual @[simp] theorem Ioi_toDual : Ioi (toDual a) = ofDual ⁻¹' Iio a := rfl @[deprecated (since := "2025-03-20")] alias dual_Ioi := Ioi_toDual @[simp] theorem Iio_toDual : Iio (toDual a) = ofDual ⁻¹' Ioi a := rfl @[deprecated (since := "2025-03-20")] alias dual_Iio := Iio_toDual @[simp] theorem Icc_toDual : Icc (toDual a) (toDual b) = ofDual ⁻¹' Icc b a := Set.ext fun _ => and_comm @[deprecated (since := "2025-03-20")] alias dual_Icc := Icc_toDual @[simp] theorem Ioc_toDual : Ioc (toDual a) (toDual b) = ofDual ⁻¹' Ico b a := Set.ext fun _ => and_comm @[deprecated (since := "2025-03-20")] alias dual_Ioc := Ioc_toDual @[simp] theorem Ico_toDual : Ico (toDual a) (toDual b) = ofDual ⁻¹' Ioc b a := Set.ext fun _ => and_comm @[deprecated (since := "2025-03-20")] alias dual_Ico := Ico_toDual @[simp] theorem Ioo_toDual : Ioo (toDual a) (toDual b) = ofDual ⁻¹' Ioo b a := Set.ext fun _ => and_comm @[deprecated (since := "2025-03-20")] alias dual_Ioo := Ioo_toDual @[simp] theorem Ici_ofDual {x : αᵒᵈ} : Ici (ofDual x) = toDual ⁻¹' Iic x := rfl @[simp] theorem Iic_ofDual {x : αᵒᵈ} : Iic (ofDual x) = toDual ⁻¹' Ici x := rfl @[simp] theorem Ioi_ofDual {x : αᵒᵈ} : Ioi (ofDual x) = toDual ⁻¹' Iio x := rfl @[simp] theorem Iio_ofDual {x : αᵒᵈ} : Iio (ofDual x) = toDual ⁻¹' Ioi x := rfl @[simp] theorem Icc_ofDual {x y : αᵒᵈ} : Icc (ofDual y) (ofDual x) = toDual ⁻¹' Icc x y := Set.ext fun _ => and_comm @[simp] theorem Ico_ofDual {x y : αᵒᵈ} : Ico (ofDual y) (ofDual x) = toDual ⁻¹' Ioc x y := Set.ext fun _ => and_comm @[simp] theorem Ioc_ofDual {x y : αᵒᵈ} : Ioc (ofDual y) (ofDual x) = toDual ⁻¹' Ico x y := Set.ext fun _ => and_comm @[simp] theorem Ioo_ofDual {x y : αᵒᵈ} : Ioo (ofDual y) (ofDual x) = toDual ⁻¹' Ioo x y := Set.ext fun _ => and_comm @[simp] theorem nonempty_Icc : (Icc a b).Nonempty ↔ a ≤ b := ⟨fun ⟨_, hx⟩ => hx.1.trans hx.2, fun h => ⟨a, left_mem_Icc.2 h⟩⟩ @[simp] theorem nonempty_Ico : (Ico a b).Nonempty ↔ a < b := ⟨fun ⟨_, hx⟩ => hx.1.trans_lt hx.2, fun h => ⟨a, left_mem_Ico.2 h⟩⟩ @[simp] theorem nonempty_Ioc : (Ioc a b).Nonempty ↔ a < b := ⟨fun ⟨_, hx⟩ => hx.1.trans_le hx.2, fun h => ⟨b, right_mem_Ioc.2 h⟩⟩ @[simp] theorem nonempty_Ici : (Ici a).Nonempty := ⟨a, left_mem_Ici⟩ @[simp] theorem nonempty_Iic : (Iic a).Nonempty := ⟨a, right_mem_Iic⟩ @[simp] theorem nonempty_Ioo [DenselyOrdered α] : (Ioo a b).Nonempty ↔ a < b := ⟨fun ⟨_, ha, hb⟩ => ha.trans hb, exists_between⟩ @[simp] theorem nonempty_Ioi [NoMaxOrder α] : (Ioi a).Nonempty := exists_gt a @[simp] theorem nonempty_Iio [NoMinOrder α] : (Iio a).Nonempty := exists_lt a theorem nonempty_Icc_subtype (h : a ≤ b) : Nonempty (Icc a b) := Nonempty.to_subtype (nonempty_Icc.mpr h) theorem nonempty_Ico_subtype (h : a < b) : Nonempty (Ico a b) := Nonempty.to_subtype (nonempty_Ico.mpr h) theorem nonempty_Ioc_subtype (h : a < b) : Nonempty (Ioc a b) := Nonempty.to_subtype (nonempty_Ioc.mpr h) /-- An interval `Ici a` is nonempty. -/ instance nonempty_Ici_subtype : Nonempty (Ici a) := Nonempty.to_subtype nonempty_Ici /-- An interval `Iic a` is nonempty. -/ instance nonempty_Iic_subtype : Nonempty (Iic a) := Nonempty.to_subtype nonempty_Iic theorem nonempty_Ioo_subtype [DenselyOrdered α] (h : a < b) : Nonempty (Ioo a b) := Nonempty.to_subtype (nonempty_Ioo.mpr h) /-- In an order without maximal elements, the intervals `Ioi` are nonempty. -/ instance nonempty_Ioi_subtype [NoMaxOrder α] : Nonempty (Ioi a) := Nonempty.to_subtype nonempty_Ioi /-- In an order without minimal elements, the intervals `Iio` are nonempty. -/ instance nonempty_Iio_subtype [NoMinOrder α] : Nonempty (Iio a) := Nonempty.to_subtype nonempty_Iio instance [NoMinOrder α] : NoMinOrder (Iio a) := ⟨fun a => let ⟨b, hb⟩ := exists_lt (a : α) ⟨⟨b, lt_trans hb a.2⟩, hb⟩⟩ instance [NoMinOrder α] : NoMinOrder (Iic a) := ⟨fun a => let ⟨b, hb⟩ := exists_lt (a : α) ⟨⟨b, hb.le.trans a.2⟩, hb⟩⟩ instance [NoMaxOrder α] : NoMaxOrder (Ioi a) := OrderDual.noMaxOrder (α := Iio (toDual a)) instance [NoMaxOrder α] : NoMaxOrder (Ici a) := OrderDual.noMaxOrder (α := Iic (toDual a)) @[simp] theorem Icc_eq_empty (h : ¬a ≤ b) : Icc a b = ∅ := eq_empty_iff_forall_not_mem.2 fun _ ⟨ha, hb⟩ => h (ha.trans hb) @[simp] theorem Ico_eq_empty (h : ¬a < b) : Ico a b = ∅ := eq_empty_iff_forall_not_mem.2 fun _ ⟨ha, hb⟩ => h (ha.trans_lt hb) @[simp] theorem Ioc_eq_empty (h : ¬a < b) : Ioc a b = ∅ := eq_empty_iff_forall_not_mem.2 fun _ ⟨ha, hb⟩ => h (ha.trans_le hb) @[simp] theorem Ioo_eq_empty (h : ¬a < b) : Ioo a b = ∅ := eq_empty_iff_forall_not_mem.2 fun _ ⟨ha, hb⟩ => h (ha.trans hb) @[simp] theorem Icc_eq_empty_of_lt (h : b < a) : Icc a b = ∅ := Icc_eq_empty h.not_le @[simp] theorem Ico_eq_empty_of_le (h : b ≤ a) : Ico a b = ∅ := Ico_eq_empty h.not_lt @[simp] theorem Ioc_eq_empty_of_le (h : b ≤ a) : Ioc a b = ∅ := Ioc_eq_empty h.not_lt @[simp] theorem Ioo_eq_empty_of_le (h : b ≤ a) : Ioo a b = ∅ := Ioo_eq_empty h.not_lt theorem Ico_self (a : α) : Ico a a = ∅ := Ico_eq_empty <\| lt_irrefl _ theorem Ioc_self (a : α) : Ioc a a = ∅ := Ioc_eq_empty <\| lt_irrefl _ theorem Ioo_self (a : α) : Ioo a a = ∅ := Ioo_eq_empty <\| lt_irrefl _ @[simp] theorem Ici_subset_Ici : Ici a ⊆ Ici b ↔ b ≤ a := ⟨fun h => h <\| left_mem_Ici, fun h _ hx => h.trans hx⟩ @[gcongr] alias ⟨_, _root_.GCongr.Ici_subset_Ici_of_le⟩ := Ici_subset_Ici @[simp] theorem Ici_ssubset_Ici : Ici a ⊂ Ici b ↔ b < a where mp h := by obtain ⟨ab, c, cb, ac⟩ := ssubset_iff_exists.mp h exact lt_of_le_not_le (Ici_subset_Ici.mp ab) (fun h' ↦ ac (h'.trans cb)) mpr h := (ssubset_iff_of_subset (Ici_subset_Ici.mpr h.le)).mpr ⟨b, right_mem_Iic, fun h' => h.not_le h'⟩ @[gcongr] alias ⟨_, _root_.GCongr.Ici_ssubset_Ici_of_le⟩ := Ici_ssubset_Ici @[simp] theorem Iic_subset_Iic : Iic a ⊆ Iic b ↔ a ≤ b := @Ici_subset_Ici αᵒᵈ _ _ _ @[gcongr] alias ⟨_, _root_.GCongr.Iic_subset_Iic_of_le⟩ := Iic_subset_Iic @[simp] theorem Iic_ssubset_Iic : Iic a ⊂ Iic b ↔ a < b := @Ici_ssubset_Ici αᵒᵈ _ _ _ @[gcongr] alias ⟨_, _root_.GCongr.Iic_ssubset_Iic_of_le⟩ := Iic_ssubset_Iic @[simp] theorem Ici_subset_Ioi : Ici a ⊆ Ioi b ↔ b < a := ⟨fun h => h left_mem_Ici, fun h _ hx => h.trans_le hx⟩ @[simp] theorem Iic_subset_Iio : Iic a ⊆ Iio b ↔ a < b := ⟨fun h => h right_mem_Iic, fun h _ hx => lt_of_le_of_lt hx h⟩ @[gcongr] theorem Ioo_subset_Ioo (h₁ : a₂ ≤ a₁) (h₂ : b₁ ≤ b₂) : Ioo a₁ b₁ ⊆ Ioo a₂ b₂ := fun _ ⟨hx₁, hx₂⟩ => ⟨h₁.trans_lt hx₁, hx₂.trans_le h₂⟩ @[gcongr] theorem Ioo_subset_Ioo_left (h : a₁ ≤ a₂) : Ioo a₂ b ⊆ Ioo a₁ b := Ioo_subset_Ioo h le_rfl @[gcongr] theorem Ioo_subset_Ioo_right (h : b₁ ≤ b₂) : Ioo a b₁ ⊆ Ioo a b₂ := Ioo_subset_Ioo le_rfl h @[gcongr] theorem Ico_subset_Ico (h₁ : a₂ ≤ a₁) (h₂ : b₁ ≤ b₂) : Ico a₁ b₁ ⊆ Ico a₂ b₂ := fun _ ⟨hx₁, hx₂⟩ => ⟨h₁.trans hx₁, hx₂.trans_le h₂⟩ @[gcongr] theorem Ico_subset_Ico_left (h : a₁ ≤ a₂) : Ico a₂ b ⊆ Ico a₁ b := Ico_subset_Ico h le_rfl @[gcongr] theorem Ico_subset_Ico_right (h : b₁ ≤ b₂) : Ico a b₁ ⊆ Ico a b₂ := Ico_subset_Ico le_rfl h @[gcongr] theorem Icc_subset_Icc (h₁ : a₂ ≤ a₁) (h₂ : b₁ ≤ b₂) : Icc a₁ b₁ ⊆ Icc a₂ b₂ := fun _ ⟨hx₁, hx₂⟩ => ⟨h₁.trans hx₁, le_trans hx₂ h₂⟩ @[gcongr] theorem Icc_subset_Icc_left (h : a₁ ≤ a₂) : Icc a₂ b ⊆ Icc a₁ b := Icc_subset_Icc h le_rfl @[gcongr] theorem Icc_subset_Icc_right (h : b₁ ≤ b₂) : Icc a b₁ ⊆ Icc a b₂ := Icc_subset_Icc le_rfl h theorem Icc_subset_Ioo (ha : a₂ < a₁) (hb : b₁ < b₂) : Icc a₁ b₁ ⊆ Ioo a₂ b₂ := fun _ hx => ⟨ha.trans_le hx.1, hx.2.trans_lt hb⟩ theorem Icc_subset_Ici_self : Icc a b ⊆ Ici a := fun _ => And.left theorem Icc_subset_Iic_self : Icc a b ⊆ Iic b := fun _ => And.right theorem Ioc_subset_Iic_self : Ioc a b ⊆ Iic b := fun _ => And.right @[gcongr] theorem Ioc_subset_Ioc (h₁ : a₂ ≤ a₁) (h₂ : b₁ ≤ b₂) : Ioc a₁ b₁ ⊆ Ioc a₂ b₂ := fun _ ⟨hx₁, hx₂⟩ => ⟨h₁.trans_lt hx₁, hx₂.trans h₂⟩ @[gcongr] theorem Ioc_subset_Ioc_left (h : a₁ ≤ a₂) : Ioc a₂ b ⊆ Ioc a₁ b := Ioc_subset_Ioc h le_rfl @[gcongr] theorem Ioc_subset_Ioc_right (h : b₁ ≤ b₂) : Ioc a b₁ ⊆ Ioc a b₂ := Ioc_subset_Ioc le_rfl h theorem Ico_subset_Ioo_left (h₁ : a₁ < a₂) : Ico a₂ b ⊆ Ioo a₁ b := fun _ => And.imp_left h₁.trans_le theorem Ioc_subset_Ioo_right (h : b₁ < b₂) : Ioc a b₁ ⊆ Ioo a b₂ := fun _ => And.imp_right fun h' => h'.trans_lt h theorem Icc_subset_Ico_right (h₁ : b₁ < b₂) : Icc a b₁ ⊆ Ico a b₂ := fun _ => And.imp_right fun h₂ => h₂.trans_lt h₁ theorem Ioo_subset_Ico_self : Ioo a b ⊆ Ico a b := fun _ => And.imp_left le_of_lt theorem Ioo_subset_Ioc_self : Ioo a b ⊆ Ioc a b := fun _ => And.imp_right le_of_lt theorem Ico_subset_Icc_self : Ico a b ⊆ Icc a b := fun _ => And.imp_right le_of_lt theorem Ioc_subset_Icc_self : Ioc a b ⊆ Icc a b := fun _ => And.imp_left le_of_lt theorem Ioo_subset_Icc_self : Ioo a b ⊆ Icc a b := Subset.trans Ioo_subset_Ico_self Ico_subset_Icc_self theorem Ico_subset_Iio_self : Ico a b ⊆ Iio b := fun _ => And.right theorem Ioo_subset_Iio_self : Ioo a b ⊆ Iio b := fun _ => And.right theorem Ioc_subset_Ioi_self : Ioc a b ⊆ Ioi a := fun _ => And.left theorem Ioo_subset_Ioi_self : Ioo a b ⊆ Ioi a := fun _ => And.left theorem Ioi_subset_Ici_self : Ioi a ⊆ Ici a := fun _ hx => le_of_lt hx theorem Iio_subset_Iic_self : Iio a ⊆ Iic a := fun _ hx => le_of_lt hx theorem Ico_subset_Ici_self : Ico a b ⊆ Ici a := fun _ => And.left theorem Ioi_ssubset_Ici_self : Ioi a ⊂ Ici a := ⟨Ioi_subset_Ici_self, fun h => lt_irrefl a (h le_rfl)⟩ theorem Iio_ssubset_Iic_self : Iio a ⊂ Iic a := @Ioi_ssubset_Ici_self αᵒᵈ _ _ theorem Icc_subset_Icc_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Icc a₂ b₂ ↔ a₂ ≤ a₁ ∧ b₁ ≤ b₂ := ⟨fun h => ⟨(h ⟨le_rfl, h₁⟩).1, (h ⟨h₁, le_rfl⟩).2⟩, fun ⟨h, h'⟩ _ ⟨hx, hx'⟩ => ⟨h.trans hx, hx'.trans h'⟩⟩ theorem Icc_subset_Ioo_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Ioo a₂ b₂ ↔ a₂ < a₁ ∧ b₁ < b₂ := ⟨fun h => ⟨(h ⟨le_rfl, h₁⟩).1, (h ⟨h₁, le_rfl⟩).2⟩, fun ⟨h, h'⟩ _ ⟨hx, hx'⟩ => ⟨h.trans_le hx, hx'.trans_lt h'⟩⟩ theorem Icc_subset_Ico_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Ico a₂ b₂ ↔ a₂ ≤ a₁ ∧ b₁ < b₂ := ⟨fun h => ⟨(h ⟨le_rfl, h₁⟩).1, (h ⟨h₁, le_rfl⟩).2⟩, fun ⟨h, h'⟩ _ ⟨hx, hx'⟩ => ⟨h.trans hx, hx'.trans_lt h'⟩⟩ theorem Icc_subset_Ioc_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Ioc a₂ b₂ ↔ a₂ < a₁ ∧ b₁ ≤ b₂ := ⟨fun h => ⟨(h ⟨le_rfl, h₁⟩).1, (h ⟨h₁, le_rfl⟩).2⟩, fun ⟨h, h'⟩ _ ⟨hx, hx'⟩ => ⟨h.trans_le hx, hx'.trans h'⟩⟩ theorem Icc_subset_Iio_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Iio b₂ ↔ b₁ < b₂ := ⟨fun h => h ⟨h₁, le_rfl⟩, fun h _ ⟨_, hx'⟩ => hx'.trans_lt h⟩ theorem Icc_subset_Ioi_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Ioi a₂ ↔ a₂ < a₁ := ⟨fun h => h ⟨le_rfl, h₁⟩, fun h _ ⟨hx, _⟩ => h.trans_le hx⟩ theorem Icc_subset_Iic_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Iic b₂ ↔ b₁ ≤ b₂ := ⟨fun h => h ⟨h₁, le_rfl⟩, fun h _ ⟨_, hx'⟩ => hx'.trans h⟩ theorem Icc_subset_Ici_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Ici a₂ ↔ a₂ ≤ a₁ := ⟨fun h => h ⟨le_rfl, h₁⟩, fun h _ ⟨hx, _⟩ => h.trans hx⟩ theorem Icc_ssubset_Icc_left (hI : a₂ ≤ b₂) (ha : a₂ < a₁) (hb : b₁ ≤ b₂) : Icc a₁ b₁ ⊂ Icc a₂ b₂ := (ssubset_iff_of_subset (Icc_subset_Icc (le_of_lt ha) hb)).mpr ⟨a₂, left_mem_Icc.mpr hI, not_and.mpr fun f _ => lt_irrefl a₂ (ha.trans_le f)⟩ theorem Icc_ssubset_Icc_right (hI : a₂ ≤ b₂) (ha : a₂ ≤ a₁) (hb : b₁ < b₂) : Icc a₁ b₁ ⊂ Icc a₂ b₂ := (ssubset_iff_of_subset (Icc_subset_Icc ha (le_of_lt hb))).mpr ⟨b₂, right_mem_Icc.mpr hI, fun f => lt_irrefl b₁ (hb.trans_le f.2)⟩ /-- If `a ≤ b`, then `(b, +∞) ⊆ (a, +∞)`. In preorders, this is just an implication. If you need the equivalence in linear orders, use `Ioi_subset_Ioi_iff`. -/ @[gcongr] theorem Ioi_subset_Ioi (h : a ≤ b) : Ioi b ⊆ Ioi a := fun _ hx => h.trans_lt hx /-- If `a < b`, then `(b, +∞) ⊂ (a, +∞)`. In preorders, this is just an implication. If you need the equivalence in linear orders, use `Ioi_ssubset_Ioi_iff`. -/ @[gcongr] theorem Ioi_ssubset_Ioi (h : a < b) : Ioi b ⊂ Ioi a := (ssubset_iff_of_subset (Ioi_subset_Ioi h.le)).mpr ⟨b, h, lt_irrefl b⟩ /-- If `a ≤ b`, then `(b, +∞) ⊆ [a, +∞)`. In preorders, this is just an implication. If you need the equivalence in dense linear orders, use `Ioi_subset_Ici_iff`. -/ theorem Ioi_subset_Ici (h : a ≤ b) : Ioi b ⊆ Ici a := Subset.trans (Ioi_subset_Ioi h) Ioi_subset_Ici_self /-- If `a ≤ b`, then `(-∞, a) ⊆ (-∞, b)`. In preorders, this is just an implication. If you need the equivalence in linear orders, use `Iio_subset_Iio_iff`. -/ @[gcongr] theorem Iio_subset_Iio (h : a ≤ b) : Iio a ⊆ Iio b := fun _ hx => lt_of_lt_of_le hx h /-- If `a < b`, then `(-∞, a) ⊂ (-∞, b)`. In preorders, this is just an implication. If you need the equivalence in linear orders, use `Iio_ssubset_Iio_iff`. -/ @[gcongr] theorem Iio_ssubset_Iio (h : a < b) : Iio a ⊂ Iio b := (ssubset_iff_of_subset (Iio_subset_Iio h.le)).mpr ⟨a, h, lt_irrefl a⟩ /-- If `a ≤ b`, then `(-∞, a) ⊆ (-∞, b]`. In preorders, this is just an implication. If you need the equivalence in dense linear orders, use `Iio_subset_Iic_iff`. -/ theorem Iio_subset_Iic (h : a ≤ b) : Iio a ⊆ Iic b := Subset.trans (Iio_subset_Iio h) Iio_subset_Iic_self theorem Ici_inter_Iic : Ici a ∩ Iic b = Icc a b := rfl theorem Ici_inter_Iio : Ici a ∩ Iio b = Ico a b := rfl theorem Ioi_inter_Iic : Ioi a ∩ Iic b = Ioc a b := rfl theorem Ioi_inter_Iio : Ioi a ∩ Iio b = Ioo a b := rfl theorem Iic_inter_Ici : Iic a ∩ Ici b = Icc b a := inter_comm _ _ theorem Iio_inter_Ici : Iio a ∩ Ici b = Ico b a := inter_comm _ _ theorem Iic_inter_Ioi : Iic a ∩ Ioi b = Ioc b a := inter_comm _ _ theorem Iio_inter_Ioi : Iio a ∩ Ioi b = Ioo b a := inter_comm _ _ theorem mem_Icc_of_Ioo (h : x ∈ Ioo a b) : x ∈ Icc a b := Ioo_subset_Icc_self h theorem mem_Ico_of_Ioo (h : x ∈ Ioo a b) : x ∈ Ico a b := Ioo_subset_Ico_self h theorem mem_Ioc_of_Ioo (h : x ∈ Ioo a b) : x ∈ Ioc a b := Ioo_subset_Ioc_self h theorem mem_Icc_of_Ico (h : x ∈ Ico a b) : x ∈ Icc a b := Ico_subset_Icc_self h theorem mem_Icc_of_Ioc (h : x ∈ Ioc a b) : x ∈ Icc a b := Ioc_subset_Icc_self h theorem mem_Ici_of_Ioi (h : x ∈ Ioi a) : x ∈ Ici a := Ioi_subset_Ici_self h theorem mem_Iic_of_Iio (h : x ∈ Iio a) : x ∈ Iic a := Iio_subset_Iic_self h theorem Icc_eq_empty_iff : Icc a b = ∅ ↔ ¬a ≤ b := by rw [← not_nonempty_iff_eq_empty, not_iff_not, nonempty_Icc] theorem Ico_eq_empty_iff : Ico a b = ∅ ↔ ¬a < b := by rw [← not_nonempty_iff_eq_empty, not_iff_not, nonempty_Ico] theorem Ioc_eq_empty_iff : Ioc a b = ∅ ↔ ¬a < b := by rw [← not_nonempty_iff_eq_empty, not_iff_not, nonempty_Ioc] theorem Ioo_eq_empty_iff [DenselyOrdered α] : Ioo a b = ∅ ↔ ¬a < b := by rw [← not_nonempty_iff_eq_empty, not_iff_not, nonempty_Ioo] theorem _root_.IsTop.Iic_eq (h : IsTop a) : Iic a = univ := eq_univ_of_forall h theorem _root_.IsBot.Ici_eq (h : IsBot a) : Ici a = univ := eq_univ_of_forall h @[simp] theorem Ioi_eq_empty_iff : Ioi a = ∅ ↔ IsMax a := by simp only [isMax_iff_forall_not_lt, eq_empty_iff_forall_not_mem, mem_Ioi] @[simp] theorem Iio_eq_empty_iff : Iio a = ∅ ↔ IsMin a := Ioi_eq_empty_iff (α := αᵒᵈ) @[simp] alias ⟨_, _root_.IsMax.Ioi_eq⟩ := Ioi_eq_empty_iff @[simp] alias ⟨_, _root_.IsMin.Iio_eq⟩ := Iio_eq_empty_iff @[simp] lemma Iio_nonempty : (Iio a).Nonempty ↔ ¬ IsMin a := by simp [nonempty_iff_ne_empty] @[simp] lemma Ioi_nonempty : (Ioi a).Nonempty ↔ ¬ IsMax a := by simp [nonempty_iff_ne_empty] theorem Iic_inter_Ioc_of_le (h : a ≤ c) : Iic a ∩ Ioc b c = Ioc b a := ext fun _ => ⟨fun H => ⟨H.2.1, H.1⟩, fun H => ⟨H.2, H.1, H.2.trans h⟩⟩ theorem not_mem_Icc_of_lt (ha : c < a) : c ∉ Icc a b := fun h => ha.not_le h.1 theorem not_mem_Icc_of_gt (hb : b < c) : c ∉ Icc a b := fun h => hb.not_le h.2 theorem not_mem_Ico_of_lt (ha : c < a) : c ∉ Ico a b := fun h => ha.not_le h.1 theorem not_mem_Ioc_of_gt (hb : b < c) : c ∉ Ioc a b := fun h => hb.not_le h.2 theorem not_mem_Ioi_self : a ∉ Ioi a := lt_irrefl _ theorem not_mem_Iio_self : b ∉ Iio b := lt_irrefl _ theorem not_mem_Ioc_of_le (ha : c ≤ a) : c ∉ Ioc a b := fun h => lt_irrefl _ <\| h.1.trans_le ha theorem not_mem_Ico_of_ge (hb : b ≤ c) : c ∉ Ico a b := fun h => lt_irrefl _ <\| h.2.trans_le hb theorem not_mem_Ioo_of_le (ha : c ≤ a) : c ∉ Ioo a b := fun h => lt_irrefl _ <\| h.1.trans_le ha theorem not_mem_Ioo_of_ge (hb : b ≤ c) : c ∉ Ioo a b := fun h => lt_irrefl _ <\| h.2.trans_le hb section matched_intervals @[simp] theorem Icc_eq_Ioc_same_iff : Icc a b = Ioc a b ↔ ¬a ≤ b where mp h := by simpa using Set.ext_iff.mp h a mpr h := by rw [Icc_eq_empty h, Ioc_eq_empty (mt le_of_lt h)] @[simp] theorem Icc_eq_Ico_same_iff : Icc a b = Ico a b ↔ ¬a ≤ b where mp h := by simpa using Set.ext_iff.mp h b mpr h := by rw [Icc_eq_empty h, Ico_eq_empty (mt le_of_lt h)] @[simp] theorem Icc_eq_Ioo_same_iff : Icc a b = Ioo a b ↔ ¬a ≤ b where mp h := by simpa using Set.ext_iff.mp h b mpr h := by rw [Icc_eq_empty h, Ioo_eq_empty (mt le_of_lt h)] @[simp] theorem Ioc_eq_Ico_same_iff : Ioc a b = Ico a b ↔ ¬a < b where mp h := by simpa using Set.ext_iff.mp h a mpr h := by rw [Ioc_eq_empty h, Ico_eq_empty h] @[simp] theorem Ioo_eq_Ioc_same_iff : Ioo a b = Ioc a b ↔ ¬a < b where mp h := by simpa using Set.ext_iff.mp h b mpr h := by rw [Ioo_eq_empty h, Ioc_eq_empty h] @[simp] theorem Ioo_eq_Ico_same_iff : Ioo a b = Ico a b ↔ ¬a < b where mp h := by simpa using Set.ext_iff.mp h a mpr h := by rw [Ioo_eq_empty h, Ico_eq_empty h] -- Mirrored versions of the above for `simp`. @[simp] theorem Ioc_eq_Icc_same_iff : Ioc a b = Icc a b ↔ ¬a ≤ b := eq_comm.trans Icc_eq_Ioc_same_iff @[simp] theorem Ico_eq_Icc_same_iff : Ico a b = Icc a b ↔ ¬a ≤ b := eq_comm.trans Icc_eq_Ico_same_iff @[simp] theorem Ioo_eq_Icc_same_iff : Ioo a b = Icc a b ↔ ¬a ≤ b := eq_comm.trans Icc_eq_Ioo_same_iff @[simp] theorem Ico_eq_Ioc_same_iff : Ico a b = Ioc a b ↔ ¬a < b := eq_comm.trans Ioc_eq_Ico_same_iff @[simp] theorem Ioc_eq_Ioo_same_iff : Ioc a b = Ioo a b ↔ ¬a < b := eq_comm.trans Ioo_eq_Ioc_same_iff @[simp] theorem Ico_eq_Ioo_same_iff : Ico a b = Ioo a b ↔ ¬a < b := eq_comm.trans Ioo_eq_Ico_same_iff end matched_intervals end Preorder section PartialOrder variable [PartialOrder α] {a b c : α} @[simp] theorem Icc_self (a : α) : Icc a a = {a} := Set.ext <\| by simp [Icc, le_antisymm_iff, and_comm] instance instIccUnique : Unique (Set.Icc a a) where default := ⟨a, by simp⟩ uniq y := Subtype.ext <\| by simpa using y.2 @[simp] theorem Icc_eq_singleton_iff : Icc a b = {c} ↔ a = c ∧ b = c := by refine ⟨fun h => ?_, ?_⟩ · have hab : a ≤ b := nonempty_Icc.1 (h.symm.subst <\| singleton_nonempty c) exact ⟨eq_of_mem_singleton <\| h ▸ left_mem_Icc.2 hab, eq_of_mem_singleton <\| h ▸ right_mem_Icc.2 hab⟩ · rintro ⟨rfl, rfl⟩ exact Icc_self _ lemma subsingleton_Icc_of_ge (hba : b ≤ a) : Set.Subsingleton (Icc a b) := fun _x ⟨hax, hxb⟩ _y ⟨hay, hyb⟩ ↦ le_antisymm (le_implies_le_of_le_of_le hxb hay hba) (le_implies_le_of_le_of_le hyb hax hba) @[simp] lemma subsingleton_Icc_iff {α : Type} [LinearOrder α] {a b : α} : Set.Subsingleton (Icc a b) ↔ b ≤ a := by refine ⟨fun h ↦ ?_, subsingleton_Icc_of_ge⟩ contrapose! h simp only [gt_iff_lt, not_subsingleton_iff] exact ⟨a, ⟨le_refl _, h.le⟩, b, ⟨h.le, le_refl _⟩, h.ne⟩ @[simp] theorem Icc_diff_left : Icc a b \ {a} = Ioc a b := ext fun x => by simp [lt_iff_le_and_ne, eq_comm, and_right_comm] @[simp] theorem Icc_diff_right : Icc a b \ {b} = Ico a b := ext fun x => by simp [lt_iff_le_and_ne, and_assoc] @[simp] theorem Ico_diff_left : Ico a b \ {a} = Ioo a b := ext fun x => by simp [and_right_comm, ← lt_iff_le_and_ne, eq_comm] @[simp] theorem Ioc_diff_right : Ioc a b \ {b} = Ioo a b := ext fun x => by simp [and_assoc, ← lt_iff_le_and_ne] @[simp] theorem Icc_diff_both : Icc a b \ {a, b} = Ioo a b := by rw [insert_eq, ← diff_diff, Icc_diff_left, Ioc_diff_right] @[simp] theorem Ici_diff_left : Ici a \ {a} = Ioi a := ext fun x => by simp [lt_iff_le_and_ne, eq_comm] @[simp] theorem Iic_diff_right : Iic a \ {a} = Iio a := ext fun x => by simp [lt_iff_le_and_ne] @[simp] theorem Ico_diff_Ioo_same (h : a < b) : Ico a b \ Ioo a b = {a} := by rw [← Ico_diff_left, diff_diff_cancel_left (singleton_subset_iff.2 <\| left_mem_Ico.2 h)] @[simp] theorem Ioc_diff_Ioo_same (h : a < b) : Ioc a b \ Ioo a b = {b} := by rw [← Ioc_diff_right, diff_diff_cancel_left (singleton_subset_iff.2 <\| right_mem_Ioc.2 h)] @[simp] theorem Icc_diff_Ico_same (h : a ≤ b) : Icc a b \ Ico a b = {b} := by rw [← Icc_diff_right, diff_diff_cancel_left (singleton_subset_iff.2 <\| right_mem_Icc.2 h)] @[simp] theorem Icc_diff_Ioc_same (h : a ≤ b) : Icc a b \ Ioc a b = {a} := by rw [← Icc_diff_left, diff_diff_cancel_left (singleton_subset_iff.2 <\| left_mem_Icc.2 h)] @[simp] theorem Icc_diff_Ioo_same (h : a ≤ b) : Icc a b \ Ioo a b = {a, b} := by rw [← Icc_diff_both, diff_diff_cancel_left] simp [insert_subset_iff, h] @[simp] theorem Ici_diff_Ioi_same : Ici a \ Ioi a = {a} := by rw [← Ici_diff_left, diff_diff_cancel_left (singleton_subset_iff.2 left_mem_Ici)] @[simp] theorem Iic_diff_Iio_same : Iic a \ Iio a = {a} := by rw [← Iic_diff_right, diff_diff_cancel_left (singleton_subset_iff.2 right_mem_Iic)] theorem Ioi_union_left : Ioi a ∪ {a} = Ici a := ext fun x => by simp [eq_comm, le_iff_eq_or_lt] theorem Iio_union_right : Iio a ∪ {a} = Iic a := ext fun _ => le_iff_lt_or_eq.symm theorem Ioo_union_left (hab : a < b) : Ioo a b ∪ {a} = Ico a b := by rw [← Ico_diff_left, diff_union_self, union_eq_self_of_subset_right (singleton_subset_iff.2 <\| left_mem_Ico.2 hab)] theorem Ioo_union_right (hab : a < b) : Ioo a b ∪ {b} = Ioc a b := by simpa only [Ioo_toDual, Ico_toDual] using Ioo_union_left hab.dual theorem Ioo_union_both (h : a ≤ b) : Ioo a b ∪ {a, b} = Icc a b := by have : (Icc a b \ {a, b}) ∪ {a, b} = Icc a b := diff_union_of_subset fun \| x, .inl rfl => left_mem_Icc.mpr h \| x, .inr rfl => right_mem_Icc.mpr h rw [← this, Icc_diff_both] theorem Ioc_union_left (hab : a ≤ b) : Ioc a b ∪ {a} = Icc a b := by rw [← Icc_diff_left, diff_union_self, union_eq_self_of_subset_right (singleton_subset_iff.2 <\| left_mem_Icc.2 hab)] theorem Ico_union_right (hab : a ≤ b) : Ico a b ∪ {b} = Icc a b := by simpa only [Ioc_toDual, Icc_toDual] using Ioc_union_left hab.dual @[simp] theorem Ico_insert_right (h : a ≤ b) : insert b (Ico a b) = Icc a b := by rw [insert_eq, union_comm, Ico_union_right h] @[simp] theorem Ioc_insert_left (h : a ≤ b) : insert a (Ioc a b) = Icc a b := by rw [insert_eq, union_comm, Ioc_union_left h] @[simp] theorem Ioo_insert_left (h : a < b) : insert a (Ioo a b) = Ico a b := by rw [insert_eq, union_comm, Ioo_union_left h] @[simp] theorem Ioo_insert_right (h : a < b) : insert b (Ioo a b) = Ioc a b := by rw [insert_eq, union_comm, Ioo_union_right h] @[simp] theorem Iio_insert : insert a (Iio a) = Iic a := ext fun _ => le_iff_eq_or_lt.symm @[simp] theorem Ioi_insert : insert a (Ioi a) = Ici a := ext fun _ => (or_congr_left eq_comm).trans le_iff_eq_or_lt.symm theorem mem_Ici_Ioi_of_subset_of_subset {s : Set α} (ho : Ioi a ⊆ s) (hc : s ⊆ Ici a) : s ∈ ({Ici a, Ioi a} : Set (Set α)) := by_cases (fun h : a ∈ s => Or.inl <\| Subset.antisymm hc <\| by rw [← Ioi_union_left, union_subset_iff]; simp []) fun h => Or.inr <\| Subset.antisymm (fun _ hx => lt_of_le_of_ne (hc hx) fun heq => h <\| heq.symm ▸ hx) ho theorem mem_Iic_Iio_of_subset_of_subset {s : Set α} (ho : Iio a ⊆ s) (hc : s ⊆ Iic a) : s ∈ ({Iic a, Iio a} : Set (Set α)) := @mem_Ici_Ioi_of_subset_of_subset αᵒᵈ _ a s ho hc theorem mem_Icc_Ico_Ioc_Ioo_of_subset_of_subset {s : Set α} (ho : Ioo a b ⊆ s) (hc : s ⊆ Icc a b) : s ∈ ({Icc a b, Ico a b, Ioc a b, Ioo a b} : Set (Set α)) := by classical by_cases ha : a ∈ s <;> by_cases hb : b ∈ s · refine Or.inl (Subset.antisymm hc ?_) rwa [← Ico_diff_left, diff_singleton_subset_iff, insert_eq_of_mem ha, ← Icc_diff_right, diff_singleton_subset_iff, insert_eq_of_mem hb] at ho · refine Or.inr <\| Or.inl <\| Subset.antisymm ?_ ?_ · rw [← Icc_diff_right] exact subset_diff_singleton hc hb · rwa [← Ico_diff_left, diff_singleton_subset_iff, insert_eq_of_mem ha] at ho · refine Or.inr <\| Or.inr <\| Or.inl <\| Subset.antisymm ?_ ?_ · rw [← Icc_diff_left] exact subset_diff_singleton hc ha · rwa [← Ioc_diff_right, diff_singleton_subset_iff, insert_eq_of_mem hb] at ho · refine Or.inr <\| Or.inr <\| Or.inr <\| Subset.antisymm ?_ ho rw [← Ico_diff_left, ← Icc_diff_right] apply_rules [subset_diff_singleton] theorem eq_left_or_mem_Ioo_of_mem_Ico {x : α} (hmem : x ∈ Ico a b) : x = a ∨ x ∈ Ioo a b := hmem.1.eq_or_gt.imp_right fun h => ⟨h, hmem.2⟩ theorem eq_right_or_mem_Ioo_of_mem_Ioc {x : α} (hmem : x ∈ Ioc a b) : x = b ∨ x ∈ Ioo a b := hmem.2.eq_or_lt.imp_right <\| And.intro hmem.1 theorem eq_endpoints_or_mem_Ioo_of_mem_Icc {x : α} (hmem : x ∈ Icc a b) : x = a ∨ x = b ∨ x ∈ Ioo a b := hmem.1.eq_or_gt.imp_right fun h => eq_right_or_mem_Ioo_of_mem_Ioc ⟨h, hmem.2⟩ theorem _root_.IsMax.Ici_eq (h : IsMax a) : Ici a = {a} := eq_singleton_iff_unique_mem.2 ⟨left_mem_Ici, fun _ => h.eq_of_ge⟩ theorem _root_.IsMin.Iic_eq (h : IsMin a) : Iic a = {a} := h.toDual.Ici_eq theorem Ici_injective : Injective (Ici : α → Set α) := fun _ _ => eq_of_forall_ge_iff ∘ Set.ext_iff.1 theorem Iic_injective : Injective (Iic : α → Set α) := fun _ _ => eq_of_forall_le_iff ∘ Set.ext_iff.1 theorem Ici_inj : Ici a = Ici b ↔ a = b := Ici_injective.eq_iff theorem Iic_inj : Iic a = Iic b ↔ a = b := Iic_injective.eq_iff @[simp] theorem Icc_inter_Icc_eq_singleton (hab : a ≤ b) (hbc : b ≤ c) : Icc a b ∩ Icc b c = {b} := by rw [← Ici_inter_Iic, ← Iic_inter_Ici, inter_inter_inter_comm, Iic_inter_Ici] simp [hab, hbc] lemma Icc_eq_Icc_iff {d : α} (h : a ≤ b) : Icc a b = Icc c d ↔ a = c ∧ b = d := by refine ⟨fun heq ↦ ?_, by rintro ⟨rfl, rfl⟩; rfl⟩ have h' : c ≤ d := by by_contra contra; rw [Icc_eq_empty_iff.mpr contra, Icc_eq_empty_iff] at heq; contradiction simp only [Set.ext_iff, mem_Icc] at heq obtain ⟨-, h₁⟩ := (heq b).mp ⟨h, le_refl _⟩ obtain ⟨h₂, -⟩ := (heq a).mp ⟨le_refl _, h⟩ obtain ⟨h₃, -⟩ := (heq c).mpr ⟨le_refl _, h'⟩ obtain ⟨-, h₄⟩ := (heq d).mpr ⟨h', le_refl _⟩ exact ⟨le_antisymm h₃ h₂, le_antisymm h₁ h₄⟩ end PartialOrder section OrderTop @[simp] theorem Ici_top [PartialOrder α] [OrderTop α] : Ici (⊤ : α) = {⊤} := isMax_top.Ici_eq variable [Preorder α] [OrderTop α] {a : α} theorem Ioi_top : Ioi (⊤ : α) = ∅ := isMax_top.Ioi_eq @[simp] theorem Iic_top : Iic (⊤ : α) = univ := isTop_top.Iic_eq @[simp] theorem Icc_top : Icc a ⊤ = Ici a := by simp [← Ici_inter_Iic] @[simp] theorem Ioc_top : Ioc a ⊤ = Ioi a := by simp [← Ioi_inter_Iic] end OrderTop section OrderBot @[simp] theorem Iic_bot [PartialOrder α] [OrderBot α] : Iic (⊥ : α) = {⊥} := isMin_bot.Iic_eq variable [Preorder α] [OrderBot α] {a : α} theorem Iio_bot : Iio (⊥ : α) = ∅ := isMin_bot.Iio_eq @[simp] theorem Ici_bot : Ici (⊥ : α) = univ := isBot_bot.Ici_eq @[simp] theorem Icc_bot : Icc ⊥ a = Iic a := by simp [← Ici_inter_Iic] @[simp] theorem Ico_bot : Ico ⊥ a = Iio a := by simp [← Ici_inter_Iio] end OrderBot theorem Icc_bot_top [Preorder α] [BoundedOrder α] : Icc (⊥ : α) ⊤ = univ := by simp section Lattice section Inf variable [SemilatticeInf α] @[simp] theorem Iic_inter_Iic {a b : α} : Iic a ∩ Iic b = Iic (a ⊓ b) := by ext x simp [Iic] @[simp] theorem Ioc_inter_Iic (a b c : α) : Ioc a b ∩ Iic c = Ioc a (b ⊓ c) := by rw [← Ioi_inter_Iic, ← Ioi_inter_Iic, inter_assoc, Iic_inter_Iic] end Inf section Sup variable [SemilatticeSup α] @[simp] theorem Ici_inter_Ici {a b : α} : Ici a ∩ Ici b = Ici (a ⊔ b) := by ext x simp [Ici] @[simp] theorem Ico_inter_Ici (a b c : α) : Ico a b ∩ Ici c = Ico (a ⊔ c) b := by rw [← Ici_inter_Iio, ← Ici_inter_Iio, ← Ici_inter_Ici, inter_right_comm] end Sup section Both variable [Lattice α] {a b c a₁ a₂ b₁ b₂ : α} theorem Icc_inter_Icc : Icc a₁ b₁ ∩ Icc a₂ b₂ = Icc (a₁ ⊔ a₂) (b₁ ⊓ b₂) := by simp only [Ici_inter_Iic.symm, Ici_inter_Ici.symm, Iic_inter_Iic.symm]; ac_rfl end Both end Lattice /-! ### Closed intervals in `α × β` -/ section Prod variable {β : Type} [Preorder α] [Preorder β] @[simp] theorem Iic_prod_Iic (a : α) (b : β) : Iic a ×ˢ Iic b = Iic (a, b) := rfl @[simp] theorem Ici_prod_Ici (a : α) (b : β) : Ici a ×ˢ Ici b = Ici (a, b) := rfl theorem Ici_prod_eq (a : α × β) : Ici a = Ici a.1 ×ˢ Ici a.2 := rfl theorem Iic_prod_eq (a : α × β) : Iic a = Iic a.1 ×ˢ Iic a.2 := rfl @[simp] theorem Icc_prod_Icc (a₁ a₂ : α) (b₁ b₂ : β) : Icc a₁ a₂ ×ˢ Icc b₁ b₂ = Icc (a₁, b₁) (a₂, b₂) := by ext ⟨x, y⟩ simp [and_assoc, and_comm, and_left_comm] theorem Icc_prod_eq (a b : α × β) : Icc a b = Icc a.1 b.1 ×ˢ Icc a.2 b.2 := by simp end Prod end Set /-! ### Lemmas about intervals in dense orders -/ section Dense variable (α) [Preorder α] [DenselyOrdered α] {x y : α} instance : NoMinOrder (Set.Ioo x y) := ⟨fun ⟨a, ha₁, ha₂⟩ => by rcases exists_between ha₁ with ⟨b, hb₁, hb₂⟩ exact ⟨⟨b, hb₁, hb₂.trans ha₂⟩, hb₂⟩⟩ instance : NoMinOrder (Set.Ioc x y) := ⟨fun ⟨a, ha₁, ha₂⟩ => by rcases exists_between ha₁ with ⟨b, hb₁, hb₂⟩ exact ⟨⟨b, hb₁, hb₂.le.trans ha₂⟩, hb₂⟩⟩ instance : NoMinOrder (Set.Ioi x) := ⟨fun ⟨a, ha⟩ => by rcases exists_between ha with ⟨b, hb₁, hb₂⟩ exact ⟨⟨b, hb₁⟩, hb₂⟩⟩ instance : NoMaxOrder (Set.Ioo x y) := ⟨fun ⟨a, ha₁, ha₂⟩ => by rcases exists_between ha₂ with ⟨b, hb₁, hb₂⟩ exact ⟨⟨b, ha₁.trans hb₁, hb₂⟩, hb₁⟩⟩ instance : NoMaxOrder (Set.Ico x y) := ⟨fun ⟨a, ha₁, ha₂⟩ => by rcases exists_between ha₂ with ⟨b, hb₁, hb₂⟩ exact ⟨⟨b, ha₁.trans hb₁.le, hb₂⟩, hb₁⟩⟩ instance : NoMaxOrder (Set.Iio x) := ⟨fun ⟨a, ha⟩ => by rcases exists_between ha with ⟨b, hb₁, hb₂⟩ exact ⟨⟨b, hb₂⟩, hb₁⟩⟩ end Dense /-! ### Intervals in `Prop` -/ namespace Set @[simp] lemma Iic_False : Iic False = {False} := by aesop @[simp] lemma Iic_True : Iic True = univ := by aesop @[simp] lemma Ici_False : Ici False = univ := by aesop @[simp] lemma Ici_True : Ici True = {True} := by aesop lemma Iio_False : Iio False = ∅ := by aesop @[simp] lemma Iio_True : Iio True = {False} := by aesop (add simp [Ioi, lt_iff_le_not_le]) @[simp] lemma Ioi_False : Ioi False = {True} := by aesop (add simp [Ioi, lt_iff_le_not_le]) lemma Ioi_True : Ioi True = ∅ := by aesop end Set		Mathlib/Order/Interval/Set/Basic.lean	1,228	1,231
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Mario Carneiro, Yury Kudryashov -/ import Mathlib.Topology.Bases import Mathlib.Topology.Compactness.LocallyCompact import Mathlib.Topology.Compactness.LocallyFinite /-! # Sigma-compactness in topological spaces ## Main definitions * `IsSigmaCompact`: a set that is the union of countably many compact sets. * `SigmaCompactSpace X`: `X` is a σ-compact topological space; i.e., is the union of a countable collection of compact subspaces. -/ open Set Filter Topology TopologicalSpace universe u v variable {X : Type} {Y : Type} {ι : Type} variable [TopologicalSpace X] [TopologicalSpace Y] {s t : Set X} /-- A subset `s ⊆ X` is called σ-compact* if it is the union of countably many compact sets. -/ def IsSigmaCompact (s : Set X) : Prop := ∃ K : ℕ → Set X, (∀ n, IsCompact (K n)) ∧ ⋃ n, K n = s /-- Compact sets are σ-compact. -/ lemma IsCompact.isSigmaCompact {s : Set X} (hs : IsCompact s) : IsSigmaCompact s := ⟨fun _ => s, fun _ => hs, iUnion_const _⟩ /-- The empty set is σ-compact. -/	@[simp] lemma isSigmaCompact_empty : IsSigmaCompact (∅ : Set X) := IsCompact.isSigmaCompact isCompact_empty /-- Countable unions of compact sets are σ-compact. -/ lemma isSigmaCompact_iUnion_of_isCompact [hι : Countable ι] (s : ι → Set X) (hcomp : ∀ i, IsCompact (s i)) : IsSigmaCompact (⋃ i, s i) := by rcases isEmpty_or_nonempty ι	Mathlib/Topology/Compactness/SigmaCompact.lean	36	43
/- Copyright (c) 2024 Kalle Kytölä. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kalle Kytölä -/ import Mathlib.Topology.Separation.CompletelyRegular import Mathlib.MeasureTheory.Measure.ProbabilityMeasure /-! # Dirac deltas as probability measures and embedding of a space into probability measures on it ## Main definitions * `diracProba`: The Dirac delta mass at a point as a probability measure. ## Main results * `isEmbedding_diracProba`: If `X` is a completely regular T0 space with its Borel sigma algebra, then the mapping that takes a point `x : X` to the delta-measure `diracProba x` is an embedding `X ↪ ProbabilityMeasure X`. ## Tags probability measure, Dirac delta, embedding -/ open Topology Metric Filter Set ENNReal NNReal BoundedContinuousFunction open scoped Topology ENNReal NNReal BoundedContinuousFunction lemma CompletelyRegularSpace.exists_BCNN {X : Type} [TopologicalSpace X] [CompletelyRegularSpace X] {K : Set X} (K_closed : IsClosed K) {x : X} (x_notin_K : x ∉ K) : ∃ (f : X →ᵇ ℝ≥0), f x = 1 ∧ (∀ y ∈ K, f y = 0) := by obtain ⟨g, g_cont, gx_zero, g_one_on_K⟩ := CompletelyRegularSpace.completely_regular x K K_closed x_notin_K have g_bdd : ∀ x y, dist (Real.toNNReal (g x)) (Real.toNNReal (g y)) ≤ 1 := by refine fun x y ↦ ((Real.lipschitzWith_toNNReal).dist_le_mul (g x) (g y)).trans ?_ simpa using Real.dist_le_of_mem_Icc_01 (g x).prop (g y).prop set g' := BoundedContinuousFunction.mkOfBound ⟨fun x ↦ Real.toNNReal (g x), continuous_real_toNNReal.comp g_cont.subtype_val⟩ 1 g_bdd set f := 1 - g' refine ⟨f, by simp [f, g', gx_zero], fun y y_in_K ↦ by simp [f, g', g_one_on_K y_in_K, tsub_self]⟩ namespace MeasureTheory section embed_to_probabilityMeasure variable {X : Type} [MeasurableSpace X] /-- The Dirac delta mass at a point `x : X` as a `ProbabilityMeasure`. -/ noncomputable def diracProba (x : X) : ProbabilityMeasure X := ⟨Measure.dirac x, Measure.dirac.isProbabilityMeasure⟩ /-- The assignment `x ↦ diracProba x` is injective if all singletons are measurable. -/ lemma injective_diracProba {X : Type*} [MeasurableSpace X] [MeasurableSpace.SeparatesPoints X] : Function.Injective (fun (x : X) ↦ diracProba x) := by intro x y x_eq_y rw [← dirac_eq_dirac_iff] rwa [Subtype.ext_iff] at x_eq_y @[simp] lemma diracProba_toMeasure_apply' (x : X) {A : Set X} (A_mble : MeasurableSet A) : (diracProba x).toMeasure A = A.indicator 1 x := Measure.dirac_apply' x A_mble @[simp] lemma diracProba_toMeasure_apply_of_mem {x : X} {A : Set X} (x_in_A : x ∈ A) : (diracProba x).toMeasure A = 1 := Measure.dirac_apply_of_mem x_in_A @[simp] lemma diracProba_toMeasure_apply [MeasurableSingletonClass X] (x : X) (A : Set X) : (diracProba x).toMeasure A = A.indicator 1 x := Measure.dirac_apply _ _ variable [TopologicalSpace X] [OpensMeasurableSpace X] /-- The assignment `x ↦ diracProba x` is continuous `X → ProbabilityMeasure X`. -/ lemma continuous_diracProba : Continuous (fun (x : X) ↦ diracProba x) := by rw [continuous_iff_continuousAt] apply fun x ↦ ProbabilityMeasure.tendsto_iff_forall_lintegral_tendsto.mpr fun f ↦ ?_ have f_mble : Measurable (fun X ↦ (f X : ℝ≥0∞)) := measurable_coe_nnreal_ennreal_iff.mpr f.continuous.measurable simp only [diracProba, ProbabilityMeasure.coe_mk, lintegral_dirac' _ f_mble] exact (ENNReal.continuous_coe.comp f.continuous).continuousAt /-- In a T0 topological space equipped with a sigma algebra which contains all open sets, the assignment `x ↦ diracProba x` is injective. -/ lemma injective_diracProba_of_T0 [T0Space X] : Function.Injective (fun (x : X) ↦ diracProba x) := by intro x y δx_eq_δy by_contra x_ne_y exact dirac_ne_dirac x_ne_y <\| congr_arg Subtype.val δx_eq_δy	lemma not_tendsto_diracProba_of_not_tendsto [CompletelyRegularSpace X] {x : X} (L : Filter X) (h : ¬ Tendsto id L (𝓝 x)) : ¬ Tendsto diracProba L (𝓝 (diracProba x)) := by obtain ⟨U, U_nhd, hU⟩ : ∃ U, U ∈ 𝓝 x ∧ ∃ᶠ x in L, x ∉ U := by by_contra! con apply h intro U U_nhd simpa only [not_frequently, not_not] using con U U_nhd have Uint_nhd : interior U ∈ 𝓝 x := by simpa only [interior_mem_nhds] using U_nhd obtain ⟨f, fx_eq_one, f_vanishes_outside⟩ := CompletelyRegularSpace.exists_BCNN isOpen_interior.isClosed_compl (by simpa only [mem_compl_iff, not_not] using mem_of_mem_nhds Uint_nhd) rw [ProbabilityMeasure.tendsto_iff_forall_lintegral_tendsto, not_forall] use f simp only [diracProba, ProbabilityMeasure.coe_mk, fx_eq_one, lintegral_dirac' _ (measurable_coe_nnreal_ennreal_iff.mpr f.continuous.measurable)] apply not_tendsto_iff_exists_frequently_nmem.mpr refine ⟨Ioi 0, Ioi_mem_nhds (by simp only [ENNReal.coe_one, zero_lt_one]), hU.mp (Eventually.of_forall ?_)⟩ intro x x_notin_U rw [f_vanishes_outside x (compl_subset_compl.mpr (show interior U ⊆ U from interior_subset) x_notin_U)] simp only [ENNReal.coe_zero, mem_Ioi, lt_self_iff_false, not_false_eq_true]	Mathlib/MeasureTheory/Measure/DiracProba.lean	86	108
/- Copyright (c) 2020 Yury Kudryashov. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yury Kudryashov -/ import Mathlib.Algebra.Star.SelfAdjoint import Mathlib.LinearAlgebra.Dimension.StrongRankCondition import Mathlib.LinearAlgebra.FreeModule.Finite.Basic /-! # Quaternions In this file we define quaternions `ℍ[R]` over a commutative ring `R`, and define some algebraic structures on `ℍ[R]`. ## Main definitions * `QuaternionAlgebra R a b c`, `ℍ[R, a, b, c]` : [Bourbaki, Algebra I][bourbaki1989] with coefficients `a`, `b`, `c` (Many other references such as Wikipedia assume $\operatorname{char} R ≠ 2$ therefore one can complete the square and WLOG assume $b = 0$.) * `Quaternion R`, `ℍ[R]` : the space of quaternions, a.k.a. `QuaternionAlgebra R (-1) (0) (-1)`; * `Quaternion.normSq` : square of the norm of a quaternion; We also define the following algebraic structures on `ℍ[R]`: * `Ring ℍ[R, a, b, c]`, `StarRing ℍ[R, a, b, c]`, and `Algebra R ℍ[R, a, b, c]` : for any commutative ring `R`; * `Ring ℍ[R]`, `StarRing ℍ[R]`, and `Algebra R ℍ[R]` : for any commutative ring `R`; * `IsDomain ℍ[R]` : for a linear ordered commutative ring `R`; * `DivisionRing ℍ[R]` : for a linear ordered field `R`. ## Notation The following notation is available with `open Quaternion` or `open scoped Quaternion`. * `ℍ[R, c₁, c₂, c₃]` : `QuaternionAlgebra R c₁ c₂ c₃` * `ℍ[R, c₁, c₂]` : `QuaternionAlgebra R c₁ 0 c₂` * `ℍ[R]` : quaternions over `R`. ## Implementation notes We define quaternions over any ring `R`, not just `ℝ` to be able to deal with, e.g., integer or rational quaternions without using real numbers. In particular, all definitions in this file are computable. ## Tags quaternion -/ /-- Quaternion algebra over a type with fixed coefficients where $i^2 = a + bi$ and $j^2 = c$, denoted as `ℍ[R,a,b]`. Implemented as a structure with four fields: `re`, `imI`, `imJ`, and `imK`. -/ @[ext] structure QuaternionAlgebra (R : Type) (a b c : R) where /-- Real part of a quaternion. -/ re : R /-- First imaginary part (i) of a quaternion. -/ imI : R /-- Second imaginary part (j) of a quaternion. -/ imJ : R /-- Third imaginary part (k) of a quaternion. -/ imK : R @[inherit_doc] scoped[Quaternion] notation "ℍ[" R "," a "," b "," c "]" => QuaternionAlgebra R a b c @[inherit_doc] scoped[Quaternion] notation "ℍ[" R "," a "," b "]" => QuaternionAlgebra R a 0 b namespace QuaternionAlgebra open Quaternion /-- The equivalence between a quaternion algebra over `R` and `R × R × R × R`. -/ @[simps] def equivProd {R : Type} (c₁ c₂ c₃ : R) : ℍ[R,c₁,c₂,c₃] ≃ R × R × R × R where toFun a := ⟨a.1, a.2, a.3, a.4⟩ invFun a := ⟨a.1, a.2.1, a.2.2.1, a.2.2.2⟩ left_inv _ := rfl right_inv _ := rfl /-- The equivalence between a quaternion algebra over `R` and `Fin 4 → R`. -/ @[simps symm_apply] def equivTuple {R : Type} (c₁ c₂ c₃ : R) : ℍ[R,c₁,c₂,c₃] ≃ (Fin 4 → R) where toFun a := ![a.1, a.2, a.3, a.4] invFun a := ⟨a 0, a 1, a 2, a 3⟩ left_inv _ := rfl right_inv f := by ext ⟨_, _ \| _ \| _ \| _ \| _ \| ⟨⟩⟩ <;> rfl @[simp] theorem equivTuple_apply {R : Type} (c₁ c₂ c₃ : R) (x : ℍ[R,c₁,c₂,c₃]) : equivTuple c₁ c₂ c₃ x = ![x.re, x.imI, x.imJ, x.imK] := rfl @[simp] theorem mk.eta {R : Type} {c₁ c₂ c₃} (a : ℍ[R,c₁,c₂,c₃]) : mk a.1 a.2 a.3 a.4 = a := rfl variable {S T R : Type} {c₁ c₂ c₃ : R} (r x y : R) (a b : ℍ[R,c₁,c₂,c₃]) instance [Subsingleton R] : Subsingleton ℍ[R, c₁, c₂, c₃] := (equivTuple c₁ c₂ c₃).subsingleton instance [Nontrivial R] : Nontrivial ℍ[R, c₁, c₂, c₃] := (equivTuple c₁ c₂ c₃).surjective.nontrivial section Zero variable [Zero R] /-- The imaginary part of a quaternion. Note that unless `c₂ = 0`, this definition is not particularly well-behaved; for instance, `QuaternionAlgebra.star_im` only says that the star of an imaginary quaternion is imaginary under this condition. -/ def im (x : ℍ[R,c₁,c₂,c₃]) : ℍ[R,c₁,c₂,c₃] := ⟨0, x.imI, x.imJ, x.imK⟩ @[simp] theorem im_re : a.im.re = 0 := rfl @[simp] theorem im_imI : a.im.imI = a.imI := rfl @[simp] theorem im_imJ : a.im.imJ = a.imJ := rfl @[simp] theorem im_imK : a.im.imK = a.imK := rfl @[simp] theorem im_idem : a.im.im = a.im := rfl /-- Coercion `R → ℍ[R,c₁,c₂,c₃]`. -/ @[coe] def coe (x : R) : ℍ[R,c₁,c₂,c₃] := ⟨x, 0, 0, 0⟩ instance : CoeTC R ℍ[R,c₁,c₂,c₃] := ⟨coe⟩ @[simp, norm_cast] theorem coe_re : (x : ℍ[R,c₁,c₂,c₃]).re = x := rfl @[simp, norm_cast] theorem coe_imI : (x : ℍ[R,c₁,c₂,c₃]).imI = 0 := rfl @[simp, norm_cast] theorem coe_imJ : (x : ℍ[R,c₁,c₂,c₃]).imJ = 0 := rfl @[simp, norm_cast] theorem coe_imK : (x : ℍ[R,c₁,c₂,c₃]).imK = 0 := rfl theorem coe_injective : Function.Injective (coe : R → ℍ[R,c₁,c₂,c₃]) := fun _ _ h => congr_arg re h @[simp] theorem coe_inj {x y : R} : (x : ℍ[R,c₁,c₂,c₃]) = y ↔ x = y := coe_injective.eq_iff -- Porting note: removed `simps`, added simp lemmas manually. -- Should adjust `simps` to name properly, i.e. as `zero_re` rather than `instZero_zero_re`. instance : Zero ℍ[R,c₁,c₂,c₃] := ⟨⟨0, 0, 0, 0⟩⟩ @[scoped simp] theorem zero_re : (0 : ℍ[R,c₁,c₂,c₃]).re = 0 := rfl @[scoped simp] theorem zero_imI : (0 : ℍ[R,c₁,c₂,c₃]).imI = 0 := rfl @[scoped simp] theorem zero_imJ : (0 : ℍ[R,c₁,c₂,c₃]).imJ = 0 := rfl @[scoped simp] theorem zero_imK : (0 : ℍ[R,c₁,c₂,c₃]).imK = 0 := rfl @[scoped simp] theorem zero_im : (0 : ℍ[R,c₁,c₂,c₃]).im = 0 := rfl @[simp, norm_cast] theorem coe_zero : ((0 : R) : ℍ[R,c₁,c₂,c₃]) = 0 := rfl instance : Inhabited ℍ[R,c₁,c₂,c₃] := ⟨0⟩ section One variable [One R] -- Porting note: removed `simps`, added simp lemmas manually. Should adjust `simps` to name properly instance : One ℍ[R,c₁,c₂,c₃] := ⟨⟨1, 0, 0, 0⟩⟩ @[scoped simp] theorem one_re : (1 : ℍ[R,c₁,c₂,c₃]).re = 1 := rfl @[scoped simp] theorem one_imI : (1 : ℍ[R,c₁,c₂,c₃]).imI = 0 := rfl @[scoped simp] theorem one_imJ : (1 : ℍ[R,c₁,c₂,c₃]).imJ = 0 := rfl @[scoped simp] theorem one_imK : (1 : ℍ[R,c₁,c₂,c₃]).imK = 0 := rfl @[scoped simp] theorem one_im : (1 : ℍ[R,c₁,c₂,c₃]).im = 0 := rfl @[simp, norm_cast] theorem coe_one : ((1 : R) : ℍ[R,c₁,c₂,c₃]) = 1 := rfl end One end Zero section Add variable [Add R] -- Porting note: removed `simps`, added simp lemmas manually. Should adjust `simps` to name properly instance : Add ℍ[R,c₁,c₂,c₃] := ⟨fun a b => ⟨a.1 + b.1, a.2 + b.2, a.3 + b.3, a.4 + b.4⟩⟩ @[simp] theorem add_re : (a + b).re = a.re + b.re := rfl @[simp] theorem add_imI : (a + b).imI = a.imI + b.imI := rfl @[simp] theorem add_imJ : (a + b).imJ = a.imJ + b.imJ := rfl @[simp] theorem add_imK : (a + b).imK = a.imK + b.imK := rfl @[simp] theorem mk_add_mk (a₁ a₂ a₃ a₄ b₁ b₂ b₃ b₄ : R) : (mk a₁ a₂ a₃ a₄ : ℍ[R,c₁,c₂,c₃]) + mk b₁ b₂ b₃ b₄ = mk (a₁ + b₁) (a₂ + b₂) (a₃ + b₃) (a₄ + b₄) := rfl end Add section AddZeroClass variable [AddZeroClass R] @[simp] theorem add_im : (a + b).im = a.im + b.im := QuaternionAlgebra.ext (zero_add _).symm rfl rfl rfl @[simp, norm_cast] theorem coe_add : ((x + y : R) : ℍ[R,c₁,c₂,c₃]) = x + y := by ext <;> simp end AddZeroClass section Neg variable [Neg R] -- Porting note: removed `simps`, added simp lemmas manually. Should adjust `simps` to name properly instance : Neg ℍ[R,c₁,c₂,c₃] := ⟨fun a => ⟨-a.1, -a.2, -a.3, -a.4⟩⟩ @[simp] theorem neg_re : (-a).re = -a.re := rfl @[simp] theorem neg_imI : (-a).imI = -a.imI := rfl @[simp] theorem neg_imJ : (-a).imJ = -a.imJ := rfl @[simp] theorem neg_imK : (-a).imK = -a.imK := rfl @[simp] theorem neg_mk (a₁ a₂ a₃ a₄ : R) : -(mk a₁ a₂ a₃ a₄ : ℍ[R,c₁,c₂,c₃]) = ⟨-a₁, -a₂, -a₃, -a₄⟩ := rfl end Neg section AddGroup variable [AddGroup R] @[simp] theorem neg_im : (-a).im = -a.im := QuaternionAlgebra.ext neg_zero.symm rfl rfl rfl @[simp, norm_cast] theorem coe_neg : ((-x : R) : ℍ[R,c₁,c₂,c₃]) = -x := by ext <;> simp instance : Sub ℍ[R,c₁,c₂,c₃] := ⟨fun a b => ⟨a.1 - b.1, a.2 - b.2, a.3 - b.3, a.4 - b.4⟩⟩ @[simp] theorem sub_re : (a - b).re = a.re - b.re := rfl @[simp] theorem sub_imI : (a - b).imI = a.imI - b.imI := rfl @[simp] theorem sub_imJ : (a - b).imJ = a.imJ - b.imJ := rfl @[simp] theorem sub_imK : (a - b).imK = a.imK - b.imK := rfl @[simp] theorem sub_im : (a - b).im = a.im - b.im := QuaternionAlgebra.ext (sub_zero _).symm rfl rfl rfl @[simp] theorem mk_sub_mk (a₁ a₂ a₃ a₄ b₁ b₂ b₃ b₄ : R) : (mk a₁ a₂ a₃ a₄ : ℍ[R,c₁,c₂,c₃]) - mk b₁ b₂ b₃ b₄ = mk (a₁ - b₁) (a₂ - b₂) (a₃ - b₃) (a₄ - b₄) := rfl @[simp, norm_cast] theorem coe_im : (x : ℍ[R,c₁,c₂,c₃]).im = 0 := rfl @[simp] theorem re_add_im : ↑a.re + a.im = a := QuaternionAlgebra.ext (add_zero _) (zero_add _) (zero_add _) (zero_add _) @[simp] theorem sub_self_im : a - a.im = a.re := QuaternionAlgebra.ext (sub_zero _) (sub_self _) (sub_self _) (sub_self _) @[simp] theorem sub_self_re : a - a.re = a.im := QuaternionAlgebra.ext (sub_self _) (sub_zero _) (sub_zero _) (sub_zero _) end AddGroup section Ring variable [Ring R] /-- Multiplication is given by * `1 * x = x * 1 = x`; * `i * i = c₁ + c₂ * i`; * `j * j = c₃`; * `i * j = k`, `j * i = c₂ * j - k`; * `k * k = - c₁ * c₃`; * `i * k = c₁ * j + c₂ * k`, `k * i = -c₁ * j`; * `j * k = c₂ * c₃ - c₃ * i`, `k * j = c₃ * i`. -/ instance : Mul ℍ[R,c₁,c₂,c₃] := ⟨fun a b => ⟨a.1 * b.1 + c₁ * a.2 * b.2 + c₃ * a.3 * b.3 + c₂ * c₃ * a.3 * b.4 - c₁ * c₃ * a.4 * b.4, a.1 * b.2 + a.2 * b.1 + c₂ * a.2 * b.2 - c₃ * a.3 * b.4 + c₃ * a.4 * b.3, a.1 * b.3 + c₁ * a.2 * b.4 + a.3 * b.1 + c₂ * a.3 * b.2 - c₁ * a.4 * b.2, a.1 * b.4 + a.2 * b.3 + c₂ * a.2 * b.4 - a.3 * b.2 + a.4 * b.1⟩⟩ @[simp] theorem mul_re : (a * b).re = a.1 * b.1 + c₁ * a.2 * b.2 + c₃ * a.3 * b.3 + c₂ * c₃ * a.3 * b.4 - c₁ * c₃ * a.4 * b.4 := rfl @[simp] theorem mul_imI : (a * b).imI = a.1 * b.2 + a.2 * b.1 + c₂ * a.2 * b.2 - c₃ * a.3 * b.4 + c₃ * a.4 * b.3 := rfl @[simp] theorem mul_imJ : (a * b).imJ = a.1 * b.3 + c₁ * a.2 * b.4 + a.3 * b.1 + c₂ * a.3 * b.2 - c₁ * a.4 * b.2 := rfl @[simp] theorem mul_imK : (a * b).imK = a.1 * b.4 + a.2 * b.3 + c₂ * a.2 * b.4 - a.3 * b.2 + a.4 * b.1 := rfl @[simp] theorem mk_mul_mk (a₁ a₂ a₃ a₄ b₁ b₂ b₃ b₄ : R) : (mk a₁ a₂ a₃ a₄ : ℍ[R,c₁,c₂,c₃]) * mk b₁ b₂ b₃ b₄ = mk (a₁ * b₁ + c₁ * a₂ * b₂ + c₃ * a₃ * b₃ + c₂ * c₃ * a₃ * b₄ - c₁ * c₃ * a₄ * b₄) (a₁ * b₂ + a₂ * b₁ + c₂ * a₂ * b₂ - c₃ * a₃ * b₄ + c₃ * a₄ * b₃) (a₁ * b₃ + c₁ * a₂ * b₄ + a₃ * b₁ + c₂ * a₃ * b₂ - c₁ * a₄ * b₂) (a₁ * b₄ + a₂ * b₃ + c₂ * a₂ * b₄ - a₃ * b₂ + a₄ * b₁) := rfl end Ring section SMul variable [SMul S R] [SMul T R] (s : S) instance : SMul S ℍ[R,c₁,c₂,c₃] where smul s a := ⟨s • a.1, s • a.2, s • a.3, s • a.4⟩ instance [SMul S T] [IsScalarTower S T R] : IsScalarTower S T ℍ[R,c₁,c₂,c₃] where smul_assoc s t x := by ext <;> exact smul_assoc _ _ _ instance [SMulCommClass S T R] : SMulCommClass S T ℍ[R,c₁,c₂,c₃] where smul_comm s t x := by ext <;> exact smul_comm _ _ _ @[simp] theorem smul_re : (s • a).re = s • a.re := rfl @[simp] theorem smul_imI : (s • a).imI = s • a.imI := rfl @[simp] theorem smul_imJ : (s • a).imJ = s • a.imJ := rfl @[simp] theorem smul_imK : (s • a).imK = s • a.imK := rfl @[simp] theorem smul_im {S} [CommRing R] [SMulZeroClass S R] (s : S) : (s • a).im = s • a.im := QuaternionAlgebra.ext (smul_zero s).symm rfl rfl rfl @[simp] theorem smul_mk (re im_i im_j im_k : R) : s • (⟨re, im_i, im_j, im_k⟩ : ℍ[R,c₁,c₂,c₃]) = ⟨s • re, s • im_i, s • im_j, s • im_k⟩ := rfl end SMul @[simp, norm_cast] theorem coe_smul [Zero R] [SMulZeroClass S R] (s : S) (r : R) : (↑(s • r) : ℍ[R,c₁,c₂,c₃]) = s • (r : ℍ[R,c₁,c₂,c₃]) := QuaternionAlgebra.ext rfl (smul_zero _).symm (smul_zero _).symm (smul_zero _).symm instance [AddCommGroup R] : AddCommGroup ℍ[R,c₁,c₂,c₃] := (equivProd c₁ c₂ c₃).injective.addCommGroup _ rfl (fun _ _ ↦ rfl) (fun _ ↦ rfl) (fun _ _ ↦ rfl) (fun _ _ ↦ rfl) (fun _ _ ↦ rfl) section AddCommGroupWithOne variable [AddCommGroupWithOne R] instance : AddCommGroupWithOne ℍ[R,c₁,c₂,c₃] where natCast n := ((n : R) : ℍ[R,c₁,c₂,c₃]) natCast_zero := by simp natCast_succ := by simp intCast n := ((n : R) : ℍ[R,c₁,c₂,c₃]) intCast_ofNat _ := congr_arg coe (Int.cast_natCast _) intCast_negSucc n := by change coe _ = -coe _ rw [Int.cast_negSucc, coe_neg] @[simp, norm_cast] theorem natCast_re (n : ℕ) : (n : ℍ[R,c₁,c₂,c₃]).re = n := rfl @[simp, norm_cast] theorem natCast_imI (n : ℕ) : (n : ℍ[R,c₁,c₂,c₃]).imI = 0 := rfl @[simp, norm_cast] theorem natCast_imJ (n : ℕ) : (n : ℍ[R,c₁,c₂,c₃]).imJ = 0 := rfl @[simp, norm_cast] theorem natCast_imK (n : ℕ) : (n : ℍ[R,c₁,c₂,c₃]).imK = 0 := rfl @[simp, norm_cast] theorem natCast_im (n : ℕ) : (n : ℍ[R,c₁,c₂,c₃]).im = 0 := rfl @[norm_cast] theorem coe_natCast (n : ℕ) : ↑(n : R) = (n : ℍ[R,c₁,c₂,c₃]) := rfl @[simp, norm_cast] theorem intCast_re (z : ℤ) : (z : ℍ[R,c₁,c₂,c₃]).re = z := rfl @[scoped simp] theorem ofNat_re (n : ℕ) [n.AtLeastTwo] : (ofNat(n) : ℍ[R,c₁,c₂,c₃]).re = ofNat(n) := rfl @[scoped simp] theorem ofNat_imI (n : ℕ) [n.AtLeastTwo] : (ofNat(n) : ℍ[R,c₁,c₂,c₃]).imI = 0 := rfl @[scoped simp] theorem ofNat_imJ (n : ℕ) [n.AtLeastTwo] : (ofNat(n) : ℍ[R,c₁,c₂,c₃]).imJ = 0 := rfl @[scoped simp] theorem ofNat_imK (n : ℕ) [n.AtLeastTwo] : (ofNat(n) : ℍ[R,c₁,c₂,c₃]).imK = 0 := rfl @[scoped simp] theorem ofNat_im (n : ℕ) [n.AtLeastTwo] : (ofNat(n) : ℍ[R,c₁,c₂,c₃]).im = 0 := rfl @[simp, norm_cast] theorem intCast_imI (z : ℤ) : (z : ℍ[R,c₁,c₂,c₃]).imI = 0 := rfl @[simp, norm_cast] theorem intCast_imJ (z : ℤ) : (z : ℍ[R,c₁,c₂,c₃]).imJ = 0 := rfl @[simp, norm_cast] theorem intCast_imK (z : ℤ) : (z : ℍ[R,c₁,c₂,c₃]).imK = 0 := rfl @[simp, norm_cast] theorem intCast_im (z : ℤ) : (z : ℍ[R,c₁,c₂,c₃]).im = 0 := rfl @[norm_cast] theorem coe_intCast (z : ℤ) : ↑(z : R) = (z : ℍ[R,c₁,c₂,c₃]) := rfl end AddCommGroupWithOne -- For the remainder of the file we assume `CommRing R`. variable [CommRing R] instance instRing : Ring ℍ[R,c₁,c₂,c₃] where __ := inferInstanceAs (AddCommGroupWithOne ℍ[R,c₁,c₂,c₃]) left_distrib _ _ _ := by ext <;> simp <;> ring right_distrib _ _ _ := by ext <;> simp <;> ring zero_mul _ := by ext <;> simp mul_zero _ := by ext <;> simp mul_assoc _ _ _ := by ext <;> simp <;> ring one_mul _ := by ext <;> simp mul_one _ := by ext <;> simp @[norm_cast, simp] theorem coe_mul : ((x * y : R) : ℍ[R,c₁,c₂,c₃]) = x * y := by ext <;> simp @[norm_cast, simp] lemma coe_ofNat {n : ℕ} [n.AtLeastTwo]: ((ofNat(n) : R) : ℍ[R,c₁,c₂,c₃]) = (ofNat(n) : ℍ[R,c₁,c₂,c₃]) := by rfl -- TODO: add weaker `MulAction`, `DistribMulAction`, and `Module` instances (and repeat them -- for `ℍ[R]`) instance [CommSemiring S] [Algebra S R] : Algebra S ℍ[R,c₁,c₂,c₃] where smul := (· • ·) algebraMap := { toFun s := coe (algebraMap S R s) map_one' := by simp only [map_one, coe_one] map_zero' := by simp only [map_zero, coe_zero] map_mul' x y := by simp only [map_mul, coe_mul] map_add' x y := by simp only [map_add, coe_add] } smul_def' s x := by ext <;> simp [Algebra.smul_def] commutes' s x := by ext <;> simp [Algebra.commutes] theorem algebraMap_eq (r : R) : algebraMap R ℍ[R,c₁,c₂,c₃] r = ⟨r, 0, 0, 0⟩ := rfl theorem algebraMap_injective : (algebraMap R ℍ[R,c₁,c₂,c₃] : _ → _).Injective := fun _ _ ↦ by simp [algebraMap_eq] instance [NoZeroDivisors R] : NoZeroSMulDivisors R ℍ[R,c₁,c₂,c₃] := ⟨by rintro t ⟨a, b, c, d⟩ h rw [or_iff_not_imp_left] intro ht simpa [QuaternionAlgebra.ext_iff, ht] using h⟩ section variable (c₁ c₂ c₃) /-- `QuaternionAlgebra.re` as a `LinearMap` -/ @[simps] def reₗ : ℍ[R,c₁,c₂,c₃] →ₗ[R] R where toFun := re map_add' _ _ := rfl map_smul' _ _ := rfl /-- `QuaternionAlgebra.imI` as a `LinearMap` -/ @[simps] def imIₗ : ℍ[R,c₁,c₂,c₃] →ₗ[R] R where toFun := imI map_add' _ _ := rfl map_smul' _ _ := rfl /-- `QuaternionAlgebra.imJ` as a `LinearMap` -/ @[simps] def imJₗ : ℍ[R,c₁,c₂,c₃] →ₗ[R] R where toFun := imJ map_add' _ _ := rfl map_smul' _ _ := rfl /-- `QuaternionAlgebra.imK` as a `LinearMap` -/ @[simps] def imKₗ : ℍ[R,c₁,c₂,c₃] →ₗ[R] R where toFun := imK map_add' _ _ := rfl map_smul' _ _ := rfl /-- `QuaternionAlgebra.equivTuple` as a linear equivalence. -/ def linearEquivTuple : ℍ[R,c₁,c₂,c₃] ≃ₗ[R] Fin 4 → R := LinearEquiv.symm -- proofs are not `rfl` in the forward direction { (equivTuple c₁ c₂ c₃).symm with toFun := (equivTuple c₁ c₂ c₃).symm invFun := equivTuple c₁ c₂ c₃ map_add' := fun _ _ => rfl map_smul' := fun _ _ => rfl } @[simp] theorem coe_linearEquivTuple : ⇑(linearEquivTuple c₁ c₂ c₃) = equivTuple c₁ c₂ c₃ := rfl @[simp] theorem coe_linearEquivTuple_symm : ⇑(linearEquivTuple c₁ c₂ c₃).symm = (equivTuple c₁ c₂ c₃).symm := rfl /-- `ℍ[R, c₁, c₂, c₃]` has a basis over `R` given by `1`, `i`, `j`, and `k`. -/ noncomputable def basisOneIJK : Basis (Fin 4) R ℍ[R,c₁,c₂,c₃] := .ofEquivFun <\| linearEquivTuple c₁ c₂ c₃ @[simp] theorem coe_basisOneIJK_repr (q : ℍ[R,c₁,c₂,c₃]) : ((basisOneIJK c₁ c₂ c₃).repr q) = ![q.re, q.imI, q.imJ, q.imK] := rfl instance : Module.Finite R ℍ[R,c₁,c₂,c₃] := .of_basis (basisOneIJK c₁ c₂ c₃) instance : Module.Free R ℍ[R,c₁,c₂,c₃] := .of_basis (basisOneIJK c₁ c₂ c₃) theorem rank_eq_four [StrongRankCondition R] : Module.rank R ℍ[R,c₁,c₂,c₃] = 4 := by rw [rank_eq_card_basis (basisOneIJK c₁ c₂ c₃), Fintype.card_fin] norm_num theorem finrank_eq_four [StrongRankCondition R] : Module.finrank R ℍ[R,c₁,c₂,c₃] = 4 := by rw [Module.finrank, rank_eq_four, Cardinal.toNat_ofNat] /-- There is a natural equivalence when swapping the first and third coefficients of a quaternion algebra if `c₂` is 0. -/ @[simps] def swapEquiv : ℍ[R,c₁,0,c₃] ≃ₐ[R] ℍ[R,c₃,0,c₁] where toFun t := ⟨t.1, t.3, t.2, -t.4⟩ invFun t := ⟨t.1, t.3, t.2, -t.4⟩ left_inv _ := by simp right_inv _ := by simp map_mul' _ _ := by ext <;> simp <;> ring map_add' _ _ := by ext <;> simp [add_comm] commutes' _ := by simp [algebraMap_eq] end @[norm_cast, simp] theorem coe_sub : ((x - y : R) : ℍ[R,c₁,c₂,c₃]) = x - y := (algebraMap R ℍ[R,c₁,c₂,c₃]).map_sub x y @[norm_cast, simp] theorem coe_pow (n : ℕ) : (↑(x ^ n) : ℍ[R,c₁,c₂,c₃]) = (x : ℍ[R,c₁,c₂,c₃]) ^ n := (algebraMap R ℍ[R,c₁,c₂,c₃]).map_pow x n theorem coe_commutes : ↑r * a = a * r := Algebra.commutes r a theorem coe_commute : Commute (↑r) a := coe_commutes r a theorem coe_mul_eq_smul : ↑r * a = r • a := (Algebra.smul_def r a).symm theorem mul_coe_eq_smul : a * r = r • a := by rw [← coe_commutes, coe_mul_eq_smul] @[norm_cast, simp] theorem coe_algebraMap : ⇑(algebraMap R ℍ[R,c₁,c₂,c₃]) = coe := rfl theorem smul_coe : x • (y : ℍ[R,c₁,c₂,c₃]) = ↑(x * y) := by rw [coe_mul, coe_mul_eq_smul] /-- Quaternion conjugate. -/ instance instStarQuaternionAlgebra : Star ℍ[R,c₁,c₂,c₃] where star a := ⟨a.1 + c₂ * a.2, -a.2, -a.3, -a.4⟩ @[simp] theorem re_star : (star a).re = a.re + c₂ * a.imI := rfl @[simp] theorem imI_star : (star a).imI = -a.imI := rfl @[simp] theorem imJ_star : (star a).imJ = -a.imJ := rfl @[simp] theorem imK_star : (star a).imK = -a.imK := rfl @[simp] theorem im_star : (star a).im = -a.im := QuaternionAlgebra.ext neg_zero.symm rfl rfl rfl @[simp] theorem star_mk (a₁ a₂ a₃ a₄ : R) : star (mk a₁ a₂ a₃ a₄ : ℍ[R,c₁,c₂,c₃]) = ⟨a₁ + c₂ * a₂, -a₂, -a₃, -a₄⟩ := rfl instance instStarRing : StarRing ℍ[R,c₁,c₂,c₃] where star_involutive x := by simp [Star.star] star_add a b := by ext <;> simp [add_comm] ; ring star_mul a b := by ext <;> simp <;> ring theorem self_add_star' : a + star a = ↑(2 * a.re + c₂ * a.imI) := by ext <;> simp [two_mul]; ring theorem self_add_star : a + star a = 2 * a.re + c₂ * a.imI := by simp [self_add_star'] theorem star_add_self' : star a + a = ↑(2 * a.re + c₂ * a.imI) := by rw [add_comm, self_add_star'] theorem star_add_self : star a + a = 2 * a.re + c₂ * a.imI := by rw [add_comm, self_add_star] theorem star_eq_two_re_sub : star a = ↑(2 * a.re + c₂ * a.imI) - a := eq_sub_iff_add_eq.2 a.star_add_self' lemma comm (r : R) (x : ℍ[R, c₁, c₂, c₃]) : r * x = x * r := by ext <;> simp [mul_comm] instance : IsStarNormal a := ⟨by rw [commute_iff_eq, a.star_eq_two_re_sub]; ext <;> simp <;> ring⟩ @[simp, norm_cast] theorem star_coe : star (x : ℍ[R,c₁,c₂,c₃]) = x := by ext <;> simp @[simp] theorem star_im : star a.im = -a.im + c₂ * a.imI := by ext <;> simp @[simp] theorem star_smul [Monoid S] [DistribMulAction S R] [SMulCommClass S R R] (s : S) (a : ℍ[R,c₁,c₂,c₃]) : star (s • a) = s • star a := QuaternionAlgebra.ext (by simp [mul_smul_comm]) (smul_neg _ _).symm (smul_neg _ _).symm (smul_neg _ _).symm /-- A version of `star_smul` for the special case when `c₂ = 0`, without `SMulCommClass S R R`. -/ theorem star_smul' [Monoid S] [DistribMulAction S R] (s : S) (a : ℍ[R,c₁,0,c₃]) : star (s • a) = s • star a := QuaternionAlgebra.ext (by simp) (smul_neg _ _).symm (smul_neg _ _).symm (smul_neg _ _).symm theorem eq_re_of_eq_coe {a : ℍ[R,c₁,c₂,c₃]} {x : R} (h : a = x) : a = a.re := by rw [h, coe_re] theorem eq_re_iff_mem_range_coe {a : ℍ[R,c₁,c₂,c₃]} : a = a.re ↔ a ∈ Set.range (coe : R → ℍ[R,c₁,c₂,c₃]) := ⟨fun h => ⟨a.re, h.symm⟩, fun ⟨_, h⟩ => eq_re_of_eq_coe h.symm⟩ section CharZero variable [NoZeroDivisors R] [CharZero R] @[simp] theorem star_eq_self {c₁ c₂ : R} {a : ℍ[R,c₁,c₂,c₃]} : star a = a ↔ a = a.re := by simp_all [QuaternionAlgebra.ext_iff, neg_eq_iff_add_eq_zero, add_self_eq_zero] theorem star_eq_neg {c₁ : R} {a : ℍ[R,c₁,0,c₃]} : star a = -a ↔ a.re = 0 := by simp [QuaternionAlgebra.ext_iff, eq_neg_iff_add_eq_zero] end CharZero -- Can't use `rw ← star_eq_self` in the proof without additional assumptions theorem star_mul_eq_coe : star a * a = (star a * a).re := by ext <;> simp <;> ring theorem mul_star_eq_coe : a * star a = (a * star a).re := by rw [← star_comm_self'] exact a.star_mul_eq_coe open MulOpposite /-- Quaternion conjugate as an `AlgEquiv` to the opposite ring. -/ def starAe : ℍ[R,c₁,c₂,c₃] ≃ₐ[R] ℍ[R,c₁,c₂,c₃]ᵐᵒᵖ := { starAddEquiv.trans opAddEquiv with toFun := op ∘ star invFun := star ∘ unop map_mul' := fun x y => by simp commutes' := fun r => by simp } @[simp] theorem coe_starAe : ⇑(starAe : ℍ[R,c₁,c₂,c₃] ≃ₐ[R] _) = op ∘ star := rfl end QuaternionAlgebra /-- Space of quaternions over a type, denoted as `ℍ[R]`. Implemented as a structure with four fields: `re`, `im_i`, `im_j`, and `im_k`. -/ def Quaternion (R : Type) [Zero R] [One R] [Neg R] := QuaternionAlgebra R (-1) (0) (-1) @[inherit_doc] scoped[Quaternion] notation "ℍ[" R "]" => Quaternion R open Quaternion /-- The equivalence between the quaternions over `R` and `R × R × R × R`. -/ @[simps!] def Quaternion.equivProd (R : Type) [Zero R] [One R] [Neg R] : ℍ[R] ≃ R × R × R × R := QuaternionAlgebra.equivProd _ _ _ /-- The equivalence between the quaternions over `R` and `Fin 4 → R`. -/ @[simps! symm_apply] def Quaternion.equivTuple (R : Type) [Zero R] [One R] [Neg R] : ℍ[R] ≃ (Fin 4 → R) := QuaternionAlgebra.equivTuple _ _ _ @[simp] theorem Quaternion.equivTuple_apply (R : Type) [Zero R] [One R] [Neg R] (x : ℍ[R]) : Quaternion.equivTuple R x = ![x.re, x.imI, x.imJ, x.imK] := rfl instance {R : Type} [Zero R] [One R] [Neg R] [Subsingleton R] : Subsingleton ℍ[R] := inferInstanceAs (Subsingleton <\| ℍ[R, -1, 0, -1]) instance {R : Type} [Zero R] [One R] [Neg R] [Nontrivial R] : Nontrivial ℍ[R] := inferInstanceAs (Nontrivial <\| ℍ[R, -1, 0, -1]) namespace Quaternion variable {S T R : Type*} [CommRing R] (r x y : R) (a b : ℍ[R]) /-- Coercion `R → ℍ[R]`. -/ @[coe] def coe : R → ℍ[R] := QuaternionAlgebra.coe instance : CoeTC R ℍ[R] := ⟨coe⟩ instance instRing : Ring ℍ[R] := QuaternionAlgebra.instRing instance : Inhabited ℍ[R] := inferInstanceAs <\| Inhabited ℍ[R,-1, 0, -1]	instance [SMul S R] : SMul S ℍ[R] := inferInstanceAs <\| SMul S ℍ[R,-1, 0, -1]	Mathlib/Algebra/Quaternion.lean	770	772
/- Copyright (c) 2022 Joseph Myers. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Joseph Myers -/ import Mathlib.Algebra.ModEq import Mathlib.Algebra.Order.Archimedean.Basic import Mathlib.Algebra.Ring.Periodic import Mathlib.Data.Int.SuccPred import Mathlib.Order.Circular /-! # Reducing to an interval modulo its length This file defines operations that reduce a number (in an `Archimedean` `LinearOrderedAddCommGroup`) to a number in a given interval, modulo the length of that interval. ## Main definitions * `toIcoDiv hp a b` (where `hp : 0 < p`): The unique integer such that this multiple of `p`, subtracted from `b`, is in `Ico a (a + p)`. * `toIcoMod hp a b` (where `hp : 0 < p`): Reduce `b` to the interval `Ico a (a + p)`. * `toIocDiv hp a b` (where `hp : 0 < p`): The unique integer such that this multiple of `p`, subtracted from `b`, is in `Ioc a (a + p)`. * `toIocMod hp a b` (where `hp : 0 < p`): Reduce `b` to the interval `Ioc a (a + p)`. -/ assert_not_exists TwoSidedIdeal noncomputable section section LinearOrderedAddCommGroup variable {α : Type} [AddCommGroup α] [LinearOrder α] [IsOrderedAddMonoid α] [hα : Archimedean α] {p : α} (hp : 0 < p) {a b c : α} {n : ℤ} section include hp /-- The unique integer such that this multiple of `p`, subtracted from `b`, is in `Ico a (a + p)`. -/ def toIcoDiv (a b : α) : ℤ := (existsUnique_sub_zsmul_mem_Ico hp b a).choose theorem sub_toIcoDiv_zsmul_mem_Ico (a b : α) : b - toIcoDiv hp a b • p ∈ Set.Ico a (a + p) := (existsUnique_sub_zsmul_mem_Ico hp b a).choose_spec.1 theorem toIcoDiv_eq_of_sub_zsmul_mem_Ico (h : b - n • p ∈ Set.Ico a (a + p)) : toIcoDiv hp a b = n := ((existsUnique_sub_zsmul_mem_Ico hp b a).choose_spec.2 _ h).symm /-- The unique integer such that this multiple of `p`, subtracted from `b`, is in `Ioc a (a + p)`. -/ def toIocDiv (a b : α) : ℤ := (existsUnique_sub_zsmul_mem_Ioc hp b a).choose theorem sub_toIocDiv_zsmul_mem_Ioc (a b : α) : b - toIocDiv hp a b • p ∈ Set.Ioc a (a + p) := (existsUnique_sub_zsmul_mem_Ioc hp b a).choose_spec.1 theorem toIocDiv_eq_of_sub_zsmul_mem_Ioc (h : b - n • p ∈ Set.Ioc a (a + p)) : toIocDiv hp a b = n := ((existsUnique_sub_zsmul_mem_Ioc hp b a).choose_spec.2 _ h).symm /-- Reduce `b` to the interval `Ico a (a + p)`. -/ def toIcoMod (a b : α) : α := b - toIcoDiv hp a b • p /-- Reduce `b` to the interval `Ioc a (a + p)`. -/ def toIocMod (a b : α) : α := b - toIocDiv hp a b • p theorem toIcoMod_mem_Ico (a b : α) : toIcoMod hp a b ∈ Set.Ico a (a + p) := sub_toIcoDiv_zsmul_mem_Ico hp a b theorem toIcoMod_mem_Ico' (b : α) : toIcoMod hp 0 b ∈ Set.Ico 0 p := by convert toIcoMod_mem_Ico hp 0 b exact (zero_add p).symm theorem toIocMod_mem_Ioc (a b : α) : toIocMod hp a b ∈ Set.Ioc a (a + p) := sub_toIocDiv_zsmul_mem_Ioc hp a b theorem left_le_toIcoMod (a b : α) : a ≤ toIcoMod hp a b := (Set.mem_Ico.1 (toIcoMod_mem_Ico hp a b)).1 theorem left_lt_toIocMod (a b : α) : a < toIocMod hp a b := (Set.mem_Ioc.1 (toIocMod_mem_Ioc hp a b)).1 theorem toIcoMod_lt_right (a b : α) : toIcoMod hp a b < a + p := (Set.mem_Ico.1 (toIcoMod_mem_Ico hp a b)).2 theorem toIocMod_le_right (a b : α) : toIocMod hp a b ≤ a + p := (Set.mem_Ioc.1 (toIocMod_mem_Ioc hp a b)).2 @[simp] theorem self_sub_toIcoDiv_zsmul (a b : α) : b - toIcoDiv hp a b • p = toIcoMod hp a b := rfl @[simp] theorem self_sub_toIocDiv_zsmul (a b : α) : b - toIocDiv hp a b • p = toIocMod hp a b := rfl @[simp] theorem toIcoDiv_zsmul_sub_self (a b : α) : toIcoDiv hp a b • p - b = -toIcoMod hp a b := by rw [toIcoMod, neg_sub] @[simp] theorem toIocDiv_zsmul_sub_self (a b : α) : toIocDiv hp a b • p - b = -toIocMod hp a b := by rw [toIocMod, neg_sub] @[simp] theorem toIcoMod_sub_self (a b : α) : toIcoMod hp a b - b = -toIcoDiv hp a b • p := by rw [toIcoMod, sub_sub_cancel_left, neg_smul] @[simp] theorem toIocMod_sub_self (a b : α) : toIocMod hp a b - b = -toIocDiv hp a b • p := by rw [toIocMod, sub_sub_cancel_left, neg_smul] @[simp] theorem self_sub_toIcoMod (a b : α) : b - toIcoMod hp a b = toIcoDiv hp a b • p := by rw [toIcoMod, sub_sub_cancel] @[simp] theorem self_sub_toIocMod (a b : α) : b - toIocMod hp a b = toIocDiv hp a b • p := by rw [toIocMod, sub_sub_cancel] @[simp] theorem toIcoMod_add_toIcoDiv_zsmul (a b : α) : toIcoMod hp a b + toIcoDiv hp a b • p = b := by rw [toIcoMod, sub_add_cancel] @[simp] theorem toIocMod_add_toIocDiv_zsmul (a b : α) : toIocMod hp a b + toIocDiv hp a b • p = b := by rw [toIocMod, sub_add_cancel] @[simp] theorem toIcoDiv_zsmul_sub_toIcoMod (a b : α) : toIcoDiv hp a b • p + toIcoMod hp a b = b := by rw [add_comm, toIcoMod_add_toIcoDiv_zsmul] @[simp] theorem toIocDiv_zsmul_sub_toIocMod (a b : α) : toIocDiv hp a b • p + toIocMod hp a b = b := by rw [add_comm, toIocMod_add_toIocDiv_zsmul] theorem toIcoMod_eq_iff : toIcoMod hp a b = c ↔ c ∈ Set.Ico a (a + p) ∧ ∃ z : ℤ, b = c + z • p := by refine ⟨fun h => ⟨h ▸ toIcoMod_mem_Ico hp a b, toIcoDiv hp a b, h ▸ (toIcoMod_add_toIcoDiv_zsmul _ _ _).symm⟩, ?_⟩ simp_rw [← @sub_eq_iff_eq_add] rintro ⟨hc, n, rfl⟩ rw [← toIcoDiv_eq_of_sub_zsmul_mem_Ico hp hc, toIcoMod] theorem toIocMod_eq_iff : toIocMod hp a b = c ↔ c ∈ Set.Ioc a (a + p) ∧ ∃ z : ℤ, b = c + z • p := by refine ⟨fun h => ⟨h ▸ toIocMod_mem_Ioc hp a b, toIocDiv hp a b, h ▸ (toIocMod_add_toIocDiv_zsmul hp _ _).symm⟩, ?_⟩ simp_rw [← @sub_eq_iff_eq_add] rintro ⟨hc, n, rfl⟩ rw [← toIocDiv_eq_of_sub_zsmul_mem_Ioc hp hc, toIocMod] @[simp] theorem toIcoDiv_apply_left (a : α) : toIcoDiv hp a a = 0 := toIcoDiv_eq_of_sub_zsmul_mem_Ico hp <\| by simp [hp] @[simp] theorem toIocDiv_apply_left (a : α) : toIocDiv hp a a = -1 := toIocDiv_eq_of_sub_zsmul_mem_Ioc hp <\| by simp [hp] @[simp] theorem toIcoMod_apply_left (a : α) : toIcoMod hp a a = a := by rw [toIcoMod_eq_iff hp, Set.left_mem_Ico] exact ⟨lt_add_of_pos_right _ hp, 0, by simp⟩ @[simp] theorem toIocMod_apply_left (a : α) : toIocMod hp a a = a + p := by rw [toIocMod_eq_iff hp, Set.right_mem_Ioc] exact ⟨lt_add_of_pos_right _ hp, -1, by simp⟩ theorem toIcoDiv_apply_right (a : α) : toIcoDiv hp a (a + p) = 1 := toIcoDiv_eq_of_sub_zsmul_mem_Ico hp <\| by simp [hp] theorem toIocDiv_apply_right (a : α) : toIocDiv hp a (a + p) = 0 := toIocDiv_eq_of_sub_zsmul_mem_Ioc hp <\| by simp [hp] theorem toIcoMod_apply_right (a : α) : toIcoMod hp a (a + p) = a := by rw [toIcoMod_eq_iff hp, Set.left_mem_Ico] exact ⟨lt_add_of_pos_right _ hp, 1, by simp⟩ theorem toIocMod_apply_right (a : α) : toIocMod hp a (a + p) = a + p := by rw [toIocMod_eq_iff hp, Set.right_mem_Ioc] exact ⟨lt_add_of_pos_right _ hp, 0, by simp⟩ @[simp] theorem toIcoDiv_add_zsmul (a b : α) (m : ℤ) : toIcoDiv hp a (b + m • p) = toIcoDiv hp a b + m := toIcoDiv_eq_of_sub_zsmul_mem_Ico hp <\| by simpa only [add_smul, add_sub_add_right_eq_sub] using sub_toIcoDiv_zsmul_mem_Ico hp a b @[simp] theorem toIcoDiv_add_zsmul' (a b : α) (m : ℤ) : toIcoDiv hp (a + m • p) b = toIcoDiv hp a b - m := by refine toIcoDiv_eq_of_sub_zsmul_mem_Ico _ ?_ rw [sub_smul, ← sub_add, add_right_comm] simpa using sub_toIcoDiv_zsmul_mem_Ico hp a b @[simp] theorem toIocDiv_add_zsmul (a b : α) (m : ℤ) : toIocDiv hp a (b + m • p) = toIocDiv hp a b + m := toIocDiv_eq_of_sub_zsmul_mem_Ioc hp <\| by simpa only [add_smul, add_sub_add_right_eq_sub] using sub_toIocDiv_zsmul_mem_Ioc hp a b @[simp] theorem toIocDiv_add_zsmul' (a b : α) (m : ℤ) : toIocDiv hp (a + m • p) b = toIocDiv hp a b - m := by refine toIocDiv_eq_of_sub_zsmul_mem_Ioc _ ?_ rw [sub_smul, ← sub_add, add_right_comm] simpa using sub_toIocDiv_zsmul_mem_Ioc hp a b @[simp] theorem toIcoDiv_zsmul_add (a b : α) (m : ℤ) : toIcoDiv hp a (m • p + b) = m + toIcoDiv hp a b := by rw [add_comm, toIcoDiv_add_zsmul, add_comm] /-! Note we omit `toIcoDiv_zsmul_add'` as `-m + toIcoDiv hp a b` is not very convenient. -/ @[simp] theorem toIocDiv_zsmul_add (a b : α) (m : ℤ) : toIocDiv hp a (m • p + b) = m + toIocDiv hp a b := by rw [add_comm, toIocDiv_add_zsmul, add_comm] /-! Note we omit `toIocDiv_zsmul_add'` as `-m + toIocDiv hp a b` is not very convenient. -/ @[simp] theorem toIcoDiv_sub_zsmul (a b : α) (m : ℤ) : toIcoDiv hp a (b - m • p) = toIcoDiv hp a b - m := by rw [sub_eq_add_neg, ← neg_smul, toIcoDiv_add_zsmul, sub_eq_add_neg] @[simp] theorem toIcoDiv_sub_zsmul' (a b : α) (m : ℤ) : toIcoDiv hp (a - m • p) b = toIcoDiv hp a b + m := by rw [sub_eq_add_neg, ← neg_smul, toIcoDiv_add_zsmul', sub_neg_eq_add] @[simp] theorem toIocDiv_sub_zsmul (a b : α) (m : ℤ) : toIocDiv hp a (b - m • p) = toIocDiv hp a b - m := by rw [sub_eq_add_neg, ← neg_smul, toIocDiv_add_zsmul, sub_eq_add_neg] @[simp] theorem toIocDiv_sub_zsmul' (a b : α) (m : ℤ) : toIocDiv hp (a - m • p) b = toIocDiv hp a b + m := by rw [sub_eq_add_neg, ← neg_smul, toIocDiv_add_zsmul', sub_neg_eq_add] @[simp] theorem toIcoDiv_add_right (a b : α) : toIcoDiv hp a (b + p) = toIcoDiv hp a b + 1 := by simpa only [one_zsmul] using toIcoDiv_add_zsmul hp a b 1 @[simp] theorem toIcoDiv_add_right' (a b : α) : toIcoDiv hp (a + p) b = toIcoDiv hp a b - 1 := by simpa only [one_zsmul] using toIcoDiv_add_zsmul' hp a b 1 @[simp] theorem toIocDiv_add_right (a b : α) : toIocDiv hp a (b + p) = toIocDiv hp a b + 1 := by simpa only [one_zsmul] using toIocDiv_add_zsmul hp a b 1 @[simp] theorem toIocDiv_add_right' (a b : α) : toIocDiv hp (a + p) b = toIocDiv hp a b - 1 := by simpa only [one_zsmul] using toIocDiv_add_zsmul' hp a b 1 @[simp] theorem toIcoDiv_add_left (a b : α) : toIcoDiv hp a (p + b) = toIcoDiv hp a b + 1 := by rw [add_comm, toIcoDiv_add_right] @[simp] theorem toIcoDiv_add_left' (a b : α) : toIcoDiv hp (p + a) b = toIcoDiv hp a b - 1 := by rw [add_comm, toIcoDiv_add_right'] @[simp] theorem toIocDiv_add_left (a b : α) : toIocDiv hp a (p + b) = toIocDiv hp a b + 1 := by rw [add_comm, toIocDiv_add_right] @[simp] theorem toIocDiv_add_left' (a b : α) : toIocDiv hp (p + a) b = toIocDiv hp a b - 1 := by rw [add_comm, toIocDiv_add_right'] @[simp] theorem toIcoDiv_sub (a b : α) : toIcoDiv hp a (b - p) = toIcoDiv hp a b - 1 := by simpa only [one_zsmul] using toIcoDiv_sub_zsmul hp a b 1 @[simp] theorem toIcoDiv_sub' (a b : α) : toIcoDiv hp (a - p) b = toIcoDiv hp a b + 1 := by simpa only [one_zsmul] using toIcoDiv_sub_zsmul' hp a b 1 @[simp] theorem toIocDiv_sub (a b : α) : toIocDiv hp a (b - p) = toIocDiv hp a b - 1 := by simpa only [one_zsmul] using toIocDiv_sub_zsmul hp a b 1 @[simp] theorem toIocDiv_sub' (a b : α) : toIocDiv hp (a - p) b = toIocDiv hp a b + 1 := by simpa only [one_zsmul] using toIocDiv_sub_zsmul' hp a b 1 theorem toIcoDiv_sub_eq_toIcoDiv_add (a b c : α) : toIcoDiv hp a (b - c) = toIcoDiv hp (a + c) b := by apply toIcoDiv_eq_of_sub_zsmul_mem_Ico rw [← sub_right_comm, Set.sub_mem_Ico_iff_left, add_right_comm] exact sub_toIcoDiv_zsmul_mem_Ico hp (a + c) b theorem toIocDiv_sub_eq_toIocDiv_add (a b c : α) : toIocDiv hp a (b - c) = toIocDiv hp (a + c) b := by apply toIocDiv_eq_of_sub_zsmul_mem_Ioc rw [← sub_right_comm, Set.sub_mem_Ioc_iff_left, add_right_comm] exact sub_toIocDiv_zsmul_mem_Ioc hp (a + c) b theorem toIcoDiv_sub_eq_toIcoDiv_add' (a b c : α) : toIcoDiv hp (a - c) b = toIcoDiv hp a (b + c) := by rw [← sub_neg_eq_add, toIcoDiv_sub_eq_toIcoDiv_add, sub_eq_add_neg] theorem toIocDiv_sub_eq_toIocDiv_add' (a b c : α) : toIocDiv hp (a - c) b = toIocDiv hp a (b + c) := by rw [← sub_neg_eq_add, toIocDiv_sub_eq_toIocDiv_add, sub_eq_add_neg] theorem toIcoDiv_neg (a b : α) : toIcoDiv hp a (-b) = -(toIocDiv hp (-a) b + 1) := by suffices toIcoDiv hp a (-b) = -toIocDiv hp (-(a + p)) b by rwa [neg_add, ← sub_eq_add_neg, toIocDiv_sub_eq_toIocDiv_add', toIocDiv_add_right] at this rw [← neg_eq_iff_eq_neg, eq_comm] apply toIocDiv_eq_of_sub_zsmul_mem_Ioc obtain ⟨hc, ho⟩ := sub_toIcoDiv_zsmul_mem_Ico hp a (-b) rw [← neg_lt_neg_iff, neg_sub' (-b), neg_neg, ← neg_smul] at ho rw [← neg_le_neg_iff, neg_sub' (-b), neg_neg, ← neg_smul] at hc refine ⟨ho, hc.trans_eq ?_⟩ rw [neg_add, neg_add_cancel_right] theorem toIcoDiv_neg' (a b : α) : toIcoDiv hp (-a) b = -(toIocDiv hp a (-b) + 1) := by simpa only [neg_neg] using toIcoDiv_neg hp (-a) (-b) theorem toIocDiv_neg (a b : α) : toIocDiv hp a (-b) = -(toIcoDiv hp (-a) b + 1) := by rw [← neg_neg b, toIcoDiv_neg, neg_neg, neg_neg, neg_add', neg_neg, add_sub_cancel_right] theorem toIocDiv_neg' (a b : α) : toIocDiv hp (-a) b = -(toIcoDiv hp a (-b) + 1) := by simpa only [neg_neg] using toIocDiv_neg hp (-a) (-b) @[simp] theorem toIcoMod_add_zsmul (a b : α) (m : ℤ) : toIcoMod hp a (b + m • p) = toIcoMod hp a b := by rw [toIcoMod, toIcoDiv_add_zsmul, toIcoMod, add_smul] abel @[simp] theorem toIcoMod_add_zsmul' (a b : α) (m : ℤ) : toIcoMod hp (a + m • p) b = toIcoMod hp a b + m • p := by simp only [toIcoMod, toIcoDiv_add_zsmul', sub_smul, sub_add] @[simp] theorem toIocMod_add_zsmul (a b : α) (m : ℤ) : toIocMod hp a (b + m • p) = toIocMod hp a b := by rw [toIocMod, toIocDiv_add_zsmul, toIocMod, add_smul] abel @[simp] theorem toIocMod_add_zsmul' (a b : α) (m : ℤ) : toIocMod hp (a + m • p) b = toIocMod hp a b + m • p := by simp only [toIocMod, toIocDiv_add_zsmul', sub_smul, sub_add] @[simp] theorem toIcoMod_zsmul_add (a b : α) (m : ℤ) : toIcoMod hp a (m • p + b) = toIcoMod hp a b := by rw [add_comm, toIcoMod_add_zsmul] @[simp] theorem toIcoMod_zsmul_add' (a b : α) (m : ℤ) : toIcoMod hp (m • p + a) b = m • p + toIcoMod hp a b := by rw [add_comm, toIcoMod_add_zsmul', add_comm] @[simp] theorem toIocMod_zsmul_add (a b : α) (m : ℤ) : toIocMod hp a (m • p + b) = toIocMod hp a b := by rw [add_comm, toIocMod_add_zsmul] @[simp] theorem toIocMod_zsmul_add' (a b : α) (m : ℤ) : toIocMod hp (m • p + a) b = m • p + toIocMod hp a b := by rw [add_comm, toIocMod_add_zsmul', add_comm] @[simp] theorem toIcoMod_sub_zsmul (a b : α) (m : ℤ) : toIcoMod hp a (b - m • p) = toIcoMod hp a b := by rw [sub_eq_add_neg, ← neg_smul, toIcoMod_add_zsmul] @[simp] theorem toIcoMod_sub_zsmul' (a b : α) (m : ℤ) : toIcoMod hp (a - m • p) b = toIcoMod hp a b - m • p := by simp_rw [sub_eq_add_neg, ← neg_smul, toIcoMod_add_zsmul'] @[simp] theorem toIocMod_sub_zsmul (a b : α) (m : ℤ) : toIocMod hp a (b - m • p) = toIocMod hp a b := by rw [sub_eq_add_neg, ← neg_smul, toIocMod_add_zsmul] @[simp] theorem toIocMod_sub_zsmul' (a b : α) (m : ℤ) : toIocMod hp (a - m • p) b = toIocMod hp a b - m • p := by simp_rw [sub_eq_add_neg, ← neg_smul, toIocMod_add_zsmul'] @[simp] theorem toIcoMod_add_right (a b : α) : toIcoMod hp a (b + p) = toIcoMod hp a b := by simpa only [one_zsmul] using toIcoMod_add_zsmul hp a b 1 @[simp] theorem toIcoMod_add_right' (a b : α) : toIcoMod hp (a + p) b = toIcoMod hp a b + p := by simpa only [one_zsmul] using toIcoMod_add_zsmul' hp a b 1 @[simp] theorem toIocMod_add_right (a b : α) : toIocMod hp a (b + p) = toIocMod hp a b := by simpa only [one_zsmul] using toIocMod_add_zsmul hp a b 1 @[simp] theorem toIocMod_add_right' (a b : α) : toIocMod hp (a + p) b = toIocMod hp a b + p := by simpa only [one_zsmul] using toIocMod_add_zsmul' hp a b 1 @[simp] theorem toIcoMod_add_left (a b : α) : toIcoMod hp a (p + b) = toIcoMod hp a b := by rw [add_comm, toIcoMod_add_right] @[simp] theorem toIcoMod_add_left' (a b : α) : toIcoMod hp (p + a) b = p + toIcoMod hp a b := by rw [add_comm, toIcoMod_add_right', add_comm] @[simp] theorem toIocMod_add_left (a b : α) : toIocMod hp a (p + b) = toIocMod hp a b := by rw [add_comm, toIocMod_add_right] @[simp] theorem toIocMod_add_left' (a b : α) : toIocMod hp (p + a) b = p + toIocMod hp a b := by rw [add_comm, toIocMod_add_right', add_comm] @[simp] theorem toIcoMod_sub (a b : α) : toIcoMod hp a (b - p) = toIcoMod hp a b := by simpa only [one_zsmul] using toIcoMod_sub_zsmul hp a b 1 @[simp] theorem toIcoMod_sub' (a b : α) : toIcoMod hp (a - p) b = toIcoMod hp a b - p := by simpa only [one_zsmul] using toIcoMod_sub_zsmul' hp a b 1 @[simp] theorem toIocMod_sub (a b : α) : toIocMod hp a (b - p) = toIocMod hp a b := by simpa only [one_zsmul] using toIocMod_sub_zsmul hp a b 1 @[simp] theorem toIocMod_sub' (a b : α) : toIocMod hp (a - p) b = toIocMod hp a b - p := by simpa only [one_zsmul] using toIocMod_sub_zsmul' hp a b 1 theorem toIcoMod_sub_eq_sub (a b c : α) : toIcoMod hp a (b - c) = toIcoMod hp (a + c) b - c := by simp_rw [toIcoMod, toIcoDiv_sub_eq_toIcoDiv_add, sub_right_comm] theorem toIocMod_sub_eq_sub (a b c : α) : toIocMod hp a (b - c) = toIocMod hp (a + c) b - c := by simp_rw [toIocMod, toIocDiv_sub_eq_toIocDiv_add, sub_right_comm] theorem toIcoMod_add_right_eq_add (a b c : α) : toIcoMod hp a (b + c) = toIcoMod hp (a - c) b + c := by simp_rw [toIcoMod, toIcoDiv_sub_eq_toIcoDiv_add', sub_add_eq_add_sub] theorem toIocMod_add_right_eq_add (a b c : α) : toIocMod hp a (b + c) = toIocMod hp (a - c) b + c := by simp_rw [toIocMod, toIocDiv_sub_eq_toIocDiv_add', sub_add_eq_add_sub] theorem toIcoMod_neg (a b : α) : toIcoMod hp a (-b) = p - toIocMod hp (-a) b := by simp_rw [toIcoMod, toIocMod, toIcoDiv_neg, neg_smul, add_smul] abel theorem toIcoMod_neg' (a b : α) : toIcoMod hp (-a) b = p - toIocMod hp a (-b) := by simpa only [neg_neg] using toIcoMod_neg hp (-a) (-b) theorem toIocMod_neg (a b : α) : toIocMod hp a (-b) = p - toIcoMod hp (-a) b := by simp_rw [toIocMod, toIcoMod, toIocDiv_neg, neg_smul, add_smul] abel theorem toIocMod_neg' (a b : α) : toIocMod hp (-a) b = p - toIcoMod hp a (-b) := by simpa only [neg_neg] using toIocMod_neg hp (-a) (-b) theorem toIcoMod_eq_toIcoMod : toIcoMod hp a b = toIcoMod hp a c ↔ ∃ n : ℤ, c - b = n • p := by refine ⟨fun h => ⟨toIcoDiv hp a c - toIcoDiv hp a b, ?_⟩, fun h => ?_⟩ · conv_lhs => rw [← toIcoMod_add_toIcoDiv_zsmul hp a b, ← toIcoMod_add_toIcoDiv_zsmul hp a c] rw [h, sub_smul] abel · rcases h with ⟨z, hz⟩ rw [sub_eq_iff_eq_add] at hz rw [hz, toIcoMod_zsmul_add] theorem toIocMod_eq_toIocMod : toIocMod hp a b = toIocMod hp a c ↔ ∃ n : ℤ, c - b = n • p := by refine ⟨fun h => ⟨toIocDiv hp a c - toIocDiv hp a b, ?_⟩, fun h => ?_⟩ · conv_lhs => rw [← toIocMod_add_toIocDiv_zsmul hp a b, ← toIocMod_add_toIocDiv_zsmul hp a c] rw [h, sub_smul] abel · rcases h with ⟨z, hz⟩ rw [sub_eq_iff_eq_add] at hz rw [hz, toIocMod_zsmul_add] /-! ### Links between the `Ico` and `Ioc` variants applied to the same element -/ section IcoIoc namespace AddCommGroup theorem modEq_iff_toIcoMod_eq_left : a ≡ b [PMOD p] ↔ toIcoMod hp a b = a := modEq_iff_eq_add_zsmul.trans ⟨by rintro ⟨n, rfl⟩ rw [toIcoMod_add_zsmul, toIcoMod_apply_left], fun h => ⟨toIcoDiv hp a b, eq_add_of_sub_eq h⟩⟩ theorem modEq_iff_toIocMod_eq_right : a ≡ b [PMOD p] ↔ toIocMod hp a b = a + p := by refine modEq_iff_eq_add_zsmul.trans ⟨?_, fun h => ⟨toIocDiv hp a b + 1, ?_⟩⟩ · rintro ⟨z, rfl⟩ rw [toIocMod_add_zsmul, toIocMod_apply_left] · rwa [add_one_zsmul, add_left_comm, ← sub_eq_iff_eq_add'] alias ⟨ModEq.toIcoMod_eq_left, _⟩ := modEq_iff_toIcoMod_eq_left alias ⟨ModEq.toIcoMod_eq_right, _⟩ := modEq_iff_toIocMod_eq_right variable (a b) open List in theorem tfae_modEq : TFAE [a ≡ b [PMOD p], ∀ z : ℤ, b - z • p ∉ Set.Ioo a (a + p), toIcoMod hp a b ≠ toIocMod hp a b, toIcoMod hp a b + p = toIocMod hp a b] := by rw [modEq_iff_toIcoMod_eq_left hp] tfae_have 3 → 2 := by rw [← not_exists, not_imp_not] exact fun ⟨i, hi⟩ => ((toIcoMod_eq_iff hp).2 ⟨Set.Ioo_subset_Ico_self hi, i, (sub_add_cancel b _).symm⟩).trans ((toIocMod_eq_iff hp).2 ⟨Set.Ioo_subset_Ioc_self hi, i, (sub_add_cancel b _).symm⟩).symm tfae_have 4 → 3 \| h => by rw [← h, Ne, eq_comm, add_eq_left] exact hp.ne' tfae_have 1 → 4 \| h => by rw [h, eq_comm, toIocMod_eq_iff, Set.right_mem_Ioc] refine ⟨lt_add_of_pos_right a hp, toIcoDiv hp a b - 1, ?_⟩ rw [sub_one_zsmul, add_add_add_comm, add_neg_cancel, add_zero] conv_lhs => rw [← toIcoMod_add_toIcoDiv_zsmul hp a b, h] tfae_have 2 → 1 := by rw [← not_exists, not_imp_comm] have h' := toIcoMod_mem_Ico hp a b exact fun h => ⟨_, h'.1.lt_of_ne' h, h'.2⟩ tfae_finish variable {a b} theorem modEq_iff_not_forall_mem_Ioo_mod : a ≡ b [PMOD p] ↔ ∀ z : ℤ, b - z • p ∉ Set.Ioo a (a + p) := (tfae_modEq hp a b).out 0 1 theorem modEq_iff_toIcoMod_ne_toIocMod : a ≡ b [PMOD p] ↔ toIcoMod hp a b ≠ toIocMod hp a b := (tfae_modEq hp a b).out 0 2 theorem modEq_iff_toIcoMod_add_period_eq_toIocMod : a ≡ b [PMOD p] ↔ toIcoMod hp a b + p = toIocMod hp a b := (tfae_modEq hp a b).out 0 3 theorem not_modEq_iff_toIcoMod_eq_toIocMod : ¬a ≡ b [PMOD p] ↔ toIcoMod hp a b = toIocMod hp a b := (modEq_iff_toIcoMod_ne_toIocMod _).not_left theorem not_modEq_iff_toIcoDiv_eq_toIocDiv : ¬a ≡ b [PMOD p] ↔ toIcoDiv hp a b = toIocDiv hp a b := by rw [not_modEq_iff_toIcoMod_eq_toIocMod hp, toIcoMod, toIocMod, sub_right_inj, zsmul_left_inj hp] theorem modEq_iff_toIcoDiv_eq_toIocDiv_add_one : a ≡ b [PMOD p] ↔ toIcoDiv hp a b = toIocDiv hp a b + 1 := by rw [modEq_iff_toIcoMod_add_period_eq_toIocMod hp, toIcoMod, toIocMod, ← eq_sub_iff_add_eq, sub_sub, sub_right_inj, ← add_one_zsmul, zsmul_left_inj hp] end AddCommGroup open AddCommGroup /-- If `a` and `b` fall within the same cycle WRT `c`, then they are congruent modulo `p`. -/ @[simp] theorem toIcoMod_inj {c : α} : toIcoMod hp c a = toIcoMod hp c b ↔ a ≡ b [PMOD p] := by simp_rw [toIcoMod_eq_toIcoMod, modEq_iff_eq_add_zsmul, sub_eq_iff_eq_add'] alias ⟨_, AddCommGroup.ModEq.toIcoMod_eq_toIcoMod⟩ := toIcoMod_inj theorem Ico_eq_locus_Ioc_eq_iUnion_Ioo : { b \| toIcoMod hp a b = toIocMod hp a b } = ⋃ z : ℤ, Set.Ioo (a + z • p) (a + p + z • p) := by ext1 simp_rw [Set.mem_setOf, Set.mem_iUnion, ← Set.sub_mem_Ioo_iff_left, ← not_modEq_iff_toIcoMod_eq_toIocMod, modEq_iff_not_forall_mem_Ioo_mod hp, not_forall, Classical.not_not] theorem toIocDiv_wcovBy_toIcoDiv (a b : α) : toIocDiv hp a b ⩿ toIcoDiv hp a b := by suffices toIocDiv hp a b = toIcoDiv hp a b ∨ toIocDiv hp a b + 1 = toIcoDiv hp a b by rwa [wcovBy_iff_eq_or_covBy, ← Order.succ_eq_iff_covBy] rw [eq_comm, ← not_modEq_iff_toIcoDiv_eq_toIocDiv, eq_comm, ← modEq_iff_toIcoDiv_eq_toIocDiv_add_one] exact em' _ theorem toIcoMod_le_toIocMod (a b : α) : toIcoMod hp a b ≤ toIocMod hp a b := by rw [toIcoMod, toIocMod, sub_le_sub_iff_left] exact zsmul_left_mono hp.le (toIocDiv_wcovBy_toIcoDiv _ _ _).le theorem toIocMod_le_toIcoMod_add (a b : α) : toIocMod hp a b ≤ toIcoMod hp a b + p := by rw [toIcoMod, toIocMod, sub_add, sub_le_sub_iff_left, sub_le_iff_le_add, ← add_one_zsmul, (zsmul_left_strictMono hp).le_iff_le] apply (toIocDiv_wcovBy_toIcoDiv _ _ _).le_succ end IcoIoc open AddCommGroup theorem toIcoMod_eq_self : toIcoMod hp a b = b ↔ b ∈ Set.Ico a (a + p) := by rw [toIcoMod_eq_iff, and_iff_left] exact ⟨0, by simp⟩ theorem toIocMod_eq_self : toIocMod hp a b = b ↔ b ∈ Set.Ioc a (a + p) := by rw [toIocMod_eq_iff, and_iff_left] exact ⟨0, by simp⟩ @[simp] theorem toIcoMod_toIcoMod (a₁ a₂ b : α) : toIcoMod hp a₁ (toIcoMod hp a₂ b) = toIcoMod hp a₁ b := (toIcoMod_eq_toIcoMod _).2 ⟨toIcoDiv hp a₂ b, self_sub_toIcoMod hp a₂ b⟩ @[simp] theorem toIcoMod_toIocMod (a₁ a₂ b : α) : toIcoMod hp a₁ (toIocMod hp a₂ b) = toIcoMod hp a₁ b := (toIcoMod_eq_toIcoMod _).2 ⟨toIocDiv hp a₂ b, self_sub_toIocMod hp a₂ b⟩ @[simp] theorem toIocMod_toIocMod (a₁ a₂ b : α) : toIocMod hp a₁ (toIocMod hp a₂ b) = toIocMod hp a₁ b := (toIocMod_eq_toIocMod _).2 ⟨toIocDiv hp a₂ b, self_sub_toIocMod hp a₂ b⟩ @[simp] theorem toIocMod_toIcoMod (a₁ a₂ b : α) : toIocMod hp a₁ (toIcoMod hp a₂ b) = toIocMod hp a₁ b := (toIocMod_eq_toIocMod _).2 ⟨toIcoDiv hp a₂ b, self_sub_toIcoMod hp a₂ b⟩ theorem toIcoMod_periodic (a : α) : Function.Periodic (toIcoMod hp a) p := toIcoMod_add_right hp a theorem toIocMod_periodic (a : α) : Function.Periodic (toIocMod hp a) p := toIocMod_add_right hp a -- helper lemmas for when `a = 0` section Zero theorem toIcoMod_zero_sub_comm (a b : α) : toIcoMod hp 0 (a - b) = p - toIocMod hp 0 (b - a) := by rw [← neg_sub, toIcoMod_neg, neg_zero] theorem toIocMod_zero_sub_comm (a b : α) : toIocMod hp 0 (a - b) = p - toIcoMod hp 0 (b - a) := by rw [← neg_sub, toIocMod_neg, neg_zero] theorem toIcoDiv_eq_sub (a b : α) : toIcoDiv hp a b = toIcoDiv hp 0 (b - a) := by rw [toIcoDiv_sub_eq_toIcoDiv_add, zero_add] theorem toIocDiv_eq_sub (a b : α) : toIocDiv hp a b = toIocDiv hp 0 (b - a) := by rw [toIocDiv_sub_eq_toIocDiv_add, zero_add] theorem toIcoMod_eq_sub (a b : α) : toIcoMod hp a b = toIcoMod hp 0 (b - a) + a := by rw [toIcoMod_sub_eq_sub, zero_add, sub_add_cancel] theorem toIocMod_eq_sub (a b : α) : toIocMod hp a b = toIocMod hp 0 (b - a) + a := by rw [toIocMod_sub_eq_sub, zero_add, sub_add_cancel] theorem toIcoMod_add_toIocMod_zero (a b : α) : toIcoMod hp 0 (a - b) + toIocMod hp 0 (b - a) = p := by rw [toIcoMod_zero_sub_comm, sub_add_cancel] theorem toIocMod_add_toIcoMod_zero (a b : α) : toIocMod hp 0 (a - b) + toIcoMod hp 0 (b - a) = p := by rw [_root_.add_comm, toIcoMod_add_toIocMod_zero] end Zero /-- `toIcoMod` as an equiv from the quotient. -/ @[simps symm_apply] def QuotientAddGroup.equivIcoMod (a : α) : α ⧸ AddSubgroup.zmultiples p ≃ Set.Ico a (a + p) where toFun b := ⟨(toIcoMod_periodic hp a).lift b, QuotientAddGroup.induction_on b <\| toIcoMod_mem_Ico hp a⟩ invFun := (↑) right_inv b := Subtype.ext <\| (toIcoMod_eq_self hp).mpr b.prop left_inv b := by induction b using QuotientAddGroup.induction_on dsimp rw [QuotientAddGroup.eq_iff_sub_mem, toIcoMod_sub_self] apply AddSubgroup.zsmul_mem_zmultiples @[simp] theorem QuotientAddGroup.equivIcoMod_coe (a b : α) : QuotientAddGroup.equivIcoMod hp a ↑b = ⟨toIcoMod hp a b, toIcoMod_mem_Ico hp a _⟩ := rfl @[simp] theorem QuotientAddGroup.equivIcoMod_zero (a : α) : QuotientAddGroup.equivIcoMod hp a 0 = ⟨toIcoMod hp a 0, toIcoMod_mem_Ico hp a _⟩ := rfl /-- `toIocMod` as an equiv from the quotient. -/ @[simps symm_apply] def QuotientAddGroup.equivIocMod (a : α) : α ⧸ AddSubgroup.zmultiples p ≃ Set.Ioc a (a + p) where toFun b := ⟨(toIocMod_periodic hp a).lift b, QuotientAddGroup.induction_on b <\| toIocMod_mem_Ioc hp a⟩ invFun := (↑) right_inv b := Subtype.ext <\| (toIocMod_eq_self hp).mpr b.prop left_inv b := by induction b using QuotientAddGroup.induction_on dsimp rw [QuotientAddGroup.eq_iff_sub_mem, toIocMod_sub_self] apply AddSubgroup.zsmul_mem_zmultiples @[simp] theorem QuotientAddGroup.equivIocMod_coe (a b : α) : QuotientAddGroup.equivIocMod hp a ↑b = ⟨toIocMod hp a b, toIocMod_mem_Ioc hp a _⟩ := rfl @[simp] theorem QuotientAddGroup.equivIocMod_zero (a : α) : QuotientAddGroup.equivIocMod hp a 0 = ⟨toIocMod hp a 0, toIocMod_mem_Ioc hp a _⟩ := rfl end /-! ### The circular order structure on `α ⧸ AddSubgroup.zmultiples p` -/ section Circular open AddCommGroup private theorem toIxxMod_iff (x₁ x₂ x₃ : α) : toIcoMod hp x₁ x₂ ≤ toIocMod hp x₁ x₃ ↔ toIcoMod hp 0 (x₂ - x₁) + toIcoMod hp 0 (x₁ - x₃) ≤ p := by rw [toIcoMod_eq_sub, toIocMod_eq_sub _ x₁, add_le_add_iff_right, ← neg_sub x₁ x₃, toIocMod_neg, neg_zero, le_sub_iff_add_le] private theorem toIxxMod_cyclic_left {x₁ x₂ x₃ : α} (h : toIcoMod hp x₁ x₂ ≤ toIocMod hp x₁ x₃) : toIcoMod hp x₂ x₃ ≤ toIocMod hp x₂ x₁ := by let x₂' := toIcoMod hp x₁ x₂ let x₃' := toIcoMod hp x₂' x₃ have h : x₂' ≤ toIocMod hp x₁ x₃' := by simpa [x₃'] have h₂₁ : x₂' < x₁ + p := toIcoMod_lt_right _ _ _ have h₃₂ : x₃' - p < x₂' := sub_lt_iff_lt_add.2 (toIcoMod_lt_right _ _ _) suffices hequiv : x₃' ≤ toIocMod hp x₂' x₁ by obtain ⟨z, hd⟩ : ∃ z : ℤ, x₂ = x₂' + z • p := ((toIcoMod_eq_iff hp).1 rfl).2 simpa [hd, toIocMod_add_zsmul', toIcoMod_add_zsmul', add_le_add_iff_right] rcases le_or_lt x₃' (x₁ + p) with h₃₁ \| h₁₃ · suffices hIoc₂₁ : toIocMod hp x₂' x₁ = x₁ + p from hIoc₂₁.symm.trans_ge h₃₁ apply (toIocMod_eq_iff hp).2 exact ⟨⟨h₂₁, by simp [x₂', left_le_toIcoMod]⟩, -1, by simp⟩ have hIoc₁₃ : toIocMod hp x₁ x₃' = x₃' - p := by apply (toIocMod_eq_iff hp).2 exact ⟨⟨lt_sub_iff_add_lt.2 h₁₃, le_of_lt (h₃₂.trans h₂₁)⟩, 1, by simp⟩ have not_h₃₂ := (h.trans hIoc₁₃.le).not_lt contradiction private theorem toIxxMod_antisymm (h₁₂₃ : toIcoMod hp a b ≤ toIocMod hp a c) (h₁₃₂ : toIcoMod hp a c ≤ toIocMod hp a b) : b ≡ a [PMOD p] ∨ c ≡ b [PMOD p] ∨ a ≡ c [PMOD p] := by by_contra! h rw [modEq_comm] at h rw [← (not_modEq_iff_toIcoMod_eq_toIocMod hp).mp h.2.2] at h₁₂₃ rw [← (not_modEq_iff_toIcoMod_eq_toIocMod hp).mp h.1] at h₁₃₂ exact h.2.1 ((toIcoMod_inj _).1 <\| h₁₃₂.antisymm h₁₂₃) private theorem toIxxMod_total' (a b c : α) : toIcoMod hp b a ≤ toIocMod hp b c ∨ toIcoMod hp b c ≤ toIocMod hp b a := by /- an essential ingredient is the lemma saying {a-b} + {b-a} = period if a ≠ b (and = 0 if a = b). Thus if a ≠ b and b ≠ c then ({a-b} + {b-c}) + ({c-b} + {b-a}) = 2 period, so one of `{a-b} + {b-c}` and `{c-b} + {b-a}` must be `≤ period` -/ have := congr_arg₂ (· + ·) (toIcoMod_add_toIocMod_zero hp a b) (toIcoMod_add_toIocMod_zero hp c b) simp only [add_add_add_comm] at this rw [_root_.add_comm (toIocMod _ _ _), add_add_add_comm, ← two_nsmul] at this replace := min_le_of_add_le_two_nsmul this.le rw [min_le_iff] at this rw [toIxxMod_iff, toIxxMod_iff] refine this.imp (le_trans <\| add_le_add_left ?_ _) (le_trans <\| add_le_add_left ?_ _) · apply toIcoMod_le_toIocMod · apply toIcoMod_le_toIocMod private theorem toIxxMod_total (a b c : α) : toIcoMod hp a b ≤ toIocMod hp a c ∨ toIcoMod hp c b ≤ toIocMod hp c a := (toIxxMod_total' _ _ _ _).imp_right <\| toIxxMod_cyclic_left _ private theorem toIxxMod_trans {x₁ x₂ x₃ x₄ : α} (h₁₂₃ : toIcoMod hp x₁ x₂ ≤ toIocMod hp x₁ x₃ ∧ ¬toIcoMod hp x₃ x₂ ≤ toIocMod hp x₃ x₁) (h₂₃₄ : toIcoMod hp x₂ x₄ ≤ toIocMod hp x₂ x₃ ∧ ¬toIcoMod hp x₃ x₄ ≤ toIocMod hp x₃ x₂) : toIcoMod hp x₁ x₄ ≤ toIocMod hp x₁ x₃ ∧ ¬toIcoMod hp x₃ x₄ ≤ toIocMod hp x₃ x₁ := by constructor · suffices h : ¬x₃ ≡ x₂ [PMOD p] by have h₁₂₃' := toIxxMod_cyclic_left _ (toIxxMod_cyclic_left _ h₁₂₃.1) have h₂₃₄' := toIxxMod_cyclic_left _ (toIxxMod_cyclic_left _ h₂₃₄.1) rw [(not_modEq_iff_toIcoMod_eq_toIocMod hp).1 h] at h₂₃₄' exact toIxxMod_cyclic_left _ (h₁₂₃'.trans h₂₃₄') by_contra h rw [(modEq_iff_toIcoMod_eq_left hp).1 h] at h₁₂₃ exact h₁₂₃.2 (left_lt_toIocMod _ _ _).le · rw [not_le] at h₁₂₃ h₂₃₄ ⊢ exact (h₁₂₃.2.trans_le (toIcoMod_le_toIocMod _ x₃ x₂)).trans h₂₃₄.2 namespace QuotientAddGroup variable [hp' : Fact (0 < p)] instance : Btw (α ⧸ AddSubgroup.zmultiples p) where btw x₁ x₂ x₃ := (equivIcoMod hp'.out 0 (x₂ - x₁) : α) ≤ equivIocMod hp'.out 0 (x₃ - x₁) theorem btw_coe_iff' {x₁ x₂ x₃ : α} : Btw.btw (x₁ : α ⧸ AddSubgroup.zmultiples p) x₂ x₃ ↔ toIcoMod hp'.out 0 (x₂ - x₁) ≤ toIocMod hp'.out 0 (x₃ - x₁) := Iff.rfl -- maybe harder to use than the primed one? theorem btw_coe_iff {x₁ x₂ x₃ : α} : Btw.btw (x₁ : α ⧸ AddSubgroup.zmultiples p) x₂ x₃ ↔ toIcoMod hp'.out x₁ x₂ ≤ toIocMod hp'.out x₁ x₃ := by rw [btw_coe_iff', toIocMod_sub_eq_sub, toIcoMod_sub_eq_sub, zero_add, sub_le_sub_iff_right] instance circularPreorder : CircularPreorder (α ⧸ AddSubgroup.zmultiples p) where btw_refl x := show _ ≤ _ by simp [sub_self, hp'.out.le] btw_cyclic_left {x₁ x₂ x₃} h := by induction x₁ using QuotientAddGroup.induction_on induction x₂ using QuotientAddGroup.induction_on induction x₃ using QuotientAddGroup.induction_on simp_rw [btw_coe_iff] at h ⊢ apply toIxxMod_cyclic_left _ h sbtw := _ sbtw_iff_btw_not_btw := Iff.rfl sbtw_trans_left {x₁ x₂ x₃ x₄} (h₁₂₃ : _ ∧ _) (h₂₃₄ : _ ∧ _) := show _ ∧ _ by induction x₁ using QuotientAddGroup.induction_on induction x₂ using QuotientAddGroup.induction_on induction x₃ using QuotientAddGroup.induction_on induction x₄ using QuotientAddGroup.induction_on simp_rw [btw_coe_iff] at h₁₂₃ h₂₃₄ ⊢ apply toIxxMod_trans _ h₁₂₃ h₂₃₄ instance circularOrder : CircularOrder (α ⧸ AddSubgroup.zmultiples p) := { QuotientAddGroup.circularPreorder with btw_antisymm := fun {x₁ x₂ x₃} h₁₂₃ h₃₂₁ => by induction x₁ using QuotientAddGroup.induction_on induction x₂ using QuotientAddGroup.induction_on induction x₃ using QuotientAddGroup.induction_on rw [btw_cyclic] at h₃₂₁ simp_rw [btw_coe_iff] at h₁₂₃ h₃₂₁ simp_rw [← modEq_iff_eq_mod_zmultiples] exact toIxxMod_antisymm _ h₁₂₃ h₃₂₁ btw_total := fun x₁ x₂ x₃ => by induction x₁ using QuotientAddGroup.induction_on induction x₂ using QuotientAddGroup.induction_on induction x₃ using QuotientAddGroup.induction_on simp_rw [btw_coe_iff] apply toIxxMod_total } end QuotientAddGroup end Circular end LinearOrderedAddCommGroup /-! ### Connections to `Int.floor` and `Int.fract` -/ section LinearOrderedField variable {α : Type} [Field α] [LinearOrder α] [IsStrictOrderedRing α] [FloorRing α] {p : α} (hp : 0 < p) theorem toIcoDiv_eq_floor (a b : α) : toIcoDiv hp a b = ⌊(b - a) / p⌋ := by refine toIcoDiv_eq_of_sub_zsmul_mem_Ico hp ?_ rw [Set.mem_Ico, zsmul_eq_mul, ← sub_nonneg, add_comm, sub_right_comm, ← sub_lt_iff_lt_add, sub_right_comm _ _ a] exact ⟨Int.sub_floor_div_mul_nonneg _ hp, Int.sub_floor_div_mul_lt _ hp⟩ theorem toIocDiv_eq_neg_floor (a b : α) : toIocDiv hp a b = -⌊(a + p - b) / p⌋ := by refine toIocDiv_eq_of_sub_zsmul_mem_Ioc hp ?_ rw [Set.mem_Ioc, zsmul_eq_mul, Int.cast_neg, neg_mul, sub_neg_eq_add, ← sub_nonneg, sub_add_eq_sub_sub] refine ⟨?_, Int.sub_floor_div_mul_nonneg _ hp⟩ rw [← add_lt_add_iff_right p, add_assoc, add_comm b, ← sub_lt_iff_lt_add, add_comm (_ _), ← sub_lt_iff_lt_add] exact Int.sub_floor_div_mul_lt _ hp theorem toIcoDiv_zero_one (b : α) : toIcoDiv (zero_lt_one' α) 0 b = ⌊b⌋ := by simp [toIcoDiv_eq_floor] theorem toIcoMod_eq_add_fract_mul (a b : α) : toIcoMod hp a b = a + Int.fract ((b - a) / p) * p := by rw [toIcoMod, toIcoDiv_eq_floor, Int.fract] field_simp ring theorem toIcoMod_eq_fract_mul (b : α) : toIcoMod hp 0 b = Int.fract (b / p) * p := by simp [toIcoMod_eq_add_fract_mul] theorem toIocMod_eq_sub_fract_mul (a b : α) : toIocMod hp a b = a + p - Int.fract ((a + p - b) / p) * p := by rw [toIocMod, toIocDiv_eq_neg_floor, Int.fract] field_simp ring theorem toIcoMod_zero_one (b : α) : toIcoMod (zero_lt_one' α) 0 b = Int.fract b := by simp [toIcoMod_eq_add_fract_mul] end LinearOrderedField /-! ### Lemmas about unions of translates of intervals -/ section Union open Set Int section LinearOrderedAddCommGroup variable {α : Type} [AddCommGroup α] [LinearOrder α] [IsOrderedAddMonoid α] [Archimedean α] {p : α} (hp : 0 < p) (a : α) include hp theorem iUnion_Ioc_add_zsmul : ⋃ n : ℤ, Ioc (a + n • p) (a + (n + 1) • p) = univ := by refine eq_univ_iff_forall.mpr fun b => mem_iUnion.mpr ?_ rcases sub_toIocDiv_zsmul_mem_Ioc hp a b with ⟨hl, hr⟩ refine ⟨toIocDiv hp a b, ⟨lt_sub_iff_add_lt.mp hl, ?_⟩⟩ rw [add_smul, one_smul, ← add_assoc] convert sub_le_iff_le_add.mp hr using 1; abel theorem iUnion_Ico_add_zsmul : ⋃ n : ℤ, Ico (a + n • p) (a + (n + 1) • p) = univ := by refine eq_univ_iff_forall.mpr fun b => mem_iUnion.mpr ?_ rcases sub_toIcoDiv_zsmul_mem_Ico hp a b with ⟨hl, hr⟩ refine ⟨toIcoDiv hp a b, ⟨le_sub_iff_add_le.mp hl, ?_⟩⟩ rw [add_smul, one_smul, ← add_assoc] convert sub_lt_iff_lt_add.mp hr using 1; abel theorem iUnion_Icc_add_zsmul : ⋃ n : ℤ, Icc (a + n • p) (a + (n + 1) • p) = univ := by simpa only [iUnion_Ioc_add_zsmul hp a, univ_subset_iff] using iUnion_mono fun n : ℤ => (Ioc_subset_Icc_self : Ioc (a + n • p) (a + (n + 1) • p) ⊆ Icc _ _) theorem iUnion_Ioc_zsmul : ⋃ n : ℤ, Ioc (n • p) ((n + 1) • p) = univ := by simpa only [zero_add] using iUnion_Ioc_add_zsmul hp 0 theorem iUnion_Ico_zsmul : ⋃ n : ℤ, Ico (n • p) ((n + 1) • p) = univ := by simpa only [zero_add] using iUnion_Ico_add_zsmul hp 0 theorem iUnion_Icc_zsmul : ⋃ n : ℤ, Icc (n • p) ((n + 1) • p) = univ := by simpa only [zero_add] using iUnion_Icc_add_zsmul hp 0 end LinearOrderedAddCommGroup section LinearOrderedRing variable {α : Type} [Ring α] [LinearOrder α] [IsStrictOrderedRing α] [Archimedean α] (a : α) theorem iUnion_Ioc_add_intCast : ⋃ n : ℤ, Ioc (a + n) (a + n + 1) = Set.univ := by simpa only [zsmul_one, Int.cast_add, Int.cast_one, ← add_assoc] using iUnion_Ioc_add_zsmul zero_lt_one a theorem iUnion_Ico_add_intCast : ⋃ n : ℤ, Ico (a + n) (a + n + 1) = Set.univ := by simpa only [zsmul_one, Int.cast_add, Int.cast_one, ← add_assoc] using iUnion_Ico_add_zsmul zero_lt_one a theorem iUnion_Icc_add_intCast : ⋃ n : ℤ, Icc (a + n) (a + n + 1) = Set.univ := by simpa only [zsmul_one, Int.cast_add, Int.cast_one, ← add_assoc] using iUnion_Icc_add_zsmul zero_lt_one a variable (α) theorem iUnion_Ioc_intCast : ⋃ n : ℤ, Ioc (n : α) (n + 1) = Set.univ := by simpa only [zero_add] using iUnion_Ioc_add_intCast (0 : α) theorem iUnion_Ico_intCast : ⋃ n : ℤ, Ico (n : α) (n + 1) = Set.univ := by simpa only [zero_add] using iUnion_Ico_add_intCast (0 : α) theorem iUnion_Icc_intCast : ⋃ n : ℤ, Icc (n : α) (n + 1) = Set.univ := by simpa only [zero_add] using iUnion_Icc_add_intCast (0 : α) end LinearOrderedRing end Union		Mathlib/Algebra/Order/ToIntervalMod.lean	1,023	1,027
/- Copyright (c) 2020 David Wärn. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: David Wärn -/ import Mathlib.CategoryTheory.NatIso import Mathlib.CategoryTheory.EqToHom /-! # Quotient category Constructs the quotient of a category by an arbitrary family of relations on its hom-sets, by introducing a type synonym for the objects, and identifying homs as necessary. This is analogous to 'the quotient of a group by the normal closure of a subset', rather than 'the quotient of a group by a normal subgroup'. When taking the quotient by a congruence relation, `functor_map_eq_iff` says that no unnecessary identifications have been made. -/ /-- A `HomRel` on `C` consists of a relation on every hom-set. -/ def HomRel (C) [Quiver C] := ∀ ⦃X Y : C⦄, (X ⟶ Y) → (X ⟶ Y) → Prop -- The `Inhabited` instance should be constructed by a deriving handler. -- https://github.com/leanprover-community/mathlib4/issues/380 instance (C) [Quiver C] : Inhabited (HomRel C) where default := fun _ _ _ _ ↦ PUnit namespace CategoryTheory section variable {C D : Type} [Category C] [Category D] (F : C ⥤ D) /-- A functor induces a `HomRel` on its domain, relating those maps that have the same image. -/ def Functor.homRel : HomRel C := fun _ _ f g ↦ F.map f = F.map g @[simp] lemma Functor.homRel_iff {X Y : C} (f g : X ⟶ Y) : F.homRel f g ↔ F.map f = F.map g := Iff.rfl end variable {C : Type _} [Category C] (r : HomRel C) /-- A `HomRel` is a congruence when it's an equivalence on every hom-set, and it can be composed from left and right. -/ class Congruence : Prop where /-- `r` is an equivalence on every hom-set. -/ equivalence : ∀ {X Y}, _root_.Equivalence (@r X Y) /-- Precomposition with an arrow respects `r`. -/ compLeft : ∀ {X Y Z} (f : X ⟶ Y) {g g' : Y ⟶ Z}, r g g' → r (f ≫ g) (f ≫ g') /-- Postcomposition with an arrow respects `r`. -/ compRight : ∀ {X Y Z} {f f' : X ⟶ Y} (g : Y ⟶ Z), r f f' → r (f ≫ g) (f' ≫ g) /-- For `F : C ⥤ D`, `F.homRel` is a congruence. -/ instance Functor.congruence_homRel {C D : Type} [Category C] [Category D] (F : C ⥤ D) : Congruence F.homRel where equivalence := { refl := fun _ ↦ rfl symm := by aesop trans := by aesop } compLeft := by aesop compRight := by aesop /-- A type synonym for `C`, thought of as the objects of the quotient category. -/	@[ext] structure Quotient (r : HomRel C) where /-- The object of `C`. -/	Mathlib/CategoryTheory/Quotient.lean	69	71
/- Copyright (c) 2020 Yury Kudryashov. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yury Kudryashov -/ import Mathlib.Analysis.InnerProductSpace.PiL2 import Mathlib.Analysis.SpecialFunctions.Sqrt import Mathlib.Analysis.NormedSpace.HomeomorphBall import Mathlib.Analysis.Calculus.ContDiff.WithLp import Mathlib.Analysis.Calculus.FDeriv.WithLp /-! # Calculus in inner product spaces In this file we prove that the inner product and square of the norm in an inner space are infinitely `ℝ`-smooth. In order to state these results, we need a `NormedSpace ℝ E` instance. Though we can deduce this structure from `InnerProductSpace 𝕜 E`, this instance may be not definitionally equal to some other “natural” instance. So, we assume `[NormedSpace ℝ E]`. We also prove that functions to a `EuclideanSpace` are (higher) differentiable if and only if their components are. This follows from the corresponding fact for finite product of normed spaces, and from the equivalence of norms in finite dimensions. ## TODO The last part of the file should be generalized to `PiLp`. -/ noncomputable section open RCLike Real Filter section DerivInner variable {𝕜 E F : Type} [RCLike 𝕜] variable [NormedAddCommGroup E] [InnerProductSpace 𝕜 E] variable [NormedAddCommGroup F] [InnerProductSpace ℝ F] local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y variable (𝕜) [NormedSpace ℝ E] /-- Derivative of the inner product. -/ def fderivInnerCLM (p : E × E) : E × E →L[ℝ] 𝕜 := isBoundedBilinearMap_inner.deriv p @[simp] theorem fderivInnerCLM_apply (p x : E × E) : fderivInnerCLM 𝕜 p x = ⟪p.1, x.2⟫ + ⟪x.1, p.2⟫ := rfl variable {𝕜} theorem contDiff_inner {n} : ContDiff ℝ n fun p : E × E => ⟪p.1, p.2⟫ := isBoundedBilinearMap_inner.contDiff theorem contDiffAt_inner {p : E × E} {n} : ContDiffAt ℝ n (fun p : E × E => ⟪p.1, p.2⟫) p := ContDiff.contDiffAt contDiff_inner theorem differentiable_inner : Differentiable ℝ fun p : E × E => ⟪p.1, p.2⟫ := isBoundedBilinearMap_inner.differentiableAt variable (𝕜) variable {G : Type} [NormedAddCommGroup G] [NormedSpace ℝ G] {f g : G → E} {f' g' : G →L[ℝ] E} {s : Set G} {x : G} {n : WithTop ℕ∞} theorem ContDiffWithinAt.inner (hf : ContDiffWithinAt ℝ n f s x) (hg : ContDiffWithinAt ℝ n g s x) : ContDiffWithinAt ℝ n (fun x => ⟪f x, g x⟫) s x := contDiffAt_inner.comp_contDiffWithinAt x (hf.prodMk hg) nonrec theorem ContDiffAt.inner (hf : ContDiffAt ℝ n f x) (hg : ContDiffAt ℝ n g x) : ContDiffAt ℝ n (fun x => ⟪f x, g x⟫) x := hf.inner 𝕜 hg theorem ContDiffOn.inner (hf : ContDiffOn ℝ n f s) (hg : ContDiffOn ℝ n g s) : ContDiffOn ℝ n (fun x => ⟪f x, g x⟫) s := fun x hx => (hf x hx).inner 𝕜 (hg x hx) theorem ContDiff.inner (hf : ContDiff ℝ n f) (hg : ContDiff ℝ n g) : ContDiff ℝ n fun x => ⟪f x, g x⟫ := contDiff_inner.comp (hf.prodMk hg) #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 added `by exact` to handle a unification issue. -/ theorem HasFDerivWithinAt.inner (hf : HasFDerivWithinAt f f' s x) (hg : HasFDerivWithinAt g g' s x) : HasFDerivWithinAt (fun t => ⟪f t, g t⟫) ((fderivInnerCLM 𝕜 (f x, g x)).comp <\| f'.prod g') s x := by exact isBoundedBilinearMap_inner (𝕜 := 𝕜) (E := E) \|>.hasFDerivAt (f x, g x) \|>.comp_hasFDerivWithinAt x (hf.prodMk hg) theorem HasStrictFDerivAt.inner (hf : HasStrictFDerivAt f f' x) (hg : HasStrictFDerivAt g g' x) : HasStrictFDerivAt (fun t => ⟪f t, g t⟫) ((fderivInnerCLM 𝕜 (f x, g x)).comp <\| f'.prod g') x := isBoundedBilinearMap_inner (𝕜 := 𝕜) (E := E) \|>.hasStrictFDerivAt (f x, g x) \|>.comp x (hf.prodMk hg) #adaptation_note /-- https://github.com/leanprover/lean4/pull/6024 added `by exact` to handle a unification issue. -/ theorem HasFDerivAt.inner (hf : HasFDerivAt f f' x) (hg : HasFDerivAt g g' x) : HasFDerivAt (fun t => ⟪f t, g t⟫) ((fderivInnerCLM 𝕜 (f x, g x)).comp <\| f'.prod g') x := by exact isBoundedBilinearMap_inner (𝕜 := 𝕜) (E := E) \|>.hasFDerivAt (f x, g x) \|>.comp x (hf.prodMk hg) theorem HasDerivWithinAt.inner {f g : ℝ → E} {f' g' : E} {s : Set ℝ} {x : ℝ} (hf : HasDerivWithinAt f f' s x) (hg : HasDerivWithinAt g g' s x) : HasDerivWithinAt (fun t => ⟪f t, g t⟫) (⟪f x, g'⟫ + ⟪f', g x⟫) s x := by simpa using (hf.hasFDerivWithinAt.inner 𝕜 hg.hasFDerivWithinAt).hasDerivWithinAt theorem HasDerivAt.inner {f g : ℝ → E} {f' g' : E} {x : ℝ} : HasDerivAt f f' x → HasDerivAt g g' x → HasDerivAt (fun t => ⟪f t, g t⟫) (⟪f x, g'⟫ + ⟪f', g x⟫) x := by simpa only [← hasDerivWithinAt_univ] using HasDerivWithinAt.inner 𝕜 theorem DifferentiableWithinAt.inner (hf : DifferentiableWithinAt ℝ f s x) (hg : DifferentiableWithinAt ℝ g s x) : DifferentiableWithinAt ℝ (fun x => ⟪f x, g x⟫) s x := (hf.hasFDerivWithinAt.inner 𝕜 hg.hasFDerivWithinAt).differentiableWithinAt theorem DifferentiableAt.inner (hf : DifferentiableAt ℝ f x) (hg : DifferentiableAt ℝ g x) : DifferentiableAt ℝ (fun x => ⟪f x, g x⟫) x := (hf.hasFDerivAt.inner 𝕜 hg.hasFDerivAt).differentiableAt theorem DifferentiableOn.inner (hf : DifferentiableOn ℝ f s) (hg : DifferentiableOn ℝ g s) : DifferentiableOn ℝ (fun x => ⟪f x, g x⟫) s := fun x hx => (hf x hx).inner 𝕜 (hg x hx) theorem Differentiable.inner (hf : Differentiable ℝ f) (hg : Differentiable ℝ g) : Differentiable ℝ fun x => ⟪f x, g x⟫ := fun x => (hf x).inner 𝕜 (hg x) theorem fderiv_inner_apply (hf : DifferentiableAt ℝ f x) (hg : DifferentiableAt ℝ g x) (y : G) : fderiv ℝ (fun t => ⟪f t, g t⟫) x y = ⟪f x, fderiv ℝ g x y⟫ + ⟪fderiv ℝ f x y, g x⟫ := by rw [(hf.hasFDerivAt.inner 𝕜 hg.hasFDerivAt).fderiv]; rfl theorem deriv_inner_apply {f g : ℝ → E} {x : ℝ} (hf : DifferentiableAt ℝ f x) (hg : DifferentiableAt ℝ g x) : deriv (fun t => ⟪f t, g t⟫) x = ⟪f x, deriv g x⟫ + ⟪deriv f x, g x⟫ := (hf.hasDerivAt.inner 𝕜 hg.hasDerivAt).deriv section include 𝕜 theorem contDiff_norm_sq : ContDiff ℝ n fun x : E => ‖x‖ ^ 2 := by convert (reCLM : 𝕜 →L[ℝ] ℝ).contDiff.comp ((contDiff_id (E := E)).inner 𝕜 (contDiff_id (E := E))) exact (inner_self_eq_norm_sq _).symm theorem ContDiff.norm_sq (hf : ContDiff ℝ n f) : ContDiff ℝ n fun x => ‖f x‖ ^ 2 := (contDiff_norm_sq 𝕜).comp hf theorem ContDiffWithinAt.norm_sq (hf : ContDiffWithinAt ℝ n f s x) : ContDiffWithinAt ℝ n (fun y => ‖f y‖ ^ 2) s x := (contDiff_norm_sq 𝕜).contDiffAt.comp_contDiffWithinAt x hf nonrec theorem ContDiffAt.norm_sq (hf : ContDiffAt ℝ n f x) : ContDiffAt ℝ n (‖f ·‖ ^ 2) x := hf.norm_sq 𝕜 theorem contDiffAt_norm {x : E} (hx : x ≠ 0) : ContDiffAt ℝ n norm x := by have : ‖id x‖ ^ 2 ≠ 0 := pow_ne_zero 2 (norm_pos_iff.2 hx).ne' simpa only [id, sqrt_sq, norm_nonneg] using (contDiffAt_id.norm_sq 𝕜).sqrt this theorem ContDiffAt.norm (hf : ContDiffAt ℝ n f x) (h0 : f x ≠ 0) : ContDiffAt ℝ n (fun y => ‖f y‖) x := (contDiffAt_norm 𝕜 h0).comp x hf theorem ContDiffAt.dist (hf : ContDiffAt ℝ n f x) (hg : ContDiffAt ℝ n g x) (hne : f x ≠ g x) : ContDiffAt ℝ n (fun y => dist (f y) (g y)) x := by simp only [dist_eq_norm] exact (hf.sub hg).norm 𝕜 (sub_ne_zero.2 hne) theorem ContDiffWithinAt.norm (hf : ContDiffWithinAt ℝ n f s x) (h0 : f x ≠ 0) : ContDiffWithinAt ℝ n (fun y => ‖f y‖) s x := (contDiffAt_norm 𝕜 h0).comp_contDiffWithinAt x hf theorem ContDiffWithinAt.dist (hf : ContDiffWithinAt ℝ n f s x) (hg : ContDiffWithinAt ℝ n g s x) (hne : f x ≠ g x) : ContDiffWithinAt ℝ n (fun y => dist (f y) (g y)) s x := by simp only [dist_eq_norm]; exact (hf.sub hg).norm 𝕜 (sub_ne_zero.2 hne) theorem ContDiffOn.norm_sq (hf : ContDiffOn ℝ n f s) : ContDiffOn ℝ n (fun y => ‖f y‖ ^ 2) s := fun x hx => (hf x hx).norm_sq 𝕜 theorem ContDiffOn.norm (hf : ContDiffOn ℝ n f s) (h0 : ∀ x ∈ s, f x ≠ 0) : ContDiffOn ℝ n (fun y => ‖f y‖) s := fun x hx => (hf x hx).norm 𝕜 (h0 x hx) theorem ContDiffOn.dist (hf : ContDiffOn ℝ n f s) (hg : ContDiffOn ℝ n g s) (hne : ∀ x ∈ s, f x ≠ g x) : ContDiffOn ℝ n (fun y => dist (f y) (g y)) s := fun x hx => (hf x hx).dist 𝕜 (hg x hx) (hne x hx) theorem ContDiff.norm (hf : ContDiff ℝ n f) (h0 : ∀ x, f x ≠ 0) : ContDiff ℝ n fun y => ‖f y‖ := contDiff_iff_contDiffAt.2 fun x => hf.contDiffAt.norm 𝕜 (h0 x) theorem ContDiff.dist (hf : ContDiff ℝ n f) (hg : ContDiff ℝ n g) (hne : ∀ x, f x ≠ g x) : ContDiff ℝ n fun y => dist (f y) (g y) := contDiff_iff_contDiffAt.2 fun x => hf.contDiffAt.dist 𝕜 hg.contDiffAt (hne x) end theorem hasStrictFDerivAt_norm_sq (x : F) : HasStrictFDerivAt (fun x => ‖x‖ ^ 2) (2 • (innerSL ℝ x)) x := by simp only [sq, ← @inner_self_eq_norm_mul_norm ℝ] convert (hasStrictFDerivAt_id x).inner ℝ (hasStrictFDerivAt_id x) ext y simp [two_smul, real_inner_comm] theorem HasFDerivAt.norm_sq {f : G → F} {f' : G →L[ℝ] F} (hf : HasFDerivAt f f' x) : HasFDerivAt (‖f ·‖ ^ 2) (2 • (innerSL ℝ (f x)).comp f') x := (hasStrictFDerivAt_norm_sq _).hasFDerivAt.comp x hf theorem HasDerivAt.norm_sq {f : ℝ → F} {f' : F} {x : ℝ} (hf : HasDerivAt f f' x) : HasDerivAt (‖f ·‖ ^ 2) (2 * Inner.inner (f x) f') x := by simpa using hf.hasFDerivAt.norm_sq.hasDerivAt theorem HasFDerivWithinAt.norm_sq {f : G → F} {f' : G →L[ℝ] F} (hf : HasFDerivWithinAt f f' s x) : HasFDerivWithinAt (‖f ·‖ ^ 2) (2 • (innerSL ℝ (f x)).comp f') s x := (hasStrictFDerivAt_norm_sq _).hasFDerivAt.comp_hasFDerivWithinAt x hf theorem HasDerivWithinAt.norm_sq {f : ℝ → F} {f' : F} {s : Set ℝ} {x : ℝ} (hf : HasDerivWithinAt f f' s x) : HasDerivWithinAt (‖f ·‖ ^ 2) (2 * Inner.inner (f x) f') s x := by simpa using hf.hasFDerivWithinAt.norm_sq.hasDerivWithinAt section include 𝕜 theorem DifferentiableAt.norm_sq (hf : DifferentiableAt ℝ f x) : DifferentiableAt ℝ (fun y => ‖f y‖ ^ 2) x := ((contDiffAt_id.norm_sq 𝕜).differentiableAt le_rfl).comp x hf theorem DifferentiableAt.norm (hf : DifferentiableAt ℝ f x) (h0 : f x ≠ 0) : DifferentiableAt ℝ (fun y => ‖f y‖) x := ((contDiffAt_norm 𝕜 h0).differentiableAt le_rfl).comp x hf theorem DifferentiableAt.dist (hf : DifferentiableAt ℝ f x) (hg : DifferentiableAt ℝ g x) (hne : f x ≠ g x) : DifferentiableAt ℝ (fun y => dist (f y) (g y)) x := by simp only [dist_eq_norm]; exact (hf.sub hg).norm 𝕜 (sub_ne_zero.2 hne) theorem Differentiable.norm_sq (hf : Differentiable ℝ f) : Differentiable ℝ fun y => ‖f y‖ ^ 2 := fun x => (hf x).norm_sq 𝕜 theorem Differentiable.norm (hf : Differentiable ℝ f) (h0 : ∀ x, f x ≠ 0) : Differentiable ℝ fun y => ‖f y‖ := fun x => (hf x).norm 𝕜 (h0 x) theorem Differentiable.dist (hf : Differentiable ℝ f) (hg : Differentiable ℝ g) (hne : ∀ x, f x ≠ g x) : Differentiable ℝ fun y => dist (f y) (g y) := fun x => (hf x).dist 𝕜 (hg x) (hne x) theorem DifferentiableWithinAt.norm_sq (hf : DifferentiableWithinAt ℝ f s x) : DifferentiableWithinAt ℝ (fun y => ‖f y‖ ^ 2) s x := ((contDiffAt_id.norm_sq 𝕜).differentiableAt le_rfl).comp_differentiableWithinAt x hf theorem DifferentiableWithinAt.norm (hf : DifferentiableWithinAt ℝ f s x) (h0 : f x ≠ 0) : DifferentiableWithinAt ℝ (fun y => ‖f y‖) s x := ((contDiffAt_id.norm 𝕜 h0).differentiableAt le_rfl).comp_differentiableWithinAt x hf theorem DifferentiableWithinAt.dist (hf : DifferentiableWithinAt ℝ f s x) (hg : DifferentiableWithinAt ℝ g s x) (hne : f x ≠ g x) : DifferentiableWithinAt ℝ (fun y => dist (f y) (g y)) s x := by simp only [dist_eq_norm] exact (hf.sub hg).norm 𝕜 (sub_ne_zero.2 hne) theorem DifferentiableOn.norm_sq (hf : DifferentiableOn ℝ f s) : DifferentiableOn ℝ (fun y => ‖f y‖ ^ 2) s := fun x hx => (hf x hx).norm_sq 𝕜 theorem DifferentiableOn.norm (hf : DifferentiableOn ℝ f s) (h0 : ∀ x ∈ s, f x ≠ 0) : DifferentiableOn ℝ (fun y => ‖f y‖) s := fun x hx => (hf x hx).norm 𝕜 (h0 x hx) theorem DifferentiableOn.dist (hf : DifferentiableOn ℝ f s) (hg : DifferentiableOn ℝ g s) (hne : ∀ x ∈ s, f x ≠ g x) : DifferentiableOn ℝ (fun y => dist (f y) (g y)) s := fun x hx => (hf x hx).dist 𝕜 (hg x hx) (hne x hx) end end DerivInner section PiLike /-! ### Convenience aliases of `PiLp` lemmas for `EuclideanSpace` -/ open ContinuousLinearMap variable {𝕜 ι H : Type} [RCLike 𝕜] [NormedAddCommGroup H] [NormedSpace 𝕜 H] [Fintype ι] {f : H → EuclideanSpace 𝕜 ι} {f' : H →L[𝕜] EuclideanSpace 𝕜 ι} {t : Set H} {y : H} theorem differentiableWithinAt_euclidean : DifferentiableWithinAt 𝕜 f t y ↔ ∀ i, DifferentiableWithinAt 𝕜 (fun x => f x i) t y := differentiableWithinAt_piLp _ theorem differentiableAt_euclidean : DifferentiableAt 𝕜 f y ↔ ∀ i, DifferentiableAt 𝕜 (fun x => f x i) y := differentiableAt_piLp _ theorem differentiableOn_euclidean : DifferentiableOn 𝕜 f t ↔ ∀ i, DifferentiableOn 𝕜 (fun x => f x i) t := differentiableOn_piLp _ theorem differentiable_euclidean : Differentiable 𝕜 f ↔ ∀ i, Differentiable 𝕜 fun x => f x i := differentiable_piLp _ theorem hasStrictFDerivAt_euclidean : HasStrictFDerivAt f f' y ↔ ∀ i, HasStrictFDerivAt (fun x => f x i) (PiLp.proj _ _ i ∘L f') y := hasStrictFDerivAt_piLp _ theorem hasFDerivWithinAt_euclidean : HasFDerivWithinAt f f' t y ↔ ∀ i, HasFDerivWithinAt (fun x => f x i) (PiLp.proj _ _ i ∘L f') t y := hasFDerivWithinAt_piLp _ theorem contDiffWithinAt_euclidean {n : WithTop ℕ∞} : ContDiffWithinAt 𝕜 n f t y ↔ ∀ i, ContDiffWithinAt 𝕜 n (fun x => f x i) t y := contDiffWithinAt_piLp _ theorem contDiffAt_euclidean {n : WithTop ℕ∞} : ContDiffAt 𝕜 n f y ↔ ∀ i, ContDiffAt 𝕜 n (fun x => f x i) y := contDiffAt_piLp _ theorem contDiffOn_euclidean {n : WithTop ℕ∞} : ContDiffOn 𝕜 n f t ↔ ∀ i, ContDiffOn 𝕜 n (fun x => f x i) t := contDiffOn_piLp _ theorem contDiff_euclidean {n : WithTop ℕ∞} : ContDiff 𝕜 n f ↔ ∀ i, ContDiff 𝕜 n fun x => f x i := contDiff_piLp _ end PiLike section DiffeomorphUnitBall open Metric hiding mem_nhds_iff variable {n : ℕ∞} {E : Type} [NormedAddCommGroup E] [InnerProductSpace ℝ E] theorem PartialHomeomorph.contDiff_univUnitBall : ContDiff ℝ n (univUnitBall : E → E) := by suffices ContDiff ℝ n fun x : E => (√(1 + ‖x‖ ^ 2 : ℝ))⁻¹ from this.smul contDiff_id have h : ∀ x : E, (0 : ℝ) < (1 : ℝ) + ‖x‖ ^ 2 := fun x => by positivity refine ContDiff.inv ?_ fun x => Real.sqrt_ne_zero'.mpr (h x) exact (contDiff_const.add <\| contDiff_norm_sq ℝ).sqrt fun x => (h x).ne' theorem PartialHomeomorph.contDiffOn_univUnitBall_symm :	ContDiffOn ℝ n univUnitBall.symm (ball (0 : E) 1) := fun y hy ↦ by apply ContDiffAt.contDiffWithinAt suffices ContDiffAt ℝ n (fun y : E => (√(1 - ‖y‖ ^ 2 : ℝ))⁻¹) y from this.smul contDiffAt_id have h : (0 : ℝ) < (1 : ℝ) - ‖(y : E)‖ ^ 2 := by rwa [mem_ball_zero_iff, ← _root_.abs_one, ← abs_norm, ← sq_lt_sq, one_pow, ← sub_pos] at hy	Mathlib/Analysis/InnerProductSpace/Calculus.lean	333	337
/- Copyright (c) 2021 Patrick Massot. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Patrick Massot -/ import Mathlib.Analysis.Calculus.MeanValue import Mathlib.MeasureTheory.Integral.DominatedConvergence import Mathlib.MeasureTheory.Integral.Bochner.Set import Mathlib.Analysis.NormedSpace.HahnBanach.SeparatingDual /-! # Derivatives of integrals depending on parameters A parametric integral is a function with shape `f = fun x : H ↦ ∫ a : α, F x a ∂μ` for some `F : H → α → E`, where `H` and `E` are normed spaces and `α` is a measured space with measure `μ`. We already know from `continuous_of_dominated` in `Mathlib/MeasureTheory/Integral/Bochner/Basic.lean` how to guarantee that `f` is continuous using the dominated convergence theorem. In this file, we want to express the derivative of `f` as the integral of the derivative of `F` with respect to `x`. ## Main results As explained above, all results express the derivative of a parametric integral as the integral of a derivative. The variations come from the assumptions and from the different ways of expressing derivative, especially Fréchet derivatives vs elementary derivative of function of one real variable. * `hasFDerivAt_integral_of_dominated_loc_of_lip`: this version assumes that - `F x` is ae-measurable for x near `x₀`, - `F x₀` is integrable, - `fun x ↦ F x a` has derivative `F' a : H →L[ℝ] E` at `x₀` which is ae-measurable, - `fun x ↦ F x a` is locally Lipschitz near `x₀` for almost every `a`, with a Lipschitz bound which is integrable with respect to `a`. A subtle point is that the "near x₀" in the last condition has to be uniform in `a`. This is controlled by a positive number `ε`. * `hasFDerivAt_integral_of_dominated_of_fderiv_le`: this version assumes `fun x ↦ F x a` has derivative `F' x a` for `x` near `x₀` and `F' x` is bounded by an integrable function independent from `x` near `x₀`. `hasDerivAt_integral_of_dominated_loc_of_lip` and `hasDerivAt_integral_of_dominated_loc_of_deriv_le` are versions of the above two results that assume `H = ℝ` or `H = ℂ` and use the high-school derivative `deriv` instead of Fréchet derivative `fderiv`. We also provide versions of these theorems for set integrals. ## Tags integral, derivative -/ noncomputable section open TopologicalSpace MeasureTheory Filter Metric open scoped Topology Filter variable {α : Type} [MeasurableSpace α] {μ : Measure α} {𝕜 : Type} [RCLike 𝕜] {E : Type} [NormedAddCommGroup E] [NormedSpace ℝ E] [NormedSpace 𝕜 E] {H : Type} [NormedAddCommGroup H] [NormedSpace 𝕜 H] variable {F : H → α → E} {x₀ : H} {bound : α → ℝ} {ε : ℝ} /-- Differentiation under integral of `x ↦ ∫ F x a` at a given point `x₀`, assuming `F x₀` is integrable, `‖F x a - F x₀ a‖ ≤ bound a * ‖x - x₀‖` for `x` in a ball around `x₀` for ae `a` with integrable Lipschitz bound `bound` (with a ball radius independent of `a`), and `F x` is ae-measurable for `x` in the same ball. See `hasFDerivAt_integral_of_dominated_loc_of_lip` for a slightly less general but usually more useful version. -/ theorem hasFDerivAt_integral_of_dominated_loc_of_lip' {F' : α → H →L[𝕜] E} (ε_pos : 0 < ε) (hF_meas : ∀ x ∈ ball x₀ ε, AEStronglyMeasurable (F x) μ) (hF_int : Integrable (F x₀) μ) (hF'_meas : AEStronglyMeasurable F' μ) (h_lipsch : ∀ᵐ a ∂μ, ∀ x ∈ ball x₀ ε, ‖F x a - F x₀ a‖ ≤ bound a * ‖x - x₀‖) (bound_integrable : Integrable (bound : α → ℝ) μ) (h_diff : ∀ᵐ a ∂μ, HasFDerivAt (F · a) (F' a) x₀) : Integrable F' μ ∧ HasFDerivAt (fun x ↦ ∫ a, F x a ∂μ) (∫ a, F' a ∂μ) x₀ := by have x₀_in : x₀ ∈ ball x₀ ε := mem_ball_self ε_pos have nneg : ∀ x, 0 ≤ ‖x - x₀‖⁻¹ := fun x ↦ inv_nonneg.mpr (norm_nonneg _) set b : α → ℝ := fun a ↦ \|bound a\| have b_int : Integrable b μ := bound_integrable.norm have b_nonneg : ∀ a, 0 ≤ b a := fun a ↦ abs_nonneg _ replace h_lipsch : ∀ᵐ a ∂μ, ∀ x ∈ ball x₀ ε, ‖F x a - F x₀ a‖ ≤ b a * ‖x - x₀‖ := h_lipsch.mono fun a ha x hx ↦ (ha x hx).trans <\| mul_le_mul_of_nonneg_right (le_abs_self _) (norm_nonneg _) have hF_int' : ∀ x ∈ ball x₀ ε, Integrable (F x) μ := fun x x_in ↦ by have : ∀ᵐ a ∂μ, ‖F x₀ a - F x a‖ ≤ ε * b a := by simp only [norm_sub_rev (F x₀ _)] refine h_lipsch.mono fun a ha ↦ (ha x x_in).trans ?_ rw [mul_comm ε] rw [mem_ball, dist_eq_norm] at x_in exact mul_le_mul_of_nonneg_left x_in.le (b_nonneg _) exact integrable_of_norm_sub_le (hF_meas x x_in) hF_int (bound_integrable.norm.const_mul ε) this have hF'_int : Integrable F' μ := have : ∀ᵐ a ∂μ, ‖F' a‖ ≤ b a := by apply (h_diff.and h_lipsch).mono rintro a ⟨ha_diff, ha_lip⟩ exact ha_diff.le_of_lip' (b_nonneg a) (mem_of_superset (ball_mem_nhds _ ε_pos) <\| ha_lip) b_int.mono' hF'_meas this refine ⟨hF'_int, ?_⟩ /- Discard the trivial case where `E` is not complete, as all integrals vanish. -/ by_cases hE : CompleteSpace E; swap · rcases subsingleton_or_nontrivial H with hH\|hH · have : Subsingleton (H →L[𝕜] E) := inferInstance convert hasFDerivAt_of_subsingleton _ x₀ · have : ¬(CompleteSpace (H →L[𝕜] E)) := by simpa [SeparatingDual.completeSpace_continuousLinearMap_iff] using hE simp only [integral, hE, ↓reduceDIte, this] exact hasFDerivAt_const 0 x₀ have h_ball : ball x₀ ε ∈ 𝓝 x₀ := ball_mem_nhds x₀ ε_pos have : ∀ᶠ x in 𝓝 x₀, ‖x - x₀‖⁻¹ * ‖((∫ a, F x a ∂μ) - ∫ a, F x₀ a ∂μ) - (∫ a, F' a ∂μ) (x - x₀)‖ = ‖∫ a, ‖x - x₀‖⁻¹ • (F x a - F x₀ a - F' a (x - x₀)) ∂μ‖ := by apply mem_of_superset (ball_mem_nhds _ ε_pos) intro x x_in; simp only rw [Set.mem_setOf_eq, ← norm_smul_of_nonneg (nneg _), integral_smul, integral_sub, integral_sub, ← ContinuousLinearMap.integral_apply hF'_int] exacts [hF_int' x x_in, hF_int, (hF_int' x x_in).sub hF_int, hF'_int.apply_continuousLinearMap _] rw [hasFDerivAt_iff_tendsto, tendsto_congr' this, ← tendsto_zero_iff_norm_tendsto_zero, ← show (∫ a : α, ‖x₀ - x₀‖⁻¹ • (F x₀ a - F x₀ a - (F' a) (x₀ - x₀)) ∂μ) = 0 by simp] apply tendsto_integral_filter_of_dominated_convergence · filter_upwards [h_ball] with _ x_in apply AEStronglyMeasurable.const_smul exact ((hF_meas _ x_in).sub (hF_meas _ x₀_in)).sub (hF'_meas.apply_continuousLinearMap _) · refine mem_of_superset h_ball fun x hx ↦ ?_ apply (h_diff.and h_lipsch).mono on_goal 1 => rintro a ⟨-, ha_bound⟩ show ‖‖x - x₀‖⁻¹ • (F x a - F x₀ a - F' a (x - x₀))‖ ≤ b a + ‖F' a‖ replace ha_bound : ‖F x a - F x₀ a‖ ≤ b a * ‖x - x₀‖ := ha_bound x hx calc ‖‖x - x₀‖⁻¹ • (F x a - F x₀ a - F' a (x - x₀))‖ = ‖‖x - x₀‖⁻¹ • (F x a - F x₀ a) - ‖x - x₀‖⁻¹ • F' a (x - x₀)‖ := by rw [smul_sub] _ ≤ ‖‖x - x₀‖⁻¹ • (F x a - F x₀ a)‖ + ‖‖x - x₀‖⁻¹ • F' a (x - x₀)‖ := norm_sub_le _ _ _ = ‖x - x₀‖⁻¹ * ‖F x a - F x₀ a‖ + ‖x - x₀‖⁻¹ * ‖F' a (x - x₀)‖ := by rw [norm_smul_of_nonneg, norm_smul_of_nonneg] <;> exact nneg _ _ ≤ ‖x - x₀‖⁻¹ * (b a * ‖x - x₀‖) + ‖x - x₀‖⁻¹ * (‖F' a‖ * ‖x - x₀‖) := by gcongr; exact (F' a).le_opNorm _ _ ≤ b a + ‖F' a‖ := ?_ simp only [← div_eq_inv_mul] apply_rules [add_le_add, div_le_of_le_mul₀] <;> first \| rfl \| positivity · exact b_int.add hF'_int.norm · apply h_diff.mono intro a ha suffices Tendsto (fun x ↦ ‖x - x₀‖⁻¹ • (F x a - F x₀ a - F' a (x - x₀))) (𝓝 x₀) (𝓝 0) by simpa rw [tendsto_zero_iff_norm_tendsto_zero] have : (fun x ↦ ‖x - x₀‖⁻¹ * ‖F x a - F x₀ a - F' a (x - x₀)‖) = fun x ↦ ‖‖x - x₀‖⁻¹ • (F x a - F x₀ a - F' a (x - x₀))‖ := by ext x rw [norm_smul_of_nonneg (nneg _)] rwa [hasFDerivAt_iff_tendsto, this] at ha /-- Differentiation under integral of `x ↦ ∫ F x a` at a given point `x₀`, assuming `F x₀` is integrable, `x ↦ F x a` is locally Lipschitz on a ball around `x₀` for ae `a` (with a ball radius independent of `a`) with integrable Lipschitz bound, and `F x` is ae-measurable for `x` in a possibly smaller neighborhood of `x₀`. -/ theorem hasFDerivAt_integral_of_dominated_loc_of_lip {F' : α → H →L[𝕜] E} (ε_pos : 0 < ε) (hF_meas : ∀ᶠ x in 𝓝 x₀, AEStronglyMeasurable (F x) μ) (hF_int : Integrable (F x₀) μ) (hF'_meas : AEStronglyMeasurable F' μ) (h_lip : ∀ᵐ a ∂μ, LipschitzOnWith (Real.nnabs <\| bound a) (F · a) (ball x₀ ε)) (bound_integrable : Integrable (bound : α → ℝ) μ) (h_diff : ∀ᵐ a ∂μ, HasFDerivAt (F · a) (F' a) x₀) : Integrable F' μ ∧ HasFDerivAt (fun x ↦ ∫ a, F x a ∂μ) (∫ a, F' a ∂μ) x₀ := by obtain ⟨δ, δ_pos, hδ⟩ : ∃ δ > 0, ∀ x ∈ ball x₀ δ, AEStronglyMeasurable (F x) μ ∧ x ∈ ball x₀ ε := eventually_nhds_iff_ball.mp (hF_meas.and (ball_mem_nhds x₀ ε_pos)) choose hδ_meas hδε using hδ replace h_lip : ∀ᵐ a : α ∂μ, ∀ x ∈ ball x₀ δ, ‖F x a - F x₀ a‖ ≤ \|bound a\| * ‖x - x₀‖ := h_lip.mono fun a lip x hx ↦ lip.norm_sub_le (hδε x hx) (mem_ball_self ε_pos) replace bound_integrable := bound_integrable.norm apply hasFDerivAt_integral_of_dominated_loc_of_lip' δ_pos <;> assumption open scoped Interval in /-- Differentiation under integral of `x ↦ ∫ x in a..b, F x t` at a given point `x₀ ∈ (a,b)`, assuming `F x₀` is integrable on `(a,b)`, that `x ↦ F x t` is Lipschitz on a ball around `x₀` for almost every `t` (with a ball radius independent of `t`) with integrable Lipschitz bound, and `F x` is a.e.-measurable for `x` in a possibly smaller neighborhood of `x₀`. -/ theorem hasFDerivAt_integral_of_dominated_loc_of_lip_interval [NormedSpace ℝ H] {μ : Measure ℝ} {F : H → ℝ → E} {F' : ℝ → H →L[ℝ] E} {a b : ℝ} {bound : ℝ → ℝ} (ε_pos : 0 < ε) (hF_meas : ∀ᶠ x in 𝓝 x₀, AEStronglyMeasurable (F x) <\| μ.restrict (Ι a b)) (hF_int : IntervalIntegrable (F x₀) μ a b) (hF'_meas : AEStronglyMeasurable F' <\| μ.restrict (Ι a b)) (h_lip : ∀ᵐ t ∂μ.restrict (Ι a b), LipschitzOnWith (Real.nnabs <\| bound t) (F · t) (ball x₀ ε)) (bound_integrable : IntervalIntegrable bound μ a b) (h_diff : ∀ᵐ t ∂μ.restrict (Ι a b), HasFDerivAt (F · t) (F' t) x₀) : IntervalIntegrable F' μ a b ∧ HasFDerivAt (fun x ↦ ∫ t in a..b, F x t ∂μ) (∫ t in a..b, F' t ∂μ) x₀ := by simp_rw [AEStronglyMeasurable.aestronglyMeasurable_uIoc_iff, eventually_and] at hF_meas hF'_meas rw [ae_restrict_uIoc_iff] at h_lip h_diff have H₁ := hasFDerivAt_integral_of_dominated_loc_of_lip ε_pos hF_meas.1 hF_int.1 hF'_meas.1 h_lip.1 bound_integrable.1 h_diff.1 have H₂ := hasFDerivAt_integral_of_dominated_loc_of_lip ε_pos hF_meas.2 hF_int.2 hF'_meas.2 h_lip.2 bound_integrable.2 h_diff.2 exact ⟨⟨H₁.1, H₂.1⟩, H₁.2.sub H₂.2⟩ /-- Differentiation under integral of `x ↦ ∫ F x a` at a given point `x₀`, assuming `F x₀` is integrable, `x ↦ F x a` is differentiable on a ball around `x₀` for ae `a` with derivative norm uniformly bounded by an integrable function (the ball radius is independent of `a`), and `F x` is ae-measurable for `x` in a possibly smaller neighborhood of `x₀`. -/ theorem hasFDerivAt_integral_of_dominated_of_fderiv_le {F' : H → α → H →L[𝕜] E} (ε_pos : 0 < ε) (hF_meas : ∀ᶠ x in 𝓝 x₀, AEStronglyMeasurable (F x) μ) (hF_int : Integrable (F x₀) μ) (hF'_meas : AEStronglyMeasurable (F' x₀) μ) (h_bound : ∀ᵐ a ∂μ, ∀ x ∈ ball x₀ ε, ‖F' x a‖ ≤ bound a) (bound_integrable : Integrable (bound : α → ℝ) μ) (h_diff : ∀ᵐ a ∂μ, ∀ x ∈ ball x₀ ε, HasFDerivAt (F · a) (F' x a) x) : HasFDerivAt (fun x ↦ ∫ a, F x a ∂μ) (∫ a, F' x₀ a ∂μ) x₀ := by letI : NormedSpace ℝ H := NormedSpace.restrictScalars ℝ 𝕜 H have x₀_in : x₀ ∈ ball x₀ ε := mem_ball_self ε_pos have diff_x₀ : ∀ᵐ a ∂μ, HasFDerivAt (F · a) (F' x₀ a) x₀ := h_diff.mono fun a ha ↦ ha x₀ x₀_in have : ∀ᵐ a ∂μ, LipschitzOnWith (Real.nnabs (bound a)) (F · a) (ball x₀ ε) := by apply (h_diff.and h_bound).mono rintro a ⟨ha_deriv, ha_bound⟩ refine (convex_ball _ _).lipschitzOnWith_of_nnnorm_hasFDerivWithin_le (fun x x_in ↦ (ha_deriv x x_in).hasFDerivWithinAt) fun x x_in ↦ ?_ rw [← NNReal.coe_le_coe, coe_nnnorm, Real.coe_nnabs] exact (ha_bound x x_in).trans (le_abs_self _) exact (hasFDerivAt_integral_of_dominated_loc_of_lip ε_pos hF_meas hF_int hF'_meas this bound_integrable diff_x₀).2 open scoped Interval in /-- Differentiation under integral of `x ↦ ∫ x in a..b, F x a` at a given point `x₀`, assuming `F x₀` is integrable on `(a,b)`, `x ↦ F x a` is differentiable on a ball around `x₀` for ae `a` with derivative norm uniformly bounded by an integrable function (the ball radius is independent of `a`), and `F x` is ae-measurable for `x` in a possibly smaller neighborhood of `x₀`. -/ theorem hasFDerivAt_integral_of_dominated_of_fderiv_le'' [NormedSpace ℝ H] {μ : Measure ℝ} {F : H → ℝ → E} {F' : H → ℝ → H →L[ℝ] E} {a b : ℝ} {bound : ℝ → ℝ} (ε_pos : 0 < ε) (hF_meas : ∀ᶠ x in 𝓝 x₀, AEStronglyMeasurable (F x) <\| μ.restrict (Ι a b)) (hF_int : IntervalIntegrable (F x₀) μ a b) (hF'_meas : AEStronglyMeasurable (F' x₀) <\| μ.restrict (Ι a b)) (h_bound : ∀ᵐ t ∂μ.restrict (Ι a b), ∀ x ∈ ball x₀ ε, ‖F' x t‖ ≤ bound t) (bound_integrable : IntervalIntegrable bound μ a b) (h_diff : ∀ᵐ t ∂μ.restrict (Ι a b), ∀ x ∈ ball x₀ ε, HasFDerivAt (F · t) (F' x t) x) : HasFDerivAt (fun x ↦ ∫ t in a..b, F x t ∂μ) (∫ t in a..b, F' x₀ t ∂μ) x₀ := by rw [ae_restrict_uIoc_iff] at h_diff h_bound simp_rw [AEStronglyMeasurable.aestronglyMeasurable_uIoc_iff, eventually_and] at hF_meas hF'_meas exact (hasFDerivAt_integral_of_dominated_of_fderiv_le ε_pos hF_meas.1 hF_int.1 hF'_meas.1 h_bound.1 bound_integrable.1 h_diff.1).sub (hasFDerivAt_integral_of_dominated_of_fderiv_le ε_pos hF_meas.2 hF_int.2 hF'_meas.2 h_bound.2 bound_integrable.2 h_diff.2) section variable {F : 𝕜 → α → E} {x₀ : 𝕜} /-- Derivative under integral of `x ↦ ∫ F x a` at a given point `x₀ : 𝕜`, `𝕜 = ℝ` or `𝕜 = ℂ`, assuming `F x₀` is integrable, `x ↦ F x a` is locally Lipschitz on a ball around `x₀` for ae `a` (with ball radius independent of `a`) with integrable Lipschitz bound, and `F x` is ae-measurable for `x` in a possibly smaller neighborhood of `x₀`. -/ theorem hasDerivAt_integral_of_dominated_loc_of_lip {F' : α → E} (ε_pos : 0 < ε) (hF_meas : ∀ᶠ x in 𝓝 x₀, AEStronglyMeasurable (F x) μ) (hF_int : Integrable (F x₀) μ) (hF'_meas : AEStronglyMeasurable F' μ) (h_lipsch : ∀ᵐ a ∂μ, LipschitzOnWith (Real.nnabs <\| bound a) (F · a) (ball x₀ ε)) (bound_integrable : Integrable (bound : α → ℝ) μ) (h_diff : ∀ᵐ a ∂μ, HasDerivAt (F · a) (F' a) x₀) : Integrable F' μ ∧ HasDerivAt (fun x ↦ ∫ a, F x a ∂μ) (∫ a, F' a ∂μ) x₀ := by set L : E →L[𝕜] 𝕜 →L[𝕜] E := ContinuousLinearMap.smulRightL 𝕜 𝕜 E 1 replace h_diff : ∀ᵐ a ∂μ, HasFDerivAt (F · a) (L (F' a)) x₀ := h_diff.mono fun x hx ↦ hx.hasFDerivAt have hm : AEStronglyMeasurable (L ∘ F') μ := L.continuous.comp_aestronglyMeasurable hF'_meas obtain ⟨hF'_int, key⟩ := hasFDerivAt_integral_of_dominated_loc_of_lip ε_pos hF_meas hF_int hm h_lipsch bound_integrable h_diff replace hF'_int : Integrable F' μ := by rw [← integrable_norm_iff hm] at hF'_int simpa only [L, (· ∘ ·), integrable_norm_iff, hF'_meas, one_mul, norm_one, ContinuousLinearMap.comp_apply, ContinuousLinearMap.coe_restrict_scalarsL', ContinuousLinearMap.norm_restrictScalars, ContinuousLinearMap.norm_smulRightL_apply] using hF'_int refine ⟨hF'_int, ?_⟩ by_cases hE : CompleteSpace E; swap · simpa [integral, hE] using hasDerivAt_const x₀ 0 simp_rw [hasDerivAt_iff_hasFDerivAt] at h_diff ⊢ simpa only [(· ∘ ·), ContinuousLinearMap.integral_comp_comm _ hF'_int] using key /-- Derivative under integral of `x ↦ ∫ F x a` at a given point `x₀ : ℝ`, assuming `F x₀` is integrable, `x ↦ F x a` is differentiable on an interval around `x₀` for ae `a` (with interval radius independent of `a`) with derivative uniformly bounded by an integrable function, and `F x` is ae-measurable for `x` in a possibly smaller neighborhood of `x₀`. -/ theorem hasDerivAt_integral_of_dominated_loc_of_deriv_le (ε_pos : 0 < ε) (hF_meas : ∀ᶠ x in 𝓝 x₀, AEStronglyMeasurable (F x) μ) (hF_int : Integrable (F x₀) μ) {F' : 𝕜 → α → E} (hF'_meas : AEStronglyMeasurable (F' x₀) μ) (h_bound : ∀ᵐ a ∂μ, ∀ x ∈ ball x₀ ε, ‖F' x a‖ ≤ bound a) (bound_integrable : Integrable bound μ) (h_diff : ∀ᵐ a ∂μ, ∀ x ∈ ball x₀ ε, HasDerivAt (F · a) (F' x a) x) : Integrable (F' x₀) μ ∧ HasDerivAt (fun n ↦ ∫ a, F n a ∂μ) (∫ a, F' x₀ a ∂μ) x₀ := by	have x₀_in : x₀ ∈ ball x₀ ε := mem_ball_self ε_pos have diff_x₀ : ∀ᵐ a ∂μ, HasDerivAt (F · a) (F' x₀ a) x₀ := h_diff.mono fun a ha ↦ ha x₀ x₀_in have : ∀ᵐ a ∂μ, LipschitzOnWith (Real.nnabs (bound a)) (fun x : 𝕜 ↦ F x a) (ball x₀ ε) := by apply (h_diff.and h_bound).mono rintro a ⟨ha_deriv, ha_bound⟩ refine (convex_ball _ _).lipschitzOnWith_of_nnnorm_hasDerivWithin_le (fun x x_in ↦ (ha_deriv x x_in).hasDerivWithinAt) fun x x_in ↦ ?_ rw [← NNReal.coe_le_coe, coe_nnnorm, Real.coe_nnabs] exact (ha_bound x x_in).trans (le_abs_self _) exact hasDerivAt_integral_of_dominated_loc_of_lip ε_pos hF_meas hF_int hF'_meas this bound_integrable diff_x₀ end	Mathlib/Analysis/Calculus/ParametricIntegral.lean	291	309
/- Copyright (c) 2016 Jeremy Avigad. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jeremy Avigad, Leonardo de Moura, Mario Carneiro -/ import Mathlib.Algebra.Order.Group.Abs import Mathlib.Algebra.Order.Ring.Basic import Mathlib.Algebra.Order.Ring.Int import Mathlib.Algebra.Ring.Divisibility.Basic import Mathlib.Algebra.Ring.Int.Units import Mathlib.Data.Nat.Cast.Order.Ring /-! # Absolute values in linear ordered rings. -/ variable {α : Type} section LinearOrderedAddCommGroup variable [CommGroup α] [LinearOrder α] [IsOrderedMonoid α] @[to_additive] lemma mabs_zpow (n : ℤ) (a : α) : \|a ^ n\|ₘ = \|a\|ₘ ^ \|n\| := by obtain n0 \| n0 := le_total 0 n · obtain ⟨n, rfl⟩ := Int.eq_ofNat_of_zero_le n0 simp only [mabs_pow, zpow_natCast, Nat.abs_cast] · obtain ⟨m, h⟩ := Int.eq_ofNat_of_zero_le (neg_nonneg.2 n0) rw [← mabs_inv, ← zpow_neg, ← abs_neg, h, zpow_natCast, Nat.abs_cast, zpow_natCast] exact mabs_pow m _ end LinearOrderedAddCommGroup lemma odd_abs [LinearOrder α] [Ring α] {a : α} : Odd (abs a) ↔ Odd a := by rcases abs_choice a with h \| h <;> simp only [h, odd_neg] section LinearOrderedRing variable [Ring α] [LinearOrder α] [IsStrictOrderedRing α] {n : ℕ} {a b : α} @[simp] lemma abs_one : \|(1 : α)\| = 1 := abs_of_pos zero_lt_one lemma abs_two : \|(2 : α)\| = 2 := abs_of_pos zero_lt_two lemma abs_mul (a b : α) : \|a b\| = \|a\| * \|b\| := by rw [abs_eq (mul_nonneg (abs_nonneg a) (abs_nonneg b))] rcases le_total a 0 with ha \| ha <;> rcases le_total b 0 with hb \| hb <;> simp only [abs_of_nonpos, abs_of_nonneg, true_or, or_true, eq_self_iff_true, neg_mul, mul_neg, neg_neg, ] /-- `abs` as a `MonoidWithZeroHom`. -/ def absHom : α →₀ α where toFun := abs map_zero' := abs_zero map_one' := abs_one map_mul' := abs_mul @[simp] lemma abs_pow (a : α) (n : ℕ) : \|a ^ n\| = \|a\| ^ n := (absHom.toMonoidHom : α →* α).map_pow _ _ lemma pow_abs (a : α) (n : ℕ) : \|a\| ^ n = \|a ^ n\| := (abs_pow a n).symm lemma Even.pow_abs (hn : Even n) (a : α) : \|a\| ^ n = a ^ n := by rw [← abs_pow, abs_eq_self]; exact hn.pow_nonneg _ lemma abs_neg_one_pow (n : ℕ) : \|(-1 : α) ^ n\| = 1 := by rw [← pow_abs, abs_neg, abs_one, one_pow] lemma abs_pow_eq_one (a : α) (h : n ≠ 0) : \|a ^ n\| = 1 ↔ \|a\| = 1 := by convert pow_left_inj₀ (abs_nonneg a) zero_le_one h exacts [(pow_abs _ _).symm, (one_pow _).symm] omit [IsStrictOrderedRing α] in @[simp] lemma abs_mul_abs_self (a : α) : \|a\| * \|a\| = a * a := abs_by_cases (fun x => x * x = a * a) rfl (neg_mul_neg a a) @[simp] lemma abs_mul_self (a : α) : \|a * a\| = a * a := by rw [abs_mul, abs_mul_abs_self] lemma abs_eq_iff_mul_self_eq : \|a\| = \|b\| ↔ a * a = b * b := by rw [← abs_mul_abs_self, ← abs_mul_abs_self b] exact (mul_self_inj (abs_nonneg a) (abs_nonneg b)).symm lemma abs_lt_iff_mul_self_lt : \|a\| < \|b\| ↔ a * a < b * b := by rw [← abs_mul_abs_self, ← abs_mul_abs_self b] exact mul_self_lt_mul_self_iff (abs_nonneg a) (abs_nonneg b) lemma abs_le_iff_mul_self_le : \|a\| ≤ \|b\| ↔ a * a ≤ b * b := by rw [← abs_mul_abs_self, ← abs_mul_abs_self b] exact mul_self_le_mul_self_iff (abs_nonneg a) (abs_nonneg b) lemma abs_le_one_iff_mul_self_le_one : \|a\| ≤ 1 ↔ a * a ≤ 1 := by simpa only [abs_one, one_mul] using abs_le_iff_mul_self_le (a := a) (b := 1) omit [IsStrictOrderedRing α] in @[simp] lemma sq_abs (a : α) : \|a\| ^ 2 = a ^ 2 := by simpa only [sq] using abs_mul_abs_self a lemma abs_sq (x : α) : \|x ^ 2\| = x ^ 2 := by simpa only [sq] using abs_mul_self x lemma sq_lt_sq : a ^ 2 < b ^ 2 ↔ \|a\| < \|b\| := by simpa only [sq_abs] using sq_lt_sq₀ (abs_nonneg a) (abs_nonneg b) lemma sq_lt_sq' (h1 : -b < a) (h2 : a < b) : a ^ 2 < b ^ 2 := sq_lt_sq.2 (lt_of_lt_of_le (abs_lt.2 ⟨h1, h2⟩) (le_abs_self _)) lemma sq_le_sq : a ^ 2 ≤ b ^ 2 ↔ \|a\| ≤ \|b\| := by simpa only [sq_abs] using sq_le_sq₀ (abs_nonneg a) (abs_nonneg b) lemma sq_le_sq' (h1 : -b ≤ a) (h2 : a ≤ b) : a ^ 2 ≤ b ^ 2 := sq_le_sq.2 (le_trans (abs_le.mpr ⟨h1, h2⟩) (le_abs_self _)) lemma abs_lt_of_sq_lt_sq (h : a ^ 2 < b ^ 2) (hb : 0 ≤ b) : \|a\| < b := by rwa [← abs_of_nonneg hb, ← sq_lt_sq] lemma abs_lt_of_sq_lt_sq' (h : a ^ 2 < b ^ 2) (hb : 0 ≤ b) : -b < a ∧ a < b := abs_lt.1 <\| abs_lt_of_sq_lt_sq h hb lemma abs_le_of_sq_le_sq (h : a ^ 2 ≤ b ^ 2) (hb : 0 ≤ b) : \|a\| ≤ b := by rwa [← abs_of_nonneg hb, ← sq_le_sq] theorem le_of_sq_le_sq (h : a ^ 2 ≤ b ^ 2) (hb : 0 ≤ b) : a ≤ b := le_abs_self a \|>.trans <\| abs_le_of_sq_le_sq h hb lemma abs_le_of_sq_le_sq' (h : a ^ 2 ≤ b ^ 2) (hb : 0 ≤ b) : -b ≤ a ∧ a ≤ b := abs_le.1 <\| abs_le_of_sq_le_sq h hb lemma sq_eq_sq_iff_abs_eq_abs (a b : α) : a ^ 2 = b ^ 2 ↔ \|a\| = \|b\| := by simp only [le_antisymm_iff, sq_le_sq] @[simp] lemma sq_le_one_iff_abs_le_one (a : α) : a ^ 2 ≤ 1 ↔ \|a\| ≤ 1 := by simpa only [one_pow, abs_one] using sq_le_sq (a := a) (b := 1) @[simp] lemma sq_lt_one_iff_abs_lt_one (a : α) : a ^ 2 < 1 ↔ \|a\| < 1 := by simpa only [one_pow, abs_one] using sq_lt_sq (a := a) (b := 1) @[simp] lemma one_le_sq_iff_one_le_abs (a : α) : 1 ≤ a ^ 2 ↔ 1 ≤ \|a\| := by simpa only [one_pow, abs_one] using sq_le_sq (a := 1) (b := a) @[simp] lemma one_lt_sq_iff_one_lt_abs (a : α) : 1 < a ^ 2 ↔ 1 < \|a\| := by simpa only [one_pow, abs_one] using sq_lt_sq (a := 1) (b := a) lemma exists_abs_lt {α : Type} [Ring α] [LinearOrder α] [IsStrictOrderedRing α] (a : α) : ∃ b > 0, \|a\| < b := ⟨\|a\| + 1, lt_of_lt_of_le zero_lt_one <\| by simp, lt_add_one \|a\|⟩ end LinearOrderedRing section LinearOrderedCommRing variable [CommRing α] [LinearOrder α] [IsStrictOrderedRing α] (a b : α) (n : ℕ) omit [IsStrictOrderedRing α] in theorem abs_sub_sq (a b : α) : \|a - b\| \|a - b\| = a * a + b * b - (1 + 1) * a * b := by rw [abs_mul_abs_self] simp only [mul_add, add_comm, add_left_comm, mul_comm, sub_eq_add_neg, mul_one, mul_neg, neg_add_rev, neg_neg, add_assoc] lemma abs_unit_intCast (a : ℤˣ) : \|((a : ℤ) : α)\| = 1 := by cases Int.units_eq_one_or a <;> simp_all private def geomSum : ℕ → α \| 0 => 1 \| n + 1 => a * geomSum n + b ^ (n + 1) private theorem abs_geomSum_le : \|geomSum a b n\| ≤ (n + 1) * max \|a\| \|b\| ^ n := by induction n with \| zero => simp [geomSum] \| succ n ih => ?_ refine (abs_add_le ..).trans ?_	rw [abs_mul, abs_pow, Nat.cast_succ, add_one_mul] refine add_le_add ?_ (pow_le_pow_left₀ (abs_nonneg _) le_sup_right _)	Mathlib/Algebra/Order/Ring/Abs.lean	166	167
/- Copyright (c) 2024 Theodore Hwa. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro, Kim Morrison, Violeta Hernández Palacios, Junyan Xu, Theodore Hwa -/ import Mathlib.Logic.Hydra import Mathlib.SetTheory.Surreal.Basic /-! ### Surreal multiplication In this file, we show that multiplication of surreal numbers is well-defined, and thus the surreal numbers form a linear ordered commutative ring. An inductive argument proves the following three main theorems: * P1: being numeric is closed under multiplication, * P2: multiplying a numeric pregame by equivalent numeric pregames results in equivalent pregames, * P3: the product of two positive numeric pregames is positive (`mul_pos`). This is Theorem 8 in [Conway2001], or Theorem 3.8 in [SchleicherStoll]. P1 allows us to define multiplication as an operation on numeric pregames, P2 says that this is well-defined as an operation on the quotient by `PGame.Equiv`, namely the surreal numbers, and P3 is an axiom that needs to be satisfied for the surreals to be a `OrderedRing`. We follow the proof in [SchleicherStoll], except that we use the well-foundedness of the hydra relation `CutExpand` on `Multiset PGame` instead of the argument based on a depth function in the paper. In the argument, P3 is stated with four variables `x₁`, `x₂`, `y₁`, `y₂` satisfying `x₁ < x₂` and `y₁ < y₂`, and says that `x₁ * y₂ + x₂ * x₁ < x₁ * y₁ + x₂ * y₂`, which is equivalent to `0 < x₂ - x₁ → 0 < y₂ - y₁ → 0 < (x₂ - x₁) * (y₂ - y₁)`, i.e. `@mul_pos PGame _ (x₂ - x₁) (y₂ - y₁)`. It has to be stated in this form and not in terms of `mul_pos` because we need to show P1, P2 and (a specialized form of) P3 simultaneously, and for example `P1 x y` will be deduced from P3 with variables taking values simpler than `x` or `y` (among other induction hypotheses), but if you subtract two pregames simpler than `x` or `y`, the result may no longer be simpler. The specialized version of P3 is called P4, which takes only three arguments `x₁`, `x₂`, `y` and requires that `y₂ = y` or `-y` and that `y₁` is a left option of `y₂`. After P1, P2 and P4 are shown, a further inductive argument (this time using the `GameAdd` relation) proves P3 in full. Implementation strategy of the inductive argument: we * extract specialized versions (`IH1`, `IH2`, `IH3`, `IH4` and `IH24`) of the induction hypothesis that are easier to apply (taking `IsOption` arguments directly), and * show they are invariant under certain symmetries (permutation and negation of arguments) and that the induction hypothesis indeed implies the specialized versions. * utilize the symmetries to minimize calculation. The whole proof features a clear separation into lemmas of different roles: * verification of symmetry properties of P and IH (`P3_comm`, `ih1_neg_left`, etc.), * calculations that connect P1, P2, P3, and inequalities between the product of two surreals and its options (`mulOption_lt_iff_P1`, etc.), * specializations of the induction hypothesis (`numeric_option_mul`, `ih1`, `ih1_swap`, `ih₁₂`, `ih4`, etc.), * application of specialized induction hypothesis (`P1_of_ih`, `mul_right_le_of_equiv`, `P3_of_lt`, etc.). ## References * [Conway, On numbers and games][Conway2001] * [Schleicher, Stoll, An introduction to Conway's games and numbers][SchleicherStoll] -/ universe u open SetTheory Game PGame WellFounded namespace Surreal.Multiplication /-- The nontrivial part of P1 in [SchleicherStoll] says that the left options of `x * y` are less than the right options, and this is the general form of these statements. -/ def P1 (x₁ x₂ x₃ y₁ y₂ y₃ : PGame) := ⟦x₁ * y₁⟧ + ⟦x₂ * y₂⟧ - ⟦x₁ * y₂⟧ < ⟦x₃ * y₁⟧ + ⟦x₂ * y₃⟧ - (⟦x₃ * y₃⟧ : Game) /-- The proposition P2, without numericity assumptions. -/ def P2 (x₁ x₂ y : PGame) := x₁ ≈ x₂ → ⟦x₁ * y⟧ = (⟦x₂ * y⟧ : Game) /-- The proposition P3, without the `x₁ < x₂` and `y₁ < y₂` assumptions. -/ def P3 (x₁ x₂ y₁ y₂ : PGame) := ⟦x₁ * y₂⟧ + ⟦x₂ * y₁⟧ < ⟦x₁ * y₁⟧ + (⟦x₂ * y₂⟧ : Game) /-- The proposition P4, without numericity assumptions. In the references, the second part of the conjunction is stated as `∀ j, P3 x₁ x₂ y (y.moveRight j)`, which is equivalent to our statement by `P3_comm` and `P3_neg`. We choose to state everything in terms of left options for uniform treatment. -/ def P4 (x₁ x₂ y : PGame) := x₁ < x₂ → (∀ i, P3 x₁ x₂ (y.moveLeft i) y) ∧ ∀ j, P3 x₁ x₂ ((-y).moveLeft j) (-y) /-- The conjunction of P2 and P4. -/ def P24 (x₁ x₂ y : PGame) : Prop := P2 x₁ x₂ y ∧ P4 x₁ x₂ y variable {x x₁ x₂ x₃ x' y y₁ y₂ y₃ y' : PGame.{u}} /-! #### Symmetry properties of P1, P2, P3, and P4 -/ lemma P3_comm : P3 x₁ x₂ y₁ y₂ ↔ P3 y₁ y₂ x₁ x₂ := by rw [P3, P3, add_comm] congr! 2 <;> rw [quot_mul_comm] lemma P3.trans (h₁ : P3 x₁ x₂ y₁ y₂) (h₂ : P3 x₂ x₃ y₁ y₂) : P3 x₁ x₃ y₁ y₂ := by rw [P3] at h₁ h₂ rw [P3, ← add_lt_add_iff_left (⟦x₂ * y₁⟧ + ⟦x₂ * y₂⟧)] convert add_lt_add h₁ h₂ using 1 <;> abel lemma P3_neg : P3 x₁ x₂ y₁ y₂ ↔ P3 (-x₂) (-x₁) y₁ y₂ := by simp_rw [P3, quot_neg_mul] rw [← _root_.neg_lt_neg_iff] abel_nf lemma P2_neg_left : P2 x₁ x₂ y ↔ P2 (-x₂) (-x₁) y := by rw [P2, P2] constructor · rw [quot_neg_mul, quot_neg_mul, eq_comm, neg_inj, neg_equiv_neg_iff, PGame.equiv_comm] exact (· ·) · rw [PGame.equiv_comm, neg_equiv_neg_iff, quot_neg_mul, quot_neg_mul, neg_inj, eq_comm] exact (· ·) lemma P2_neg_right : P2 x₁ x₂ y ↔ P2 x₁ x₂ (-y) := by rw [P2, P2, quot_mul_neg, quot_mul_neg, neg_inj] lemma P4_neg_left : P4 x₁ x₂ y ↔ P4 (-x₂) (-x₁) y := by simp_rw [P4, PGame.neg_lt_neg_iff, moveLeft_neg, ← P3_neg] lemma P4_neg_right : P4 x₁ x₂ y ↔ P4 x₁ x₂ (-y) := by rw [P4, P4, neg_neg, and_comm] lemma P24_neg_left : P24 x₁ x₂ y ↔ P24 (-x₂) (-x₁) y := by rw [P24, P24, P2_neg_left, P4_neg_left] lemma P24_neg_right : P24 x₁ x₂ y ↔ P24 x₁ x₂ (-y) := by rw [P24, P24, P2_neg_right, P4_neg_right] /-! #### Explicit calculations necessary for the main proof -/ lemma mulOption_lt_iff_P1 {i j k l} : (⟦mulOption x y i k⟧ : Game) < -⟦mulOption x (-y) j l⟧ ↔ P1 (x.moveLeft i) x (x.moveLeft j) y (y.moveLeft k) (-(-y).moveLeft l) := by dsimp only [P1, mulOption, quot_sub, quot_add] simp_rw [neg_sub', neg_add, quot_mul_neg, neg_neg] lemma mulOption_lt_mul_iff_P3 {i j} : ⟦mulOption x y i j⟧ < (⟦x * y⟧ : Game) ↔ P3 (x.moveLeft i) x (y.moveLeft j) y := by dsimp only [mulOption, quot_sub, quot_add] exact sub_lt_iff_lt_add' lemma P1_of_eq (he : x₁ ≈ x₃) (h₁ : P2 x₁ x₃ y₁) (h₃ : P2 x₁ x₃ y₃) (h3 : P3 x₁ x₂ y₂ y₃) : P1 x₁ x₂ x₃ y₁ y₂ y₃ := by rw [P1, ← h₁ he, ← h₃ he, sub_lt_sub_iff] convert add_lt_add_left h3 ⟦x₁ * y₁⟧ using 1 <;> abel lemma P1_of_lt (h₁ : P3 x₃ x₂ y₂ y₃) (h₂ : P3 x₁ x₃ y₂ y₁) : P1 x₁ x₂ x₃ y₁ y₂ y₃ := by rw [P1, sub_lt_sub_iff, ← add_lt_add_iff_left ⟦x₃ * y₂⟧] convert add_lt_add h₁ h₂ using 1 <;> abel /-- The type of lists of arguments for P1, P2, and P4. -/ inductive Args : Type (u + 1) \| P1 (x y : PGame.{u}) : Args \| P24 (x₁ x₂ y : PGame.{u}) : Args /-- The multiset associated to a list of arguments. -/ def Args.toMultiset : Args → Multiset PGame \| (Args.P1 x y) => {x, y} \| (Args.P24 x₁ x₂ y) => {x₁, x₂, y} /-- A list of arguments is numeric if all the arguments are. -/ def Args.Numeric (a : Args) := ∀ x ∈ a.toMultiset, SetTheory.PGame.Numeric x lemma Args.numeric_P1 {x y} : (Args.P1 x y).Numeric ↔ x.Numeric ∧ y.Numeric := by simp [Args.Numeric, Args.toMultiset] lemma Args.numeric_P24 {x₁ x₂ y} : (Args.P24 x₁ x₂ y).Numeric ↔ x₁.Numeric ∧ x₂.Numeric ∧ y.Numeric := by simp [Args.Numeric, Args.toMultiset] open Relation /-- The relation specifying when a list of (pregame) arguments is considered simpler than another: `ArgsRel a₁ a₂` is true if `a₁`, considered as a multiset, can be obtained from `a₂` by repeatedly removing a pregame from `a₂` and adding back one or two options of the pregame. -/ def ArgsRel := InvImage (TransGen <\| CutExpand IsOption) Args.toMultiset /-- `ArgsRel` is well-founded. -/ theorem argsRel_wf : WellFounded ArgsRel := InvImage.wf _ wf_isOption.cutExpand.transGen /-- The statement that we will show by induction using the well-founded relation `ArgsRel`. -/ def P124 : Args → Prop \| (Args.P1 x y) => Numeric (x * y) \| (Args.P24 x₁ x₂ y) => P24 x₁ x₂ y /-- The property that all arguments are numeric is leftward-closed under `ArgsRel`. -/ lemma ArgsRel.numeric_closed {a' a} : ArgsRel a' a → a.Numeric → a'.Numeric := TransGen.closed' <\| @cutExpand_closed _ IsOption ⟨wf_isOption.isIrrefl.1⟩ _ Numeric.isOption /-- A specialized induction hypothesis used to prove P1. -/ def IH1 (x y : PGame) : Prop := ∀ ⦃x₁ x₂ y'⦄, IsOption x₁ x → IsOption x₂ x → (y' = y ∨ IsOption y' y) → P24 x₁ x₂ y' /-! #### Symmetry properties of `IH1` -/ lemma ih1_neg_left : IH1 x y → IH1 (-x) y := fun h x₁ x₂ y' h₁ h₂ hy ↦ by rw [isOption_neg] at h₁ h₂ exact P24_neg_left.2 (h h₂ h₁ hy) lemma ih1_neg_right : IH1 x y → IH1 x (-y) := fun h x₁ x₂ y' ↦ by rw [← neg_eq_iff_eq_neg, isOption_neg, P24_neg_right] apply h /-! #### Specialize `ih` to obtain specialized induction hypotheses for P1 -/ lemma numeric_option_mul (ih : ∀ a, ArgsRel a (Args.P1 x y) → P124 a) (h : IsOption x' x) : (x' * y).Numeric := ih (Args.P1 x' y) (TransGen.single <\| cutExpand_pair_left h) lemma numeric_mul_option (ih : ∀ a, ArgsRel a (Args.P1 x y) → P124 a) (h : IsOption y' y) : (x * y').Numeric := ih (Args.P1 x y') (TransGen.single <\| cutExpand_pair_right h) lemma numeric_option_mul_option (ih : ∀ a, ArgsRel a (Args.P1 x y) → P124 a) (hx : IsOption x' x) (hy : IsOption y' y) : (x' * y').Numeric := ih (Args.P1 x' y') ((TransGen.single <\| cutExpand_pair_right hy).tail <\| cutExpand_pair_left hx) lemma ih1 (ih : ∀ a, ArgsRel a (Args.P1 x y) → P124 a) : IH1 x y := by rintro x₁ x₂ y' h₁ h₂ (rfl\|hy) <;> apply ih (Args.P24 _ _ _) on_goal 2 => refine TransGen.tail ?_ (cutExpand_pair_right hy) all_goals exact TransGen.single (cutExpand_double_left h₁ h₂) lemma ih1_swap (ih : ∀ a, ArgsRel a (Args.P1 x y) → P124 a) : IH1 y x := ih1 <\| by simp_rw [ArgsRel, InvImage, Args.toMultiset, Multiset.pair_comm] at ih ⊢ exact ih lemma P3_of_ih (hy : Numeric y) (ihyx : IH1 y x) (i k l) : P3 (x.moveLeft i) x (y.moveLeft k) (-(-y).moveLeft l) := P3_comm.2 <\| ((ihyx (IsOption.moveLeft k) (isOption_neg.1 <\| .moveLeft l) <\| Or.inl rfl).2 (by rw [moveLeft_neg, neg_neg]; apply hy.left_lt_right)).1 i lemma P24_of_ih (ihxy : IH1 x y) (i j) : P24 (x.moveLeft i) (x.moveLeft j) y := ihxy (IsOption.moveLeft i) (IsOption.moveLeft j) (Or.inl rfl) section lemma mulOption_lt_of_lt (hy : y.Numeric) (ihxy : IH1 x y) (ihyx : IH1 y x) (i j k l) (h : x.moveLeft i < x.moveLeft j) : (⟦mulOption x y i k⟧ : Game) < -⟦mulOption x (-y) j l⟧ := mulOption_lt_iff_P1.2 <\| P1_of_lt (P3_of_ih hy ihyx j k l) <\| ((P24_of_ih ihxy i j).2 h).1 k lemma mulOption_lt (hx : x.Numeric) (hy : y.Numeric) (ihxy : IH1 x y) (ihyx : IH1 y x) (i j k l) : (⟦mulOption x y i k⟧ : Game) < -⟦mulOption x (-y) j l⟧ := by	obtain (h\|h\|h) := lt_or_equiv_or_gt (hx.moveLeft i) (hx.moveLeft j) · exact mulOption_lt_of_lt hy ihxy ihyx i j k l h · have ml := @IsOption.moveLeft exact mulOption_lt_iff_P1.2 (P1_of_eq h (P24_of_ih ihxy i j).1 (ihxy (ml i) (ml j) <\| Or.inr <\| isOption_neg.1 <\| ml l).1 <\| P3_of_ih hy ihyx i k l) · rw [mulOption_neg_neg, lt_neg] exact mulOption_lt_of_lt hy.neg (ih1_neg_right ihxy) (ih1_neg_left ihyx) j i l _ h	Mathlib/SetTheory/Surreal/Multiplication.lean	247	254
/- Copyright (c) 2020 Johan Commelin. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johan Commelin -/ import Mathlib.RingTheory.WittVector.Frobenius import Mathlib.RingTheory.WittVector.Verschiebung import Mathlib.RingTheory.WittVector.MulP /-! ## Identities between operations on the ring of Witt vectors In this file we derive common identities between the Frobenius and Verschiebung operators. ## Main declarations * `frobenius_verschiebung`: the composition of Frobenius and Verschiebung is multiplication by `p` * `verschiebung_mul_frobenius`: the “projection formula”: `V(x * F y) = V x * y` * `iterate_verschiebung_mul_coeff`: an identity from [Haze09] 6.2 ## References * [Hazewinkel, Witt Vectors][Haze09] * [Commelin and Lewis, Formalizing the Ring of Witt Vectors][CL21] -/ namespace WittVector variable {p : ℕ} {R : Type} [hp : Fact p.Prime] [CommRing R] -- type as `\bbW` local notation "𝕎" => WittVector p noncomputable section -- Porting note: `ghost_calc` failure: `simp only []` and the manual instances had to be added. /-- The composition of Frobenius and Verschiebung is multiplication by `p`. -/ theorem frobenius_verschiebung (x : 𝕎 R) : frobenius (verschiebung x) = x p := by have : IsPoly p fun {R} [CommRing R] x ↦ frobenius (verschiebung x) := IsPoly.comp (hg := frobenius_isPoly p) (hf := verschiebung_isPoly) have : IsPoly p fun {R} [CommRing R] x ↦ x * p := mulN_isPoly p p ghost_calc x ghost_simp [mul_comm] /-- Verschiebung is the same as multiplication by `p` on the ring of Witt vectors of `ZMod p`. -/ theorem verschiebung_zmod (x : 𝕎 (ZMod p)) : verschiebung x = x * p := by rw [← frobenius_verschiebung, frobenius_zmodp] variable (p R) theorem coeff_p_pow [CharP R p] (i : ℕ) : ((p : 𝕎 R) ^ i).coeff i = 1 := by induction' i with i h · simp only [one_coeff_zero, Ne, pow_zero] · rw [pow_succ, ← frobenius_verschiebung, coeff_frobenius_charP, verschiebung_coeff_succ, h, one_pow] theorem coeff_p_pow_eq_zero [CharP R p] {i j : ℕ} (hj : j ≠ i) : ((p : 𝕎 R) ^ i).coeff j = 0 := by induction' i with i hi generalizing j · rw [pow_zero, one_coeff_eq_of_pos] exact Nat.pos_of_ne_zero hj · rw [pow_succ, ← frobenius_verschiebung, coeff_frobenius_charP] cases j · rw [verschiebung_coeff_zero, zero_pow hp.out.ne_zero] · rw [verschiebung_coeff_succ, hi (ne_of_apply_ne _ hj), zero_pow hp.out.ne_zero] theorem coeff_p [CharP R p] (i : ℕ) : (p : 𝕎 R).coeff i = if i = 1 then 1 else 0 := by split_ifs with hi · simpa only [hi, pow_one] using coeff_p_pow p R 1 · simpa only [pow_one] using coeff_p_pow_eq_zero p R hi @[simp] theorem coeff_p_zero [CharP R p] : (p : 𝕎 R).coeff 0 = 0 := by rw [coeff_p, if_neg] exact zero_ne_one @[simp] theorem coeff_p_one [CharP R p] : (p : 𝕎 R).coeff 1 = 1 := by rw [coeff_p, if_pos rfl] theorem p_nonzero [Nontrivial R] [CharP R p] : (p : 𝕎 R) ≠ 0 := by intro h simpa only [h, zero_coeff, zero_ne_one] using coeff_p_one p R theorem FractionRing.p_nonzero [Nontrivial R] [CharP R p] : (p : FractionRing (𝕎 R)) ≠ 0 := by simpa using (IsFractionRing.injective (𝕎 R) (FractionRing (𝕎 R))).ne (WittVector.p_nonzero _ _) variable {p R} -- Porting note: `ghost_calc` failure: `simp only []` and the manual instances had to be added. /-- The “projection formula” for Frobenius and Verschiebung. -/ theorem verschiebung_mul_frobenius (x y : 𝕎 R) : verschiebung (x * frobenius y) = verschiebung x * y := by have : IsPoly₂ p fun {R} [Rcr : CommRing R] x y ↦ verschiebung (x * frobenius y) := IsPoly.comp₂ (hg := verschiebung_isPoly) (hf := IsPoly₂.comp (hh := mulIsPoly₂) (hf := idIsPolyI' p) (hg := frobenius_isPoly p)) have : IsPoly₂ p fun {R} [CommRing R] x y ↦ verschiebung x * y := IsPoly₂.comp (hh := mulIsPoly₂) (hf := verschiebung_isPoly) (hg := idIsPolyI' p) ghost_calc x y rintro ⟨⟩ <;> ghost_simp [mul_assoc] theorem mul_charP_coeff_zero [CharP R p] (x : 𝕎 R) : (x * p).coeff 0 = 0 := by rw [← frobenius_verschiebung, coeff_frobenius_charP, verschiebung_coeff_zero, zero_pow hp.out.ne_zero] theorem mul_charP_coeff_succ [CharP R p] (x : 𝕎 R) (i : ℕ) : (x * p).coeff (i + 1) = x.coeff i ^ p := by rw [← frobenius_verschiebung, coeff_frobenius_charP, verschiebung_coeff_succ] theorem mul_pow_charP_coeff_zero [CharP R p] (x : 𝕎 R) {m n : ℕ} (h : m < n) : (x * p ^ n).coeff m = 0 := by induction' n with n ih generalizing m · contradiction · rw [pow_succ, ← mul_assoc] cases m with \| zero => exact mul_charP_coeff_zero _ \| succ m' => rw [mul_charP_coeff_succ, ih, zero_pow hp.out.ne_zero] simpa using h theorem mul_pow_charP_coeff_succ [CharP R p] (x : 𝕎 R) {m n : ℕ} : (x * p ^ n).coeff (m + n) = x.coeff m ^ (p ^ n) := by induction' n with n ih generalizing m · simp · rw [pow_succ, ← mul_assoc, ← add_assoc,mul_charP_coeff_succ, pow_succ, pow_mul] congr exact ih theorem verschiebung_frobenius [CharP R p] (x : 𝕎 R) : verschiebung (frobenius x) = x * p := by ext ⟨i⟩ · rw [mul_charP_coeff_zero, verschiebung_coeff_zero] · rw [mul_charP_coeff_succ, verschiebung_coeff_succ, coeff_frobenius_charP] theorem verschiebung_frobenius_comm [CharP R p] : Function.Commute (verschiebung : 𝕎 R → 𝕎 R) frobenius := fun x => by rw [verschiebung_frobenius, frobenius_verschiebung] /-! ## Iteration lemmas -/ open Function theorem iterate_verschiebung_coeff_eq_zero (x : 𝕎 R) {n : ℕ} {m : ℕ} (h : m < n) : (verschiebung^[n] x).coeff m = 0 := by induction' n with n ih generalizing m · contradiction · rw [iterate_succ_apply'] cases m with \| zero => exact verschiebung_coeff_zero _ \| succ m' => rw [verschiebung_coeff_succ, ih] simpa using h theorem iterate_verschiebung_coeff (x : 𝕎 R) (n k : ℕ) : (verschiebung^[n] x).coeff (k + n) = x.coeff k := by induction' n with k ih · simp · rw [iterate_succ_apply', Nat.add_succ, verschiebung_coeff_succ] exact ih theorem iterate_verschiebung_mul_left (x y : 𝕎 R) (i : ℕ) : verschiebung^[i] x * y = verschiebung^[i] (x * frobenius^[i] y) := by induction' i with i ih generalizing y · simp · rw [iterate_succ_apply', ← verschiebung_mul_frobenius, ih, iterate_succ_apply']; rfl section CharP variable [CharP R p] theorem iterate_verschiebung_mul (x y : 𝕎 R) (i j : ℕ) : verschiebung^[i] x * verschiebung^[j] y = verschiebung^[i + j] (frobenius^[j] x * frobenius^[i] y) := by calc _ = verschiebung^[i] (x * frobenius^[i] (verschiebung^[j] y)) := ?_ _ = verschiebung^[i] (x * verschiebung^[j] (frobenius^[i] y)) := ?_ _ = verschiebung^[i] (verschiebung^[j] (frobenius^[i] y) * x) := ?_ _ = verschiebung^[i] (verschiebung^[j] (frobenius^[i] y * frobenius^[j] x)) := ?_ _ = verschiebung^[i + j] (frobenius^[i] y * frobenius^[j] x) := ?_ _ = _ := ?_ · apply iterate_verschiebung_mul_left · rw [verschiebung_frobenius_comm.iterate_iterate] · rw [mul_comm] · rw [iterate_verschiebung_mul_left] · rw [iterate_add_apply] · rw [mul_comm]	-- Porting note: `ring_nf` doesn't handle powers yet; needed to add `Nat.pow_succ` rewrite theorem iterate_frobenius_coeff (x : 𝕎 R) (i k : ℕ) : (frobenius^[i] x).coeff k = x.coeff k ^ p ^ i := by induction' i with i ih · simp · rw [iterate_succ_apply', coeff_frobenius_charP, ih, Nat.pow_succ] ring_nf /-- This is a slightly specialized form of [Hazewinkel, Witt Vectors][Haze09] 6.2 equation 5. -/ theorem iterate_verschiebung_mul_coeff (x y : 𝕎 R) (i j : ℕ) : (verschiebung^[i] x * verschiebung^[j] y).coeff (i + j) = x.coeff 0 ^ p ^ j * y.coeff 0 ^ p ^ i := by	Mathlib/RingTheory/WittVector/Identities.lean	189	201
/- Copyright (c) 2018 Chris Hughes. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Chris Hughes, Abhimanyu Pallavi Sudhir -/ import Mathlib.Algebra.CharP.Defs import Mathlib.Algebra.Order.CauSeq.BigOperators import Mathlib.Algebra.Order.Star.Basic import Mathlib.Data.Complex.BigOperators import Mathlib.Data.Complex.Norm import Mathlib.Data.Nat.Choose.Sum /-! # Exponential Function This file contains the definitions of the real and complex exponential function. ## Main definitions * `Complex.exp`: The complex exponential function, defined via its Taylor series * `Real.exp`: The real exponential function, defined as the real part of the complex exponential -/ open CauSeq Finset IsAbsoluteValue open scoped ComplexConjugate namespace Complex theorem isCauSeq_norm_exp (z : ℂ) : IsCauSeq abs fun n => ∑ m ∈ range n, ‖z ^ m / m.factorial‖ := let ⟨n, hn⟩ := exists_nat_gt ‖z‖ have hn0 : (0 : ℝ) < n := lt_of_le_of_lt (norm_nonneg _) hn IsCauSeq.series_ratio_test n (‖z‖ / n) (div_nonneg (norm_nonneg _) (le_of_lt hn0)) (by rwa [div_lt_iff₀ hn0, one_mul]) fun m hm => by rw [abs_norm, abs_norm, Nat.factorial_succ, pow_succ', mul_comm m.succ, Nat.cast_mul, ← div_div, mul_div_assoc, mul_div_right_comm, Complex.norm_mul, Complex.norm_div, norm_natCast] gcongr exact le_trans hm (Nat.le_succ _) @[deprecated (since := "2025-02-16")] alias isCauSeq_abs_exp := isCauSeq_norm_exp noncomputable section theorem isCauSeq_exp (z : ℂ) : IsCauSeq (‖·‖) fun n => ∑ m ∈ range n, z ^ m / m.factorial := (isCauSeq_norm_exp z).of_abv /-- The Cauchy sequence consisting of partial sums of the Taylor series of the complex exponential function -/ @[pp_nodot] def exp' (z : ℂ) : CauSeq ℂ (‖·‖) := ⟨fun n => ∑ m ∈ range n, z ^ m / m.factorial, isCauSeq_exp z⟩ /-- The complex exponential function, defined via its Taylor series -/ @[pp_nodot] def exp (z : ℂ) : ℂ := CauSeq.lim (exp' z) /-- scoped notation for the complex exponential function -/ scoped notation "cexp" => Complex.exp end end Complex namespace Real open Complex noncomputable section /-- The real exponential function, defined as the real part of the complex exponential -/ @[pp_nodot] nonrec def exp (x : ℝ) : ℝ := (exp x).re /-- scoped notation for the real exponential function -/ scoped notation "rexp" => Real.exp end end Real namespace Complex variable (x y : ℂ) @[simp] theorem exp_zero : exp 0 = 1 := by rw [exp] refine lim_eq_of_equiv_const fun ε ε0 => ⟨1, fun j hj => ?_⟩ convert (config := .unfoldSameFun) ε0 -- ε0 : ε > 0 but goal is _ < ε rcases j with - \| j · exact absurd hj (not_le_of_gt zero_lt_one) · dsimp [exp'] induction' j with j ih · dsimp [exp']; simp [show Nat.succ 0 = 1 from rfl] · rw [← ih (by simp [Nat.succ_le_succ])] simp only [sum_range_succ, pow_succ] simp theorem exp_add : exp (x + y) = exp x * exp y := by have hj : ∀ j : ℕ, (∑ m ∈ range j, (x + y) ^ m / m.factorial) = ∑ i ∈ range j, ∑ k ∈ range (i + 1), x ^ k / k.factorial * (y ^ (i - k) / (i - k).factorial) := by intro j refine Finset.sum_congr rfl fun m _ => ?_ rw [add_pow, div_eq_mul_inv, sum_mul] refine Finset.sum_congr rfl fun I hi => ?_ have h₁ : (m.choose I : ℂ) ≠ 0 := Nat.cast_ne_zero.2 (pos_iff_ne_zero.1 (Nat.choose_pos (Nat.le_of_lt_succ (mem_range.1 hi)))) have h₂ := Nat.choose_mul_factorial_mul_factorial (Nat.le_of_lt_succ <\| Finset.mem_range.1 hi) rw [← h₂, Nat.cast_mul, Nat.cast_mul, mul_inv, mul_inv] simp only [mul_left_comm (m.choose I : ℂ), mul_assoc, mul_left_comm (m.choose I : ℂ)⁻¹, mul_comm (m.choose I : ℂ)] rw [inv_mul_cancel₀ h₁] simp [div_eq_mul_inv, mul_comm, mul_assoc, mul_left_comm] simp_rw [exp, exp', lim_mul_lim] apply (lim_eq_lim_of_equiv _).symm simp only [hj] exact cauchy_product (isCauSeq_norm_exp x) (isCauSeq_exp y) /-- the exponential function as a monoid hom from `Multiplicative ℂ` to `ℂ` -/ @[simps] noncomputable def expMonoidHom : MonoidHom (Multiplicative ℂ) ℂ := { toFun := fun z => exp z.toAdd, map_one' := by simp, map_mul' := by simp [exp_add] } theorem exp_list_sum (l : List ℂ) : exp l.sum = (l.map exp).prod := map_list_prod (M := Multiplicative ℂ) expMonoidHom l theorem exp_multiset_sum (s : Multiset ℂ) : exp s.sum = (s.map exp).prod := @MonoidHom.map_multiset_prod (Multiplicative ℂ) ℂ _ _ expMonoidHom s theorem exp_sum {α : Type} (s : Finset α) (f : α → ℂ) : exp (∑ x ∈ s, f x) = ∏ x ∈ s, exp (f x) := map_prod (β := Multiplicative ℂ) expMonoidHom f s lemma exp_nsmul (x : ℂ) (n : ℕ) : exp (n • x) = exp x ^ n := @MonoidHom.map_pow (Multiplicative ℂ) ℂ _ _ expMonoidHom _ _ theorem exp_nat_mul (x : ℂ) : ∀ n : ℕ, exp (n x) = exp x ^ n \| 0 => by rw [Nat.cast_zero, zero_mul, exp_zero, pow_zero] \| Nat.succ n => by rw [pow_succ, Nat.cast_add_one, add_mul, exp_add, ← exp_nat_mul _ n, one_mul] @[simp] theorem exp_ne_zero : exp x ≠ 0 := fun h => zero_ne_one (α := ℂ) <\| by rw [← exp_zero, ← add_neg_cancel x, exp_add, h]; simp theorem exp_neg : exp (-x) = (exp x)⁻¹ := by rw [← mul_right_inj' (exp_ne_zero x), ← exp_add]; simp [mul_inv_cancel₀ (exp_ne_zero x)] theorem exp_sub : exp (x - y) = exp x / exp y := by simp [sub_eq_add_neg, exp_add, exp_neg, div_eq_mul_inv] theorem exp_int_mul (z : ℂ) (n : ℤ) : Complex.exp (n * z) = Complex.exp z ^ n := by cases n · simp [exp_nat_mul] · simp [exp_add, add_mul, pow_add, exp_neg, exp_nat_mul] @[simp] theorem exp_conj : exp (conj x) = conj (exp x) := by dsimp [exp] rw [← lim_conj] refine congr_arg CauSeq.lim (CauSeq.ext fun _ => ?_) dsimp [exp', Function.comp_def, cauSeqConj] rw [map_sum (starRingEnd _)] refine sum_congr rfl fun n _ => ?_ rw [map_div₀, map_pow, ← ofReal_natCast, conj_ofReal] @[simp] theorem ofReal_exp_ofReal_re (x : ℝ) : ((exp x).re : ℂ) = exp x := conj_eq_iff_re.1 <\| by rw [← exp_conj, conj_ofReal] @[simp, norm_cast] theorem ofReal_exp (x : ℝ) : (Real.exp x : ℂ) = exp x := ofReal_exp_ofReal_re _ @[simp] theorem exp_ofReal_im (x : ℝ) : (exp x).im = 0 := by rw [← ofReal_exp_ofReal_re, ofReal_im] theorem exp_ofReal_re (x : ℝ) : (exp x).re = Real.exp x := rfl end Complex namespace Real open Complex variable (x y : ℝ) @[simp] theorem exp_zero : exp 0 = 1 := by simp [Real.exp] nonrec theorem exp_add : exp (x + y) = exp x * exp y := by simp [exp_add, exp] /-- the exponential function as a monoid hom from `Multiplicative ℝ` to `ℝ` -/ @[simps] noncomputable def expMonoidHom : MonoidHom (Multiplicative ℝ) ℝ := { toFun := fun x => exp x.toAdd, map_one' := by simp, map_mul' := by simp [exp_add] } theorem exp_list_sum (l : List ℝ) : exp l.sum = (l.map exp).prod := map_list_prod (M := Multiplicative ℝ) expMonoidHom l theorem exp_multiset_sum (s : Multiset ℝ) : exp s.sum = (s.map exp).prod := @MonoidHom.map_multiset_prod (Multiplicative ℝ) ℝ _ _ expMonoidHom s theorem exp_sum {α : Type} (s : Finset α) (f : α → ℝ) : exp (∑ x ∈ s, f x) = ∏ x ∈ s, exp (f x) := map_prod (β := Multiplicative ℝ) expMonoidHom f s lemma exp_nsmul (x : ℝ) (n : ℕ) : exp (n • x) = exp x ^ n := @MonoidHom.map_pow (Multiplicative ℝ) ℝ _ _ expMonoidHom _ _ nonrec theorem exp_nat_mul (x : ℝ) (n : ℕ) : exp (n x) = exp x ^ n := ofReal_injective (by simp [exp_nat_mul]) @[simp] nonrec theorem exp_ne_zero : exp x ≠ 0 := fun h => exp_ne_zero x <\| by rw [exp, ← ofReal_inj] at h; simp_all nonrec theorem exp_neg : exp (-x) = (exp x)⁻¹ := ofReal_injective <\| by simp [exp_neg] theorem exp_sub : exp (x - y) = exp x / exp y := by simp [sub_eq_add_neg, exp_add, exp_neg, div_eq_mul_inv] open IsAbsoluteValue Nat theorem sum_le_exp_of_nonneg {x : ℝ} (hx : 0 ≤ x) (n : ℕ) : ∑ i ∈ range n, x ^ i / i ! ≤ exp x := calc ∑ i ∈ range n, x ^ i / i ! ≤ lim (⟨_, isCauSeq_re (exp' x)⟩ : CauSeq ℝ abs) := by refine le_lim (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩) simp only [exp', const_apply, re_sum] norm_cast refine sum_le_sum_of_subset_of_nonneg (range_mono hj) fun _ _ _ ↦ ?_ positivity _ = exp x := by rw [exp, Complex.exp, ← cauSeqRe, lim_re] lemma pow_div_factorial_le_exp (hx : 0 ≤ x) (n : ℕ) : x ^ n / n ! ≤ exp x := calc x ^ n / n ! ≤ ∑ k ∈ range (n + 1), x ^ k / k ! := single_le_sum (f := fun k ↦ x ^ k / k !) (fun k _ ↦ by positivity) (self_mem_range_succ n) _ ≤ exp x := sum_le_exp_of_nonneg hx _ theorem quadratic_le_exp_of_nonneg {x : ℝ} (hx : 0 ≤ x) : 1 + x + x ^ 2 / 2 ≤ exp x := calc 1 + x + x ^ 2 / 2 = ∑ i ∈ range 3, x ^ i / i ! := by simp only [sum_range_succ, range_one, sum_singleton, _root_.pow_zero, factorial, cast_one, ne_eq, one_ne_zero, not_false_eq_true, div_self, pow_one, mul_one, div_one, Nat.mul_one, cast_succ, add_right_inj] ring_nf _ ≤ exp x := sum_le_exp_of_nonneg hx 3 private theorem add_one_lt_exp_of_pos {x : ℝ} (hx : 0 < x) : x + 1 < exp x := (by nlinarith : x + 1 < 1 + x + x ^ 2 / 2).trans_le (quadratic_le_exp_of_nonneg hx.le) private theorem add_one_le_exp_of_nonneg {x : ℝ} (hx : 0 ≤ x) : x + 1 ≤ exp x := by rcases eq_or_lt_of_le hx with (rfl \| h) · simp exact (add_one_lt_exp_of_pos h).le theorem one_le_exp {x : ℝ} (hx : 0 ≤ x) : 1 ≤ exp x := by linarith [add_one_le_exp_of_nonneg hx] @[bound] theorem exp_pos (x : ℝ) : 0 < exp x := (le_total 0 x).elim (lt_of_lt_of_le zero_lt_one ∘ one_le_exp) fun h => by rw [← neg_neg x, Real.exp_neg] exact inv_pos.2 (lt_of_lt_of_le zero_lt_one (one_le_exp (neg_nonneg.2 h))) @[bound] lemma exp_nonneg (x : ℝ) : 0 ≤ exp x := x.exp_pos.le @[simp] theorem abs_exp (x : ℝ) : \|exp x\| = exp x := abs_of_pos (exp_pos _) lemma exp_abs_le (x : ℝ) : exp \|x\| ≤ exp x + exp (-x) := by cases le_total x 0 <;> simp [abs_of_nonpos, abs_of_nonneg, exp_nonneg, ] @[mono] theorem exp_strictMono : StrictMono exp := fun x y h => by rw [← sub_add_cancel y x, Real.exp_add] exact (lt_mul_iff_one_lt_left (exp_pos _)).2 (lt_of_lt_of_le (by linarith) (add_one_le_exp_of_nonneg (by linarith))) @[gcongr] theorem exp_lt_exp_of_lt {x y : ℝ} (h : x < y) : exp x < exp y := exp_strictMono h @[mono] theorem exp_monotone : Monotone exp := exp_strictMono.monotone @[gcongr, bound] theorem exp_le_exp_of_le {x y : ℝ} (h : x ≤ y) : exp x ≤ exp y := exp_monotone h @[simp] theorem exp_lt_exp {x y : ℝ} : exp x < exp y ↔ x < y := exp_strictMono.lt_iff_lt @[simp] theorem exp_le_exp {x y : ℝ} : exp x ≤ exp y ↔ x ≤ y := exp_strictMono.le_iff_le theorem exp_injective : Function.Injective exp := exp_strictMono.injective @[simp] theorem exp_eq_exp {x y : ℝ} : exp x = exp y ↔ x = y := exp_injective.eq_iff @[simp] theorem exp_eq_one_iff : exp x = 1 ↔ x = 0 := exp_injective.eq_iff' exp_zero @[simp] theorem one_lt_exp_iff {x : ℝ} : 1 < exp x ↔ 0 < x := by rw [← exp_zero, exp_lt_exp] @[bound] private alias ⟨_, Bound.one_lt_exp_of_pos⟩ := one_lt_exp_iff @[simp] theorem exp_lt_one_iff {x : ℝ} : exp x < 1 ↔ x < 0 := by rw [← exp_zero, exp_lt_exp] @[simp] theorem exp_le_one_iff {x : ℝ} : exp x ≤ 1 ↔ x ≤ 0 := exp_zero ▸ exp_le_exp @[simp] theorem one_le_exp_iff {x : ℝ} : 1 ≤ exp x ↔ 0 ≤ x := exp_zero ▸ exp_le_exp end Real namespace Complex theorem sum_div_factorial_le {α : Type} [Field α] [LinearOrder α] [IsStrictOrderedRing α] (n j : ℕ) (hn : 0 < n) : (∑ m ∈ range j with n ≤ m, (1 / m.factorial : α)) ≤ n.succ / (n.factorial * n) := calc (∑ m ∈ range j with n ≤ m, (1 / m.factorial : α)) = ∑ m ∈ range (j - n), (1 / ((m + n).factorial : α)) := by refine sum_nbij' (· - n) (· + n) ?_ ?_ ?_ ?_ ?_ <;> simp +contextual [lt_tsub_iff_right, tsub_add_cancel_of_le] _ ≤ ∑ m ∈ range (j - n), ((n.factorial : α) * (n.succ : α) ^ m)⁻¹ := by simp_rw [one_div] gcongr rw [← Nat.cast_pow, ← Nat.cast_mul, Nat.cast_le, add_comm] exact Nat.factorial_mul_pow_le_factorial _ = (n.factorial : α)⁻¹ * ∑ m ∈ range (j - n), (n.succ : α)⁻¹ ^ m := by simp [mul_inv, ← mul_sum, ← sum_mul, mul_comm, inv_pow] _ = ((n.succ : α) - n.succ * (n.succ : α)⁻¹ ^ (j - n)) / (n.factorial * n) := by have h₁ : (n.succ : α) ≠ 1 := @Nat.cast_one α _ ▸ mt Nat.cast_inj.1 (mt Nat.succ.inj (pos_iff_ne_zero.1 hn)) have h₂ : (n.succ : α) ≠ 0 := by positivity have h₃ : (n.factorial * n : α) ≠ 0 := by positivity have h₄ : (n.succ - 1 : α) = n := by simp rw [geom_sum_inv h₁ h₂, eq_div_iff_mul_eq h₃, mul_comm _ (n.factorial * n : α), ← mul_assoc (n.factorial⁻¹ : α), ← mul_inv_rev, h₄, ← mul_assoc (n.factorial * n : α), mul_comm (n : α) n.factorial, mul_inv_cancel₀ h₃, one_mul, mul_comm] _ ≤ n.succ / (n.factorial * n : α) := by gcongr; apply sub_le_self; positivity theorem exp_bound {x : ℂ} (hx : ‖x‖ ≤ 1) {n : ℕ} (hn : 0 < n) : ‖exp x - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ ‖x‖ ^ n * ((n.succ : ℝ) * (n.factorial * n : ℝ)⁻¹) := by rw [← lim_const (abv := norm) (∑ m ∈ range n, _), exp, sub_eq_add_neg, ← lim_neg, lim_add, ← lim_norm] refine lim_le (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩) simp_rw [← sub_eq_add_neg] show ‖(∑ m ∈ range j, x ^ m / m.factorial) - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ ‖x‖ ^ n * ((n.succ : ℝ) * (n.factorial * n : ℝ)⁻¹) rw [sum_range_sub_sum_range hj] calc ‖∑ m ∈ range j with n ≤ m, (x ^ m / m.factorial : ℂ)‖ = ‖∑ m ∈ range j with n ≤ m, (x ^ n * (x ^ (m - n) / m.factorial) : ℂ)‖ := by refine congr_arg norm (sum_congr rfl fun m hm => ?_) rw [mem_filter, mem_range] at hm rw [← mul_div_assoc, ← pow_add, add_tsub_cancel_of_le hm.2] _ ≤ ∑ m ∈ range j with n ≤ m, ‖x ^ n * (x ^ (m - n) / m.factorial)‖ := IsAbsoluteValue.abv_sum norm .. _ ≤ ∑ m ∈ range j with n ≤ m, ‖x‖ ^ n * (1 / m.factorial) := by simp_rw [Complex.norm_mul, Complex.norm_pow, Complex.norm_div, norm_natCast] gcongr rw [Complex.norm_pow] exact pow_le_one₀ (norm_nonneg _) hx _ = ‖x‖ ^ n * ∑ m ∈ range j with n ≤ m, (1 / m.factorial : ℝ) := by simp [abs_mul, abv_pow abs, abs_div, ← mul_sum] _ ≤ ‖x‖ ^ n * (n.succ * (n.factorial * n : ℝ)⁻¹) := by gcongr exact sum_div_factorial_le _ _ hn theorem exp_bound' {x : ℂ} {n : ℕ} (hx : ‖x‖ / n.succ ≤ 1 / 2) : ‖exp x - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ ‖x‖ ^ n / n.factorial * 2 := by rw [← lim_const (abv := norm) (∑ m ∈ range n, _), exp, sub_eq_add_neg, ← lim_neg, lim_add, ← lim_norm] refine lim_le (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩) simp_rw [← sub_eq_add_neg] show ‖(∑ m ∈ range j, x ^ m / m.factorial) - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ ‖x‖ ^ n / n.factorial * 2 let k := j - n have hj : j = n + k := (add_tsub_cancel_of_le hj).symm rw [hj, sum_range_add_sub_sum_range] calc ‖∑ i ∈ range k, x ^ (n + i) / ((n + i).factorial : ℂ)‖ ≤ ∑ i ∈ range k, ‖x ^ (n + i) / ((n + i).factorial : ℂ)‖ := IsAbsoluteValue.abv_sum _ _ _ _ ≤ ∑ i ∈ range k, ‖x‖ ^ (n + i) / (n + i).factorial := by simp [norm_natCast, Complex.norm_pow] _ ≤ ∑ i ∈ range k, ‖x‖ ^ (n + i) / ((n.factorial : ℝ) * (n.succ : ℝ) ^ i) := ?_ _ = ∑ i ∈ range k, ‖x‖ ^ n / n.factorial * (‖x‖ ^ i / (n.succ : ℝ) ^ i) := ?_ _ ≤ ‖x‖ ^ n / ↑n.factorial * 2 := ?_ · gcongr exact mod_cast Nat.factorial_mul_pow_le_factorial · refine Finset.sum_congr rfl fun _ _ => ?_ simp only [pow_add, div_eq_inv_mul, mul_inv, mul_left_comm, mul_assoc] · rw [← mul_sum] gcongr simp_rw [← div_pow] rw [geom_sum_eq, div_le_iff_of_neg] · trans (-1 : ℝ) · linarith · simp only [neg_le_sub_iff_le_add, div_pow, Nat.cast_succ, le_add_iff_nonneg_left] positivity · linarith · linarith theorem norm_exp_sub_one_le {x : ℂ} (hx : ‖x‖ ≤ 1) : ‖exp x - 1‖ ≤ 2 * ‖x‖ := calc ‖exp x - 1‖ = ‖exp x - ∑ m ∈ range 1, x ^ m / m.factorial‖ := by simp [sum_range_succ] _ ≤ ‖x‖ ^ 1 * ((Nat.succ 1 : ℝ) * ((Nat.factorial 1) * (1 : ℕ) : ℝ)⁻¹) := (exp_bound hx (by decide)) _ = 2 * ‖x‖ := by simp [two_mul, mul_two, mul_add, mul_comm, add_mul, Nat.factorial] theorem norm_exp_sub_one_sub_id_le {x : ℂ} (hx : ‖x‖ ≤ 1) : ‖exp x - 1 - x‖ ≤ ‖x‖ ^ 2 := calc ‖exp x - 1 - x‖ = ‖exp x - ∑ m ∈ range 2, x ^ m / m.factorial‖ := by simp [sub_eq_add_neg, sum_range_succ_comm, add_assoc, Nat.factorial] _ ≤ ‖x‖ ^ 2 * ((Nat.succ 2 : ℝ) * (Nat.factorial 2 * (2 : ℕ) : ℝ)⁻¹) := (exp_bound hx (by decide)) _ ≤ ‖x‖ ^ 2 * 1 := by gcongr; norm_num [Nat.factorial] _ = ‖x‖ ^ 2 := by rw [mul_one] lemma norm_exp_sub_sum_le_exp_norm_sub_sum (x : ℂ) (n : ℕ) : ‖exp x - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ Real.exp ‖x‖ - ∑ m ∈ range n, ‖x‖ ^ m / m.factorial := by rw [← CauSeq.lim_const (abv := norm) (∑ m ∈ range n, _), Complex.exp, sub_eq_add_neg, ← CauSeq.lim_neg, CauSeq.lim_add, ← lim_norm] refine CauSeq.lim_le (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩) simp_rw [← sub_eq_add_neg] calc ‖(∑ m ∈ range j, x ^ m / m.factorial) - ∑ m ∈ range n, x ^ m / m.factorial‖ _ ≤ (∑ m ∈ range j, ‖x‖ ^ m / m.factorial) - ∑ m ∈ range n, ‖x‖ ^ m / m.factorial := by rw [sum_range_sub_sum_range hj, sum_range_sub_sum_range hj] refine (IsAbsoluteValue.abv_sum norm ..).trans_eq ?_ congr with i simp [Complex.norm_pow] _ ≤ Real.exp ‖x‖ - ∑ m ∈ range n, ‖x‖ ^ m / m.factorial := by gcongr exact Real.sum_le_exp_of_nonneg (norm_nonneg _) _ lemma norm_exp_le_exp_norm (x : ℂ) : ‖exp x‖ ≤ Real.exp ‖x‖ := by convert norm_exp_sub_sum_le_exp_norm_sub_sum x 0 using 1 <;> simp lemma norm_exp_sub_sum_le_norm_mul_exp (x : ℂ) (n : ℕ) : ‖exp x - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ ‖x‖ ^ n * Real.exp ‖x‖ := by rw [← CauSeq.lim_const (abv := norm) (∑ m ∈ range n, _), Complex.exp, sub_eq_add_neg, ← CauSeq.lim_neg, CauSeq.lim_add, ← lim_norm] refine CauSeq.lim_le (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩) simp_rw [← sub_eq_add_neg] show ‖(∑ m ∈ range j, x ^ m / m.factorial) - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ _ rw [sum_range_sub_sum_range hj] calc ‖∑ m ∈ range j with n ≤ m, (x ^ m / m.factorial : ℂ)‖ = ‖∑ m ∈ range j with n ≤ m, (x ^ n * (x ^ (m - n) / m.factorial) : ℂ)‖ := by refine congr_arg norm (sum_congr rfl fun m hm => ?_) rw [mem_filter, mem_range] at hm rw [← mul_div_assoc, ← pow_add, add_tsub_cancel_of_le hm.2] _ ≤ ∑ m ∈ range j with n ≤ m, ‖x ^ n * (x ^ (m - n) / m.factorial)‖ := IsAbsoluteValue.abv_sum norm .. _ ≤ ∑ m ∈ range j with n ≤ m, ‖x‖ ^ n * (‖x‖ ^ (m - n) / (m - n).factorial) := by simp_rw [Complex.norm_mul, Complex.norm_pow, Complex.norm_div, norm_natCast] gcongr with i hi · rw [Complex.norm_pow] · simp _ = ‖x‖ ^ n * ∑ m ∈ range j with n ≤ m, (‖x‖ ^ (m - n) / (m - n).factorial) := by rw [← mul_sum] _ = ‖x‖ ^ n * ∑ m ∈ range (j - n), (‖x‖ ^ m / m.factorial) := by congr 1 refine (sum_bij (fun m hm ↦ m + n) ?_ ?_ ?_ ?_).symm · intro a ha simp only [mem_filter, mem_range, le_add_iff_nonneg_left, zero_le, and_true] simp only [mem_range] at ha rwa [← lt_tsub_iff_right] · intro a ha b hb hab simpa using hab · intro b hb simp only [mem_range, exists_prop] simp only [mem_filter, mem_range] at hb refine ⟨b - n, ?_, ?_⟩ · rw [tsub_lt_tsub_iff_right hb.2] exact hb.1 · rw [tsub_add_cancel_of_le hb.2] · simp _ ≤ ‖x‖ ^ n * Real.exp ‖x‖ := by gcongr refine Real.sum_le_exp_of_nonneg ?_ _ exact norm_nonneg _ @[deprecated (since := "2025-02-16")] alias abs_exp_sub_one_le := norm_exp_sub_one_le @[deprecated (since := "2025-02-16")] alias abs_exp_sub_one_sub_id_le := norm_exp_sub_one_sub_id_le @[deprecated (since := "2025-02-16")] alias abs_exp_sub_sum_le_exp_abs_sub_sum := norm_exp_sub_sum_le_exp_norm_sub_sum @[deprecated (since := "2025-02-16")] alias abs_exp_le_exp_abs := norm_exp_le_exp_norm @[deprecated (since := "2025-02-16")] alias abs_exp_sub_sum_le_abs_mul_exp := norm_exp_sub_sum_le_norm_mul_exp end Complex namespace Real open Complex Finset nonrec theorem exp_bound {x : ℝ} (hx : \|x\| ≤ 1) {n : ℕ} (hn : 0 < n) : \|exp x - ∑ m ∈ range n, x ^ m / m.factorial\| ≤ \|x\| ^ n * (n.succ / (n.factorial * n)) := by have hxc : ‖(x : ℂ)‖ ≤ 1 := mod_cast hx convert exp_bound hxc hn using 2 <;> norm_cast theorem exp_bound' {x : ℝ} (h1 : 0 ≤ x) (h2 : x ≤ 1) {n : ℕ} (hn : 0 < n) : Real.exp x ≤ (∑ m ∈ Finset.range n, x ^ m / m.factorial) + x ^ n * (n + 1) / (n.factorial * n) := by have h3 : \|x\| = x := by simpa have h4 : \|x\| ≤ 1 := by rwa [h3] have h' := Real.exp_bound h4 hn rw [h3] at h' have h'' := (abs_sub_le_iff.1 h').1 have t := sub_le_iff_le_add'.1 h'' simpa [mul_div_assoc] using t theorem abs_exp_sub_one_le {x : ℝ} (hx : \|x\| ≤ 1) : \|exp x - 1\| ≤ 2 * \|x\| := by have : ‖(x : ℂ)‖ ≤ 1 := mod_cast hx exact_mod_cast Complex.norm_exp_sub_one_le (x := x) this theorem abs_exp_sub_one_sub_id_le {x : ℝ} (hx : \|x\| ≤ 1) : \|exp x - 1 - x\| ≤ x ^ 2 := by rw [← sq_abs] have : ‖(x : ℂ)‖ ≤ 1 := mod_cast hx exact_mod_cast Complex.norm_exp_sub_one_sub_id_le this /-- A finite initial segment of the exponential series, followed by an arbitrary tail. For fixed `n` this is just a linear map wrt `r`, and each map is a simple linear function of the previous (see `expNear_succ`), with `expNear n x r ⟶ exp x` as `n ⟶ ∞`, for any `r`. -/ noncomputable def expNear (n : ℕ) (x r : ℝ) : ℝ := (∑ m ∈ range n, x ^ m / m.factorial) + x ^ n / n.factorial * r @[simp] theorem expNear_zero (x r) : expNear 0 x r = r := by simp [expNear] @[simp] theorem expNear_succ (n x r) : expNear (n + 1) x r = expNear n x (1 + x / (n + 1) * r) := by simp [expNear, range_succ, mul_add, add_left_comm, add_assoc, pow_succ, div_eq_mul_inv, mul_inv, Nat.factorial] ac_rfl theorem expNear_sub (n x r₁ r₂) : expNear n x r₁ - expNear n x r₂ = x ^ n / n.factorial * (r₁ - r₂) := by simp [expNear, mul_sub] theorem exp_approx_end (n m : ℕ) (x : ℝ) (e₁ : n + 1 = m) (h : \|x\| ≤ 1) : \|exp x - expNear m x 0\| ≤ \|x\| ^ m / m.factorial * ((m + 1) / m) := by simp only [expNear, mul_zero, add_zero] convert exp_bound (n := m) h ?_ using 1 · field_simp [mul_comm] · omega theorem exp_approx_succ {n} {x a₁ b₁ : ℝ} (m : ℕ) (e₁ : n + 1 = m) (a₂ b₂ : ℝ) (e : \|1 + x / m * a₂ - a₁\| ≤ b₁ - \|x\| / m * b₂) (h : \|exp x - expNear m x a₂\| ≤ \|x\| ^ m / m.factorial * b₂) : \|exp x - expNear n x a₁\| ≤ \|x\| ^ n / n.factorial * b₁ := by refine (abs_sub_le _ _ _).trans ((add_le_add_right h _).trans ?_) subst e₁; rw [expNear_succ, expNear_sub, abs_mul] convert mul_le_mul_of_nonneg_left (a := \|x\| ^ n / ↑(Nat.factorial n)) (le_sub_iff_add_le'.1 e) ?_ using 1 · simp [mul_add, pow_succ', div_eq_mul_inv, abs_mul, abs_inv, ← pow_abs, mul_inv, Nat.factorial] ac_rfl · simp [div_nonneg, abs_nonneg] theorem exp_approx_end' {n} {x a b : ℝ} (m : ℕ) (e₁ : n + 1 = m) (rm : ℝ) (er : ↑m = rm) (h : \|x\| ≤ 1) (e : \|1 - a\| ≤ b - \|x\| / rm * ((rm + 1) / rm)) : \|exp x - expNear n x a\| ≤ \|x\| ^ n / n.factorial * b := by subst er exact exp_approx_succ _ e₁ _ _ (by simpa using e) (exp_approx_end _ _ _ e₁ h) theorem exp_1_approx_succ_eq {n} {a₁ b₁ : ℝ} {m : ℕ} (en : n + 1 = m) {rm : ℝ} (er : ↑m = rm) (h : \|exp 1 - expNear m 1 ((a₁ - 1) * rm)\| ≤ \|1\| ^ m / m.factorial * (b₁ * rm)) : \|exp 1 - expNear n 1 a₁\| ≤ \|1\| ^ n / n.factorial * b₁ := by subst er refine exp_approx_succ _ en _ _ ?_ h field_simp [show (m : ℝ) ≠ 0 by norm_cast; omega] theorem exp_approx_start (x a b : ℝ) (h : \|exp x - expNear 0 x a\| ≤ \|x\| ^ 0 / Nat.factorial 0 * b) : \|exp x - a\| ≤ b := by simpa using h theorem exp_bound_div_one_sub_of_interval' {x : ℝ} (h1 : 0 < x) (h2 : x < 1) : Real.exp x < 1 / (1 - x) := by have H : 0 < 1 - (1 + x + x ^ 2) * (1 - x) := calc 0 < x ^ 3 := by positivity _ = 1 - (1 + x + x ^ 2) * (1 - x) := by ring calc exp x ≤ _ := exp_bound' h1.le h2.le zero_lt_three _ ≤ 1 + x + x ^ 2 := by -- Porting note: was `norm_num [Finset.sum] <;> nlinarith` -- This proof should be restored after the norm_num plugin for big operators is ported. -- (It may also need the positivity extensions in https://github.com/leanprover-community/mathlib4/pull/3907.) rw [show 3 = 1 + 1 + 1 from rfl] repeat rw [Finset.sum_range_succ] norm_num [Nat.factorial] nlinarith _ < 1 / (1 - x) := by rw [lt_div_iff₀] <;> nlinarith theorem exp_bound_div_one_sub_of_interval {x : ℝ} (h1 : 0 ≤ x) (h2 : x < 1) : Real.exp x ≤ 1 / (1 - x) := by rcases eq_or_lt_of_le h1 with (rfl \| h1) · simp · exact (exp_bound_div_one_sub_of_interval' h1 h2).le theorem add_one_lt_exp {x : ℝ} (hx : x ≠ 0) : x + 1 < Real.exp x := by obtain hx \| hx := hx.symm.lt_or_lt · exact add_one_lt_exp_of_pos hx obtain h' \| h' := le_or_lt 1 (-x) · linarith [x.exp_pos] have hx' : 0 < x + 1 := by linarith simpa [add_comm, exp_neg, inv_lt_inv₀ (exp_pos _) hx'] using exp_bound_div_one_sub_of_interval' (neg_pos.2 hx) h' theorem add_one_le_exp (x : ℝ) : x + 1 ≤ Real.exp x := by obtain rfl \| hx := eq_or_ne x 0 · simp · exact (add_one_lt_exp hx).le lemma one_sub_lt_exp_neg {x : ℝ} (hx : x ≠ 0) : 1 - x < exp (-x) := (sub_eq_neg_add _ _).trans_lt <\| add_one_lt_exp <\| neg_ne_zero.2 hx lemma one_sub_le_exp_neg (x : ℝ) : 1 - x ≤ exp (-x) := (sub_eq_neg_add _ _).trans_le <\| add_one_le_exp _ theorem one_sub_div_pow_le_exp_neg {n : ℕ} {t : ℝ} (ht' : t ≤ n) : (1 - t / n) ^ n ≤ exp (-t) := by rcases eq_or_ne n 0 with (rfl \| hn) · simp rwa [Nat.cast_zero] at ht' calc (1 - t / n) ^ n ≤ rexp (-(t / n)) ^ n := by gcongr · exact sub_nonneg.2 <\| div_le_one_of_le₀ ht' n.cast_nonneg · exact one_sub_le_exp_neg _ _ = rexp (-t) := by rw [← Real.exp_nat_mul, mul_neg, mul_comm, div_mul_cancel₀]; positivity lemma le_inv_mul_exp (x : ℝ) {c : ℝ} (hc : 0 < c) : x ≤ c⁻¹ * exp (c * x) := by rw [le_inv_mul_iff₀ hc] calc c * x _ ≤ c * x + 1 := le_add_of_nonneg_right zero_le_one _ ≤ _ := Real.add_one_le_exp (c * x) end Real namespace Mathlib.Meta.Positivity open Lean.Meta Qq /-- Extension for the `positivity` tactic: `Real.exp` is always positive. -/ @[positivity Real.exp _] def evalExp : PositivityExt where eval {u α} _ _ e := do match u, α, e with \| 0, ~q(ℝ), ~q(Real.exp $a) => assertInstancesCommute pure (.positive q(Real.exp_pos $a)) \| _, _, _ => throwError "not Real.exp" end Mathlib.Meta.Positivity namespace Complex @[simp] theorem norm_exp_ofReal (x : ℝ) : ‖exp x‖ = Real.exp x := by rw [← ofReal_exp] exact Complex.norm_of_nonneg (le_of_lt (Real.exp_pos _)) @[deprecated (since := "2025-02-16")] alias abs_exp_ofReal := norm_exp_ofReal end Complex		Mathlib/Data/Complex/Exponential.lean	907	908
/- Copyright (c) 2022 Eric Wieser. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Eric Wieser, Jujian Zhang -/ import Mathlib.Algebra.DirectSum.Module import Mathlib.Algebra.Module.Submodule.Basic /-! # Decompositions of additive monoids, groups, and modules into direct sums ## Main definitions * `DirectSum.Decomposition ℳ`: A typeclass to provide a constructive decomposition from an additive monoid `M` into a family of additive submonoids `ℳ` * `DirectSum.decompose ℳ`: The canonical equivalence provided by the above typeclass ## Main statements * `DirectSum.Decomposition.isInternal`: The link to `DirectSum.IsInternal`. ## Implementation details As we want to talk about different types of decomposition (additive monoids, modules, rings, ...), we choose to avoid heavily bundling `DirectSum.decompose`, instead making copies for the `AddEquiv`, `LinearEquiv`, etc. This means we have to repeat statements that follow from these bundled homs, but means we don't have to repeat statements for different types of decomposition. -/ variable {ι R M σ : Type} open DirectSum namespace DirectSum section AddCommMonoid variable [DecidableEq ι] [AddCommMonoid M] variable [SetLike σ M] [AddSubmonoidClass σ M] (ℳ : ι → σ) /-- A decomposition is an equivalence between an additive monoid `M` and a direct sum of additive submonoids `ℳ i` of that `M`, such that the "recomposition" is canonical. This definition also works for additive groups and modules. This is a version of `DirectSum.IsInternal` which comes with a constructive inverse to the canonical "recomposition" rather than just a proof that the "recomposition" is bijective. Often it is easier to construct a term of this type via `Decomposition.ofAddHom` or `Decomposition.ofLinearMap`. -/ class Decomposition where decompose' : M → ⨁ i, ℳ i left_inv : Function.LeftInverse (DirectSum.coeAddMonoidHom ℳ) decompose' right_inv : Function.RightInverse (DirectSum.coeAddMonoidHom ℳ) decompose' /-- `DirectSum.Decomposition` instances, while carrying data, are always equal. -/ instance : Subsingleton (Decomposition ℳ) := ⟨fun x y ↦ by obtain ⟨_, _, xr⟩ := x obtain ⟨_, yl, _⟩ := y congr exact Function.LeftInverse.eq_rightInverse xr yl⟩ /-- A convenience method to construct a decomposition from an `AddMonoidHom`, such that the proofs of left and right inverse can be constructed via `ext`. -/ abbrev Decomposition.ofAddHom (decompose : M →+ ⨁ i, ℳ i) (h_left_inv : (DirectSum.coeAddMonoidHom ℳ).comp decompose = .id _) (h_right_inv : decompose.comp (DirectSum.coeAddMonoidHom ℳ) = .id _) : Decomposition ℳ where decompose' := decompose left_inv := DFunLike.congr_fun h_left_inv right_inv := DFunLike.congr_fun h_right_inv /-- Noncomputably conjure a decomposition instance from a `DirectSum.IsInternal` proof. -/ noncomputable def IsInternal.chooseDecomposition (h : IsInternal ℳ) : DirectSum.Decomposition ℳ where decompose' := (Equiv.ofBijective _ h).symm left_inv := (Equiv.ofBijective _ h).right_inv right_inv := (Equiv.ofBijective _ h).left_inv variable [Decomposition ℳ] protected theorem Decomposition.isInternal : DirectSum.IsInternal ℳ := ⟨Decomposition.right_inv.injective, Decomposition.left_inv.surjective⟩ /-- If `M` is graded by `ι` with degree `i` component `ℳ i`, then it is isomorphic as to a direct sum of components. This is the canonical spelling of the `decompose'` field. -/ def decompose : M ≃ ⨁ i, ℳ i where toFun := Decomposition.decompose' invFun := DirectSum.coeAddMonoidHom ℳ left_inv := Decomposition.left_inv right_inv := Decomposition.right_inv omit [AddSubmonoidClass σ M] in /-- A substructure `p ⊆ M` is homogeneous if for every `m ∈ p`, all homogeneous components of `m` are in `p`. -/ def SetLike.IsHomogeneous {P : Type} [SetLike P M] (p : P) : Prop := ∀ (i : ι) ⦃m : M⦄, m ∈ p → (DirectSum.decompose ℳ m i : M) ∈ p @[elab_as_elim] protected theorem Decomposition.inductionOn {motive : M → Prop} (zero : motive 0) (homogeneous : ∀ {i} (m : ℳ i), motive (m : M)) (add : ∀ m m' : M, motive m → motive m' → motive (m + m')) : ∀ m, motive m := by let ℳ' : ι → AddSubmonoid M := fun i ↦ (⟨⟨ℳ i, fun x y ↦ AddMemClass.add_mem x y⟩, (ZeroMemClass.zero_mem _)⟩ : AddSubmonoid M) haveI t : DirectSum.Decomposition ℳ' := { decompose' := DirectSum.decompose ℳ left_inv := fun _ ↦ (decompose ℳ).left_inv _ right_inv := fun _ ↦ (decompose ℳ).right_inv _ } have mem : ∀ m, m ∈ iSup ℳ' := fun _m ↦ (DirectSum.IsInternal.addSubmonoid_iSup_eq_top ℳ' (Decomposition.isInternal ℳ')).symm ▸ trivial -- Porting note: needs to use @ even though no implicit argument is provided exact fun m ↦ @AddSubmonoid.iSup_induction _ _ _ ℳ' _ _ (mem m) (fun i m h ↦ homogeneous ⟨m, h⟩) zero add -- exact fun m ↦ -- AddSubmonoid.iSup_induction ℳ' (mem m) (fun i m h ↦ h_homogeneous ⟨m, h⟩) h_zero h_add @[simp] theorem Decomposition.decompose'_eq : Decomposition.decompose' = decompose ℳ := rfl @[simp] theorem decompose_symm_of {i : ι} (x : ℳ i) : (decompose ℳ).symm (DirectSum.of _ i x) = x := DirectSum.coeAddMonoidHom_of ℳ _ _ @[simp] theorem decompose_coe {i : ι} (x : ℳ i) : decompose ℳ (x : M) = DirectSum.of _ i x := by rw [← decompose_symm_of _, Equiv.apply_symm_apply] theorem decompose_of_mem {x : M} {i : ι} (hx : x ∈ ℳ i) : decompose ℳ x = DirectSum.of (fun i ↦ ℳ i) i ⟨x, hx⟩ := decompose_coe _ ⟨x, hx⟩ theorem decompose_of_mem_same {x : M} {i : ι} (hx : x ∈ ℳ i) : (decompose ℳ x i : M) = x := by rw [decompose_of_mem _ hx, DirectSum.of_eq_same, Subtype.coe_mk]	theorem decompose_of_mem_ne {x : M} {i j : ι} (hx : x ∈ ℳ i) (hij : i ≠ j) : (decompose ℳ x j : M) = 0 := by	Mathlib/Algebra/DirectSum/Decomposition.lean	136	137
/- Copyright (c) 2022 Moritz Doll. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Moritz Doll -/ import Mathlib.LinearAlgebra.LinearPMap import Mathlib.Topology.Algebra.Module.Basic /-! # Partially defined linear operators over topological vector spaces We define basic notions of partially defined linear operators, which we call unbounded operators for short. In this file we prove all elementary properties of unbounded operators that do not assume that the underlying spaces are normed. ## Main definitions * `LinearPMap.IsClosed`: An unbounded operator is closed iff its graph is closed. * `LinearPMap.IsClosable`: An unbounded operator is closable iff the closure of its graph is a graph. * `LinearPMap.closure`: For a closable unbounded operator `f : LinearPMap R E F` the closure is the smallest closed extension of `f`. If `f` is not closable, then `f.closure` is defined as `f`. * `LinearPMap.HasCore`: a submodule contained in the domain is a core if restricting to the core does not lose information about the unbounded operator. ## Main statements * `LinearPMap.closable_iff_exists_closed_extension`: an unbounded operator is closable iff it has a closed extension. * `LinearPMap.closable.existsUnique`: there exists a unique closure * `LinearPMap.closureHasCore`: the domain of `f` is a core of its closure ## References * [J. Weidmann, Linear Operators in Hilbert Spaces][weidmann_linear] ## Tags Unbounded operators, closed operators -/ open Topology variable {R E F : Type*} variable [CommRing R] [AddCommGroup E] [AddCommGroup F] variable [Module R E] [Module R F] variable [TopologicalSpace E] [TopologicalSpace F] namespace LinearPMap /-! ### Closed and closable operators -/ /-- An unbounded operator is closed iff its graph is closed. -/ def IsClosed (f : E →ₗ.[R] F) : Prop := _root_.IsClosed (f.graph : Set (E × F)) variable [ContinuousAdd E] [ContinuousAdd F] variable [TopologicalSpace R] [ContinuousSMul R E] [ContinuousSMul R F] /-- An unbounded operator is closable iff the closure of its graph is a graph. -/ def IsClosable (f : E →ₗ.[R] F) : Prop := ∃ f' : LinearPMap R E F, f.graph.topologicalClosure = f'.graph /-- A closed operator is trivially closable. -/ theorem IsClosed.isClosable {f : E →ₗ.[R] F} (hf : f.IsClosed) : f.IsClosable := ⟨f, hf.submodule_topologicalClosure_eq⟩ /-- If `g` has a closable extension `f`, then `g` itself is closable. -/ theorem IsClosable.leIsClosable {f g : E →ₗ.[R] F} (hf : f.IsClosable) (hfg : g ≤ f) : g.IsClosable := by obtain ⟨f', hf⟩ := hf have : g.graph.topologicalClosure ≤ f'.graph := by rw [← hf] exact Submodule.topologicalClosure_mono (le_graph_of_le hfg) use g.graph.topologicalClosure.toLinearPMap rw [Submodule.toLinearPMap_graph_eq] exact fun _ hx hx' => f'.graph_fst_eq_zero_snd (this hx) hx' /-- The closure is unique. -/ theorem IsClosable.existsUnique {f : E →ₗ.[R] F} (hf : f.IsClosable) : ∃! f' : E →ₗ.[R] F, f.graph.topologicalClosure = f'.graph := by refine existsUnique_of_exists_of_unique hf fun _ _ hy₁ hy₂ => eq_of_eq_graph ?_ rw [← hy₁, ← hy₂] open Classical in /-- If `f` is closable, then `f.closure` is the closure. Otherwise it is defined as `f.closure = f`. -/ noncomputable def closure (f : E →ₗ.[R] F) : E →ₗ.[R] F := if hf : f.IsClosable then hf.choose else f theorem closure_def {f : E →ₗ.[R] F} (hf : f.IsClosable) : f.closure = hf.choose := by simp [closure, hf] theorem closure_def' {f : E →ₗ.[R] F} (hf : ¬f.IsClosable) : f.closure = f := by simp [closure, hf] /-- The closure (as a submodule) of the graph is equal to the graph of the closure (as a `LinearPMap`). -/ theorem IsClosable.graph_closure_eq_closure_graph {f : E →ₗ.[R] F} (hf : f.IsClosable) : f.graph.topologicalClosure = f.closure.graph := by rw [closure_def hf] exact hf.choose_spec /-- A `LinearPMap` is contained in its closure. -/ theorem le_closure (f : E →ₗ.[R] F) : f ≤ f.closure := by by_cases hf : f.IsClosable · refine le_of_le_graph ?_ rw [← hf.graph_closure_eq_closure_graph] exact (graph f).le_topologicalClosure rw [closure_def' hf] theorem IsClosable.closure_mono {f g : E →ₗ.[R] F} (hg : g.IsClosable) (h : f ≤ g) : f.closure ≤ g.closure := by refine le_of_le_graph ?_ rw [← (hg.leIsClosable h).graph_closure_eq_closure_graph] rw [← hg.graph_closure_eq_closure_graph] exact Submodule.topologicalClosure_mono (le_graph_of_le h) /-- If `f` is closable, then the closure is closed. -/ theorem IsClosable.closure_isClosed {f : E →ₗ.[R] F} (hf : f.IsClosable) : f.closure.IsClosed := by rw [IsClosed, ← hf.graph_closure_eq_closure_graph] exact f.graph.isClosed_topologicalClosure /-- If `f` is closable, then the closure is closable. -/ theorem IsClosable.closureIsClosable {f : E →ₗ.[R] F} (hf : f.IsClosable) : f.closure.IsClosable := hf.closure_isClosed.isClosable theorem isClosable_iff_exists_closed_extension {f : E →ₗ.[R] F} : f.IsClosable ↔ ∃ g : E →ₗ.[R] F, g.IsClosed ∧ f ≤ g := ⟨fun h => ⟨f.closure, h.closure_isClosed, f.le_closure⟩, fun ⟨_, hg, h⟩ => hg.isClosable.leIsClosable h⟩ /-! ### The core of a linear operator -/ /-- A submodule `S` is a core of `f` if the closure of the restriction of `f` to `S` is `f`. -/ structure HasCore (f : E →ₗ.[R] F) (S : Submodule R E) : Prop where le_domain : S ≤ f.domain closure_eq : (f.domRestrict S).closure = f theorem hasCore_def {f : E →ₗ.[R] F} {S : Submodule R E} (h : f.HasCore S) : (f.domRestrict S).closure = f := h.2 /-- For every unbounded operator `f` the submodule `f.domain` is a core of its closure. Note that we don't require that `f` is closable, due to the definition of the closure. -/ theorem closureHasCore (f : E →ₗ.[R] F) : f.closure.HasCore f.domain := by refine ⟨f.le_closure.1, ?_⟩ congr ext x h1 h2 · simp only [domRestrict_domain, Submodule.mem_inf, and_iff_left_iff_imp] intro hx exact f.le_closure.1 hx let z : f.closure.domain := ⟨x, f.le_closure.1 h2⟩ have hyz : x = z := rfl rw [f.le_closure.2 hyz] exact domRestrict_apply hyz /-! ### Topological properties of the inverse -/ section Inverse variable {f : E →ₗ.[R] F} /-- If `f` is invertible and closable as well as its closure being invertible, then the graph of the inverse of the closure is given by the closure of the graph of the inverse. -/ theorem closure_inverse_graph (hf : LinearMap.ker f.toFun = ⊥) (hf' : f.IsClosable) (hcf : LinearMap.ker f.closure.toFun = ⊥) : f.closure.inverse.graph = f.inverse.graph.topologicalClosure := by rw [inverse_graph hf, inverse_graph hcf, ← hf'.graph_closure_eq_closure_graph] apply SetLike.ext' simp only [Submodule.topologicalClosure_coe, Submodule.map_coe, LinearEquiv.prodComm_apply] apply (image_closure_subset_closure_image continuous_swap).antisymm have h1 := Set.image_equiv_eq_preimage_symm f.graph (LinearEquiv.prodComm R E F).toEquiv have h2 := Set.image_equiv_eq_preimage_symm (_root_.closure f.graph) (LinearEquiv.prodComm R E F).toEquiv simp only [LinearEquiv.coe_toEquiv, LinearEquiv.prodComm_apply, LinearEquiv.coe_toEquiv_symm] at h1 h2 rw [h1, h2] apply continuous_swap.closure_preimage_subset /-- Assuming that `f` is invertible and closable, then the closure is invertible if and only if the inverse of `f` is closable. -/ theorem inverse_isClosable_iff (hf : LinearMap.ker f.toFun = ⊥) (hf' : f.IsClosable) : f.inverse.IsClosable ↔ LinearMap.ker f.closure.toFun = ⊥ := by constructor · intro ⟨f', h⟩ rw [LinearMap.ker_eq_bot'] intro ⟨x, hx⟩ hx' simp only [Submodule.mk_eq_zero] rw [toFun_eq_coe, eq_comm, image_iff] at hx' have : (0, x) ∈ graph f' := by rw [← h, inverse_graph hf] rw [← hf'.graph_closure_eq_closure_graph, ← SetLike.mem_coe, Submodule.topologicalClosure_coe] at hx' apply image_closure_subset_closure_image continuous_swap simp only [Set.mem_image, Prod.exists, Prod.swap_prod_mk, Prod.mk.injEq] exact ⟨x, 0, hx', rfl, rfl⟩ exact graph_fst_eq_zero_snd f' this rfl · intro h use f.closure.inverse exact (closure_inverse_graph hf hf' h).symm	/-- If `f` is invertible and closable, then taking the closure and the inverse commute. -/ theorem inverse_closure (hf : LinearMap.ker f.toFun = ⊥) (hf' : f.IsClosable) (hcf : LinearMap.ker f.closure.toFun = ⊥) : f.inverse.closure = f.closure.inverse := by apply eq_of_eq_graph rw [closure_inverse_graph hf hf' hcf, ((inverse_isClosable_iff hf hf').mpr hcf).graph_closure_eq_closure_graph] end Inverse end LinearPMap	Mathlib/Topology/Algebra/Module/LinearPMap.lean	207	225
/- Copyright (c) 2021 Yaël Dillies. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yaël Dillies -/ import Mathlib.Data.Fintype.BigOperators import Mathlib.Data.DFinsupp.BigOperators import Mathlib.Data.DFinsupp.Order import Mathlib.Order.Interval.Finset.Basic import Mathlib.Algebra.Group.Pointwise.Finset.Basic /-! # Finite intervals of finitely supported functions This file provides the `LocallyFiniteOrder` instance for `Π₀ i, α i` when `α` itself is locally finite and calculates the cardinality of its finite intervals. -/ open DFinsupp Finset open Pointwise variable {ι : Type} {α : ι → Type} namespace Finset variable [DecidableEq ι] [∀ i, Zero (α i)] {s : Finset ι} {f : Π₀ i, α i} {t : ∀ i, Finset (α i)} /-- Finitely supported product of finsets. -/ def dfinsupp (s : Finset ι) (t : ∀ i, Finset (α i)) : Finset (Π₀ i, α i) := (s.pi t).map ⟨fun f => DFinsupp.mk s fun i => f i i.2, by refine (mk_injective _).comp fun f g h => ?_ ext i hi convert congr_fun h ⟨i, hi⟩⟩ @[simp] theorem card_dfinsupp (s : Finset ι) (t : ∀ i, Finset (α i)) : #(s.dfinsupp t) = ∏ i ∈ s, #(t i) := (card_map _).trans <\| card_pi _ _ variable [∀ i, DecidableEq (α i)] theorem mem_dfinsupp_iff : f ∈ s.dfinsupp t ↔ f.support ⊆ s ∧ ∀ i ∈ s, f i ∈ t i := by refine mem_map.trans ⟨?_, ?_⟩ · rintro ⟨f, hf, rfl⟩ rw [Function.Embedding.coeFn_mk] refine ⟨support_mk_subset, fun i hi => ?_⟩ convert mem_pi.1 hf i hi exact mk_of_mem hi · refine fun h => ⟨fun i _ => f i, mem_pi.2 h.2, ?_⟩ ext i dsimp exact ite_eq_left_iff.2 fun hi => (not_mem_support_iff.1 fun H => hi <\| h.1 H).symm /-- When `t` is supported on `s`, `f ∈ s.dfinsupp t` precisely means that `f` is pointwise in `t`. -/ @[simp] theorem mem_dfinsupp_iff_of_support_subset {t : Π₀ i, Finset (α i)} (ht : t.support ⊆ s) : f ∈ s.dfinsupp t ↔ ∀ i, f i ∈ t i := by refine mem_dfinsupp_iff.trans (forall_and.symm.trans <\| forall_congr' fun i => ⟨ fun h => ?_, fun h => ⟨fun hi => ht <\| mem_support_iff.2 fun H => mem_support_iff.1 hi ?_, fun _ => h⟩⟩) · by_cases hi : i ∈ s · exact h.2 hi · rw [not_mem_support_iff.1 (mt h.1 hi), not_mem_support_iff.1 (not_mem_mono ht hi)] exact zero_mem_zero · rwa [H, mem_zero] at h end Finset open Finset namespace DFinsupp section BundledSingleton variable [∀ i, Zero (α i)] {f : Π₀ i, α i} {i : ι} {a : α i} /-- Pointwise `Finset.singleton` bundled as a `DFinsupp`. -/ def singleton (f : Π₀ i, α i) : Π₀ i, Finset (α i) where toFun i := {f i} support' := f.support'.map fun s => ⟨s.1, fun i => (s.prop i).imp id (congr_arg _)⟩ theorem mem_singleton_apply_iff : a ∈ f.singleton i ↔ a = f i := mem_singleton end BundledSingleton section BundledIcc variable [∀ i, Zero (α i)] [∀ i, PartialOrder (α i)] [∀ i, LocallyFiniteOrder (α i)] {f g : Π₀ i, α i} {i : ι} {a : α i} /-- Pointwise `Finset.Icc` bundled as a `DFinsupp`. -/ def rangeIcc (f g : Π₀ i, α i) : Π₀ i, Finset (α i) where toFun i := Icc (f i) (g i) support' := f.support'.bind fun fs => g.support'.map fun gs => ⟨ fs.1 + gs.1, fun i => or_iff_not_imp_left.2 fun h => by have hf : f i = 0 := (fs.prop i).resolve_left (Multiset.not_mem_mono (Multiset.Le.subset <\| Multiset.le_add_right _ _) h) have hg : g i = 0 := (gs.prop i).resolve_left (Multiset.not_mem_mono (Multiset.Le.subset <\| Multiset.le_add_left _ _) h) simp_rw [hf, hg] exact Icc_self _⟩ @[simp] theorem rangeIcc_apply (f g : Π₀ i, α i) (i : ι) : f.rangeIcc g i = Icc (f i) (g i) := rfl theorem mem_rangeIcc_apply_iff : a ∈ f.rangeIcc g i ↔ f i ≤ a ∧ a ≤ g i := mem_Icc theorem support_rangeIcc_subset [DecidableEq ι] [∀ i, DecidableEq (α i)] : (f.rangeIcc g).support ⊆ f.support ∪ g.support := by refine fun x hx => ?_ by_contra h refine not_mem_support_iff.2 ?_ hx rw [rangeIcc_apply, not_mem_support_iff.1 (not_mem_mono subset_union_left h), not_mem_support_iff.1 (not_mem_mono subset_union_right h)] exact Icc_self _ end BundledIcc section Pi variable [∀ i, Zero (α i)] [DecidableEq ι] [∀ i, DecidableEq (α i)] /-- Given a finitely supported function `f : Π₀ i, Finset (α i)`, one can define the finset `f.pi` of all finitely supported functions whose value at `i` is in `f i` for all `i`. -/ def pi (f : Π₀ i, Finset (α i)) : Finset (Π₀ i, α i) := f.support.dfinsupp f @[simp] theorem mem_pi {f : Π₀ i, Finset (α i)} {g : Π₀ i, α i} : g ∈ f.pi ↔ ∀ i, g i ∈ f i := mem_dfinsupp_iff_of_support_subset <\| Subset.refl _ @[simp] theorem card_pi (f : Π₀ i, Finset (α i)) : #f.pi = f.prod fun i ↦ #(f i) := by rw [pi, card_dfinsupp] exact Finset.prod_congr rfl fun i _ => by simp only [Pi.natCast_apply, Nat.cast_id] end Pi section PartialOrder variable [DecidableEq ι] [∀ i, DecidableEq (α i)] variable [∀ i, PartialOrder (α i)] [∀ i, Zero (α i)] [∀ i, LocallyFiniteOrder (α i)] instance instLocallyFiniteOrder : LocallyFiniteOrder (Π₀ i, α i) := LocallyFiniteOrder.ofIcc (Π₀ i, α i) (fun f g => (f.support ∪ g.support).dfinsupp <\| f.rangeIcc g) (fun f g x => by	refine (mem_dfinsupp_iff_of_support_subset <\| support_rangeIcc_subset).trans ?_ simp_rw [mem_rangeIcc_apply_iff, forall_and] rfl)	Mathlib/Data/DFinsupp/Interval.lean	152	154
/- Copyright (c) 2021 Johan Commelin. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johan Commelin, Aaron Anderson -/ import Mathlib.Algebra.Order.BigOperators.Group.Finset import Mathlib.Algebra.Order.Module.Defs import Mathlib.Algebra.Order.Pi import Mathlib.Data.Finsupp.Basic import Mathlib.Data.Finsupp.SMulWithZero /-! # Pointwise order on finitely supported functions This file lifts order structures on `α` to `ι →₀ α`. ## Main declarations * `Finsupp.orderEmbeddingToFun`: The order embedding from finitely supported functions to functions. -/ noncomputable section open Finset variable {ι κ α β : Type*} namespace Finsupp /-! ### Order structures -/ section Zero variable [Zero α] section OrderedAddCommMonoid variable [AddCommMonoid β] [PartialOrder β] [IsOrderedAddMonoid β] {f : ι →₀ α} {h₁ h₂ : ι → α → β} @[gcongr] lemma sum_le_sum (h : ∀ i ∈ f.support, h₁ i (f i) ≤ h₂ i (f i)) : f.sum h₁ ≤ f.sum h₂ := Finset.sum_le_sum h end OrderedAddCommMonoid section LE variable [LE α] {f g : ι →₀ α} instance instLEFinsupp : LE (ι →₀ α) := ⟨fun f g => ∀ i, f i ≤ g i⟩ lemma le_def : f ≤ g ↔ ∀ i, f i ≤ g i := Iff.rfl @[simp, norm_cast] lemma coe_le_coe : ⇑f ≤ g ↔ f ≤ g := Iff.rfl /-- The order on `Finsupp`s over a partial order embeds into the order on functions -/ def orderEmbeddingToFun : (ι →₀ α) ↪o (ι → α) where toFun f := f inj' f g h := Finsupp.ext fun i => by dsimp at h rw [h] map_rel_iff' := coe_le_coe @[simp] theorem orderEmbeddingToFun_apply {f : ι →₀ α} {i : ι} : orderEmbeddingToFun f i = f i := rfl end LE section Preorder variable [Preorder α] {f g : ι →₀ α} {i : ι} {a b : α} instance preorder : Preorder (ι →₀ α) := { Finsupp.instLEFinsupp with le_refl := fun _ _ => le_rfl le_trans := fun _ _ _ hfg hgh i => (hfg i).trans (hgh i) } lemma lt_def : f < g ↔ f ≤ g ∧ ∃ i, f i < g i := Pi.lt_def @[simp, norm_cast] lemma coe_lt_coe : ⇑f < g ↔ f < g := Iff.rfl lemma coe_mono : Monotone (Finsupp.toFun : (ι →₀ α) → ι → α) := fun _ _ ↦ id lemma coe_strictMono : Monotone (Finsupp.toFun : (ι →₀ α) → ι → α) := fun _ _ ↦ id @[simp] lemma single_le_single : single i a ≤ single i b ↔ a ≤ b := by classical exact Pi.single_le_single lemma single_mono : Monotone (single i : α → ι →₀ α) := fun _ _ ↦ single_le_single.2 @[gcongr] protected alias ⟨_, GCongr.single_mono⟩ := single_le_single @[simp] lemma single_nonneg : 0 ≤ single i a ↔ 0 ≤ a := by classical exact Pi.single_nonneg @[simp] lemma single_nonpos : single i a ≤ 0 ↔ a ≤ 0 := by classical exact Pi.single_nonpos variable [AddCommMonoid β] [PartialOrder β] [IsOrderedAddMonoid β] lemma sum_le_sum_index [DecidableEq ι] {f₁ f₂ : ι →₀ α} {h : ι → α → β} (hf : f₁ ≤ f₂) (hh : ∀ i ∈ f₁.support ∪ f₂.support, Monotone (h i)) (hh₀ : ∀ i ∈ f₁.support ∪ f₂.support, h i 0 = 0) : f₁.sum h ≤ f₂.sum h := by classical rw [sum_of_support_subset _ Finset.subset_union_left _ hh₀, sum_of_support_subset _ Finset.subset_union_right _ hh₀] exact Finset.sum_le_sum fun i hi ↦ hh _ hi <\| hf _ end Preorder instance partialorder [PartialOrder α] : PartialOrder (ι →₀ α) := { Finsupp.preorder with le_antisymm := fun _f _g hfg hgf => ext fun i => (hfg i).antisymm (hgf i) } instance semilatticeInf [SemilatticeInf α] : SemilatticeInf (ι →₀ α) := { Finsupp.partialorder with inf := zipWith (· ⊓ ·) (inf_idem _) inf_le_left := fun _f _g _i => inf_le_left inf_le_right := fun _f _g _i => inf_le_right le_inf := fun _f _g _i h1 h2 s => le_inf (h1 s) (h2 s) } @[simp] theorem inf_apply [SemilatticeInf α] {i : ι} {f g : ι →₀ α} : (f ⊓ g) i = f i ⊓ g i := rfl instance semilatticeSup [SemilatticeSup α] : SemilatticeSup (ι →₀ α) := { Finsupp.partialorder with sup := zipWith (· ⊔ ·) (sup_idem _) le_sup_left := fun _f _g _i => le_sup_left le_sup_right := fun _f _g _i => le_sup_right sup_le := fun _f _g _h hf hg i => sup_le (hf i) (hg i) } @[simp] theorem sup_apply [SemilatticeSup α] {i : ι} {f g : ι →₀ α} : (f ⊔ g) i = f i ⊔ g i := rfl instance lattice [Lattice α] : Lattice (ι →₀ α) := { Finsupp.semilatticeInf, Finsupp.semilatticeSup with } section Lattice variable [DecidableEq ι] [Lattice α] (f g : ι →₀ α) theorem support_inf_union_support_sup : (f ⊓ g).support ∪ (f ⊔ g).support = f.support ∪ g.support := coe_injective <\| compl_injective <\| by ext; simp [inf_eq_and_sup_eq_iff] theorem support_sup_union_support_inf : (f ⊔ g).support ∪ (f ⊓ g).support = f.support ∪ g.support := (union_comm _ _).trans <\| support_inf_union_support_sup _ _ end Lattice end Zero /-! ### Algebraic order structures -/ section OrderedAddCommMonoid variable [AddCommMonoid α] [PartialOrder α] [IsOrderedAddMonoid α] {i : ι} {f : ι → κ} {g g₁ g₂ : ι →₀ α} instance isOrderedAddMonoid : IsOrderedAddMonoid (ι →₀ α) := { add_le_add_left := fun _a _b h c s => add_le_add_left (h s) (c s) } lemma mapDomain_mono : Monotone (mapDomain f : (ι →₀ α) → (κ →₀ α)) := by classical exact fun g₁ g₂ h ↦ sum_le_sum_index h (fun _ _ ↦ single_mono) (by simp) @[gcongr] protected lemma GCongr.mapDomain_mono (hg : g₁ ≤ g₂) : g₁.mapDomain f ≤ g₂.mapDomain f := mapDomain_mono hg lemma mapDomain_nonneg (hg : 0 ≤ g) : 0 ≤ g.mapDomain f := by simpa using mapDomain_mono hg lemma mapDomain_nonpos (hg : g ≤ 0) : g.mapDomain f ≤ 0 := by simpa using mapDomain_mono hg end OrderedAddCommMonoid instance isOrderedCancelAddMonoid [AddCommMonoid α] [PartialOrder α] [IsOrderedCancelAddMonoid α] : IsOrderedCancelAddMonoid (ι →₀ α) := { le_of_add_le_add_left := fun _f _g _i h s => le_of_add_le_add_left (h s) } instance addLeftReflectLE [AddCommMonoid α] [PartialOrder α] [AddLeftReflectLE α] : AddLeftReflectLE (ι →₀ α) := ⟨fun _f _g _h H x => le_of_add_le_add_left <\| H x⟩ section SMulZeroClass variable [Zero α] [Preorder α] [Zero β] [Preorder β] [SMulZeroClass α β] instance instPosSMulMono [PosSMulMono α β] : PosSMulMono α (ι →₀ β) := PosSMulMono.lift _ coe_le_coe coe_smul instance instSMulPosMono [SMulPosMono α β] : SMulPosMono α (ι →₀ β) := SMulPosMono.lift _ coe_le_coe coe_smul coe_zero instance instPosSMulReflectLE [PosSMulReflectLE α β] : PosSMulReflectLE α (ι →₀ β) := PosSMulReflectLE.lift _ coe_le_coe coe_smul instance instSMulPosReflectLE [SMulPosReflectLE α β] : SMulPosReflectLE α (ι →₀ β) := SMulPosReflectLE.lift _ coe_le_coe coe_smul coe_zero end SMulZeroClass section SMulWithZero variable [Zero α] [PartialOrder α] [Zero β] [PartialOrder β] [SMulWithZero α β]	instance instPosSMulStrictMono [PosSMulStrictMono α β] : PosSMulStrictMono α (ι →₀ β) :=	Mathlib/Data/Finsupp/Order.lean	197	198
/- Copyright (c) 2018 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Julian Kuelshammer -/ import Mathlib.Algebra.CharP.Defs import Mathlib.Algebra.Group.Commute.Basic import Mathlib.Algebra.Group.Pointwise.Set.Finite import Mathlib.Algebra.Group.Subgroup.Finite import Mathlib.Algebra.Module.NatInt import Mathlib.Algebra.Order.Group.Action import Mathlib.Algebra.Order.Ring.Abs import Mathlib.Data.Int.ModEq import Mathlib.Dynamics.PeriodicPts.Lemmas import Mathlib.GroupTheory.Index import Mathlib.NumberTheory.Divisors import Mathlib.Order.Interval.Set.Infinite /-! # Order of an element This file defines the order of an element of a finite group. For a finite group `G` the order of `x ∈ G` is the minimal `n ≥ 1` such that `x ^ n = 1`. ## Main definitions * `IsOfFinOrder` is a predicate on an element `x` of a monoid `G` saying that `x` is of finite order. * `IsOfFinAddOrder` is the additive analogue of `IsOfFinOrder`. * `orderOf x` defines the order of an element `x` of a monoid `G`, by convention its value is `0` if `x` has infinite order. * `addOrderOf` is the additive analogue of `orderOf`. ## Tags order of an element -/ assert_not_exists Field open Function Fintype Nat Pointwise Subgroup Submonoid open scoped Finset variable {G H A α β : Type} section Monoid variable [Monoid G] {a b x y : G} {n m : ℕ} section IsOfFinOrder -- Porting note (https://github.com/leanprover-community/mathlib4/issues/12129): additional beta reduction needed @[to_additive] theorem isPeriodicPt_mul_iff_pow_eq_one (x : G) : IsPeriodicPt (x ·) n 1 ↔ x ^ n = 1 := by rw [IsPeriodicPt, IsFixedPt, mul_left_iterate]; beta_reduce; rw [mul_one] /-- `IsOfFinOrder` is a predicate on an element `x` of a monoid to be of finite order, i.e. there exists `n ≥ 1` such that `x ^ n = 1`. -/ @[to_additive "`IsOfFinAddOrder` is a predicate on an element `a` of an additive monoid to be of finite order, i.e. there exists `n ≥ 1` such that `n • a = 0`."] def IsOfFinOrder (x : G) : Prop := (1 : G) ∈ periodicPts (x * ·) theorem isOfFinAddOrder_ofMul_iff : IsOfFinAddOrder (Additive.ofMul x) ↔ IsOfFinOrder x := Iff.rfl theorem isOfFinOrder_ofAdd_iff {α : Type} [AddMonoid α] {x : α} : IsOfFinOrder (Multiplicative.ofAdd x) ↔ IsOfFinAddOrder x := Iff.rfl @[to_additive] theorem isOfFinOrder_iff_pow_eq_one : IsOfFinOrder x ↔ ∃ n, 0 < n ∧ x ^ n = 1 := by simp [IsOfFinOrder, mem_periodicPts, isPeriodicPt_mul_iff_pow_eq_one] @[to_additive] alias ⟨IsOfFinOrder.exists_pow_eq_one, _⟩ := isOfFinOrder_iff_pow_eq_one @[to_additive] lemma isOfFinOrder_iff_zpow_eq_one {G} [DivisionMonoid G] {x : G} : IsOfFinOrder x ↔ ∃ (n : ℤ), n ≠ 0 ∧ x ^ n = 1 := by rw [isOfFinOrder_iff_pow_eq_one] refine ⟨fun ⟨n, hn, hn'⟩ ↦ ⟨n, Int.natCast_ne_zero_iff_pos.mpr hn, zpow_natCast x n ▸ hn'⟩, fun ⟨n, hn, hn'⟩ ↦ ⟨n.natAbs, Int.natAbs_pos.mpr hn, ?_⟩⟩ rcases (Int.natAbs_eq_iff (a := n)).mp rfl with h \| h · rwa [h, zpow_natCast] at hn' · rwa [h, zpow_neg, inv_eq_one, zpow_natCast] at hn' /-- See also `injective_pow_iff_not_isOfFinOrder`. -/ @[to_additive "See also `injective_nsmul_iff_not_isOfFinAddOrder`."] theorem not_isOfFinOrder_of_injective_pow {x : G} (h : Injective fun n : ℕ => x ^ n) : ¬IsOfFinOrder x := by simp_rw [isOfFinOrder_iff_pow_eq_one, not_exists, not_and] intro n hn_pos hnx rw [← pow_zero x] at hnx rw [h hnx] at hn_pos exact irrefl 0 hn_pos /-- 1 is of finite order in any monoid. -/ @[to_additive (attr := simp) "0 is of finite order in any additive monoid."] theorem IsOfFinOrder.one : IsOfFinOrder (1 : G) := isOfFinOrder_iff_pow_eq_one.mpr ⟨1, Nat.one_pos, one_pow 1⟩ @[to_additive] lemma IsOfFinOrder.pow {n : ℕ} : IsOfFinOrder a → IsOfFinOrder (a ^ n) := by simp_rw [isOfFinOrder_iff_pow_eq_one] rintro ⟨m, hm, ha⟩ exact ⟨m, hm, by simp [pow_right_comm _ n, ha]⟩ @[to_additive] lemma IsOfFinOrder.of_pow {n : ℕ} (h : IsOfFinOrder (a ^ n)) (hn : n ≠ 0) : IsOfFinOrder a := by rw [isOfFinOrder_iff_pow_eq_one] at rcases h with ⟨m, hm, ha⟩ exact ⟨n * m, mul_pos hn.bot_lt hm, by rwa [pow_mul]⟩ @[to_additive (attr := simp)] lemma isOfFinOrder_pow {n : ℕ} : IsOfFinOrder (a ^ n) ↔ IsOfFinOrder a ∨ n = 0 := by rcases Decidable.eq_or_ne n 0 with rfl \| hn · simp · exact ⟨fun h ↦ .inl <\| h.of_pow hn, fun h ↦ (h.resolve_right hn).pow⟩ /-- Elements of finite order are of finite order in submonoids. -/ @[to_additive "Elements of finite order are of finite order in submonoids."] theorem Submonoid.isOfFinOrder_coe {H : Submonoid G} {x : H} : IsOfFinOrder (x : G) ↔ IsOfFinOrder x := by rw [isOfFinOrder_iff_pow_eq_one, isOfFinOrder_iff_pow_eq_one] norm_cast theorem IsConj.isOfFinOrder (h : IsConj x y) : IsOfFinOrder x → IsOfFinOrder y := by simp_rw [isOfFinOrder_iff_pow_eq_one] rintro ⟨n, n_gt_0, eq'⟩ exact ⟨n, n_gt_0, by rw [← isConj_one_right, ← eq']; exact h.pow n⟩ /-- The image of an element of finite order has finite order. -/ @[to_additive "The image of an element of finite additive order has finite additive order."] theorem MonoidHom.isOfFinOrder [Monoid H] (f : G →* H) {x : G} (h : IsOfFinOrder x) : IsOfFinOrder <\| f x := isOfFinOrder_iff_pow_eq_one.mpr <\| by obtain ⟨n, npos, hn⟩ := h.exists_pow_eq_one exact ⟨n, npos, by rw [← f.map_pow, hn, f.map_one]⟩ /-- If a direct product has finite order then so does each component. -/ @[to_additive "If a direct product has finite additive order then so does each component."] theorem IsOfFinOrder.apply {η : Type} {Gs : η → Type} [∀ i, Monoid (Gs i)] {x : ∀ i, Gs i} (h : IsOfFinOrder x) : ∀ i, IsOfFinOrder (x i) := by obtain ⟨n, npos, hn⟩ := h.exists_pow_eq_one exact fun _ => isOfFinOrder_iff_pow_eq_one.mpr ⟨n, npos, (congr_fun hn.symm _).symm⟩ /-- The submonoid generated by an element is a group if that element has finite order. -/ @[to_additive "The additive submonoid generated by an element is an additive group if that element has finite order."] noncomputable abbrev IsOfFinOrder.groupPowers (hx : IsOfFinOrder x) : Group (Submonoid.powers x) := by obtain ⟨hpos, hx⟩ := hx.exists_pow_eq_one.choose_spec exact Submonoid.groupPowers hpos hx end IsOfFinOrder /-- `orderOf x` is the order of the element `x`, i.e. the `n ≥ 1`, s.t. `x ^ n = 1` if it exists. Otherwise, i.e. if `x` is of infinite order, then `orderOf x` is `0` by convention. -/ @[to_additive "`addOrderOf a` is the order of the element `a`, i.e. the `n ≥ 1`, s.t. `n • a = 0` if it exists. Otherwise, i.e. if `a` is of infinite order, then `addOrderOf a` is `0` by convention."] noncomputable def orderOf (x : G) : ℕ := minimalPeriod (x * ·) 1 @[simp] theorem addOrderOf_ofMul_eq_orderOf (x : G) : addOrderOf (Additive.ofMul x) = orderOf x := rfl @[simp] lemma orderOf_ofAdd_eq_addOrderOf {α : Type} [AddMonoid α] (a : α) : orderOf (Multiplicative.ofAdd a) = addOrderOf a := rfl @[to_additive] protected lemma IsOfFinOrder.orderOf_pos (h : IsOfFinOrder x) : 0 < orderOf x := minimalPeriod_pos_of_mem_periodicPts h @[to_additive addOrderOf_nsmul_eq_zero] theorem pow_orderOf_eq_one (x : G) : x ^ orderOf x = 1 := by convert Eq.trans _ (isPeriodicPt_minimalPeriod (x ·) 1) -- Porting note (https://github.com/leanprover-community/mathlib4/issues/12129): additional beta reduction needed in the middle of the rewrite rw [orderOf, mul_left_iterate]; beta_reduce; rw [mul_one] @[to_additive] theorem orderOf_eq_zero (h : ¬IsOfFinOrder x) : orderOf x = 0 := by rwa [orderOf, minimalPeriod, dif_neg] @[to_additive] theorem orderOf_eq_zero_iff : orderOf x = 0 ↔ ¬IsOfFinOrder x := ⟨fun h H ↦ H.orderOf_pos.ne' h, orderOf_eq_zero⟩ @[to_additive] theorem orderOf_eq_zero_iff' : orderOf x = 0 ↔ ∀ n : ℕ, 0 < n → x ^ n ≠ 1 := by simp_rw [orderOf_eq_zero_iff, isOfFinOrder_iff_pow_eq_one, not_exists, not_and] @[to_additive] theorem orderOf_eq_iff {n} (h : 0 < n) : orderOf x = n ↔ x ^ n = 1 ∧ ∀ m, m < n → 0 < m → x ^ m ≠ 1 := by simp_rw [Ne, ← isPeriodicPt_mul_iff_pow_eq_one, orderOf, minimalPeriod] split_ifs with h1 · classical rw [find_eq_iff] simp only [h, true_and] push_neg rfl · rw [iff_false_left h.ne] rintro ⟨h', -⟩ exact h1 ⟨n, h, h'⟩ /-- A group element has finite order iff its order is positive. -/ @[to_additive "A group element has finite additive order iff its order is positive."] theorem orderOf_pos_iff : 0 < orderOf x ↔ IsOfFinOrder x := by rw [iff_not_comm.mp orderOf_eq_zero_iff, pos_iff_ne_zero] @[to_additive] theorem IsOfFinOrder.mono [Monoid β] {y : β} (hx : IsOfFinOrder x) (h : orderOf y ∣ orderOf x) : IsOfFinOrder y := by rw [← orderOf_pos_iff] at hx ⊢; exact Nat.pos_of_dvd_of_pos h hx @[to_additive] theorem pow_ne_one_of_lt_orderOf (n0 : n ≠ 0) (h : n < orderOf x) : x ^ n ≠ 1 := fun j => not_isPeriodicPt_of_pos_of_lt_minimalPeriod n0 h ((isPeriodicPt_mul_iff_pow_eq_one x).mpr j) @[to_additive] theorem orderOf_le_of_pow_eq_one (hn : 0 < n) (h : x ^ n = 1) : orderOf x ≤ n := IsPeriodicPt.minimalPeriod_le hn (by rwa [isPeriodicPt_mul_iff_pow_eq_one]) @[to_additive (attr := simp)] theorem orderOf_one : orderOf (1 : G) = 1 := by rw [orderOf, ← minimalPeriod_id (x := (1 : G)), ← one_mul_eq_id] @[to_additive (attr := simp) AddMonoid.addOrderOf_eq_one_iff] theorem orderOf_eq_one_iff : orderOf x = 1 ↔ x = 1 := by rw [orderOf, minimalPeriod_eq_one_iff_isFixedPt, IsFixedPt, mul_one] @[to_additive (attr := simp) mod_addOrderOf_nsmul] lemma pow_mod_orderOf (x : G) (n : ℕ) : x ^ (n % orderOf x) = x ^ n := calc x ^ (n % orderOf x) = x ^ (n % orderOf x + orderOf x * (n / orderOf x)) := by simp [pow_add, pow_mul, pow_orderOf_eq_one] _ = x ^ n := by rw [Nat.mod_add_div] @[to_additive] theorem orderOf_dvd_of_pow_eq_one (h : x ^ n = 1) : orderOf x ∣ n := IsPeriodicPt.minimalPeriod_dvd ((isPeriodicPt_mul_iff_pow_eq_one _).mpr h) @[to_additive] theorem orderOf_dvd_iff_pow_eq_one {n : ℕ} : orderOf x ∣ n ↔ x ^ n = 1 := ⟨fun h => by rw [← pow_mod_orderOf, Nat.mod_eq_zero_of_dvd h, _root_.pow_zero], orderOf_dvd_of_pow_eq_one⟩ @[to_additive addOrderOf_smul_dvd] theorem orderOf_pow_dvd (n : ℕ) : orderOf (x ^ n) ∣ orderOf x := by rw [orderOf_dvd_iff_pow_eq_one, pow_right_comm, pow_orderOf_eq_one, one_pow] @[to_additive] lemma pow_injOn_Iio_orderOf : (Set.Iio <\| orderOf x).InjOn (x ^ ·) := by simpa only [mul_left_iterate, mul_one] using iterate_injOn_Iio_minimalPeriod (f := (x * ·)) (x := 1) @[to_additive] protected lemma IsOfFinOrder.mem_powers_iff_mem_range_orderOf [DecidableEq G] (hx : IsOfFinOrder x) : y ∈ Submonoid.powers x ↔ y ∈ (Finset.range (orderOf x)).image (x ^ ·) := Finset.mem_range_iff_mem_finset_range_of_mod_eq' hx.orderOf_pos <\| pow_mod_orderOf _ @[to_additive] protected lemma IsOfFinOrder.powers_eq_image_range_orderOf [DecidableEq G] (hx : IsOfFinOrder x) : (Submonoid.powers x : Set G) = (Finset.range (orderOf x)).image (x ^ ·) := Set.ext fun _ ↦ hx.mem_powers_iff_mem_range_orderOf @[to_additive] theorem pow_eq_one_iff_modEq : x ^ n = 1 ↔ n ≡ 0 [MOD orderOf x] := by rw [modEq_zero_iff_dvd, orderOf_dvd_iff_pow_eq_one] @[to_additive] theorem orderOf_map_dvd {H : Type} [Monoid H] (ψ : G → H) (x : G) : orderOf (ψ x) ∣ orderOf x := by apply orderOf_dvd_of_pow_eq_one rw [← map_pow, pow_orderOf_eq_one] apply map_one @[to_additive] theorem exists_pow_eq_self_of_coprime (h : n.Coprime (orderOf x)) : ∃ m : ℕ, (x ^ n) ^ m = x := by by_cases h0 : orderOf x = 0 · rw [h0, coprime_zero_right] at h exact ⟨1, by rw [h, pow_one, pow_one]⟩ by_cases h1 : orderOf x = 1 · exact ⟨0, by rw [orderOf_eq_one_iff.mp h1, one_pow, one_pow]⟩ obtain ⟨m, h⟩ := exists_mul_emod_eq_one_of_coprime h (one_lt_iff_ne_zero_and_ne_one.mpr ⟨h0, h1⟩) exact ⟨m, by rw [← pow_mul, ← pow_mod_orderOf, h, pow_one]⟩ /-- If `x^n = 1`, but `x^(n/p) ≠ 1` for all prime factors `p` of `n`, then `x` has order `n` in `G`. -/ @[to_additive addOrderOf_eq_of_nsmul_and_div_prime_nsmul "If `n * x = 0`, but `n/p * x ≠ 0` for all prime factors `p` of `n`, then `x` has order `n` in `G`."] theorem orderOf_eq_of_pow_and_pow_div_prime (hn : 0 < n) (hx : x ^ n = 1) (hd : ∀ p : ℕ, p.Prime → p ∣ n → x ^ (n / p) ≠ 1) : orderOf x = n := by -- Let `a` be `n/(orderOf x)`, and show `a = 1` obtain ⟨a, ha⟩ := exists_eq_mul_right_of_dvd (orderOf_dvd_of_pow_eq_one hx) suffices a = 1 by simp [this, ha] -- Assume `a` is not one... by_contra h have a_min_fac_dvd_p_sub_one : a.minFac ∣ n := by obtain ⟨b, hb⟩ : ∃ b : ℕ, a = b * a.minFac := exists_eq_mul_left_of_dvd a.minFac_dvd rw [hb, ← mul_assoc] at ha exact Dvd.intro_left (orderOf x * b) ha.symm -- Use the minimum prime factor of `a` as `p`. refine hd a.minFac (Nat.minFac_prime h) a_min_fac_dvd_p_sub_one ?_ rw [← orderOf_dvd_iff_pow_eq_one, Nat.dvd_div_iff_mul_dvd a_min_fac_dvd_p_sub_one, ha, mul_comm, Nat.mul_dvd_mul_iff_left (IsOfFinOrder.orderOf_pos _)] · exact Nat.minFac_dvd a · rw [isOfFinOrder_iff_pow_eq_one] exact Exists.intro n (id ⟨hn, hx⟩) @[to_additive] theorem orderOf_eq_orderOf_iff {H : Type} [Monoid H] {y : H} : orderOf x = orderOf y ↔ ∀ n : ℕ, x ^ n = 1 ↔ y ^ n = 1 := by simp_rw [← isPeriodicPt_mul_iff_pow_eq_one, ← minimalPeriod_eq_minimalPeriod_iff, orderOf] /-- An injective homomorphism of monoids preserves orders of elements. -/ @[to_additive "An injective homomorphism of additive monoids preserves orders of elements."] theorem orderOf_injective {H : Type} [Monoid H] (f : G →* H) (hf : Function.Injective f) (x : G) : orderOf (f x) = orderOf x := by simp_rw [orderOf_eq_orderOf_iff, ← f.map_pow, ← f.map_one, hf.eq_iff, forall_const] /-- A multiplicative equivalence preserves orders of elements. -/ @[to_additive (attr := simp) "An additive equivalence preserves orders of elements."] lemma MulEquiv.orderOf_eq {H : Type} [Monoid H] (e : G ≃ H) (x : G) : orderOf (e x) = orderOf x := orderOf_injective e.toMonoidHom e.injective x @[to_additive] theorem Function.Injective.isOfFinOrder_iff [Monoid H] {f : G →* H} (hf : Injective f) : IsOfFinOrder (f x) ↔ IsOfFinOrder x := by rw [← orderOf_pos_iff, orderOf_injective f hf x, ← orderOf_pos_iff] @[to_additive (attr := norm_cast, simp)] theorem orderOf_submonoid {H : Submonoid G} (y : H) : orderOf (y : G) = orderOf y := orderOf_injective H.subtype Subtype.coe_injective y @[to_additive] theorem orderOf_units {y : Gˣ} : orderOf (y : G) = orderOf y := orderOf_injective (Units.coeHom G) Units.ext y /-- If the order of `x` is finite, then `x` is a unit with inverse `x ^ (orderOf x - 1)`. -/ @[to_additive (attr := simps) "If the additive order of `x` is finite, then `x` is an additive unit with inverse `(addOrderOf x - 1) • x`. "] noncomputable def IsOfFinOrder.unit {M} [Monoid M] {x : M} (hx : IsOfFinOrder x) : Mˣ := ⟨x, x ^ (orderOf x - 1), by rw [← _root_.pow_succ', tsub_add_cancel_of_le (by exact hx.orderOf_pos), pow_orderOf_eq_one], by rw [← _root_.pow_succ, tsub_add_cancel_of_le (by exact hx.orderOf_pos), pow_orderOf_eq_one]⟩ @[to_additive] lemma IsOfFinOrder.isUnit {M} [Monoid M] {x : M} (hx : IsOfFinOrder x) : IsUnit x := ⟨hx.unit, rfl⟩ variable (x) @[to_additive] theorem orderOf_pow' (h : n ≠ 0) : orderOf (x ^ n) = orderOf x / gcd (orderOf x) n := by unfold orderOf rw [← minimalPeriod_iterate_eq_div_gcd h, mul_left_iterate] @[to_additive] lemma orderOf_pow_of_dvd {x : G} {n : ℕ} (hn : n ≠ 0) (dvd : n ∣ orderOf x) : orderOf (x ^ n) = orderOf x / n := by rw [orderOf_pow' _ hn, Nat.gcd_eq_right dvd] @[to_additive] lemma orderOf_pow_orderOf_div {x : G} {n : ℕ} (hx : orderOf x ≠ 0) (hn : n ∣ orderOf x) : orderOf (x ^ (orderOf x / n)) = n := by rw [orderOf_pow_of_dvd _ (Nat.div_dvd_of_dvd hn), Nat.div_div_self hn hx] rw [← Nat.div_mul_cancel hn] at hx; exact left_ne_zero_of_mul hx variable (n) @[to_additive] protected lemma IsOfFinOrder.orderOf_pow (h : IsOfFinOrder x) : orderOf (x ^ n) = orderOf x / gcd (orderOf x) n := by unfold orderOf rw [← minimalPeriod_iterate_eq_div_gcd' h, mul_left_iterate] @[to_additive] lemma Nat.Coprime.orderOf_pow (h : (orderOf y).Coprime m) : orderOf (y ^ m) = orderOf y := by by_cases hg : IsOfFinOrder y · rw [hg.orderOf_pow y m , h.gcd_eq_one, Nat.div_one] · rw [m.coprime_zero_left.1 (orderOf_eq_zero hg ▸ h), pow_one] @[to_additive] lemma IsOfFinOrder.natCard_powers_le_orderOf (ha : IsOfFinOrder a) : Nat.card (powers a : Set G) ≤ orderOf a := by classical simpa [ha.powers_eq_image_range_orderOf, Finset.card_range, Nat.Iio_eq_range] using Finset.card_image_le (s := Finset.range (orderOf a)) @[to_additive] lemma IsOfFinOrder.finite_powers (ha : IsOfFinOrder a) : (powers a : Set G).Finite := by classical rw [ha.powers_eq_image_range_orderOf]; exact Finset.finite_toSet _ namespace Commute variable {x} @[to_additive] theorem orderOf_mul_dvd_lcm (h : Commute x y) : orderOf (x * y) ∣ Nat.lcm (orderOf x) (orderOf y) := by rw [orderOf, ← comp_mul_left] exact Function.Commute.minimalPeriod_of_comp_dvd_lcm h.function_commute_mul_left @[to_additive] theorem orderOf_dvd_lcm_mul (h : Commute x y): orderOf y ∣ Nat.lcm (orderOf x) (orderOf (x * y)) := by by_cases h0 : orderOf x = 0 · rw [h0, lcm_zero_left] apply dvd_zero conv_lhs => rw [← one_mul y, ← pow_orderOf_eq_one x, ← succ_pred_eq_of_pos (Nat.pos_of_ne_zero h0), _root_.pow_succ, mul_assoc] exact (((Commute.refl x).mul_right h).pow_left _).orderOf_mul_dvd_lcm.trans (lcm_dvd_iff.2 ⟨(orderOf_pow_dvd _).trans (dvd_lcm_left _ _), dvd_lcm_right _ _⟩) @[to_additive addOrderOf_add_dvd_mul_addOrderOf] theorem orderOf_mul_dvd_mul_orderOf (h : Commute x y): orderOf (x * y) ∣ orderOf x * orderOf y := dvd_trans h.orderOf_mul_dvd_lcm (lcm_dvd_mul _ _) @[to_additive addOrderOf_add_eq_mul_addOrderOf_of_coprime] theorem orderOf_mul_eq_mul_orderOf_of_coprime (h : Commute x y) (hco : (orderOf x).Coprime (orderOf y)) : orderOf (x * y) = orderOf x * orderOf y := by rw [orderOf, ← comp_mul_left] exact h.function_commute_mul_left.minimalPeriod_of_comp_eq_mul_of_coprime hco /-- Commuting elements of finite order are closed under multiplication. -/ @[to_additive "Commuting elements of finite additive order are closed under addition."] theorem isOfFinOrder_mul (h : Commute x y) (hx : IsOfFinOrder x) (hy : IsOfFinOrder y) : IsOfFinOrder (x * y) := orderOf_pos_iff.mp <\| pos_of_dvd_of_pos h.orderOf_mul_dvd_mul_orderOf <\| mul_pos hx.orderOf_pos hy.orderOf_pos /-- If each prime factor of `orderOf x` has higher multiplicity in `orderOf y`, and `x` commutes with `y`, then `x * y` has the same order as `y`. -/ @[to_additive addOrderOf_add_eq_right_of_forall_prime_mul_dvd "If each prime factor of `addOrderOf x` has higher multiplicity in `addOrderOf y`, and `x` commutes with `y`, then `x + y` has the same order as `y`."] theorem orderOf_mul_eq_right_of_forall_prime_mul_dvd (h : Commute x y) (hy : IsOfFinOrder y) (hdvd : ∀ p : ℕ, p.Prime → p ∣ orderOf x → p * orderOf x ∣ orderOf y) : orderOf (x * y) = orderOf y := by have hoy := hy.orderOf_pos have hxy := dvd_of_forall_prime_mul_dvd hdvd apply orderOf_eq_of_pow_and_pow_div_prime hoy <;> simp only [Ne, ← orderOf_dvd_iff_pow_eq_one] · exact h.orderOf_mul_dvd_lcm.trans (lcm_dvd hxy dvd_rfl) refine fun p hp hpy hd => hp.ne_one ?_ rw [← Nat.dvd_one, ← mul_dvd_mul_iff_right hoy.ne', one_mul, ← dvd_div_iff_mul_dvd hpy] refine (orderOf_dvd_lcm_mul h).trans (lcm_dvd ((dvd_div_iff_mul_dvd hpy).2 ?_) hd) by_cases h : p ∣ orderOf x exacts [hdvd p hp h, (hp.coprime_iff_not_dvd.2 h).mul_dvd_of_dvd_of_dvd hpy hxy] end Commute section PPrime variable {x n} {p : ℕ} [hp : Fact p.Prime] @[to_additive] theorem orderOf_eq_prime_iff : orderOf x = p ↔ x ^ p = 1 ∧ x ≠ 1 := by rw [orderOf, minimalPeriod_eq_prime_iff, isPeriodicPt_mul_iff_pow_eq_one, IsFixedPt, mul_one] /-- The backward direction of `orderOf_eq_prime_iff`. -/ @[to_additive "The backward direction of `addOrderOf_eq_prime_iff`."] theorem orderOf_eq_prime (hg : x ^ p = 1) (hg1 : x ≠ 1) : orderOf x = p := orderOf_eq_prime_iff.mpr ⟨hg, hg1⟩ @[to_additive addOrderOf_eq_prime_pow] theorem orderOf_eq_prime_pow (hnot : ¬x ^ p ^ n = 1) (hfin : x ^ p ^ (n + 1) = 1) : orderOf x = p ^ (n + 1) := by apply minimalPeriod_eq_prime_pow <;> rwa [isPeriodicPt_mul_iff_pow_eq_one] @[to_additive exists_addOrderOf_eq_prime_pow_iff] theorem exists_orderOf_eq_prime_pow_iff : (∃ k : ℕ, orderOf x = p ^ k) ↔ ∃ m : ℕ, x ^ (p : ℕ) ^ m = 1 := ⟨fun ⟨k, hk⟩ => ⟨k, by rw [← hk, pow_orderOf_eq_one]⟩, fun ⟨_, hm⟩ => by obtain ⟨k, _, hk⟩ := (Nat.dvd_prime_pow hp.elim).mp (orderOf_dvd_of_pow_eq_one hm) exact ⟨k, hk⟩⟩ end PPrime /-- The equivalence between `Fin (orderOf x)` and `Submonoid.powers x`, sending `i` to `x ^ i` -/ @[to_additive "The equivalence between `Fin (addOrderOf a)` and `AddSubmonoid.multiples a`, sending `i` to `i • a`"] noncomputable def finEquivPowers {x : G} (hx : IsOfFinOrder x) : Fin (orderOf x) ≃ powers x := Equiv.ofBijective (fun n ↦ ⟨x ^ (n : ℕ), ⟨n, rfl⟩⟩) ⟨fun ⟨_, h₁⟩ ⟨_, h₂⟩ ij ↦ Fin.ext (pow_injOn_Iio_orderOf h₁ h₂ (Subtype.mk_eq_mk.1 ij)), fun ⟨_, i, rfl⟩ ↦ ⟨⟨i % orderOf x, mod_lt _ hx.orderOf_pos⟩, Subtype.eq <\| pow_mod_orderOf _ _⟩⟩ @[to_additive (attr := simp)] lemma finEquivPowers_apply {x : G} (hx : IsOfFinOrder x) {n : Fin (orderOf x)} : finEquivPowers hx n = ⟨x ^ (n : ℕ), n, rfl⟩ := rfl @[to_additive (attr := simp)] lemma finEquivPowers_symm_apply {x : G} (hx : IsOfFinOrder x) (n : ℕ) : (finEquivPowers hx).symm ⟨x ^ n, _, rfl⟩ = ⟨n % orderOf x, Nat.mod_lt _ hx.orderOf_pos⟩ := by rw [Equiv.symm_apply_eq, finEquivPowers_apply, Subtype.mk_eq_mk, ← pow_mod_orderOf, Fin.val_mk] variable {x n} (hx : IsOfFinOrder x) include hx @[to_additive] theorem IsOfFinOrder.pow_eq_pow_iff_modEq : x ^ n = x ^ m ↔ n ≡ m [MOD orderOf x] := by wlog hmn : m ≤ n generalizing m n · rw [eq_comm, ModEq.comm, this (le_of_not_le hmn)] obtain ⟨k, rfl⟩ := Nat.exists_eq_add_of_le hmn rw [pow_add, (hx.isUnit.pow _).mul_eq_left, pow_eq_one_iff_modEq] exact ⟨fun h ↦ Nat.ModEq.add_left _ h, fun h ↦ Nat.ModEq.add_left_cancel' _ h⟩ @[to_additive] lemma IsOfFinOrder.pow_inj_mod {n m : ℕ} : x ^ n = x ^ m ↔ n % orderOf x = m % orderOf x := hx.pow_eq_pow_iff_modEq end Monoid section CancelMonoid variable [LeftCancelMonoid G] {x y : G} {a : G} {m n : ℕ} @[to_additive] theorem pow_eq_pow_iff_modEq : x ^ n = x ^ m ↔ n ≡ m [MOD orderOf x] := by wlog hmn : m ≤ n generalizing m n · rw [eq_comm, ModEq.comm, this (le_of_not_le hmn)] obtain ⟨k, rfl⟩ := Nat.exists_eq_add_of_le hmn rw [← mul_one (x ^ m), pow_add, mul_left_cancel_iff, pow_eq_one_iff_modEq] exact ⟨fun h => Nat.ModEq.add_left _ h, fun h => Nat.ModEq.add_left_cancel' _ h⟩ @[to_additive (attr := simp)] lemma injective_pow_iff_not_isOfFinOrder : Injective (fun n : ℕ ↦ x ^ n) ↔ ¬IsOfFinOrder x := by refine ⟨fun h => not_isOfFinOrder_of_injective_pow h, fun h n m hnm => ?_⟩ rwa [pow_eq_pow_iff_modEq, orderOf_eq_zero_iff.mpr h, modEq_zero_iff] at hnm @[to_additive] lemma pow_inj_mod {n m : ℕ} : x ^ n = x ^ m ↔ n % orderOf x = m % orderOf x := pow_eq_pow_iff_modEq @[to_additive] theorem pow_inj_iff_of_orderOf_eq_zero (h : orderOf x = 0) {n m : ℕ} : x ^ n = x ^ m ↔ n = m := by rw [pow_eq_pow_iff_modEq, h, modEq_zero_iff] @[to_additive] theorem infinite_not_isOfFinOrder {x : G} (h : ¬IsOfFinOrder x) : { y : G \| ¬IsOfFinOrder y }.Infinite := by let s := { n \| 0 < n }.image fun n : ℕ => x ^ n have hs : s ⊆ { y : G \| ¬IsOfFinOrder y } := by rintro - ⟨n, hn : 0 < n, rfl⟩ (contra : IsOfFinOrder (x ^ n)) apply h rw [isOfFinOrder_iff_pow_eq_one] at contra ⊢ obtain ⟨m, hm, hm'⟩ := contra exact ⟨n * m, mul_pos hn hm, by rwa [pow_mul]⟩ suffices s.Infinite by exact this.mono hs contrapose! h have : ¬Injective fun n : ℕ => x ^ n := by have := Set.not_injOn_infinite_finite_image (Set.Ioi_infinite 0) (Set.not_infinite.mp h) contrapose! this exact Set.injOn_of_injective this rwa [injective_pow_iff_not_isOfFinOrder, Classical.not_not] at this @[to_additive (attr := simp)] lemma finite_powers : (powers a : Set G).Finite ↔ IsOfFinOrder a := by refine ⟨fun h ↦ ?_, IsOfFinOrder.finite_powers⟩ obtain ⟨m, n, hmn, ha⟩ := h.exists_lt_map_eq_of_forall_mem (f := fun n : ℕ ↦ a ^ n) (fun n ↦ by simp [mem_powers_iff]) refine isOfFinOrder_iff_pow_eq_one.2 ⟨n - m, tsub_pos_iff_lt.2 hmn, ?_⟩ rw [← mul_left_cancel_iff (a := a ^ m), ← pow_add, add_tsub_cancel_of_le hmn.le, ha, mul_one] @[to_additive (attr := simp)] lemma infinite_powers : (powers a : Set G).Infinite ↔ ¬ IsOfFinOrder a := finite_powers.not /-- See also `orderOf_eq_card_powers`. -/ @[to_additive "See also `addOrder_eq_card_multiples`."] lemma Nat.card_submonoidPowers : Nat.card (powers a) = orderOf a := by classical by_cases ha : IsOfFinOrder a · exact (Nat.card_congr (finEquivPowers ha).symm).trans <\| by simp · have := (infinite_powers.2 ha).to_subtype rw [orderOf_eq_zero ha, Nat.card_eq_zero_of_infinite] end CancelMonoid section Group variable [Group G] {x y : G} {i : ℤ} /-- Inverses of elements of finite order have finite order. -/ @[to_additive (attr := simp) "Inverses of elements of finite additive order have finite additive order."] theorem isOfFinOrder_inv_iff {x : G} : IsOfFinOrder x⁻¹ ↔ IsOfFinOrder x := by simp [isOfFinOrder_iff_pow_eq_one] @[to_additive] alias ⟨IsOfFinOrder.of_inv, IsOfFinOrder.inv⟩ := isOfFinOrder_inv_iff @[to_additive] theorem orderOf_dvd_iff_zpow_eq_one : (orderOf x : ℤ) ∣ i ↔ x ^ i = 1 := by rcases Int.eq_nat_or_neg i with ⟨i, rfl \| rfl⟩ · rw [Int.natCast_dvd_natCast, orderOf_dvd_iff_pow_eq_one, zpow_natCast] · rw [dvd_neg, Int.natCast_dvd_natCast, zpow_neg, inv_eq_one, zpow_natCast, orderOf_dvd_iff_pow_eq_one] @[to_additive (attr := simp)] theorem orderOf_inv (x : G) : orderOf x⁻¹ = orderOf x := by simp [orderOf_eq_orderOf_iff] @[to_additive] theorem orderOf_dvd_sub_iff_zpow_eq_zpow {a b : ℤ} : (orderOf x : ℤ) ∣ a - b ↔ x ^ a = x ^ b := by rw [orderOf_dvd_iff_zpow_eq_one, zpow_sub, mul_inv_eq_one] namespace Subgroup variable {H : Subgroup G} @[to_additive (attr := norm_cast)] lemma orderOf_coe (a : H) : orderOf (a : G) = orderOf a := orderOf_injective H.subtype Subtype.coe_injective _ @[to_additive (attr := simp)] lemma orderOf_mk (a : G) (ha) : orderOf (⟨a, ha⟩ : H) = orderOf a := (orderOf_coe _).symm end Subgroup @[to_additive mod_addOrderOf_zsmul] lemma zpow_mod_orderOf (x : G) (z : ℤ) : x ^ (z % (orderOf x : ℤ)) = x ^ z := calc x ^ (z % (orderOf x : ℤ)) = x ^ (z % orderOf x + orderOf x * (z / orderOf x) : ℤ) := by simp [zpow_add, zpow_mul, pow_orderOf_eq_one] _ = x ^ z := by rw [Int.emod_add_ediv] @[to_additive (attr := simp) zsmul_smul_addOrderOf] theorem zpow_pow_orderOf : (x ^ i) ^ orderOf x = 1 := by by_cases h : IsOfFinOrder x · rw [← zpow_natCast, ← zpow_mul, mul_comm, zpow_mul, zpow_natCast, pow_orderOf_eq_one, one_zpow] · rw [orderOf_eq_zero h, _root_.pow_zero] @[to_additive] theorem IsOfFinOrder.zpow (h : IsOfFinOrder x) {i : ℤ} : IsOfFinOrder (x ^ i) := isOfFinOrder_iff_pow_eq_one.mpr ⟨orderOf x, h.orderOf_pos, zpow_pow_orderOf⟩ @[to_additive] theorem IsOfFinOrder.of_mem_zpowers (h : IsOfFinOrder x) (h' : y ∈ Subgroup.zpowers x) : IsOfFinOrder y := by obtain ⟨k, rfl⟩ := Subgroup.mem_zpowers_iff.mp h' exact h.zpow @[to_additive] theorem orderOf_dvd_of_mem_zpowers (h : y ∈ Subgroup.zpowers x) : orderOf y ∣ orderOf x := by obtain ⟨k, rfl⟩ := Subgroup.mem_zpowers_iff.mp h rw [orderOf_dvd_iff_pow_eq_one] exact zpow_pow_orderOf theorem smul_eq_self_of_mem_zpowers {α : Type} [MulAction G α] (hx : x ∈ Subgroup.zpowers y) {a : α} (hs : y • a = a) : x • a = a := by obtain ⟨k, rfl⟩ := Subgroup.mem_zpowers_iff.mp hx rw [← MulAction.toPerm_apply, ← MulAction.toPermHom_apply, MonoidHom.map_zpow _ y k, MulAction.toPermHom_apply] exact Function.IsFixedPt.perm_zpow (by exact hs) k -- Porting note: help elab'n with `by exact` theorem vadd_eq_self_of_mem_zmultiples {α G : Type} [AddGroup G] [AddAction G α] {x y : G} (hx : x ∈ AddSubgroup.zmultiples y) {a : α} (hs : y +ᵥ a = a) : x +ᵥ a = a := @smul_eq_self_of_mem_zpowers (Multiplicative G) _ _ _ α _ hx a hs attribute [to_additive existing] smul_eq_self_of_mem_zpowers @[to_additive] lemma IsOfFinOrder.mem_powers_iff_mem_zpowers (hx : IsOfFinOrder x) : y ∈ powers x ↔ y ∈ zpowers x := ⟨fun ⟨n, hn⟩ ↦ ⟨n, by simp_all⟩, fun ⟨i, hi⟩ ↦ ⟨(i % orderOf x).natAbs, by dsimp only rwa [← zpow_natCast, Int.natAbs_of_nonneg <\| Int.emod_nonneg _ <\| Int.natCast_ne_zero_iff_pos.2 <\| hx.orderOf_pos, zpow_mod_orderOf]⟩⟩ @[to_additive] lemma IsOfFinOrder.powers_eq_zpowers (hx : IsOfFinOrder x) : (powers x : Set G) = zpowers x := Set.ext fun _ ↦ hx.mem_powers_iff_mem_zpowers @[to_additive] lemma IsOfFinOrder.mem_zpowers_iff_mem_range_orderOf [DecidableEq G] (hx : IsOfFinOrder x) : y ∈ zpowers x ↔ y ∈ (Finset.range (orderOf x)).image (x ^ ·) := hx.mem_powers_iff_mem_zpowers.symm.trans hx.mem_powers_iff_mem_range_orderOf /-- The equivalence between `Fin (orderOf x)` and `Subgroup.zpowers x`, sending `i` to `x ^ i`. -/ @[to_additive "The equivalence between `Fin (addOrderOf a)` and `Subgroup.zmultiples a`, sending `i` to `i • a`."] noncomputable def finEquivZPowers (hx : IsOfFinOrder x) : Fin (orderOf x) ≃ zpowers x := (finEquivPowers hx).trans <\| Equiv.setCongr hx.powers_eq_zpowers @[to_additive] lemma finEquivZPowers_apply (hx : IsOfFinOrder x) {n : Fin (orderOf x)} : finEquivZPowers hx n = ⟨x ^ (n : ℕ), n, zpow_natCast x n⟩ := rfl @[to_additive] lemma finEquivZPowers_symm_apply (hx : IsOfFinOrder x) (n : ℕ) : (finEquivZPowers hx).symm ⟨x ^ n, ⟨n, by simp⟩⟩ = ⟨n % orderOf x, Nat.mod_lt _ hx.orderOf_pos⟩ := by rw [finEquivZPowers, Equiv.symm_trans_apply]; exact finEquivPowers_symm_apply _ n end Group section CommMonoid variable [CommMonoid G] {x y : G} /-- Elements of finite order are closed under multiplication. -/ @[to_additive "Elements of finite additive order are closed under addition."] theorem IsOfFinOrder.mul (hx : IsOfFinOrder x) (hy : IsOfFinOrder y) : IsOfFinOrder (x * y) := (Commute.all x y).isOfFinOrder_mul hx hy end CommMonoid section FiniteMonoid variable [Monoid G] {x : G} {n : ℕ} @[to_additive] theorem sum_card_orderOf_eq_card_pow_eq_one [Fintype G] [DecidableEq G] (hn : n ≠ 0) : ∑ m ∈ divisors n, #{x : G \| orderOf x = m} = #{x : G \| x ^ n = 1} := by refine (Finset.card_biUnion ?_).symm.trans ?_ · simp +contextual [Set.PairwiseDisjoint, Set.Pairwise, disjoint_iff, Finset.ext_iff] · congr; ext; simp [hn, orderOf_dvd_iff_pow_eq_one] @[to_additive] theorem orderOf_le_card_univ [Fintype G] : orderOf x ≤ Fintype.card G := Finset.le_card_of_inj_on_range (x ^ ·) (fun _ _ ↦ Finset.mem_univ _) pow_injOn_Iio_orderOf @[to_additive] theorem orderOf_le_card [Finite G] : orderOf x ≤ Nat.card G := by obtain ⟨⟩ := nonempty_fintype G simpa using orderOf_le_card_univ end FiniteMonoid section FiniteCancelMonoid variable [LeftCancelMonoid G] -- TODO: Of course everything also works for `RightCancelMonoid`. section Finite variable [Finite G] {x y : G} {n : ℕ} -- TODO: Use this to show that a finite left cancellative monoid is a group. @[to_additive] lemma isOfFinOrder_of_finite (x : G) : IsOfFinOrder x := by by_contra h; exact infinite_not_isOfFinOrder h <\| Set.toFinite _ /-- This is the same as `IsOfFinOrder.orderOf_pos` but with one fewer explicit assumption since this is automatic in case of a finite cancellative monoid. -/ @[to_additive "This is the same as `IsOfFinAddOrder.addOrderOf_pos` but with one fewer explicit assumption since this is automatic in case of a finite cancellative additive monoid."] lemma orderOf_pos (x : G) : 0 < orderOf x := (isOfFinOrder_of_finite x).orderOf_pos /-- This is the same as `orderOf_pow'` and `orderOf_pow''` but with one assumption less which is automatic in the case of a finite cancellative monoid. -/ @[to_additive "This is the same as `addOrderOf_nsmul'` and `addOrderOf_nsmul` but with one assumption less which is automatic in the case of a finite cancellative additive monoid."] theorem orderOf_pow (x : G) : orderOf (x ^ n) = orderOf x / gcd (orderOf x) n := (isOfFinOrder_of_finite _).orderOf_pow .. @[to_additive] theorem mem_powers_iff_mem_range_orderOf [DecidableEq G] : y ∈ powers x ↔ y ∈ (Finset.range (orderOf x)).image (x ^ ·) := Finset.mem_range_iff_mem_finset_range_of_mod_eq' (orderOf_pos x) <\| pow_mod_orderOf _ /-- The equivalence between `Submonoid.powers` of two elements `x, y` of the same order, mapping `x ^ i` to `y ^ i`. -/ @[to_additive "The equivalence between `Submonoid.multiples` of two elements `a, b` of the same additive order, mapping `i • a` to `i • b`."] noncomputable def powersEquivPowers (h : orderOf x = orderOf y) : powers x ≃ powers y := (finEquivPowers <\| isOfFinOrder_of_finite _).symm.trans <\| (finCongr h).trans <\| finEquivPowers <\| isOfFinOrder_of_finite _ @[to_additive (attr := simp)] theorem powersEquivPowers_apply (h : orderOf x = orderOf y) (n : ℕ) : powersEquivPowers h ⟨x ^ n, n, rfl⟩ = ⟨y ^ n, n, rfl⟩ := by rw [powersEquivPowers, Equiv.trans_apply, Equiv.trans_apply, finEquivPowers_symm_apply, ← Equiv.eq_symm_apply, finEquivPowers_symm_apply] simp [h] end Finite variable [Fintype G] {x : G} @[to_additive] lemma orderOf_eq_card_powers : orderOf x = Fintype.card (powers x : Submonoid G) := (Fintype.card_fin (orderOf x)).symm.trans <\| Fintype.card_eq.2 ⟨finEquivPowers <\| isOfFinOrder_of_finite _⟩ end FiniteCancelMonoid section FiniteGroup variable [Group G] {x y : G} @[to_additive] theorem zpow_eq_one_iff_modEq {n : ℤ} : x ^ n = 1 ↔ n ≡ 0 [ZMOD orderOf x] := by rw [Int.modEq_zero_iff_dvd, orderOf_dvd_iff_zpow_eq_one] @[to_additive] theorem zpow_eq_zpow_iff_modEq {m n : ℤ} : x ^ m = x ^ n ↔ m ≡ n [ZMOD orderOf x] := by rw [← mul_inv_eq_one, ← zpow_sub, zpow_eq_one_iff_modEq, Int.modEq_iff_dvd, Int.modEq_iff_dvd, zero_sub, neg_sub] @[to_additive (attr := simp)] theorem injective_zpow_iff_not_isOfFinOrder : (Injective fun n : ℤ => x ^ n) ↔ ¬IsOfFinOrder x := by refine ⟨?_, fun h n m hnm => ?_⟩ · simp_rw [isOfFinOrder_iff_pow_eq_one] rintro h ⟨n, hn, hx⟩ exact Nat.cast_ne_zero.2 hn.ne' (h <\| by simpa using hx) rwa [zpow_eq_zpow_iff_modEq, orderOf_eq_zero_iff.2 h, Nat.cast_zero, Int.modEq_zero_iff] at hnm section Finite variable [Finite G] @[to_additive] theorem exists_zpow_eq_one (x : G) : ∃ (i : ℤ) (_ : i ≠ 0), x ^ (i : ℤ) = 1 := by obtain ⟨w, hw1, hw2⟩ := isOfFinOrder_of_finite x refine ⟨w, Int.natCast_ne_zero.mpr (_root_.ne_of_gt hw1), ?_⟩ rw [zpow_natCast] exact (isPeriodicPt_mul_iff_pow_eq_one _).mp hw2 @[to_additive] lemma mem_powers_iff_mem_zpowers : y ∈ powers x ↔ y ∈ zpowers x := (isOfFinOrder_of_finite _).mem_powers_iff_mem_zpowers @[to_additive] lemma powers_eq_zpowers (x : G) : (powers x : Set G) = zpowers x := (isOfFinOrder_of_finite _).powers_eq_zpowers @[to_additive] lemma mem_zpowers_iff_mem_range_orderOf [DecidableEq G] : y ∈ zpowers x ↔ y ∈ (Finset.range (orderOf x)).image (x ^ ·) := (isOfFinOrder_of_finite _).mem_zpowers_iff_mem_range_orderOf /-- The equivalence between `Subgroup.zpowers` of two elements `x, y` of the same order, mapping `x ^ i` to `y ^ i`. -/ @[to_additive "The equivalence between `Subgroup.zmultiples` of two elements `a, b` of the same additive order, mapping `i • a` to `i • b`."] noncomputable def zpowersEquivZPowers (h : orderOf x = orderOf y) : Subgroup.zpowers x ≃ Subgroup.zpowers y := (finEquivZPowers <\| isOfFinOrder_of_finite _).symm.trans <\| (finCongr h).trans <\| finEquivZPowers <\| isOfFinOrder_of_finite _ @[to_additive (attr := simp) zmultiples_equiv_zmultiples_apply] theorem zpowersEquivZPowers_apply (h : orderOf x = orderOf y) (n : ℕ) : zpowersEquivZPowers h ⟨x ^ n, n, zpow_natCast x n⟩ = ⟨y ^ n, n, zpow_natCast y n⟩ := by rw [zpowersEquivZPowers, Equiv.trans_apply, Equiv.trans_apply, finEquivZPowers_symm_apply, ← Equiv.eq_symm_apply, finEquivZPowers_symm_apply] simp [h] end Finite variable [Fintype G] {x : G} {n : ℕ} /-- See also `Nat.card_zpowers`. -/ @[to_additive "See also `Nat.card_zmultiples`."] theorem Fintype.card_zpowers : Fintype.card (zpowers x) = orderOf x := (Fintype.card_eq.2 ⟨finEquivZPowers <\| isOfFinOrder_of_finite _⟩).symm.trans <\| Fintype.card_fin (orderOf x) @[to_additive] theorem card_zpowers_le (a : G) {k : ℕ} (k_pos : k ≠ 0) (ha : a ^ k = 1) : Fintype.card (Subgroup.zpowers a) ≤ k := by rw [Fintype.card_zpowers] apply orderOf_le_of_pow_eq_one k_pos.bot_lt ha open QuotientGroup @[to_additive] theorem orderOf_dvd_card : orderOf x ∣ Fintype.card G := by classical have ft_prod : Fintype ((G ⧸ zpowers x) × zpowers x) := Fintype.ofEquiv G groupEquivQuotientProdSubgroup have ft_s : Fintype (zpowers x) := @Fintype.prodRight _ _ _ ft_prod _ have ft_cosets : Fintype (G ⧸ zpowers x) := @Fintype.prodLeft _ _ _ ft_prod ⟨⟨1, (zpowers x).one_mem⟩⟩ have eq₁ : Fintype.card G = @Fintype.card _ ft_cosets * @Fintype.card _ ft_s := calc Fintype.card G = @Fintype.card _ ft_prod := @Fintype.card_congr _ _ _ ft_prod groupEquivQuotientProdSubgroup _ = @Fintype.card _ (@instFintypeProd _ _ ft_cosets ft_s) := congr_arg (@Fintype.card _) <\| Subsingleton.elim _ _ _ = @Fintype.card _ ft_cosets * @Fintype.card _ ft_s := @Fintype.card_prod _ _ ft_cosets ft_s have eq₂ : orderOf x = @Fintype.card _ ft_s := calc orderOf x = _ := Fintype.card_zpowers.symm _ = _ := congr_arg (@Fintype.card _) <\| Subsingleton.elim _ _ exact Dvd.intro (@Fintype.card (G ⧸ Subgroup.zpowers x) ft_cosets) (by rw [eq₁, eq₂, mul_comm]) @[to_additive] theorem orderOf_dvd_natCard {G : Type} [Group G] (x : G) : orderOf x ∣ Nat.card G := by obtain h \| h := fintypeOrInfinite G · simp only [Nat.card_eq_fintype_card, orderOf_dvd_card] · simp only [card_eq_zero_of_infinite, dvd_zero] @[to_additive] nonrec lemma Subgroup.orderOf_dvd_natCard {G : Type} [Group G] (s : Subgroup G) {x} (hx : x ∈ s) : orderOf x ∣ Nat.card s := by simpa using orderOf_dvd_natCard (⟨x, hx⟩ : s) @[to_additive] lemma Subgroup.orderOf_le_card {G : Type} [Group G] (s : Subgroup G) (hs : (s : Set G).Finite) {x} (hx : x ∈ s) : orderOf x ≤ Nat.card s := le_of_dvd (Nat.card_pos_iff.2 <\| ⟨s.coe_nonempty.to_subtype, hs.to_subtype⟩) <\| s.orderOf_dvd_natCard hx @[to_additive] lemma Submonoid.orderOf_le_card {G : Type} [Group G] (s : Submonoid G) (hs : (s : Set G).Finite) {x} (hx : x ∈ s) : orderOf x ≤ Nat.card s := by rw [← Nat.card_submonoidPowers]; exact Nat.card_mono hs <\| powers_le.2 hx @[to_additive (attr := simp) card_nsmul_eq_zero'] theorem pow_card_eq_one' {G : Type} [Group G] {x : G} : x ^ Nat.card G = 1 := orderOf_dvd_iff_pow_eq_one.mp <\| orderOf_dvd_natCard _ @[to_additive (attr := simp) card_nsmul_eq_zero] theorem pow_card_eq_one : x ^ Fintype.card G = 1 := by rw [← Nat.card_eq_fintype_card, pow_card_eq_one'] @[to_additive] theorem Subgroup.pow_index_mem {G : Type} [Group G] (H : Subgroup G) [Normal H] (g : G) : g ^ index H ∈ H := by rw [← eq_one_iff, QuotientGroup.mk_pow H, index, pow_card_eq_one'] @[to_additive (attr := simp) mod_card_nsmul] lemma pow_mod_card (a : G) (n : ℕ) : a ^ (n % card G) = a ^ n := by rw [eq_comm, ← pow_mod_orderOf, ← Nat.mod_mod_of_dvd n orderOf_dvd_card, pow_mod_orderOf] @[to_additive (attr := simp) mod_card_zsmul] theorem zpow_mod_card (a : G) (n : ℤ) : a ^ (n % Fintype.card G : ℤ) = a ^ n := by rw [eq_comm, ← zpow_mod_orderOf, ← Int.emod_emod_of_dvd n (Int.natCast_dvd_natCast.2 orderOf_dvd_card), zpow_mod_orderOf] @[to_additive (attr := simp) mod_natCard_nsmul] lemma pow_mod_natCard {G} [Group G] (a : G) (n : ℕ) : a ^ (n % Nat.card G) = a ^ n := by rw [eq_comm, ← pow_mod_orderOf, ← Nat.mod_mod_of_dvd n <\| orderOf_dvd_natCard _, pow_mod_orderOf] @[to_additive (attr := simp) mod_natCard_zsmul] lemma zpow_mod_natCard {G} [Group G] (a : G) (n : ℤ) : a ^ (n % Nat.card G : ℤ) = a ^ n := by rw [eq_comm, ← zpow_mod_orderOf, ← Int.emod_emod_of_dvd n <\| Int.natCast_dvd_natCast.2 <\| orderOf_dvd_natCard _, zpow_mod_orderOf] /-- If `gcd(\|G\|,n)=1` then the `n`th power map is a bijection -/ @[to_additive (attr := simps) "If `gcd(\|G\|,n)=1` then the smul by `n` is a bijection"] noncomputable def powCoprime {G : Type} [Group G] (h : (Nat.card G).Coprime n) : G ≃ G where toFun g := g ^ n invFun g := g ^ (Nat.card G).gcdB n left_inv g := by have key := congr_arg (g ^ ·) ((Nat.card G).gcd_eq_gcd_ab n) dsimp only at key rwa [zpow_add, zpow_mul, zpow_mul, zpow_natCast, zpow_natCast, zpow_natCast, h.gcd_eq_one, pow_one, pow_card_eq_one', one_zpow, one_mul, eq_comm] at key right_inv g := by have key := congr_arg (g ^ ·) ((Nat.card G).gcd_eq_gcd_ab n) dsimp only at key rwa [zpow_add, zpow_mul, zpow_mul', zpow_natCast, zpow_natCast, zpow_natCast, h.gcd_eq_one, pow_one, pow_card_eq_one', one_zpow, one_mul, eq_comm] at key @[to_additive] theorem powCoprime_one {G : Type} [Group G] (h : (Nat.card G).Coprime n) : powCoprime h 1 = 1 := one_pow n @[to_additive] theorem powCoprime_inv {G : Type} [Group G] (h : (Nat.card G).Coprime n) {g : G} : powCoprime h g⁻¹ = (powCoprime h g)⁻¹ := inv_pow g n @[to_additive Nat.Coprime.nsmul_right_bijective] lemma Nat.Coprime.pow_left_bijective {G} [Group G] (hn : (Nat.card G).Coprime n) : Bijective (· ^ n : G → G) := (powCoprime hn).bijective /- TODO: Generalise to `Submonoid.powers`. -/ @[to_additive] theorem image_range_orderOf [DecidableEq G] : letI : Fintype (zpowers x) := (Subgroup.zpowers x).instFintypeSubtypeMemOfDecidablePred Finset.image (fun i => x ^ i) (Finset.range (orderOf x)) = (zpowers x : Set G).toFinset := by letI : Fintype (zpowers x) := (Subgroup.zpowers x).instFintypeSubtypeMemOfDecidablePred ext x rw [Set.mem_toFinset, SetLike.mem_coe, mem_zpowers_iff_mem_range_orderOf] /- TODO: Generalise to `Finite` + `CancelMonoid`. -/ @[to_additive gcd_nsmul_card_eq_zero_iff] theorem pow_gcd_card_eq_one_iff : x ^ n = 1 ↔ x ^ gcd n (Fintype.card G) = 1 := ⟨fun h => pow_gcd_eq_one _ h <\| pow_card_eq_one, fun h => by let ⟨m, hm⟩ := gcd_dvd_left n (Fintype.card G) rw [hm, pow_mul, h, one_pow]⟩ lemma smul_eq_of_le_smul {G : Type} [Group G] [Finite G] {α : Type} [PartialOrder α] {g : G} {a : α} [MulAction G α] [CovariantClass G α HSMul.hSMul LE.le] (h : a ≤ g • a) : g • a = a := by have key := smul_mono_right g (le_pow_smul h (Nat.card G - 1)) rw [smul_smul, ← _root_.pow_succ', Nat.sub_one_add_one_eq_of_pos Nat.card_pos, pow_card_eq_one', one_smul] at key exact le_antisymm key h lemma smul_eq_of_smul_le {G : Type} [Group G] [Finite G] {α : Type} [PartialOrder α] {g : G} {a : α} [MulAction G α] [CovariantClass G α HSMul.hSMul LE.le] (h : g • a ≤ a) : g • a = a := by have key := smul_mono_right g (pow_smul_le h (Nat.card G - 1)) rw [smul_smul, ← _root_.pow_succ', Nat.sub_one_add_one_eq_of_pos Nat.card_pos, pow_card_eq_one', one_smul] at key exact le_antisymm h key end FiniteGroup section PowIsSubgroup /-- A nonempty idempotent subset of a finite cancellative monoid is a submonoid -/ @[to_additive "A nonempty idempotent subset of a finite cancellative add monoid is a submonoid"] def submonoidOfIdempotent {M : Type} [LeftCancelMonoid M] [Finite M] (S : Set M) (hS1 : S.Nonempty) (hS2 : S * S = S) : Submonoid M := have pow_mem (a : M) (ha : a ∈ S) (n : ℕ) : a ^ (n + 1) ∈ S := by induction n with \| zero => rwa [zero_add, pow_one] \| succ n ih => rw [← hS2, pow_succ] exact Set.mul_mem_mul ih ha { carrier := S one_mem' := by obtain ⟨a, ha⟩ := hS1 rw [← pow_orderOf_eq_one a, ← tsub_add_cancel_of_le (succ_le_of_lt (orderOf_pos a))] exact pow_mem a ha (orderOf a - 1) mul_mem' := fun ha hb => (congr_arg₂ (· ∈ ·) rfl hS2).mp (Set.mul_mem_mul ha hb) } /-- A nonempty idempotent subset of a finite group is a subgroup -/ @[to_additive "A nonempty idempotent subset of a finite add group is a subgroup"] def subgroupOfIdempotent {G : Type} [Group G] [Finite G] (S : Set G) (hS1 : S.Nonempty) (hS2 : S S = S) : Subgroup G := { submonoidOfIdempotent S hS1 hS2 with carrier := S inv_mem' := fun {a} ha => show a⁻¹ ∈ submonoidOfIdempotent S hS1 hS2 by rw [← one_mul a⁻¹, ← pow_one a, ← pow_orderOf_eq_one a, ← pow_sub a (orderOf_pos a)] exact pow_mem ha (orderOf a - 1) } /-- If `S` is a nonempty subset of a finite group `G`, then `S ^ \|G\|` is a subgroup -/ @[to_additive (attr := simps!) smulCardAddSubgroup "If `S` is a nonempty subset of a finite add group `G`, then `\|G\| • S` is a subgroup"] def powCardSubgroup {G : Type*} [Group G] [Fintype G] (S : Set G) (hS : S.Nonempty) : Subgroup G := have one_mem : (1 : G) ∈ S ^ Fintype.card G := by obtain ⟨a, ha⟩ := hS rw [← pow_card_eq_one] exact Set.pow_mem_pow ha subgroupOfIdempotent (S ^ Fintype.card G) ⟨1, one_mem⟩ <\| by classical apply (Set.eq_of_subset_of_card_le (Set.subset_mul_left _ one_mem) (ge_of_eq _)).symm simp_rw [← pow_add, Group.card_pow_eq_card_pow_card_univ S (Fintype.card G + Fintype.card G) le_add_self] end PowIsSubgroup section LinearOrderedSemiring variable [Semiring G] [LinearOrder G] [IsStrictOrderedRing G] {a : G} protected lemma IsOfFinOrder.eq_one (ha₀ : 0 ≤ a) (ha : IsOfFinOrder a) : a = 1 := by obtain ⟨n, hn, ha⟩ := ha.exists_pow_eq_one exact (pow_eq_one_iff_of_nonneg ha₀ hn.ne').1 ha end LinearOrderedSemiring section LinearOrderedRing variable [Ring G] [LinearOrder G] [IsStrictOrderedRing G] {a x : G} protected lemma IsOfFinOrder.eq_neg_one (ha₀ : a ≤ 0) (ha : IsOfFinOrder a) : a = -1 := (sq_eq_one_iff.1 <\| ha.pow.eq_one <\| sq_nonneg a).resolve_left <\| by rintro rfl; exact one_pos.not_le ha₀ theorem orderOf_abs_ne_one (h : \|x\| ≠ 1) : orderOf x = 0 := by rw [orderOf_eq_zero_iff'] intro n hn hx replace hx : \|x\| ^ n = 1 := by simpa only [abs_one, abs_pow] using congr_arg abs hx rcases h.lt_or_lt with h \| h · exact ((pow_lt_one₀ (abs_nonneg x) h hn.ne').ne hx).elim · exact ((one_lt_pow₀ h hn.ne').ne' hx).elim theorem LinearOrderedRing.orderOf_le_two : orderOf x ≤ 2 := by rcases ne_or_eq \|x\| 1 with h \| h · simp [orderOf_abs_ne_one h] rcases eq_or_eq_neg_of_abs_eq h with (rfl \| rfl) · simp exact orderOf_le_of_pow_eq_one zero_lt_two (by simp) end LinearOrderedRing section Prod variable [Monoid α] [Monoid β] {x : α × β} {a : α} {b : β} @[to_additive] protected theorem Prod.orderOf (x : α × β) : orderOf x = (orderOf x.1).lcm (orderOf x.2) := minimalPeriod_prodMap _ _ _ @[to_additive] theorem orderOf_fst_dvd_orderOf : orderOf x.1 ∣ orderOf x := minimalPeriod_fst_dvd @[to_additive] theorem orderOf_snd_dvd_orderOf : orderOf x.2 ∣ orderOf x := minimalPeriod_snd_dvd @[to_additive] theorem IsOfFinOrder.fst {x : α × β} (hx : IsOfFinOrder x) : IsOfFinOrder x.1 := hx.mono orderOf_fst_dvd_orderOf @[to_additive] theorem IsOfFinOrder.snd {x : α × β} (hx : IsOfFinOrder x) : IsOfFinOrder x.2 :=	hx.mono orderOf_snd_dvd_orderOf @[to_additive IsOfFinAddOrder.prod_mk] theorem IsOfFinOrder.prod_mk : IsOfFinOrder a → IsOfFinOrder b → IsOfFinOrder (a, b) := by	Mathlib/GroupTheory/OrderOfElement.lean	1,106	1,109
/- Copyright (c) 2020 Markus Himmel. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Markus Himmel -/ import Mathlib.RingTheory.Ideal.Maps /-! # Ideals in product rings For commutative rings `R` and `S` and ideals `I ≤ R`, `J ≤ S`, we define `Ideal.prod I J` as the product `I × J`, viewed as an ideal of `R × S`. In `ideal_prod_eq` we show that every ideal of `R × S` is of this form. Furthermore, we show that every prime ideal of `R × S` is of the form `p × S` or `R × p`, where `p` is a prime ideal. -/ universe u v variable {R : Type u} {S : Type v} [Semiring R] [Semiring S] (I : Ideal R) (J : Ideal S) namespace Ideal /-- `I × J` as an ideal of `R × S`. -/ def prod : Ideal (R × S) := I.comap (RingHom.fst R S) ⊓ J.comap (RingHom.snd R S) @[simp] theorem mem_prod {r : R} {s : S} : (⟨r, s⟩ : R × S) ∈ prod I J ↔ r ∈ I ∧ s ∈ J := Iff.rfl @[simp] theorem prod_top_top : prod (⊤ : Ideal R) (⊤ : Ideal S) = ⊤ := Ideal.ext <\| by simp /-- Every ideal of the product ring is of the form `I × J`, where `I` and `J` can be explicitly given as the image under the projection maps. -/ theorem ideal_prod_eq (I : Ideal (R × S)) : I = Ideal.prod (map (RingHom.fst R S) I : Ideal R) (map (RingHom.snd R S) I) := by apply Ideal.ext rintro ⟨r, s⟩ rw [mem_prod, mem_map_iff_of_surjective (RingHom.fst R S) Prod.fst_surjective, mem_map_iff_of_surjective (RingHom.snd R S) Prod.snd_surjective] refine ⟨fun h => ⟨⟨_, ⟨h, rfl⟩⟩, ⟨_, ⟨h, rfl⟩⟩⟩, ?_⟩ rintro ⟨⟨⟨r, s'⟩, ⟨h₁, rfl⟩⟩, ⟨⟨r', s⟩, ⟨h₂, rfl⟩⟩⟩ simpa using I.add_mem (I.mul_mem_left (1, 0) h₁) (I.mul_mem_left (0, 1) h₂) @[simp] theorem map_fst_prod (I : Ideal R) (J : Ideal S) : map (RingHom.fst R S) (prod I J) = I := by ext x rw [mem_map_iff_of_surjective (RingHom.fst R S) Prod.fst_surjective] exact ⟨by rintro ⟨x, ⟨h, rfl⟩⟩ exact h.1, fun h => ⟨⟨x, 0⟩, ⟨⟨h, Ideal.zero_mem _⟩, rfl⟩⟩⟩ @[simp] theorem map_snd_prod (I : Ideal R) (J : Ideal S) : map (RingHom.snd R S) (prod I J) = J := by ext x rw [mem_map_iff_of_surjective (RingHom.snd R S) Prod.snd_surjective] exact ⟨by rintro ⟨x, ⟨h, rfl⟩⟩ exact h.2, fun h => ⟨⟨0, x⟩, ⟨⟨Ideal.zero_mem _, h⟩, rfl⟩⟩⟩ @[simp] theorem map_prodComm_prod : map ((RingEquiv.prodComm : R × S ≃+* S × R) : R × S →+* S × R) (prod I J) = prod J I := by refine Trans.trans (ideal_prod_eq _) ?_ simp [map_map] /-- Ideals of `R × S` are in one-to-one correspondence with pairs of ideals of `R` and ideals of `S`. -/ def idealProdEquiv : Ideal (R × S) ≃o Ideal R × Ideal S where toFun I := ⟨map (RingHom.fst R S) I, map (RingHom.snd R S) I⟩ invFun I := prod I.1 I.2 left_inv I := (ideal_prod_eq I).symm right_inv := fun ⟨I, J⟩ => by simp map_rel_iff' {I J} := by simp only [Equiv.coe_fn_mk, ge_iff_le, Prod.mk_le_mk] refine ⟨fun h ↦ ?_, fun h ↦ ⟨map_mono h, map_mono h⟩⟩ rw [ideal_prod_eq I, ideal_prod_eq J] exact inf_le_inf (comap_mono h.1) (comap_mono h.2) @[simp] theorem idealProdEquiv_symm_apply (I : Ideal R) (J : Ideal S) : idealProdEquiv.symm ⟨I, J⟩ = prod I J := rfl theorem prod.ext_iff {I I' : Ideal R} {J J' : Ideal S} : prod I J = prod I' J' ↔ I = I' ∧ J = J' := by simp only [← idealProdEquiv_symm_apply, idealProdEquiv.symm.injective.eq_iff, Prod.mk_inj] theorem isPrime_of_isPrime_prod_top {I : Ideal R} (h : (Ideal.prod I (⊤ : Ideal S)).IsPrime) : I.IsPrime := by constructor · contrapose! h rw [h, prod_top_top, isPrime_iff] simp [isPrime_iff, h] · intro x y hxy have : (⟨x, 1⟩ : R × S) * ⟨y, 1⟩ ∈ prod I ⊤ := by rw [Prod.mk_mul_mk, mul_one, mem_prod] exact ⟨hxy, trivial⟩ simpa using h.mem_or_mem this theorem isPrime_of_isPrime_prod_top' {I : Ideal S} (h : (Ideal.prod (⊤ : Ideal R) I).IsPrime) : I.IsPrime := by apply isPrime_of_isPrime_prod_top (S := R) rw [← map_prodComm_prod] -- Note: couldn't synthesize the right instances without the `R` and `S` hints exact map_isPrime_of_equiv (RingEquiv.prodComm (R := R) (S := S)) theorem isPrime_ideal_prod_top {I : Ideal R} [h : I.IsPrime] : (prod I (⊤ : Ideal S)).IsPrime := by constructor · rcases h with ⟨h, -⟩ contrapose! h rw [← prod_top_top, prod.ext_iff] at h exact h.1 rintro ⟨r₁, s₁⟩ ⟨r₂, s₂⟩ ⟨h₁, _⟩ rcases h.mem_or_mem h₁ with h \| h · exact Or.inl ⟨h, trivial⟩ · exact Or.inr ⟨h, trivial⟩ theorem isPrime_ideal_prod_top' {I : Ideal S} [h : I.IsPrime] : (prod (⊤ : Ideal R) I).IsPrime := by letI : IsPrime (prod I (⊤ : Ideal R)) := isPrime_ideal_prod_top rw [← map_prodComm_prod] -- Note: couldn't synthesize the right instances without the `R` and `S` hints exact map_isPrime_of_equiv (RingEquiv.prodComm (R := S) (S := R)) theorem ideal_prod_prime_aux {I : Ideal R} {J : Ideal S} : (Ideal.prod I J).IsPrime → I = ⊤ ∨ J = ⊤ := by contrapose! simp only [ne_top_iff_one, isPrime_iff, not_and, not_forall, not_or] exact fun ⟨hI, hJ⟩ _ => ⟨⟨0, 1⟩, ⟨1, 0⟩, by simp, by simp [hJ], by simp [hI]⟩ /-- Classification of prime ideals in product rings: the prime ideals of `R × S` are precisely the ideals of the form `p × S` or `R × p`, where `p` is a prime ideal of `R` or `S`. -/ theorem ideal_prod_prime (I : Ideal (R × S)) : I.IsPrime ↔ (∃ p : Ideal R, p.IsPrime ∧ I = Ideal.prod p ⊤) ∨ ∃ p : Ideal S, p.IsPrime ∧ I = Ideal.prod ⊤ p := by constructor · rw [ideal_prod_eq I] intro hI rcases ideal_prod_prime_aux hI with (h \| h) · right rw [h] at hI ⊢ exact ⟨_, ⟨isPrime_of_isPrime_prod_top' hI, rfl⟩⟩ · left rw [h] at hI ⊢ exact ⟨_, ⟨isPrime_of_isPrime_prod_top hI, rfl⟩⟩ · rintro (⟨p, ⟨h, rfl⟩⟩ \| ⟨p, ⟨h, rfl⟩⟩) · exact isPrime_ideal_prod_top · exact isPrime_ideal_prod_top' end Ideal		Mathlib/RingTheory/Ideal/Prod.lean	157	173
/- Copyright (c) 2020 Kim Morrison. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kim Morrison, Eric Wieser -/ import Mathlib.Data.Matrix.Basis import Mathlib.Data.Matrix.Composition import Mathlib.Data.Matrix.Kronecker import Mathlib.RingTheory.TensorProduct.Basic /-! # Algebra isomorphisms between tensor products and matrices ## Main definitions * `matrixEquivTensor : Matrix n n A ≃ₐ[R] (A ⊗[R] Matrix n n R)`. * `Matrix.kroneckerTMulAlgEquiv : Matrix m m A ⊗[R] Matrix n n B ≃ₐ[R] Matrix (m × n) (m × n) (A ⊗[R] B)`, where the forward map is the (tensor-ified) kronecker product. -/ suppress_compilation open TensorProduct Algebra.TensorProduct Matrix variable {l m n p : Type} {R A B M N : Type} section Module variable [CommSemiring R] [AddCommMonoid M] [AddCommMonoid N] [Semiring A] [Semiring B] variable [Module R M] [Module R N] [Algebra R A] [Algebra R B] variable [Fintype l] [Fintype m] [Fintype n] [Fintype p] variable [DecidableEq l] [DecidableEq m] [DecidableEq n] [DecidableEq p] open Kronecker variable (l m n p R M N) attribute [local ext] ext_linearMap /-- `Matrix.kroneckerTMul` as a linear equivalence, when the two arguments are tensored. -/ def kroneckerTMulLinearEquiv : Matrix l m M ⊗[R] Matrix n p N ≃ₗ[R] Matrix (l × n) (m × p) (M ⊗[R] N) := .ofLinear (TensorProduct.lift <\| kroneckerTMulBilinear _) ((LinearMap.lsum R _ R fun ii => LinearMap.lsum R _ R fun jj => TensorProduct.map (stdBasisMatrixLinearMap R ii.1 jj.1) (stdBasisMatrixLinearMap R ii.2 jj.2)) ∘ₗ (ofLinearEquiv R).symm.toLinearMap) (by ext : 4 simp [-LinearMap.lsum_apply, LinearMap.lsum_piSingle, stdBasisMatrix_kroneckerTMul_stdBasisMatrix]) (by ext : 5 simp [-LinearMap.lsum_apply, LinearMap.lsum_piSingle, stdBasisMatrix_kroneckerTMul_stdBasisMatrix]) @[simp] theorem kroneckerTMulLinearEquiv_tmul (a : Matrix l m M) (b : Matrix n p N) : kroneckerTMulLinearEquiv l m n p R M N (a ⊗ₜ b) = a ⊗ₖₜ b := rfl @[simp] theorem kroneckerTMulAlgEquiv_symm_stdBasisMatrix_tmul (ia : l) (ja : m) (ib : n) (jb : p) (a : M) (b : N) : (kroneckerTMulLinearEquiv l m n p R M N).symm (stdBasisMatrix (ia, ib) (ja, jb) (a ⊗ₜ b)) = stdBasisMatrix ia ja a ⊗ₜ stdBasisMatrix ib jb b := by rw [LinearEquiv.symm_apply_eq, kroneckerTMulLinearEquiv_tmul, stdBasisMatrix_kroneckerTMul_stdBasisMatrix] @[simp] theorem kroneckerTMulLinearEquiv_one : kroneckerTMulLinearEquiv m m n n R A B 1 = 1 := by simp [Algebra.TensorProduct.one_def] /-- Note this can't be stated for rectangular matrices because there is no `HMul (TensorProduct R _ _) (TensorProduct R _ _) (TensorProduct R _ _)` instance. -/ @[simp] theorem kroneckerTMulLinearEquiv_mul : ∀ x y : Matrix m m A ⊗[R] Matrix n n B, kroneckerTMulLinearEquiv m m n n R A B (x * y) = kroneckerTMulLinearEquiv m m n n R A B x * kroneckerTMulLinearEquiv m m n n R A B y := (kroneckerTMulLinearEquiv m m n n R A B).toLinearMap.map_mul_iff.2 <\| by ext : 10 simp [stdBasisMatrix_kroneckerTMul_stdBasisMatrix, mul_kroneckerTMul_mul] end Module variable [CommSemiring R]	variable [Semiring A] [Semiring B] [Algebra R A] [Algebra R B]	Mathlib/RingTheory/MatrixAlgebra.lean	89	89
/- Copyright (c) 2022 Andrew Yang. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Andrew Yang -/ import Mathlib.AlgebraicGeometry.Gluing import Mathlib.CategoryTheory.Limits.Opposites import Mathlib.AlgebraicGeometry.AffineScheme import Mathlib.CategoryTheory.Limits.Shapes.Diagonal import Mathlib.CategoryTheory.ChosenFiniteProducts.Over /-! # Fibred products of schemes In this file we construct the fibred product of schemes via gluing. We roughly follow [har77] Theorem 3.3. In particular, the main construction is to show that for an open cover `{ Uᵢ }` of `X`, if there exist fibred products `Uᵢ ×[Z] Y` for each `i`, then there exists a fibred product `X ×[Z] Y`. Then, for constructing the fibred product for arbitrary schemes `X, Y, Z`, we can use the construction to reduce to the case where `X, Y, Z` are all affine, where fibred products are constructed via tensor products. -/ universe v u noncomputable section open CategoryTheory CategoryTheory.Limits AlgebraicGeometry namespace AlgebraicGeometry.Scheme namespace Pullback variable {C : Type u} [Category.{v} C] variable {X Y Z : Scheme.{u}} (𝒰 : OpenCover.{u} X) (f : X ⟶ Z) (g : Y ⟶ Z) variable [∀ i, HasPullback (𝒰.map i ≫ f) g] /-- The intersection of `Uᵢ ×[Z] Y` and `Uⱼ ×[Z] Y` is given by (Uᵢ ×[Z] Y) ×[X] Uⱼ -/ def v (i j : 𝒰.J) : Scheme := pullback ((pullback.fst (𝒰.map i ≫ f) g) ≫ 𝒰.map i) (𝒰.map j) /-- The canonical transition map `(Uᵢ ×[Z] Y) ×[X] Uⱼ ⟶ (Uⱼ ×[Z] Y) ×[X] Uᵢ` given by the fact that pullbacks are associative and symmetric. -/ def t (i j : 𝒰.J) : v 𝒰 f g i j ⟶ v 𝒰 f g j i := by have : HasPullback (pullback.snd _ _ ≫ 𝒰.map i ≫ f) g := hasPullback_assoc_symm (𝒰.map j) (𝒰.map i) (𝒰.map i ≫ f) g have : HasPullback (pullback.snd _ _ ≫ 𝒰.map j ≫ f) g := hasPullback_assoc_symm (𝒰.map i) (𝒰.map j) (𝒰.map j ≫ f) g refine (pullbackSymmetry ..).hom ≫ (pullbackAssoc ..).inv ≫ ?_ refine ?_ ≫ (pullbackAssoc ..).hom ≫ (pullbackSymmetry ..).hom refine pullback.map _ _ _ _ (pullbackSymmetry _ _).hom (𝟙 _) (𝟙 _) ?_ ?_ · rw [pullbackSymmetry_hom_comp_snd_assoc, pullback.condition_assoc, Category.comp_id] · rw [Category.comp_id, Category.id_comp] @[simp, reassoc] theorem t_fst_fst (i j : 𝒰.J) : t 𝒰 f g i j ≫ pullback.fst _ _ ≫ pullback.fst _ _ = pullback.snd _ _ := by simp only [t, Category.assoc, pullbackSymmetry_hom_comp_fst_assoc, pullbackAssoc_hom_snd_fst, pullback.lift_fst_assoc, pullbackSymmetry_hom_comp_snd, pullbackAssoc_inv_fst_fst, pullbackSymmetry_hom_comp_fst] @[simp, reassoc] theorem t_fst_snd (i j : 𝒰.J) : t 𝒰 f g i j ≫ pullback.fst _ _ ≫ pullback.snd _ _ = pullback.fst _ _ ≫ pullback.snd _ _ := by simp only [t, Category.assoc, pullbackSymmetry_hom_comp_fst_assoc, pullbackAssoc_hom_snd_snd, pullback.lift_snd, Category.comp_id, pullbackAssoc_inv_snd, pullbackSymmetry_hom_comp_snd_assoc] @[simp, reassoc] theorem t_snd (i j : 𝒰.J) : t 𝒰 f g i j ≫ pullback.snd _ _ = pullback.fst _ _ ≫ pullback.fst _ _ := by simp only [t, Category.assoc, pullbackSymmetry_hom_comp_snd, pullbackAssoc_hom_fst, pullback.lift_fst_assoc, pullbackSymmetry_hom_comp_fst, pullbackAssoc_inv_fst_snd, pullbackSymmetry_hom_comp_snd_assoc] theorem t_id (i : 𝒰.J) : t 𝒰 f g i i = 𝟙 _ := by apply pullback.hom_ext <;> rw [Category.id_comp] · apply pullback.hom_ext · rw [← cancel_mono (𝒰.map i)]; simp only [pullback.condition, Category.assoc, t_fst_fst] · simp only [Category.assoc, t_fst_snd] · rw [← cancel_mono (𝒰.map i)]; simp only [pullback.condition, t_snd, Category.assoc] /-- The inclusion map of `V i j = (Uᵢ ×[Z] Y) ×[X] Uⱼ ⟶ Uᵢ ×[Z] Y` -/ abbrev fV (i j : 𝒰.J) : v 𝒰 f g i j ⟶ pullback (𝒰.map i ≫ f) g := pullback.fst _ _ /-- The map `((Xᵢ ×[Z] Y) ×[X] Xⱼ) ×[Xᵢ ×[Z] Y] ((Xᵢ ×[Z] Y) ×[X] Xₖ)` ⟶ `((Xⱼ ×[Z] Y) ×[X] Xₖ) ×[Xⱼ ×[Z] Y] ((Xⱼ ×[Z] Y) ×[X] Xᵢ)` needed for gluing -/ def t' (i j k : 𝒰.J) : pullback (fV 𝒰 f g i j) (fV 𝒰 f g i k) ⟶ pullback (fV 𝒰 f g j k) (fV 𝒰 f g j i) := by refine (pullbackRightPullbackFstIso ..).hom ≫ ?_ refine ?_ ≫ (pullbackSymmetry _ _).hom refine ?_ ≫ (pullbackRightPullbackFstIso ..).inv refine pullback.map _ _ _ _ (t 𝒰 f g i j) (𝟙 _) (𝟙 _) ?_ ?_ · simp_rw [Category.comp_id, t_fst_fst_assoc, ← pullback.condition] · rw [Category.comp_id, Category.id_comp] @[simp, reassoc] theorem t'_fst_fst_fst (i j k : 𝒰.J) : t' 𝒰 f g i j k ≫ pullback.fst _ _ ≫ pullback.fst _ _ ≫ pullback.fst _ _ = pullback.fst _ _ ≫ pullback.snd _ _ := by simp only [t', Category.assoc, pullbackSymmetry_hom_comp_fst_assoc, pullbackRightPullbackFstIso_inv_snd_fst_assoc, pullback.lift_fst_assoc, t_fst_fst, pullbackRightPullbackFstIso_hom_fst_assoc] @[simp, reassoc] theorem t'_fst_fst_snd (i j k : 𝒰.J) : t' 𝒰 f g i j k ≫ pullback.fst _ _ ≫ pullback.fst _ _ ≫ pullback.snd _ _ = pullback.fst _ _ ≫ pullback.fst _ _ ≫ pullback.snd _ _ := by simp only [t', Category.assoc, pullbackSymmetry_hom_comp_fst_assoc, pullbackRightPullbackFstIso_inv_snd_fst_assoc, pullback.lift_fst_assoc, t_fst_snd, pullbackRightPullbackFstIso_hom_fst_assoc] @[simp, reassoc] theorem t'_fst_snd (i j k : 𝒰.J) : t' 𝒰 f g i j k ≫ pullback.fst _ _ ≫ pullback.snd _ _ = pullback.snd _ _ ≫ pullback.snd _ _ := by simp only [t', Category.assoc, pullbackSymmetry_hom_comp_fst_assoc, pullbackRightPullbackFstIso_inv_snd_snd, pullback.lift_snd, Category.comp_id, pullbackRightPullbackFstIso_hom_snd] @[simp, reassoc] theorem t'_snd_fst_fst (i j k : 𝒰.J) : t' 𝒰 f g i j k ≫ pullback.snd _ _ ≫ pullback.fst _ _ ≫ pullback.fst _ _ = pullback.fst _ _ ≫ pullback.snd _ _ := by simp only [t', Category.assoc, pullbackSymmetry_hom_comp_snd_assoc, pullbackRightPullbackFstIso_inv_fst_assoc, pullback.lift_fst_assoc, t_fst_fst, pullbackRightPullbackFstIso_hom_fst_assoc] @[simp, reassoc] theorem t'_snd_fst_snd (i j k : 𝒰.J) : t' 𝒰 f g i j k ≫ pullback.snd _ _ ≫ pullback.fst _ _ ≫ pullback.snd _ _ = pullback.fst _ _ ≫ pullback.fst _ _ ≫ pullback.snd _ _ := by simp only [t', Category.assoc, pullbackSymmetry_hom_comp_snd_assoc, pullbackRightPullbackFstIso_inv_fst_assoc, pullback.lift_fst_assoc, t_fst_snd, pullbackRightPullbackFstIso_hom_fst_assoc] @[simp, reassoc] theorem t'_snd_snd (i j k : 𝒰.J) : t' 𝒰 f g i j k ≫ pullback.snd _ _ ≫ pullback.snd _ _ = pullback.fst _ _ ≫ pullback.fst _ _ ≫ pullback.fst _ _ := by simp only [t', Category.assoc, pullbackSymmetry_hom_comp_snd_assoc, pullbackRightPullbackFstIso_inv_fst_assoc, pullback.lift_fst_assoc, t_snd, pullbackRightPullbackFstIso_hom_fst_assoc] theorem cocycle_fst_fst_fst (i j k : 𝒰.J) : t' 𝒰 f g i j k ≫ t' 𝒰 f g j k i ≫ t' 𝒰 f g k i j ≫ pullback.fst _ _ ≫ pullback.fst _ _ ≫ pullback.fst _ _ = pullback.fst _ _ ≫ pullback.fst _ _ ≫ pullback.fst _ _ := by simp only [t'_fst_fst_fst, t'_fst_snd, t'_snd_snd] theorem cocycle_fst_fst_snd (i j k : 𝒰.J) : t' 𝒰 f g i j k ≫ t' 𝒰 f g j k i ≫ t' 𝒰 f g k i j ≫ pullback.fst _ _ ≫ pullback.fst _ _ ≫ pullback.snd _ _ = pullback.fst _ _ ≫ pullback.fst _ _ ≫ pullback.snd _ _ := by simp only [t'_fst_fst_snd] theorem cocycle_fst_snd (i j k : 𝒰.J) : t' 𝒰 f g i j k ≫ t' 𝒰 f g j k i ≫ t' 𝒰 f g k i j ≫ pullback.fst _ _ ≫ pullback.snd _ _ = pullback.fst _ _ ≫ pullback.snd _ _ := by simp only [t'_fst_snd, t'_snd_snd, t'_fst_fst_fst] theorem cocycle_snd_fst_fst (i j k : 𝒰.J) : t' 𝒰 f g i j k ≫ t' 𝒰 f g j k i ≫ t' 𝒰 f g k i j ≫ pullback.snd _ _ ≫ pullback.fst _ _ ≫ pullback.fst _ _ = pullback.snd _ _ ≫ pullback.fst _ _ ≫ pullback.fst _ _ := by rw [← cancel_mono (𝒰.map i)] simp only [pullback.condition_assoc, t'_snd_fst_fst, t'_fst_snd, t'_snd_snd] theorem cocycle_snd_fst_snd (i j k : 𝒰.J) : t' 𝒰 f g i j k ≫ t' 𝒰 f g j k i ≫ t' 𝒰 f g k i j ≫ pullback.snd _ _ ≫ pullback.fst _ _ ≫ pullback.snd _ _ = pullback.snd _ _ ≫ pullback.fst _ _ ≫ pullback.snd _ _ := by simp only [pullback.condition_assoc, t'_snd_fst_snd] theorem cocycle_snd_snd (i j k : 𝒰.J) : t' 𝒰 f g i j k ≫ t' 𝒰 f g j k i ≫ t' 𝒰 f g k i j ≫ pullback.snd _ _ ≫ pullback.snd _ _ = pullback.snd _ _ ≫ pullback.snd _ _ := by simp only [t'_snd_snd, t'_fst_fst_fst, t'_fst_snd] -- `by tidy` should solve it, but it times out. theorem cocycle (i j k : 𝒰.J) : t' 𝒰 f g i j k ≫ t' 𝒰 f g j k i ≫ t' 𝒰 f g k i j = 𝟙 _ := by apply pullback.hom_ext <;> rw [Category.id_comp] · apply pullback.hom_ext · apply pullback.hom_ext · simp_rw [Category.assoc, cocycle_fst_fst_fst 𝒰 f g i j k] · simp_rw [Category.assoc, cocycle_fst_fst_snd 𝒰 f g i j k] · simp_rw [Category.assoc, cocycle_fst_snd 𝒰 f g i j k] · apply pullback.hom_ext · apply pullback.hom_ext · simp_rw [Category.assoc, cocycle_snd_fst_fst 𝒰 f g i j k] · simp_rw [Category.assoc, cocycle_snd_fst_snd 𝒰 f g i j k] · simp_rw [Category.assoc, cocycle_snd_snd 𝒰 f g i j k] /-- Given `Uᵢ ×[Z] Y`, this is the glued fibered product `X ×[Z] Y`. -/ @[simps U V f t t', simps -isSimp J] def gluing : Scheme.GlueData.{u} where J := 𝒰.J U i := pullback (𝒰.map i ≫ f) g V := fun ⟨i, j⟩ => v 𝒰 f g i j -- `p⁻¹(Uᵢ ∩ Uⱼ)` where `p : Uᵢ ×[Z] Y ⟶ Uᵢ ⟶ X`. f _ _ := pullback.fst _ _ f_id _ := inferInstance f_open := inferInstance t i j := t 𝒰 f g i j t_id i := t_id 𝒰 f g i t' i j k := t' 𝒰 f g i j k t_fac i j k := by apply pullback.hom_ext on_goal 1 => apply pullback.hom_ext all_goals simp only [t'_snd_fst_fst, t'_snd_fst_snd, t'_snd_snd, t_fst_fst, t_fst_snd, t_snd, Category.assoc] cocycle i j k := cocycle 𝒰 f g i j k @[simp] lemma gluing_ι (j : 𝒰.J) : (gluing 𝒰 f g).ι j = Multicoequalizer.π (gluing 𝒰 f g).diagram j := rfl /-- The first projection from the glued scheme into `X`. -/ def p1 : (gluing 𝒰 f g).glued ⟶ X := by apply Multicoequalizer.desc (gluing 𝒰 f g).diagram _ fun i ↦ pullback.fst _ _ ≫ 𝒰.map i simp [t_fst_fst_assoc, ← pullback.condition] /-- The second projection from the glued scheme into `Y`. -/ def p2 : (gluing 𝒰 f g).glued ⟶ Y := by apply Multicoequalizer.desc _ _ fun i ↦ pullback.snd _ _ simp [t_fst_snd] theorem p_comm : p1 𝒰 f g ≫ f = p2 𝒰 f g ≫ g := by apply Multicoequalizer.hom_ext simp [p1, p2, pullback.condition] variable (s : PullbackCone f g) /-- (Implementation) The canonical map `(s.X ×[X] Uᵢ) ×[s.X] (s.X ×[X] Uⱼ) ⟶ (Uᵢ ×[Z] Y) ×[X] Uⱼ` This is used in `gluedLift`. -/ def gluedLiftPullbackMap (i j : 𝒰.J) : pullback ((𝒰.pullbackCover s.fst).map i) ((𝒰.pullbackCover s.fst).map j) ⟶ (gluing 𝒰 f g).V ⟨i, j⟩ := by refine (pullbackRightPullbackFstIso _ _ _).hom ≫ ?_ refine pullback.map _ _ _ _ ?_ (𝟙 _) (𝟙 _) ?_ ?_ · exact (pullbackSymmetry _ _).hom ≫ pullback.map _ _ _ _ (𝟙 _) s.snd f (Category.id_comp _).symm s.condition · simpa using pullback.condition · simp only [Category.comp_id, Category.id_comp] @[reassoc] theorem gluedLiftPullbackMap_fst (i j : 𝒰.J) : gluedLiftPullbackMap 𝒰 f g s i j ≫ pullback.fst _ _ = pullback.fst _ _ ≫ (pullbackSymmetry _ _).hom ≫ pullback.map _ _ _ _ (𝟙 _) s.snd f (Category.id_comp _).symm s.condition := by simp [gluedLiftPullbackMap] @[reassoc] theorem gluedLiftPullbackMap_snd (i j : 𝒰.J) : gluedLiftPullbackMap 𝒰 f g s i j ≫ pullback.snd _ _ = pullback.snd _ _ ≫ pullback.snd _ _ := by simp [gluedLiftPullbackMap] /-- The lifted map `s.X ⟶ (gluing 𝒰 f g).glued` in order to show that `(gluing 𝒰 f g).glued` is indeed the pullback. Given a pullback cone `s`, we have the maps `s.fst ⁻¹' Uᵢ ⟶ Uᵢ` and `s.fst ⁻¹' Uᵢ ⟶ s.X ⟶ Y` that we may lift to a map `s.fst ⁻¹' Uᵢ ⟶ Uᵢ ×[Z] Y`. to glue these into a map `s.X ⟶ Uᵢ ×[Z] Y`, we need to show that the maps agree on `(s.fst ⁻¹' Uᵢ) ×[s.X] (s.fst ⁻¹' Uⱼ) ⟶ Uᵢ ×[Z] Y`. This is achieved by showing that both of these maps factors through `gluedLiftPullbackMap`. -/ def gluedLift : s.pt ⟶ (gluing 𝒰 f g).glued := by fapply (𝒰.pullbackCover s.fst).glueMorphisms · exact fun i ↦ (pullbackSymmetry _ _).hom ≫ pullback.map _ _ _ _ (𝟙 _) s.snd f (Category.id_comp _).symm s.condition ≫ (gluing 𝒰 f g).ι i intro i j rw [← gluedLiftPullbackMap_fst_assoc, ← gluing_f, ← (gluing 𝒰 f g).glue_condition i j, gluing_t, gluing_f] simp_rw [← Category.assoc] congr 1 apply pullback.hom_ext <;> simp_rw [Category.assoc] · rw [t_fst_fst, gluedLiftPullbackMap_snd] congr 1 rw [← Iso.inv_comp_eq, pullbackSymmetry_inv_comp_snd, pullback.lift_fst, Category.comp_id] · rw [t_fst_snd, gluedLiftPullbackMap_fst_assoc, pullback.lift_snd, pullback.lift_snd] simp_rw [pullbackSymmetry_hom_comp_snd_assoc] exact pullback.condition_assoc _ theorem gluedLift_p1 : gluedLift 𝒰 f g s ≫ p1 𝒰 f g = s.fst := by rw [← cancel_epi (𝒰.pullbackCover s.fst).fromGlued] apply Multicoequalizer.hom_ext intro b simp_rw [Cover.fromGlued, Multicoequalizer.π_desc_assoc, gluedLift, ← Category.assoc] simp_rw [(𝒰.pullbackCover s.fst).ι_glueMorphisms] simp [p1, pullback.condition] theorem gluedLift_p2 : gluedLift 𝒰 f g s ≫ p2 𝒰 f g = s.snd := by rw [← cancel_epi (𝒰.pullbackCover s.fst).fromGlued] apply Multicoequalizer.hom_ext intro b simp_rw [Cover.fromGlued, Multicoequalizer.π_desc_assoc, gluedLift, ← Category.assoc] simp_rw [(𝒰.pullbackCover s.fst).ι_glueMorphisms] simp [p2, pullback.condition] /-- (Implementation) The canonical map `(W ×[X] Uᵢ) ×[W] (Uⱼ ×[Z] Y) ⟶ (Uⱼ ×[Z] Y) ×[X] Uᵢ = V j i` where `W` is the glued fibred product. This is used in `lift_comp_ι`. -/ def pullbackFstιToV (i j : 𝒰.J) : pullback (pullback.fst (p1 𝒰 f g) (𝒰.map i)) ((gluing 𝒰 f g).ι j) ⟶ v 𝒰 f g j i := (pullbackSymmetry _ _ ≪≫ pullbackRightPullbackFstIso (p1 𝒰 f g) (𝒰.map i) _).hom ≫ (pullback.congrHom (Multicoequalizer.π_desc ..) rfl).hom @[simp, reassoc] theorem pullbackFstιToV_fst (i j : 𝒰.J) : pullbackFstιToV 𝒰 f g i j ≫ pullback.fst _ _ = pullback.snd _ _ := by simp [pullbackFstιToV, p1] @[simp, reassoc] theorem pullbackFstιToV_snd (i j : 𝒰.J) : pullbackFstιToV 𝒰 f g i j ≫ pullback.snd _ _ = pullback.fst _ _ ≫ pullback.snd _ _ := by simp [pullbackFstιToV, p1] /-- We show that the map `W ×[X] Uᵢ ⟶ Uᵢ ×[Z] Y ⟶ W` is the first projection, where the first map is given by the lift of `W ×[X] Uᵢ ⟶ Uᵢ` and `W ×[X] Uᵢ ⟶ W ⟶ Y`. It suffices to show that the two map agrees when restricted onto `Uⱼ ×[Z] Y`. In this case, both maps factor through `V j i` via `pullback_fst_ι_to_V` -/ theorem lift_comp_ι (i : 𝒰.J) : pullback.lift (pullback.snd _ _) (pullback.fst _ _ ≫ p2 𝒰 f g) (by rw [← pullback.condition_assoc, Category.assoc, p_comm]) ≫ (gluing 𝒰 f g).ι i = (pullback.fst _ _ : pullback (p1 𝒰 f g) (𝒰.map i) ⟶ _) := by apply ((gluing 𝒰 f g).openCover.pullbackCover (pullback.fst _ _)).hom_ext intro j dsimp only [Cover.pullbackCover] trans pullbackFstιToV 𝒰 f g i j ≫ fV 𝒰 f g j i ≫ (gluing 𝒰 f g).ι _ · rw [← show _ = fV 𝒰 f g j i ≫ _ from (gluing 𝒰 f g).glue_condition j i] simp_rw [← Category.assoc] congr 1 rw [gluing_f, gluing_t] apply pullback.hom_ext <;> simp_rw [Category.assoc] · simp_rw [t_fst_fst, pullback.lift_fst, pullbackFstιToV_snd, GlueData.openCover_map] · simp_rw [t_fst_snd, pullback.lift_snd, pullbackFstιToV_fst_assoc, pullback.condition_assoc, GlueData.openCover_map, p2] simp · rw [pullback.condition, ← Category.assoc] simp_rw [pullbackFstιToV_fst, GlueData.openCover_map] /-- The canonical isomorphism between `W ×[X] Uᵢ` and `Uᵢ ×[X] Y`. That is, the preimage of `Uᵢ` in `W` along `p1` is indeed `Uᵢ ×[X] Y`. -/ def pullbackP1Iso (i : 𝒰.J) : pullback (p1 𝒰 f g) (𝒰.map i) ≅ pullback (𝒰.map i ≫ f) g := by fconstructor · exact pullback.lift (pullback.snd _ _) (pullback.fst _ _ ≫ p2 𝒰 f g) (by rw [← pullback.condition_assoc, Category.assoc, p_comm]) · apply pullback.lift ((gluing 𝒰 f g).ι i) (pullback.fst _ _) rw [gluing_ι, p1, Multicoequalizer.π_desc] · apply pullback.hom_ext · simpa using lift_comp_ι 𝒰 f g i · simp_rw [Category.assoc, pullback.lift_snd, pullback.lift_fst, Category.id_comp] · apply pullback.hom_ext · simp_rw [Category.assoc, pullback.lift_fst, pullback.lift_snd, Category.id_comp] · simp [p2] @[simp, reassoc] theorem pullbackP1Iso_hom_fst (i : 𝒰.J) : (pullbackP1Iso 𝒰 f g i).hom ≫ pullback.fst _ _ = pullback.snd _ _ := by simp_rw [pullbackP1Iso, pullback.lift_fst] @[simp, reassoc] theorem pullbackP1Iso_hom_snd (i : 𝒰.J) : (pullbackP1Iso 𝒰 f g i).hom ≫ pullback.snd _ _ = pullback.fst _ _ ≫ p2 𝒰 f g := by simp_rw [pullbackP1Iso, pullback.lift_snd] @[simp, reassoc] theorem pullbackP1Iso_inv_fst (i : 𝒰.J) : (pullbackP1Iso 𝒰 f g i).inv ≫ pullback.fst _ _ = (gluing 𝒰 f g).ι i := by simp_rw [pullbackP1Iso, pullback.lift_fst] @[simp, reassoc] theorem pullbackP1Iso_inv_snd (i : 𝒰.J) : (pullbackP1Iso 𝒰 f g i).inv ≫ pullback.snd _ _ = pullback.fst _ _ := by simp_rw [pullbackP1Iso, pullback.lift_snd] @[simp, reassoc] theorem pullbackP1Iso_hom_ι (i : 𝒰.J) : (pullbackP1Iso 𝒰 f g i).hom ≫ Multicoequalizer.π (gluing 𝒰 f g).diagram i = pullback.fst _ _ := by rw [← gluing_ι, ← pullbackP1Iso_inv_fst, Iso.hom_inv_id_assoc] /-- The glued scheme (`(gluing 𝒰 f g).glued`) is indeed the pullback of `f` and `g`. -/ def gluedIsLimit : IsLimit (PullbackCone.mk _ _ (p_comm 𝒰 f g)) := by apply PullbackCone.isLimitAux' intro s refine ⟨gluedLift 𝒰 f g s, gluedLift_p1 𝒰 f g s, gluedLift_p2 𝒰 f g s, ?_⟩ intro m h₁ h₂ simp_rw [PullbackCone.mk_pt, PullbackCone.mk_π_app] at h₁ h₂ apply (𝒰.pullbackCover s.fst).hom_ext intro i rw [gluedLift, (𝒰.pullbackCover s.fst).ι_glueMorphisms, 𝒰.pullbackCover_map] rw [← cancel_epi (pullbackRightPullbackFstIso (p1 𝒰 f g) (𝒰.map i) m ≪≫ pullback.congrHom h₁ rfl).hom, Iso.trans_hom, Category.assoc, pullback.congrHom_hom, pullback.lift_fst_assoc, Category.comp_id, pullbackRightPullbackFstIso_hom_fst_assoc, pullback.condition] conv_lhs => rhs; rw [← pullbackP1Iso_hom_ι] simp_rw [← Category.assoc] congr 1 apply pullback.hom_ext · simp_rw [Category.assoc, pullbackP1Iso_hom_fst, pullback.lift_fst, Category.comp_id, pullbackSymmetry_hom_comp_fst, pullback.lift_snd, Category.comp_id, pullbackRightPullbackFstIso_hom_snd] · simp_rw [Category.assoc, pullbackP1Iso_hom_snd, pullback.lift_snd, pullbackSymmetry_hom_comp_snd_assoc, pullback.lift_fst_assoc, Category.comp_id, pullbackRightPullbackFstIso_hom_fst_assoc, ← pullback.condition_assoc, h₂]	include 𝒰 in theorem hasPullback_of_cover : HasPullback f g := ⟨⟨⟨_, gluedIsLimit 𝒰 f g⟩⟩⟩	Mathlib/AlgebraicGeometry/Pullbacks.lean	419	421
/- Copyright (c) 2018 Kenny Lau. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kenny Lau, Mario Carneiro, Johan Commelin, Amelia Livingston, Anne Baanen -/ import Mathlib.Algebra.Group.Pointwise.Set.Scalar import Mathlib.Algebra.Ring.Subsemiring.Basic import Mathlib.RingTheory.Localization.Defs /-! # Integer elements of a localization ## Main definitions * `IsLocalization.IsInteger` is a predicate stating that `x : S` is in the image of `R` ## Implementation notes See `Mathlib/RingTheory/Localization/Basic.lean` for a design overview. ## Tags localization, ring localization, commutative ring localization, characteristic predicate, commutative ring, field of fractions -/ variable {R : Type} [CommSemiring R] {M : Submonoid R} {S : Type} [CommSemiring S] variable [Algebra R S] {P : Type} [CommSemiring P] open Function namespace IsLocalization section variable (R) -- TODO: define a subalgebra of `IsInteger`s /-- Given `a : S`, `S` a localization of `R`, `IsInteger R a` iff `a` is in the image of the localization map from `R` to `S`. -/ def IsInteger (a : S) : Prop := a ∈ (algebraMap R S).rangeS end theorem isInteger_zero : IsInteger R (0 : S) := Subsemiring.zero_mem _ theorem isInteger_one : IsInteger R (1 : S) := Subsemiring.one_mem _ theorem isInteger_add {a b : S} (ha : IsInteger R a) (hb : IsInteger R b) : IsInteger R (a + b) := Subsemiring.add_mem _ ha hb theorem isInteger_mul {a b : S} (ha : IsInteger R a) (hb : IsInteger R b) : IsInteger R (a b) := Subsemiring.mul_mem _ ha hb theorem isInteger_smul {a : R} {b : S} (hb : IsInteger R b) : IsInteger R (a • b) := by rcases hb with ⟨b', hb⟩ use a * b' rw [← hb, (algebraMap R S).map_mul, Algebra.smul_def] variable (M) variable [IsLocalization M S] /-- Each element `a : S` has an `M`-multiple which is an integer. This version multiplies `a` on the right, matching the argument order in `LocalizationMap.surj`. -/ theorem exists_integer_multiple' (a : S) : ∃ b : M, IsInteger R (a * algebraMap R S b) := let ⟨⟨Num, denom⟩, h⟩ := IsLocalization.surj _ a ⟨denom, Set.mem_range.mpr ⟨Num, h.symm⟩⟩ /-- Each element `a : S` has an `M`-multiple which is an integer. This version multiplies `a` on the left, matching the argument order in the `SMul` instance. -/ theorem exists_integer_multiple (a : S) : ∃ b : M, IsInteger R ((b : R) • a) := by simp_rw [Algebra.smul_def, mul_comm _ a] apply exists_integer_multiple' /-- We can clear the denominators of a `Finset`-indexed family of fractions. -/ theorem exist_integer_multiples {ι : Type*} (s : Finset ι) (f : ι → S) : ∃ b : M, ∀ i ∈ s, IsLocalization.IsInteger R ((b : R) • f i) := by	haveI := Classical.propDecidable refine ⟨∏ i ∈ s, (sec M (f i)).2, fun i hi => ⟨?_, ?_⟩⟩ · exact (∏ j ∈ s.erase i, (sec M (f j)).2) * (sec M (f i)).1	Mathlib/RingTheory/Localization/Integer.lean	85	87
/- Copyright (c) 2023 Rémy Degenne. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Rémy Degenne -/ import Mathlib.MeasureTheory.Measure.Decomposition.RadonNikodym /-! # Exponentially tilted measures The exponential tilting of a measure `μ` on `α` by a function `f : α → ℝ` is the measure with density `x ↦ exp (f x) / ∫ y, exp (f y) ∂μ` with respect to `μ`. This is sometimes also called the Esscher transform. The definition is mostly used for `f` linear, in which case the exponentially tilted measure belongs to the natural exponential family of the base measure. Exponentially tilted measures for general `f` can be used for example to establish variational expressions for the Kullback-Leibler divergence. ## Main definitions * `Measure.tilted μ f`: exponential tilting of `μ` by `f`, equal to `μ.withDensity (fun x ↦ ENNReal.ofReal (exp (f x) / ∫ x, exp (f x) ∂μ))`. -/ open Real open scoped ENNReal NNReal namespace MeasureTheory variable {α : Type} {mα : MeasurableSpace α} {μ : Measure α} {f : α → ℝ} /-- Exponentially tilted measure. When `x ↦ exp (f x)` is integrable, `μ.tilted f` is the probability measure with density with respect to `μ` proportional to `exp (f x)`. Otherwise it is 0. -/ noncomputable def Measure.tilted (μ : Measure α) (f : α → ℝ) : Measure α := μ.withDensity (fun x ↦ ENNReal.ofReal (exp (f x) / ∫ x, exp (f x) ∂μ)) @[simp] lemma tilted_of_not_integrable (hf : ¬ Integrable (fun x ↦ exp (f x)) μ) : μ.tilted f = 0 := by rw [Measure.tilted, integral_undef hf] simp @[simp] lemma tilted_of_not_aemeasurable (hf : ¬ AEMeasurable f μ) : μ.tilted f = 0 := by refine tilted_of_not_integrable ?_ suffices ¬ AEMeasurable (fun x ↦ exp (f x)) μ by exact fun h ↦ this h.1.aemeasurable exact fun h ↦ hf (aemeasurable_of_aemeasurable_exp h) @[simp] lemma tilted_zero_measure (f : α → ℝ) : (0 : Measure α).tilted f = 0 := by simp [Measure.tilted] @[simp] lemma tilted_const' (μ : Measure α) (c : ℝ) : μ.tilted (fun _ ↦ c) = (μ Set.univ)⁻¹ • μ := by cases eq_zero_or_neZero μ with \| inl h => rw [h]; simp \| inr h0 => simp only [Measure.tilted, withDensity_const, integral_const, smul_eq_mul] by_cases h_univ : μ Set.univ = ∞ · simp only [measureReal_def, h_univ, ENNReal.toReal_top, zero_mul, div_zero, ENNReal.ofReal_zero, zero_smul, ENNReal.inv_top] congr rw [div_eq_mul_inv, mul_inv, mul_comm, mul_assoc, inv_mul_cancel₀ (exp_pos _).ne', mul_one, measureReal_def, ← ENNReal.toReal_inv, ENNReal.ofReal_toReal] simp [h0.out] lemma tilted_const (μ : Measure α) [IsProbabilityMeasure μ] (c : ℝ) : μ.tilted (fun _ ↦ c) = μ := by simp @[simp] lemma tilted_zero' (μ : Measure α) : μ.tilted 0 = (μ Set.univ)⁻¹ • μ := by change μ.tilted (fun _ ↦ 0) = (μ Set.univ)⁻¹ • μ simp lemma tilted_zero (μ : Measure α) [IsProbabilityMeasure μ] : μ.tilted 0 = μ := by simp lemma tilted_congr {g : α → ℝ} (hfg : f =ᵐ[μ] g) : μ.tilted f = μ.tilted g := by have h_int_eq : ∫ x, exp (f x) ∂μ = ∫ x, exp (g x) ∂μ := by refine integral_congr_ae ?_ filter_upwards [hfg] with x hx rw [hx] refine withDensity_congr_ae ?_ filter_upwards [hfg] with x hx rw [h_int_eq, hx] lemma tilted_eq_withDensity_nnreal (μ : Measure α) (f : α → ℝ) : μ.tilted f = μ.withDensity (fun x ↦ ((↑) : ℝ≥0 → ℝ≥0∞) (⟨exp (f x) / ∫ x, exp (f x) ∂μ, by positivity⟩ : ℝ≥0)) := by rw [Measure.tilted] congr with x rw [ENNReal.ofReal_eq_coe_nnreal] lemma tilted_apply' (μ : Measure α) (f : α → ℝ) {s : Set α} (hs : MeasurableSet s) : μ.tilted f s = ∫⁻ a in s, ENNReal.ofReal (exp (f a) / ∫ x, exp (f x) ∂μ) ∂μ := by rw [Measure.tilted, withDensity_apply _ hs] lemma tilted_apply (μ : Measure α) [SFinite μ] (f : α → ℝ) (s : Set α) : μ.tilted f s = ∫⁻ a in s, ENNReal.ofReal (exp (f a) / ∫ x, exp (f x) ∂μ) ∂μ := by rw [Measure.tilted, withDensity_apply' _ s] lemma tilted_apply_eq_ofReal_integral' {s : Set α} (f : α → ℝ) (hs : MeasurableSet s) : μ.tilted f s = ENNReal.ofReal (∫ a in s, exp (f a) / ∫ x, exp (f x) ∂μ ∂μ) := by by_cases hf : Integrable (fun x ↦ exp (f x)) μ · rw [tilted_apply' _ _ hs, ← ofReal_integral_eq_lintegral_ofReal] · exact hf.integrableOn.div_const _ · exact ae_of_all _ (fun _ ↦ by positivity) · simp only [hf, not_false_eq_true, tilted_of_not_integrable, Measure.coe_zero, Pi.zero_apply, integral_undef hf, div_zero, integral_zero, ENNReal.ofReal_zero] lemma tilted_apply_eq_ofReal_integral [SFinite μ] (f : α → ℝ) (s : Set α) : μ.tilted f s = ENNReal.ofReal (∫ a in s, exp (f a) / ∫ x, exp (f x) ∂μ ∂μ) := by by_cases hf : Integrable (fun x ↦ exp (f x)) μ · rw [tilted_apply _ _, ← ofReal_integral_eq_lintegral_ofReal] · exact hf.integrableOn.div_const _ · exact ae_of_all _ (fun _ ↦ by positivity) · simp [tilted_of_not_integrable hf, integral_undef hf] lemma isProbabilityMeasure_tilted [NeZero μ] (hf : Integrable (fun x ↦ exp (f x)) μ) : IsProbabilityMeasure (μ.tilted f) := by constructor simp_rw [tilted_apply' _ _ MeasurableSet.univ, setLIntegral_univ, ENNReal.ofReal_div_of_pos (integral_exp_pos hf), div_eq_mul_inv] rw [lintegral_mul_const'' _ hf.1.aemeasurable.ennreal_ofReal, ← ofReal_integral_eq_lintegral_ofReal hf (ae_of_all _ fun _ ↦ (exp_pos _).le), ENNReal.mul_inv_cancel] · simp only [ne_eq, ENNReal.ofReal_eq_zero, not_le] exact integral_exp_pos hf · simp instance isZeroOrProbabilityMeasure_tilted : IsZeroOrProbabilityMeasure (μ.tilted f) := by rcases eq_zero_or_neZero μ with hμ \| hμ · simp only [hμ, tilted_zero_measure] infer_instance by_cases hf : Integrable (fun x ↦ exp (f x)) μ · have := isProbabilityMeasure_tilted hf infer_instance · simp only [hf, not_false_eq_true, tilted_of_not_integrable] infer_instance section lintegral lemma setLIntegral_tilted' (f : α → ℝ) (g : α → ℝ≥0∞) {s : Set α} (hs : MeasurableSet s) : ∫⁻ x in s, g x ∂(μ.tilted f) = ∫⁻ x in s, ENNReal.ofReal (exp (f x) / ∫ x, exp (f x) ∂μ) g x ∂μ := by by_cases hf : AEMeasurable f μ · rw [Measure.tilted, setLIntegral_withDensity_eq_setLIntegral_mul_non_measurable₀] · simp only [Pi.mul_apply] · refine AEMeasurable.restrict ?_ exact ((measurable_exp.comp_aemeasurable hf).div_const _).ennreal_ofReal · exact hs · filter_upwards simp only [ENNReal.ofReal_lt_top, implies_true] · have hf' : ¬ Integrable (fun x ↦ exp (f x)) μ := by exact fun h ↦ hf (aemeasurable_of_aemeasurable_exp h.1.aemeasurable) simp only [hf, not_false_eq_true, tilted_of_not_aemeasurable, Measure.restrict_zero, lintegral_zero_measure] rw [integral_undef hf'] simp lemma setLIntegral_tilted [SFinite μ] (f : α → ℝ) (g : α → ℝ≥0∞) (s : Set α) : ∫⁻ x in s, g x ∂(μ.tilted f) = ∫⁻ x in s, ENNReal.ofReal (exp (f x) / ∫ x, exp (f x) ∂μ) * g x ∂μ := by by_cases hf : AEMeasurable f μ · rw [Measure.tilted, setLIntegral_withDensity_eq_setLIntegral_mul_non_measurable₀'] · simp only [Pi.mul_apply] · refine AEMeasurable.restrict ?_ exact ((measurable_exp.comp_aemeasurable hf).div_const _).ennreal_ofReal · filter_upwards simp only [ENNReal.ofReal_lt_top, implies_true] · have hf' : ¬ Integrable (fun x ↦ exp (f x)) μ := by exact fun h ↦ hf (aemeasurable_of_aemeasurable_exp h.1.aemeasurable) simp only [hf, not_false_eq_true, tilted_of_not_aemeasurable, Measure.restrict_zero, lintegral_zero_measure] rw [integral_undef hf'] simp lemma lintegral_tilted (f : α → ℝ) (g : α → ℝ≥0∞) : ∫⁻ x, g x ∂(μ.tilted f) = ∫⁻ x, ENNReal.ofReal (exp (f x) / ∫ x, exp (f x) ∂μ) * (g x) ∂μ := by rw [← setLIntegral_univ, setLIntegral_tilted' f g MeasurableSet.univ, setLIntegral_univ] end lintegral section integral variable {E : Type} [NormedAddCommGroup E] [NormedSpace ℝ E] lemma setIntegral_tilted' (f : α → ℝ) (g : α → E) {s : Set α} (hs : MeasurableSet s) : ∫ x in s, g x ∂(μ.tilted f) = ∫ x in s, (exp (f x) / ∫ x, exp (f x) ∂μ) • (g x) ∂μ := by by_cases hf : AEMeasurable f μ · rw [tilted_eq_withDensity_nnreal, setIntegral_withDensity_eq_setIntegral_smul₀ _ _ hs] · congr · suffices AEMeasurable (fun x ↦ exp (f x) / ∫ x, exp (f x) ∂μ) μ by rw [← aemeasurable_coe_nnreal_real_iff] refine AEMeasurable.restrict ?_ simpa only [NNReal.coe_mk] exact (measurable_exp.comp_aemeasurable hf).div_const _ · have hf' : ¬ Integrable (fun x ↦ exp (f x)) μ := by exact fun h ↦ hf (aemeasurable_of_aemeasurable_exp h.1.aemeasurable) simp only [hf, not_false_eq_true, tilted_of_not_aemeasurable, Measure.restrict_zero, integral_zero_measure] rw [integral_undef hf'] simp lemma setIntegral_tilted [SFinite μ] (f : α → ℝ) (g : α → E) (s : Set α) : ∫ x in s, g x ∂(μ.tilted f) = ∫ x in s, (exp (f x) / ∫ x, exp (f x) ∂μ) • (g x) ∂μ := by by_cases hf : AEMeasurable f μ · rw [tilted_eq_withDensity_nnreal, setIntegral_withDensity_eq_setIntegral_smul₀'] · congr · suffices AEMeasurable (fun x ↦ exp (f x) / ∫ x, exp (f x) ∂μ) μ by rw [← aemeasurable_coe_nnreal_real_iff] refine AEMeasurable.restrict ?_ simpa only [NNReal.coe_mk] exact (measurable_exp.comp_aemeasurable hf).div_const _ · have hf' : ¬ Integrable (fun x ↦ exp (f x)) μ := by exact fun h ↦ hf (aemeasurable_of_aemeasurable_exp h.1.aemeasurable) simp only [hf, not_false_eq_true, tilted_of_not_aemeasurable, Measure.restrict_zero, integral_zero_measure] rw [integral_undef hf'] simp lemma integral_tilted (f : α → ℝ) (g : α → E) : ∫ x, g x ∂(μ.tilted f) = ∫ x, (exp (f x) / ∫ x, exp (f x) ∂μ) • (g x) ∂μ := by rw [← setIntegral_univ, setIntegral_tilted' f g MeasurableSet.univ, setIntegral_univ] end integral lemma integral_exp_tilted (f g : α → ℝ) : ∫ x, exp (g x) ∂(μ.tilted f) = (∫ x, exp ((f + g) x) ∂μ) / ∫ x, exp (f x) ∂μ := by cases eq_zero_or_neZero μ with \| inl h => rw [h]; simp \| inr h0 => rw [integral_tilted f] simp_rw [smul_eq_mul] have : ∀ x, (exp (f x) / ∫ x, exp (f x) ∂μ) exp (g x) = (exp ((f + g) x) / ∫ x, exp (f x) ∂μ) := by intro x rw [Pi.add_apply, exp_add] ring simp_rw [this, div_eq_mul_inv] rw [integral_mul_const] lemma tilted_tilted (hf : Integrable (fun x ↦ exp (f x)) μ) (g : α → ℝ) : (μ.tilted f).tilted g = μ.tilted (f + g) := by cases eq_zero_or_neZero μ with \| inl h => simp [h] \| inr h0 => ext1 s hs rw [tilted_apply' _ _ hs, tilted_apply' _ _ hs, setLIntegral_tilted' f _ hs] congr with x rw [← ENNReal.ofReal_mul (by positivity), integral_exp_tilted f, Pi.add_apply, exp_add] congr 1 simp only [Pi.add_apply] field_simp ring_nf congr 1 rw [mul_assoc, mul_inv_cancel₀, mul_one] exact (integral_exp_pos hf).ne' lemma tilted_comm (hf : Integrable (fun x ↦ exp (f x)) μ) {g : α → ℝ} (hg : Integrable (fun x ↦ exp (g x)) μ) : (μ.tilted f).tilted g = (μ.tilted g).tilted f := by rw [tilted_tilted hf, add_comm, tilted_tilted hg] @[simp] lemma tilted_neg_same' (hf : Integrable (fun x ↦ exp (f x)) μ) : (μ.tilted f).tilted (-f) = (μ Set.univ)⁻¹ • μ := by rw [tilted_tilted hf]; simp @[simp] lemma tilted_neg_same [IsProbabilityMeasure μ] (hf : Integrable (fun x ↦ exp (f x)) μ) : (μ.tilted f).tilted (-f) = μ := by simp [hf] lemma tilted_absolutelyContinuous (μ : Measure α) (f : α → ℝ) : μ.tilted f ≪ μ := withDensity_absolutelyContinuous _ _ lemma absolutelyContinuous_tilted (hf : Integrable (fun x ↦ exp (f x)) μ) : μ ≪ μ.tilted f := by cases eq_zero_or_neZero μ with \| inl h => simp only [h, tilted_zero_measure]; exact fun _ _ ↦ by simp \| inr h0 => refine withDensity_absolutelyContinuous' ?_ ?_ · exact (hf.1.aemeasurable.div_const _).ennreal_ofReal · filter_upwards simp only [ne_eq, ENNReal.ofReal_eq_zero, not_le] exact fun _ ↦ div_pos (exp_pos _) (integral_exp_pos hf)	lemma integrable_tilted_iff {E : Type*} [NormedAddCommGroup E] [NormedSpace ℝ E] {f : α → ℝ} (hf : Integrable (fun x ↦ exp (f x)) μ) (g : α → E) : Integrable g (μ.tilted f) ↔ Integrable (fun x ↦ exp (f x) • g x) μ := by by_cases hμ : μ = 0 · simp [hμ] have hf_meas : AEMeasurable f μ := aemeasurable_of_aemeasurable_exp hf.1.aemeasurable rw [Measure.tilted, integrable_withDensity_iff_integrable_smul₀' (by fun_prop) (by simp)] calc Integrable (fun x ↦ (ENNReal.ofReal (exp (f x) / ∫ a, exp (f a) ∂μ)).toReal • g x) μ _ ↔ Integrable (fun x ↦ (exp (f x) / ∫ a, exp (f a) ∂μ) • g x) μ := by	Mathlib/MeasureTheory/Measure/Tilted.lean	293	301
/- Copyright (c) 2024 Johan Commelin. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johan Commelin -/ import Mathlib.Algebra.MvPolynomial.Monad import Mathlib.LinearAlgebra.Charpoly.ToMatrix import Mathlib.LinearAlgebra.FreeModule.StrongRankCondition import Mathlib.LinearAlgebra.Matrix.Charpoly.Univ import Mathlib.RingTheory.TensorProduct.Finite import Mathlib.RingTheory.TensorProduct.Free /-! # Characteristic polynomials of linear families of endomorphisms The coefficients of the characteristic polynomials of a linear family of endomorphisms are homogeneous polynomials in the parameters. This result is used in Lie theory to establish the existence of regular elements and Cartan subalgebras, and ultimately a well-defined notion of rank for Lie algebras. In this file we prove this result about characteristic polynomials. Let `L` and `M` be modules over a nontrivial commutative ring `R`, and let `φ : L →ₗ[R] Module.End R M` be a linear map. Let `b` be a basis of `L`, indexed by `ι`. Then we define a multivariate polynomial with variables indexed by `ι` that evaluates on elements `x` of `L` to the characteristic polynomial of `φ x`. ## Main declarations * `Matrix.toMvPolynomial M i`: the family of multivariate polynomials that evaluates on `c : n → R` to the dot product of the `i`-th row of `M` with `c`. `Matrix.toMvPolynomial M i` is the sum of the monomials `C (M i j) * X j`. * `LinearMap.toMvPolynomial b₁ b₂ f`: a version of `Matrix.toMvPolynomial` for linear maps `f` with respect to bases `b₁` and `b₂` of the domain and codomain. * `LinearMap.polyCharpoly`: the multivariate polynomial that evaluates on elements `x` of `L` to the characteristic polynomial of `φ x`. * `LinearMap.polyCharpoly_map_eq_charpoly`: the evaluation of `polyCharpoly` on elements `x` of `L` is the characteristic polynomial of `φ x`. * `LinearMap.polyCharpoly_coeff_isHomogeneous`: the coefficients of `polyCharpoly` are homogeneous polynomials in the parameters. * `LinearMap.nilRank`: the smallest index at which `polyCharpoly` has a non-zero coefficient, which is independent of the choice of basis for `L`. * `LinearMap.IsNilRegular`: an element `x` of `L` is nil-regular with respect to `φ` if the `n`-th coefficient of the characteristic polynomial of `φ x` is non-zero, where `n` denotes the nil-rank of `φ`. ## Implementation details We show that `LinearMap.polyCharpoly` does not depend on the choice of basis of the target module. This is done via `LinearMap.polyCharpoly_eq_polyCharpolyAux` and `LinearMap.polyCharpolyAux_basisIndep`. The latter is proven by considering the base change of the `R`-linear map `φ : L →ₗ[R] End R M` to the multivariate polynomial ring `MvPolynomial ι R`, and showing that `polyCharpolyAux φ` is equal to the characteristic polynomial of this base change. The proof concludes because characteristic polynomials are independent of the chosen basis. ## References * [barnes1967]: "On Cartan subalgebras of Lie algebras" by D.W. Barnes. -/ open scoped Matrix namespace Matrix variable {m n o R S : Type} variable [Fintype n] [Fintype o] [CommSemiring R] [CommSemiring S] open MvPolynomial /-- Let `M` be an `(m × n)`-matrix over `R`. Then `Matrix.toMvPolynomial M` is the family (indexed by `i : m`) of multivariate polynomials in `n` variables over `R` that evaluates on `c : n → R` to the dot product of the `i`-th row of `M` with `c`: `Matrix.toMvPolynomial M i` is the sum of the monomials `C (M i j) X j`. -/ noncomputable def toMvPolynomial (M : Matrix m n R) (i : m) : MvPolynomial n R := ∑ j, monomial (.single j 1) (M i j) lemma toMvPolynomial_eval_eq_apply (M : Matrix m n R) (i : m) (c : n → R) : eval c (M.toMvPolynomial i) = (M ᵥ c) i := by simp only [toMvPolynomial, map_sum, eval_monomial, pow_zero, Finsupp.prod_single_index, pow_one, mulVec, dotProduct] lemma toMvPolynomial_map (f : R →+ S) (M : Matrix m n R) (i : m) : (M.map f).toMvPolynomial i = MvPolynomial.map f (M.toMvPolynomial i) := by simp only [toMvPolynomial, map_apply, map_sum, map_monomial] lemma toMvPolynomial_isHomogeneous (M : Matrix m n R) (i : m) : (M.toMvPolynomial i).IsHomogeneous 1 := by apply MvPolynomial.IsHomogeneous.sum rintro j - apply MvPolynomial.isHomogeneous_monomial _ _ simp [Finsupp.degree, Finsupp.support_single_ne_zero _ one_ne_zero, Finset.sum_singleton, Finsupp.single_eq_same] lemma toMvPolynomial_totalDegree_le (M : Matrix m n R) (i : m) : (M.toMvPolynomial i).totalDegree ≤ 1 := by apply (toMvPolynomial_isHomogeneous _ _).totalDegree_le @[simp] lemma toMvPolynomial_constantCoeff (M : Matrix m n R) (i : m) : constantCoeff (M.toMvPolynomial i) = 0 := by simp only [toMvPolynomial, ← C_mul_X_eq_monomial, map_sum, map_mul, constantCoeff_X, mul_zero, Finset.sum_const_zero] @[simp] lemma toMvPolynomial_zero : (0 : Matrix m n R).toMvPolynomial = 0 := by ext; simp only [toMvPolynomial, zero_apply, map_zero, Finset.sum_const_zero, Pi.zero_apply] @[simp] lemma toMvPolynomial_one [DecidableEq n] : (1 : Matrix n n R).toMvPolynomial = X := by ext i : 1 rw [toMvPolynomial, Finset.sum_eq_single i] · simp only [one_apply_eq, ← C_mul_X_eq_monomial, C_1, one_mul] · rintro j - hj simp only [one_apply_ne hj.symm, map_zero] · intro h exact (h (Finset.mem_univ _)).elim lemma toMvPolynomial_add (M N : Matrix m n R) : (M + N).toMvPolynomial = M.toMvPolynomial + N.toMvPolynomial := by ext i : 1 simp only [toMvPolynomial, add_apply, map_add, Finset.sum_add_distrib, Pi.add_apply] lemma toMvPolynomial_mul (M : Matrix m n R) (N : Matrix n o R) (i : m) : (M * N).toMvPolynomial i = bind₁ N.toMvPolynomial (M.toMvPolynomial i) := by simp only [toMvPolynomial, mul_apply, map_sum, Finset.sum_comm (γ := o), bind₁, aeval, AlgHom.coe_mk, coe_eval₂Hom, eval₂_monomial, algebraMap_apply, Algebra.id.map_eq_id, RingHom.id_apply, C_apply, pow_zero, Finsupp.prod_single_index, pow_one, Finset.mul_sum, monomial_mul, zero_add] end Matrix namespace LinearMap open MvPolynomial section variable {R M₁ M₂ ι₁ ι₂ : Type} variable [CommRing R] [AddCommGroup M₁] [AddCommGroup M₂] variable [Module R M₁] [Module R M₂] variable [Fintype ι₁] [Finite ι₂] variable [DecidableEq ι₁] variable (b₁ : Basis ι₁ R M₁) (b₂ : Basis ι₂ R M₂) /-- Let `f : M₁ →ₗ[R] M₂` be an `R`-linear map between modules `M₁` and `M₂` with bases `b₁` and `b₂` respectively. Then `LinearMap.toMvPolynomial b₁ b₂ f` is the family of multivariate polynomials over `R` that evaluates on an element `x` of `M₁` (represented on the basis `b₁`) to the element `f x` of `M₂` (represented on the basis `b₂`). -/ noncomputable def toMvPolynomial (f : M₁ →ₗ[R] M₂) (i : ι₂) : MvPolynomial ι₁ R := (toMatrix b₁ b₂ f).toMvPolynomial i lemma toMvPolynomial_eval_eq_apply (f : M₁ →ₗ[R] M₂) (i : ι₂) (c : ι₁ →₀ R) : eval c (f.toMvPolynomial b₁ b₂ i) = b₂.repr (f (b₁.repr.symm c)) i := by rw [toMvPolynomial, Matrix.toMvPolynomial_eval_eq_apply, ← LinearMap.toMatrix_mulVec_repr b₁ b₂, LinearEquiv.apply_symm_apply] open Algebra.TensorProduct in lemma toMvPolynomial_baseChange (f : M₁ →ₗ[R] M₂) (i : ι₂) (A : Type) [CommRing A] [Algebra R A] : (f.baseChange A).toMvPolynomial (basis A b₁) (basis A b₂) i = MvPolynomial.map (algebraMap R A) (f.toMvPolynomial b₁ b₂ i) := by simp only [toMvPolynomial, toMatrix_baseChange, Matrix.toMvPolynomial_map] lemma toMvPolynomial_isHomogeneous (f : M₁ →ₗ[R] M₂) (i : ι₂) : (f.toMvPolynomial b₁ b₂ i).IsHomogeneous 1 := Matrix.toMvPolynomial_isHomogeneous _ _ lemma toMvPolynomial_totalDegree_le (f : M₁ →ₗ[R] M₂) (i : ι₂) : (f.toMvPolynomial b₁ b₂ i).totalDegree ≤ 1 := Matrix.toMvPolynomial_totalDegree_le _ _ @[simp] lemma toMvPolynomial_constantCoeff (f : M₁ →ₗ[R] M₂) (i : ι₂) : constantCoeff (f.toMvPolynomial b₁ b₂ i) = 0 := Matrix.toMvPolynomial_constantCoeff _ _ @[simp] lemma toMvPolynomial_zero : (0 : M₁ →ₗ[R] M₂).toMvPolynomial b₁ b₂ = 0 := by unfold toMvPolynomial; simp only [map_zero, Matrix.toMvPolynomial_zero] @[simp] lemma toMvPolynomial_id : (id : M₁ →ₗ[R] M₁).toMvPolynomial b₁ b₁ = X := by unfold toMvPolynomial; simp only [toMatrix_id, Matrix.toMvPolynomial_one] lemma toMvPolynomial_add (f g : M₁ →ₗ[R] M₂) : (f + g).toMvPolynomial b₁ b₂ = f.toMvPolynomial b₁ b₂ + g.toMvPolynomial b₁ b₂ := by unfold toMvPolynomial; simp only [map_add, Matrix.toMvPolynomial_add] end variable {R M₁ M₂ M₃ ι₁ ι₂ ι₃ : Type} variable [CommRing R] [AddCommGroup M₁] [AddCommGroup M₂] [AddCommGroup M₃] variable [Module R M₁] [Module R M₂] [Module R M₃] variable [Fintype ι₁] [Fintype ι₂] [Finite ι₃] variable [DecidableEq ι₁] [DecidableEq ι₂] variable (b₁ : Basis ι₁ R M₁) (b₂ : Basis ι₂ R M₂) (b₃ : Basis ι₃ R M₃) lemma toMvPolynomial_comp (g : M₂ →ₗ[R] M₃) (f : M₁ →ₗ[R] M₂) (i : ι₃) : (g ∘ₗ f).toMvPolynomial b₁ b₃ i = bind₁ (f.toMvPolynomial b₁ b₂) (g.toMvPolynomial b₂ b₃ i) := by simp only [toMvPolynomial, toMatrix_comp b₁ b₂ b₃, Matrix.toMvPolynomial_mul] rfl end LinearMap variable {R L M n ι ι' ιM : Type} variable [CommRing R] [AddCommGroup L] [Module R L] [AddCommGroup M] [Module R M] variable (φ : L →ₗ[R] Module.End R M) variable [Fintype ι] [Fintype ι'] [Fintype ιM] [DecidableEq ι] [DecidableEq ι'] namespace LinearMap section aux variable [DecidableEq ιM] (b : Basis ι R L) (bₘ : Basis ιM R M) open Matrix /-- (Implementation detail, see `LinearMap.polyCharpoly`.) Let `L` and `M` be finite free modules over `R`, and let `φ : L →ₗ[R] Module.End R M` be a linear map. Let `b` be a basis of `L` and `bₘ` a basis of `M`. Then `LinearMap.polyCharpolyAux φ b bₘ` is the polynomial that evaluates on elements `x` of `L` to the characteristic polynomial of `φ x` acting on `M`. This definition does not depend on the choice of `bₘ` (see `LinearMap.polyCharpolyAux_basisIndep`). -/ noncomputable def polyCharpolyAux : Polynomial (MvPolynomial ι R) := (charpoly.univ R ιM).map <\| MvPolynomial.bind₁ (φ.toMvPolynomial b bₘ.end) open Algebra.TensorProduct MvPolynomial in lemma polyCharpolyAux_baseChange (A : Type) [CommRing A] [Algebra R A] : polyCharpolyAux (tensorProduct _ _ _ _ ∘ₗ φ.baseChange A) (basis A b) (basis A bₘ) = (polyCharpolyAux φ b bₘ).map (MvPolynomial.map (algebraMap R A)) := by simp only [polyCharpolyAux] rw [← charpoly.univ_map_map _ (algebraMap R A)] simp only [Polynomial.map_map] congr 1 apply ringHom_ext · intro r simp only [RingHom.coe_comp, RingHom.coe_coe, Function.comp_apply, map_C, bind₁_C_right] · rintro ij simp only [RingHom.coe_comp, RingHom.coe_coe, Function.comp_apply, map_X, bind₁_X_right] classical rw [toMvPolynomial_comp _ (basis A (Basis.end bₘ)), ← toMvPolynomial_baseChange] suffices toMvPolynomial (M₂ := (Module.End A (TensorProduct R A M))) (basis A bₘ.end) (basis A bₘ).end (tensorProduct R A M M) ij = X ij by rw [this, bind₁_X_right] simp only [toMvPolynomial, Matrix.toMvPolynomial] suffices ∀ kl, (toMatrix (basis A bₘ.end) (basis A bₘ).end) (tensorProduct R A M M) ij kl = if kl = ij then 1 else 0 by rw [Finset.sum_eq_single ij] · rw [this, if_pos rfl, X] · rintro kl - H rw [this, if_neg H, map_zero] · intro h exact (h (Finset.mem_univ _)).elim intro kl rw [toMatrix_apply, tensorProduct, TensorProduct.AlgebraTensorModule.lift_apply, basis_apply, TensorProduct.lift.tmul, coe_restrictScalars] dsimp only [coe_mk, AddHom.coe_mk, smul_apply, baseChangeHom_apply] rw [one_smul, Basis.baseChange_end, Basis.repr_self_apply] open LinearMap in lemma polyCharpolyAux_map_eq_toMatrix_charpoly (x : L) : (polyCharpolyAux φ b bₘ).map (MvPolynomial.eval (b.repr x)) = (toMatrix bₘ bₘ (φ x)).charpoly := by rw [polyCharpolyAux, Polynomial.map_map, ← MvPolynomial.eval₂Hom_C_eq_bind₁, MvPolynomial.comp_eval₂Hom, charpoly.univ_map_eval₂Hom] congr ext rw [of_apply, Function.curry_apply, toMvPolynomial_eval_eq_apply, LinearEquiv.symm_apply_apply] rfl open LinearMap in lemma polyCharpolyAux_eval_eq_toMatrix_charpoly_coeff (x : L) (i : ℕ) : MvPolynomial.eval (b.repr x) ((polyCharpolyAux φ b bₘ).coeff i) = (toMatrix bₘ bₘ (φ x)).charpoly.coeff i := by simp [← polyCharpolyAux_map_eq_toMatrix_charpoly φ b bₘ x] @[simp] lemma polyCharpolyAux_map_eq_charpoly [Module.Finite R M] [Module.Free R M] (x : L) : (polyCharpolyAux φ b bₘ).map (MvPolynomial.eval (b.repr x)) = (φ x).charpoly := by nontriviality R rw [polyCharpolyAux_map_eq_toMatrix_charpoly, LinearMap.charpoly_toMatrix] @[simp] lemma polyCharpolyAux_coeff_eval [Module.Finite R M] [Module.Free R M] (x : L) (i : ℕ) : MvPolynomial.eval (b.repr x) ((polyCharpolyAux φ b bₘ).coeff i) = (φ x).charpoly.coeff i := by nontriviality R rw [← polyCharpolyAux_map_eq_charpoly φ b bₘ x, Polynomial.coeff_map] lemma polyCharpolyAux_map_eval [Module.Finite R M] [Module.Free R M] (x : ι → R) : (polyCharpolyAux φ b bₘ).map (MvPolynomial.eval x) = (φ (b.repr.symm (Finsupp.equivFunOnFinite.symm x))).charpoly := by simp only [← polyCharpolyAux_map_eq_charpoly φ b bₘ, LinearEquiv.apply_symm_apply, Finsupp.equivFunOnFinite, Equiv.coe_fn_symm_mk, Finsupp.coe_mk] open Algebra.TensorProduct TensorProduct in lemma polyCharpolyAux_map_aeval (A : Type) [CommRing A] [Algebra R A] [Module.Finite A (A ⊗[R] M)] [Module.Free A (A ⊗[R] M)] (x : ι → A) : (polyCharpolyAux φ b bₘ).map (MvPolynomial.aeval x).toRingHom = LinearMap.charpoly ((tensorProduct R A M M).comp (baseChange A φ) ((basis A b).repr.symm (Finsupp.equivFunOnFinite.symm x))) := by rw [← polyCharpolyAux_map_eval (tensorProduct R A M M ∘ₗ baseChange A φ) _ (basis A bₘ), polyCharpolyAux_baseChange, Polynomial.map_map] congr exact DFunLike.ext _ _ fun f ↦ (MvPolynomial.eval_map (algebraMap R A) x f).symm open Algebra.TensorProduct MvPolynomial in /-- `LinearMap.polyCharpolyAux` is independent of the choice of basis of the target module. Proof strategy: 1. Rewrite `polyCharpolyAux` as the (honest, ordinary) characteristic polynomial of the basechange of `φ` to the multivariate polynomial ring `MvPolynomial ι R`. 2. Use that the characteristic polynomial of a linear map is independent of the choice of basis. This independence result is used transitively via `LinearMap.polyCharpolyAux_map_aeval` and `LinearMap.polyCharpolyAux_map_eq_charpoly`. -/ lemma polyCharpolyAux_basisIndep {ιM' : Type} [Fintype ιM'] [DecidableEq ιM'] (bₘ' : Basis ιM' R M) : polyCharpolyAux φ b bₘ = polyCharpolyAux φ b bₘ' := by let f : Polynomial (MvPolynomial ι R) → Polynomial (MvPolynomial ι R) := Polynomial.map (MvPolynomial.aeval X).toRingHom have hf : Function.Injective f := by simp only [f, aeval_X_left, AlgHom.toRingHom_eq_coe, AlgHom.id_toRingHom, Polynomial.map_id] exact Polynomial.map_injective (RingHom.id _) Function.injective_id apply hf let _h1 : Module.Finite (MvPolynomial ι R) (TensorProduct R (MvPolynomial ι R) M) := Module.Finite.of_basis (basis (MvPolynomial ι R) bₘ) let _h2 : Module.Free (MvPolynomial ι R) (TensorProduct R (MvPolynomial ι R) M) := Module.Free.of_basis (basis (MvPolynomial ι R) bₘ) simp only [f, polyCharpolyAux_map_aeval, polyCharpolyAux_map_aeval] end aux open Module Matrix variable [Module.Free R M] [Module.Finite R M] (b : Basis ι R L) /-- Let `L` and `M` be finite free modules over `R`, and let `φ : L →ₗ[R] Module.End R M` be a linear family of endomorphisms. Let `b` be a basis of `L` and `bₘ` a basis of `M`. Then `LinearMap.polyCharpoly φ b` is the polynomial that evaluates on elements `x` of `L` to the characteristic polynomial of `φ x` acting on `M`. -/ noncomputable def polyCharpoly : Polynomial (MvPolynomial ι R) := φ.polyCharpolyAux b (Module.Free.chooseBasis R M) lemma polyCharpoly_eq_of_basis [DecidableEq ιM] (bₘ : Basis ιM R M) : polyCharpoly φ b = (charpoly.univ R ιM).map (MvPolynomial.bind₁ (φ.toMvPolynomial b bₘ.end)) := by rw [polyCharpoly, φ.polyCharpolyAux_basisIndep b (Module.Free.chooseBasis R M) bₘ, polyCharpolyAux] lemma polyCharpoly_monic : (polyCharpoly φ b).Monic := (charpoly.univ_monic R _).map _ lemma polyCharpoly_ne_zero [Nontrivial R] : (polyCharpoly φ b) ≠ 0 := (polyCharpoly_monic _ _).ne_zero @[simp] lemma polyCharpoly_natDegree [Nontrivial R] : (polyCharpoly φ b).natDegree = finrank R M := by rw [polyCharpoly, polyCharpolyAux, (charpoly.univ_monic _ _).natDegree_map, charpoly.univ_natDegree, finrank_eq_card_chooseBasisIndex] lemma polyCharpoly_coeff_isHomogeneous (i j : ℕ) (hij : i + j = finrank R M) [Nontrivial R] : ((polyCharpoly φ b).coeff i).IsHomogeneous j := by rw [finrank_eq_card_chooseBasisIndex] at hij rw [polyCharpoly, polyCharpolyAux, Polynomial.coeff_map, ← one_mul j] apply (charpoly.univ_coeff_isHomogeneous _ _ _ _ hij).eval₂ · exact fun r ↦ MvPolynomial.isHomogeneous_C _ _ · exact LinearMap.toMvPolynomial_isHomogeneous _ _ _ open Algebra.TensorProduct MvPolynomial in lemma polyCharpoly_baseChange (A : Type) [CommRing A] [Algebra R A] : polyCharpoly (tensorProduct _ _ _ _ ∘ₗ φ.baseChange A) (basis A b) = (polyCharpoly φ b).map (MvPolynomial.map (algebraMap R A)) := by unfold polyCharpoly rw [← φ.polyCharpolyAux_baseChange] apply polyCharpolyAux_basisIndep @[simp] lemma polyCharpoly_map_eq_charpoly (x : L) : (polyCharpoly φ b).map (MvPolynomial.eval (b.repr x)) = (φ x).charpoly := by rw [polyCharpoly, polyCharpolyAux_map_eq_charpoly] @[simp] lemma polyCharpoly_coeff_eval (x : L) (i : ℕ) : MvPolynomial.eval (b.repr x) ((polyCharpoly φ b).coeff i) = (φ x).charpoly.coeff i := by	rw [polyCharpoly, polyCharpolyAux_coeff_eval] lemma polyCharpoly_coeff_eq_zero_of_basis (b : Basis ι R L) (b' : Basis ι' R L) (k : ℕ) (H : (polyCharpoly φ b).coeff k = 0) :	Mathlib/Algebra/Module/LinearMap/Polynomial.lean	405	408

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