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/- Copyright (c) 2019 Jan-David Salchow. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jan-David Salchow, Sébastien Gouëzel, Jean Lo -/ import Mathlib.Analysis.NormedSpace.OperatorNorm.Basic /-! # Operator norm as an `NNNorm` Operator norm as an `NNNorm`, i.e. taking values in non-negative reals. -/ suppress_compilation open Bornology open Filter hiding map_smul open scoped NNReal Topology Uniformity -- the `ₗ` subscript variables are for special cases about linear (as opposed to semilinear) maps variable {𝕜 𝕜₂ 𝕜₃ E Eₗ F Fₗ G Gₗ 𝓕 : Type} section SemiNormed open Metric ContinuousLinearMap variable [SeminormedAddCommGroup E] [SeminormedAddCommGroup Eₗ] [SeminormedAddCommGroup F] [SeminormedAddCommGroup Fₗ] [SeminormedAddCommGroup G] [SeminormedAddCommGroup Gₗ] variable [NontriviallyNormedField 𝕜] [NontriviallyNormedField 𝕜₂] [NontriviallyNormedField 𝕜₃] [NormedSpace 𝕜 E] [NormedSpace 𝕜 Eₗ] [NormedSpace 𝕜₂ F] [NormedSpace 𝕜 Fₗ] [NormedSpace 𝕜₃ G] [NormedSpace 𝕜 Gₗ] {σ₁₂ : 𝕜 →+ 𝕜₂} {σ₂₃ : 𝕜₂ →+* 𝕜₃} {σ₁₃ : 𝕜 →+* 𝕜₃} [RingHomCompTriple σ₁₂ σ₂₃ σ₁₃] variable [FunLike 𝓕 E F] namespace ContinuousLinearMap section OpNorm open Set Real section variable [RingHomIsometric σ₁₂] [RingHomIsometric σ₂₃] (f g : E →SL[σ₁₂] F) (h : F →SL[σ₂₃] G) (x : E) theorem nnnorm_def (f : E →SL[σ₁₂] F) : ‖f‖₊ = sInf { c \| ∀ x, ‖f x‖₊ ≤ c * ‖x‖₊ } := by ext rw [NNReal.coe_sInf, coe_nnnorm, norm_def, NNReal.coe_image] simp_rw [← NNReal.coe_le_coe, NNReal.coe_mul, coe_nnnorm, mem_setOf_eq, NNReal.coe_mk, exists_prop] /-- If one controls the norm of every `A x`, then one controls the norm of `A`. -/ theorem opNNNorm_le_bound (f : E →SL[σ₁₂] F) (M : ℝ≥0) (hM : ∀ x, ‖f x‖₊ ≤ M * ‖x‖₊) : ‖f‖₊ ≤ M := opNorm_le_bound f (zero_le M) hM /-- If one controls the norm of every `A x`, `‖x‖₊ ≠ 0`, then one controls the norm of `A`. -/ theorem opNNNorm_le_bound' (f : E →SL[σ₁₂] F) (M : ℝ≥0) (hM : ∀ x, ‖x‖₊ ≠ 0 → ‖f x‖₊ ≤ M * ‖x‖₊) : ‖f‖₊ ≤ M := opNorm_le_bound' f (zero_le M) fun x hx => hM x <\| by rwa [← NNReal.coe_ne_zero] /-- For a continuous real linear map `f`, if one controls the norm of every `f x`, `‖x‖₊ = 1`, then one controls the norm of `f`. -/ theorem opNNNorm_le_of_unit_nnnorm [NormedSpace ℝ E] [NormedSpace ℝ F] {f : E →L[ℝ] F} {C : ℝ≥0} (hf : ∀ x, ‖x‖₊ = 1 → ‖f x‖₊ ≤ C) : ‖f‖₊ ≤ C := opNorm_le_of_unit_norm C.coe_nonneg fun x hx => hf x <\| by rwa [← NNReal.coe_eq_one] theorem opNNNorm_le_of_lipschitz {f : E →SL[σ₁₂] F} {K : ℝ≥0} (hf : LipschitzWith K f) : ‖f‖₊ ≤ K := opNorm_le_of_lipschitz hf theorem opNNNorm_eq_of_bounds {φ : E →SL[σ₁₂] F} (M : ℝ≥0) (h_above : ∀ x, ‖φ x‖₊ ≤ M * ‖x‖₊) (h_below : ∀ N, (∀ x, ‖φ x‖₊ ≤ N * ‖x‖₊) → M ≤ N) : ‖φ‖₊ = M := Subtype.ext <\| opNorm_eq_of_bounds (zero_le M) h_above <\| Subtype.forall'.mpr h_below theorem opNNNorm_le_iff {f : E →SL[σ₁₂] F} {C : ℝ≥0} : ‖f‖₊ ≤ C ↔ ∀ x, ‖f x‖₊ ≤ C * ‖x‖₊ := opNorm_le_iff C.2 theorem isLeast_opNNNorm : IsLeast {C : ℝ≥0 \| ∀ x, ‖f x‖₊ ≤ C * ‖x‖₊} ‖f‖₊ := by simpa only [← opNNNorm_le_iff] using isLeast_Ici theorem opNNNorm_comp_le [RingHomIsometric σ₁₃] (f : E →SL[σ₁₂] F) : ‖h.comp f‖₊ ≤ ‖h‖₊ * ‖f‖₊ := opNorm_comp_le h f lemma opENorm_comp_le [RingHomIsometric σ₁₃] (f : E →SL[σ₁₂] F) : ‖h.comp f‖ₑ ≤ ‖h‖ₑ * ‖f‖ₑ := by simpa [enorm, ← ENNReal.coe_mul] using opNNNorm_comp_le h f theorem le_opNNNorm : ‖f x‖₊ ≤ ‖f‖₊ * ‖x‖₊ := f.le_opNorm x lemma le_opENorm : ‖f x‖ₑ ≤ ‖f‖ₑ * ‖x‖ₑ := by dsimp [enorm]; exact mod_cast le_opNNNorm .. theorem nndist_le_opNNNorm (x y : E) : nndist (f x) (f y) ≤ ‖f‖₊ * nndist x y := dist_le_opNorm f x y /-- continuous linear maps are Lipschitz continuous. -/ theorem lipschitz : LipschitzWith ‖f‖₊ f := AddMonoidHomClass.lipschitz_of_bound_nnnorm f _ f.le_opNNNorm /-- Evaluation of a continuous linear map `f` at a point is Lipschitz continuous in `f`. -/ theorem lipschitz_apply (x : E) : LipschitzWith ‖x‖₊ fun f : E →SL[σ₁₂] F => f x := lipschitzWith_iff_norm_sub_le.2 fun f g => ((f - g).le_opNorm x).trans_eq (mul_comm _ _) end section Sup variable [RingHomIsometric σ₁₂] theorem exists_mul_lt_apply_of_lt_opNNNorm (f : E →SL[σ₁₂] F) {r : ℝ≥0} (hr : r < ‖f‖₊) : ∃ x, r * ‖x‖₊ < ‖f x‖₊ := by simpa only [not_forall, not_le, Set.mem_setOf] using not_mem_of_lt_csInf (nnnorm_def f ▸ hr : r < sInf { c : ℝ≥0 \| ∀ x, ‖f x‖₊ ≤ c * ‖x‖₊ }) (OrderBot.bddBelow _) theorem exists_mul_lt_of_lt_opNorm (f : E →SL[σ₁₂] F) {r : ℝ} (hr₀ : 0 ≤ r) (hr : r < ‖f‖) : ∃ x, r * ‖x‖ < ‖f x‖ := by lift r to ℝ≥0 using hr₀ exact f.exists_mul_lt_apply_of_lt_opNNNorm hr theorem exists_lt_apply_of_lt_opNNNorm {𝕜 𝕜₂ E F : Type} [NormedAddCommGroup E] [SeminormedAddCommGroup F] [DenselyNormedField 𝕜] [NontriviallyNormedField 𝕜₂] {σ₁₂ : 𝕜 →+ 𝕜₂} [NormedSpace 𝕜 E] [NormedSpace 𝕜₂ F] [RingHomIsometric σ₁₂] (f : E →SL[σ₁₂] F) {r : ℝ≥0} (hr : r < ‖f‖₊) : ∃ x : E, ‖x‖₊ < 1 ∧ r < ‖f x‖₊ := by obtain ⟨y, hy⟩ := f.exists_mul_lt_apply_of_lt_opNNNorm hr have hy' : ‖y‖₊ ≠ 0 := nnnorm_ne_zero_iff.2 fun heq => by simp [heq, nnnorm_zero, map_zero, not_lt_zero'] at hy have hfy : ‖f y‖₊ ≠ 0 := (zero_le'.trans_lt hy).ne' rw [← inv_inv ‖f y‖₊, NNReal.lt_inv_iff_mul_lt (inv_ne_zero hfy), mul_assoc, mul_comm ‖y‖₊, ← mul_assoc, ← NNReal.lt_inv_iff_mul_lt hy'] at hy obtain ⟨k, hk₁, hk₂⟩ := NormedField.exists_lt_nnnorm_lt 𝕜 hy refine ⟨k • y, (nnnorm_smul k y).symm ▸ (NNReal.lt_inv_iff_mul_lt hy').1 hk₂, ?_⟩ have : ‖σ₁₂ k‖₊ = ‖k‖₊ := Subtype.ext RingHomIsometric.is_iso rwa [map_smulₛₗ f, nnnorm_smul, ← div_lt_iff₀ hfy.bot_lt, div_eq_mul_inv, this] theorem exists_lt_apply_of_lt_opNorm {𝕜 𝕜₂ E F : Type} [NormedAddCommGroup E] [SeminormedAddCommGroup F] [DenselyNormedField 𝕜] [NontriviallyNormedField 𝕜₂] {σ₁₂ : 𝕜 →+ 𝕜₂} [NormedSpace 𝕜 E] [NormedSpace 𝕜₂ F] [RingHomIsometric σ₁₂] (f : E →SL[σ₁₂] F) {r : ℝ} (hr : r < ‖f‖) : ∃ x : E, ‖x‖ < 1 ∧ r < ‖f x‖ := by by_cases hr₀ : r < 0 · exact ⟨0, by simpa using hr₀⟩ · lift r to ℝ≥0 using not_lt.1 hr₀ exact f.exists_lt_apply_of_lt_opNNNorm hr theorem sSup_unit_ball_eq_nnnorm {𝕜 𝕜₂ E F : Type} [NormedAddCommGroup E] [SeminormedAddCommGroup F] [DenselyNormedField 𝕜] [NontriviallyNormedField 𝕜₂] {σ₁₂ : 𝕜 →+ 𝕜₂} [NormedSpace 𝕜 E] [NormedSpace 𝕜₂ F] [RingHomIsometric σ₁₂] (f : E →SL[σ₁₂] F) : sSup ((fun x => ‖f x‖₊) '' ball 0 1) = ‖f‖₊ := by refine csSup_eq_of_forall_le_of_forall_lt_exists_gt ((nonempty_ball.mpr zero_lt_one).image _) ?_ fun ub hub => ?_ · rintro - ⟨x, hx, rfl⟩ simpa only [mul_one] using f.le_opNorm_of_le (mem_ball_zero_iff.1 hx).le · obtain ⟨x, hx, hxf⟩ := f.exists_lt_apply_of_lt_opNNNorm hub exact ⟨_, ⟨x, mem_ball_zero_iff.2 hx, rfl⟩, hxf⟩ theorem sSup_unit_ball_eq_norm {𝕜 𝕜₂ E F : Type} [NormedAddCommGroup E] [SeminormedAddCommGroup F] [DenselyNormedField 𝕜] [NontriviallyNormedField 𝕜₂] {σ₁₂ : 𝕜 →+ 𝕜₂} [NormedSpace 𝕜 E] [NormedSpace 𝕜₂ F] [RingHomIsometric σ₁₂] (f : E →SL[σ₁₂] F) : sSup ((fun x => ‖f x‖) '' ball 0 1) = ‖f‖ := by simpa only [NNReal.coe_sSup, Set.image_image] using NNReal.coe_inj.2 f.sSup_unit_ball_eq_nnnorm theorem sSup_unitClosedBall_eq_nnnorm {𝕜 𝕜₂ E F : Type} [NormedAddCommGroup E] [SeminormedAddCommGroup F] [DenselyNormedField 𝕜] [NontriviallyNormedField 𝕜₂] {σ₁₂ : 𝕜 →+ 𝕜₂} [NormedSpace 𝕜 E] [NormedSpace 𝕜₂ F] [RingHomIsometric σ₁₂] (f : E →SL[σ₁₂] F) : sSup ((fun x => ‖f x‖₊) '' closedBall 0 1) = ‖f‖₊ := by have hbdd : ∀ y ∈ (fun x => ‖f x‖₊) '' closedBall 0 1, y ≤ ‖f‖₊ := by rintro - ⟨x, hx, rfl⟩ exact f.unit_le_opNorm x (mem_closedBall_zero_iff.1 hx)	refine le_antisymm (csSup_le ((nonempty_closedBall.mpr zero_le_one).image _) hbdd) ?_ rw [← sSup_unit_ball_eq_nnnorm] exact csSup_le_csSup ⟨‖f‖₊, hbdd⟩ ((nonempty_ball.2 zero_lt_one).image _) (Set.image_subset _ ball_subset_closedBall) @[deprecated (since := "2024-12-01")] alias sSup_closed_unit_ball_eq_nnnorm := sSup_unitClosedBall_eq_nnnorm	Mathlib/Analysis/NormedSpace/OperatorNorm/NNNorm.lean	178	185
/- Copyright (c) 2022 Matej Penciak. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Matej Penciak, Moritz Doll, Fabien Clery -/ import Mathlib.LinearAlgebra.Matrix.NonsingularInverse /-! # The Symplectic Group This file defines the symplectic group and proves elementary properties. ## Main Definitions * `Matrix.J`: the canonical `2n × 2n` skew-symmetric matrix * `symplecticGroup`: the group of symplectic matrices ## TODO * Every symplectic matrix has determinant 1. * For `n = 1` the symplectic group coincides with the special linear group. -/ open Matrix variable {l R : Type} namespace Matrix variable (l) [DecidableEq l] (R) [CommRing R] section JMatrixLemmas /-- The matrix defining the canonical skew-symmetric bilinear form. -/ def J : Matrix (l ⊕ l) (l ⊕ l) R := Matrix.fromBlocks 0 (-1) 1 0 @[simp] theorem J_transpose : (J l R)ᵀ = -J l R := by rw [J, fromBlocks_transpose, ← neg_one_smul R (fromBlocks _ _ _ _ : Matrix (l ⊕ l) (l ⊕ l) R), fromBlocks_smul, Matrix.transpose_zero, Matrix.transpose_one, transpose_neg] simp [fromBlocks] variable [Fintype l] theorem J_squared : J l R J l R = -1 := by rw [J, fromBlocks_multiply] simp only [Matrix.zero_mul, Matrix.neg_mul, zero_add, neg_zero, Matrix.one_mul, add_zero] rw [← neg_zero, ← Matrix.fromBlocks_neg, ← fromBlocks_one] theorem J_inv : (J l R)⁻¹ = -J l R := by refine Matrix.inv_eq_right_inv ?_ rw [Matrix.mul_neg, J_squared] exact neg_neg 1 theorem J_det_mul_J_det : det (J l R) * det (J l R) = 1 := by rw [← det_mul, J_squared, ← one_smul R (-1 : Matrix _ _ R), smul_neg, ← neg_smul, det_smul, Fintype.card_sum, det_one, mul_one] apply Even.neg_one_pow exact Even.add_self _ theorem isUnit_det_J : IsUnit (det (J l R)) := isUnit_iff_exists_inv.mpr ⟨det (J l R), J_det_mul_J_det _ _⟩ end JMatrixLemmas variable [Fintype l] /-- The group of symplectic matrices over a ring `R`. -/ def symplecticGroup : Submonoid (Matrix (l ⊕ l) (l ⊕ l) R) where carrier := { A \| A * J l R * Aᵀ = J l R } mul_mem' {a b} ha hb := by simp only [Set.mem_setOf_eq, transpose_mul] at * rw [← Matrix.mul_assoc, a.mul_assoc, a.mul_assoc, hb] exact ha one_mem' := by simp end Matrix namespace SymplecticGroup variable [DecidableEq l] [Fintype l] [CommRing R] open Matrix theorem mem_iff {A : Matrix (l ⊕ l) (l ⊕ l) R} : A ∈ symplecticGroup l R ↔ A * J l R * Aᵀ = J l R := by simp [symplecticGroup] instance coeMatrix : Coe (symplecticGroup l R) (Matrix (l ⊕ l) (l ⊕ l) R) := ⟨Subtype.val⟩ section SymplecticJ variable (l) (R) theorem J_mem : J l R ∈ symplecticGroup l R := by rw [mem_iff, J, fromBlocks_multiply, fromBlocks_transpose, fromBlocks_multiply] simp /-- The canonical skew-symmetric matrix as an element in the symplectic group. -/ def symJ : symplecticGroup l R := ⟨J l R, J_mem l R⟩ variable {l} {R} @[simp] theorem coe_J : ↑(symJ l R) = J l R := rfl end SymplecticJ variable {A : Matrix (l ⊕ l) (l ⊕ l) R} theorem neg_mem (h : A ∈ symplecticGroup l R) : -A ∈ symplecticGroup l R := by rw [mem_iff] at h ⊢ simp [h] theorem symplectic_det (hA : A ∈ symplecticGroup l R) : IsUnit <\| det A := by rw [isUnit_iff_exists_inv] use A.det refine (isUnit_det_J l R).mul_left_cancel ?_ rw [mul_one] rw [mem_iff] at hA apply_fun det at hA simp only [det_mul, det_transpose] at hA rw [mul_comm A.det, mul_assoc] at hA exact hA theorem transpose_mem (hA : A ∈ symplecticGroup l R) : Aᵀ ∈ symplecticGroup l R := by rw [mem_iff] at hA ⊢ rw [transpose_transpose] have huA := symplectic_det hA have huAT : IsUnit Aᵀ.det := by rw [Matrix.det_transpose] exact huA calc Aᵀ * J l R * A = (-Aᵀ) * (J l R)⁻¹ * A := by rw [J_inv] simp _ = (-Aᵀ) * (A * J l R * Aᵀ)⁻¹ * A := by rw [hA] _ = -(Aᵀ * (Aᵀ⁻¹ * (J l R)⁻¹)) * A⁻¹ * A := by simp only [Matrix.mul_inv_rev, Matrix.mul_assoc, Matrix.neg_mul] _ = -(J l R)⁻¹ := by rw [mul_nonsing_inv_cancel_left _ _ huAT, nonsing_inv_mul_cancel_right _ _ huA] _ = J l R := by simp [J_inv] @[simp] theorem transpose_mem_iff : Aᵀ ∈ symplecticGroup l R ↔ A ∈ symplecticGroup l R := ⟨fun hA => by simpa using transpose_mem hA, transpose_mem⟩ theorem mem_iff' : A ∈ symplecticGroup l R ↔ Aᵀ * J l R * A = J l R := by rw [← transpose_mem_iff, mem_iff, transpose_transpose] instance hasInv : Inv (symplecticGroup l R) where inv A := ⟨(-J l R) * (A : Matrix (l ⊕ l) (l ⊕ l) R)ᵀ * J l R, mul_mem (mul_mem (neg_mem <\| J_mem _ _) <\| transpose_mem A.2) <\| J_mem _ _⟩ theorem coe_inv (A : symplecticGroup l R) : (↑A⁻¹ : Matrix _ _ _) = (-J l R) * (↑A)ᵀ * J l R := rfl theorem inv_left_mul_aux (hA : A ∈ symplecticGroup l R) : -(J l R * Aᵀ * J l R * A) = 1 := calc -(J l R * Aᵀ * J l R * A) = (-J l R) * (Aᵀ * J l R * A) := by simp only [Matrix.mul_assoc, Matrix.neg_mul] _ = (-J l R) * J l R := by rw [mem_iff'] at hA rw [hA] _ = (-1 : R) • (J l R * J l R) := by simp only [Matrix.neg_mul, neg_smul, one_smul] _ = (-1 : R) • (-1 : Matrix _ _ _) := by rw [J_squared] _ = 1 := by simp only [neg_smul_neg, one_smul] theorem coe_inv' (A : symplecticGroup l R) : (↑A⁻¹ : Matrix (l ⊕ l) (l ⊕ l) R) = (↑A)⁻¹ := by refine (coe_inv A).trans (inv_eq_left_inv ?_).symm simp [inv_left_mul_aux, coe_inv] theorem inv_eq_symplectic_inv (A : Matrix (l ⊕ l) (l ⊕ l) R) (hA : A ∈ symplecticGroup l R) : A⁻¹ = (-J l R) * Aᵀ * J l R := inv_eq_left_inv (by simp only [Matrix.neg_mul, inv_left_mul_aux hA])	instance : Group (symplecticGroup l R) := { SymplecticGroup.hasInv, Submonoid.toMonoid _ with	Mathlib/LinearAlgebra/SymplecticGroup.lean	178	179
/- Copyright (c) 2021 Aaron Anderson. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Aaron Anderson -/ import Mathlib.ModelTheory.Ultraproducts import Mathlib.ModelTheory.Bundled import Mathlib.ModelTheory.Skolem import Mathlib.Order.Filter.AtTopBot.Basic /-! # First-Order Satisfiability This file deals with the satisfiability of first-order theories, as well as equivalence over them. ## Main Definitions - `FirstOrder.Language.Theory.IsSatisfiable`: `T.IsSatisfiable` indicates that `T` has a nonempty model. - `FirstOrder.Language.Theory.IsFinitelySatisfiable`: `T.IsFinitelySatisfiable` indicates that every finite subset of `T` is satisfiable. - `FirstOrder.Language.Theory.IsComplete`: `T.IsComplete` indicates that `T` is satisfiable and models each sentence or its negation. - `Cardinal.Categorical`: A theory is `κ`-categorical if all models of size `κ` are isomorphic. ## Main Results - The Compactness Theorem, `FirstOrder.Language.Theory.isSatisfiable_iff_isFinitelySatisfiable`, shows that a theory is satisfiable iff it is finitely satisfiable. - `FirstOrder.Language.completeTheory.isComplete`: The complete theory of a structure is complete. - `FirstOrder.Language.Theory.exists_large_model_of_infinite_model` shows that any theory with an infinite model has arbitrarily large models. - `FirstOrder.Language.Theory.exists_elementaryEmbedding_card_eq`: The Upward Löwenheim–Skolem Theorem: If `κ` is a cardinal greater than the cardinalities of `L` and an infinite `L`-structure `M`, then `M` has an elementary extension of cardinality `κ`. ## Implementation Details - Satisfiability of an `L.Theory` `T` is defined in the minimal universe containing all the symbols of `L`. By Löwenheim-Skolem, this is equivalent to satisfiability in any universe. -/ universe u v w w' open Cardinal CategoryTheory open Cardinal FirstOrder namespace FirstOrder namespace Language variable {L : Language.{u, v}} {T : L.Theory} {α : Type w} {n : ℕ} namespace Theory variable (T) /-- A theory is satisfiable if a structure models it. -/ def IsSatisfiable : Prop := Nonempty (ModelType.{u, v, max u v} T) /-- A theory is finitely satisfiable if all of its finite subtheories are satisfiable. -/ def IsFinitelySatisfiable : Prop := ∀ T0 : Finset L.Sentence, (T0 : L.Theory) ⊆ T → IsSatisfiable (T0 : L.Theory) variable {T} {T' : L.Theory} theorem Model.isSatisfiable (M : Type w) [Nonempty M] [L.Structure M] [M ⊨ T] : T.IsSatisfiable := ⟨((⊥ : Substructure _ (ModelType.of T M)).elementarySkolem₁Reduct.toModel T).shrink⟩ theorem IsSatisfiable.mono (h : T'.IsSatisfiable) (hs : T ⊆ T') : T.IsSatisfiable := ⟨(Theory.Model.mono (ModelType.is_model h.some) hs).bundled⟩ theorem isSatisfiable_empty (L : Language.{u, v}) : IsSatisfiable (∅ : L.Theory) := ⟨default⟩ theorem isSatisfiable_of_isSatisfiable_onTheory {L' : Language.{w, w'}} (φ : L →ᴸ L') (h : (φ.onTheory T).IsSatisfiable) : T.IsSatisfiable := Model.isSatisfiable (h.some.reduct φ) theorem isSatisfiable_onTheory_iff {L' : Language.{w, w'}} {φ : L →ᴸ L'} (h : φ.Injective) : (φ.onTheory T).IsSatisfiable ↔ T.IsSatisfiable := by classical refine ⟨isSatisfiable_of_isSatisfiable_onTheory φ, fun h' => ?_⟩ haveI : Inhabited h'.some := Classical.inhabited_of_nonempty' exact Model.isSatisfiable (h'.some.defaultExpansion h) theorem IsSatisfiable.isFinitelySatisfiable (h : T.IsSatisfiable) : T.IsFinitelySatisfiable := fun _ => h.mono /-- The Compactness Theorem of first-order logic: A theory is satisfiable if and only if it is finitely satisfiable. -/ theorem isSatisfiable_iff_isFinitelySatisfiable {T : L.Theory} : T.IsSatisfiable ↔ T.IsFinitelySatisfiable := ⟨Theory.IsSatisfiable.isFinitelySatisfiable, fun h => by classical set M : Finset T → Type max u v := fun T0 : Finset T => (h (T0.map (Function.Embedding.subtype fun x => x ∈ T)) T0.map_subtype_subset).some.Carrier let M' := Filter.Product (Ultrafilter.of (Filter.atTop : Filter (Finset T))) M have h' : M' ⊨ T := by refine ⟨fun φ hφ => ?_⟩ rw [Ultraproduct.sentence_realize] refine Filter.Eventually.filter_mono (Ultrafilter.of_le _) (Filter.eventually_atTop.2 ⟨{⟨φ, hφ⟩}, fun s h' => Theory.realize_sentence_of_mem (s.map (Function.Embedding.subtype fun x => x ∈ T)) ?_⟩) simp only [Finset.coe_map, Function.Embedding.coe_subtype, Set.mem_image, Finset.mem_coe, Subtype.exists, Subtype.coe_mk, exists_and_right, exists_eq_right] exact ⟨hφ, h' (Finset.mem_singleton_self _)⟩ exact ⟨ModelType.of T M'⟩⟩ theorem isSatisfiable_directed_union_iff {ι : Type} [Nonempty ι] {T : ι → L.Theory} (h : Directed (· ⊆ ·) T) : Theory.IsSatisfiable (⋃ i, T i) ↔ ∀ i, (T i).IsSatisfiable := by refine ⟨fun h' i => h'.mono (Set.subset_iUnion _ _), fun h' => ?_⟩ rw [isSatisfiable_iff_isFinitelySatisfiable, IsFinitelySatisfiable] intro T0 hT0 obtain ⟨i, hi⟩ := h.exists_mem_subset_of_finset_subset_biUnion hT0 exact (h' i).mono hi theorem isSatisfiable_union_distinctConstantsTheory_of_card_le (T : L.Theory) (s : Set α) (M : Type w') [Nonempty M] [L.Structure M] [M ⊨ T] (h : Cardinal.lift.{w'} #s ≤ Cardinal.lift.{w} #M) : ((L.lhomWithConstants α).onTheory T ∪ L.distinctConstantsTheory s).IsSatisfiable := by haveI : Inhabited M := Classical.inhabited_of_nonempty inferInstance rw [Cardinal.lift_mk_le'] at h letI : (constantsOn α).Structure M := constantsOn.structure (Function.extend (↑) h.some default) have : M ⊨ (L.lhomWithConstants α).onTheory T ∪ L.distinctConstantsTheory s := by refine ((LHom.onTheory_model _ _).2 inferInstance).union ?_ rw [model_distinctConstantsTheory] refine fun a as b bs ab => ?_ rw [← Subtype.coe_mk a as, ← Subtype.coe_mk b bs, ← Subtype.ext_iff] exact h.some.injective ((Subtype.coe_injective.extend_apply h.some default ⟨a, as⟩).symm.trans (ab.trans (Subtype.coe_injective.extend_apply h.some default ⟨b, bs⟩))) exact Model.isSatisfiable M theorem isSatisfiable_union_distinctConstantsTheory_of_infinite (T : L.Theory) (s : Set α) (M : Type w') [L.Structure M] [M ⊨ T] [Infinite M] : ((L.lhomWithConstants α).onTheory T ∪ L.distinctConstantsTheory s).IsSatisfiable := by classical rw [distinctConstantsTheory_eq_iUnion, Set.union_iUnion, isSatisfiable_directed_union_iff] · exact fun t => isSatisfiable_union_distinctConstantsTheory_of_card_le T _ M ((lift_le_aleph0.2 (finset_card_lt_aleph0 _).le).trans (aleph0_le_lift.2 (aleph0_le_mk M))) · apply Monotone.directed_le refine monotone_const.union (monotone_distinctConstantsTheory.comp ?_) simp only [Finset.coe_map, Function.Embedding.coe_subtype] exact Monotone.comp (g := Set.image ((↑) : s → α)) (f := ((↑) : Finset s → Set s)) Set.monotone_image fun _ _ => Finset.coe_subset.2 /-- Any theory with an infinite model has arbitrarily large models. -/ theorem exists_large_model_of_infinite_model (T : L.Theory) (κ : Cardinal.{w}) (M : Type w') [L.Structure M] [M ⊨ T] [Infinite M] : ∃ N : ModelType.{_, _, max u v w} T, Cardinal.lift.{max u v w} κ ≤ #N := by obtain ⟨N⟩ := isSatisfiable_union_distinctConstantsTheory_of_infinite T (Set.univ : Set κ.out) M refine ⟨(N.is_model.mono Set.subset_union_left).bundled.reduct _, ?_⟩ haveI : N ⊨ distinctConstantsTheory _ _ := N.is_model.mono Set.subset_union_right rw [ModelType.reduct_Carrier, coe_of] refine _root_.trans (lift_le.2 (le_of_eq (Cardinal.mk_out κ).symm)) ?_ rw [← mk_univ] refine (card_le_of_model_distinctConstantsTheory L Set.univ N).trans (lift_le.{max u v w}.1 ?_) rw [lift_lift] theorem isSatisfiable_iUnion_iff_isSatisfiable_iUnion_finset {ι : Type} (T : ι → L.Theory) : IsSatisfiable (⋃ i, T i) ↔ ∀ s : Finset ι, IsSatisfiable (⋃ i ∈ s, T i) := by classical refine ⟨fun h s => h.mono (Set.iUnion_mono fun _ => Set.iUnion_subset_iff.2 fun _ => refl _), fun h => ?_⟩ rw [isSatisfiable_iff_isFinitelySatisfiable] intro s hs rw [Set.iUnion_eq_iUnion_finset] at hs obtain ⟨t, ht⟩ := Directed.exists_mem_subset_of_finset_subset_biUnion (by exact Monotone.directed_le fun t1 t2 (h : ∀ ⦃x⦄, x ∈ t1 → x ∈ t2) => Set.iUnion_mono fun _ => Set.iUnion_mono' fun h1 => ⟨h h1, refl _⟩) hs exact (h t).mono ht end Theory variable (L) /-- A version of The Downward Löwenheim–Skolem theorem where the structure `N` elementarily embeds into `M`, but is not by type a substructure of `M`, and thus can be chosen to belong to the universe of the cardinal `κ`. -/ theorem exists_elementaryEmbedding_card_eq_of_le (M : Type w') [L.Structure M] [Nonempty M] (κ : Cardinal.{w}) (h1 : ℵ₀ ≤ κ) (h2 : lift.{w} L.card ≤ Cardinal.lift.{max u v} κ) (h3 : lift.{w'} κ ≤ Cardinal.lift.{w} #M) : ∃ N : Bundled L.Structure, Nonempty (N ↪ₑ[L] M) ∧ #N = κ := by obtain ⟨S, _, hS⟩ := exists_elementarySubstructure_card_eq L ∅ κ h1 (by simp) h2 h3 have : Small.{w} S := by rw [← lift_inj.{_, w + 1}, lift_lift, lift_lift] at hS exact small_iff_lift_mk_lt_univ.2 (lt_of_eq_of_lt hS κ.lift_lt_univ') refine ⟨(equivShrink S).bundledInduced L, ⟨S.subtype.comp (Equiv.bundledInducedEquiv L _).symm.toElementaryEmbedding⟩, lift_inj.1 (_root_.trans ?_ hS)⟩ simp only [Equiv.bundledInduced_α, lift_mk_shrink'] section /-- The Upward Löwenheim–Skolem Theorem: If `κ` is a cardinal greater than the cardinalities of `L` and an infinite `L`-structure `M`, then `M` has an elementary extension of cardinality `κ`. -/ theorem exists_elementaryEmbedding_card_eq_of_ge (M : Type w') [L.Structure M] [iM : Infinite M] (κ : Cardinal.{w}) (h1 : Cardinal.lift.{w} L.card ≤ Cardinal.lift.{max u v} κ) (h2 : Cardinal.lift.{w} #M ≤ Cardinal.lift.{w'} κ) : ∃ N : Bundled L.Structure, Nonempty (M ↪ₑ[L] N) ∧ #N = κ := by obtain ⟨N0, hN0⟩ := (L.elementaryDiagram M).exists_large_model_of_infinite_model κ M rw [← lift_le.{max u v}, lift_lift, lift_lift] at h2 obtain ⟨N, ⟨NN0⟩, hN⟩ := exists_elementaryEmbedding_card_eq_of_le (L[[M]]) N0 κ (aleph0_le_lift.1 ((aleph0_le_lift.2 (aleph0_le_mk M)).trans h2)) (by simp only [card_withConstants, lift_add, lift_lift] rw [add_comm, add_eq_max (aleph0_le_lift.2 (infinite_iff.1 iM)), max_le_iff] rw [← lift_le.{w'}, lift_lift, lift_lift] at h1 exact ⟨h2, h1⟩) (hN0.trans (by rw [← lift_umax, lift_id])) letI := (lhomWithConstants L M).reduct N haveI h : N ⊨ L.elementaryDiagram M := (NN0.theory_model_iff (L.elementaryDiagram M)).2 inferInstance	refine ⟨Bundled.of N, ⟨?_⟩, hN⟩ apply ElementaryEmbedding.ofModelsElementaryDiagram L M N end /-- The Löwenheim–Skolem Theorem: If `κ` is a cardinal greater than the cardinalities of `L` and an infinite `L`-structure `M`, then there is an elementary embedding in the appropriate direction between then `M` and a structure of cardinality `κ`. -/ theorem exists_elementaryEmbedding_card_eq (M : Type w') [L.Structure M] [iM : Infinite M] (κ : Cardinal.{w}) (h1 : ℵ₀ ≤ κ) (h2 : lift.{w} L.card ≤ Cardinal.lift.{max u v} κ) : ∃ N : Bundled L.Structure, (Nonempty (N ↪ₑ[L] M) ∨ Nonempty (M ↪ₑ[L] N)) ∧ #N = κ := by cases le_or_gt (lift.{w'} κ) (Cardinal.lift.{w} #M) with \| inl h => obtain ⟨N, hN1, hN2⟩ := exists_elementaryEmbedding_card_eq_of_le L M κ h1 h2 h exact ⟨N, Or.inl hN1, hN2⟩ \| inr h => obtain ⟨N, hN1, hN2⟩ := exists_elementaryEmbedding_card_eq_of_ge L M κ h2 (le_of_lt h) exact ⟨N, Or.inr hN1, hN2⟩ /-- A consequence of the Löwenheim–Skolem Theorem: If `κ` is a cardinal greater than the	Mathlib/ModelTheory/Satisfiability.lean	233	252
/- Copyright (c) 2023 Peter Nelson. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Peter Nelson -/ import Mathlib.SetTheory.Cardinal.Finite import Mathlib.Data.Set.Finite.Powerset /-! # Noncomputable Set Cardinality We define the cardinality of set `s` as a term `Set.encard s : ℕ∞` and a term `Set.ncard s : ℕ`. The latter takes the junk value of zero if `s` is infinite. Both functions are noncomputable, and are defined in terms of `ENat.card` (which takes a type as its argument); this file can be seen as an API for the same function in the special case where the type is a coercion of a `Set`, allowing for smoother interactions with the `Set` API. `Set.encard` never takes junk values, so is more mathematically natural than `Set.ncard`, even though it takes values in a less convenient type. It is probably the right choice in settings where one is concerned with the cardinalities of sets that may or may not be infinite. `Set.ncard` has a nicer codomain, but when using it, `Set.Finite` hypotheses are normally needed to make sure its values are meaningful. More generally, `Set.ncard` is intended to be used over the obvious alternative `Finset.card` when finiteness is 'propositional' rather than 'structural'. When working with sets that are finite by virtue of their definition, then `Finset.card` probably makes more sense. One setting where `Set.ncard` works nicely is in a type `α` with `[Finite α]`, where every set is automatically finite. In this setting, we use default arguments and a simple tactic so that finiteness goals are discharged automatically in `Set.ncard` theorems. ## Main Definitions * `Set.encard s` is the cardinality of the set `s` as an extended natural number, with value `⊤` if `s` is infinite. * `Set.ncard s` is the cardinality of the set `s` as a natural number, provided `s` is Finite. If `s` is Infinite, then `Set.ncard s = 0`. * `toFinite_tac` is a tactic that tries to synthesize a `Set.Finite s` argument with `Set.toFinite`. This will work for `s : Set α` where there is a `Finite α` instance. ## Implementation Notes The theorems in this file are very similar to those in `Data.Finset.Card`, but with `Set` operations instead of `Finset`. We first prove all the theorems for `Set.encard`, and then derive most of the `Set.ncard` results as a consequence. Things are done this way to avoid reliance on the `Finset` API for theorems about infinite sets, and to allow for a refactor that removes or modifies `Set.ncard` in the future. Nearly all the theorems for `Set.ncard` require finiteness of one or more of their arguments. We provide this assumption with a default argument of the form `(hs : s.Finite := by toFinite_tac)`, where `toFinite_tac` will find an `s.Finite` term in the cases where `s` is a set in a `Finite` type. Often, where there are two set arguments `s` and `t`, the finiteness of one follows from the other in the context of the theorem, in which case we only include the ones that are needed, and derive the other inside the proof. A few of the theorems, such as `ncard_union_le` do not require finiteness arguments; they are true by coincidence due to junk values. -/ namespace Set variable {α β : Type} {s t : Set α} /-- The cardinality of a set as a term in `ℕ∞` -/ noncomputable def encard (s : Set α) : ℕ∞ := ENat.card s @[simp] theorem encard_univ_coe (s : Set α) : encard (univ : Set s) = encard s := by rw [encard, encard, ENat.card_congr (Equiv.Set.univ ↑s)] theorem encard_univ (α : Type) : encard (univ : Set α) = ENat.card α := by rw [encard, ENat.card_congr (Equiv.Set.univ α)] theorem Finite.encard_eq_coe_toFinset_card (h : s.Finite) : s.encard = h.toFinset.card := by have := h.fintype rw [encard, ENat.card_eq_coe_fintype_card, toFinite_toFinset, toFinset_card] theorem encard_eq_coe_toFinset_card (s : Set α) [Fintype s] : encard s = s.toFinset.card := by have h := toFinite s rw [h.encard_eq_coe_toFinset_card, toFinite_toFinset] @[simp] theorem toENat_cardinalMk (s : Set α) : (Cardinal.mk s).toENat = s.encard := rfl theorem toENat_cardinalMk_subtype (P : α → Prop) : (Cardinal.mk {x // P x}).toENat = {x \| P x}.encard := rfl @[simp] theorem coe_fintypeCard (s : Set α) [Fintype s] : Fintype.card s = s.encard := by simp [encard_eq_coe_toFinset_card] @[simp, norm_cast] theorem encard_coe_eq_coe_finsetCard (s : Finset α) : encard (s : Set α) = s.card := by rw [Finite.encard_eq_coe_toFinset_card (Finset.finite_toSet s)]; simp @[simp] theorem Infinite.encard_eq {s : Set α} (h : s.Infinite) : s.encard = ⊤ := by have := h.to_subtype rw [encard, ENat.card_eq_top_of_infinite] @[simp] theorem encard_eq_zero : s.encard = 0 ↔ s = ∅ := by rw [encard, ENat.card_eq_zero_iff_empty, isEmpty_subtype, eq_empty_iff_forall_not_mem] @[simp] theorem encard_empty : (∅ : Set α).encard = 0 := by rw [encard_eq_zero] theorem nonempty_of_encard_ne_zero (h : s.encard ≠ 0) : s.Nonempty := by rwa [nonempty_iff_ne_empty, Ne, ← encard_eq_zero] theorem encard_ne_zero : s.encard ≠ 0 ↔ s.Nonempty := by rw [ne_eq, encard_eq_zero, nonempty_iff_ne_empty] @[simp] theorem encard_pos : 0 < s.encard ↔ s.Nonempty := by rw [pos_iff_ne_zero, encard_ne_zero] protected alias ⟨_, Nonempty.encard_pos⟩ := encard_pos @[simp] theorem encard_singleton (e : α) : ({e} : Set α).encard = 1 := by rw [encard, ENat.card_eq_coe_fintype_card, Fintype.card_ofSubsingleton, Nat.cast_one] theorem encard_union_eq (h : Disjoint s t) : (s ∪ t).encard = s.encard + t.encard := by classical simp [encard, ENat.card_congr (Equiv.Set.union h)] theorem encard_insert_of_not_mem {a : α} (has : a ∉ s) : (insert a s).encard = s.encard + 1 := by rw [← union_singleton, encard_union_eq (by simpa), encard_singleton] theorem Finite.encard_lt_top (h : s.Finite) : s.encard < ⊤ := by induction s, h using Set.Finite.induction_on with \| empty => simp \| insert hat _ ht' => rw [encard_insert_of_not_mem hat] exact lt_tsub_iff_right.1 ht' theorem Finite.encard_eq_coe (h : s.Finite) : s.encard = ENat.toNat s.encard := (ENat.coe_toNat h.encard_lt_top.ne).symm theorem Finite.exists_encard_eq_coe (h : s.Finite) : ∃ (n : ℕ), s.encard = n := ⟨_, h.encard_eq_coe⟩ @[simp] theorem encard_lt_top_iff : s.encard < ⊤ ↔ s.Finite := ⟨fun h ↦ by_contra fun h' ↦ h.ne (Infinite.encard_eq h'), Finite.encard_lt_top⟩ @[simp] theorem encard_eq_top_iff : s.encard = ⊤ ↔ s.Infinite := by rw [← not_iff_not, ← Ne, ← lt_top_iff_ne_top, encard_lt_top_iff, not_infinite] alias ⟨_, encard_eq_top⟩ := encard_eq_top_iff theorem encard_ne_top_iff : s.encard ≠ ⊤ ↔ s.Finite := by simp theorem finite_of_encard_le_coe {k : ℕ} (h : s.encard ≤ k) : s.Finite := by rw [← encard_lt_top_iff]; exact h.trans_lt (WithTop.coe_lt_top _) theorem finite_of_encard_eq_coe {k : ℕ} (h : s.encard = k) : s.Finite := finite_of_encard_le_coe h.le theorem encard_le_coe_iff {k : ℕ} : s.encard ≤ k ↔ s.Finite ∧ ∃ (n₀ : ℕ), s.encard = n₀ ∧ n₀ ≤ k := ⟨fun h ↦ ⟨finite_of_encard_le_coe h, by rwa [ENat.le_coe_iff] at h⟩, fun ⟨_,⟨n₀,hs, hle⟩⟩ ↦ by rwa [hs, Nat.cast_le]⟩ @[simp] theorem encard_prod : (s ×ˢ t).encard = s.encard * t.encard := by simp [Set.encard, ENat.card_congr (Equiv.Set.prod ..)] section Lattice theorem encard_le_encard (h : s ⊆ t) : s.encard ≤ t.encard := by rw [← union_diff_cancel h, encard_union_eq disjoint_sdiff_right]; exact le_self_add @[deprecated (since := "2025-01-05")] alias encard_le_card := encard_le_encard theorem encard_mono {α : Type*} : Monotone (encard : Set α → ℕ∞) := fun _ _ ↦ encard_le_encard theorem encard_diff_add_encard_of_subset (h : s ⊆ t) : (t \ s).encard + s.encard = t.encard := by rw [← encard_union_eq disjoint_sdiff_left, diff_union_self, union_eq_self_of_subset_right h] @[simp] theorem one_le_encard_iff_nonempty : 1 ≤ s.encard ↔ s.Nonempty := by rw [nonempty_iff_ne_empty, Ne, ← encard_eq_zero, ENat.one_le_iff_ne_zero] theorem encard_diff_add_encard_inter (s t : Set α) : (s \ t).encard + (s ∩ t).encard = s.encard := by rw [← encard_union_eq (disjoint_of_subset_right inter_subset_right disjoint_sdiff_left), diff_union_inter] theorem encard_union_add_encard_inter (s t : Set α) : (s ∪ t).encard + (s ∩ t).encard = s.encard + t.encard := by rw [← diff_union_self, encard_union_eq disjoint_sdiff_left, add_right_comm, encard_diff_add_encard_inter] theorem encard_eq_encard_iff_encard_diff_eq_encard_diff (h : (s ∩ t).Finite) : s.encard = t.encard ↔ (s \ t).encard = (t \ s).encard := by rw [← encard_diff_add_encard_inter s t, ← encard_diff_add_encard_inter t s, inter_comm t s, WithTop.add_right_inj h.encard_lt_top.ne] theorem encard_le_encard_iff_encard_diff_le_encard_diff (h : (s ∩ t).Finite) : s.encard ≤ t.encard ↔ (s \ t).encard ≤ (t \ s).encard := by	rw [← encard_diff_add_encard_inter s t, ← encard_diff_add_encard_inter t s, inter_comm t s, WithTop.add_le_add_iff_right h.encard_lt_top.ne]	Mathlib/Data/Set/Card.lean	195	196
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Jeremy Avigad -/ import Mathlib.Algebra.Group.Basic import Mathlib.Algebra.Notation.Pi import Mathlib.Data.Set.Lattice import Mathlib.Order.Filter.Defs /-! # Theory of filters on sets A filter on a type `α` is a collection of sets of `α` which contains the whole `α`, is upwards-closed, and is stable under intersection. They are mostly used to abstract two related kinds of ideas: * limits, including finite or infinite limits of sequences, finite or infinite limits of functions at a point or at infinity, etc... * things happening eventually, including things happening for large enough `n : ℕ`, or near enough a point `x`, or for close enough pairs of points, or things happening almost everywhere in the sense of measure theory. Dually, filters can also express the idea of things happening often: for arbitrarily large `n`, or at a point in any neighborhood of given a point etc... ## Main definitions In this file, we endow `Filter α` it with a complete lattice structure. This structure is lifted from the lattice structure on `Set (Set X)` using the Galois insertion which maps a filter to its elements in one direction, and an arbitrary set of sets to the smallest filter containing it in the other direction. We also prove `Filter` is a monadic functor, with a push-forward operation `Filter.map` and a pull-back operation `Filter.comap` that form a Galois connections for the order on filters. The examples of filters appearing in the description of the two motivating ideas are: * `(Filter.atTop : Filter ℕ)` : made of sets of `ℕ` containing `{n \| n ≥ N}` for some `N` * `𝓝 x` : made of neighborhoods of `x` in a topological space (defined in topology.basic) * `𝓤 X` : made of entourages of a uniform space (those space are generalizations of metric spaces defined in `Mathlib/Topology/UniformSpace/Basic.lean`) * `MeasureTheory.ae` : made of sets whose complement has zero measure with respect to `μ` (defined in `Mathlib/MeasureTheory/OuterMeasure/AE`) The predicate "happening eventually" is `Filter.Eventually`, and "happening often" is `Filter.Frequently`, whose definitions are immediate after `Filter` is defined (but they come rather late in this file in order to immediately relate them to the lattice structure). ## Notations * `∀ᶠ x in f, p x` : `f.Eventually p`; * `∃ᶠ x in f, p x` : `f.Frequently p`; * `f =ᶠ[l] g` : `∀ᶠ x in l, f x = g x`; * `f ≤ᶠ[l] g` : `∀ᶠ x in l, f x ≤ g x`; * `𝓟 s` : `Filter.Principal s`, localized in `Filter`. ## References * [N. Bourbaki, General Topology][bourbaki1966] Important note: Bourbaki requires that a filter on `X` cannot contain all sets of `X`, which we do not require. This gives `Filter X` better formal properties, in particular a bottom element `⊥` for its lattice structure, at the cost of including the assumption `[NeBot f]` in a number of lemmas and definitions. -/ assert_not_exists OrderedSemiring Fintype open Function Set Order open scoped symmDiff universe u v w x y namespace Filter variable {α : Type u} {f g : Filter α} {s t : Set α} instance inhabitedMem : Inhabited { s : Set α // s ∈ f } := ⟨⟨univ, f.univ_sets⟩⟩ theorem filter_eq_iff : f = g ↔ f.sets = g.sets := ⟨congr_arg _, filter_eq⟩ @[simp] theorem sets_subset_sets : f.sets ⊆ g.sets ↔ g ≤ f := .rfl @[simp] theorem sets_ssubset_sets : f.sets ⊂ g.sets ↔ g < f := .rfl /-- An extensionality lemma that is useful for filters with good lemmas about `sᶜ ∈ f` (e.g., `Filter.comap`, `Filter.coprod`, `Filter.Coprod`, `Filter.cofinite`). -/ protected theorem coext (h : ∀ s, sᶜ ∈ f ↔ sᶜ ∈ g) : f = g := Filter.ext <\| compl_surjective.forall.2 h instance : Trans (· ⊇ ·) ((· ∈ ·) : Set α → Filter α → Prop) (· ∈ ·) where trans h₁ h₂ := mem_of_superset h₂ h₁ instance : Trans Membership.mem (· ⊆ ·) (Membership.mem : Filter α → Set α → Prop) where trans h₁ h₂ := mem_of_superset h₁ h₂ @[simp] theorem inter_mem_iff {s t : Set α} : s ∩ t ∈ f ↔ s ∈ f ∧ t ∈ f := ⟨fun h => ⟨mem_of_superset h inter_subset_left, mem_of_superset h inter_subset_right⟩, and_imp.2 inter_mem⟩ theorem diff_mem {s t : Set α} (hs : s ∈ f) (ht : tᶜ ∈ f) : s \ t ∈ f := inter_mem hs ht theorem congr_sets (h : { x \| x ∈ s ↔ x ∈ t } ∈ f) : s ∈ f ↔ t ∈ f := ⟨fun hs => mp_mem hs (mem_of_superset h fun _ => Iff.mp), fun hs => mp_mem hs (mem_of_superset h fun _ => Iff.mpr)⟩ lemma copy_eq {S} (hmem : ∀ s, s ∈ S ↔ s ∈ f) : f.copy S hmem = f := Filter.ext hmem /-- Weaker version of `Filter.biInter_mem` that assumes `Subsingleton β` rather than `Finite β`. -/ theorem biInter_mem' {β : Type v} {s : β → Set α} {is : Set β} (hf : is.Subsingleton) : (⋂ i ∈ is, s i) ∈ f ↔ ∀ i ∈ is, s i ∈ f := by apply Subsingleton.induction_on hf <;> simp /-- Weaker version of `Filter.iInter_mem` that assumes `Subsingleton β` rather than `Finite β`. -/ theorem iInter_mem' {β : Sort v} {s : β → Set α} [Subsingleton β] : (⋂ i, s i) ∈ f ↔ ∀ i, s i ∈ f := by rw [← sInter_range, sInter_eq_biInter, biInter_mem' (subsingleton_range s), forall_mem_range] theorem exists_mem_subset_iff : (∃ t ∈ f, t ⊆ s) ↔ s ∈ f := ⟨fun ⟨_, ht, ts⟩ => mem_of_superset ht ts, fun hs => ⟨s, hs, Subset.rfl⟩⟩ theorem monotone_mem {f : Filter α} : Monotone fun s => s ∈ f := fun _ _ hst h => mem_of_superset h hst theorem exists_mem_and_iff {P : Set α → Prop} {Q : Set α → Prop} (hP : Antitone P) (hQ : Antitone Q) : ((∃ u ∈ f, P u) ∧ ∃ u ∈ f, Q u) ↔ ∃ u ∈ f, P u ∧ Q u := by constructor · rintro ⟨⟨u, huf, hPu⟩, v, hvf, hQv⟩ exact ⟨u ∩ v, inter_mem huf hvf, hP inter_subset_left hPu, hQ inter_subset_right hQv⟩ · rintro ⟨u, huf, hPu, hQu⟩ exact ⟨⟨u, huf, hPu⟩, u, huf, hQu⟩ theorem forall_in_swap {β : Type} {p : Set α → β → Prop} : (∀ a ∈ f, ∀ (b), p a b) ↔ ∀ (b), ∀ a ∈ f, p a b := Set.forall_in_swap end Filter namespace Filter variable {α : Type u} {β : Type v} {γ : Type w} {δ : Type} {ι : Sort x} theorem mem_principal_self (s : Set α) : s ∈ 𝓟 s := Subset.rfl section Lattice variable {f g : Filter α} {s t : Set α} protected theorem not_le : ¬f ≤ g ↔ ∃ s ∈ g, s ∉ f := by simp_rw [le_def, not_forall, exists_prop] /-- `GenerateSets g s`: `s` is in the filter closure of `g`. -/ inductive GenerateSets (g : Set (Set α)) : Set α → Prop \| basic {s : Set α} : s ∈ g → GenerateSets g s \| univ : GenerateSets g univ \| superset {s t : Set α} : GenerateSets g s → s ⊆ t → GenerateSets g t \| inter {s t : Set α} : GenerateSets g s → GenerateSets g t → GenerateSets g (s ∩ t) /-- `generate g` is the largest filter containing the sets `g`. -/ def generate (g : Set (Set α)) : Filter α where sets := {s \| GenerateSets g s} univ_sets := GenerateSets.univ sets_of_superset := GenerateSets.superset inter_sets := GenerateSets.inter lemma mem_generate_of_mem {s : Set <\| Set α} {U : Set α} (h : U ∈ s) : U ∈ generate s := GenerateSets.basic h theorem le_generate_iff {s : Set (Set α)} {f : Filter α} : f ≤ generate s ↔ s ⊆ f.sets := Iff.intro (fun h _ hu => h <\| GenerateSets.basic <\| hu) fun h _ hu => hu.recOn (fun h' => h h') univ_mem (fun _ hxy hx => mem_of_superset hx hxy) fun _ _ hx hy => inter_mem hx hy @[simp] lemma generate_singleton (s : Set α) : generate {s} = 𝓟 s := le_antisymm (fun _t ht ↦ mem_of_superset (mem_generate_of_mem <\| mem_singleton _) ht) <\| le_generate_iff.2 <\| singleton_subset_iff.2 Subset.rfl /-- `mkOfClosure s hs` constructs a filter on `α` whose elements set is exactly `s : Set (Set α)`, provided one gives the assumption `hs : (generate s).sets = s`. -/ protected def mkOfClosure (s : Set (Set α)) (hs : (generate s).sets = s) : Filter α where sets := s univ_sets := hs ▸ univ_mem sets_of_superset := hs ▸ mem_of_superset inter_sets := hs ▸ inter_mem theorem mkOfClosure_sets {s : Set (Set α)} {hs : (generate s).sets = s} : Filter.mkOfClosure s hs = generate s := Filter.ext fun u => show u ∈ (Filter.mkOfClosure s hs).sets ↔ u ∈ (generate s).sets from hs.symm ▸ Iff.rfl /-- Galois insertion from sets of sets into filters. -/ def giGenerate (α : Type) : @GaloisInsertion (Set (Set α)) (Filter α)ᵒᵈ _ _ Filter.generate Filter.sets where gc _ _ := le_generate_iff le_l_u _ _ h := GenerateSets.basic h choice s hs := Filter.mkOfClosure s (le_antisymm hs <\| le_generate_iff.1 <\| le_rfl) choice_eq _ _ := mkOfClosure_sets theorem mem_inf_iff {f g : Filter α} {s : Set α} : s ∈ f ⊓ g ↔ ∃ t₁ ∈ f, ∃ t₂ ∈ g, s = t₁ ∩ t₂ := Iff.rfl theorem mem_inf_of_left {f g : Filter α} {s : Set α} (h : s ∈ f) : s ∈ f ⊓ g := ⟨s, h, univ, univ_mem, (inter_univ s).symm⟩ theorem mem_inf_of_right {f g : Filter α} {s : Set α} (h : s ∈ g) : s ∈ f ⊓ g := ⟨univ, univ_mem, s, h, (univ_inter s).symm⟩ theorem inter_mem_inf {α : Type u} {f g : Filter α} {s t : Set α} (hs : s ∈ f) (ht : t ∈ g) : s ∩ t ∈ f ⊓ g := ⟨s, hs, t, ht, rfl⟩ theorem mem_inf_of_inter {f g : Filter α} {s t u : Set α} (hs : s ∈ f) (ht : t ∈ g) (h : s ∩ t ⊆ u) : u ∈ f ⊓ g := mem_of_superset (inter_mem_inf hs ht) h theorem mem_inf_iff_superset {f g : Filter α} {s : Set α} : s ∈ f ⊓ g ↔ ∃ t₁ ∈ f, ∃ t₂ ∈ g, t₁ ∩ t₂ ⊆ s := ⟨fun ⟨t₁, h₁, t₂, h₂, Eq⟩ => ⟨t₁, h₁, t₂, h₂, Eq ▸ Subset.rfl⟩, fun ⟨_, h₁, _, h₂, sub⟩ => mem_inf_of_inter h₁ h₂ sub⟩ section CompleteLattice /-- Complete lattice structure on `Filter α`. -/ instance instCompleteLatticeFilter : CompleteLattice (Filter α) where inf a b := min a b sup a b := max a b le_sup_left _ _ _ h := h.1 le_sup_right _ _ _ h := h.2 sup_le _ _ _ h₁ h₂ _ h := ⟨h₁ h, h₂ h⟩ inf_le_left _ _ _ := mem_inf_of_left inf_le_right _ _ _ := mem_inf_of_right le_inf := fun _ _ _ h₁ h₂ _s ⟨_a, ha, _b, hb, hs⟩ => hs.symm ▸ inter_mem (h₁ ha) (h₂ hb) le_sSup _ _ h₁ _ h₂ := h₂ h₁ sSup_le _ _ h₁ _ h₂ _ h₃ := h₁ _ h₃ h₂ sInf_le _ _ h₁ _ h₂ := by rw [← Filter.sSup_lowerBounds]; exact fun _ h₃ ↦ h₃ h₁ h₂ le_sInf _ _ h₁ _ h₂ := by rw [← Filter.sSup_lowerBounds] at h₂; exact h₂ h₁ le_top _ _ := univ_mem' bot_le _ _ _ := trivial instance : Inhabited (Filter α) := ⟨⊥⟩ end CompleteLattice theorem NeBot.ne {f : Filter α} (hf : NeBot f) : f ≠ ⊥ := hf.ne' @[simp] theorem not_neBot {f : Filter α} : ¬f.NeBot ↔ f = ⊥ := neBot_iff.not_left theorem NeBot.mono {f g : Filter α} (hf : NeBot f) (hg : f ≤ g) : NeBot g := ⟨ne_bot_of_le_ne_bot hf.1 hg⟩ theorem neBot_of_le {f g : Filter α} [hf : NeBot f] (hg : f ≤ g) : NeBot g := hf.mono hg @[simp] theorem sup_neBot {f g : Filter α} : NeBot (f ⊔ g) ↔ NeBot f ∨ NeBot g := by simp only [neBot_iff, not_and_or, Ne, sup_eq_bot_iff] theorem not_disjoint_self_iff : ¬Disjoint f f ↔ f.NeBot := by rw [disjoint_self, neBot_iff] theorem bot_sets_eq : (⊥ : Filter α).sets = univ := rfl /-- Either `f = ⊥` or `Filter.NeBot f`. This is a version of `eq_or_ne` that uses `Filter.NeBot` as the second alternative, to be used as an instance. -/ theorem eq_or_neBot (f : Filter α) : f = ⊥ ∨ NeBot f := (eq_or_ne f ⊥).imp_right NeBot.mk theorem sup_sets_eq {f g : Filter α} : (f ⊔ g).sets = f.sets ∩ g.sets := (giGenerate α).gc.u_inf theorem sSup_sets_eq {s : Set (Filter α)} : (sSup s).sets = ⋂ f ∈ s, (f : Filter α).sets := (giGenerate α).gc.u_sInf theorem iSup_sets_eq {f : ι → Filter α} : (iSup f).sets = ⋂ i, (f i).sets := (giGenerate α).gc.u_iInf theorem generate_empty : Filter.generate ∅ = (⊤ : Filter α) := (giGenerate α).gc.l_bot theorem generate_univ : Filter.generate univ = (⊥ : Filter α) := bot_unique fun _ _ => GenerateSets.basic (mem_univ _) theorem generate_union {s t : Set (Set α)} : Filter.generate (s ∪ t) = Filter.generate s ⊓ Filter.generate t := (giGenerate α).gc.l_sup theorem generate_iUnion {s : ι → Set (Set α)} : Filter.generate (⋃ i, s i) = ⨅ i, Filter.generate (s i) := (giGenerate α).gc.l_iSup @[simp] theorem mem_sup {f g : Filter α} {s : Set α} : s ∈ f ⊔ g ↔ s ∈ f ∧ s ∈ g := Iff.rfl theorem union_mem_sup {f g : Filter α} {s t : Set α} (hs : s ∈ f) (ht : t ∈ g) : s ∪ t ∈ f ⊔ g := ⟨mem_of_superset hs subset_union_left, mem_of_superset ht subset_union_right⟩ @[simp] theorem mem_iSup {x : Set α} {f : ι → Filter α} : x ∈ iSup f ↔ ∀ i, x ∈ f i := by simp only [← Filter.mem_sets, iSup_sets_eq, mem_iInter] @[simp] theorem iSup_neBot {f : ι → Filter α} : (⨆ i, f i).NeBot ↔ ∃ i, (f i).NeBot := by simp [neBot_iff] theorem iInf_eq_generate (s : ι → Filter α) : iInf s = generate (⋃ i, (s i).sets) := eq_of_forall_le_iff fun _ ↦ by simp [le_generate_iff] theorem mem_iInf_of_mem {f : ι → Filter α} (i : ι) {s} (hs : s ∈ f i) : s ∈ ⨅ i, f i := iInf_le f i hs @[simp] theorem le_principal_iff {s : Set α} {f : Filter α} : f ≤ 𝓟 s ↔ s ∈ f := ⟨fun h => h Subset.rfl, fun hs _ ht => mem_of_superset hs ht⟩ theorem Iic_principal (s : Set α) : Iic (𝓟 s) = { l \| s ∈ l } := Set.ext fun _ => le_principal_iff theorem principal_mono {s t : Set α} : 𝓟 s ≤ 𝓟 t ↔ s ⊆ t := by simp only [le_principal_iff, mem_principal] @[gcongr] alias ⟨_, _root_.GCongr.filter_principal_mono⟩ := principal_mono @[mono] theorem monotone_principal : Monotone (𝓟 : Set α → Filter α) := fun _ _ => principal_mono.2 @[simp] theorem principal_eq_iff_eq {s t : Set α} : 𝓟 s = 𝓟 t ↔ s = t := by simp only [le_antisymm_iff, le_principal_iff, mem_principal]; rfl @[simp] theorem join_principal_eq_sSup {s : Set (Filter α)} : join (𝓟 s) = sSup s := rfl @[simp] theorem principal_univ : 𝓟 (univ : Set α) = ⊤ := top_unique <\| by simp only [le_principal_iff, mem_top, eq_self_iff_true] @[simp] theorem principal_empty : 𝓟 (∅ : Set α) = ⊥ := bot_unique fun _ _ => empty_subset _ theorem generate_eq_biInf (S : Set (Set α)) : generate S = ⨅ s ∈ S, 𝓟 s := eq_of_forall_le_iff fun f => by simp [le_generate_iff, le_principal_iff, subset_def] /-! ### Lattice equations -/ theorem empty_mem_iff_bot {f : Filter α} : ∅ ∈ f ↔ f = ⊥ := ⟨fun h => bot_unique fun s _ => mem_of_superset h (empty_subset s), fun h => h.symm ▸ mem_bot⟩ theorem nonempty_of_mem {f : Filter α} [hf : NeBot f] {s : Set α} (hs : s ∈ f) : s.Nonempty := s.eq_empty_or_nonempty.elim (fun h => absurd hs (h.symm ▸ mt empty_mem_iff_bot.mp hf.1)) id theorem NeBot.nonempty_of_mem {f : Filter α} (hf : NeBot f) {s : Set α} (hs : s ∈ f) : s.Nonempty := @Filter.nonempty_of_mem α f hf s hs @[simp] theorem empty_not_mem (f : Filter α) [NeBot f] : ¬∅ ∈ f := fun h => (nonempty_of_mem h).ne_empty rfl theorem nonempty_of_neBot (f : Filter α) [NeBot f] : Nonempty α := nonempty_of_exists <\| nonempty_of_mem (univ_mem : univ ∈ f) theorem compl_not_mem {f : Filter α} {s : Set α} [NeBot f] (h : s ∈ f) : sᶜ ∉ f := fun hsc => (nonempty_of_mem (inter_mem h hsc)).ne_empty <\| inter_compl_self s theorem filter_eq_bot_of_isEmpty [IsEmpty α] (f : Filter α) : f = ⊥ := empty_mem_iff_bot.mp <\| univ_mem' isEmptyElim protected lemma disjoint_iff {f g : Filter α} : Disjoint f g ↔ ∃ s ∈ f, ∃ t ∈ g, Disjoint s t := by simp only [disjoint_iff, ← empty_mem_iff_bot, mem_inf_iff, inf_eq_inter, bot_eq_empty, @eq_comm _ ∅] theorem disjoint_of_disjoint_of_mem {f g : Filter α} {s t : Set α} (h : Disjoint s t) (hs : s ∈ f) (ht : t ∈ g) : Disjoint f g := Filter.disjoint_iff.mpr ⟨s, hs, t, ht, h⟩ theorem NeBot.not_disjoint (hf : f.NeBot) (hs : s ∈ f) (ht : t ∈ f) : ¬Disjoint s t := fun h => not_disjoint_self_iff.2 hf <\| Filter.disjoint_iff.2 ⟨s, hs, t, ht, h⟩ theorem inf_eq_bot_iff {f g : Filter α} : f ⊓ g = ⊥ ↔ ∃ U ∈ f, ∃ V ∈ g, U ∩ V = ∅ := by simp only [← disjoint_iff, Filter.disjoint_iff, Set.disjoint_iff_inter_eq_empty] /-- There is exactly one filter on an empty type. -/ instance unique [IsEmpty α] : Unique (Filter α) where default := ⊥ uniq := filter_eq_bot_of_isEmpty theorem NeBot.nonempty (f : Filter α) [hf : f.NeBot] : Nonempty α := not_isEmpty_iff.mp fun _ ↦ hf.ne (Subsingleton.elim _ _) /-- There are only two filters on a `Subsingleton`: `⊥` and `⊤`. If the type is empty, then they are equal. -/ theorem eq_top_of_neBot [Subsingleton α] (l : Filter α) [NeBot l] : l = ⊤ := by refine top_unique fun s hs => ?_ obtain rfl : s = univ := Subsingleton.eq_univ_of_nonempty (nonempty_of_mem hs) exact univ_mem theorem forall_mem_nonempty_iff_neBot {f : Filter α} : (∀ s : Set α, s ∈ f → s.Nonempty) ↔ NeBot f := ⟨fun h => ⟨fun hf => not_nonempty_empty (h ∅ <\| hf.symm ▸ mem_bot)⟩, @nonempty_of_mem _ _⟩ instance instNeBotTop [Nonempty α] : NeBot (⊤ : Filter α) := forall_mem_nonempty_iff_neBot.1 fun s hs => by rwa [mem_top.1 hs, ← nonempty_iff_univ_nonempty] instance instNontrivialFilter [Nonempty α] : Nontrivial (Filter α) := ⟨⟨⊤, ⊥, instNeBotTop.ne⟩⟩ theorem nontrivial_iff_nonempty : Nontrivial (Filter α) ↔ Nonempty α := ⟨fun _ => by_contra fun h' => haveI := not_nonempty_iff.1 h' not_subsingleton (Filter α) inferInstance, @Filter.instNontrivialFilter α⟩ theorem eq_sInf_of_mem_iff_exists_mem {S : Set (Filter α)} {l : Filter α} (h : ∀ {s}, s ∈ l ↔ ∃ f ∈ S, s ∈ f) : l = sInf S := le_antisymm (le_sInf fun f hf _ hs => h.2 ⟨f, hf, hs⟩) fun _ hs => let ⟨_, hf, hs⟩ := h.1 hs; (sInf_le hf) hs theorem eq_iInf_of_mem_iff_exists_mem {f : ι → Filter α} {l : Filter α} (h : ∀ {s}, s ∈ l ↔ ∃ i, s ∈ f i) : l = iInf f := eq_sInf_of_mem_iff_exists_mem <\| h.trans (exists_range_iff (p := (_ ∈ ·))).symm theorem eq_biInf_of_mem_iff_exists_mem {f : ι → Filter α} {p : ι → Prop} {l : Filter α} (h : ∀ {s}, s ∈ l ↔ ∃ i, p i ∧ s ∈ f i) : l = ⨅ (i) (_ : p i), f i := by rw [iInf_subtype'] exact eq_iInf_of_mem_iff_exists_mem fun {_} => by simp only [Subtype.exists, h, exists_prop] theorem iInf_sets_eq {f : ι → Filter α} (h : Directed (· ≥ ·) f) [ne : Nonempty ι] : (iInf f).sets = ⋃ i, (f i).sets := let ⟨i⟩ := ne let u := { sets := ⋃ i, (f i).sets univ_sets := mem_iUnion.2 ⟨i, univ_mem⟩ sets_of_superset := by simp only [mem_iUnion, exists_imp] exact fun i hx hxy => ⟨i, mem_of_superset hx hxy⟩ inter_sets := by simp only [mem_iUnion, exists_imp] intro x y a hx b hy rcases h a b with ⟨c, ha, hb⟩ exact ⟨c, inter_mem (ha hx) (hb hy)⟩ } have : u = iInf f := eq_iInf_of_mem_iff_exists_mem mem_iUnion congr_arg Filter.sets this.symm theorem mem_iInf_of_directed {f : ι → Filter α} (h : Directed (· ≥ ·) f) [Nonempty ι] (s) : s ∈ iInf f ↔ ∃ i, s ∈ f i := by simp only [← Filter.mem_sets, iInf_sets_eq h, mem_iUnion] theorem mem_biInf_of_directed {f : β → Filter α} {s : Set β} (h : DirectedOn (f ⁻¹'o (· ≥ ·)) s) (ne : s.Nonempty) {t : Set α} : (t ∈ ⨅ i ∈ s, f i) ↔ ∃ i ∈ s, t ∈ f i := by haveI := ne.to_subtype simp_rw [iInf_subtype', mem_iInf_of_directed h.directed_val, Subtype.exists, exists_prop] theorem biInf_sets_eq {f : β → Filter α} {s : Set β} (h : DirectedOn (f ⁻¹'o (· ≥ ·)) s) (ne : s.Nonempty) : (⨅ i ∈ s, f i).sets = ⋃ i ∈ s, (f i).sets := ext fun t => by simp [mem_biInf_of_directed h ne] @[simp] theorem sup_join {f₁ f₂ : Filter (Filter α)} : join f₁ ⊔ join f₂ = join (f₁ ⊔ f₂) := Filter.ext fun x => by simp only [mem_sup, mem_join] @[simp] theorem iSup_join {ι : Sort w} {f : ι → Filter (Filter α)} : ⨆ x, join (f x) = join (⨆ x, f x) := Filter.ext fun x => by simp only [mem_iSup, mem_join] instance : DistribLattice (Filter α) := { Filter.instCompleteLatticeFilter with le_sup_inf := by intro x y z s simp only [and_assoc, mem_inf_iff, mem_sup, exists_prop, exists_imp, and_imp] rintro hs t₁ ht₁ t₂ ht₂ rfl exact ⟨t₁, x.sets_of_superset hs inter_subset_left, ht₁, t₂, x.sets_of_superset hs inter_subset_right, ht₂, rfl⟩ } /-- If `f : ι → Filter α` is directed, `ι` is not empty, and `∀ i, f i ≠ ⊥`, then `iInf f ≠ ⊥`. See also `iInf_neBot_of_directed` for a version assuming `Nonempty α` instead of `Nonempty ι`. -/ theorem iInf_neBot_of_directed' {f : ι → Filter α} [Nonempty ι] (hd : Directed (· ≥ ·) f) : (∀ i, NeBot (f i)) → NeBot (iInf f) := not_imp_not.1 <\| by simpa only [not_forall, not_neBot, ← empty_mem_iff_bot, mem_iInf_of_directed hd] using id /-- If `f : ι → Filter α` is directed, `α` is not empty, and `∀ i, f i ≠ ⊥`, then `iInf f ≠ ⊥`. See also `iInf_neBot_of_directed'` for a version assuming `Nonempty ι` instead of `Nonempty α`. -/ theorem iInf_neBot_of_directed {f : ι → Filter α} [hn : Nonempty α] (hd : Directed (· ≥ ·) f) (hb : ∀ i, NeBot (f i)) : NeBot (iInf f) := by cases isEmpty_or_nonempty ι · constructor simp [iInf_of_empty f, top_ne_bot] · exact iInf_neBot_of_directed' hd hb theorem sInf_neBot_of_directed' {s : Set (Filter α)} (hne : s.Nonempty) (hd : DirectedOn (· ≥ ·) s) (hbot : ⊥ ∉ s) : NeBot (sInf s) := (sInf_eq_iInf' s).symm ▸ @iInf_neBot_of_directed' _ _ _ hne.to_subtype hd.directed_val fun ⟨_, hf⟩ => ⟨ne_of_mem_of_not_mem hf hbot⟩ theorem sInf_neBot_of_directed [Nonempty α] {s : Set (Filter α)} (hd : DirectedOn (· ≥ ·) s) (hbot : ⊥ ∉ s) : NeBot (sInf s) := (sInf_eq_iInf' s).symm ▸ iInf_neBot_of_directed hd.directed_val fun ⟨_, hf⟩ => ⟨ne_of_mem_of_not_mem hf hbot⟩ theorem iInf_neBot_iff_of_directed' {f : ι → Filter α} [Nonempty ι] (hd : Directed (· ≥ ·) f) : NeBot (iInf f) ↔ ∀ i, NeBot (f i) := ⟨fun H i => H.mono (iInf_le _ i), iInf_neBot_of_directed' hd⟩ theorem iInf_neBot_iff_of_directed {f : ι → Filter α} [Nonempty α] (hd : Directed (· ≥ ·) f) : NeBot (iInf f) ↔ ∀ i, NeBot (f i) := ⟨fun H i => H.mono (iInf_le _ i), iInf_neBot_of_directed hd⟩ /-! #### `principal` equations -/ @[simp] theorem inf_principal {s t : Set α} : 𝓟 s ⊓ 𝓟 t = 𝓟 (s ∩ t) := le_antisymm (by simp only [le_principal_iff, mem_inf_iff]; exact ⟨s, Subset.rfl, t, Subset.rfl, rfl⟩) (by simp [le_inf_iff, inter_subset_left, inter_subset_right]) @[simp] theorem sup_principal {s t : Set α} : 𝓟 s ⊔ 𝓟 t = 𝓟 (s ∪ t) := Filter.ext fun u => by simp only [union_subset_iff, mem_sup, mem_principal] @[simp] theorem iSup_principal {ι : Sort w} {s : ι → Set α} : ⨆ x, 𝓟 (s x) = 𝓟 (⋃ i, s i) := Filter.ext fun x => by simp only [mem_iSup, mem_principal, iUnion_subset_iff] @[simp] theorem principal_eq_bot_iff {s : Set α} : 𝓟 s = ⊥ ↔ s = ∅ := empty_mem_iff_bot.symm.trans <\| mem_principal.trans subset_empty_iff @[simp] theorem principal_neBot_iff {s : Set α} : NeBot (𝓟 s) ↔ s.Nonempty := neBot_iff.trans <\| (not_congr principal_eq_bot_iff).trans nonempty_iff_ne_empty.symm alias ⟨_, _root_.Set.Nonempty.principal_neBot⟩ := principal_neBot_iff theorem isCompl_principal (s : Set α) : IsCompl (𝓟 s) (𝓟 sᶜ) := IsCompl.of_eq (by rw [inf_principal, inter_compl_self, principal_empty]) <\| by rw [sup_principal, union_compl_self, principal_univ] theorem mem_inf_principal' {f : Filter α} {s t : Set α} : s ∈ f ⊓ 𝓟 t ↔ tᶜ ∪ s ∈ f := by simp only [← le_principal_iff, (isCompl_principal s).le_left_iff, disjoint_assoc, inf_principal, ← (isCompl_principal (t ∩ sᶜ)).le_right_iff, compl_inter, compl_compl] lemma mem_inf_principal {f : Filter α} {s t : Set α} : s ∈ f ⊓ 𝓟 t ↔ { x \| x ∈ t → x ∈ s } ∈ f := by simp only [mem_inf_principal', imp_iff_not_or, setOf_or, compl_def, setOf_mem_eq] lemma iSup_inf_principal (f : ι → Filter α) (s : Set α) : ⨆ i, f i ⊓ 𝓟 s = (⨆ i, f i) ⊓ 𝓟 s := by ext simp only [mem_iSup, mem_inf_principal] theorem inf_principal_eq_bot {f : Filter α} {s : Set α} : f ⊓ 𝓟 s = ⊥ ↔ sᶜ ∈ f := by rw [← empty_mem_iff_bot, mem_inf_principal] simp only [mem_empty_iff_false, imp_false, compl_def] theorem mem_of_eq_bot {f : Filter α} {s : Set α} (h : f ⊓ 𝓟 sᶜ = ⊥) : s ∈ f := by rwa [inf_principal_eq_bot, compl_compl] at h theorem diff_mem_inf_principal_compl {f : Filter α} {s : Set α} (hs : s ∈ f) (t : Set α) : s \ t ∈ f ⊓ 𝓟 tᶜ := inter_mem_inf hs <\| mem_principal_self tᶜ theorem principal_le_iff {s : Set α} {f : Filter α} : 𝓟 s ≤ f ↔ ∀ V ∈ f, s ⊆ V := by simp_rw [le_def, mem_principal] end Lattice @[mono, gcongr] theorem join_mono {f₁ f₂ : Filter (Filter α)} (h : f₁ ≤ f₂) : join f₁ ≤ join f₂ := fun _ hs => h hs /-! ### Eventually -/ theorem eventually_iff {f : Filter α} {P : α → Prop} : (∀ᶠ x in f, P x) ↔ { x \| P x } ∈ f := Iff.rfl @[simp] theorem eventually_mem_set {s : Set α} {l : Filter α} : (∀ᶠ x in l, x ∈ s) ↔ s ∈ l := Iff.rfl protected theorem ext' {f₁ f₂ : Filter α} (h : ∀ p : α → Prop, (∀ᶠ x in f₁, p x) ↔ ∀ᶠ x in f₂, p x) : f₁ = f₂ := Filter.ext h theorem Eventually.filter_mono {f₁ f₂ : Filter α} (h : f₁ ≤ f₂) {p : α → Prop} (hp : ∀ᶠ x in f₂, p x) : ∀ᶠ x in f₁, p x := h hp theorem eventually_of_mem {f : Filter α} {P : α → Prop} {U : Set α} (hU : U ∈ f) (h : ∀ x ∈ U, P x) : ∀ᶠ x in f, P x := mem_of_superset hU h protected theorem Eventually.and {p q : α → Prop} {f : Filter α} : f.Eventually p → f.Eventually q → ∀ᶠ x in f, p x ∧ q x := inter_mem @[simp] theorem eventually_true (f : Filter α) : ∀ᶠ _ in f, True := univ_mem theorem Eventually.of_forall {p : α → Prop} {f : Filter α} (hp : ∀ x, p x) : ∀ᶠ x in f, p x := univ_mem' hp @[simp] theorem eventually_false_iff_eq_bot {f : Filter α} : (∀ᶠ _ in f, False) ↔ f = ⊥ := empty_mem_iff_bot @[simp] theorem eventually_const {f : Filter α} [t : NeBot f] {p : Prop} : (∀ᶠ _ in f, p) ↔ p := by by_cases h : p <;> simp [h, t.ne] theorem eventually_iff_exists_mem {p : α → Prop} {f : Filter α} : (∀ᶠ x in f, p x) ↔ ∃ v ∈ f, ∀ y ∈ v, p y := exists_mem_subset_iff.symm theorem Eventually.exists_mem {p : α → Prop} {f : Filter α} (hp : ∀ᶠ x in f, p x) : ∃ v ∈ f, ∀ y ∈ v, p y := eventually_iff_exists_mem.1 hp theorem Eventually.mp {p q : α → Prop} {f : Filter α} (hp : ∀ᶠ x in f, p x) (hq : ∀ᶠ x in f, p x → q x) : ∀ᶠ x in f, q x := mp_mem hp hq theorem Eventually.mono {p q : α → Prop} {f : Filter α} (hp : ∀ᶠ x in f, p x) (hq : ∀ x, p x → q x) : ∀ᶠ x in f, q x := hp.mp (Eventually.of_forall hq) theorem forall_eventually_of_eventually_forall {f : Filter α} {p : α → β → Prop} (h : ∀ᶠ x in f, ∀ y, p x y) : ∀ y, ∀ᶠ x in f, p x y := fun y => h.mono fun _ h => h y @[simp] theorem eventually_and {p q : α → Prop} {f : Filter α} : (∀ᶠ x in f, p x ∧ q x) ↔ (∀ᶠ x in f, p x) ∧ ∀ᶠ x in f, q x := inter_mem_iff theorem Eventually.congr {f : Filter α} {p q : α → Prop} (h' : ∀ᶠ x in f, p x) (h : ∀ᶠ x in f, p x ↔ q x) : ∀ᶠ x in f, q x := h'.mp (h.mono fun _ hx => hx.mp) theorem eventually_congr {f : Filter α} {p q : α → Prop} (h : ∀ᶠ x in f, p x ↔ q x) : (∀ᶠ x in f, p x) ↔ ∀ᶠ x in f, q x := ⟨fun hp => hp.congr h, fun hq => hq.congr <\| by simpa only [Iff.comm] using h⟩ @[simp] theorem eventually_or_distrib_left {f : Filter α} {p : Prop} {q : α → Prop} : (∀ᶠ x in f, p ∨ q x) ↔ p ∨ ∀ᶠ x in f, q x := by_cases (fun h : p => by simp [h]) fun h => by simp [h] @[simp] theorem eventually_or_distrib_right {f : Filter α} {p : α → Prop} {q : Prop} : (∀ᶠ x in f, p x ∨ q) ↔ (∀ᶠ x in f, p x) ∨ q := by simp only [@or_comm _ q, eventually_or_distrib_left] theorem eventually_imp_distrib_left {f : Filter α} {p : Prop} {q : α → Prop} : (∀ᶠ x in f, p → q x) ↔ p → ∀ᶠ x in f, q x := by simp only [imp_iff_not_or, eventually_or_distrib_left] @[simp] theorem eventually_bot {p : α → Prop} : ∀ᶠ x in ⊥, p x := ⟨⟩ @[simp] theorem eventually_top {p : α → Prop} : (∀ᶠ x in ⊤, p x) ↔ ∀ x, p x := Iff.rfl @[simp] theorem eventually_sup {p : α → Prop} {f g : Filter α} : (∀ᶠ x in f ⊔ g, p x) ↔ (∀ᶠ x in f, p x) ∧ ∀ᶠ x in g, p x := Iff.rfl @[simp] theorem eventually_sSup {p : α → Prop} {fs : Set (Filter α)} : (∀ᶠ x in sSup fs, p x) ↔ ∀ f ∈ fs, ∀ᶠ x in f, p x := Iff.rfl @[simp] theorem eventually_iSup {p : α → Prop} {fs : ι → Filter α} : (∀ᶠ x in ⨆ b, fs b, p x) ↔ ∀ b, ∀ᶠ x in fs b, p x := mem_iSup @[simp] theorem eventually_principal {a : Set α} {p : α → Prop} : (∀ᶠ x in 𝓟 a, p x) ↔ ∀ x ∈ a, p x := Iff.rfl theorem Eventually.forall_mem {α : Type} {f : Filter α} {s : Set α} {P : α → Prop} (hP : ∀ᶠ x in f, P x) (hf : 𝓟 s ≤ f) : ∀ x ∈ s, P x := Filter.eventually_principal.mp (hP.filter_mono hf) theorem eventually_inf {f g : Filter α} {p : α → Prop} : (∀ᶠ x in f ⊓ g, p x) ↔ ∃ s ∈ f, ∃ t ∈ g, ∀ x ∈ s ∩ t, p x := mem_inf_iff_superset theorem eventually_inf_principal {f : Filter α} {p : α → Prop} {s : Set α} : (∀ᶠ x in f ⊓ 𝓟 s, p x) ↔ ∀ᶠ x in f, x ∈ s → p x := mem_inf_principal theorem eventually_iff_all_subsets {f : Filter α} {p : α → Prop} : (∀ᶠ x in f, p x) ↔ ∀ (s : Set α), ∀ᶠ x in f, x ∈ s → p x where mp h _ := by filter_upwards [h] with _ pa _ using pa mpr h := by filter_upwards [h univ] with _ pa using pa (by simp) /-! ### Frequently -/ theorem Eventually.frequently {f : Filter α} [NeBot f] {p : α → Prop} (h : ∀ᶠ x in f, p x) : ∃ᶠ x in f, p x := compl_not_mem h theorem Frequently.of_forall {f : Filter α} [NeBot f] {p : α → Prop} (h : ∀ x, p x) : ∃ᶠ x in f, p x := Eventually.frequently (Eventually.of_forall h) theorem Frequently.mp {p q : α → Prop} {f : Filter α} (h : ∃ᶠ x in f, p x) (hpq : ∀ᶠ x in f, p x → q x) : ∃ᶠ x in f, q x := mt (fun hq => hq.mp <\| hpq.mono fun _ => mt) h lemma frequently_congr {p q : α → Prop} {f : Filter α} (h : ∀ᶠ x in f, p x ↔ q x) : (∃ᶠ x in f, p x) ↔ ∃ᶠ x in f, q x := ⟨fun h' ↦ h'.mp (h.mono fun _ ↦ Iff.mp), fun h' ↦ h'.mp (h.mono fun _ ↦ Iff.mpr)⟩ theorem Frequently.filter_mono {p : α → Prop} {f g : Filter α} (h : ∃ᶠ x in f, p x) (hle : f ≤ g) : ∃ᶠ x in g, p x := mt (fun h' => h'.filter_mono hle) h theorem Frequently.mono {p q : α → Prop} {f : Filter α} (h : ∃ᶠ x in f, p x) (hpq : ∀ x, p x → q x) : ∃ᶠ x in f, q x := h.mp (Eventually.of_forall hpq) theorem Frequently.and_eventually {p q : α → Prop} {f : Filter α} (hp : ∃ᶠ x in f, p x) (hq : ∀ᶠ x in f, q x) : ∃ᶠ x in f, p x ∧ q x := by refine mt (fun h => hq.mp <\| h.mono ?_) hp exact fun x hpq hq hp => hpq ⟨hp, hq⟩ theorem Eventually.and_frequently {p q : α → Prop} {f : Filter α} (hp : ∀ᶠ x in f, p x) (hq : ∃ᶠ x in f, q x) : ∃ᶠ x in f, p x ∧ q x := by simpa only [and_comm] using hq.and_eventually hp theorem Frequently.exists {p : α → Prop} {f : Filter α} (hp : ∃ᶠ x in f, p x) : ∃ x, p x := by by_contra H replace H : ∀ᶠ x in f, ¬p x := Eventually.of_forall (not_exists.1 H) exact hp H theorem Eventually.exists {p : α → Prop} {f : Filter α} [NeBot f] (hp : ∀ᶠ x in f, p x) : ∃ x, p x := hp.frequently.exists lemma frequently_iff_neBot {l : Filter α} {p : α → Prop} : (∃ᶠ x in l, p x) ↔ NeBot (l ⊓ 𝓟 {x \| p x}) := by rw [neBot_iff, Ne, inf_principal_eq_bot]; rfl lemma frequently_mem_iff_neBot {l : Filter α} {s : Set α} : (∃ᶠ x in l, x ∈ s) ↔ NeBot (l ⊓ 𝓟 s) := frequently_iff_neBot theorem frequently_iff_forall_eventually_exists_and {p : α → Prop} {f : Filter α} : (∃ᶠ x in f, p x) ↔ ∀ {q : α → Prop}, (∀ᶠ x in f, q x) → ∃ x, p x ∧ q x := ⟨fun hp _ hq => (hp.and_eventually hq).exists, fun H hp => by simpa only [and_not_self_iff, exists_false] using H hp⟩ theorem frequently_iff {f : Filter α} {P : α → Prop} : (∃ᶠ x in f, P x) ↔ ∀ {U}, U ∈ f → ∃ x ∈ U, P x := by simp only [frequently_iff_forall_eventually_exists_and, @and_comm (P _)] rfl @[simp] theorem not_eventually {p : α → Prop} {f : Filter α} : (¬∀ᶠ x in f, p x) ↔ ∃ᶠ x in f, ¬p x := by simp [Filter.Frequently] @[simp] theorem not_frequently {p : α → Prop} {f : Filter α} : (¬∃ᶠ x in f, p x) ↔ ∀ᶠ x in f, ¬p x := by simp only [Filter.Frequently, not_not] @[simp] theorem frequently_true_iff_neBot (f : Filter α) : (∃ᶠ _ in f, True) ↔ NeBot f := by simp [frequently_iff_neBot] @[simp] theorem frequently_false (f : Filter α) : ¬∃ᶠ _ in f, False := by simp @[simp] theorem frequently_const {f : Filter α} [NeBot f] {p : Prop} : (∃ᶠ _ in f, p) ↔ p := by by_cases p <;> simp [] @[simp] theorem frequently_or_distrib {f : Filter α} {p q : α → Prop} : (∃ᶠ x in f, p x ∨ q x) ↔ (∃ᶠ x in f, p x) ∨ ∃ᶠ x in f, q x := by simp only [Filter.Frequently, ← not_and_or, not_or, eventually_and] theorem frequently_or_distrib_left {f : Filter α} [NeBot f] {p : Prop} {q : α → Prop} : (∃ᶠ x in f, p ∨ q x) ↔ p ∨ ∃ᶠ x in f, q x := by simp theorem frequently_or_distrib_right {f : Filter α} [NeBot f] {p : α → Prop} {q : Prop} : (∃ᶠ x in f, p x ∨ q) ↔ (∃ᶠ x in f, p x) ∨ q := by simp theorem frequently_imp_distrib {f : Filter α} {p q : α → Prop} : (∃ᶠ x in f, p x → q x) ↔ (∀ᶠ x in f, p x) → ∃ᶠ x in f, q x := by simp [imp_iff_not_or] theorem frequently_imp_distrib_left {f : Filter α} [NeBot f] {p : Prop} {q : α → Prop} : (∃ᶠ x in f, p → q x) ↔ p → ∃ᶠ x in f, q x := by simp [frequently_imp_distrib] theorem frequently_imp_distrib_right {f : Filter α} [NeBot f] {p : α → Prop} {q : Prop} : (∃ᶠ x in f, p x → q) ↔ (∀ᶠ x in f, p x) → q := by simp only [frequently_imp_distrib, frequently_const] theorem eventually_imp_distrib_right {f : Filter α} {p : α → Prop} {q : Prop} : (∀ᶠ x in f, p x → q) ↔ (∃ᶠ x in f, p x) → q := by simp only [imp_iff_not_or, eventually_or_distrib_right, not_frequently] @[simp] theorem frequently_and_distrib_left {f : Filter α} {p : Prop} {q : α → Prop} : (∃ᶠ x in f, p ∧ q x) ↔ p ∧ ∃ᶠ x in f, q x := by simp only [Filter.Frequently, not_and, eventually_imp_distrib_left, Classical.not_imp] @[simp] theorem frequently_and_distrib_right {f : Filter α} {p : α → Prop} {q : Prop} : (∃ᶠ x in f, p x ∧ q) ↔ (∃ᶠ x in f, p x) ∧ q := by simp only [@and_comm _ q, frequently_and_distrib_left] @[simp] theorem frequently_bot {p : α → Prop} : ¬∃ᶠ x in ⊥, p x := by simp @[simp] theorem frequently_top {p : α → Prop} : (∃ᶠ x in ⊤, p x) ↔ ∃ x, p x := by simp [Filter.Frequently] @[simp] theorem frequently_principal {a : Set α} {p : α → Prop} : (∃ᶠ x in 𝓟 a, p x) ↔ ∃ x ∈ a, p x := by simp [Filter.Frequently, not_forall] theorem frequently_inf_principal {f : Filter α} {s : Set α} {p : α → Prop} : (∃ᶠ x in f ⊓ 𝓟 s, p x) ↔ ∃ᶠ x in f, x ∈ s ∧ p x := by simp only [Filter.Frequently, eventually_inf_principal, not_and] alias ⟨Frequently.of_inf_principal, Frequently.inf_principal⟩ := frequently_inf_principal theorem frequently_sup {p : α → Prop} {f g : Filter α} : (∃ᶠ x in f ⊔ g, p x) ↔ (∃ᶠ x in f, p x) ∨ ∃ᶠ x in g, p x := by simp only [Filter.Frequently, eventually_sup, not_and_or] @[simp] theorem frequently_sSup {p : α → Prop} {fs : Set (Filter α)} : (∃ᶠ x in sSup fs, p x) ↔ ∃ f ∈ fs, ∃ᶠ x in f, p x := by simp only [Filter.Frequently, not_forall, eventually_sSup, exists_prop] @[simp] theorem frequently_iSup {p : α → Prop} {fs : β → Filter α} : (∃ᶠ x in ⨆ b, fs b, p x) ↔ ∃ b, ∃ᶠ x in fs b, p x := by simp only [Filter.Frequently, eventually_iSup, not_forall] theorem Eventually.choice {r : α → β → Prop} {l : Filter α} [l.NeBot] (h : ∀ᶠ x in l, ∃ y, r x y) : ∃ f : α → β, ∀ᶠ x in l, r x (f x) := by haveI : Nonempty β := let ⟨_, hx⟩ := h.exists; hx.nonempty choose! f hf using fun x (hx : ∃ y, r x y) => hx exact ⟨f, h.mono hf⟩ lemma skolem {ι : Type} {α : ι → Type} [∀ i, Nonempty (α i)] {P : ∀ i : ι, α i → Prop} {F : Filter ι} : (∀ᶠ i in F, ∃ b, P i b) ↔ ∃ b : (Π i, α i), ∀ᶠ i in F, P i (b i) := by classical refine ⟨fun H ↦ ?_, fun ⟨b, hb⟩ ↦ hb.mp (.of_forall fun x a ↦ ⟨_, a⟩)⟩ refine ⟨fun i ↦ if h : ∃ b, P i b then h.choose else Nonempty.some inferInstance, ?_⟩ filter_upwards [H] with i hi exact dif_pos hi ▸ hi.choose_spec /-! ### Relation “eventually equal” -/ section EventuallyEq variable {l : Filter α} {f g : α → β} theorem EventuallyEq.eventually (h : f =ᶠ[l] g) : ∀ᶠ x in l, f x = g x := h @[simp] lemma eventuallyEq_top : f =ᶠ[⊤] g ↔ f = g := by simp [EventuallyEq, funext_iff] theorem EventuallyEq.rw {l : Filter α} {f g : α → β} (h : f =ᶠ[l] g) (p : α → β → Prop) (hf : ∀ᶠ x in l, p x (f x)) : ∀ᶠ x in l, p x (g x) := hf.congr <\| h.mono fun _ hx => hx ▸ Iff.rfl theorem eventuallyEq_set {s t : Set α} {l : Filter α} : s =ᶠ[l] t ↔ ∀ᶠ x in l, x ∈ s ↔ x ∈ t := eventually_congr <\| Eventually.of_forall fun _ ↦ eq_iff_iff alias ⟨EventuallyEq.mem_iff, Eventually.set_eq⟩ := eventuallyEq_set @[simp] theorem eventuallyEq_univ {s : Set α} {l : Filter α} : s =ᶠ[l] univ ↔ s ∈ l := by simp [eventuallyEq_set] theorem EventuallyEq.exists_mem {l : Filter α} {f g : α → β} (h : f =ᶠ[l] g) : ∃ s ∈ l, EqOn f g s := Eventually.exists_mem h theorem eventuallyEq_of_mem {l : Filter α} {f g : α → β} {s : Set α} (hs : s ∈ l) (h : EqOn f g s) : f =ᶠ[l] g := eventually_of_mem hs h theorem eventuallyEq_iff_exists_mem {l : Filter α} {f g : α → β} : f =ᶠ[l] g ↔ ∃ s ∈ l, EqOn f g s := eventually_iff_exists_mem theorem EventuallyEq.filter_mono {l l' : Filter α} {f g : α → β} (h₁ : f =ᶠ[l] g) (h₂ : l' ≤ l) : f =ᶠ[l'] g := h₂ h₁ @[refl, simp] theorem EventuallyEq.refl (l : Filter α) (f : α → β) : f =ᶠ[l] f := Eventually.of_forall fun _ => rfl protected theorem EventuallyEq.rfl {l : Filter α} {f : α → β} : f =ᶠ[l] f := EventuallyEq.refl l f theorem EventuallyEq.of_eq {l : Filter α} {f g : α → β} (h : f = g) : f =ᶠ[l] g := h ▸ .rfl alias _root_.Eq.eventuallyEq := EventuallyEq.of_eq @[symm] theorem EventuallyEq.symm {f g : α → β} {l : Filter α} (H : f =ᶠ[l] g) : g =ᶠ[l] f := H.mono fun _ => Eq.symm lemma eventuallyEq_comm {f g : α → β} {l : Filter α} : f =ᶠ[l] g ↔ g =ᶠ[l] f := ⟨.symm, .symm⟩ @[trans] theorem EventuallyEq.trans {l : Filter α} {f g h : α → β} (H₁ : f =ᶠ[l] g) (H₂ : g =ᶠ[l] h) : f =ᶠ[l] h := H₂.rw (fun x y => f x = y) H₁ theorem EventuallyEq.congr_left {l : Filter α} {f g h : α → β} (H : f =ᶠ[l] g) : f =ᶠ[l] h ↔ g =ᶠ[l] h := ⟨H.symm.trans, H.trans⟩ theorem EventuallyEq.congr_right {l : Filter α} {f g h : α → β} (H : g =ᶠ[l] h) : f =ᶠ[l] g ↔ f =ᶠ[l] h := ⟨(·.trans H), (·.trans H.symm)⟩ instance {l : Filter α} : Trans ((· =ᶠ[l] ·) : (α → β) → (α → β) → Prop) (· =ᶠ[l] ·) (· =ᶠ[l] ·) where trans := EventuallyEq.trans theorem EventuallyEq.prodMk {l} {f f' : α → β} (hf : f =ᶠ[l] f') {g g' : α → γ} (hg : g =ᶠ[l] g') : (fun x => (f x, g x)) =ᶠ[l] fun x => (f' x, g' x) := hf.mp <\| hg.mono <\| by intros simp only [] @[deprecated (since := "2025-03-10")] alias EventuallyEq.prod_mk := EventuallyEq.prodMk -- See `EventuallyEq.comp_tendsto` further below for a similar statement w.r.t. -- composition on the right. theorem EventuallyEq.fun_comp {f g : α → β} {l : Filter α} (H : f =ᶠ[l] g) (h : β → γ) : h ∘ f =ᶠ[l] h ∘ g := H.mono fun _ hx => congr_arg h hx theorem EventuallyEq.comp₂ {δ} {f f' : α → β} {g g' : α → γ} {l} (Hf : f =ᶠ[l] f') (h : β → γ → δ) (Hg : g =ᶠ[l] g') : (fun x => h (f x) (g x)) =ᶠ[l] fun x => h (f' x) (g' x) := (Hf.prodMk Hg).fun_comp (uncurry h) @[to_additive] theorem EventuallyEq.mul [Mul β] {f f' g g' : α → β} {l : Filter α} (h : f =ᶠ[l] g) (h' : f' =ᶠ[l] g') : (fun x => f x * f' x) =ᶠ[l] fun x => g x * g' x := h.comp₂ (· * ·) h' @[to_additive const_smul] theorem EventuallyEq.pow_const {γ} [Pow β γ] {f g : α → β} {l : Filter α} (h : f =ᶠ[l] g) (c : γ) : (fun x => f x ^ c) =ᶠ[l] fun x => g x ^ c := h.fun_comp (· ^ c) @[to_additive] theorem EventuallyEq.inv [Inv β] {f g : α → β} {l : Filter α} (h : f =ᶠ[l] g) : (fun x => (f x)⁻¹) =ᶠ[l] fun x => (g x)⁻¹ := h.fun_comp Inv.inv @[to_additive] theorem EventuallyEq.div [Div β] {f f' g g' : α → β} {l : Filter α} (h : f =ᶠ[l] g) (h' : f' =ᶠ[l] g') : (fun x => f x / f' x) =ᶠ[l] fun x => g x / g' x := h.comp₂ (· / ·) h' attribute [to_additive] EventuallyEq.const_smul @[to_additive] theorem EventuallyEq.smul {𝕜} [SMul 𝕜 β] {l : Filter α} {f f' : α → 𝕜} {g g' : α → β} (hf : f =ᶠ[l] f') (hg : g =ᶠ[l] g') : (fun x => f x • g x) =ᶠ[l] fun x => f' x • g' x := hf.comp₂ (· • ·) hg theorem EventuallyEq.sup [Max β] {l : Filter α} {f f' g g' : α → β} (hf : f =ᶠ[l] f') (hg : g =ᶠ[l] g') : (fun x => f x ⊔ g x) =ᶠ[l] fun x => f' x ⊔ g' x := hf.comp₂ (· ⊔ ·) hg theorem EventuallyEq.inf [Min β] {l : Filter α} {f f' g g' : α → β} (hf : f =ᶠ[l] f') (hg : g =ᶠ[l] g') : (fun x => f x ⊓ g x) =ᶠ[l] fun x => f' x ⊓ g' x := hf.comp₂ (· ⊓ ·) hg theorem EventuallyEq.preimage {l : Filter α} {f g : α → β} (h : f =ᶠ[l] g) (s : Set β) : f ⁻¹' s =ᶠ[l] g ⁻¹' s := h.fun_comp s theorem EventuallyEq.inter {s t s' t' : Set α} {l : Filter α} (h : s =ᶠ[l] t) (h' : s' =ᶠ[l] t') : (s ∩ s' : Set α) =ᶠ[l] (t ∩ t' : Set α) := h.comp₂ (· ∧ ·) h' theorem EventuallyEq.union {s t s' t' : Set α} {l : Filter α} (h : s =ᶠ[l] t) (h' : s' =ᶠ[l] t') : (s ∪ s' : Set α) =ᶠ[l] (t ∪ t' : Set α) := h.comp₂ (· ∨ ·) h' theorem EventuallyEq.compl {s t : Set α} {l : Filter α} (h : s =ᶠ[l] t) : (sᶜ : Set α) =ᶠ[l] (tᶜ : Set α) := h.fun_comp Not theorem EventuallyEq.diff {s t s' t' : Set α} {l : Filter α} (h : s =ᶠ[l] t) (h' : s' =ᶠ[l] t') : (s \ s' : Set α) =ᶠ[l] (t \ t' : Set α) := h.inter h'.compl protected theorem EventuallyEq.symmDiff {s t s' t' : Set α} {l : Filter α} (h : s =ᶠ[l] t) (h' : s' =ᶠ[l] t') : (s ∆ s' : Set α) =ᶠ[l] (t ∆ t' : Set α) := (h.diff h').union (h'.diff h) theorem eventuallyEq_empty {s : Set α} {l : Filter α} : s =ᶠ[l] (∅ : Set α) ↔ ∀ᶠ x in l, x ∉ s := eventuallyEq_set.trans <\| by simp theorem inter_eventuallyEq_left {s t : Set α} {l : Filter α} : (s ∩ t : Set α) =ᶠ[l] s ↔ ∀ᶠ x in l, x ∈ s → x ∈ t := by simp only [eventuallyEq_set, mem_inter_iff, and_iff_left_iff_imp] theorem inter_eventuallyEq_right {s t : Set α} {l : Filter α} : (s ∩ t : Set α) =ᶠ[l] t ↔ ∀ᶠ x in l, x ∈ t → x ∈ s := by rw [inter_comm, inter_eventuallyEq_left] @[simp] theorem eventuallyEq_principal {s : Set α} {f g : α → β} : f =ᶠ[𝓟 s] g ↔ EqOn f g s := Iff.rfl theorem eventuallyEq_inf_principal_iff {F : Filter α} {s : Set α} {f g : α → β} : f =ᶠ[F ⊓ 𝓟 s] g ↔ ∀ᶠ x in F, x ∈ s → f x = g x := eventually_inf_principal theorem EventuallyEq.sub_eq [AddGroup β] {f g : α → β} {l : Filter α} (h : f =ᶠ[l] g) : f - g =ᶠ[l] 0 := by simpa using ((EventuallyEq.refl l f).sub h).symm theorem eventuallyEq_iff_sub [AddGroup β] {f g : α → β} {l : Filter α} : f =ᶠ[l] g ↔ f - g =ᶠ[l] 0 := ⟨fun h => h.sub_eq, fun h => by simpa using h.add (EventuallyEq.refl l g)⟩ theorem eventuallyEq_iff_all_subsets {f g : α → β} {l : Filter α} : f =ᶠ[l] g ↔ ∀ s : Set α, ∀ᶠ x in l, x ∈ s → f x = g x := eventually_iff_all_subsets section LE variable [LE β] {l : Filter α} theorem EventuallyLE.congr {f f' g g' : α → β} (H : f ≤ᶠ[l] g) (hf : f =ᶠ[l] f') (hg : g =ᶠ[l] g') : f' ≤ᶠ[l] g' := H.mp <\| hg.mp <\| hf.mono fun x hf hg H => by rwa [hf, hg] at H theorem eventuallyLE_congr {f f' g g' : α → β} (hf : f =ᶠ[l] f') (hg : g =ᶠ[l] g') : f ≤ᶠ[l] g ↔ f' ≤ᶠ[l] g' := ⟨fun H => H.congr hf hg, fun H => H.congr hf.symm hg.symm⟩ theorem eventuallyLE_iff_all_subsets {f g : α → β} {l : Filter α} : f ≤ᶠ[l] g ↔ ∀ s : Set α, ∀ᶠ x in l, x ∈ s → f x ≤ g x := eventually_iff_all_subsets end LE section Preorder variable [Preorder β] {l : Filter α} {f g h : α → β} theorem EventuallyEq.le (h : f =ᶠ[l] g) : f ≤ᶠ[l] g := h.mono fun _ => le_of_eq @[refl] theorem EventuallyLE.refl (l : Filter α) (f : α → β) : f ≤ᶠ[l] f := EventuallyEq.rfl.le theorem EventuallyLE.rfl : f ≤ᶠ[l] f := EventuallyLE.refl l f @[trans] theorem EventuallyLE.trans (H₁ : f ≤ᶠ[l] g) (H₂ : g ≤ᶠ[l] h) : f ≤ᶠ[l] h := H₂.mp <\| H₁.mono fun _ => le_trans instance : Trans ((· ≤ᶠ[l] ·) : (α → β) → (α → β) → Prop) (· ≤ᶠ[l] ·) (· ≤ᶠ[l] ·) where trans := EventuallyLE.trans @[trans] theorem EventuallyEq.trans_le (H₁ : f =ᶠ[l] g) (H₂ : g ≤ᶠ[l] h) : f ≤ᶠ[l] h := H₁.le.trans H₂ instance : Trans ((· =ᶠ[l] ·) : (α → β) → (α → β) → Prop) (· ≤ᶠ[l] ·) (· ≤ᶠ[l] ·) where trans := EventuallyEq.trans_le @[trans] theorem EventuallyLE.trans_eq (H₁ : f ≤ᶠ[l] g) (H₂ : g =ᶠ[l] h) : f ≤ᶠ[l] h := H₁.trans H₂.le instance : Trans ((· ≤ᶠ[l] ·) : (α → β) → (α → β) → Prop) (· =ᶠ[l] ·) (· ≤ᶠ[l] ·) where trans := EventuallyLE.trans_eq end Preorder variable {l : Filter α} theorem EventuallyLE.antisymm [PartialOrder β] {l : Filter α} {f g : α → β} (h₁ : f ≤ᶠ[l] g) (h₂ : g ≤ᶠ[l] f) : f =ᶠ[l] g := h₂.mp <\| h₁.mono fun _ => le_antisymm theorem eventuallyLE_antisymm_iff [PartialOrder β] {l : Filter α} {f g : α → β} : f =ᶠ[l] g ↔ f ≤ᶠ[l] g ∧ g ≤ᶠ[l] f := by simp only [EventuallyEq, EventuallyLE, le_antisymm_iff, eventually_and] theorem EventuallyLE.le_iff_eq [PartialOrder β] {l : Filter α} {f g : α → β} (h : f ≤ᶠ[l] g) : g ≤ᶠ[l] f ↔ g =ᶠ[l] f := ⟨fun h' => h'.antisymm h, EventuallyEq.le⟩ theorem Eventually.ne_of_lt [Preorder β] {l : Filter α} {f g : α → β} (h : ∀ᶠ x in l, f x < g x) : ∀ᶠ x in l, f x ≠ g x := h.mono fun _ hx => hx.ne theorem Eventually.ne_top_of_lt [Preorder β] [OrderTop β] {l : Filter α} {f g : α → β} (h : ∀ᶠ x in l, f x < g x) : ∀ᶠ x in l, f x ≠ ⊤ := h.mono fun _ hx => hx.ne_top theorem Eventually.lt_top_of_ne [PartialOrder β] [OrderTop β] {l : Filter α} {f : α → β} (h : ∀ᶠ x in l, f x ≠ ⊤) : ∀ᶠ x in l, f x < ⊤ := h.mono fun _ hx => hx.lt_top theorem Eventually.lt_top_iff_ne_top [PartialOrder β] [OrderTop β] {l : Filter α} {f : α → β} : (∀ᶠ x in l, f x < ⊤) ↔ ∀ᶠ x in l, f x ≠ ⊤ := ⟨Eventually.ne_of_lt, Eventually.lt_top_of_ne⟩ @[mono] theorem EventuallyLE.inter {s t s' t' : Set α} {l : Filter α} (h : s ≤ᶠ[l] t) (h' : s' ≤ᶠ[l] t') : (s ∩ s' : Set α) ≤ᶠ[l] (t ∩ t' : Set α) := h'.mp <\| h.mono fun _ => And.imp @[mono] theorem EventuallyLE.union {s t s' t' : Set α} {l : Filter α} (h : s ≤ᶠ[l] t) (h' : s' ≤ᶠ[l] t') : (s ∪ s' : Set α) ≤ᶠ[l] (t ∪ t' : Set α) := h'.mp <\| h.mono fun _ => Or.imp @[mono] theorem EventuallyLE.compl {s t : Set α} {l : Filter α} (h : s ≤ᶠ[l] t) : (tᶜ : Set α) ≤ᶠ[l] (sᶜ : Set α) := h.mono fun _ => mt @[mono] theorem EventuallyLE.diff {s t s' t' : Set α} {l : Filter α} (h : s ≤ᶠ[l] t) (h' : t' ≤ᶠ[l] s') : (s \ s' : Set α) ≤ᶠ[l] (t \ t' : Set α) := h.inter h'.compl theorem set_eventuallyLE_iff_mem_inf_principal {s t : Set α} {l : Filter α} : s ≤ᶠ[l] t ↔ t ∈ l ⊓ 𝓟 s := eventually_inf_principal.symm theorem set_eventuallyLE_iff_inf_principal_le {s t : Set α} {l : Filter α} : s ≤ᶠ[l] t ↔ l ⊓ 𝓟 s ≤ l ⊓ 𝓟 t := set_eventuallyLE_iff_mem_inf_principal.trans <\| by simp only [le_inf_iff, inf_le_left, true_and, le_principal_iff] theorem set_eventuallyEq_iff_inf_principal {s t : Set α} {l : Filter α} : s =ᶠ[l] t ↔ l ⊓ 𝓟 s = l ⊓ 𝓟 t := by simp only [eventuallyLE_antisymm_iff, le_antisymm_iff, set_eventuallyLE_iff_inf_principal_le] theorem EventuallyLE.sup [SemilatticeSup β] {l : Filter α} {f₁ f₂ g₁ g₂ : α → β} (hf : f₁ ≤ᶠ[l] f₂) (hg : g₁ ≤ᶠ[l] g₂) : f₁ ⊔ g₁ ≤ᶠ[l] f₂ ⊔ g₂ := by filter_upwards [hf, hg] with x hfx hgx using sup_le_sup hfx hgx theorem EventuallyLE.sup_le [SemilatticeSup β] {l : Filter α} {f g h : α → β} (hf : f ≤ᶠ[l] h) (hg : g ≤ᶠ[l] h) : f ⊔ g ≤ᶠ[l] h := by filter_upwards [hf, hg] with x hfx hgx using _root_.sup_le hfx hgx theorem EventuallyLE.le_sup_of_le_left [SemilatticeSup β] {l : Filter α} {f g h : α → β} (hf : h ≤ᶠ[l] f) : h ≤ᶠ[l] f ⊔ g := hf.mono fun _ => _root_.le_sup_of_le_left theorem EventuallyLE.le_sup_of_le_right [SemilatticeSup β] {l : Filter α} {f g h : α → β} (hg : h ≤ᶠ[l] g) : h ≤ᶠ[l] f ⊔ g := hg.mono fun _ => _root_.le_sup_of_le_right theorem join_le {f : Filter (Filter α)} {l : Filter α} (h : ∀ᶠ m in f, m ≤ l) : join f ≤ l := fun _ hs => h.mono fun _ hm => hm hs end EventuallyEq end Filter open Filter theorem Set.EqOn.eventuallyEq {α β} {s : Set α} {f g : α → β} (h : EqOn f g s) : f =ᶠ[𝓟 s] g := h theorem Set.EqOn.eventuallyEq_of_mem {α β} {s : Set α} {l : Filter α} {f g : α → β} (h : EqOn f g s) (hl : s ∈ l) : f =ᶠ[l] g := h.eventuallyEq.filter_mono <\| Filter.le_principal_iff.2 hl theorem HasSubset.Subset.eventuallyLE {α} {l : Filter α} {s t : Set α} (h : s ⊆ t) : s ≤ᶠ[l] t := Filter.Eventually.of_forall h variable {α β : Type*} {F : Filter α} {G : Filter β} namespace Filter lemma compl_mem_comk {p : Set α → Prop} {he hmono hunion s} : sᶜ ∈ comk p he hmono hunion ↔ p s := by simp end Filter		Mathlib/Order/Filter/Basic.lean	1,386	1,387
/- 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.Data.Complex.ExponentialBounds import Mathlib.NumberTheory.Harmonic.Defs import Mathlib.Analysis.Normed.Order.Lattice import Mathlib.Analysis.SpecialFunctions.Pow.Real /-! # The Euler-Mascheroni constant `γ` We define the constant `γ`, and give upper and lower bounds for it. ## Main definitions and results * `Real.eulerMascheroniConstant`: the constant `γ` * `Real.tendsto_harmonic_sub_log`: the sequence `n ↦ harmonic n - log n` tends to `γ` as `n → ∞` * `one_half_lt_eulerMascheroniConstant` and `eulerMascheroniConstant_lt_two_thirds`: upper and lower bounds. ## Outline of proofs We show that * the sequence `eulerMascheroniSeq` given by `n ↦ harmonic n - log (n + 1)` is strictly increasing; * the sequence `eulerMascheroniSeq'` given by `n ↦ harmonic n - log n`, modified with a junk value for `n = 0`, is strictly decreasing; * the difference `eulerMascheroniSeq' n - eulerMascheroniSeq n` is non-negative and tends to 0. It follows that both sequences tend to a common limit `γ`, and we have the inequality `eulerMascheroniSeq n < γ < eulerMascheroniSeq' n` for all `n`. Taking `n = 6` gives the bounds `1 / 2 < γ < 2 / 3`. -/ open Filter Topology namespace Real section LowerSequence /-- The sequence with `n`-th term `harmonic n - log (n + 1)`. -/ noncomputable def eulerMascheroniSeq (n : ℕ) : ℝ := harmonic n - log (n + 1) lemma eulerMascheroniSeq_zero : eulerMascheroniSeq 0 = 0 := by simp [eulerMascheroniSeq, harmonic_zero] lemma strictMono_eulerMascheroniSeq : StrictMono eulerMascheroniSeq := by refine strictMono_nat_of_lt_succ (fun n ↦ ?_) rw [eulerMascheroniSeq, eulerMascheroniSeq, ← sub_pos, sub_sub_sub_comm, harmonic_succ, add_comm, Rat.cast_add, add_sub_cancel_right, ← log_div (by positivity) (by positivity), add_div, Nat.cast_add_one, Nat.cast_add_one, div_self (by positivity), sub_pos, one_div, Rat.cast_inv, Rat.cast_add, Rat.cast_one, Rat.cast_natCast] refine (log_lt_sub_one_of_pos ?_ (ne_of_gt <\| lt_add_of_pos_right _ ?_)).trans_le (le_of_eq ?_) · positivity · positivity · simp only [add_sub_cancel_left] lemma one_half_lt_eulerMascheroniSeq_six : 1 / 2 < eulerMascheroniSeq 6 := by have : eulerMascheroniSeq 6 = 49 / 20 - log 7 := by rw [eulerMascheroniSeq] norm_num rw [this, lt_sub_iff_add_lt, ← lt_sub_iff_add_lt', log_lt_iff_lt_exp (by positivity)] refine lt_of_lt_of_le ?_ (Real.sum_le_exp_of_nonneg (by norm_num) 7) simp_rw [Finset.sum_range_succ, Nat.factorial_succ] norm_num end LowerSequence section UpperSequence /-- The sequence with `n`-th term `harmonic n - log n`. We use a junk value for `n = 0`, in order to have the sequence be strictly decreasing. -/ noncomputable def eulerMascheroniSeq' (n : ℕ) : ℝ := if n = 0 then 2 else ↑(harmonic n) - log n lemma eulerMascheroniSeq'_one : eulerMascheroniSeq' 1 = 1 := by simp [eulerMascheroniSeq'] lemma strictAnti_eulerMascheroniSeq' : StrictAnti eulerMascheroniSeq' := by refine strictAnti_nat_of_succ_lt (fun n ↦ ?_) rcases Nat.eq_zero_or_pos n with rfl \| hn · simp [eulerMascheroniSeq'] simp_rw [eulerMascheroniSeq', eq_false_intro hn.ne', reduceCtorEq, if_false] rw [← sub_pos, sub_sub_sub_comm, harmonic_succ, Rat.cast_add, ← sub_sub, sub_self, zero_sub, sub_eq_add_neg, neg_sub, ← sub_eq_neg_add, sub_pos, ← log_div (by positivity) (by positivity), ← neg_lt_neg_iff, ← log_inv] refine (log_lt_sub_one_of_pos ?_ ?_).trans_le (le_of_eq ?_) · positivity · field_simp · field_simp lemma eulerMascheroniSeq'_six_lt_two_thirds : eulerMascheroniSeq' 6 < 2 / 3 := by have h1 : eulerMascheroniSeq' 6 = 49 / 20 - log 6 := by rw [eulerMascheroniSeq'] norm_num rw [h1, sub_lt_iff_lt_add, ← sub_lt_iff_lt_add', lt_log_iff_exp_lt (by positivity)] norm_num have := rpow_lt_rpow (exp_pos _).le exp_one_lt_d9 (by norm_num : (0 : ℝ) < 107 / 60) rw [exp_one_rpow] at this refine lt_trans this ?_ rw [← rpow_lt_rpow_iff (z := 60), ← rpow_mul, div_mul_cancel₀, ← Nat.cast_ofNat, ← Nat.cast_ofNat, rpow_natCast, Nat.cast_ofNat, ← Nat.cast_ofNat (n := 60), rpow_natCast] · norm_num all_goals positivity lemma eulerMascheroniSeq_lt_eulerMascheroniSeq' (m n : ℕ) : eulerMascheroniSeq m < eulerMascheroniSeq' n := by have (r : ℕ) : eulerMascheroniSeq r < eulerMascheroniSeq' r := by rcases eq_zero_or_pos r with rfl \| hr · simp [eulerMascheroniSeq, eulerMascheroniSeq'] simp only [eulerMascheroniSeq, eulerMascheroniSeq', hr.ne', if_false] gcongr linarith apply (strictMono_eulerMascheroniSeq.monotone (le_max_left m n)).trans_lt exact (this _).trans_le (strictAnti_eulerMascheroniSeq'.antitone (le_max_right m n)) end UpperSequence /-- The Euler-Mascheroni constant `γ`. -/ noncomputable def eulerMascheroniConstant : ℝ := limUnder atTop eulerMascheroniSeq lemma tendsto_eulerMascheroniSeq : Tendsto eulerMascheroniSeq atTop (𝓝 eulerMascheroniConstant) := by have := tendsto_atTop_ciSup strictMono_eulerMascheroniSeq.monotone ?_ · rwa [eulerMascheroniConstant, this.limUnder_eq] · exact ⟨_, fun _ ⟨_, hn⟩ ↦ hn ▸ (eulerMascheroniSeq_lt_eulerMascheroniSeq' _ 1).le⟩ lemma tendsto_harmonic_sub_log_add_one : Tendsto (fun n : ℕ ↦ harmonic n - log (n + 1)) atTop (𝓝 eulerMascheroniConstant) := tendsto_eulerMascheroniSeq lemma tendsto_eulerMascheroniSeq' : Tendsto eulerMascheroniSeq' atTop (𝓝 eulerMascheroniConstant) := by suffices Tendsto (fun n ↦ eulerMascheroniSeq' n - eulerMascheroniSeq n) atTop (𝓝 0) by simpa using this.add tendsto_eulerMascheroniSeq suffices Tendsto (fun x : ℝ ↦ log (x + 1) - log x) atTop (𝓝 0) by apply (this.comp tendsto_natCast_atTop_atTop).congr' filter_upwards [eventually_ne_atTop 0] with n hn simp [eulerMascheroniSeq, eulerMascheroniSeq', eq_false_intro hn] exact tendsto_log_comp_add_sub_log 1 lemma tendsto_harmonic_sub_log : Tendsto (fun n : ℕ ↦ harmonic n - log n) atTop (𝓝 eulerMascheroniConstant) := by apply tendsto_eulerMascheroniSeq'.congr' filter_upwards [eventually_ne_atTop 0] with n hn simp_rw [eulerMascheroniSeq', hn, if_false] lemma eulerMascheroniSeq_lt_eulerMascheroniConstant (n : ℕ) : eulerMascheroniSeq n < eulerMascheroniConstant := by refine (strictMono_eulerMascheroniSeq (Nat.lt_succ_self n)).trans_le ?_ apply strictMono_eulerMascheroniSeq.monotone.ge_of_tendsto tendsto_eulerMascheroniSeq lemma eulerMascheroniConstant_lt_eulerMascheroniSeq' (n : ℕ) : eulerMascheroniConstant < eulerMascheroniSeq' n := by refine lt_of_le_of_lt ?_ (strictAnti_eulerMascheroniSeq' (Nat.lt_succ_self n)) apply strictAnti_eulerMascheroniSeq'.antitone.le_of_tendsto tendsto_eulerMascheroniSeq'	/-- Lower bound for `γ`. (The true value is about 0.57.) -/ lemma one_half_lt_eulerMascheroniConstant : 1 / 2 < eulerMascheroniConstant := one_half_lt_eulerMascheroniSeq_six.trans (eulerMascheroniSeq_lt_eulerMascheroniConstant _)	Mathlib/NumberTheory/Harmonic/EulerMascheroni.lean	163	166
/- Copyright (c) 2020 Johan Commelin. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johan Commelin, Robert Y. Lewis -/ import Mathlib.FieldTheory.Finite.Polynomial import Mathlib.NumberTheory.Basic import Mathlib.RingTheory.WittVector.WittPolynomial /-! # Witt structure polynomials In this file we prove the main theorem that makes the whole theory of Witt vectors work. Briefly, consider a polynomial `Φ : MvPolynomial idx ℤ` over the integers, with polynomials variables indexed by an arbitrary type `idx`. Then there exists a unique family of polynomials `φ : ℕ → MvPolynomial (idx × ℕ) Φ` such that for all `n : ℕ` we have (`wittStructureInt_existsUnique`) ``` bind₁ φ (wittPolynomial p ℤ n) = bind₁ (fun i ↦ (rename (prod.mk i) (wittPolynomial p ℤ n))) Φ ``` In other words: evaluating the `n`-th Witt polynomial on the family `φ` is the same as evaluating `Φ` on the (appropriately renamed) `n`-th Witt polynomials. N.b.: As far as we know, these polynomials do not have a name in the literature, so we have decided to call them the “Witt structure polynomials”. See `wittStructureInt`. ## Special cases With the main result of this file in place, we apply it to certain special polynomials. For example, by taking `Φ = X tt + X ff` resp. `Φ = X tt * X ff` we obtain families of polynomials `witt_add` resp. `witt_mul` (with type `ℕ → MvPolynomial (Bool × ℕ) ℤ`) that will be used in later files to define the addition and multiplication on the ring of Witt vectors. ## Outline of the proof The proof of `wittStructureInt_existsUnique` is rather technical, and takes up most of this file. We start by proving the analogous version for polynomials with rational coefficients, instead of integer coefficients. In this case, the solution is rather easy, since the Witt polynomials form a faithful change of coordinates in the polynomial ring `MvPolynomial ℕ ℚ`. We therefore obtain a family of polynomials `wittStructureRat Φ` for every `Φ : MvPolynomial idx ℚ`. If `Φ` has integer coefficients, then the polynomials `wittStructureRat Φ n` do so as well. Proving this claim is the essential core of this file, and culminates in `map_wittStructureInt`, which proves that upon mapping the coefficients of `wittStructureInt Φ n` from the integers to the rationals, one obtains `wittStructureRat Φ n`. Ultimately, the proof of `map_wittStructureInt` relies on ``` dvd_sub_pow_of_dvd_sub {R : Type} [CommRing R] {p : ℕ} {a b : R} : (p : R) ∣ a - b → ∀ (k : ℕ), (p : R) ^ (k + 1) ∣ a ^ p ^ k - b ^ p ^ k ``` ## Main results `wittStructureRat Φ`: the family of polynomials `ℕ → MvPolynomial (idx × ℕ) ℚ` associated with `Φ : MvPolynomial idx ℚ` and satisfying the property explained above. * `wittStructureRat_prop`: the proof that `wittStructureRat` indeed satisfies the property. * `wittStructureInt Φ`: the family of polynomials `ℕ → MvPolynomial (idx × ℕ) ℤ` associated with `Φ : MvPolynomial idx ℤ` and satisfying the property explained above. * `map_wittStructureInt`: the proof that the integral polynomials `with_structure_int Φ` are equal to `wittStructureRat Φ` when mapped to polynomials with rational coefficients. * `wittStructureInt_prop`: the proof that `wittStructureInt` indeed satisfies the property. * Five families of polynomials that will be used to define the ring structure on the ring of Witt vectors: - `WittVector.wittZero` - `WittVector.wittOne` - `WittVector.wittAdd` - `WittVector.wittMul` - `WittVector.wittNeg` (We also define `WittVector.wittSub`, and later we will prove that it describes subtraction, which is defined as `fun a b ↦ a + -b`. See `WittVector.sub_coeff` for this proof.) ## References * [Hazewinkel, Witt Vectors][Haze09] * [Commelin and Lewis, Formalizing the Ring of Witt Vectors][CL21] -/ open MvPolynomial Set open Finset (range) open Finsupp (single) -- This lemma reduces a bundled morphism to a "mere" function, -- and consequently the simplifier cannot use a lot of powerful simp-lemmas. -- We disable this locally, and probably it should be disabled globally in mathlib. attribute [-simp] coe_eval₂Hom variable {p : ℕ} {R : Type} {idx : Type} [CommRing R] open scoped Witt section PPrime variable (p) variable [hp : Fact p.Prime] -- Notation with ring of coefficients explicit set_option quotPrecheck false in @[inherit_doc] scoped[Witt] notation "W_" => wittPolynomial p -- Notation with ring of coefficients implicit set_option quotPrecheck false in @[inherit_doc] scoped[Witt] notation "W" => wittPolynomial p _ /-- `wittStructureRat Φ` is a family of polynomials `ℕ → MvPolynomial (idx × ℕ) ℚ` that are uniquely characterised by the property that ``` bind₁ (wittStructureRat p Φ) (wittPolynomial p ℚ n) = bind₁ (fun i ↦ (rename (prod.mk i) (wittPolynomial p ℚ n))) Φ ``` In other words: evaluating the `n`-th Witt polynomial on the family `wittStructureRat Φ` is the same as evaluating `Φ` on the (appropriately renamed) `n`-th Witt polynomials. See `wittStructureRat_prop` for this property, and `wittStructureRat_existsUnique` for the fact that `wittStructureRat` gives the unique family of polynomials with this property. These polynomials turn out to have integral coefficients, but it requires some effort to show this. See `wittStructureInt` for the version with integral coefficients, and `map_wittStructureInt` for the fact that it is equal to `wittStructureRat` when mapped to polynomials over the rationals. -/ noncomputable def wittStructureRat (Φ : MvPolynomial idx ℚ) (n : ℕ) : MvPolynomial (idx × ℕ) ℚ := bind₁ (fun k => bind₁ (fun i => rename (Prod.mk i) (W_ ℚ k)) Φ) (xInTermsOfW p ℚ n) theorem wittStructureRat_prop (Φ : MvPolynomial idx ℚ) (n : ℕ) : bind₁ (wittStructureRat p Φ) (W_ ℚ n) = bind₁ (fun i => rename (Prod.mk i) (W_ ℚ n)) Φ := calc bind₁ (wittStructureRat p Φ) (W_ ℚ n) = bind₁ (fun k => bind₁ (fun i => (rename (Prod.mk i)) (W_ ℚ k)) Φ) (bind₁ (xInTermsOfW p ℚ) (W_ ℚ n)) := by rw [bind₁_bind₁]; exact eval₂Hom_congr (RingHom.ext_rat _ _) rfl rfl _ = bind₁ (fun i => rename (Prod.mk i) (W_ ℚ n)) Φ := by rw [bind₁_xInTermsOfW_wittPolynomial p _ n, bind₁_X_right] theorem wittStructureRat_existsUnique (Φ : MvPolynomial idx ℚ) : ∃! φ : ℕ → MvPolynomial (idx × ℕ) ℚ, ∀ n : ℕ, bind₁ φ (W_ ℚ n) = bind₁ (fun i => rename (Prod.mk i) (W_ ℚ n)) Φ := by refine ⟨wittStructureRat p Φ, ?_, ?_⟩ · intro n; apply wittStructureRat_prop · intro φ H funext n rw [show φ n = bind₁ φ (bind₁ (W_ ℚ) (xInTermsOfW p ℚ n)) by rw [bind₁_wittPolynomial_xInTermsOfW p, bind₁_X_right]] rw [bind₁_bind₁] exact eval₂Hom_congr (RingHom.ext_rat _ _) (funext H) rfl theorem wittStructureRat_rec_aux (Φ : MvPolynomial idx ℚ) (n : ℕ) : wittStructureRat p Φ n * C ((p : ℚ) ^ n) = bind₁ (fun b => rename (fun i => (b, i)) (W_ ℚ n)) Φ - ∑ i ∈ range n, C ((p : ℚ) ^ i) * wittStructureRat p Φ i ^ p ^ (n - i) := by have := xInTermsOfW_aux p ℚ n replace := congr_arg (bind₁ fun k : ℕ => bind₁ (fun i => rename (Prod.mk i) (W_ ℚ k)) Φ) this rw [map_mul, bind₁_C_right] at this rw [wittStructureRat, this]; clear this conv_lhs => simp only [map_sub, bind₁_X_right] rw [sub_right_inj] simp only [map_sum, map_mul, bind₁_C_right, map_pow] rfl /-- Write `wittStructureRat p φ n` in terms of `wittStructureRat p φ i` for `i < n`. -/ theorem wittStructureRat_rec (Φ : MvPolynomial idx ℚ) (n : ℕ) : wittStructureRat p Φ n = C (1 / (p : ℚ) ^ n) * (bind₁ (fun b => rename (fun i => (b, i)) (W_ ℚ n)) Φ - ∑ i ∈ range n, C ((p : ℚ) ^ i) * wittStructureRat p Φ i ^ p ^ (n - i)) := by calc wittStructureRat p Φ n = C (1 / (p : ℚ) ^ n) * (wittStructureRat p Φ n * C ((p : ℚ) ^ n)) := ?_ _ = _ := by rw [wittStructureRat_rec_aux] rw [mul_left_comm, ← C_mul, div_mul_cancel₀, C_1, mul_one] exact pow_ne_zero _ (Nat.cast_ne_zero.2 hp.1.ne_zero) /-- `wittStructureInt Φ` is a family of polynomials `ℕ → MvPolynomial (idx × ℕ) ℤ` that are uniquely characterised by the property that ``` bind₁ (wittStructureInt p Φ) (wittPolynomial p ℤ n) = bind₁ (fun i ↦ (rename (prod.mk i) (wittPolynomial p ℤ n))) Φ ``` In other words: evaluating the `n`-th Witt polynomial on the family `wittStructureInt Φ` is the same as evaluating `Φ` on the (appropriately renamed) `n`-th Witt polynomials. See `wittStructureInt_prop` for this property, and `wittStructureInt_existsUnique` for the fact that `wittStructureInt` gives the unique family of polynomials with this property. -/ noncomputable def wittStructureInt (Φ : MvPolynomial idx ℤ) (n : ℕ) : MvPolynomial (idx × ℕ) ℤ := Finsupp.mapRange Rat.num (Rat.num_intCast 0) (wittStructureRat p (map (Int.castRingHom ℚ) Φ) n) variable {p} theorem bind₁_rename_expand_wittPolynomial (Φ : MvPolynomial idx ℤ) (n : ℕ) (IH : ∀ m : ℕ, m < n + 1 → map (Int.castRingHom ℚ) (wittStructureInt p Φ m) = wittStructureRat p (map (Int.castRingHom ℚ) Φ) m) : bind₁ (fun b => rename (fun i => (b, i)) (expand p (W_ ℤ n))) Φ = bind₁ (fun i => expand p (wittStructureInt p Φ i)) (W_ ℤ n) := by apply MvPolynomial.map_injective (Int.castRingHom ℚ) Int.cast_injective simp only [map_bind₁, map_rename, map_expand, rename_expand, map_wittPolynomial] have key := (wittStructureRat_prop p (map (Int.castRingHom ℚ) Φ) n).symm apply_fun expand p at key simp only [expand_bind₁] at key rw [key]; clear key apply eval₂Hom_congr' rfl _ rfl rintro i hi - rw [wittPolynomial_vars, Finset.mem_range] at hi simp only [IH i hi] theorem C_p_pow_dvd_bind₁_rename_wittPolynomial_sub_sum (Φ : MvPolynomial idx ℤ) (n : ℕ) (IH : ∀ m : ℕ, m < n → map (Int.castRingHom ℚ) (wittStructureInt p Φ m) = wittStructureRat p (map (Int.castRingHom ℚ) Φ) m) : (C ((p ^ n :) : ℤ) : MvPolynomial (idx × ℕ) ℤ) ∣ bind₁ (fun b : idx => rename (fun i => (b, i)) (wittPolynomial p ℤ n)) Φ - ∑ i ∈ range n, C ((p : ℤ) ^ i) * wittStructureInt p Φ i ^ p ^ (n - i) := by rcases n with - \| n · simp only [isUnit_one, Int.ofNat_zero, Int.natCast_succ, zero_add, pow_zero, C_1, IsUnit.dvd, Nat.cast_one] -- prepare a useful equation for rewriting have key := bind₁_rename_expand_wittPolynomial Φ n IH apply_fun map (Int.castRingHom (ZMod (p ^ (n + 1)))) at key conv_lhs at key => simp only [map_bind₁, map_rename, map_expand, map_wittPolynomial] -- clean up and massage rw [C_dvd_iff_zmod, RingHom.map_sub, sub_eq_zero, map_bind₁] simp only [map_rename, map_wittPolynomial, wittPolynomial_zmod_self] rw [key]; clear key IH rw [bind₁, aeval_wittPolynomial, map_sum, map_sum, Finset.sum_congr rfl] intro k hk rw [Finset.mem_range, Nat.lt_succ_iff] at hk -- Porting note (https://github.com/leanprover-community/mathlib4/issues/11083): was much slower -- simp only [← sub_eq_zero, ← RingHom.map_sub, ← C_dvd_iff_zmod, C_eq_coe_nat, ← mul_sub, ← -- Nat.cast_pow] rw [← sub_eq_zero, ← RingHom.map_sub, ← C_dvd_iff_zmod, C_eq_coe_nat, ← Nat.cast_pow, ← Nat.cast_pow, C_eq_coe_nat, ← mul_sub] have : p ^ (n + 1) = p ^ k * p ^ (n - k + 1) := by rw [← pow_add, ← add_assoc]; congr 2; rw [add_comm, ← tsub_eq_iff_eq_add_of_le hk] rw [this] rw [Nat.cast_mul, Nat.cast_pow, Nat.cast_pow] apply mul_dvd_mul_left ((p : MvPolynomial (idx × ℕ) ℤ) ^ k) rw [show p ^ (n + 1 - k) = p * p ^ (n - k) by rw [← pow_succ', ← tsub_add_eq_add_tsub hk]] rw [pow_mul] -- the machine! apply dvd_sub_pow_of_dvd_sub rw [← C_eq_coe_nat, C_dvd_iff_zmod, RingHom.map_sub, sub_eq_zero, map_expand, RingHom.map_pow, MvPolynomial.expand_zmod] variable (p) @[simp] theorem map_wittStructureInt (Φ : MvPolynomial idx ℤ) (n : ℕ) : map (Int.castRingHom ℚ) (wittStructureInt p Φ n) = wittStructureRat p (map (Int.castRingHom ℚ) Φ) n := by induction n using Nat.strong_induction_on with \| h n IH => ?_ rw [wittStructureInt, map_mapRange_eq_iff, Int.coe_castRingHom] intro c rw [wittStructureRat_rec, coeff_C_mul, mul_comm, mul_div_assoc', mul_one] have sum_induction_steps : map (Int.castRingHom ℚ) (∑ i ∈ range n, C ((p : ℤ) ^ i) * wittStructureInt p Φ i ^ p ^ (n - i)) = ∑ i ∈ range n, C ((p : ℚ) ^ i) * wittStructureRat p (map (Int.castRingHom ℚ) Φ) i ^ p ^ (n - i) := by rw [map_sum] apply Finset.sum_congr rfl intro i hi rw [Finset.mem_range] at hi simp only [IH i hi, RingHom.map_mul, RingHom.map_pow, map_C] rfl simp only [← sum_induction_steps, ← map_wittPolynomial p (Int.castRingHom ℚ), ← map_rename, ← map_bind₁, ← RingHom.map_sub, coeff_map] rw [show (p : ℚ) ^ n = ((↑(p ^ n) : ℤ) : ℚ) by norm_cast] rw [← Rat.den_eq_one_iff, eq_intCast, Rat.den_div_intCast_eq_one_iff] swap; · exact mod_cast pow_ne_zero n hp.1.ne_zero revert c; rw [← C_dvd_iff_dvd_coeff] exact C_p_pow_dvd_bind₁_rename_wittPolynomial_sub_sum Φ n IH theorem wittStructureInt_prop (Φ : MvPolynomial idx ℤ) (n) : bind₁ (wittStructureInt p Φ) (wittPolynomial p ℤ n) = bind₁ (fun i => rename (Prod.mk i) (W_ ℤ n)) Φ := by apply MvPolynomial.map_injective (Int.castRingHom ℚ) Int.cast_injective have := wittStructureRat_prop p (map (Int.castRingHom ℚ) Φ) n simpa only [map_bind₁, ← eval₂Hom_map_hom, eval₂Hom_C_left, map_rename, map_wittPolynomial, AlgHom.coe_toRingHom, map_wittStructureInt] theorem eq_wittStructureInt (Φ : MvPolynomial idx ℤ) (φ : ℕ → MvPolynomial (idx × ℕ) ℤ) (h : ∀ n, bind₁ φ (wittPolynomial p ℤ n) = bind₁ (fun i => rename (Prod.mk i) (W_ ℤ n)) Φ) : φ = wittStructureInt p Φ := by funext k apply MvPolynomial.map_injective (Int.castRingHom ℚ) Int.cast_injective rw [map_wittStructureInt] -- Porting note: was `refine' congr_fun _ k` revert k refine congr_fun ?_ apply ExistsUnique.unique (wittStructureRat_existsUnique p (map (Int.castRingHom ℚ) Φ)) · intro n specialize h n apply_fun map (Int.castRingHom ℚ) at h simpa only [map_bind₁, ← eval₂Hom_map_hom, eval₂Hom_C_left, map_rename, map_wittPolynomial, AlgHom.coe_toRingHom] using h · intro n; apply wittStructureRat_prop theorem wittStructureInt_existsUnique (Φ : MvPolynomial idx ℤ) : ∃! φ : ℕ → MvPolynomial (idx × ℕ) ℤ, ∀ n : ℕ, bind₁ φ (wittPolynomial p ℤ n) = bind₁ (fun i : idx => rename (Prod.mk i) (W_ ℤ n)) Φ := ⟨wittStructureInt p Φ, wittStructureInt_prop _ _, eq_wittStructureInt _ _⟩ theorem witt_structure_prop (Φ : MvPolynomial idx ℤ) (n) : aeval (fun i => map (Int.castRingHom R) (wittStructureInt p Φ i)) (wittPolynomial p ℤ n) = aeval (fun i => rename (Prod.mk i) (W n)) Φ := by convert congr_arg (map (Int.castRingHom R)) (wittStructureInt_prop p Φ n) using 1 <;> rw [hom_bind₁] <;> apply eval₂Hom_congr (RingHom.ext_int _ _) _ rfl · rfl · simp only [map_rename, map_wittPolynomial] theorem wittStructureInt_rename {σ : Type*} (Φ : MvPolynomial idx ℤ) (f : idx → σ) (n : ℕ) : wittStructureInt p (rename f Φ) n = rename (Prod.map f id) (wittStructureInt p Φ n) := by apply MvPolynomial.map_injective (Int.castRingHom ℚ) Int.cast_injective simp only [map_rename, map_wittStructureInt, wittStructureRat, rename_bind₁, rename_rename, bind₁_rename] rfl @[simp] theorem constantCoeff_wittStructureRat_zero (Φ : MvPolynomial idx ℚ) : constantCoeff (wittStructureRat p Φ 0) = constantCoeff Φ := by simp only [wittStructureRat, bind₁, map_aeval, xInTermsOfW_zero, constantCoeff_rename, constantCoeff_wittPolynomial, aeval_X, constantCoeff_comp_algebraMap, eval₂Hom_zero'_apply, RingHom.id_apply] theorem constantCoeff_wittStructureRat (Φ : MvPolynomial idx ℚ) (h : constantCoeff Φ = 0) (n : ℕ) : constantCoeff (wittStructureRat p Φ n) = 0 := by simp only [wittStructureRat, eval₂Hom_zero'_apply, h, bind₁, map_aeval, constantCoeff_rename, constantCoeff_wittPolynomial, constantCoeff_comp_algebraMap, RingHom.id_apply, constantCoeff_xInTermsOfW] @[simp] theorem constantCoeff_wittStructureInt_zero (Φ : MvPolynomial idx ℤ) : constantCoeff (wittStructureInt p Φ 0) = constantCoeff Φ := by have inj : Function.Injective (Int.castRingHom ℚ) := by intro m n; exact Int.cast_inj.mp apply inj	rw [← constantCoeff_map, map_wittStructureInt, constantCoeff_wittStructureRat_zero, constantCoeff_map] theorem constantCoeff_wittStructureInt (Φ : MvPolynomial idx ℤ) (h : constantCoeff Φ = 0) (n : ℕ) : constantCoeff (wittStructureInt p Φ n) = 0 := by	Mathlib/RingTheory/WittVector/StructurePolynomial.lean	355	359
/- Copyright (c) 2022 Stuart Presnell. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Stuart Presnell, Eric Wieser, Yaël Dillies, Patrick Massot, Kim Morrison -/ import Mathlib.Algebra.GroupWithZero.InjSurj import Mathlib.Algebra.Order.Ring.Defs import Mathlib.Algebra.Ring.Regular import Mathlib.Order.Interval.Set.Basic import Mathlib.Tactic.FastInstance /-! # Algebraic instances for unit intervals For suitably structured underlying type `α`, we exhibit the structure of the unit intervals (`Set.Icc`, `Set.Ioc`, `Set.Ioc`, and `Set.Ioo`) from `0` to `1`. Note: Instances for the interval `Ici 0` are dealt with in `Algebra/Order/Nonneg.lean`. ## Main definitions The strongest typeclass provided on each interval is: * `Set.Icc.cancelCommMonoidWithZero` * `Set.Ico.commSemigroup` * `Set.Ioc.commMonoid` * `Set.Ioo.commSemigroup` ## TODO * algebraic instances for intervals -1 to 1 * algebraic instances for `Ici 1` * algebraic instances for `(Ioo (-1) 1)ᶜ` * provide `distribNeg` instances where applicable * prove versions of `mul_le_{left,right}` for other intervals * prove versions of the lemmas in `Topology/UnitInterval` with `ℝ` generalized to some arbitrary ordered semiring -/ assert_not_exists RelIso open Set variable {R : Type*} section OrderedSemiring variable [Semiring R] [PartialOrder R] [IsOrderedRing R] /-! ### Instances for `↥(Set.Icc 0 1)` -/ namespace Set.Icc instance zero : Zero (Icc (0 : R) 1) where zero := ⟨0, left_mem_Icc.2 zero_le_one⟩ instance one : One (Icc (0 : R) 1) where one := ⟨1, right_mem_Icc.2 zero_le_one⟩ @[simp, norm_cast] theorem coe_zero : ↑(0 : Icc (0 : R) 1) = (0 : R) := rfl @[simp, norm_cast] theorem coe_one : ↑(1 : Icc (0 : R) 1) = (1 : R) := rfl @[simp] theorem mk_zero (h : (0 : R) ∈ Icc (0 : R) 1) : (⟨0, h⟩ : Icc (0 : R) 1) = 0 := rfl @[simp] theorem mk_one (h : (1 : R) ∈ Icc (0 : R) 1) : (⟨1, h⟩ : Icc (0 : R) 1) = 1 := rfl @[simp, norm_cast] theorem coe_eq_zero {x : Icc (0 : R) 1} : (x : R) = 0 ↔ x = 0 := by symm exact Subtype.ext_iff theorem coe_ne_zero {x : Icc (0 : R) 1} : (x : R) ≠ 0 ↔ x ≠ 0 := not_iff_not.mpr coe_eq_zero @[simp, norm_cast] theorem coe_eq_one {x : Icc (0 : R) 1} : (x : R) = 1 ↔ x = 1 := by symm exact Subtype.ext_iff theorem coe_ne_one {x : Icc (0 : R) 1} : (x : R) ≠ 1 ↔ x ≠ 1 := not_iff_not.mpr coe_eq_one	omit [IsOrderedRing R] in theorem coe_nonneg (x : Icc (0 : R) 1) : 0 ≤ (x : R) := x.2.1	Mathlib/Algebra/Order/Interval/Set/Instances.lean	89	91
/- Copyright (c) 2018 Chris Hughes. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Chris Hughes, Johannes Hölzl, Kim Morrison, Jens Wagemaker -/ import Mathlib.Algebra.Group.Submonoid.Operations import Mathlib.Algebra.MonoidAlgebra.Defs import Mathlib.Algebra.Order.Monoid.Unbundled.WithTop import Mathlib.Algebra.Ring.Action.Rat import Mathlib.Data.Finset.Sort import Mathlib.Tactic.FastInstance /-! # Theory of univariate polynomials This file defines `Polynomial R`, the type of univariate polynomials over the semiring `R`, builds a semiring structure on it, and gives basic definitions that are expanded in other files in this directory. ## Main definitions * `monomial n a` is the polynomial `a X^n`. Note that `monomial n` is defined as an `R`-linear map. * `C a` is the constant polynomial `a`. Note that `C` is defined as a ring homomorphism. * `X` is the polynomial `X`, i.e., `monomial 1 1`. * `p.sum f` is `∑ n ∈ p.support, f n (p.coeff n)`, i.e., one sums the values of functions applied to coefficients of the polynomial `p`. * `p.erase n` is the polynomial `p` in which one removes the `c X^n` term. There are often two natural variants of lemmas involving sums, depending on whether one acts on the polynomials, or on the function. The naming convention is that one adds `index` when acting on the polynomials. For instance, * `sum_add_index` states that `(p + q).sum f = p.sum f + q.sum f`; * `sum_add` states that `p.sum (fun n x ↦ f n x + g n x) = p.sum f + p.sum g`. * Notation to refer to `Polynomial R`, as `R[X]` or `R[t]`. ## Implementation Polynomials are defined using `R[ℕ]`, where `R` is a semiring. The variable `X` commutes with every polynomial `p`: lemma `X_mul` proves the identity `X * p = p * X`. The relationship to `R[ℕ]` is through a structure to make polynomials irreducible from the point of view of the kernel. Most operations are irreducible since Lean can not compute anyway with `AddMonoidAlgebra`. There are two exceptions that we make semireducible: * The zero polynomial, so that its coefficients are definitionally equal to `0`. * The scalar action, to permit typeclass search to unfold it to resolve potential instance diamonds. The raw implementation of the equivalence between `R[X]` and `R[ℕ]` is done through `ofFinsupp` and `toFinsupp` (or, equivalently, `rcases p` when `p` is a polynomial gives an element `q` of `R[ℕ]`, and conversely `⟨q⟩` gives back `p`). The equivalence is also registered as a ring equiv in `Polynomial.toFinsuppIso`. These should in general not be used once the basic API for polynomials is constructed. -/ noncomputable section /-- `Polynomial R` is the type of univariate polynomials over `R`, denoted as `R[X]` within the `Polynomial` namespace. Polynomials should be seen as (semi-)rings with the additional constructor `X`. The embedding from `R` is called `C`. -/ structure Polynomial (R : Type) [Semiring R] where ofFinsupp :: toFinsupp : AddMonoidAlgebra R ℕ @[inherit_doc] scoped[Polynomial] notation:9000 R "[X]" => Polynomial R open AddMonoidAlgebra Finset open Finsupp hiding single open Function hiding Commute namespace Polynomial universe u variable {R : Type u} {a b : R} {m n : ℕ} section Semiring variable [Semiring R] {p q : R[X]} theorem forall_iff_forall_finsupp (P : R[X] → Prop) : (∀ p, P p) ↔ ∀ q : R[ℕ], P ⟨q⟩ := ⟨fun h q => h ⟨q⟩, fun h ⟨p⟩ => h p⟩ theorem exists_iff_exists_finsupp (P : R[X] → Prop) : (∃ p, P p) ↔ ∃ q : R[ℕ], P ⟨q⟩ := ⟨fun ⟨⟨p⟩, hp⟩ => ⟨p, hp⟩, fun ⟨q, hq⟩ => ⟨⟨q⟩, hq⟩⟩ @[simp] theorem eta (f : R[X]) : Polynomial.ofFinsupp f.toFinsupp = f := by cases f; rfl /-! ### Conversions to and from `AddMonoidAlgebra` Since `R[X]` is not defeq to `R[ℕ]`, but instead is a structure wrapping it, we have to copy across all the arithmetic operators manually, along with the lemmas about how they unfold around `Polynomial.ofFinsupp` and `Polynomial.toFinsupp`. -/ section AddMonoidAlgebra private irreducible_def add : R[X] → R[X] → R[X] \| ⟨a⟩, ⟨b⟩ => ⟨a + b⟩ private irreducible_def neg {R : Type u} [Ring R] : R[X] → R[X] \| ⟨a⟩ => ⟨-a⟩ private irreducible_def mul : R[X] → R[X] → R[X] \| ⟨a⟩, ⟨b⟩ => ⟨a b⟩ instance zero : Zero R[X] := ⟨⟨0⟩⟩ instance one : One R[X] := ⟨⟨1⟩⟩ instance add' : Add R[X] := ⟨add⟩ instance neg' {R : Type u} [Ring R] : Neg R[X] := ⟨neg⟩ instance sub {R : Type u} [Ring R] : Sub R[X] := ⟨fun a b => a + -b⟩ instance mul' : Mul R[X] := ⟨mul⟩ -- If the private definitions are accidentally exposed, simplify them away. @[simp] theorem add_eq_add : add p q = p + q := rfl @[simp] theorem mul_eq_mul : mul p q = p * q := rfl instance instNSMul : SMul ℕ R[X] where smul r p := ⟨r • p.toFinsupp⟩ instance smulZeroClass {S : Type} [SMulZeroClass S R] : SMulZeroClass S R[X] where smul r p := ⟨r • p.toFinsupp⟩ smul_zero a := congr_arg ofFinsupp (smul_zero a) instance {S : Type} [Zero S] [SMulZeroClass S R] [NoZeroSMulDivisors S R] : NoZeroSMulDivisors S R[X] where eq_zero_or_eq_zero_of_smul_eq_zero eq := (eq_zero_or_eq_zero_of_smul_eq_zero <\| congr_arg toFinsupp eq).imp id (congr_arg ofFinsupp) -- to avoid a bug in the `ring` tactic instance (priority := 1) pow : Pow R[X] ℕ where pow p n := npowRec n p @[simp] theorem ofFinsupp_zero : (⟨0⟩ : R[X]) = 0 := rfl @[simp] theorem ofFinsupp_one : (⟨1⟩ : R[X]) = 1 := rfl @[simp] theorem ofFinsupp_add {a b} : (⟨a + b⟩ : R[X]) = ⟨a⟩ + ⟨b⟩ := show _ = add _ _ by rw [add_def] @[simp] theorem ofFinsupp_neg {R : Type u} [Ring R] {a} : (⟨-a⟩ : R[X]) = -⟨a⟩ := show _ = neg _ by rw [neg_def] @[simp] theorem ofFinsupp_sub {R : Type u} [Ring R] {a b} : (⟨a - b⟩ : R[X]) = ⟨a⟩ - ⟨b⟩ := by rw [sub_eq_add_neg, ofFinsupp_add, ofFinsupp_neg] rfl @[simp] theorem ofFinsupp_mul (a b) : (⟨a * b⟩ : R[X]) = ⟨a⟩ * ⟨b⟩ := show _ = mul _ _ by rw [mul_def] @[simp] theorem ofFinsupp_nsmul (a : ℕ) (b) : (⟨a • b⟩ : R[X]) = (a • ⟨b⟩ : R[X]) := rfl @[simp] theorem ofFinsupp_smul {S : Type} [SMulZeroClass S R] (a : S) (b) : (⟨a • b⟩ : R[X]) = (a • ⟨b⟩ : R[X]) := rfl @[simp] theorem ofFinsupp_pow (a) (n : ℕ) : (⟨a ^ n⟩ : R[X]) = ⟨a⟩ ^ n := by change _ = npowRec n _ induction n with \| zero => simp [npowRec] \| succ n n_ih => simp [npowRec, n_ih, pow_succ] @[simp] theorem toFinsupp_zero : (0 : R[X]).toFinsupp = 0 := rfl @[simp] theorem toFinsupp_one : (1 : R[X]).toFinsupp = 1 := rfl @[simp] theorem toFinsupp_add (a b : R[X]) : (a + b).toFinsupp = a.toFinsupp + b.toFinsupp := by cases a cases b rw [← ofFinsupp_add] @[simp] theorem toFinsupp_neg {R : Type u} [Ring R] (a : R[X]) : (-a).toFinsupp = -a.toFinsupp := by cases a rw [← ofFinsupp_neg] @[simp] theorem toFinsupp_sub {R : Type u} [Ring R] (a b : R[X]) : (a - b).toFinsupp = a.toFinsupp - b.toFinsupp := by rw [sub_eq_add_neg, ← toFinsupp_neg, ← toFinsupp_add] rfl @[simp] theorem toFinsupp_mul (a b : R[X]) : (a b).toFinsupp = a.toFinsupp * b.toFinsupp := by cases a cases b rw [← ofFinsupp_mul] @[simp] theorem toFinsupp_nsmul (a : ℕ) (b : R[X]) : (a • b).toFinsupp = a • b.toFinsupp := rfl @[simp] theorem toFinsupp_smul {S : Type} [SMulZeroClass S R] (a : S) (b : R[X]) : (a • b).toFinsupp = a • b.toFinsupp := rfl @[simp] theorem toFinsupp_pow (a : R[X]) (n : ℕ) : (a ^ n).toFinsupp = a.toFinsupp ^ n := by cases a rw [← ofFinsupp_pow] theorem _root_.IsSMulRegular.polynomial {S : Type} [SMulZeroClass S R] {a : S} (ha : IsSMulRegular R a) : IsSMulRegular R[X] a \| ⟨_x⟩, ⟨_y⟩, h => congr_arg _ <\| ha.finsupp (Polynomial.ofFinsupp.inj h) theorem toFinsupp_injective : Function.Injective (toFinsupp : R[X] → AddMonoidAlgebra _ _) := fun ⟨_x⟩ ⟨_y⟩ => congr_arg _ @[simp] theorem toFinsupp_inj {a b : R[X]} : a.toFinsupp = b.toFinsupp ↔ a = b := toFinsupp_injective.eq_iff @[simp] theorem toFinsupp_eq_zero {a : R[X]} : a.toFinsupp = 0 ↔ a = 0 := by rw [← toFinsupp_zero, toFinsupp_inj] @[simp] theorem toFinsupp_eq_one {a : R[X]} : a.toFinsupp = 1 ↔ a = 1 := by rw [← toFinsupp_one, toFinsupp_inj] /-- A more convenient spelling of `Polynomial.ofFinsupp.injEq` in terms of `Iff`. -/ theorem ofFinsupp_inj {a b} : (⟨a⟩ : R[X]) = ⟨b⟩ ↔ a = b := iff_of_eq (ofFinsupp.injEq _ _) @[simp] theorem ofFinsupp_eq_zero {a} : (⟨a⟩ : R[X]) = 0 ↔ a = 0 := by rw [← ofFinsupp_zero, ofFinsupp_inj] @[simp] theorem ofFinsupp_eq_one {a} : (⟨a⟩ : R[X]) = 1 ↔ a = 1 := by rw [← ofFinsupp_one, ofFinsupp_inj] instance inhabited : Inhabited R[X] := ⟨0⟩ instance instNatCast : NatCast R[X] where natCast n := ofFinsupp n @[simp] theorem ofFinsupp_natCast (n : ℕ) : (⟨n⟩ : R[X]) = n := rfl @[simp] theorem toFinsupp_natCast (n : ℕ) : (n : R[X]).toFinsupp = n := rfl @[simp] theorem ofFinsupp_ofNat (n : ℕ) [n.AtLeastTwo] : (⟨ofNat(n)⟩ : R[X]) = ofNat(n) := rfl @[simp] theorem toFinsupp_ofNat (n : ℕ) [n.AtLeastTwo] : (ofNat(n) : R[X]).toFinsupp = ofNat(n) := rfl instance semiring : Semiring R[X] := fast_instance% Function.Injective.semiring toFinsupp toFinsupp_injective toFinsupp_zero toFinsupp_one toFinsupp_add toFinsupp_mul (fun _ _ => toFinsupp_nsmul _ _) toFinsupp_pow fun _ => rfl instance distribSMul {S} [DistribSMul S R] : DistribSMul S R[X] := fast_instance% Function.Injective.distribSMul ⟨⟨toFinsupp, toFinsupp_zero⟩, toFinsupp_add⟩ toFinsupp_injective toFinsupp_smul instance distribMulAction {S} [Monoid S] [DistribMulAction S R] : DistribMulAction S R[X] := fast_instance% Function.Injective.distribMulAction ⟨⟨toFinsupp, toFinsupp_zero (R := R)⟩, toFinsupp_add⟩ toFinsupp_injective toFinsupp_smul instance faithfulSMul {S} [SMulZeroClass S R] [FaithfulSMul S R] : FaithfulSMul S R[X] where eq_of_smul_eq_smul {_s₁ _s₂} h := eq_of_smul_eq_smul fun a : ℕ →₀ R => congr_arg toFinsupp (h ⟨a⟩) instance module {S} [Semiring S] [Module S R] : Module S R[X] := fast_instance% Function.Injective.module _ ⟨⟨toFinsupp, toFinsupp_zero⟩, toFinsupp_add⟩ toFinsupp_injective toFinsupp_smul instance smulCommClass {S₁ S₂} [SMulZeroClass S₁ R] [SMulZeroClass S₂ R] [SMulCommClass S₁ S₂ R] : SMulCommClass S₁ S₂ R[X] := ⟨by rintro m n ⟨f⟩ simp_rw [← ofFinsupp_smul, smul_comm m n f]⟩ instance isScalarTower {S₁ S₂} [SMul S₁ S₂] [SMulZeroClass S₁ R] [SMulZeroClass S₂ R] [IsScalarTower S₁ S₂ R] : IsScalarTower S₁ S₂ R[X] := ⟨by rintro _ _ ⟨⟩ simp_rw [← ofFinsupp_smul, smul_assoc]⟩ instance isScalarTower_right {α K : Type} [Semiring K] [DistribSMul α K] [IsScalarTower α K K] : IsScalarTower α K[X] K[X] := ⟨by rintro _ ⟨⟩ ⟨⟩ simp_rw [smul_eq_mul, ← ofFinsupp_smul, ← ofFinsupp_mul, ← ofFinsupp_smul, smul_mul_assoc]⟩ instance isCentralScalar {S} [SMulZeroClass S R] [SMulZeroClass Sᵐᵒᵖ R] [IsCentralScalar S R] : IsCentralScalar S R[X] := ⟨by rintro _ ⟨⟩ simp_rw [← ofFinsupp_smul, op_smul_eq_smul]⟩ instance unique [Subsingleton R] : Unique R[X] := { Polynomial.inhabited with uniq := by rintro ⟨x⟩ apply congr_arg ofFinsupp simp [eq_iff_true_of_subsingleton] } variable (R) /-- Ring isomorphism between `R[X]` and `R[ℕ]`. This is just an implementation detail, but it can be useful to transfer results from `Finsupp` to polynomials. -/ @[simps apply symm_apply] def toFinsuppIso : R[X] ≃+ R[ℕ] where toFun := toFinsupp invFun := ofFinsupp left_inv := fun ⟨_p⟩ => rfl right_inv _p := rfl map_mul' := toFinsupp_mul map_add' := toFinsupp_add instance [DecidableEq R] : DecidableEq R[X] := @Equiv.decidableEq R[X] _ (toFinsuppIso R).toEquiv (Finsupp.instDecidableEq) /-- Linear isomorphism between `R[X]` and `R[ℕ]`. This is just an implementation detail, but it can be useful to transfer results from `Finsupp` to polynomials. -/ @[simps!] def toFinsuppIsoLinear : R[X] ≃ₗ[R] R[ℕ] where __ := toFinsuppIso R map_smul' _ _ := rfl end AddMonoidAlgebra theorem ofFinsupp_sum {ι : Type} (s : Finset ι) (f : ι → R[ℕ]) : (⟨∑ i ∈ s, f i⟩ : R[X]) = ∑ i ∈ s, ⟨f i⟩ := map_sum (toFinsuppIso R).symm f s theorem toFinsupp_sum {ι : Type} (s : Finset ι) (f : ι → R[X]) : (∑ i ∈ s, f i : R[X]).toFinsupp = ∑ i ∈ s, (f i).toFinsupp := map_sum (toFinsuppIso R) f s /-- The set of all `n` such that `X^n` has a non-zero coefficient. -/ def support : R[X] → Finset ℕ \| ⟨p⟩ => p.support @[simp] theorem support_ofFinsupp (p) : support (⟨p⟩ : R[X]) = p.support := by rw [support] theorem support_toFinsupp (p : R[X]) : p.toFinsupp.support = p.support := by rw [support] @[simp] theorem support_zero : (0 : R[X]).support = ∅ := rfl @[simp] theorem support_eq_empty : p.support = ∅ ↔ p = 0 := by rcases p with ⟨⟩ simp [support] @[simp] lemma support_nonempty : p.support.Nonempty ↔ p ≠ 0 := Finset.nonempty_iff_ne_empty.trans support_eq_empty.not theorem card_support_eq_zero : #p.support = 0 ↔ p = 0 := by simp /-- `monomial s a` is the monomial `a * X^s` -/ def monomial (n : ℕ) : R →ₗ[R] R[X] where toFun t := ⟨Finsupp.single n t⟩ -- Porting note (https://github.com/leanprover-community/mathlib4/issues/10745): was `simp`. map_add' x y := by simp; rw [ofFinsupp_add] -- Porting note (https://github.com/leanprover-community/mathlib4/issues/10745): was `simp [← ofFinsupp_smul]`. map_smul' r x := by simp; rw [← ofFinsupp_smul, smul_single'] @[simp] theorem toFinsupp_monomial (n : ℕ) (r : R) : (monomial n r).toFinsupp = Finsupp.single n r := by simp [monomial] @[simp] theorem ofFinsupp_single (n : ℕ) (r : R) : (⟨Finsupp.single n r⟩ : R[X]) = monomial n r := by simp [monomial] @[simp] theorem monomial_zero_right (n : ℕ) : monomial n (0 : R) = 0 := (monomial n).map_zero -- This is not a `simp` lemma as `monomial_zero_left` is more general. theorem monomial_zero_one : monomial 0 (1 : R) = 1 := rfl -- TODO: can't we just delete this one? theorem monomial_add (n : ℕ) (r s : R) : monomial n (r + s) = monomial n r + monomial n s := (monomial n).map_add _ _ theorem monomial_mul_monomial (n m : ℕ) (r s : R) : monomial n r * monomial m s = monomial (n + m) (r * s) := toFinsupp_injective <\| by simp only [toFinsupp_monomial, toFinsupp_mul, AddMonoidAlgebra.single_mul_single] @[simp] theorem monomial_pow (n : ℕ) (r : R) (k : ℕ) : monomial n r ^ k = monomial (n * k) (r ^ k) := by induction k with \| zero => simp [pow_zero, monomial_zero_one] \| succ k ih => simp [pow_succ, ih, monomial_mul_monomial, mul_add, add_comm] theorem smul_monomial {S} [SMulZeroClass S R] (a : S) (n : ℕ) (b : R) : a • monomial n b = monomial n (a • b) := toFinsupp_injective <\| AddMonoidAlgebra.smul_single _ _ _ theorem monomial_injective (n : ℕ) : Function.Injective (monomial n : R → R[X]) := (toFinsuppIso R).symm.injective.comp (single_injective n) @[simp] theorem monomial_eq_zero_iff (t : R) (n : ℕ) : monomial n t = 0 ↔ t = 0 := LinearMap.map_eq_zero_iff _ (Polynomial.monomial_injective n) theorem monomial_eq_monomial_iff {m n : ℕ} {a b : R} : monomial m a = monomial n b ↔ m = n ∧ a = b ∨ a = 0 ∧ b = 0 := by rw [← toFinsupp_inj, toFinsupp_monomial, toFinsupp_monomial, Finsupp.single_eq_single_iff] theorem support_add : (p + q).support ⊆ p.support ∪ q.support := by simpa [support] using Finsupp.support_add /-- `C a` is the constant polynomial `a`. `C` is provided as a ring homomorphism. -/ def C : R →+* R[X] := { monomial 0 with map_one' := by simp [monomial_zero_one] map_mul' := by simp [monomial_mul_monomial] map_zero' := by simp } @[simp] theorem monomial_zero_left (a : R) : monomial 0 a = C a := rfl @[simp] theorem toFinsupp_C (a : R) : (C a).toFinsupp = single 0 a := rfl theorem C_0 : C (0 : R) = 0 := by simp theorem C_1 : C (1 : R) = 1 := rfl theorem C_mul : C (a * b) = C a * C b := C.map_mul a b theorem C_add : C (a + b) = C a + C b := C.map_add a b @[simp] theorem smul_C {S} [SMulZeroClass S R] (s : S) (r : R) : s • C r = C (s • r) := smul_monomial _ _ r theorem C_pow : C (a ^ n) = C a ^ n := C.map_pow a n theorem C_eq_natCast (n : ℕ) : C (n : R) = (n : R[X]) := map_natCast C n @[simp] theorem C_mul_monomial : C a * monomial n b = monomial n (a * b) := by simp only [← monomial_zero_left, monomial_mul_monomial, zero_add] @[simp] theorem monomial_mul_C : monomial n a * C b = monomial n (a * b) := by simp only [← monomial_zero_left, monomial_mul_monomial, add_zero] /-- `X` is the polynomial variable (aka indeterminate). -/ def X : R[X] := monomial 1 1 theorem monomial_one_one_eq_X : monomial 1 (1 : R) = X := rfl theorem monomial_one_right_eq_X_pow (n : ℕ) : monomial n (1 : R) = X ^ n := by induction n with \| zero => simp [monomial_zero_one] \| succ n ih => rw [pow_succ, ← ih, ← monomial_one_one_eq_X, monomial_mul_monomial, mul_one] @[simp] theorem toFinsupp_X : X.toFinsupp = Finsupp.single 1 (1 : R) := rfl theorem X_ne_C [Nontrivial R] (a : R) : X ≠ C a := by intro he simpa using monomial_eq_monomial_iff.1 he /-- `X` commutes with everything, even when the coefficients are noncommutative. -/ theorem X_mul : X * p = p * X := by rcases p with ⟨⟩ simp only [X, ← ofFinsupp_single, ← ofFinsupp_mul, LinearMap.coe_mk, ofFinsupp.injEq] ext simp [AddMonoidAlgebra.mul_apply, AddMonoidAlgebra.sum_single_index, add_comm] theorem X_pow_mul {n : ℕ} : X ^ n * p = p * X ^ n := by induction n with \| zero => simp \| succ n ih => conv_lhs => rw [pow_succ] rw [mul_assoc, X_mul, ← mul_assoc, ih, mul_assoc, ← pow_succ] /-- Prefer putting constants to the left of `X`. This lemma is the loop-avoiding `simp` version of `Polynomial.X_mul`. -/ @[simp] theorem X_mul_C (r : R) : X * C r = C r * X := X_mul /-- Prefer putting constants to the left of `X ^ n`. This lemma is the loop-avoiding `simp` version of `X_pow_mul`. -/ @[simp] theorem X_pow_mul_C (r : R) (n : ℕ) : X ^ n * C r = C r * X ^ n := X_pow_mul theorem X_pow_mul_assoc {n : ℕ} : p * X ^ n * q = p * q * X ^ n := by rw [mul_assoc, X_pow_mul, ← mul_assoc] /-- Prefer putting constants to the left of `X ^ n`. This lemma is the loop-avoiding `simp` version of `X_pow_mul_assoc`. -/ @[simp] theorem X_pow_mul_assoc_C {n : ℕ} (r : R) : p * X ^ n * C r = p * C r * X ^ n := X_pow_mul_assoc theorem commute_X (p : R[X]) : Commute X p := X_mul theorem commute_X_pow (p : R[X]) (n : ℕ) : Commute (X ^ n) p := X_pow_mul @[simp] theorem monomial_mul_X (n : ℕ) (r : R) : monomial n r * X = monomial (n + 1) r := by rw [X, monomial_mul_monomial, mul_one] @[simp] theorem monomial_mul_X_pow (n : ℕ) (r : R) (k : ℕ) : monomial n r * X ^ k = monomial (n + k) r := by induction k with \| zero => simp \| succ k ih => simp [ih, pow_succ, ← mul_assoc, add_assoc] @[simp] theorem X_mul_monomial (n : ℕ) (r : R) : X * monomial n r = monomial (n + 1) r := by rw [X_mul, monomial_mul_X] @[simp] theorem X_pow_mul_monomial (k n : ℕ) (r : R) : X ^ k * monomial n r = monomial (n + k) r := by rw [X_pow_mul, monomial_mul_X_pow] /-- `coeff p n` (often denoted `p.coeff n`) is the coefficient of `X^n` in `p`. -/ def coeff : R[X] → ℕ → R \| ⟨p⟩ => p @[simp] theorem coeff_ofFinsupp (p) : coeff (⟨p⟩ : R[X]) = p := by rw [coeff] theorem coeff_injective : Injective (coeff : R[X] → ℕ → R) := by rintro ⟨p⟩ ⟨q⟩ simp only [coeff, DFunLike.coe_fn_eq, imp_self, ofFinsupp.injEq] @[simp] theorem coeff_inj : p.coeff = q.coeff ↔ p = q := coeff_injective.eq_iff theorem toFinsupp_apply (f : R[X]) (i) : f.toFinsupp i = f.coeff i := by cases f; rfl theorem coeff_monomial : coeff (monomial n a) m = if n = m then a else 0 := by simp [coeff, Finsupp.single_apply] @[simp] theorem coeff_monomial_same (n : ℕ) (c : R) : (monomial n c).coeff n = c := Finsupp.single_eq_same theorem coeff_monomial_of_ne {m n : ℕ} (c : R) (h : n ≠ m) : (monomial n c).coeff m = 0 := Finsupp.single_eq_of_ne h @[simp] theorem coeff_zero (n : ℕ) : coeff (0 : R[X]) n = 0 := rfl theorem coeff_one {n : ℕ} : coeff (1 : R[X]) n = if n = 0 then 1 else 0 := by simp_rw [eq_comm (a := n) (b := 0)] exact coeff_monomial @[simp] theorem coeff_one_zero : coeff (1 : R[X]) 0 = 1 := by simp [coeff_one] @[simp] theorem coeff_X_one : coeff (X : R[X]) 1 = 1 := coeff_monomial @[simp] theorem coeff_X_zero : coeff (X : R[X]) 0 = 0 := coeff_monomial @[simp] theorem coeff_monomial_succ : coeff (monomial (n + 1) a) 0 = 0 := by simp [coeff_monomial] theorem coeff_X : coeff (X : R[X]) n = if 1 = n then 1 else 0 := coeff_monomial theorem coeff_X_of_ne_one {n : ℕ} (hn : n ≠ 1) : coeff (X : R[X]) n = 0 := by rw [coeff_X, if_neg hn.symm] @[simp] theorem mem_support_iff : n ∈ p.support ↔ p.coeff n ≠ 0 := by rcases p with ⟨⟩ simp theorem not_mem_support_iff : n ∉ p.support ↔ p.coeff n = 0 := by simp theorem coeff_C : coeff (C a) n = ite (n = 0) a 0 := by convert coeff_monomial (a := a) (m := n) (n := 0) using 2 simp [eq_comm] @[simp] theorem coeff_C_zero : coeff (C a) 0 = a := coeff_monomial theorem coeff_C_ne_zero (h : n ≠ 0) : (C a).coeff n = 0 := by rw [coeff_C, if_neg h] @[simp] lemma coeff_C_succ {r : R} {n : ℕ} : coeff (C r) (n + 1) = 0 := by simp [coeff_C] @[simp] theorem coeff_natCast_ite : (Nat.cast m : R[X]).coeff n = ite (n = 0) m 0 := by simp only [← C_eq_natCast, coeff_C, Nat.cast_ite, Nat.cast_zero] @[simp] theorem coeff_ofNat_zero (a : ℕ) [a.AtLeastTwo] : coeff (ofNat(a) : R[X]) 0 = ofNat(a) := coeff_monomial @[simp] theorem coeff_ofNat_succ (a n : ℕ) [h : a.AtLeastTwo] : coeff (ofNat(a) : R[X]) (n + 1) = 0 := by rw [← Nat.cast_ofNat] simp [-Nat.cast_ofNat] theorem C_mul_X_pow_eq_monomial : ∀ {n : ℕ}, C a * X ^ n = monomial n a \| 0 => mul_one _ \| n + 1 => by rw [pow_succ, ← mul_assoc, C_mul_X_pow_eq_monomial, X, monomial_mul_monomial, mul_one] @[simp high] theorem toFinsupp_C_mul_X_pow (a : R) (n : ℕ) : Polynomial.toFinsupp (C a * X ^ n) = Finsupp.single n a := by rw [C_mul_X_pow_eq_monomial, toFinsupp_monomial] theorem C_mul_X_eq_monomial : C a * X = monomial 1 a := by rw [← C_mul_X_pow_eq_monomial, pow_one] @[simp high] theorem toFinsupp_C_mul_X (a : R) : Polynomial.toFinsupp (C a * X) = Finsupp.single 1 a := by rw [C_mul_X_eq_monomial, toFinsupp_monomial] theorem C_injective : Injective (C : R → R[X]) := monomial_injective 0 @[simp] theorem C_inj : C a = C b ↔ a = b := C_injective.eq_iff @[simp] theorem C_eq_zero : C a = 0 ↔ a = 0 := C_injective.eq_iff' (map_zero C) theorem C_ne_zero : C a ≠ 0 ↔ a ≠ 0 := C_eq_zero.not theorem subsingleton_iff_subsingleton : Subsingleton R[X] ↔ Subsingleton R := ⟨@Injective.subsingleton _ _ _ C_injective, by intro infer_instance⟩ theorem Nontrivial.of_polynomial_ne (h : p ≠ q) : Nontrivial R := (subsingleton_or_nontrivial R).resolve_left fun _hI => h <\| Subsingleton.elim _ _ theorem forall_eq_iff_forall_eq : (∀ f g : R[X], f = g) ↔ ∀ a b : R, a = b := by simpa only [← subsingleton_iff] using subsingleton_iff_subsingleton theorem ext_iff {p q : R[X]} : p = q ↔ ∀ n, coeff p n = coeff q n := by rcases p with ⟨f : ℕ →₀ R⟩ rcases q with ⟨g : ℕ →₀ R⟩ simpa [coeff] using DFunLike.ext_iff (f := f) (g := g) @[ext] theorem ext {p q : R[X]} : (∀ n, coeff p n = coeff q n) → p = q := ext_iff.2 /-- Monomials generate the additive monoid of polynomials. -/ theorem addSubmonoid_closure_setOf_eq_monomial : AddSubmonoid.closure { p : R[X] \| ∃ n a, p = monomial n a } = ⊤ := by apply top_unique rw [← AddSubmonoid.map_equiv_top (toFinsuppIso R).symm.toAddEquiv, ← Finsupp.add_closure_setOf_eq_single, AddMonoidHom.map_mclosure] refine AddSubmonoid.closure_mono (Set.image_subset_iff.2 ?_) rintro _ ⟨n, a, rfl⟩ exact ⟨n, a, Polynomial.ofFinsupp_single _ _⟩ theorem addHom_ext {M : Type} [AddZeroClass M] {f g : R[X] →+ M} (h : ∀ n a, f (monomial n a) = g (monomial n a)) : f = g := AddMonoidHom.eq_of_eqOn_denseM addSubmonoid_closure_setOf_eq_monomial <\| by rintro p ⟨n, a, rfl⟩ exact h n a @[ext high] theorem addHom_ext' {M : Type} [AddZeroClass M] {f g : R[X] →+ M} (h : ∀ n, f.comp (monomial n).toAddMonoidHom = g.comp (monomial n).toAddMonoidHom) : f = g := addHom_ext fun n => DFunLike.congr_fun (h n) @[ext high] theorem lhom_ext' {M : Type} [AddCommMonoid M] [Module R M] {f g : R[X] →ₗ[R] M} (h : ∀ n, f.comp (monomial n) = g.comp (monomial n)) : f = g := LinearMap.toAddMonoidHom_injective <\| addHom_ext fun n => LinearMap.congr_fun (h n) -- this has the same content as the subsingleton theorem eq_zero_of_eq_zero (h : (0 : R) = (1 : R)) (p : R[X]) : p = 0 := by rw [← one_smul R p, ← h, zero_smul] section Fewnomials theorem support_monomial (n) {a : R} (H : a ≠ 0) : (monomial n a).support = singleton n := by rw [← ofFinsupp_single, support]; exact Finsupp.support_single_ne_zero _ H theorem support_monomial' (n) (a : R) : (monomial n a).support ⊆ singleton n := by rw [← ofFinsupp_single, support] exact Finsupp.support_single_subset theorem support_C {a : R} (h : a ≠ 0) : (C a).support = singleton 0 := support_monomial 0 h theorem support_C_subset (a : R) : (C a).support ⊆ singleton 0 := support_monomial' 0 a theorem support_C_mul_X {c : R} (h : c ≠ 0) : Polynomial.support (C c X) = singleton 1 := by rw [C_mul_X_eq_monomial, support_monomial 1 h] theorem support_C_mul_X' (c : R) : Polynomial.support (C c * X) ⊆ singleton 1 := by simpa only [C_mul_X_eq_monomial] using support_monomial' 1 c theorem support_C_mul_X_pow (n : ℕ) {c : R} (h : c ≠ 0) : Polynomial.support (C c * X ^ n) = singleton n := by rw [C_mul_X_pow_eq_monomial, support_monomial n h] theorem support_C_mul_X_pow' (n : ℕ) (c : R) : Polynomial.support (C c * X ^ n) ⊆ singleton n := by simpa only [C_mul_X_pow_eq_monomial] using support_monomial' n c open Finset theorem support_binomial' (k m : ℕ) (x y : R) : Polynomial.support (C x * X ^ k + C y * X ^ m) ⊆ {k, m} := support_add.trans (union_subset ((support_C_mul_X_pow' k x).trans (singleton_subset_iff.mpr (mem_insert_self k {m}))) ((support_C_mul_X_pow' m y).trans (singleton_subset_iff.mpr (mem_insert_of_mem (mem_singleton_self m))))) theorem support_trinomial' (k m n : ℕ) (x y z : R) : Polynomial.support (C x * X ^ k + C y * X ^ m + C z * X ^ n) ⊆ {k, m, n} := support_add.trans (union_subset (support_add.trans (union_subset ((support_C_mul_X_pow' k x).trans (singleton_subset_iff.mpr (mem_insert_self k {m, n}))) ((support_C_mul_X_pow' m y).trans (singleton_subset_iff.mpr (mem_insert_of_mem (mem_insert_self m {n})))))) ((support_C_mul_X_pow' n z).trans (singleton_subset_iff.mpr (mem_insert_of_mem (mem_insert_of_mem (mem_singleton_self n)))))) end Fewnomials theorem X_pow_eq_monomial (n) : X ^ n = monomial n (1 : R) := by induction n with \| zero => rw [pow_zero, monomial_zero_one] \| succ n hn => rw [pow_succ, hn, X, monomial_mul_monomial, one_mul] @[simp high] theorem toFinsupp_X_pow (n : ℕ) : (X ^ n).toFinsupp = Finsupp.single n (1 : R) := by rw [X_pow_eq_monomial, toFinsupp_monomial] theorem smul_X_eq_monomial {n} : a • X ^ n = monomial n (a : R) := by rw [X_pow_eq_monomial, smul_monomial, smul_eq_mul, mul_one] theorem support_X_pow (H : ¬(1 : R) = 0) (n : ℕ) : (X ^ n : R[X]).support = singleton n := by convert support_monomial n H exact X_pow_eq_monomial n theorem support_X_empty (H : (1 : R) = 0) : (X : R[X]).support = ∅ := by rw [X, H, monomial_zero_right, support_zero] theorem support_X (H : ¬(1 : R) = 0) : (X : R[X]).support = singleton 1 := by rw [← pow_one X, support_X_pow H 1] theorem monomial_left_inj {a : R} (ha : a ≠ 0) {i j : ℕ} : monomial i a = monomial j a ↔ i = j := by simp only [← ofFinsupp_single, ofFinsupp.injEq, Finsupp.single_left_inj ha] theorem binomial_eq_binomial {k l m n : ℕ} {u v : R} (hu : u ≠ 0) (hv : v ≠ 0) : C u * X ^ k + C v * X ^ l = C u * X ^ m + C v * X ^ n ↔ k = m ∧ l = n ∨ u = v ∧ k = n ∧ l = m ∨ u + v = 0 ∧ k = l ∧ m = n := by simp_rw [C_mul_X_pow_eq_monomial, ← toFinsupp_inj, toFinsupp_add, toFinsupp_monomial] exact Finsupp.single_add_single_eq_single_add_single hu hv theorem natCast_mul (n : ℕ) (p : R[X]) : (n : R[X]) * p = n • p := (nsmul_eq_mul _ _).symm /-- Summing the values of a function applied to the coefficients of a polynomial -/ def sum {S : Type} [AddCommMonoid S] (p : R[X]) (f : ℕ → R → S) : S := ∑ n ∈ p.support, f n (p.coeff n) theorem sum_def {S : Type} [AddCommMonoid S] (p : R[X]) (f : ℕ → R → S) : p.sum f = ∑ n ∈ p.support, f n (p.coeff n) := rfl theorem sum_eq_of_subset {S : Type} [AddCommMonoid S] {p : R[X]} (f : ℕ → R → S) (hf : ∀ i, f i 0 = 0) {s : Finset ℕ} (hs : p.support ⊆ s) : p.sum f = ∑ n ∈ s, f n (p.coeff n) := Finsupp.sum_of_support_subset _ hs f (fun i _ ↦ hf i) /-- Expressing the product of two polynomials as a double sum. -/ theorem mul_eq_sum_sum : p q = ∑ i ∈ p.support, q.sum fun j a => (monomial (i + j)) (p.coeff i * a) := by apply toFinsupp_injective rcases p with ⟨⟩; rcases q with ⟨⟩ simp_rw [sum, coeff, toFinsupp_sum, support, toFinsupp_mul, toFinsupp_monomial, AddMonoidAlgebra.mul_def, Finsupp.sum] @[simp] theorem sum_zero_index {S : Type} [AddCommMonoid S] (f : ℕ → R → S) : (0 : R[X]).sum f = 0 := by simp [sum] @[simp] theorem sum_monomial_index {S : Type} [AddCommMonoid S] {n : ℕ} (a : R) (f : ℕ → R → S) (hf : f n 0 = 0) : (monomial n a : R[X]).sum f = f n a := Finsupp.sum_single_index hf @[simp] theorem sum_C_index {a} {β} [AddCommMonoid β] {f : ℕ → R → β} (h : f 0 0 = 0) : (C a).sum f = f 0 a := sum_monomial_index a f h -- the assumption `hf` is only necessary when the ring is trivial @[simp] theorem sum_X_index {S : Type} [AddCommMonoid S] {f : ℕ → R → S} (hf : f 1 0 = 0) : (X : R[X]).sum f = f 1 1 := sum_monomial_index 1 f hf theorem sum_add_index {S : Type} [AddCommMonoid S] (p q : R[X]) (f : ℕ → R → S) (hf : ∀ i, f i 0 = 0) (h_add : ∀ a b₁ b₂, f a (b₁ + b₂) = f a b₁ + f a b₂) : (p + q).sum f = p.sum f + q.sum f := by rw [show p + q = ⟨p.toFinsupp + q.toFinsupp⟩ from add_def p q] exact Finsupp.sum_add_index (fun i _ ↦ hf i) (fun a _ b₁ b₂ ↦ h_add a b₁ b₂) theorem sum_add' {S : Type} [AddCommMonoid S] (p : R[X]) (f g : ℕ → R → S) : p.sum (f + g) = p.sum f + p.sum g := by simp [sum_def, Finset.sum_add_distrib] theorem sum_add {S : Type} [AddCommMonoid S] (p : R[X]) (f g : ℕ → R → S) : (p.sum fun n x => f n x + g n x) = p.sum f + p.sum g := sum_add' _ _ _ theorem sum_smul_index {S : Type} [AddCommMonoid S] (p : R[X]) (b : R) (f : ℕ → R → S) (hf : ∀ i, f i 0 = 0) : (b • p).sum f = p.sum fun n a => f n (b a) := Finsupp.sum_smul_index hf theorem sum_smul_index' {S T : Type} [DistribSMul T R] [AddCommMonoid S] (p : R[X]) (b : T) (f : ℕ → R → S) (hf : ∀ i, f i 0 = 0) : (b • p).sum f = p.sum fun n a => f n (b • a) := Finsupp.sum_smul_index' hf protected theorem smul_sum {S T : Type} [AddCommMonoid S] [DistribSMul T S] (p : R[X]) (b : T) (f : ℕ → R → S) : b • p.sum f = p.sum fun n a => b • f n a := Finsupp.smul_sum @[simp] theorem sum_monomial_eq : ∀ p : R[X], (p.sum fun n a => monomial n a) = p \| ⟨_p⟩ => (ofFinsupp_sum _ _).symm.trans (congr_arg _ <\| Finsupp.sum_single _) theorem sum_C_mul_X_pow_eq (p : R[X]) : (p.sum fun n a => C a * X ^ n) = p := by simp_rw [C_mul_X_pow_eq_monomial, sum_monomial_eq] @[elab_as_elim] protected theorem induction_on {motive : R[X] → Prop} (p : R[X]) (C : ∀ a, motive (C a)) (add : ∀ p q, motive p → motive q → motive (p + q)) (monomial : ∀ (n : ℕ) (a : R), motive (Polynomial.C a * X ^ n) → motive (Polynomial.C a * X ^ (n + 1))) : motive p := by have A : ∀ {n : ℕ} {a}, motive (Polynomial.C a * X ^ n) := by intro n a induction n with \| zero => rw [pow_zero, mul_one]; exact C a \| succ n ih => exact monomial _ _ ih have B : ∀ s : Finset ℕ, motive (s.sum fun n : ℕ => Polynomial.C (p.coeff n) * X ^ n) := by apply Finset.induction · convert C 0 exact C_0.symm · intro n s ns ih rw [sum_insert ns] exact add _ _ A ih rw [← sum_C_mul_X_pow_eq p, Polynomial.sum] exact B (support p) /-- To prove something about polynomials, it suffices to show the condition is closed under taking sums, and it holds for monomials. -/ @[elab_as_elim] protected theorem induction_on' {motive : R[X] → Prop} (p : R[X]) (add : ∀ p q, motive p → motive q → motive (p + q)) (monomial : ∀ (n : ℕ) (a : R), motive (monomial n a)) : motive p := Polynomial.induction_on p (monomial 0) add fun n a _h => by rw [C_mul_X_pow_eq_monomial]; exact monomial _ _ /-- `erase p n` is the polynomial `p` in which the `X^n` term has been erased. -/ irreducible_def erase (n : ℕ) : R[X] → R[X] \| ⟨p⟩ => ⟨p.erase n⟩ @[simp] theorem toFinsupp_erase (p : R[X]) (n : ℕ) : toFinsupp (p.erase n) = p.toFinsupp.erase n := by rcases p with ⟨⟩ simp only [erase_def] @[simp] theorem ofFinsupp_erase (p : R[ℕ]) (n : ℕ) : (⟨p.erase n⟩ : R[X]) = (⟨p⟩ : R[X]).erase n := by rcases p with ⟨⟩ simp only [erase_def] @[simp] theorem support_erase (p : R[X]) (n : ℕ) : support (p.erase n) = (support p).erase n := by	rcases p with ⟨⟩ simp only [support, erase_def, Finsupp.support_erase] theorem monomial_add_erase (p : R[X]) (n : ℕ) : monomial n (coeff p n) + p.erase n = p := toFinsupp_injective <\| by	Mathlib/Algebra/Polynomial/Basic.lean	956	960
/- Copyright (c) 2019 Kim Morrison. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kim Morrison, Markus Himmel -/ import Mathlib.CategoryTheory.Limits.Shapes.Equalizers import Mathlib.CategoryTheory.Limits.Shapes.Pullback.Mono import Mathlib.CategoryTheory.Limits.Shapes.StrongEpi import Mathlib.CategoryTheory.MorphismProperty.Factorization /-! # Categorical images We define the categorical image of `f` as a factorisation `f = e ≫ m` through a monomorphism `m`, so that `m` factors through the `m'` in any other such factorisation. ## Main definitions * A `MonoFactorisation` is a factorisation `f = e ≫ m`, where `m` is a monomorphism * `IsImage F` means that a given mono factorisation `F` has the universal property of the image. * `HasImage f` means that there is some image factorization for the morphism `f : X ⟶ Y`. * In this case, `image f` is some image object (selected with choice), `image.ι f : image f ⟶ Y` is the monomorphism `m` of the factorisation and `factorThruImage f : X ⟶ image f` is the morphism `e`. * `HasImages C` means that every morphism in `C` has an image. * Let `f : X ⟶ Y` and `g : P ⟶ Q` be morphisms in `C`, which we will represent as objects of the arrow category `Arrow C`. Then `sq : f ⟶ g` is a commutative square in `C`. If `f` and `g` have images, then `HasImageMap sq` represents the fact that there is a morphism `i : image f ⟶ image g` making the diagram X ----→ image f ----→ Y \| \| \| \| \| \| ↓ ↓ ↓ P ----→ image g ----→ Q commute, where the top row is the image factorisation of `f`, the bottom row is the image factorisation of `g`, and the outer rectangle is the commutative square `sq`. * If a category `HasImages`, then `HasImageMaps` means that every commutative square admits an image map. * If a category `HasImages`, then `HasStrongEpiImages` means that the morphism to the image is always a strong epimorphism. ## Main statements * When `C` has equalizers, the morphism `e` appearing in an image factorisation is an epimorphism. * When `C` has strong epi images, then these images admit image maps. ## Future work * TODO: coimages, and abelian categories. * TODO: connect this with existing working in the group theory and ring theory libraries. -/ noncomputable section universe v u open CategoryTheory open CategoryTheory.Limits.WalkingParallelPair namespace CategoryTheory.Limits variable {C : Type u} [Category.{v} C] variable {X Y : C} (f : X ⟶ Y) /-- A factorisation of a morphism `f = e ≫ m`, with `m` monic. -/ structure MonoFactorisation (f : X ⟶ Y) where I : C -- Porting note: violates naming conventions but can't think a better replacement m : I ⟶ Y [m_mono : Mono m] e : X ⟶ I fac : e ≫ m = f := by aesop_cat attribute [inherit_doc MonoFactorisation] MonoFactorisation.I MonoFactorisation.m MonoFactorisation.m_mono MonoFactorisation.e MonoFactorisation.fac attribute [reassoc (attr := simp)] MonoFactorisation.fac attribute [instance] MonoFactorisation.m_mono namespace MonoFactorisation /-- The obvious factorisation of a monomorphism through itself. -/ def self [Mono f] : MonoFactorisation f where I := X m := f e := 𝟙 X -- I'm not sure we really need this, but the linter says that an inhabited instance -- ought to exist... instance [Mono f] : Inhabited (MonoFactorisation f) := ⟨self f⟩ variable {f} /-- The morphism `m` in a factorisation `f = e ≫ m` through a monomorphism is uniquely determined. -/ @[ext (iff := false)] theorem ext {F F' : MonoFactorisation f} (hI : F.I = F'.I) (hm : F.m = eqToHom hI ≫ F'.m) : F = F' := by obtain ⟨_, Fm, _, Ffac⟩ := F; obtain ⟨_, Fm', _, Ffac'⟩ := F' cases hI simp? at hm says simp only [eqToHom_refl, Category.id_comp] at hm congr apply (cancel_mono Fm).1 rw [Ffac, hm, Ffac'] /-- Any mono factorisation of `f` gives a mono factorisation of `f ≫ g` when `g` is a mono. -/ @[simps] def compMono (F : MonoFactorisation f) {Y' : C} (g : Y ⟶ Y') [Mono g] : MonoFactorisation (f ≫ g) where I := F.I m := F.m ≫ g m_mono := mono_comp _ _ e := F.e /-- A mono factorisation of `f ≫ g`, where `g` is an isomorphism, gives a mono factorisation of `f`. -/ @[simps] def ofCompIso {Y' : C} {g : Y ⟶ Y'} [IsIso g] (F : MonoFactorisation (f ≫ g)) : MonoFactorisation f where I := F.I m := F.m ≫ inv g m_mono := mono_comp _ _ e := F.e /-- Any mono factorisation of `f` gives a mono factorisation of `g ≫ f`. -/ @[simps] def isoComp (F : MonoFactorisation f) {X' : C} (g : X' ⟶ X) : MonoFactorisation (g ≫ f) where I := F.I m := F.m e := g ≫ F.e /-- A mono factorisation of `g ≫ f`, where `g` is an isomorphism, gives a mono factorisation of `f`. -/ @[simps] def ofIsoComp {X' : C} (g : X' ⟶ X) [IsIso g] (F : MonoFactorisation (g ≫ f)) : MonoFactorisation f where I := F.I m := F.m e := inv g ≫ F.e /-- If `f` and `g` are isomorphic arrows, then a mono factorisation of `f` gives a mono factorisation of `g` -/ @[simps] def ofArrowIso {f g : Arrow C} (F : MonoFactorisation f.hom) (sq : f ⟶ g) [IsIso sq] : MonoFactorisation g.hom where I := F.I m := F.m ≫ sq.right e := inv sq.left ≫ F.e m_mono := mono_comp _ _ fac := by simp only [fac_assoc, Arrow.w, IsIso.inv_comp_eq, Category.assoc] end MonoFactorisation variable {f} /-- Data exhibiting that a given factorisation through a mono is initial. -/ structure IsImage (F : MonoFactorisation f) where lift : ∀ F' : MonoFactorisation f, F.I ⟶ F'.I lift_fac : ∀ F' : MonoFactorisation f, lift F' ≫ F'.m = F.m := by aesop_cat attribute [inherit_doc IsImage] IsImage.lift IsImage.lift_fac attribute [reassoc (attr := simp)] IsImage.lift_fac namespace IsImage @[reassoc (attr := simp)] theorem fac_lift {F : MonoFactorisation f} (hF : IsImage F) (F' : MonoFactorisation f) : F.e ≫ hF.lift F' = F'.e := (cancel_mono F'.m).1 <\| by simp variable (f) /-- The trivial factorisation of a monomorphism satisfies the universal property. -/ @[simps] def self [Mono f] : IsImage (MonoFactorisation.self f) where lift F' := F'.e instance [Mono f] : Inhabited (IsImage (MonoFactorisation.self f)) := ⟨self f⟩ variable {f} -- TODO this is another good candidate for a future `UniqueUpToCanonicalIso`. /-- Two factorisations through monomorphisms satisfying the universal property must factor through isomorphic objects. -/ @[simps] def isoExt {F F' : MonoFactorisation f} (hF : IsImage F) (hF' : IsImage F') : F.I ≅ F'.I where hom := hF.lift F' inv := hF'.lift F hom_inv_id := (cancel_mono F.m).1 (by simp) inv_hom_id := (cancel_mono F'.m).1 (by simp) variable {F F' : MonoFactorisation f} (hF : IsImage F) (hF' : IsImage F') theorem isoExt_hom_m : (isoExt hF hF').hom ≫ F'.m = F.m := by simp theorem isoExt_inv_m : (isoExt hF hF').inv ≫ F.m = F'.m := by simp theorem e_isoExt_hom : F.e ≫ (isoExt hF hF').hom = F'.e := by simp theorem e_isoExt_inv : F'.e ≫ (isoExt hF hF').inv = F.e := by simp /-- If `f` and `g` are isomorphic arrows, then a mono factorisation of `f` that is an image gives a mono factorisation of `g` that is an image -/ @[simps] def ofArrowIso {f g : Arrow C} {F : MonoFactorisation f.hom} (hF : IsImage F) (sq : f ⟶ g) [IsIso sq] : IsImage (F.ofArrowIso sq) where lift F' := hF.lift (F'.ofArrowIso (inv sq)) lift_fac F' := by simpa only [MonoFactorisation.ofArrowIso_m, Arrow.inv_right, ← Category.assoc, IsIso.comp_inv_eq] using hF.lift_fac (F'.ofArrowIso (inv sq)) end IsImage variable (f)		Mathlib/CategoryTheory/Limits/Shapes/Images.lean	221	221
/- Copyright (c) 2021 Julian Kuelshammer. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Julian Kuelshammer -/ import Mathlib.GroupTheory.SpecificGroups.Cyclic import Mathlib.GroupTheory.SpecificGroups.Dihedral /-! # Quaternion Groups We define the (generalised) quaternion groups `QuaternionGroup n` of order `4n`, also known as dicyclic groups, with elements `a i` and `xa i` for `i : ZMod n`. The (generalised) quaternion groups can be defined by the presentation $\langle a, x \| a^{2n} = 1, x^2 = a^n, x^{-1}ax=a^{-1}\rangle$. We write `a i` for $a^i$ and `xa i` for $x * a^i$. For `n=2` the quaternion group `QuaternionGroup 2` is isomorphic to the unit integral quaternions `(Quaternion ℤ)ˣ`. ## Main definition `QuaternionGroup n`: The (generalised) quaternion group of order `4n`. ## Implementation notes This file is heavily based on `DihedralGroup` by Shing Tak Lam. In mathematics, the name "quaternion group" is reserved for the cases `n ≥ 2`. Since it would be inconvenient to carry around this condition we define `QuaternionGroup` also for `n = 0` and `n = 1`. `QuaternionGroup 0` is isomorphic to the infinite dihedral group, while `QuaternionGroup 1` is isomorphic to a cyclic group of order `4`. ## References * https://en.wikipedia.org/wiki/Dicyclic_group * https://en.wikipedia.org/wiki/Quaternion_group ## TODO Show that `QuaternionGroup 2 ≃* (Quaternion ℤ)ˣ`. -/ /-- The (generalised) quaternion group `QuaternionGroup n` of order `4n`. It can be defined by the presentation $\langle a, x \| a^{2n} = 1, x^2 = a^n, x^{-1}ax=a^{-1}\rangle$. We write `a i` for $a^i$ and `xa i` for $x * a^i$. -/ inductive QuaternionGroup (n : ℕ) : Type \| a : ZMod (2 * n) → QuaternionGroup n \| xa : ZMod (2 * n) → QuaternionGroup n deriving DecidableEq namespace QuaternionGroup variable {n : ℕ} /-- Multiplication of the dihedral group. -/ private def mul : QuaternionGroup n → QuaternionGroup n → QuaternionGroup n \| a i, a j => a (i + j) \| a i, xa j => xa (j - i) \| xa i, a j => xa (i + j) \| xa i, xa j => a (n + j - i) /-- The identity `1` is given by `aⁱ`. -/ private def one : QuaternionGroup n := a 0 instance : Inhabited (QuaternionGroup n) := ⟨one⟩ /-- The inverse of an element of the quaternion group. -/ private def inv : QuaternionGroup n → QuaternionGroup n \| a i => a (-i) \| xa i => xa (n + i) /-- The group structure on `QuaternionGroup n`. -/ instance : Group (QuaternionGroup n) where mul := mul mul_assoc := by rintro (i \| i) (j \| j) (k \| k) <;> simp only [(· * ·), mul] <;> ring_nf congr calc -(n : ZMod (2 * n)) = 0 - n := by rw [zero_sub] _ = 2 * n - n := by norm_cast; simp _ = n := by ring one := one one_mul := by rintro (i \| i) · exact congr_arg a (zero_add i) · exact congr_arg xa (sub_zero i) mul_one := by rintro (i \| i) · exact congr_arg a (add_zero i) · exact congr_arg xa (add_zero i) inv := inv inv_mul_cancel := by rintro (i \| i) · exact congr_arg a (neg_add_cancel i) · exact congr_arg a (sub_self (n + i)) @[simp] theorem a_mul_a (i j : ZMod (2 * n)) : a i * a j = a (i + j) := rfl @[simp] theorem a_mul_xa (i j : ZMod (2 * n)) : a i * xa j = xa (j - i) := rfl @[simp] theorem xa_mul_a (i j : ZMod (2 * n)) : xa i * a j = xa (i + j) := rfl @[simp] theorem xa_mul_xa (i j : ZMod (2 * n)) : xa i * xa j = a ((n : ZMod (2 * n)) + j - i) := rfl @[simp] theorem a_zero : a 0 = (1 : QuaternionGroup n) := by rfl theorem one_def : (1 : QuaternionGroup n) = a 0 := rfl private def fintypeHelper : ZMod (2 * n) ⊕ ZMod (2 * n) ≃ QuaternionGroup n where invFun i := match i with \| a j => Sum.inl j \| xa j => Sum.inr j toFun i := match i with \| Sum.inl j => a j \| Sum.inr j => xa j left_inv := by rintro (x \| x) <;> rfl right_inv := by rintro (x \| x) <;> rfl /-- The special case that more or less by definition `QuaternionGroup 0` is isomorphic to the infinite dihedral group. -/ def quaternionGroupZeroEquivDihedralGroupZero : QuaternionGroup 0 ≃* DihedralGroup 0 where toFun \| a j => DihedralGroup.r j \| xa j => DihedralGroup.sr j invFun \| DihedralGroup.r j => a j \| DihedralGroup.sr j => xa j left_inv := by rintro (k \| k) <;> rfl right_inv := by rintro (k \| k) <;> rfl map_mul' := by rintro (k \| k) (l \| l) <;> simp /-- If `0 < n`, then `QuaternionGroup n` is a finite group. -/ instance [NeZero n] : Fintype (QuaternionGroup n) := Fintype.ofEquiv _ fintypeHelper instance : Nontrivial (QuaternionGroup n) := ⟨⟨a 0, xa 0, by simp [← a_zero]⟩⟩ /-- If `0 < n`, then `QuaternionGroup n` has `4n` elements. -/ theorem card [NeZero n] : Fintype.card (QuaternionGroup n) = 4 * n := by rw [← Fintype.card_eq.mpr ⟨fintypeHelper⟩, Fintype.card_sum, ZMod.card, two_mul] ring @[simp] theorem a_one_pow (k : ℕ) : (a 1 : QuaternionGroup n) ^ k = a k := by induction' k with k IH · rw [Nat.cast_zero]; rfl · rw [pow_succ, IH, a_mul_a] congr 1 norm_cast theorem a_one_pow_n : (a 1 : QuaternionGroup n) ^ (2 * n) = 1 := by simp @[simp] theorem xa_sq (i : ZMod (2 * n)) : xa i ^ 2 = a n := by simp [sq] @[simp] theorem xa_pow_four (i : ZMod (2 * n)) : xa i ^ 4 = 1 := by calc xa i ^ 4 = a (n + n) := by simp [pow_succ, add_sub_assoc, sub_sub_cancel] _ = a ↑(2 * n) := by simp [Nat.cast_add, two_mul] _ = 1 := by simp /-- If `0 < n`, then `xa i` has order 4.	-/ @[simp] theorem orderOf_xa [NeZero n] (i : ZMod (2 * n)) : orderOf (xa i) = 4 := by change _ = 2 ^ 2	Mathlib/GroupTheory/SpecificGroups/Quaternion.lean	189	192
/- 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.MeasureTheory.Constructions.BorelSpace.Order import Mathlib.MeasureTheory.Measure.Count import Mathlib.Order.Filter.ENNReal import Mathlib.Probability.UniformOn /-! # Essential supremum and infimum We define the essential supremum and infimum of a function `f : α → β` with respect to a measure `μ` on `α`. The essential supremum is the infimum of the constants `c : β` such that `f x ≤ c` almost everywhere. TODO: The essential supremum of functions `α → ℝ≥0∞` is used in particular to define the norm in the `L∞` space (see `Mathlib.MeasureTheory.Function.LpSpace`). There is a different quantity which is sometimes also called essential supremum: the least upper-bound among measurable functions of a family of measurable functions (in an almost-everywhere sense). We do not define that quantity here, which is simply the supremum of a map with values in `α →ₘ[μ] β` (see `Mathlib.MeasureTheory.Function.AEEqFun`). ## Main definitions * `essSup f μ := (ae μ).limsup f` * `essInf f μ := (ae μ).liminf f` -/ open Filter MeasureTheory ProbabilityTheory Set TopologicalSpace open scoped ENNReal NNReal variable {α β : Type} {m : MeasurableSpace α} {μ ν : Measure α} section ConditionallyCompleteLattice variable [ConditionallyCompleteLattice β] {f : α → β} /-- Essential supremum of `f` with respect to measure `μ`: the smallest `c : β` such that `f x ≤ c` a.e. -/ def essSup {_ : MeasurableSpace α} (f : α → β) (μ : Measure α) := (ae μ).limsup f /-- Essential infimum of `f` with respect to measure `μ`: the greatest `c : β` such that `c ≤ f x` a.e. -/ def essInf {_ : MeasurableSpace α} (f : α → β) (μ : Measure α) := (ae μ).liminf f theorem essSup_congr_ae {f g : α → β} (hfg : f =ᵐ[μ] g) : essSup f μ = essSup g μ := limsup_congr hfg theorem essInf_congr_ae {f g : α → β} (hfg : f =ᵐ[μ] g) : essInf f μ = essInf g μ := @essSup_congr_ae α βᵒᵈ _ _ _ _ _ hfg @[simp] theorem essSup_const' [NeZero μ] (c : β) : essSup (fun _ : α => c) μ = c := limsup_const _ @[simp] theorem essInf_const' [NeZero μ] (c : β) : essInf (fun _ : α => c) μ = c := liminf_const _ theorem essSup_const (c : β) (hμ : μ ≠ 0) : essSup (fun _ : α => c) μ = c := have := NeZero.mk hμ; essSup_const' _ theorem essInf_const (c : β) (hμ : μ ≠ 0) : essInf (fun _ : α => c) μ = c := have := NeZero.mk hμ; essInf_const' _ section SMul variable {R : Type} [Zero R] [SMulWithZero R ℝ≥0∞] [IsScalarTower R ℝ≥0∞ ℝ≥0∞] [NoZeroSMulDivisors R ℝ≥0∞] {c : R} @[simp] lemma essSup_smul_measure (hc : c ≠ 0) (f : α → β) : essSup f (c • μ) = essSup f μ := by simp_rw [essSup, Measure.ae_smul_measure_eq hc] end SMul variable [Nonempty α] lemma essSup_eq_ciSup (hμ : ∀ a, μ {a} ≠ 0) (hf : BddAbove (Set.range f)) : essSup f μ = ⨆ a, f a := by rw [essSup, ae_eq_top.2 hμ, limsup_top_eq_ciSup hf] lemma essInf_eq_ciInf (hμ : ∀ a, μ {a} ≠ 0) (hf : BddBelow (Set.range f)) : essInf f μ = ⨅ a, f a := by rw [essInf, ae_eq_top.2 hμ, liminf_top_eq_ciInf hf] variable [MeasurableSingletonClass α] @[simp] lemma essSup_count_eq_ciSup (hf : BddAbove (Set.range f)) : essSup f .count = ⨆ a, f a := essSup_eq_ciSup (by simp) hf @[simp] lemma essInf_count_eq_ciInf (hf : BddBelow (Set.range f)) : essInf f .count = ⨅ a, f a := essInf_eq_ciInf (by simp) hf @[simp] lemma essSup_uniformOn_eq_ciSup [Finite α] (hf : BddAbove (Set.range f)) : essSup f (uniformOn univ) = ⨆ a, f a := essSup_eq_ciSup (by simpa [uniformOn, cond_apply]) hf @[simp] lemma essInf_cond_count_eq_ciInf [Finite α] (hf : BddBelow (Set.range f)) : essInf f (uniformOn univ) = ⨅ a, f a := essInf_eq_ciInf (by simpa [uniformOn, cond_apply]) hf end ConditionallyCompleteLattice section ConditionallyCompleteLinearOrder variable [ConditionallyCompleteLinearOrder β] {x : β} {f : α → β} theorem essSup_eq_sInf {m : MeasurableSpace α} (μ : Measure α) (f : α → β) : essSup f μ = sInf { a \| μ { x \| a < f x } = 0 } := by dsimp [essSup, limsup, limsSup] simp only [eventually_map, ae_iff, not_le] theorem essInf_eq_sSup {m : MeasurableSpace α} (μ : Measure α) (f : α → β) : essInf f μ = sSup { a \| μ { x \| f x < a } = 0 } := by dsimp [essInf, liminf, limsInf] simp only [eventually_map, ae_iff, not_le] theorem ae_lt_of_essSup_lt (hx : essSup f μ < x) (hf : IsBoundedUnder (· ≤ ·) (ae μ) f := by isBoundedDefault) : ∀ᵐ y ∂μ, f y < x := eventually_lt_of_limsup_lt hx hf theorem ae_lt_of_lt_essInf (hx : x < essInf f μ) (hf : IsBoundedUnder (· ≥ ·) (ae μ) f := by isBoundedDefault) : ∀ᵐ y ∂μ, x < f y := eventually_lt_of_lt_liminf hx hf variable [TopologicalSpace β] [FirstCountableTopology β] [OrderTopology β] theorem ae_le_essSup (hf : IsBoundedUnder (· ≤ ·) (ae μ) f := by isBoundedDefault) : ∀ᵐ y ∂μ, f y ≤ essSup f μ := eventually_le_limsup hf theorem ae_essInf_le (hf : IsBoundedUnder (· ≥ ·) (ae μ) f := by isBoundedDefault) : ∀ᵐ y ∂μ, essInf f μ ≤ f y := eventually_liminf_le hf theorem meas_essSup_lt (hf : IsBoundedUnder (· ≤ ·) (ae μ) f := by isBoundedDefault) :	μ { y \| essSup f μ < f y } = 0 := by simp_rw [← not_le]	Mathlib/MeasureTheory/Function/EssSup.lean	145	146
/- 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 rw [norm_cpow_eq_rpow_re_of_pos ht] lemma norm_natCast_cpow_of_re_ne_zero (n : ℕ) {s : ℂ} (hs : s.re ≠ 0) : ‖(n : ℂ) ^ s‖ = (n : ℝ) ^ (s.re) := by rw [← ofReal_natCast, norm_cpow_eq_rpow_re_of_nonneg n.cast_nonneg hs] lemma norm_natCast_cpow_of_pos {n : ℕ} (hn : 0 < n) (s : ℂ) : ‖(n : ℂ) ^ s‖ = (n : ℝ) ^ (s.re) := by rw [← ofReal_natCast, norm_cpow_eq_rpow_re_of_pos (Nat.cast_pos.mpr hn) _] lemma norm_natCast_cpow_pos_of_pos {n : ℕ} (hn : 0 < n) (s : ℂ) : 0 < ‖(n : ℂ) ^ s‖ := (norm_natCast_cpow_of_pos hn _).symm ▸ Real.rpow_pos_of_pos (Nat.cast_pos.mpr hn) _ theorem cpow_mul_ofReal_nonneg {x : ℝ} (hx : 0 ≤ x) (y : ℝ) (z : ℂ) : (x : ℂ) ^ (↑y z) = (↑(x ^ y) : ℂ) ^ z := by rw [cpow_mul, ofReal_cpow hx] · rw [← ofReal_log hx, ← ofReal_mul, ofReal_im, neg_lt_zero]; exact Real.pi_pos · rw [← ofReal_log hx, ← ofReal_mul, ofReal_im]; exact Real.pi_pos.le end Complex /-! ### Positivity extension -/ namespace Mathlib.Meta.Positivity open Lean Meta Qq /-- Extension for the `positivity` tactic: exponentiation by a real number is positive (namely 1) when the exponent is zero. The other cases are done in `evalRpow`. -/ @[positivity (_ : ℝ) ^ (0 : ℝ)] def evalRpowZero : PositivityExt where eval {u α} _ _ e := do match u, α, e with \| 0, ~q(ℝ), ~q($a ^ (0 : ℝ)) => assertInstancesCommute pure (.positive q(Real.rpow_zero_pos $a)) \| _, _, _ => throwError "not Real.rpow" /-- Extension for the `positivity` tactic: exponentiation by a real number is nonnegative when the base is nonnegative and positive when the base is positive. -/ @[positivity (_ : ℝ) ^ (_ : ℝ)] def evalRpow : PositivityExt where eval {u α} _zα _pα e := do match u, α, e with \| 0, ~q(ℝ), ~q($a ^ ($b : ℝ)) => let ra ← core q(inferInstance) q(inferInstance) a assertInstancesCommute match ra with \| .positive pa => pure (.positive q(Real.rpow_pos_of_pos $pa $b)) \| .nonnegative pa => pure (.nonnegative q(Real.rpow_nonneg $pa $b)) \| _ => pure .none \| _, _, _ => throwError "not Real.rpow" end Mathlib.Meta.Positivity /-! ## Further algebraic properties of `rpow` -/ namespace Real variable {x y z : ℝ} {n : ℕ} theorem rpow_mul {x : ℝ} (hx : 0 ≤ x) (y z : ℝ) : x ^ (y * z) = (x ^ y) ^ z := by rw [← Complex.ofReal_inj, Complex.ofReal_cpow (rpow_nonneg hx _), Complex.ofReal_cpow hx, Complex.ofReal_mul, Complex.cpow_mul, Complex.ofReal_cpow hx] <;> simp only [(Complex.ofReal_mul _ _).symm, (Complex.ofReal_log hx).symm, Complex.ofReal_im, neg_lt_zero, pi_pos, le_of_lt pi_pos] lemma rpow_pow_comm {x : ℝ} (hx : 0 ≤ x) (y : ℝ) (n : ℕ) : (x ^ y) ^ n = (x ^ n) ^ y := by simp_rw [← rpow_natCast, ← rpow_mul hx, mul_comm y] lemma rpow_zpow_comm {x : ℝ} (hx : 0 ≤ x) (y : ℝ) (n : ℤ) : (x ^ y) ^ n = (x ^ n) ^ y := by simp_rw [← rpow_intCast, ← rpow_mul hx, mul_comm y] lemma rpow_add_intCast {x : ℝ} (hx : x ≠ 0) (y : ℝ) (n : ℤ) : x ^ (y + n) = x ^ y * x ^ n := by rw [rpow_def, rpow_def, Complex.ofReal_add, Complex.cpow_add _ _ (Complex.ofReal_ne_zero.mpr hx), Complex.ofReal_intCast, Complex.cpow_intCast, ← Complex.ofReal_zpow, mul_comm, Complex.re_ofReal_mul, mul_comm] lemma rpow_add_natCast {x : ℝ} (hx : x ≠ 0) (y : ℝ) (n : ℕ) : x ^ (y + n) = x ^ y * x ^ n := by simpa using rpow_add_intCast hx y n lemma rpow_sub_intCast {x : ℝ} (hx : x ≠ 0) (y : ℝ) (n : ℕ) : x ^ (y - n) = x ^ y / x ^ n := by simpa using rpow_add_intCast hx y (-n) lemma rpow_sub_natCast {x : ℝ} (hx : x ≠ 0) (y : ℝ) (n : ℕ) : x ^ (y - n) = x ^ y / x ^ n := by simpa using rpow_sub_intCast hx y n lemma rpow_add_intCast' (hx : 0 ≤ x) {n : ℤ} (h : y + n ≠ 0) : x ^ (y + n) = x ^ y * x ^ n := by rw [rpow_add' hx h, rpow_intCast] lemma rpow_add_natCast' (hx : 0 ≤ x) (h : y + n ≠ 0) : x ^ (y + n) = x ^ y * x ^ n := by rw [rpow_add' hx h, rpow_natCast] lemma rpow_sub_intCast' (hx : 0 ≤ x) {n : ℤ} (h : y - n ≠ 0) : x ^ (y - n) = x ^ y / x ^ n := by rw [rpow_sub' hx h, rpow_intCast] lemma rpow_sub_natCast' (hx : 0 ≤ x) (h : y - n ≠ 0) : x ^ (y - n) = x ^ y / x ^ n := by rw [rpow_sub' hx h, rpow_natCast] theorem rpow_add_one {x : ℝ} (hx : x ≠ 0) (y : ℝ) : x ^ (y + 1) = x ^ y * x := by simpa using rpow_add_natCast hx y 1 theorem rpow_sub_one {x : ℝ} (hx : x ≠ 0) (y : ℝ) : x ^ (y - 1) = x ^ y / x := by simpa using rpow_sub_natCast hx y 1 lemma rpow_add_one' (hx : 0 ≤ x) (h : y + 1 ≠ 0) : x ^ (y + 1) = x ^ y * x := by rw [rpow_add' hx h, rpow_one] lemma rpow_one_add' (hx : 0 ≤ x) (h : 1 + y ≠ 0) : x ^ (1 + y) = x * x ^ y := by rw [rpow_add' hx h, rpow_one] lemma rpow_sub_one' (hx : 0 ≤ x) (h : y - 1 ≠ 0) : x ^ (y - 1) = x ^ y / x := by rw [rpow_sub' hx h, rpow_one] lemma rpow_one_sub' (hx : 0 ≤ x) (h : 1 - y ≠ 0) : x ^ (1 - y) = x / x ^ y := by rw [rpow_sub' hx h, rpow_one] @[simp] theorem rpow_two (x : ℝ) : x ^ (2 : ℝ) = x ^ 2 := by rw [← rpow_natCast] simp only [Nat.cast_ofNat] theorem rpow_neg_one (x : ℝ) : x ^ (-1 : ℝ) = x⁻¹ := by suffices H : x ^ ((-1 : ℤ) : ℝ) = x⁻¹ by rwa [Int.cast_neg, Int.cast_one] at H simp only [rpow_intCast, zpow_one, zpow_neg] theorem mul_rpow (hx : 0 ≤ x) (hy : 0 ≤ y) : (x * y) ^ z = x ^ z * y ^ z := by iterate 2 rw [Real.rpow_def_of_nonneg]; split_ifs with h_ifs <;> simp_all · rw [log_mul ‹_› ‹_›, add_mul, exp_add, rpow_def_of_pos (hy.lt_of_ne' ‹_›)] all_goals positivity theorem inv_rpow (hx : 0 ≤ x) (y : ℝ) : x⁻¹ ^ y = (x ^ y)⁻¹ := by simp only [← rpow_neg_one, ← rpow_mul hx, mul_comm] theorem div_rpow (hx : 0 ≤ x) (hy : 0 ≤ y) (z : ℝ) : (x / y) ^ z = x ^ z / y ^ z := by simp only [div_eq_mul_inv, mul_rpow hx (inv_nonneg.2 hy), inv_rpow hy] theorem log_rpow {x : ℝ} (hx : 0 < x) (y : ℝ) : log (x ^ y) = y * log x := by apply exp_injective rw [exp_log (rpow_pos_of_pos hx y), ← exp_log hx, mul_comm, rpow_def_of_pos (exp_pos (log x)) y] theorem mul_log_eq_log_iff {x y z : ℝ} (hx : 0 < x) (hz : 0 < z) : y * log x = log z ↔ x ^ y = z := ⟨fun h ↦ log_injOn_pos (rpow_pos_of_pos hx _) hz <\| log_rpow hx _ \|>.trans h, by rintro rfl; rw [log_rpow hx]⟩ @[simp] lemma rpow_rpow_inv (hx : 0 ≤ x) (hy : y ≠ 0) : (x ^ y) ^ y⁻¹ = x := by rw [← rpow_mul hx, mul_inv_cancel₀ hy, rpow_one] @[simp] lemma rpow_inv_rpow (hx : 0 ≤ x) (hy : y ≠ 0) : (x ^ y⁻¹) ^ y = x := by rw [← rpow_mul hx, inv_mul_cancel₀ hy, rpow_one] theorem pow_rpow_inv_natCast (hx : 0 ≤ x) (hn : n ≠ 0) : (x ^ n) ^ (n⁻¹ : ℝ) = x := by have hn0 : (n : ℝ) ≠ 0 := Nat.cast_ne_zero.2 hn rw [← rpow_natCast, ← rpow_mul hx, mul_inv_cancel₀ hn0, rpow_one] theorem rpow_inv_natCast_pow (hx : 0 ≤ x) (hn : n ≠ 0) : (x ^ (n⁻¹ : ℝ)) ^ n = x := by have hn0 : (n : ℝ) ≠ 0 := Nat.cast_ne_zero.2 hn rw [← rpow_natCast, ← rpow_mul hx, inv_mul_cancel₀ hn0, rpow_one] lemma rpow_natCast_mul (hx : 0 ≤ x) (n : ℕ) (z : ℝ) : x ^ (n * z) = (x ^ n) ^ z := by rw [rpow_mul hx, rpow_natCast] lemma rpow_mul_natCast (hx : 0 ≤ x) (y : ℝ) (n : ℕ) : x ^ (y * n) = (x ^ y) ^ n := by rw [rpow_mul hx, rpow_natCast] lemma rpow_intCast_mul (hx : 0 ≤ x) (n : ℤ) (z : ℝ) : x ^ (n * z) = (x ^ n) ^ z := by rw [rpow_mul hx, rpow_intCast] lemma rpow_mul_intCast (hx : 0 ≤ x) (y : ℝ) (n : ℤ) : x ^ (y * n) = (x ^ y) ^ n := by rw [rpow_mul hx, rpow_intCast] /-! Note: lemmas about `(∏ i ∈ s, f i ^ r)` such as `Real.finset_prod_rpow` are proved in `Mathlib/Analysis/SpecialFunctions/Pow/NNReal.lean` instead. -/ /-! ## Order and monotonicity -/ @[gcongr, bound] theorem rpow_lt_rpow (hx : 0 ≤ x) (hxy : x < y) (hz : 0 < z) : x ^ z < y ^ z := by rw [le_iff_eq_or_lt] at hx; rcases hx with hx \| hx · rw [← hx, zero_rpow (ne_of_gt hz)] exact rpow_pos_of_pos (by rwa [← hx] at hxy) _ · rw [rpow_def_of_pos hx, rpow_def_of_pos (lt_trans hx hxy), exp_lt_exp] exact mul_lt_mul_of_pos_right (log_lt_log hx hxy) hz theorem strictMonoOn_rpow_Ici_of_exponent_pos {r : ℝ} (hr : 0 < r) : StrictMonoOn (fun (x : ℝ) => x ^ r) (Set.Ici 0) := fun _ ha _ _ hab => rpow_lt_rpow ha hab hr @[gcongr, bound] theorem rpow_le_rpow {x y z : ℝ} (h : 0 ≤ x) (h₁ : x ≤ y) (h₂ : 0 ≤ z) : x ^ z ≤ y ^ z := by rcases eq_or_lt_of_le h₁ with (rfl \| h₁'); · rfl rcases eq_or_lt_of_le h₂ with (rfl \| h₂'); · simp exact le_of_lt (rpow_lt_rpow h h₁' h₂') theorem monotoneOn_rpow_Ici_of_exponent_nonneg {r : ℝ} (hr : 0 ≤ r) : MonotoneOn (fun (x : ℝ) => x ^ r) (Set.Ici 0) := fun _ ha _ _ hab => rpow_le_rpow ha hab hr lemma rpow_lt_rpow_of_neg (hx : 0 < x) (hxy : x < y) (hz : z < 0) : y ^ z < x ^ z := by have := hx.trans hxy rw [← inv_lt_inv₀, ← rpow_neg, ← rpow_neg] on_goal 1 => refine rpow_lt_rpow ?_ hxy (neg_pos.2 hz) all_goals positivity lemma rpow_le_rpow_of_nonpos (hx : 0 < x) (hxy : x ≤ y) (hz : z ≤ 0) : y ^ z ≤ x ^ z := by have := hx.trans_le hxy rw [← inv_le_inv₀, ← rpow_neg, ← rpow_neg] on_goal 1 => refine rpow_le_rpow ?_ hxy (neg_nonneg.2 hz) all_goals positivity theorem rpow_lt_rpow_iff (hx : 0 ≤ x) (hy : 0 ≤ y) (hz : 0 < z) : x ^ z < y ^ z ↔ x < y := ⟨lt_imp_lt_of_le_imp_le fun h => rpow_le_rpow hy h (le_of_lt hz), fun h => rpow_lt_rpow hx h hz⟩ theorem rpow_le_rpow_iff (hx : 0 ≤ x) (hy : 0 ≤ y) (hz : 0 < z) : x ^ z ≤ y ^ z ↔ x ≤ y := le_iff_le_iff_lt_iff_lt.2 <\| rpow_lt_rpow_iff hy hx hz lemma rpow_lt_rpow_iff_of_neg (hx : 0 < x) (hy : 0 < y) (hz : z < 0) : x ^ z < y ^ z ↔ y < x := ⟨lt_imp_lt_of_le_imp_le fun h ↦ rpow_le_rpow_of_nonpos hx h hz.le, fun h ↦ rpow_lt_rpow_of_neg hy h hz⟩ lemma rpow_le_rpow_iff_of_neg (hx : 0 < x) (hy : 0 < y) (hz : z < 0) : x ^ z ≤ y ^ z ↔ y ≤ x := le_iff_le_iff_lt_iff_lt.2 <\| rpow_lt_rpow_iff_of_neg hy hx hz lemma le_rpow_inv_iff_of_pos (hx : 0 ≤ x) (hy : 0 ≤ y) (hz : 0 < z) : x ≤ y ^ z⁻¹ ↔ x ^ z ≤ y := by rw [← rpow_le_rpow_iff hx _ hz, rpow_inv_rpow] <;> positivity lemma rpow_inv_le_iff_of_pos (hx : 0 ≤ x) (hy : 0 ≤ y) (hz : 0 < z) : x ^ z⁻¹ ≤ y ↔ x ≤ y ^ z := by rw [← rpow_le_rpow_iff _ hy hz, rpow_inv_rpow] <;> positivity lemma lt_rpow_inv_iff_of_pos (hx : 0 ≤ x) (hy : 0 ≤ y) (hz : 0 < z) : x < y ^ z⁻¹ ↔ x ^ z < y := lt_iff_lt_of_le_iff_le <\| rpow_inv_le_iff_of_pos hy hx hz lemma rpow_inv_lt_iff_of_pos (hx : 0 ≤ x) (hy : 0 ≤ y) (hz : 0 < z) : x ^ z⁻¹ < y ↔ x < y ^ z := lt_iff_lt_of_le_iff_le <\| le_rpow_inv_iff_of_pos hy hx hz theorem le_rpow_inv_iff_of_neg (hx : 0 < x) (hy : 0 < y) (hz : z < 0) : x ≤ y ^ z⁻¹ ↔ y ≤ x ^ z := by rw [← rpow_le_rpow_iff_of_neg _ hx hz, rpow_inv_rpow _ hz.ne] <;> positivity theorem lt_rpow_inv_iff_of_neg (hx : 0 < x) (hy : 0 < y) (hz : z < 0) : x < y ^ z⁻¹ ↔ y < x ^ z := by rw [← rpow_lt_rpow_iff_of_neg _ hx hz, rpow_inv_rpow _ hz.ne] <;> positivity theorem rpow_inv_lt_iff_of_neg (hx : 0 < x) (hy : 0 < y) (hz : z < 0) : x ^ z⁻¹ < y ↔ y ^ z < x := by rw [← rpow_lt_rpow_iff_of_neg hy _ hz, rpow_inv_rpow _ hz.ne] <;> positivity theorem rpow_inv_le_iff_of_neg (hx : 0 < x) (hy : 0 < y) (hz : z < 0) : x ^ z⁻¹ ≤ y ↔ y ^ z ≤ x := by rw [← rpow_le_rpow_iff_of_neg hy _ hz, rpow_inv_rpow _ hz.ne] <;> positivity theorem rpow_lt_rpow_of_exponent_lt (hx : 1 < x) (hyz : y < z) : x ^ y < x ^ z := by repeat' rw [rpow_def_of_pos (lt_trans zero_lt_one hx)] rw [exp_lt_exp]; exact mul_lt_mul_of_pos_left hyz (log_pos hx) @[gcongr] theorem rpow_le_rpow_of_exponent_le (hx : 1 ≤ x) (hyz : y ≤ z) : x ^ y ≤ x ^ z := by repeat' rw [rpow_def_of_pos (lt_of_lt_of_le zero_lt_one hx)] rw [exp_le_exp]; exact mul_le_mul_of_nonneg_left hyz (log_nonneg hx) theorem rpow_lt_rpow_of_exponent_neg {x y z : ℝ} (hy : 0 < y) (hxy : y < x) (hz : z < 0) : x ^ z < y ^ z := by have hx : 0 < x := hy.trans hxy rw [← neg_neg z, Real.rpow_neg (le_of_lt hx) (-z), Real.rpow_neg (le_of_lt hy) (-z), inv_lt_inv₀ (rpow_pos_of_pos hx _) (rpow_pos_of_pos hy _)] exact Real.rpow_lt_rpow (by positivity) hxy <\| neg_pos_of_neg hz theorem strictAntiOn_rpow_Ioi_of_exponent_neg {r : ℝ} (hr : r < 0) : StrictAntiOn (fun (x : ℝ) => x ^ r) (Set.Ioi 0) := fun _ ha _ _ hab => rpow_lt_rpow_of_exponent_neg ha hab hr theorem rpow_le_rpow_of_exponent_nonpos {x y : ℝ} (hy : 0 < y) (hxy : y ≤ x) (hz : z ≤ 0) : x ^ z ≤ y ^ z := by rcases ne_or_eq z 0 with hz_zero \| rfl case inl => rcases ne_or_eq x y with hxy' \| rfl case inl => exact le_of_lt <\| rpow_lt_rpow_of_exponent_neg hy (Ne.lt_of_le (id (Ne.symm hxy')) hxy) (Ne.lt_of_le hz_zero hz) case inr => simp case inr => simp theorem antitoneOn_rpow_Ioi_of_exponent_nonpos {r : ℝ} (hr : r ≤ 0) : AntitoneOn (fun (x : ℝ) => x ^ r) (Set.Ioi 0) := fun _ ha _ _ hab => rpow_le_rpow_of_exponent_nonpos ha hab hr @[simp] theorem rpow_le_rpow_left_iff (hx : 1 < x) : x ^ y ≤ x ^ z ↔ y ≤ z := by have x_pos : 0 < x := lt_trans zero_lt_one hx rw [← log_le_log_iff (rpow_pos_of_pos x_pos y) (rpow_pos_of_pos x_pos z), log_rpow x_pos, log_rpow x_pos, mul_le_mul_right (log_pos hx)] @[simp] theorem rpow_lt_rpow_left_iff (hx : 1 < x) : x ^ y < x ^ z ↔ y < z := by rw [lt_iff_not_le, rpow_le_rpow_left_iff hx, lt_iff_not_le] theorem rpow_lt_rpow_of_exponent_gt (hx0 : 0 < x) (hx1 : x < 1) (hyz : z < y) : x ^ y < x ^ z := by repeat' rw [rpow_def_of_pos hx0] rw [exp_lt_exp]; exact mul_lt_mul_of_neg_left hyz (log_neg hx0 hx1) theorem rpow_le_rpow_of_exponent_ge (hx0 : 0 < x) (hx1 : x ≤ 1) (hyz : z ≤ y) : x ^ y ≤ x ^ z := by repeat' rw [rpow_def_of_pos hx0] rw [exp_le_exp]; exact mul_le_mul_of_nonpos_left hyz (log_nonpos (le_of_lt hx0) hx1) @[simp] theorem rpow_le_rpow_left_iff_of_base_lt_one (hx0 : 0 < x) (hx1 : x < 1) : x ^ y ≤ x ^ z ↔ z ≤ y := by rw [← log_le_log_iff (rpow_pos_of_pos hx0 y) (rpow_pos_of_pos hx0 z), log_rpow hx0, log_rpow hx0, mul_le_mul_right_of_neg (log_neg hx0 hx1)] @[simp] theorem rpow_lt_rpow_left_iff_of_base_lt_one (hx0 : 0 < x) (hx1 : x < 1) : x ^ y < x ^ z ↔ z < y := by rw [lt_iff_not_le, rpow_le_rpow_left_iff_of_base_lt_one hx0 hx1, lt_iff_not_le] theorem rpow_lt_one {x z : ℝ} (hx1 : 0 ≤ x) (hx2 : x < 1) (hz : 0 < z) : x ^ z < 1 := by rw [← one_rpow z] exact rpow_lt_rpow hx1 hx2 hz theorem rpow_le_one {x z : ℝ} (hx1 : 0 ≤ x) (hx2 : x ≤ 1) (hz : 0 ≤ z) : x ^ z ≤ 1 := by rw [← one_rpow z] exact rpow_le_rpow hx1 hx2 hz theorem rpow_lt_one_of_one_lt_of_neg {x z : ℝ} (hx : 1 < x) (hz : z < 0) : x ^ z < 1 := by convert rpow_lt_rpow_of_exponent_lt hx hz exact (rpow_zero x).symm theorem rpow_le_one_of_one_le_of_nonpos {x z : ℝ} (hx : 1 ≤ x) (hz : z ≤ 0) : x ^ z ≤ 1 := by convert rpow_le_rpow_of_exponent_le hx hz exact (rpow_zero x).symm theorem one_lt_rpow {x z : ℝ} (hx : 1 < x) (hz : 0 < z) : 1 < x ^ z := by rw [← one_rpow z] exact rpow_lt_rpow zero_le_one hx hz theorem one_le_rpow {x z : ℝ} (hx : 1 ≤ x) (hz : 0 ≤ z) : 1 ≤ x ^ z := by rw [← one_rpow z] exact rpow_le_rpow zero_le_one hx hz theorem one_lt_rpow_of_pos_of_lt_one_of_neg (hx1 : 0 < x) (hx2 : x < 1) (hz : z < 0) : 1 < x ^ z := by convert rpow_lt_rpow_of_exponent_gt hx1 hx2 hz exact (rpow_zero x).symm theorem one_le_rpow_of_pos_of_le_one_of_nonpos (hx1 : 0 < x) (hx2 : x ≤ 1) (hz : z ≤ 0) : 1 ≤ x ^ z := by convert rpow_le_rpow_of_exponent_ge hx1 hx2 hz exact (rpow_zero x).symm theorem rpow_lt_one_iff_of_pos (hx : 0 < x) : x ^ y < 1 ↔ 1 < x ∧ y < 0 ∨ x < 1 ∧ 0 < y := by rw [rpow_def_of_pos hx, exp_lt_one_iff, mul_neg_iff, log_pos_iff hx.le, log_neg_iff hx] theorem rpow_lt_one_iff (hx : 0 ≤ x) : x ^ y < 1 ↔ x = 0 ∧ y ≠ 0 ∨ 1 < x ∧ y < 0 ∨ x < 1 ∧ 0 < y := by rcases hx.eq_or_lt with (rfl \| hx) · rcases _root_.em (y = 0) with (rfl \| hy) <;> simp [, lt_irrefl, zero_lt_one] · simp [rpow_lt_one_iff_of_pos hx, hx.ne.symm] theorem rpow_lt_one_iff' {x y : ℝ} (hx : 0 ≤ x) (hy : 0 < y) : x ^ y < 1 ↔ x < 1 := by rw [← Real.rpow_lt_rpow_iff hx zero_le_one hy, Real.one_rpow] theorem one_lt_rpow_iff_of_pos (hx : 0 < x) : 1 < x ^ y ↔ 1 < x ∧ 0 < y ∨ x < 1 ∧ y < 0 := by rw [rpow_def_of_pos hx, one_lt_exp_iff, mul_pos_iff, log_pos_iff hx.le, log_neg_iff hx] theorem one_lt_rpow_iff (hx : 0 ≤ x) : 1 < x ^ y ↔ 1 < x ∧ 0 < y ∨ 0 < x ∧ x < 1 ∧ y < 0 := by rcases hx.eq_or_lt with (rfl \| hx) · rcases _root_.em (y = 0) with (rfl \| hy) <;> simp [, lt_irrefl, (zero_lt_one' ℝ).not_lt] · simp [one_lt_rpow_iff_of_pos hx, hx] /-- This is a more general but less convenient version of `rpow_le_rpow_of_exponent_ge`. This version allows `x = 0`, so it explicitly forbids `x = y = 0`, `z ≠ 0`. -/ theorem rpow_le_rpow_of_exponent_ge_of_imp (hx0 : 0 ≤ x) (hx1 : x ≤ 1) (hyz : z ≤ y) (h : x = 0 → y = 0 → z = 0) : x ^ y ≤ x ^ z := by rcases eq_or_lt_of_le hx0 with (rfl \| hx0') · rcases eq_or_ne y 0 with rfl \| hy0 · rw [h rfl rfl] · rw [zero_rpow hy0] apply zero_rpow_nonneg · exact rpow_le_rpow_of_exponent_ge hx0' hx1 hyz /-- This version of `rpow_le_rpow_of_exponent_ge` allows `x = 0` but requires `0 ≤ z`. See also `rpow_le_rpow_of_exponent_ge_of_imp` for the most general version. -/ theorem rpow_le_rpow_of_exponent_ge' (hx0 : 0 ≤ x) (hx1 : x ≤ 1) (hz : 0 ≤ z) (hyz : z ≤ y) : x ^ y ≤ x ^ z := rpow_le_rpow_of_exponent_ge_of_imp hx0 hx1 hyz fun _ hy ↦ le_antisymm (hyz.trans_eq hy) hz lemma rpow_max {x y p : ℝ} (hx : 0 ≤ x) (hy : 0 ≤ y) (hp : 0 ≤ p) : (max x y) ^ p = max (x ^ p) (y ^ p) := by rcases le_total x y with hxy \| hxy · rw [max_eq_right hxy, max_eq_right (rpow_le_rpow hx hxy hp)] · rw [max_eq_left hxy, max_eq_left (rpow_le_rpow hy hxy hp)] theorem self_le_rpow_of_le_one (h₁ : 0 ≤ x) (h₂ : x ≤ 1) (h₃ : y ≤ 1) : x ≤ x ^ y := by simpa only [rpow_one] using rpow_le_rpow_of_exponent_ge_of_imp h₁ h₂ h₃ fun _ ↦ (absurd · one_ne_zero) theorem self_le_rpow_of_one_le (h₁ : 1 ≤ x) (h₂ : 1 ≤ y) : x ≤ x ^ y := by simpa only [rpow_one] using rpow_le_rpow_of_exponent_le h₁ h₂ theorem rpow_le_self_of_le_one (h₁ : 0 ≤ x) (h₂ : x ≤ 1) (h₃ : 1 ≤ y) : x ^ y ≤ x := by simpa only [rpow_one] using rpow_le_rpow_of_exponent_ge_of_imp h₁ h₂ h₃ fun _ ↦ (absurd · (one_pos.trans_le h₃).ne') theorem rpow_le_self_of_one_le (h₁ : 1 ≤ x) (h₂ : y ≤ 1) : x ^ y ≤ x := by simpa only [rpow_one] using rpow_le_rpow_of_exponent_le h₁ h₂ theorem self_lt_rpow_of_lt_one (h₁ : 0 < x) (h₂ : x < 1) (h₃ : y < 1) : x < x ^ y := by simpa only [rpow_one] using rpow_lt_rpow_of_exponent_gt h₁ h₂ h₃ theorem self_lt_rpow_of_one_lt (h₁ : 1 < x) (h₂ : 1 < y) : x < x ^ y := by simpa only [rpow_one] using rpow_lt_rpow_of_exponent_lt h₁ h₂ theorem rpow_lt_self_of_lt_one (h₁ : 0 < x) (h₂ : x < 1) (h₃ : 1 < y) : x ^ y < x := by simpa only [rpow_one] using rpow_lt_rpow_of_exponent_gt h₁ h₂ h₃ theorem rpow_lt_self_of_one_lt (h₁ : 1 < x) (h₂ : y < 1) : x ^ y < x := by simpa only [rpow_one] using rpow_lt_rpow_of_exponent_lt h₁ h₂ theorem rpow_left_injOn {x : ℝ} (hx : x ≠ 0) : InjOn (fun y : ℝ => y ^ x) { y : ℝ \| 0 ≤ y } := by rintro y hy z hz (hyz : y ^ x = z ^ x) rw [← rpow_one y, ← rpow_one z, ← mul_inv_cancel₀ hx, rpow_mul hy, rpow_mul hz, hyz] lemma rpow_left_inj (hx : 0 ≤ x) (hy : 0 ≤ y) (hz : z ≠ 0) : x ^ z = y ^ z ↔ x = y := (rpow_left_injOn hz).eq_iff hx hy lemma rpow_inv_eq (hx : 0 ≤ x) (hy : 0 ≤ y) (hz : z ≠ 0) : x ^ z⁻¹ = y ↔ x = y ^ z := by rw [← rpow_left_inj _ hy hz, rpow_inv_rpow hx hz]; positivity lemma eq_rpow_inv (hx : 0 ≤ x) (hy : 0 ≤ y) (hz : z ≠ 0) : x = y ^ z⁻¹ ↔ x ^ z = y := by rw [← rpow_left_inj hx _ hz, rpow_inv_rpow hy hz]; positivity theorem le_rpow_iff_log_le (hx : 0 < x) (hy : 0 < y) : x ≤ y ^ z ↔ log x ≤ z * log y := by rw [← log_le_log_iff hx (rpow_pos_of_pos hy z), log_rpow hy] lemma le_pow_iff_log_le (hx : 0 < x) (hy : 0 < y) : x ≤ y ^ n ↔ log x ≤ n * log y := rpow_natCast _ _ ▸ le_rpow_iff_log_le hx hy lemma le_zpow_iff_log_le {n : ℤ} (hx : 0 < x) (hy : 0 < y) : x ≤ y ^ n ↔ log x ≤ n * log y := rpow_intCast _ _ ▸ le_rpow_iff_log_le hx hy lemma le_rpow_of_log_le (hy : 0 < y) (h : log x ≤ z * log y) : x ≤ y ^ z := by obtain hx \| hx := le_or_lt x 0 · exact hx.trans (rpow_pos_of_pos hy _).le · exact (le_rpow_iff_log_le hx hy).2 h lemma le_pow_of_log_le (hy : 0 < y) (h : log x ≤ n * log y) : x ≤ y ^ n := rpow_natCast _ _ ▸ le_rpow_of_log_le hy h lemma le_zpow_of_log_le {n : ℤ} (hy : 0 < y) (h : log x ≤ n * log y) : x ≤ y ^ n := rpow_intCast _ _ ▸ le_rpow_of_log_le hy h theorem lt_rpow_iff_log_lt (hx : 0 < x) (hy : 0 < y) : x < y ^ z ↔ log x < z * log y := by rw [← log_lt_log_iff hx (rpow_pos_of_pos hy z), log_rpow hy] lemma lt_pow_iff_log_lt (hx : 0 < x) (hy : 0 < y) : x < y ^ n ↔ log x < n * log y := rpow_natCast _ _ ▸ lt_rpow_iff_log_lt hx hy lemma lt_zpow_iff_log_lt {n : ℤ} (hx : 0 < x) (hy : 0 < y) : x < y ^ n ↔ log x < n * log y := rpow_intCast _ _ ▸ lt_rpow_iff_log_lt hx hy lemma lt_rpow_of_log_lt (hy : 0 < y) (h : log x < z * log y) : x < y ^ z := by obtain hx \| hx := le_or_lt x 0 · exact hx.trans_lt (rpow_pos_of_pos hy _) · exact (lt_rpow_iff_log_lt hx hy).2 h lemma lt_pow_of_log_lt (hy : 0 < y) (h : log x < n * log y) : x < y ^ n := rpow_natCast _ _ ▸ lt_rpow_of_log_lt hy h lemma lt_zpow_of_log_lt {n : ℤ} (hy : 0 < y) (h : log x < n * log y) : x < y ^ n := rpow_intCast _ _ ▸ lt_rpow_of_log_lt hy h lemma rpow_le_iff_le_log (hx : 0 < x) (hy : 0 < y) : x ^ z ≤ y ↔ z * log x ≤ log y := by rw [← log_le_log_iff (rpow_pos_of_pos hx _) hy, log_rpow hx] lemma pow_le_iff_le_log (hx : 0 < x) (hy : 0 < y) : x ^ n ≤ y ↔ n * log x ≤ log y := by rw [← rpow_le_iff_le_log hx hy, rpow_natCast] lemma zpow_le_iff_le_log {n : ℤ} (hx : 0 < x) (hy : 0 < y) : x ^ n ≤ y ↔ n * log x ≤ log y := by rw [← rpow_le_iff_le_log hx hy, rpow_intCast] lemma le_log_of_rpow_le (hx : 0 < x) (h : x ^ z ≤ y) : z * log x ≤ log y := log_rpow hx _ ▸ log_le_log (by positivity) h lemma le_log_of_pow_le (hx : 0 < x) (h : x ^ n ≤ y) : n * log x ≤ log y := le_log_of_rpow_le hx (rpow_natCast _ _ ▸ h) lemma le_log_of_zpow_le {n : ℤ} (hx : 0 < x) (h : x ^ n ≤ y) : n * log x ≤ log y := le_log_of_rpow_le hx (rpow_intCast _ _ ▸ h) lemma rpow_le_of_le_log (hy : 0 < y) (h : log x ≤ z * log y) : x ≤ y ^ z := by obtain hx \| hx := le_or_lt x 0 · exact hx.trans (rpow_pos_of_pos hy _).le · exact (le_rpow_iff_log_le hx hy).2 h lemma pow_le_of_le_log (hy : 0 < y) (h : log x ≤ n * log y) : x ≤ y ^ n := rpow_natCast _ _ ▸ rpow_le_of_le_log hy h lemma zpow_le_of_le_log {n : ℤ} (hy : 0 < y) (h : log x ≤ n * log y) : x ≤ y ^ n := rpow_intCast _ _ ▸ rpow_le_of_le_log hy h lemma rpow_lt_iff_lt_log (hx : 0 < x) (hy : 0 < y) : x ^ z < y ↔ z * log x < log y := by rw [← log_lt_log_iff (rpow_pos_of_pos hx _) hy, log_rpow hx] lemma pow_lt_iff_lt_log (hx : 0 < x) (hy : 0 < y) : x ^ n < y ↔ n * log x < log y := by rw [← rpow_lt_iff_lt_log hx hy, rpow_natCast] lemma zpow_lt_iff_lt_log {n : ℤ} (hx : 0 < x) (hy : 0 < y) : x ^ n < y ↔ n * log x < log y := by rw [← rpow_lt_iff_lt_log hx hy, rpow_intCast] lemma lt_log_of_rpow_lt (hx : 0 < x) (h : x ^ z < y) : z * log x < log y := log_rpow hx _ ▸ log_lt_log (by positivity) h lemma lt_log_of_pow_lt (hx : 0 < x) (h : x ^ n < y) : n * log x < log y := lt_log_of_rpow_lt hx (rpow_natCast _ _ ▸ h) lemma lt_log_of_zpow_lt {n : ℤ} (hx : 0 < x) (h : x ^ n < y) : n * log x < log y := lt_log_of_rpow_lt hx (rpow_intCast _ _ ▸ h) lemma rpow_lt_of_lt_log (hy : 0 < y) (h : log x < z * log y) : x < y ^ z := by obtain hx \| hx := le_or_lt x 0 · exact hx.trans_lt (rpow_pos_of_pos hy _) · exact (lt_rpow_iff_log_lt hx hy).2 h lemma pow_lt_of_lt_log (hy : 0 < y) (h : log x < n * log y) : x < y ^ n := rpow_natCast _ _ ▸ rpow_lt_of_lt_log hy h lemma zpow_lt_of_lt_log {n : ℤ} (hy : 0 < y) (h : log x < n * log y) : x < y ^ n := rpow_intCast _ _ ▸ rpow_lt_of_lt_log hy h theorem rpow_le_one_iff_of_pos (hx : 0 < x) : x ^ y ≤ 1 ↔ 1 ≤ x ∧ y ≤ 0 ∨ x ≤ 1 ∧ 0 ≤ y := by rw [rpow_def_of_pos hx, exp_le_one_iff, mul_nonpos_iff, log_nonneg_iff hx, log_nonpos_iff hx.le] /-- Bound for `\|log x * x ^ t\|` in the interval `(0, 1]`, for positive real `t`. -/ theorem abs_log_mul_self_rpow_lt (x t : ℝ) (h1 : 0 < x) (h2 : x ≤ 1) (ht : 0 < t) : \|log x * x ^ t\| < 1 / t := by rw [lt_div_iff₀ ht] have := abs_log_mul_self_lt (x ^ t) (rpow_pos_of_pos h1 t) (rpow_le_one h1.le h2 ht.le) rwa [log_rpow h1, mul_assoc, abs_mul, abs_of_pos ht, mul_comm] at this /-- `log x` is bounded above by a multiple of every power of `x` with positive exponent. -/ lemma log_le_rpow_div {x ε : ℝ} (hx : 0 ≤ x) (hε : 0 < ε) : log x ≤ x ^ ε / ε := by rcases hx.eq_or_lt with rfl \| h · rw [log_zero, zero_rpow hε.ne', zero_div] rw [le_div_iff₀' hε] exact (log_rpow h ε).symm.trans_le <\| (log_le_sub_one_of_pos <\| rpow_pos_of_pos h ε).trans (sub_one_lt _).le /-- The (real) logarithm of a natural number `n` is bounded by a multiple of every power of `n` with positive exponent. -/ lemma log_natCast_le_rpow_div (n : ℕ) {ε : ℝ} (hε : 0 < ε) : log n ≤ n ^ ε / ε := log_le_rpow_div n.cast_nonneg hε lemma strictMono_rpow_of_base_gt_one {b : ℝ} (hb : 1 < b) : StrictMono (b ^ · : ℝ → ℝ) := by simp_rw [Real.rpow_def_of_pos (zero_lt_one.trans hb)] exact exp_strictMono.comp <\| StrictMono.const_mul strictMono_id <\| Real.log_pos hb lemma monotone_rpow_of_base_ge_one {b : ℝ} (hb : 1 ≤ b) : Monotone (b ^ · : ℝ → ℝ) := by rcases lt_or_eq_of_le hb with hb \| rfl case inl => exact (strictMono_rpow_of_base_gt_one hb).monotone case inr => intro _ _ _; simp lemma strictAnti_rpow_of_base_lt_one {b : ℝ} (hb₀ : 0 < b) (hb₁ : b < 1) : StrictAnti (b ^ · : ℝ → ℝ) := by simp_rw [Real.rpow_def_of_pos hb₀] exact exp_strictMono.comp_strictAnti <\| StrictMono.const_mul_of_neg strictMono_id <\| Real.log_neg hb₀ hb₁ lemma antitone_rpow_of_base_le_one {b : ℝ} (hb₀ : 0 < b) (hb₁ : b ≤ 1) : Antitone (b ^ · : ℝ → ℝ) := by rcases lt_or_eq_of_le hb₁ with hb₁ \| rfl case inl => exact (strictAnti_rpow_of_base_lt_one hb₀ hb₁).antitone case inr => intro _ _ _; simp lemma rpow_right_inj (hx₀ : 0 < x) (hx₁ : x ≠ 1) : x ^ y = x ^ z ↔ y = z := by refine ⟨fun H ↦ ?_, fun H ↦ by rw [H]⟩ rcases hx₁.lt_or_lt with h \| h · exact (strictAnti_rpow_of_base_lt_one hx₀ h).injective H	· exact (strictMono_rpow_of_base_gt_one h).injective H /-- Guessing rule for the `bound` tactic: when trying to prove `x ^ y ≤ x ^ z`, we can either assume `1 ≤ x` or `0 < x ≤ 1`. -/	Mathlib/Analysis/SpecialFunctions/Pow/Real.lean	917	920
/- Copyright (c) 2021 Sébastien Gouëzel. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Sébastien Gouëzel -/ import Mathlib.MeasureTheory.Constructions.BorelSpace.Basic import Mathlib.MeasureTheory.Covering.VitaliFamily import Mathlib.Data.Set.Pairwise.Lattice /-! # Vitali covering theorems The topological Vitali covering theorem, in its most classical version, states the following. Consider a family of balls `(B (x_i, r_i))_{i ∈ I}` in a metric space, with uniformly bounded radii. Then one can extract a disjoint subfamily indexed by `J ⊆ I`, such that any `B (x_i, r_i)` is included in a ball `B (x_j, 5 r_j)`. We prove this theorem in `Vitali.exists_disjoint_subfamily_covering_enlargement_closedBall`. It is deduced from a more general version, called `Vitali.exists_disjoint_subfamily_covering_enlargement`, which applies to any family of sets together with a size function `δ` (think "radius" or "diameter"). We deduce the measurable Vitali covering theorem. Assume one is given a family `t` of closed sets with nonempty interior, such that each `a ∈ t` is included in a ball `B (x, r)` and covers a definite proportion of the ball `B (x, 6 r)` for a given measure `μ` (think of the situation where `μ` is a doubling measure and `t` is a family of balls). Consider a set `s` at which the family is fine, i.e., every point of `s` belongs to arbitrarily small elements of `t`. Then one can extract from `t` a disjoint subfamily that covers almost all `s`. It is proved in `Vitali.exists_disjoint_covering_ae`. A way to restate this theorem is to say that the set of closed sets `a` with nonempty interior covering a fixed proportion `1/C` of the ball `closedBall x (3 * diam a)` forms a Vitali family. This version is given in `Vitali.vitaliFamily`. -/ variable {α ι : Type} open Set Metric MeasureTheory TopologicalSpace Filter open scoped NNReal ENNReal Topology namespace Vitali /-- Vitali covering theorem: given a set `t` of subsets of a type, one may extract a disjoint subfamily `u` such that the `τ`-enlargement of this family covers all elements of `t`, where `τ > 1` is any fixed number. When `t` is a family of balls, the `τ`-enlargement of `ball x r` is `ball x ((1+2τ) r)`. In general, it is expressed in terms of a function `δ` (think "radius" or "diameter"), positive and bounded on all elements of `t`. The condition is that every element `a` of `t` should intersect an element `b` of `u` of size larger than that of `a` up to `τ`, i.e., `δ b ≥ δ a / τ`. We state the lemma slightly more generally, with an indexed family of sets `B a` for `a ∈ t`, for wider applicability. -/ theorem exists_disjoint_subfamily_covering_enlargement (B : ι → Set α) (t : Set ι) (δ : ι → ℝ) (τ : ℝ) (hτ : 1 < τ) (δnonneg : ∀ a ∈ t, 0 ≤ δ a) (R : ℝ) (δle : ∀ a ∈ t, δ a ≤ R) (hne : ∀ a ∈ t, (B a).Nonempty) : ∃ u ⊆ t, u.PairwiseDisjoint B ∧ ∀ a ∈ t, ∃ b ∈ u, (B a ∩ B b).Nonempty ∧ δ a ≤ τ δ b := by /- The proof could be formulated as a transfinite induction. First pick an element of `t` with `δ` as large as possible (up to a factor of `τ`). Then among the remaining elements not intersecting the already chosen one, pick another element with large `δ`. Go on forever (transfinitely) until there is nothing left. Instead, we give a direct Zorn-based argument. Consider a maximal family `u` of disjoint sets with the following property: if an element `a` of `t` intersects some element `b` of `u`, then it intersects some `b' ∈ u` with `δ b' ≥ δ a / τ`. Such a maximal family exists by Zorn. If this family did not intersect some element `a ∈ t`, then take an element `a' ∈ t` which does not intersect any element of `u`, with `δ a'` almost as large as possible. One checks easily that `u ∪ {a'}` still has this property, contradicting the maximality. Therefore, `u` intersects all elements of `t`, and by definition it satisfies all the desired properties. -/ let T : Set (Set ι) := { u \| u ⊆ t ∧ u.PairwiseDisjoint B ∧ ∀ a ∈ t, ∀ b ∈ u, (B a ∩ B b).Nonempty → ∃ c ∈ u, (B a ∩ B c).Nonempty ∧ δ a ≤ τ * δ c } -- By Zorn, choose a maximal family in the good set `T` of disjoint families. obtain ⟨u, hu⟩ : ∃ m, Maximal (fun x ↦ x ∈ T) m := by refine zorn_subset _ fun U UT hU => ?_ refine ⟨⋃₀ U, ?_, fun s hs => subset_sUnion_of_mem hs⟩ simp only [T, Set.sUnion_subset_iff, and_imp, exists_prop, forall_exists_index, mem_sUnion, Set.mem_setOf_eq] refine ⟨fun u hu => (UT hu).1, (pairwiseDisjoint_sUnion hU.directedOn).2 fun u hu => (UT hu).2.1, fun a hat b u uU hbu hab => ?_⟩ obtain ⟨c, cu, ac, hc⟩ : ∃ c, c ∈ u ∧ (B a ∩ B c).Nonempty ∧ δ a ≤ τ * δ c := (UT uU).2.2 a hat b hbu hab exact ⟨c, ⟨u, uU, cu⟩, ac, hc⟩ -- The only nontrivial bit is to check that every `a ∈ t` intersects an element `b ∈ u` with -- comparatively large `δ b`. Assume this is not the case, then we will contradict the maximality. refine ⟨u, hu.prop.1, hu.prop.2.1, fun a hat => ?_⟩ by_contra! hcon have a_disj : ∀ c ∈ u, Disjoint (B a) (B c) := by intro c hc by_contra h rw [not_disjoint_iff_nonempty_inter] at h obtain ⟨d, du, ad, hd⟩ : ∃ d, d ∈ u ∧ (B a ∩ B d).Nonempty ∧ δ a ≤ τ * δ d := hu.prop.2.2 a hat c hc h exact lt_irrefl _ ((hcon d du ad).trans_le hd) -- Let `A` be all the elements of `t` which do not intersect the family `u`. It is nonempty as it -- contains `a`. We will pick an element `a'` of `A` with `δ a'` almost as large as possible. let A := { a' \| a' ∈ t ∧ ∀ c ∈ u, Disjoint (B a') (B c) } have Anonempty : A.Nonempty := ⟨a, hat, a_disj⟩ let m := sSup (δ '' A) have bddA : BddAbove (δ '' A) := by refine ⟨R, fun x xA => ?_⟩ rcases (mem_image _ _ _).1 xA with ⟨a', ha', rfl⟩ exact δle a' ha'.1 obtain ⟨a', a'A, ha'⟩ : ∃ a' ∈ A, m / τ ≤ δ a' := by have : 0 ≤ m := (δnonneg a hat).trans (le_csSup bddA (mem_image_of_mem _ ⟨hat, a_disj⟩)) rcases eq_or_lt_of_le this with (mzero \| mpos) · refine ⟨a, ⟨hat, a_disj⟩, ?_⟩ simpa only [← mzero, zero_div] using δnonneg a hat · have I : m / τ < m := by rw [div_lt_iff₀ (zero_lt_one.trans hτ)] conv_lhs => rw [← mul_one m] exact (mul_lt_mul_left mpos).2 hτ rcases exists_lt_of_lt_csSup (Anonempty.image _) I with ⟨x, xA, hx⟩ rcases (mem_image _ _ _).1 xA with ⟨a', ha', rfl⟩ exact ⟨a', ha', hx.le⟩ clear hat hcon a_disj a have a'_ne_u : a' ∉ u := fun H => (hne _ a'A.1).ne_empty (disjoint_self.1 (a'A.2 _ H)) -- we claim that `u ∪ {a'}` still belongs to `T`, contradicting the maximality of `u`. refine a'_ne_u (hu.mem_of_prop_insert ⟨?_, ?_, ?_⟩) · -- check that `u ∪ {a'}` is made of elements of `t`. rw [insert_subset_iff] exact ⟨a'A.1, hu.prop.1⟩ · -- Check that `u ∪ {a'}` is a disjoint family. This follows from the fact that `a'` does not -- intersect `u`. exact hu.prop.2.1.insert fun b bu _ => a'A.2 b bu · -- check that every element `c` of `t` intersecting `u ∪ {a'}` intersects an element of this -- family with large `δ`. intro c ct b ba'u hcb -- if `c` already intersects an element of `u`, then it intersects an element of `u` with -- large `δ` by the assumption on `u`, and there is nothing left to do. by_cases H : ∃ d ∈ u, (B c ∩ B d).Nonempty · rcases H with ⟨d, du, hd⟩ rcases hu.prop.2.2 c ct d du hd with ⟨d', d'u, hd'⟩ exact ⟨d', mem_insert_of_mem _ d'u, hd'⟩ · -- Otherwise, `c` belongs to `A`. The element of `u ∪ {a'}` that it intersects has to be `a'`. -- Moreover, `δ c` is smaller than the maximum `m` of `δ` over `A`, which is `≤ δ a' / τ` -- thanks to the good choice of `a'`. This is the desired inequality. push_neg at H simp only [← disjoint_iff_inter_eq_empty] at H rcases mem_insert_iff.1 ba'u with (rfl \| H') · refine ⟨b, mem_insert _ _, hcb, ?_⟩ calc δ c ≤ m := le_csSup bddA (mem_image_of_mem _ ⟨ct, H⟩) _ = τ * (m / τ) := by field_simp [(zero_lt_one.trans hτ).ne'] _ ≤ τ * δ b := by gcongr · rw [← not_disjoint_iff_nonempty_inter] at hcb exact (hcb (H _ H')).elim @[deprecated (since := "2024-12-25")] alias exists_disjoint_subfamily_covering_enlargment := exists_disjoint_subfamily_covering_enlargement /-- Vitali covering theorem, closed balls version: given a family `t` of closed balls, one can extract a disjoint subfamily `u ⊆ t` so that all balls in `t` are covered by the τ-times dilations of balls in `u`, for some `τ > 3`. -/ theorem exists_disjoint_subfamily_covering_enlargement_closedBall [PseudoMetricSpace α] (t : Set ι) (x : ι → α) (r : ι → ℝ) (R : ℝ) (hr : ∀ a ∈ t, r a ≤ R) (τ : ℝ) (hτ : 3 < τ) : ∃ u ⊆ t, (u.PairwiseDisjoint fun a => closedBall (x a) (r a)) ∧ ∀ a ∈ t, ∃ b ∈ u, closedBall (x a) (r a) ⊆ closedBall (x b) (τ * r b) := by rcases eq_empty_or_nonempty t with (rfl \| _) · exact ⟨∅, Subset.refl _, pairwiseDisjoint_empty, by simp⟩ by_cases ht : ∀ a ∈ t, r a < 0 · exact ⟨t, Subset.rfl, fun a ha b _ _ => by #adaptation_note /-- nightly-2024-03-16 Previously `Function.onFun` unfolded in the following `simp only`, but now needs a separate `rw`. This may be a bug: a no import minimization may be required. -/ rw [Function.onFun] simp only [Function.onFun, closedBall_eq_empty.2 (ht a ha), empty_disjoint], fun a ha => ⟨a, ha, by simp only [closedBall_eq_empty.2 (ht a ha), empty_subset]⟩⟩ push_neg at ht let t' := { a ∈ t \| 0 ≤ r a } rcases exists_disjoint_subfamily_covering_enlargement (fun a => closedBall (x a) (r a)) t' r ((τ - 1) / 2) (by linarith) (fun a ha => ha.2) R (fun a ha => hr a ha.1) fun a ha => ⟨x a, mem_closedBall_self ha.2⟩ with ⟨u, ut', u_disj, hu⟩ have A : ∀ a ∈ t', ∃ b ∈ u, closedBall (x a) (r a) ⊆ closedBall (x b) (τ * r b) := by intro a ha rcases hu a ha with ⟨b, bu, hb, rb⟩ refine ⟨b, bu, ?_⟩ have : dist (x a) (x b) ≤ r a + r b := dist_le_add_of_nonempty_closedBall_inter_closedBall hb apply closedBall_subset_closedBall' linarith refine ⟨u, ut'.trans fun a ha => ha.1, u_disj, fun a ha => ?_⟩ rcases le_or_lt 0 (r a) with (h'a \| h'a) · exact A a ⟨ha, h'a⟩ · rcases ht with ⟨b, rb⟩ rcases A b ⟨rb.1, rb.2⟩ with ⟨c, cu, _⟩ exact ⟨c, cu, by simp only [closedBall_eq_empty.2 h'a, empty_subset]⟩ @[deprecated (since := "2024-12-25")] alias exists_disjoint_subfamily_covering_enlargment_closedBall := exists_disjoint_subfamily_covering_enlargement_closedBall /-- The measurable Vitali covering theorem. Assume one is given a family `t` of closed sets with nonempty interior, such that each `a ∈ t` is included in a ball `B (x, r)` and covers a definite proportion of the ball `B (x, 3 r)` for a given	measure `μ` (think of the situation where `μ` is a doubling measure and `t` is a family of balls). Consider a (possibly non-measurable) set `s` at which the family is fine, i.e., every point of `s` belongs to arbitrarily small elements of `t`. Then one can extract from `t` a disjoint subfamily that covers almost all `s`. For more flexibility, we give a statement with a parameterized family of sets. -/ theorem exists_disjoint_covering_ae [PseudoMetricSpace α] [MeasurableSpace α] [OpensMeasurableSpace α] [SecondCountableTopology α] (μ : Measure α) [IsLocallyFiniteMeasure μ] (s : Set α) (t : Set ι) (C : ℝ≥0) (r : ι → ℝ) (c : ι → α) (B : ι → Set α) (hB : ∀ a ∈ t, B a ⊆ closedBall (c a) (r a)) (μB : ∀ a ∈ t, μ (closedBall (c a) (3 * r a)) ≤ C * μ (B a)) (ht : ∀ a ∈ t, (interior (B a)).Nonempty) (h't : ∀ a ∈ t, IsClosed (B a)) (hf : ∀ x ∈ s, ∀ ε > (0 : ℝ), ∃ a ∈ t, r a ≤ ε ∧ c a = x) : ∃ u ⊆ t, u.Countable ∧ u.PairwiseDisjoint B ∧ μ (s \ ⋃ a ∈ u, B a) = 0 := by /- The idea of the proof is the following. Assume for simplicity that `μ` is finite. Applying the abstract Vitali covering theorem with `δ = r` given by `hf`, one obtains a disjoint subfamily `u`, such that any element of `t` intersects an element of `u` with comparable radius. Fix `ε > 0`. Since the elements of `u` have summable measure, one can remove finitely elements `w_1, ..., w_n`. so that the measure of the remaining elements is `< ε`. Consider now a point `z` not in the `w_i`. There is a small ball around `z` not intersecting the `w_i` (as they are closed), an element `a ∈ t` contained in this small ball (as the family `t` is fine at `z`) and an element `b ∈ u` intersecting `a`, with comparable radius (by definition of `u`). Then `z` belongs to the enlargement of `b`. This shows that `s \ (w_1 ∪ ... ∪ w_n)` is contained in `⋃ (b ∈ u \ {w_1, ... w_n}) (enlargement of b)`. The measure of the latter set is bounded by `∑ (b ∈ u \ {w_1, ... w_n}) C * μ b` (by the doubling property of the measure), which is at most `C ε`. Letting `ε` tend to `0` shows that `s` is almost everywhere covered by the family `u`. For the real argument, the measure is only locally finite. Therefore, we implement the same strategy, but locally restricted to balls on which the measure is finite. For this, we do not use the whole family `t`, but a subfamily `t'` supported on small balls (which is possible since the family is assumed to be fine at every point of `s`). -/ classical -- choose around each `x` a small ball on which the measure is finite have : ∀ x, ∃ R, 0 < R ∧ R ≤ 1 ∧ μ (closedBall x (20 * R)) < ∞ := fun x ↦ by refine ((eventually_le_nhds one_pos).and ?_).exists_gt refine (tendsto_closedBall_smallSets x).comp ?_ (μ.finiteAt_nhds x).eventually exact Continuous.tendsto' (by fun_prop) _ _ (mul_zero _) choose R hR0 hR1 hRμ using this -- we restrict to a subfamily `t'` of `t`, made of elements small enough to ensure that -- they only see a finite part of the measure, and with a doubling property let t' := { a ∈ t \| r a ≤ R (c a) } -- extract a disjoint subfamily `u` of `t'` thanks to the abstract Vitali covering theorem. obtain ⟨u, ut', u_disj, hu⟩ : ∃ u ⊆ t', u.PairwiseDisjoint B ∧ ∀ a ∈ t', ∃ b ∈ u, (B a ∩ B b).Nonempty ∧ r a ≤ 2 * r b := by have A : ∀ a ∈ t', r a ≤ 1 := by intro a ha apply ha.2.trans (hR1 (c a)) have A' : ∀ a ∈ t', (B a).Nonempty := fun a hat' => Set.Nonempty.mono interior_subset (ht a hat'.1) refine exists_disjoint_subfamily_covering_enlargement B t' r 2 one_lt_two (fun a ha => ?_) 1 A A' exact nonempty_closedBall.1 ((A' a ha).mono (hB a ha.1)) have ut : u ⊆ t := fun a hau => (ut' hau).1 -- As the space is second countable, the family is countable since all its sets have nonempty -- interior. have u_count : u.Countable := u_disj.countable_of_nonempty_interior fun a ha => ht a (ut ha) -- the family `u` will be the desired family refine ⟨u, fun a hat' => (ut' hat').1, u_count, u_disj, ?_⟩ -- it suffices to show that it covers almost all `s` locally around each point `x`. refine measure_null_of_locally_null _ fun x _ => ?_ -- let `v` be the subfamily of `u` made of those sets intersecting the small ball `ball x (r x)` let v := { a ∈ u \| (B a ∩ ball x (R x)).Nonempty } have vu : v ⊆ u := fun a ha => ha.1 -- they are all contained in a fixed ball of finite measure, thanks to our choice of `t'` obtain ⟨K, μK, hK⟩ : ∃ K, μ (closedBall x K) < ∞ ∧ ∀ a ∈ u, (B a ∩ ball x (R x)).Nonempty → B a ⊆ closedBall x K := by have Idist_v : ∀ a ∈ v, dist (c a) x ≤ r a + R x := by intro a hav apply dist_le_add_of_nonempty_closedBall_inter_closedBall refine hav.2.mono ?_ apply inter_subset_inter _ ball_subset_closedBall exact hB a (ut (vu hav)) set R0 := sSup (r '' v) with R0_def have R0_bdd : BddAbove (r '' v) := by refine ⟨1, fun r' hr' => ?_⟩ rcases (mem_image _ _ _).1 hr' with ⟨b, hb, rfl⟩ exact le_trans (ut' (vu hb)).2 (hR1 (c b)) rcases le_total R0 (R x) with (H \| H) · refine ⟨20 * R x, hRμ x, fun a au hax => ?_⟩ refine (hB a (ut au)).trans ?_ apply closedBall_subset_closedBall' have : r a ≤ R0 := le_csSup R0_bdd (mem_image_of_mem _ ⟨au, hax⟩) linarith [Idist_v a ⟨au, hax⟩, hR0 x] · have R0pos : 0 < R0 := (hR0 x).trans_le H have vnonempty : v.Nonempty := by by_contra h rw [nonempty_iff_ne_empty, Classical.not_not] at h rw [h, image_empty, Real.sSup_empty] at R0_def exact lt_irrefl _ (R0pos.trans_le (le_of_eq R0_def)) obtain ⟨a, hav, R0a⟩ : ∃ a ∈ v, R0 / 2 < r a := by obtain ⟨r', r'mem, hr'⟩ : ∃ r' ∈ r '' v, R0 / 2 < r' := exists_lt_of_lt_csSup (vnonempty.image _) (half_lt_self R0pos) rcases (mem_image _ _ _).1 r'mem with ⟨a, hav, rfl⟩ exact ⟨a, hav, hr'⟩ refine ⟨8 * R0, ?_, ?_⟩ · apply lt_of_le_of_lt (measure_mono _) (hRμ (c a)) apply closedBall_subset_closedBall' rw [dist_comm] linarith [Idist_v a hav, (ut' (vu hav)).2] · intro b bu hbx refine (hB b (ut bu)).trans ?_ apply closedBall_subset_closedBall' have : r b ≤ R0 := le_csSup R0_bdd (mem_image_of_mem _ ⟨bu, hbx⟩) linarith [Idist_v b ⟨bu, hbx⟩] -- we will show that, in `ball x (R x)`, almost all `s` is covered by the family `u`. refine ⟨_ ∩ ball x (R x), inter_mem_nhdsWithin _ (ball_mem_nhds _ (hR0 _)), nonpos_iff_eq_zero.mp (le_of_forall_gt_imp_ge_of_dense fun ε εpos => ?_)⟩ -- the elements of `v` are disjoint and all contained in a finite volume ball, hence the sum -- of their measures is finite. have I : (∑' a : v, μ (B a)) < ∞ := by calc (∑' a : v, μ (B a)) = μ (⋃ a ∈ v, B a) := by rw [measure_biUnion (u_count.mono vu) _ fun a ha => (h't _ (vu.trans ut ha)).measurableSet] exact u_disj.subset vu _ ≤ μ (closedBall x K) := (measure_mono (iUnion₂_subset fun a ha => hK a (vu ha) ha.2)) _ < ∞ := μK -- we can obtain a finite subfamily of `v`, such that the measures of the remaining elements -- add up to an arbitrarily small number, say `ε / C`. obtain ⟨w, hw⟩ : ∃ w : Finset v, (∑' a : { a // a ∉ w }, μ (B a)) < ε / C := haveI : 0 < ε / C := by simp only [ENNReal.div_pos_iff, εpos.ne', ENNReal.coe_ne_top, Ne, not_false_iff, and_self_iff] ((tendsto_order.1 (ENNReal.tendsto_tsum_compl_atTop_zero I.ne)).2 _ this).exists -- main property: the points `z` of `s` which are not covered by `u` are contained in the -- enlargements of the elements not in `w`. have M : (s \ ⋃ a ∈ u, B a) ∩ ball x (R x) ⊆ ⋃ a : { a // a ∉ w }, closedBall (c a) (3 * r a) := by intro z hz set k := ⋃ (a : v) (_ : a ∈ w), B a have k_closed : IsClosed k := isClosed_biUnion_finset fun i _ => h't _ (ut (vu i.2)) have z_notmem_k : z ∉ k := by simp only [k, not_exists, exists_prop, mem_iUnion, mem_sep_iff, forall_exists_index, SetCoe.exists, not_and, exists_and_right, Subtype.coe_mk] intro b hbv _ h'z have : z ∈ (s \ ⋃ a ∈ u, B a) ∩ ⋃ a ∈ u, B a := mem_inter (mem_of_mem_inter_left hz) (mem_biUnion (vu hbv) h'z) simpa only [diff_inter_self] -- since the elements of `w` are closed and finitely many, one can find a small ball around `z` -- not intersecting them have : ball x (R x) \ k ∈ 𝓝 z := by apply IsOpen.mem_nhds (isOpen_ball.sdiff k_closed) _ exact (mem_diff _).2 ⟨mem_of_mem_inter_right hz, z_notmem_k⟩ obtain ⟨d, dpos, hd⟩ : ∃ d, 0 < d ∧ closedBall z d ⊆ ball x (R x) \ k := nhds_basis_closedBall.mem_iff.1 this -- choose an element `a` of the family `t` contained in this small ball obtain ⟨a, hat, ad, rfl⟩ : ∃ a ∈ t, r a ≤ min d (R z) ∧ c a = z := hf z ((mem_diff _).1 (mem_of_mem_inter_left hz)).1 (min d (R z)) (lt_min dpos (hR0 z)) have ax : B a ⊆ ball x (R x) := by refine (hB a hat).trans ?_ refine Subset.trans ?_ (hd.trans Set.diff_subset) exact closedBall_subset_closedBall (ad.trans (min_le_left _ _)) -- it intersects an element `b` of `u` with comparable diameter, by definition of `u` obtain ⟨b, bu, ab, bdiam⟩ : ∃ b ∈ u, (B a ∩ B b).Nonempty ∧ r a ≤ 2 * r b := hu a ⟨hat, ad.trans (min_le_right _ _)⟩ have bv : b ∈ v := by refine ⟨bu, ab.mono ?_⟩ rw [inter_comm] exact inter_subset_inter_right _ ax let b' : v := ⟨b, bv⟩ -- `b` cannot belong to `w`, as the elements of `w` do not intersect `closedBall z d`, -- contrary to `b` have b'_notmem_w : b' ∉ w := by intro b'w have b'k : B b' ⊆ k := @Finset.subset_set_biUnion_of_mem _ _ _ (fun y : v => B y) _ b'w have : (ball x (R x) \ k ∩ k).Nonempty := by apply ab.mono (inter_subset_inter _ b'k) refine ((hB _ hat).trans ?_).trans hd exact closedBall_subset_closedBall (ad.trans (min_le_left _ _)) simpa only [diff_inter_self, Set.not_nonempty_empty] let b'' : { a // a ∉ w } := ⟨b', b'_notmem_w⟩ -- since `a` and `b` have comparable diameters, it follows that `z` belongs to the -- enlargement of `b` have zb : c a ∈ closedBall (c b) (3 * r b) := by rcases ab with ⟨e, ⟨ea, eb⟩⟩ have A : dist (c a) e ≤ r a := mem_closedBall'.1 (hB a hat ea) have B : dist e (c b) ≤ r b := mem_closedBall.1 (hB b (ut bu) eb) simp only [mem_closedBall] linarith only [dist_triangle (c a) e (c b), A, B, bdiam] suffices H : closedBall (c b'') (3 * r b'') ⊆ ⋃ a : { a // a ∉ w }, closedBall (c a) (3 * r a) from H zb exact subset_iUnion (fun a : { a // a ∉ w } => closedBall (c a) (3 * r a)) b'' -- now that we have proved our main inclusion, we can use it to estimate the measure of the points	Mathlib/MeasureTheory/Covering/Vitali.lean	205	388
/- Copyright (c) 2020 Aaron Anderson. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Aaron Anderson, Jalex Stark -/ import Mathlib.Algebra.Polynomial.Monic /-! # Lemmas for the interaction between polynomials and `∑` and `∏`. Recall that `∑` and `∏` are notation for `Finset.sum` and `Finset.prod` respectively. ## Main results - `Polynomial.natDegree_prod_of_monic` : the degree of a product of monic polynomials is the product of degrees. We prove this only for `[CommSemiring R]`, but it ought to be true for `[Semiring R]` and `List.prod`. - `Polynomial.natDegree_prod` : for polynomials over an integral domain, the degree of the product is the sum of degrees. - `Polynomial.leadingCoeff_prod` : for polynomials over an integral domain, the leading coefficient is the product of leading coefficients. - `Polynomial.prod_X_sub_C_coeff_card_pred` carries most of the content for computing the second coefficient of the characteristic polynomial. -/ open Finset open Multiset open Polynomial universe u w variable {R : Type u} {ι : Type w} namespace Polynomial variable (s : Finset ι) section Semiring variable {S : Type*} [Semiring S] theorem natDegree_list_sum_le (l : List S[X]) : natDegree l.sum ≤ (l.map natDegree).foldr max 0 := by apply List.sum_le_foldr_max natDegree · simp · exact natDegree_add_le theorem natDegree_multiset_sum_le (l : Multiset S[X]) : natDegree l.sum ≤ (l.map natDegree).foldr max 0 := Quotient.inductionOn l (by simpa using natDegree_list_sum_le) theorem natDegree_sum_le (f : ι → S[X]) : natDegree (∑ i ∈ s, f i) ≤ s.fold max 0 (natDegree ∘ f) := by simpa using natDegree_multiset_sum_le (s.val.map f) lemma natDegree_sum_le_of_forall_le {n : ℕ} (f : ι → S[X]) (h : ∀ i ∈ s, natDegree (f i) ≤ n) : natDegree (∑ i ∈ s, f i) ≤ n := le_trans (natDegree_sum_le s f) <\| (Finset.fold_max_le n).mpr <\| by simpa theorem degree_list_sum_le_of_forall_degree_le (l : List S[X]) (n : WithBot ℕ) (hl : ∀ p ∈ l, degree p ≤ n) : degree l.sum ≤ n := by induction l with \| nil => simp \| cons hd tl ih => simp only [List.mem_cons, forall_eq_or_imp] at hl rcases hl with ⟨hhd, htl⟩ rw [List.sum_cons] exact le_trans (degree_add_le hd tl.sum) (max_le hhd (ih htl)) theorem degree_list_sum_le (l : List S[X]) : degree l.sum ≤ (l.map natDegree).maximum := by apply degree_list_sum_le_of_forall_degree_le intros p hp by_cases h : p = 0 · subst h simp · rw [degree_eq_natDegree h] apply List.le_maximum_of_mem' rw [List.mem_map] use p simp [hp] theorem natDegree_list_prod_le (l : List S[X]) : natDegree l.prod ≤ (l.map natDegree).sum := by induction' l with hd tl IH · simp · simpa using natDegree_mul_le.trans (add_le_add_left IH _) theorem degree_list_prod_le (l : List S[X]) : degree l.prod ≤ (l.map degree).sum := by	induction' l with hd tl IH · simp · simpa using (degree_mul_le _ _).trans (add_le_add_left IH _) theorem coeff_list_prod_of_natDegree_le (l : List S[X]) (n : ℕ) (hl : ∀ p ∈ l, natDegree p ≤ n) : coeff (List.prod l) (l.length * n) = (l.map fun p => coeff p n).prod := by induction' l with hd tl IH · simp · have hl' : ∀ p ∈ tl, natDegree p ≤ n := fun p hp => hl p (List.mem_cons_of_mem _ hp) simp only [List.prod_cons, List.map, List.length] rw [add_mul, one_mul, add_comm, ← IH hl', mul_comm tl.length] have h : natDegree tl.prod ≤ n * tl.length := by refine (natDegree_list_prod_le _).trans ?_ rw [← tl.length_map natDegree, mul_comm] refine List.sum_le_card_nsmul _ _ ?_ simpa using hl' exact coeff_mul_add_eq_of_natDegree_le (hl _ List.mem_cons_self) h end Semiring	Mathlib/Algebra/Polynomial/BigOperators.lean	92	111
/- Copyright (c) 2021 Kim Morrison. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kim Morrison -/ import Mathlib.Algebra.Homology.Single /-! # Augmentation and truncation of `ℕ`-indexed (co)chain complexes. -/ noncomputable section open CategoryTheory Limits HomologicalComplex universe v u variable {V : Type u} [Category.{v} V] namespace ChainComplex /-- The truncation of an `ℕ`-indexed chain complex, deleting the object at `0` and shifting everything else down. -/ @[simps] def truncate [HasZeroMorphisms V] : ChainComplex V ℕ ⥤ ChainComplex V ℕ where obj C := { X := fun i => C.X (i + 1) d := fun i j => C.d (i + 1) (j + 1) shape := fun i j w => C.shape _ _ <\| by simpa } map f := { f := fun i => f.f (i + 1) } /-- There is a canonical chain map from the truncation of a chain map `C` to the "single object" chain complex consisting of the truncated object `C.X 0` in degree 0. The components of this chain map are `C.d 1 0` in degree 0, and zero otherwise. -/ def truncateTo [HasZeroObject V] [HasZeroMorphisms V] (C : ChainComplex V ℕ) : truncate.obj C ⟶ (single₀ V).obj (C.X 0) := (toSingle₀Equiv (truncate.obj C) (C.X 0)).symm ⟨C.d 1 0, by simp⟩ -- PROJECT when `V` is abelian (but not generally?) -- `[∀ n, Exact (C.d (n+2) (n+1)) (C.d (n+1) n)] [Epi (C.d 1 0)]` iff `QuasiIso (C.truncate_to)` variable [HasZeroMorphisms V] /-- We can "augment" a chain complex by inserting an arbitrary object in degree zero (shifting everything else up), along with a suitable differential. -/ def augment (C : ChainComplex V ℕ) {X : V} (f : C.X 0 ⟶ X) (w : C.d 1 0 ≫ f = 0) : ChainComplex V ℕ where X \| 0 => X \| i + 1 => C.X i d \| 1, 0 => f \| i + 1, j + 1 => C.d i j \| _, _ => 0 shape \| 1, 0, h => absurd rfl h \| _ + 2, 0, _ => rfl \| 0, _, _ => rfl \| i + 1, j + 1, h => by simp only; exact C.shape i j (Nat.succ_ne_succ.1 h) d_comp_d' \| _, _, 0, rfl, rfl => w \| _, _, k + 1, rfl, rfl => C.d_comp_d _ _ _ @[simp] theorem augment_X_zero (C : ChainComplex V ℕ) {X : V} (f : C.X 0 ⟶ X) (w : C.d 1 0 ≫ f = 0) : (augment C f w).X 0 = X := rfl @[simp] theorem augment_X_succ (C : ChainComplex V ℕ) {X : V} (f : C.X 0 ⟶ X) (w : C.d 1 0 ≫ f = 0) (i : ℕ) : (augment C f w).X (i + 1) = C.X i := rfl @[simp] theorem augment_d_one_zero (C : ChainComplex V ℕ) {X : V} (f : C.X 0 ⟶ X) (w : C.d 1 0 ≫ f = 0) : (augment C f w).d 1 0 = f := rfl @[simp] theorem augment_d_succ_succ (C : ChainComplex V ℕ) {X : V} (f : C.X 0 ⟶ X) (w : C.d 1 0 ≫ f = 0) (i j : ℕ) : (augment C f w).d (i + 1) (j + 1) = C.d i j := by cases i <;> rfl /-- Truncating an augmented chain complex is isomorphic (with components the identity) to the original complex. -/ def truncateAugment (C : ChainComplex V ℕ) {X : V} (f : C.X 0 ⟶ X) (w : C.d 1 0 ≫ f = 0) : truncate.obj (augment C f w) ≅ C where hom := { f := fun _ => 𝟙 _ } inv := { f := fun _ => 𝟙 _ comm' := fun i j => by cases j <;> · dsimp simp } hom_inv_id := by ext (_ \| i) <;> · dsimp simp inv_hom_id := by ext (_ \| i) <;> · dsimp simp @[simp] theorem truncateAugment_hom_f (C : ChainComplex V ℕ) {X : V} (f : C.X 0 ⟶ X) (w : C.d 1 0 ≫ f = 0) (i : ℕ) : (truncateAugment C f w).hom.f i = 𝟙 (C.X i) := rfl @[simp] theorem truncateAugment_inv_f (C : ChainComplex V ℕ) {X : V} (f : C.X 0 ⟶ X) (w : C.d 1 0 ≫ f = 0) (i : ℕ) : (truncateAugment C f w).inv.f i = 𝟙 ((truncate.obj (augment C f w)).X i) := rfl @[simp] theorem chainComplex_d_succ_succ_zero (C : ChainComplex V ℕ) (i : ℕ) : C.d (i + 2) 0 = 0 := by rw [C.shape] exact i.succ_succ_ne_one.symm /-- Augmenting a truncated complex with the original object and morphism is isomorphic (with components the identity) to the original complex. -/ def augmentTruncate (C : ChainComplex V ℕ) : augment (truncate.obj C) (C.d 1 0) (C.d_comp_d _ _ _) ≅ C where hom := { f := fun \| 0 => 𝟙 _ \| _+1 => 𝟙 _ comm' := fun i j => by -- Porting note: was an rcases n with (_\|_\|n) but that was causing issues match i with	\| 0 \| 1 \| n+2 => rcases j with - \| j <;> dsimp [augment, truncate] <;> simp }	Mathlib/Algebra/Homology/Augment.lean	132	134
/- 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.Path import Mathlib.Combinatorics.SimpleGraph.Operations import Mathlib.Data.Finset.Pairwise import Mathlib.Data.Fintype.Pigeonhole import Mathlib.Data.Fintype.Powerset import Mathlib.Data.Nat.Lattice import Mathlib.SetTheory.Cardinal.Finite /-! # Graph cliques This file defines cliques in simple graphs. A clique is a set of vertices that are pairwise adjacent. ## Main declarations * `SimpleGraph.IsClique`: Predicate for a set of vertices to be a clique. * `SimpleGraph.IsNClique`: Predicate for a set of vertices to be an `n`-clique. * `SimpleGraph.cliqueFinset`: Finset of `n`-cliques of a graph. * `SimpleGraph.CliqueFree`: Predicate for a graph to have no `n`-cliques. -/ open Finset Fintype Function SimpleGraph.Walk namespace SimpleGraph variable {α β : Type} (G H : SimpleGraph α) /-! ### Cliques -/ section Clique variable {s t : Set α} /-- A clique in a graph is a set of vertices that are pairwise adjacent. -/ abbrev IsClique (s : Set α) : Prop := s.Pairwise G.Adj theorem isClique_iff : G.IsClique s ↔ s.Pairwise G.Adj := Iff.rfl /-- A clique is a set of vertices whose induced graph is complete. -/ theorem isClique_iff_induce_eq : G.IsClique s ↔ G.induce s = ⊤ := by rw [isClique_iff] constructor · intro h ext ⟨v, hv⟩ ⟨w, hw⟩ simp only [comap_adj, Subtype.coe_mk, top_adj, Ne, Subtype.mk_eq_mk] exact ⟨Adj.ne, h hv hw⟩ · intro h v hv w hw hne have h2 : (G.induce s).Adj ⟨v, hv⟩ ⟨w, hw⟩ = _ := rfl conv_lhs at h2 => rw [h] simp only [top_adj, ne_eq, Subtype.mk.injEq, eq_iff_iff] at h2 exact h2.1 hne instance [DecidableEq α] [DecidableRel G.Adj] {s : Finset α} : Decidable (G.IsClique s) := decidable_of_iff' _ G.isClique_iff variable {G H} {a b : α} lemma isClique_empty : G.IsClique ∅ := by simp lemma isClique_singleton (a : α) : G.IsClique {a} := by simp theorem IsClique.of_subsingleton {G : SimpleGraph α} (hs : s.Subsingleton) : G.IsClique s := hs.pairwise G.Adj lemma isClique_pair : G.IsClique {a, b} ↔ a ≠ b → G.Adj a b := Set.pairwise_pair_of_symmetric G.symm @[simp] lemma isClique_insert : G.IsClique (insert a s) ↔ G.IsClique s ∧ ∀ b ∈ s, a ≠ b → G.Adj a b := Set.pairwise_insert_of_symmetric G.symm lemma isClique_insert_of_not_mem (ha : a ∉ s) : G.IsClique (insert a s) ↔ G.IsClique s ∧ ∀ b ∈ s, G.Adj a b := Set.pairwise_insert_of_symmetric_of_not_mem G.symm ha lemma IsClique.insert (hs : G.IsClique s) (h : ∀ b ∈ s, a ≠ b → G.Adj a b) : G.IsClique (insert a s) := hs.insert_of_symmetric G.symm h theorem IsClique.mono (h : G ≤ H) : G.IsClique s → H.IsClique s := Set.Pairwise.mono' h theorem IsClique.subset (h : t ⊆ s) : G.IsClique s → G.IsClique t := Set.Pairwise.mono h @[simp] theorem isClique_bot_iff : (⊥ : SimpleGraph α).IsClique s ↔ (s : Set α).Subsingleton := Set.pairwise_bot_iff alias ⟨IsClique.subsingleton, _⟩ := isClique_bot_iff protected theorem IsClique.map (h : G.IsClique s) {f : α ↪ β} : (G.map f).IsClique (f '' s) := by rintro _ ⟨a, ha, rfl⟩ _ ⟨b, hb, rfl⟩ hab exact ⟨a, b, h ha hb <\| ne_of_apply_ne _ hab, rfl, rfl⟩ theorem isClique_map_iff_of_nontrivial {f : α ↪ β} {t : Set β} (ht : t.Nontrivial) : (G.map f).IsClique t ↔ ∃ (s : Set α), G.IsClique s ∧ f '' s = t := by refine ⟨fun h ↦ ⟨f ⁻¹' t, ?_, ?_⟩, by rintro ⟨x, hs, rfl⟩; exact hs.map⟩ · rintro x (hx : f x ∈ t) y (hy : f y ∈ t) hne obtain ⟨u,v, huv, hux, hvy⟩ := h hx hy (by simpa) rw [EmbeddingLike.apply_eq_iff_eq] at hux hvy rwa [← hux, ← hvy] rw [Set.image_preimage_eq_iff] intro x hxt obtain ⟨y,hyt, hyne⟩ := ht.exists_ne x obtain ⟨u,v, -, rfl, rfl⟩ := h hyt hxt hyne exact Set.mem_range_self _ theorem isClique_map_iff {f : α ↪ β} {t : Set β} : (G.map f).IsClique t ↔ t.Subsingleton ∨ ∃ (s : Set α), G.IsClique s ∧ f '' s = t := by obtain (ht \| ht) := t.subsingleton_or_nontrivial · simp [IsClique.of_subsingleton, ht] simp [isClique_map_iff_of_nontrivial ht, ht.not_subsingleton] @[simp] theorem isClique_map_image_iff {f : α ↪ β} : (G.map f).IsClique (f '' s) ↔ G.IsClique s := by rw [isClique_map_iff, f.injective.subsingleton_image_iff] obtain (hs \| hs) := s.subsingleton_or_nontrivial · simp [hs, IsClique.of_subsingleton] simp [or_iff_right hs.not_subsingleton, Set.image_eq_image f.injective] variable {f : α ↪ β} {t : Finset β} theorem isClique_map_finset_iff_of_nontrivial (ht : t.Nontrivial) : (G.map f).IsClique t ↔ ∃ (s : Finset α), G.IsClique s ∧ s.map f = t := by constructor · rw [isClique_map_iff_of_nontrivial (by simpa)] rintro ⟨s, hs, hst⟩ obtain ⟨s, rfl⟩ := Set.Finite.exists_finset_coe <\| (show s.Finite from Set.Finite.of_finite_image (by simp [hst]) f.injective.injOn) exact ⟨s,hs, Finset.coe_inj.1 (by simpa)⟩ rintro ⟨s, hs, rfl⟩ simpa using hs.map (f := f) theorem isClique_map_finset_iff : (G.map f).IsClique t ↔ #t ≤ 1 ∨ ∃ (s : Finset α), G.IsClique s ∧ s.map f = t := by obtain (ht \| ht) := le_or_lt #t 1 · simp only [ht, true_or, iff_true] exact IsClique.of_subsingleton <\| card_le_one.1 ht rw [isClique_map_finset_iff_of_nontrivial, ← not_lt] · simp [ht, Finset.map_eq_image] exact Finset.one_lt_card_iff_nontrivial.mp ht protected theorem IsClique.finsetMap {f : α ↪ β} {s : Finset α} (h : G.IsClique s) : (G.map f).IsClique (s.map f) := by simpa /-- If a set of vertices `A` is a clique in subgraph of `G` induced by a superset of `A`, its embedding is a clique in `G`. -/ theorem IsClique.of_induce {S : Subgraph G} {F : Set α} {A : Set F} (c : (S.induce F).coe.IsClique A) : G.IsClique (Subtype.val '' A) := by simp only [Set.Pairwise, Set.mem_image, Subtype.exists, exists_and_right, exists_eq_right] intro _ ⟨_, ainA⟩ _ ⟨_, binA⟩ anb exact S.adj_sub (c ainA binA (Subtype.coe_ne_coe.mp anb)).2.2 lemma IsClique.sdiff_of_sup_edge {v w : α} {s : Set α} (hc : (G ⊔ edge v w).IsClique s) : G.IsClique (s \ {v}) := by intro _ hx _ hy hxy have := hc hx.1 hy.1 hxy simp_all [sup_adj, edge_adj] lemma isClique_sup_edge_of_ne_sdiff {v w : α} {s : Set α} (h : v ≠ w ) (hv : G.IsClique (s \ {v})) (hw : G.IsClique (s \ {w})) : (G ⊔ edge v w).IsClique s := by intro x hx y hy hxy by_cases h' : x ∈ s \ {v} ∧ y ∈ s \ {v} ∨ x ∈ s \ {w} ∧ y ∈ s \ {w} · obtain (⟨hx, hy⟩ \| ⟨hx, hy⟩) := h' · exact hv.mono le_sup_left hx hy hxy · exact hw.mono le_sup_left hx hy hxy · exact Or.inr ⟨by by_cases x = v <;> aesop, hxy⟩ lemma isClique_sup_edge_of_ne_iff {v w : α} {s : Set α} (h : v ≠ w) : (G ⊔ edge v w).IsClique s ↔ G.IsClique (s \ {v}) ∧ G.IsClique (s \ {w}) := ⟨fun h' ↦ ⟨h'.sdiff_of_sup_edge, (edge_comm .. ▸ h').sdiff_of_sup_edge⟩, fun h' ↦ isClique_sup_edge_of_ne_sdiff h h'.1 h'.2⟩ end Clique /-! ### `n`-cliques -/ section NClique variable {n : ℕ} {s : Finset α} /-- An `n`-clique in a graph is a set of `n` vertices which are pairwise connected. -/ structure IsNClique (n : ℕ) (s : Finset α) : Prop where isClique : G.IsClique s card_eq : #s = n theorem isNClique_iff : G.IsNClique n s ↔ G.IsClique s ∧ #s = n := ⟨fun h ↦ ⟨h.1, h.2⟩, fun h ↦ ⟨h.1, h.2⟩⟩ instance [DecidableEq α] [DecidableRel G.Adj] {n : ℕ} {s : Finset α} : Decidable (G.IsNClique n s) := decidable_of_iff' _ G.isNClique_iff variable {G H} {a b c : α} @[simp] lemma isNClique_empty : G.IsNClique n ∅ ↔ n = 0 := by simp [isNClique_iff, eq_comm] @[simp] lemma isNClique_singleton : G.IsNClique n {a} ↔ n = 1 := by simp [isNClique_iff, eq_comm] theorem IsNClique.mono (h : G ≤ H) : G.IsNClique n s → H.IsNClique n s := by simp_rw [isNClique_iff] exact And.imp_left (IsClique.mono h) protected theorem IsNClique.map (h : G.IsNClique n s) {f : α ↪ β} : (G.map f).IsNClique n (s.map f) := ⟨by rw [coe_map]; exact h.1.map, (card_map _).trans h.2⟩ theorem isNClique_map_iff (hn : 1 < n) {t : Finset β} {f : α ↪ β} : (G.map f).IsNClique n t ↔ ∃ s : Finset α, G.IsNClique n s ∧ s.map f = t := by rw [isNClique_iff, isClique_map_finset_iff, or_and_right, or_iff_right (by rintro ⟨h', rfl⟩; exact h'.not_lt hn)] constructor · rintro ⟨⟨s, hs, rfl⟩, rfl⟩ simp [isNClique_iff, hs] rintro ⟨s, hs, rfl⟩ simp [hs.card_eq, hs.isClique] @[simp] theorem isNClique_bot_iff : (⊥ : SimpleGraph α).IsNClique n s ↔ n ≤ 1 ∧ #s = n := by rw [isNClique_iff, isClique_bot_iff] refine and_congr_left ?_ rintro rfl exact card_le_one.symm @[simp] theorem isNClique_zero : G.IsNClique 0 s ↔ s = ∅ := by simp only [isNClique_iff, Finset.card_eq_zero, and_iff_right_iff_imp]; rintro rfl; simp @[simp] theorem isNClique_one : G.IsNClique 1 s ↔ ∃ a, s = {a} := by simp only [isNClique_iff, card_eq_one, and_iff_right_iff_imp]; rintro ⟨a, rfl⟩; simp section DecidableEq variable [DecidableEq α] protected theorem IsNClique.insert (hs : G.IsNClique n s) (h : ∀ b ∈ s, G.Adj a b) : G.IsNClique (n + 1) (insert a s) := by constructor · push_cast exact hs.1.insert fun b hb _ => h _ hb · rw [card_insert_of_not_mem fun ha => (h _ ha).ne rfl, hs.2] lemma IsNClique.erase_of_mem (hs : G.IsNClique n s) (ha : a ∈ s) : G.IsNClique (n - 1) (s.erase a) where isClique := hs.isClique.subset <\| by simp card_eq := by rw [card_erase_of_mem ha, hs.2] protected lemma IsNClique.insert_erase (hs : G.IsNClique n s) (ha : ∀ w ∈ s \ {b}, G.Adj a w) (hb : b ∈ s) : G.IsNClique n (insert a (erase s b)) := by cases n with \| zero => exact False.elim <\| not_mem_empty _ (isNClique_zero.1 hs ▸ hb) \| succ _ => exact (hs.erase_of_mem hb).insert fun w h ↦ by aesop theorem is3Clique_triple_iff : G.IsNClique 3 {a, b, c} ↔ G.Adj a b ∧ G.Adj a c ∧ G.Adj b c := by simp only [isNClique_iff, isClique_iff, Set.pairwise_insert_of_symmetric G.symm, coe_insert] by_cases hab : a = b <;> by_cases hbc : b = c <;> by_cases hac : a = c <;> subst_vars <;> simp [G.ne_of_adj, and_rotate, ] theorem is3Clique_iff : G.IsNClique 3 s ↔ ∃ a b c, G.Adj a b ∧ G.Adj a c ∧ G.Adj b c ∧ s = {a, b, c} := by refine ⟨fun h ↦ ?_, ?_⟩ · obtain ⟨a, b, c, -, -, -, hs⟩ := card_eq_three.1 h.card_eq refine ⟨a, b, c, ?_⟩ rwa [hs, eq_self_iff_true, and_true, is3Clique_triple_iff.symm, ← hs] · rintro ⟨a, b, c, hab, hbc, hca, rfl⟩ exact is3Clique_triple_iff.2 ⟨hab, hbc, hca⟩ end DecidableEq theorem is3Clique_iff_exists_cycle_length_three : (∃ s : Finset α, G.IsNClique 3 s) ↔ ∃ (u : α) (w : G.Walk u u), w.IsCycle ∧ w.length = 3 := by classical simp_rw [is3Clique_iff, isCycle_def] exact ⟨(fun ⟨_, a, _, _, hab, hac, hbc, _⟩ => ⟨a, cons hab (cons hbc (cons hac.symm nil)), by aesop⟩), (fun ⟨_, .cons hab (.cons hbc (.cons hca nil)), _, _⟩ => ⟨_, _, _, _, hab, hca.symm, hbc, rfl⟩)⟩ /-- If a set of vertices `A` is an `n`-clique in subgraph of `G` induced by a superset of `A`, its embedding is an `n`-clique in `G`. -/ theorem IsNClique.of_induce {S : Subgraph G} {F : Set α} {s : Finset { x // x ∈ F }} {n : ℕ} (cc : (S.induce F).coe.IsNClique n s) : G.IsNClique n (Finset.map ⟨Subtype.val, Subtype.val_injective⟩ s) := by rw [isNClique_iff] at cc ⊢ simp only [Subgraph.induce_verts, coe_map, card_map] exact ⟨cc.left.of_induce, cc.right⟩ lemma IsNClique.erase_of_sup_edge_of_mem [DecidableEq α] {v w : α} {s : Finset α} {n : ℕ} (hc : (G ⊔ edge v w).IsNClique n s) (hx : v ∈ s) : G.IsNClique (n - 1) (s.erase v) where isClique := coe_erase v _ ▸ hc.1.sdiff_of_sup_edge card_eq := by rw [card_erase_of_mem hx, hc.2] end NClique /-! ### Graphs without cliques -/ section CliqueFree variable {m n : ℕ} /-- `G.CliqueFree n` means that `G` has no `n`-cliques. -/ def CliqueFree (n : ℕ) : Prop := ∀ t, ¬G.IsNClique n t variable {G H} {s : Finset α} theorem IsNClique.not_cliqueFree (hG : G.IsNClique n s) : ¬G.CliqueFree n := fun h ↦ h _ hG theorem not_cliqueFree_of_top_embedding {n : ℕ} (f : (⊤ : SimpleGraph (Fin n)) ↪g G) : ¬G.CliqueFree n := by simp only [CliqueFree, isNClique_iff, isClique_iff_induce_eq, not_forall, Classical.not_not] use Finset.univ.map f.toEmbedding simp only [card_map, Finset.card_fin, eq_self_iff_true, and_true] ext ⟨v, hv⟩ ⟨w, hw⟩ simp only [coe_map, Set.mem_image, coe_univ, Set.mem_univ, true_and] at hv hw obtain ⟨v', rfl⟩ := hv obtain ⟨w', rfl⟩ := hw simp_rw [RelEmbedding.coe_toEmbedding, comap_adj, Function.Embedding.coe_subtype, f.map_adj_iff, top_adj, ne_eq, Subtype.mk.injEq, RelEmbedding.inj] /-- An embedding of a complete graph that witnesses the fact that the graph is not clique-free. -/ noncomputable def topEmbeddingOfNotCliqueFree {n : ℕ} (h : ¬G.CliqueFree n) : (⊤ : SimpleGraph (Fin n)) ↪g G := by simp only [CliqueFree, isNClique_iff, isClique_iff_induce_eq, not_forall, Classical.not_not] at h obtain ⟨ha, hb⟩ := h.choose_spec have : (⊤ : SimpleGraph (Fin #h.choose)) ≃g (⊤ : SimpleGraph h.choose) := by apply Iso.completeGraph simpa using (Fintype.equivFin h.choose).symm rw [← ha] at this convert (Embedding.induce ↑h.choose.toSet).comp this.toEmbedding exact hb.symm theorem not_cliqueFree_iff (n : ℕ) : ¬G.CliqueFree n ↔ Nonempty ((⊤ : SimpleGraph (Fin n)) ↪g G) := ⟨fun h ↦ ⟨topEmbeddingOfNotCliqueFree h⟩, fun ⟨f⟩ ↦ not_cliqueFree_of_top_embedding f⟩ theorem cliqueFree_iff {n : ℕ} : G.CliqueFree n ↔ IsEmpty ((⊤ : SimpleGraph (Fin n)) ↪g G) := by rw [← not_iff_not, not_cliqueFree_iff, not_isEmpty_iff] theorem not_cliqueFree_card_of_top_embedding [Fintype α] (f : (⊤ : SimpleGraph α) ↪g G) : ¬G.CliqueFree (card α) := by rw [not_cliqueFree_iff] exact ⟨(Iso.completeGraph (Fintype.equivFin α)).symm.toEmbedding.trans f⟩ @[simp] lemma not_cliqueFree_zero : ¬ G.CliqueFree 0 := fun h ↦ h ∅ <\| isNClique_empty.mpr rfl @[simp] theorem cliqueFree_bot (h : 2 ≤ n) : (⊥ : SimpleGraph α).CliqueFree n := by intro t ht have := le_trans h (isNClique_bot_iff.1 ht).1	contradiction theorem CliqueFree.mono (h : m ≤ n) : G.CliqueFree m → G.CliqueFree n := by	Mathlib/Combinatorics/SimpleGraph/Clique.lean	363	365
/- 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.Group.Action.Faithful import Mathlib.Algebra.Group.Nat.Defs import Mathlib.Algebra.Group.Prod import Mathlib.Algebra.Group.Submonoid.Basic import Mathlib.Algebra.Group.Submonoid.MulAction import Mathlib.Algebra.Group.TypeTags.Basic /-! # Operations on `Submonoid`s In this file we define various operations on `Submonoid`s and `MonoidHom`s. ## Main definitions ### Conversion between multiplicative and additive definitions * `Submonoid.toAddSubmonoid`, `Submonoid.toAddSubmonoid'`, `AddSubmonoid.toSubmonoid`, `AddSubmonoid.toSubmonoid'`: convert between multiplicative and additive submonoids of `M`, `Multiplicative M`, and `Additive M`. These are stated as `OrderIso`s. ### (Commutative) monoid structure on a submonoid * `Submonoid.toMonoid`, `Submonoid.toCommMonoid`: a submonoid inherits a (commutative) monoid structure. ### Group actions by submonoids * `Submonoid.MulAction`, `Submonoid.DistribMulAction`: a submonoid inherits (distributive) multiplicative actions. ### Operations on submonoids * `Submonoid.comap`: preimage of a submonoid under a monoid homomorphism as a submonoid of the domain; * `Submonoid.map`: image of a submonoid under a monoid homomorphism as a submonoid of the codomain; * `Submonoid.prod`: product of two submonoids `s : Submonoid M` and `t : Submonoid N` as a submonoid of `M × N`; ### Monoid homomorphisms between submonoid * `Submonoid.subtype`: embedding of a submonoid into the ambient monoid. * `Submonoid.inclusion`: given two submonoids `S`, `T` such that `S ≤ T`, `S.inclusion T` is the inclusion of `S` into `T` as a monoid homomorphism; * `MulEquiv.submonoidCongr`: converts a proof of `S = T` into a monoid isomorphism between `S` and `T`. * `Submonoid.prodEquiv`: monoid isomorphism between `s.prod t` and `s × t`; ### Operations on `MonoidHom`s * `MonoidHom.mrange`: range of a monoid homomorphism as a submonoid of the codomain; * `MonoidHom.mker`: kernel of a monoid homomorphism as a submonoid of the domain; * `MonoidHom.restrict`: restrict a monoid homomorphism to a submonoid; * `MonoidHom.codRestrict`: restrict the codomain of a monoid homomorphism to a submonoid; * `MonoidHom.mrangeRestrict`: restrict a monoid homomorphism to its range; ## Tags submonoid, range, product, map, comap -/ assert_not_exists MonoidWithZero open Function variable {M N P : Type} [MulOneClass M] [MulOneClass N] [MulOneClass P] (S : Submonoid M) /-! ### Conversion to/from `Additive`/`Multiplicative` -/ section /-- Submonoids of monoid `M` are isomorphic to additive submonoids of `Additive M`. -/ @[simps] def Submonoid.toAddSubmonoid : Submonoid M ≃o AddSubmonoid (Additive M) where toFun S := { carrier := Additive.toMul ⁻¹' S zero_mem' := S.one_mem' add_mem' := fun ha hb => S.mul_mem' ha hb } invFun S := { carrier := Additive.ofMul ⁻¹' S one_mem' := S.zero_mem' mul_mem' := fun ha hb => S.add_mem' ha hb} left_inv x := by cases x; rfl right_inv x := by cases x; rfl map_rel_iff' := Iff.rfl /-- Additive submonoids of an additive monoid `Additive M` are isomorphic to submonoids of `M`. -/ abbrev AddSubmonoid.toSubmonoid' : AddSubmonoid (Additive M) ≃o Submonoid M := Submonoid.toAddSubmonoid.symm theorem Submonoid.toAddSubmonoid_closure (S : Set M) : Submonoid.toAddSubmonoid (Submonoid.closure S) = AddSubmonoid.closure (Additive.toMul ⁻¹' S) := le_antisymm (Submonoid.toAddSubmonoid.le_symm_apply.1 <\| Submonoid.closure_le.2 (AddSubmonoid.subset_closure (M := Additive M))) (AddSubmonoid.closure_le.2 <\| Submonoid.subset_closure (M := M)) theorem AddSubmonoid.toSubmonoid'_closure (S : Set (Additive M)) : AddSubmonoid.toSubmonoid' (AddSubmonoid.closure S) = Submonoid.closure (Additive.ofMul ⁻¹' S) := le_antisymm (AddSubmonoid.toSubmonoid'.le_symm_apply.1 <\| AddSubmonoid.closure_le.2 (Submonoid.subset_closure (M := M))) (Submonoid.closure_le.2 <\| AddSubmonoid.subset_closure (M := Additive M)) end section variable {A : Type} [AddZeroClass A] /-- Additive submonoids of an additive monoid `A` are isomorphic to multiplicative submonoids of `Multiplicative A`. -/ @[simps] def AddSubmonoid.toSubmonoid : AddSubmonoid A ≃o Submonoid (Multiplicative A) where toFun S := { carrier := Multiplicative.toAdd ⁻¹' S one_mem' := S.zero_mem' mul_mem' := fun ha hb => S.add_mem' ha hb } invFun S := { carrier := Multiplicative.ofAdd ⁻¹' S zero_mem' := S.one_mem' add_mem' := fun ha hb => S.mul_mem' ha hb} left_inv x := by cases x; rfl right_inv x := by cases x; rfl map_rel_iff' := Iff.rfl /-- Submonoids of a monoid `Multiplicative A` are isomorphic to additive submonoids of `A`. -/ abbrev Submonoid.toAddSubmonoid' : Submonoid (Multiplicative A) ≃o AddSubmonoid A := AddSubmonoid.toSubmonoid.symm theorem AddSubmonoid.toSubmonoid_closure (S : Set A) : (AddSubmonoid.toSubmonoid) (AddSubmonoid.closure S) = Submonoid.closure (Multiplicative.toAdd ⁻¹' S) := le_antisymm (AddSubmonoid.toSubmonoid.to_galoisConnection.l_le <\| AddSubmonoid.closure_le.2 <\| Submonoid.subset_closure (M := Multiplicative A)) (Submonoid.closure_le.2 <\| AddSubmonoid.subset_closure (M := A)) theorem Submonoid.toAddSubmonoid'_closure (S : Set (Multiplicative A)) : Submonoid.toAddSubmonoid' (Submonoid.closure S) = AddSubmonoid.closure (Multiplicative.ofAdd ⁻¹' S) := le_antisymm (Submonoid.toAddSubmonoid'.to_galoisConnection.l_le <\| Submonoid.closure_le.2 <\| AddSubmonoid.subset_closure (M := A)) (AddSubmonoid.closure_le.2 <\| Submonoid.subset_closure (M := Multiplicative A)) end namespace Submonoid variable {F : Type} [FunLike F M N] [mc : MonoidHomClass F M N] open Set /-! ### `comap` and `map` -/ /-- The preimage of a submonoid along a monoid homomorphism is a submonoid. -/ @[to_additive "The preimage of an `AddSubmonoid` along an `AddMonoid` homomorphism is an `AddSubmonoid`."] def comap (f : F) (S : Submonoid N) : Submonoid M where carrier := f ⁻¹' S one_mem' := show f 1 ∈ S by rw [map_one]; exact S.one_mem mul_mem' ha hb := show f (_ _) ∈ S by rw [map_mul]; exact S.mul_mem ha hb @[to_additive (attr := simp)] theorem coe_comap (S : Submonoid N) (f : F) : (S.comap f : Set M) = f ⁻¹' S := rfl @[to_additive (attr := simp)] theorem mem_comap {S : Submonoid N} {f : F} {x : M} : x ∈ S.comap f ↔ f x ∈ S := Iff.rfl @[to_additive] theorem comap_comap (S : Submonoid P) (g : N →* P) (f : M →* N) : (S.comap g).comap f = S.comap (g.comp f) := rfl @[to_additive (attr := simp)] theorem comap_id (S : Submonoid P) : S.comap (MonoidHom.id P) = S := ext (by simp) /-- The image of a submonoid along a monoid homomorphism is a submonoid. -/ @[to_additive "The image of an `AddSubmonoid` along an `AddMonoid` homomorphism is an `AddSubmonoid`."] def map (f : F) (S : Submonoid M) : Submonoid N where carrier := f '' S one_mem' := ⟨1, S.one_mem, map_one f⟩ mul_mem' := by rintro _ _ ⟨x, hx, rfl⟩ ⟨y, hy, rfl⟩ exact ⟨x * y, S.mul_mem hx hy, by rw [map_mul]⟩ @[to_additive (attr := simp)] theorem coe_map (f : F) (S : Submonoid M) : (S.map f : Set N) = f '' S := rfl @[to_additive (attr := simp)] theorem map_coe_toMonoidHom (f : F) (S : Submonoid M) : S.map (f : M →* N) = S.map f := rfl @[to_additive (attr := simp)] theorem map_coe_toMulEquiv {F} [EquivLike F M N] [MulEquivClass F M N] (f : F) (S : Submonoid M) : S.map (f : M ≃* N) = S.map f := rfl @[to_additive (attr := simp)] theorem mem_map {f : F} {S : Submonoid M} {y : N} : y ∈ S.map f ↔ ∃ x ∈ S, f x = y := Iff.rfl @[to_additive] theorem mem_map_of_mem (f : F) {S : Submonoid M} {x : M} (hx : x ∈ S) : f x ∈ S.map f := mem_image_of_mem f hx @[to_additive] theorem apply_coe_mem_map (f : F) (S : Submonoid M) (x : S) : f x ∈ S.map f := mem_map_of_mem f x.2 @[to_additive] theorem map_map (g : N →* P) (f : M →* N) : (S.map f).map g = S.map (g.comp f) := SetLike.coe_injective <\| image_image _ _ _ -- The simpNF linter says that the LHS can be simplified via `Submonoid.mem_map`. -- However this is a higher priority lemma. -- It seems the side condition `hf` is not applied by `simpNF`. -- https://github.com/leanprover/std4/issues/207 @[to_additive (attr := simp 1100, nolint simpNF)] theorem mem_map_iff_mem {f : F} (hf : Function.Injective f) {S : Submonoid M} {x : M} : f x ∈ S.map f ↔ x ∈ S := hf.mem_set_image @[to_additive] theorem map_le_iff_le_comap {f : F} {S : Submonoid M} {T : Submonoid N} : S.map f ≤ T ↔ S ≤ T.comap f := image_subset_iff @[to_additive] theorem gc_map_comap (f : F) : GaloisConnection (map f) (comap f) := fun _ _ => map_le_iff_le_comap @[to_additive] theorem map_le_of_le_comap {T : Submonoid N} {f : F} : S ≤ T.comap f → S.map f ≤ T := (gc_map_comap f).l_le @[to_additive] theorem le_comap_of_map_le {T : Submonoid N} {f : F} : S.map f ≤ T → S ≤ T.comap f := (gc_map_comap f).le_u @[to_additive] theorem le_comap_map {f : F} : S ≤ (S.map f).comap f := (gc_map_comap f).le_u_l _ @[to_additive] theorem map_comap_le {S : Submonoid N} {f : F} : (S.comap f).map f ≤ S := (gc_map_comap f).l_u_le _ @[to_additive] theorem monotone_map {f : F} : Monotone (map f) := (gc_map_comap f).monotone_l @[to_additive] theorem monotone_comap {f : F} : Monotone (comap f) := (gc_map_comap f).monotone_u @[to_additive (attr := simp)] theorem map_comap_map {f : F} : ((S.map f).comap f).map f = S.map f := (gc_map_comap f).l_u_l_eq_l _ @[to_additive (attr := simp)] theorem comap_map_comap {S : Submonoid N} {f : F} : ((S.comap f).map f).comap f = S.comap f := (gc_map_comap f).u_l_u_eq_u _ @[to_additive] theorem map_sup (S T : Submonoid M) (f : F) : (S ⊔ T).map f = S.map f ⊔ T.map f := (gc_map_comap f : GaloisConnection (map f) (comap f)).l_sup @[to_additive] theorem map_iSup {ι : Sort} (f : F) (s : ι → Submonoid M) : (iSup s).map f = ⨆ i, (s i).map f := (gc_map_comap f : GaloisConnection (map f) (comap f)).l_iSup @[to_additive] theorem map_inf (S T : Submonoid M) (f : F) (hf : Function.Injective f) : (S ⊓ T).map f = S.map f ⊓ T.map f := SetLike.coe_injective (Set.image_inter hf) @[to_additive] theorem map_iInf {ι : Sort} [Nonempty ι] (f : F) (hf : Function.Injective f) (s : ι → Submonoid M) : (iInf s).map f = ⨅ i, (s i).map f := by apply SetLike.coe_injective simpa using (Set.injOn_of_injective hf).image_iInter_eq (s := SetLike.coe ∘ s) @[to_additive] theorem comap_inf (S T : Submonoid N) (f : F) : (S ⊓ T).comap f = S.comap f ⊓ T.comap f := (gc_map_comap f : GaloisConnection (map f) (comap f)).u_inf @[to_additive] theorem comap_iInf {ι : Sort} (f : F) (s : ι → Submonoid N) : (iInf s).comap f = ⨅ i, (s i).comap f := (gc_map_comap f : GaloisConnection (map f) (comap f)).u_iInf @[to_additive (attr := simp)] theorem map_bot (f : F) : (⊥ : Submonoid M).map f = ⊥ := (gc_map_comap f).l_bot @[to_additive (attr := simp)] theorem comap_top (f : F) : (⊤ : Submonoid N).comap f = ⊤ := (gc_map_comap f).u_top @[to_additive (attr := simp)] theorem map_id (S : Submonoid M) : S.map (MonoidHom.id M) = S := ext fun _ => ⟨fun ⟨_, h, rfl⟩ => h, fun h => ⟨_, h, rfl⟩⟩ section GaloisCoinsertion variable {ι : Type} {f : F} /-- `map f` and `comap f` form a `GaloisCoinsertion` when `f` is injective. -/ @[to_additive "`map f` and `comap f` form a `GaloisCoinsertion` when `f` is injective."] def gciMapComap (hf : Function.Injective f) : GaloisCoinsertion (map f) (comap f) := (gc_map_comap f).toGaloisCoinsertion fun S x => by simp [mem_comap, mem_map, hf.eq_iff] variable (hf : Function.Injective f) include hf @[to_additive] theorem comap_map_eq_of_injective (S : Submonoid M) : (S.map f).comap f = S := (gciMapComap hf).u_l_eq _ @[to_additive] theorem comap_surjective_of_injective : Function.Surjective (comap f) := (gciMapComap hf).u_surjective @[to_additive] theorem map_injective_of_injective : Function.Injective (map f) := (gciMapComap hf).l_injective @[to_additive] theorem comap_inf_map_of_injective (S T : Submonoid M) : (S.map f ⊓ T.map f).comap f = S ⊓ T := (gciMapComap hf).u_inf_l _ _ @[to_additive] theorem comap_iInf_map_of_injective (S : ι → Submonoid M) : (⨅ i, (S i).map f).comap f = iInf S := (gciMapComap hf).u_iInf_l _ @[to_additive] theorem comap_sup_map_of_injective (S T : Submonoid M) : (S.map f ⊔ T.map f).comap f = S ⊔ T := (gciMapComap hf).u_sup_l _ _ @[to_additive] theorem comap_iSup_map_of_injective (S : ι → Submonoid M) : (⨆ i, (S i).map f).comap f = iSup S := (gciMapComap hf).u_iSup_l _ @[to_additive] theorem map_le_map_iff_of_injective {S T : Submonoid M} : S.map f ≤ T.map f ↔ S ≤ T := (gciMapComap hf).l_le_l_iff @[to_additive] theorem map_strictMono_of_injective : StrictMono (map f) := (gciMapComap hf).strictMono_l end GaloisCoinsertion section GaloisInsertion variable {ι : Type} {f : F} /-- `map f` and `comap f` form a `GaloisInsertion` when `f` is surjective. -/ @[to_additive "`map f` and `comap f` form a `GaloisInsertion` when `f` is surjective."] def giMapComap (hf : Function.Surjective f) : GaloisInsertion (map f) (comap f) := (gc_map_comap f).toGaloisInsertion fun S x h => let ⟨y, hy⟩ := hf x mem_map.2 ⟨y, by simp [hy, h]⟩ variable (hf : Function.Surjective f) include hf @[to_additive] theorem map_comap_eq_of_surjective (S : Submonoid N) : (S.comap f).map f = S := (giMapComap hf).l_u_eq _ @[to_additive] theorem map_surjective_of_surjective : Function.Surjective (map f) := (giMapComap hf).l_surjective @[to_additive] theorem comap_injective_of_surjective : Function.Injective (comap f) := (giMapComap hf).u_injective @[to_additive] theorem map_inf_comap_of_surjective (S T : Submonoid N) : (S.comap f ⊓ T.comap f).map f = S ⊓ T := (giMapComap hf).l_inf_u _ _ @[to_additive] theorem map_iInf_comap_of_surjective (S : ι → Submonoid N) : (⨅ i, (S i).comap f).map f = iInf S := (giMapComap hf).l_iInf_u _ @[to_additive] theorem map_sup_comap_of_surjective (S T : Submonoid N) : (S.comap f ⊔ T.comap f).map f = S ⊔ T := (giMapComap hf).l_sup_u _ _ @[to_additive] theorem map_iSup_comap_of_surjective (S : ι → Submonoid N) : (⨆ i, (S i).comap f).map f = iSup S := (giMapComap hf).l_iSup_u _ @[to_additive] theorem comap_le_comap_iff_of_surjective {S T : Submonoid N} : S.comap f ≤ T.comap f ↔ S ≤ T := (giMapComap hf).u_le_u_iff @[to_additive] theorem comap_strictMono_of_surjective : StrictMono (comap f) := (giMapComap hf).strictMono_u end GaloisInsertion variable {M : Type} [MulOneClass M] (S : Submonoid M) /-- The top submonoid is isomorphic to the monoid. -/ @[to_additive (attr := simps) "The top additive submonoid is isomorphic to the additive monoid."] def topEquiv : (⊤ : Submonoid M) ≃* M where toFun x := x invFun x := ⟨x, mem_top x⟩ left_inv x := x.eta _ right_inv _ := rfl map_mul' _ _ := rfl @[to_additive (attr := simp)] theorem topEquiv_toMonoidHom : ((topEquiv : _ ≃* M) : _ →* M) = (⊤ : Submonoid M).subtype := rfl /-- A subgroup is isomorphic to its image under an injective function. If you have an isomorphism, use `MulEquiv.submonoidMap` for better definitional equalities. -/ @[to_additive "An additive subgroup is isomorphic to its image under an injective function. If you have an isomorphism, use `AddEquiv.addSubmonoidMap` for better definitional equalities."] noncomputable def equivMapOfInjective (f : M →* N) (hf : Function.Injective f) : S ≃* S.map f := { Equiv.Set.image f S hf with map_mul' := fun _ _ => Subtype.ext (f.map_mul _ _) } @[to_additive (attr := simp)] theorem coe_equivMapOfInjective_apply (f : M →* N) (hf : Function.Injective f) (x : S) : (equivMapOfInjective S f hf x : N) = f x := rfl @[to_additive (attr := simp)] theorem closure_closure_coe_preimage {s : Set M} : closure (((↑) : closure s → M) ⁻¹' s) = ⊤ := eq_top_iff.2 fun x _ ↦ Subtype.recOn x fun _ hx' ↦ closure_induction (fun _ h ↦ subset_closure h) (one_mem _) (fun _ _ _ _ ↦ mul_mem) hx' /-- Given submonoids `s`, `t` of monoids `M`, `N` respectively, `s × t` as a submonoid of `M × N`. -/ @[to_additive prod "Given `AddSubmonoid`s `s`, `t` of `AddMonoid`s `A`, `B` respectively, `s × t` as an `AddSubmonoid` of `A × B`."] def prod (s : Submonoid M) (t : Submonoid N) : Submonoid (M × N) where carrier := s ×ˢ t one_mem' := ⟨s.one_mem, t.one_mem⟩ mul_mem' hp hq := ⟨s.mul_mem hp.1 hq.1, t.mul_mem hp.2 hq.2⟩ @[to_additive coe_prod] theorem coe_prod (s : Submonoid M) (t : Submonoid N) : (s.prod t : Set (M × N)) = (s : Set M) ×ˢ (t : Set N) := rfl @[to_additive mem_prod] theorem mem_prod {s : Submonoid M} {t : Submonoid N} {p : M × N} : p ∈ s.prod t ↔ p.1 ∈ s ∧ p.2 ∈ t := Iff.rfl @[to_additive prod_mono] theorem prod_mono {s₁ s₂ : Submonoid M} {t₁ t₂ : Submonoid N} (hs : s₁ ≤ s₂) (ht : t₁ ≤ t₂) : s₁.prod t₁ ≤ s₂.prod t₂ := Set.prod_mono hs ht @[to_additive prod_top] theorem prod_top (s : Submonoid M) : s.prod (⊤ : Submonoid N) = s.comap (MonoidHom.fst M N) := ext fun x => by simp [mem_prod, MonoidHom.coe_fst] @[to_additive top_prod] theorem top_prod (s : Submonoid N) : (⊤ : Submonoid M).prod s = s.comap (MonoidHom.snd M N) := ext fun x => by simp [mem_prod, MonoidHom.coe_snd] @[to_additive (attr := simp) top_prod_top] theorem top_prod_top : (⊤ : Submonoid M).prod (⊤ : Submonoid N) = ⊤ := (top_prod _).trans <\| comap_top _ @[to_additive bot_prod_bot] theorem bot_prod_bot : (⊥ : Submonoid M).prod (⊥ : Submonoid N) = ⊥ := SetLike.coe_injective <\| by simp [coe_prod] /-- The product of submonoids is isomorphic to their product as monoids. -/ @[to_additive prodEquiv "The product of additive submonoids is isomorphic to their product as additive monoids"] def prodEquiv (s : Submonoid M) (t : Submonoid N) : s.prod t ≃* s × t := { (Equiv.Set.prod (s : Set M) (t : Set N)) with map_mul' := fun _ _ => rfl } open MonoidHom @[to_additive] theorem map_inl (s : Submonoid M) : s.map (inl M N) = s.prod ⊥ := ext fun p => ⟨fun ⟨_, hx, hp⟩ => hp ▸ ⟨hx, Set.mem_singleton 1⟩, fun ⟨hps, hp1⟩ => ⟨p.1, hps, Prod.ext rfl <\| (Set.eq_of_mem_singleton hp1).symm⟩⟩ @[to_additive] theorem map_inr (s : Submonoid N) : s.map (inr M N) = prod ⊥ s := ext fun p => ⟨fun ⟨_, hx, hp⟩ => hp ▸ ⟨Set.mem_singleton 1, hx⟩, fun ⟨hp1, hps⟩ => ⟨p.2, hps, Prod.ext (Set.eq_of_mem_singleton hp1).symm rfl⟩⟩ @[to_additive (attr := simp) prod_bot_sup_bot_prod] theorem prod_bot_sup_bot_prod (s : Submonoid M) (t : Submonoid N) : (prod s ⊥) ⊔ (prod ⊥ t) = prod s t := (le_antisymm (sup_le (prod_mono (le_refl s) bot_le) (prod_mono bot_le (le_refl t)))) fun p hp => Prod.fst_mul_snd p ▸ mul_mem ((le_sup_left : prod s ⊥ ≤ prod s ⊥ ⊔ prod ⊥ t) ⟨hp.1, Set.mem_singleton 1⟩) ((le_sup_right : prod ⊥ t ≤ prod s ⊥ ⊔ prod ⊥ t) ⟨Set.mem_singleton 1, hp.2⟩) @[to_additive] theorem mem_map_equiv {f : M ≃* N} {K : Submonoid M} {x : N} : x ∈ K.map f.toMonoidHom ↔ f.symm x ∈ K := Set.mem_image_equiv @[to_additive] theorem map_equiv_eq_comap_symm (f : M ≃* N) (K : Submonoid M) : K.map f = K.comap f.symm := SetLike.coe_injective (f.toEquiv.image_eq_preimage K) @[to_additive] theorem comap_equiv_eq_map_symm (f : N ≃* M) (K : Submonoid M) : K.comap f = K.map f.symm := (map_equiv_eq_comap_symm f.symm K).symm @[to_additive (attr := simp)] theorem map_equiv_top (f : M ≃* N) : (⊤ : Submonoid M).map f = ⊤ := SetLike.coe_injective <\| Set.image_univ.trans f.surjective.range_eq @[to_additive le_prod_iff] theorem le_prod_iff {s : Submonoid M} {t : Submonoid N} {u : Submonoid (M × N)} : u ≤ s.prod t ↔ u.map (fst M N) ≤ s ∧ u.map (snd M N) ≤ t := by constructor · intro h constructor · rintro x ⟨⟨y1, y2⟩, ⟨hy1, rfl⟩⟩ exact (h hy1).1 · rintro x ⟨⟨y1, y2⟩, ⟨hy1, rfl⟩⟩ exact (h hy1).2 · rintro ⟨hH, hK⟩ ⟨x1, x2⟩ h exact ⟨hH ⟨_, h, rfl⟩, hK ⟨_, h, rfl⟩⟩ @[to_additive prod_le_iff] theorem prod_le_iff {s : Submonoid M} {t : Submonoid N} {u : Submonoid (M × N)} : s.prod t ≤ u ↔ s.map (inl M N) ≤ u ∧ t.map (inr M N) ≤ u := by constructor · intro h constructor · rintro _ ⟨x, hx, rfl⟩ apply h exact ⟨hx, Submonoid.one_mem _⟩ · rintro _ ⟨x, hx, rfl⟩ apply h exact ⟨Submonoid.one_mem _, hx⟩ · rintro ⟨hH, hK⟩ ⟨x1, x2⟩ ⟨h1, h2⟩ have h1' : inl M N x1 ∈ u := by apply hH simpa using h1 have h2' : inr M N x2 ∈ u := by apply hK simpa using h2 simpa using Submonoid.mul_mem _ h1' h2' @[to_additive closure_prod] theorem closure_prod {s : Set M} {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_of_le_comap _ <\| closure_le.2 fun _x hx => subset_closure ⟨hx, ht⟩, map_le_of_le_comap _ <\| closure_le.2 fun _y hy => subset_closure ⟨hs, hy⟩⟩) @[to_additive (attr := simp) closure_prod_zero] lemma closure_prod_one (s : Set M) : closure (s ×ˢ ({1} : Set N)) = (closure s).prod ⊥ := le_antisymm (closure_le.2 <\| Set.prod_subset_prod_iff.2 <\| .inl ⟨subset_closure, .rfl⟩) (prod_le_iff.2 ⟨ map_le_of_le_comap _ <\| closure_le.2 fun _x hx => subset_closure ⟨hx, rfl⟩, by simp⟩) @[to_additive (attr := simp) closure_zero_prod] lemma closure_one_prod (t : Set N) : closure (({1} : Set M) ×ˢ t) = .prod ⊥ (closure t) := le_antisymm (closure_le.2 <\| Set.prod_subset_prod_iff.2 <\| .inl ⟨.rfl, subset_closure⟩) (prod_le_iff.2 ⟨by simp, map_le_of_le_comap _ <\| closure_le.2 fun _y hy => subset_closure ⟨rfl, hy⟩⟩) end Submonoid namespace MonoidHom variable {F : Type} [FunLike F M N] [mc : MonoidHomClass F M N] open Submonoid library_note "range copy pattern"/-- For many categories (monoids, modules, rings, ...) the set-theoretic image of a morphism `f` is a subobject of the codomain. When this is the case, it is useful to define the range of a morphism in such a way that the underlying carrier set of the range subobject is definitionally `Set.range f`. In particular this means that the types `↥(Set.range f)` and `↥f.range` are interchangeable without proof obligations. A convenient candidate definition for range which is mathematically correct is `map ⊤ f`, just as `Set.range` could have been defined as `f '' Set.univ`. However, this lacks the desired definitional convenience, in that it both does not match `Set.range`, and that it introduces a redundant `x ∈ ⊤` term which clutters proofs. In such a case one may resort to the `copy` pattern. A `copy` function converts the definitional problem for the carrier set of a subobject into a one-off propositional proof obligation which one discharges while writing the definition of the definitionally convenient range (the parameter `hs` in the example below). A good example is the case of a morphism of monoids. A convenient definition for `MonoidHom.mrange` would be `(⊤ : Submonoid M).map f`. However since this lacks the required definitional convenience, we first define `Submonoid.copy` as follows: ```lean protected def copy (S : Submonoid M) (s : Set M) (hs : s = S) : Submonoid M := { carrier := s, one_mem' := hs.symm ▸ S.one_mem', mul_mem' := hs.symm ▸ S.mul_mem' } ``` and then finally define: ```lean def mrange (f : M → N) : Submonoid N := ((⊤ : Submonoid M).map f).copy (Set.range f) Set.image_univ.symm ``` -/ /-- The range of a monoid homomorphism is a submonoid. See Note [range copy pattern]. -/ @[to_additive "The range of an `AddMonoidHom` is an `AddSubmonoid`."] def mrange (f : F) : Submonoid N := ((⊤ : Submonoid M).map f).copy (Set.range f) Set.image_univ.symm @[to_additive (attr := simp)] theorem coe_mrange (f : F) : (mrange f : Set N) = Set.range f := rfl @[to_additive (attr := simp)] theorem mem_mrange {f : F} {y : N} : y ∈ mrange f ↔ ∃ x, f x = y := Iff.rfl @[to_additive] lemma mrange_comp {O : Type} [MulOneClass O] (f : N → O) (g : M →* N) : mrange (f.comp g) = (mrange g).map f := SetLike.coe_injective <\| Set.range_comp f _ @[to_additive] theorem mrange_eq_map (f : F) : mrange f = (⊤ : Submonoid M).map f := Submonoid.copy_eq _ @[to_additive (attr := simp)] theorem mrange_id : mrange (MonoidHom.id M) = ⊤ := by simp [mrange_eq_map] @[to_additive] theorem map_mrange (g : N →* P) (f : M →* N) : (mrange f).map g = mrange (comp g f) := by simpa only [mrange_eq_map] using (⊤ : Submonoid M).map_map g f @[to_additive] theorem mrange_eq_top {f : F} : mrange f = (⊤ : Submonoid N) ↔ Surjective f := SetLike.ext'_iff.trans <\| Iff.trans (by rw [coe_mrange, coe_top]) Set.range_eq_univ @[deprecated (since := "2024-11-11")] alias mrange_top_iff_surjective := mrange_eq_top /-- The range of a surjective monoid hom is the whole of the codomain. -/ @[to_additive (attr := simp) "The range of a surjective `AddMonoid` hom is the whole of the codomain."] theorem mrange_eq_top_of_surjective (f : F) (hf : Function.Surjective f) : mrange f = (⊤ : Submonoid N) := mrange_eq_top.2 hf @[deprecated (since := "2024-11-11")] alias mrange_top_of_surjective := mrange_eq_top_of_surjective @[to_additive] theorem mclosure_preimage_le (f : F) (s : Set N) : closure (f ⁻¹' s) ≤ (closure s).comap f := closure_le.2 fun _ hx => SetLike.mem_coe.2 <\| mem_comap.2 <\| subset_closure hx /-- The image under a monoid hom of the submonoid generated by a set equals the submonoid generated by the image of the set. -/ @[to_additive "The image under an `AddMonoid` hom of the `AddSubmonoid` generated by a set equals the `AddSubmonoid` generated by the image of the set."] theorem map_mclosure (f : F) (s : Set M) : (closure s).map f = closure (f '' s) := Set.image_preimage.l_comm_of_u_comm (gc_map_comap f) (Submonoid.gi N).gc (Submonoid.gi M).gc fun _ ↦ rfl @[to_additive (attr := simp)] theorem mclosure_range (f : F) : closure (Set.range f) = mrange f := by rw [← Set.image_univ, ← map_mclosure, mrange_eq_map, closure_univ] /-- Restriction of a monoid hom to a submonoid of the domain. -/ @[to_additive "Restriction of an `AddMonoid` hom to an `AddSubmonoid` of the domain."] def restrict {N S : Type} [MulOneClass N] [SetLike S M] [SubmonoidClass S M] (f : M → N) (s : S) : s →* N := f.comp (SubmonoidClass.subtype _) @[to_additive (attr := simp)] theorem restrict_apply {N S : Type} [MulOneClass N] [SetLike S M] [SubmonoidClass S M] (f : M → N) (s : S) (x : s) : f.restrict s x = f x := rfl @[to_additive (attr := simp)] theorem restrict_mrange (f : M →* N) : mrange (f.restrict S) = S.map f := by simp [SetLike.ext_iff] /-- Restriction of a monoid hom to a submonoid of the codomain. -/ @[to_additive (attr := simps apply) "Restriction of an `AddMonoid` hom to an `AddSubmonoid` of the codomain."] def codRestrict {S} [SetLike S N] [SubmonoidClass S N] (f : M →* N) (s : S) (h : ∀ x, f x ∈ s) : M →* s where toFun n := ⟨f n, h n⟩ map_one' := Subtype.eq f.map_one map_mul' x y := Subtype.eq (f.map_mul x y) @[to_additive (attr := simp)] lemma injective_codRestrict {S} [SetLike S N] [SubmonoidClass S N] (f : M →* N) (s : S) (h : ∀ x, f x ∈ s) : Function.Injective (f.codRestrict s h) ↔ Function.Injective f := ⟨fun H _ _ hxy ↦ H <\| Subtype.eq hxy, fun H _ _ hxy ↦ H (congr_arg Subtype.val hxy)⟩ /-- Restriction of a monoid hom to its range interpreted as a submonoid. -/ @[to_additive "Restriction of an `AddMonoid` hom to its range interpreted as a submonoid."] def mrangeRestrict {N} [MulOneClass N] (f : M →* N) : M →* (mrange f) := (f.codRestrict (mrange f)) fun x => ⟨x, rfl⟩ @[to_additive (attr := simp)] theorem coe_mrangeRestrict {N} [MulOneClass N] (f : M →* N) (x : M) : (f.mrangeRestrict x : N) = f x := rfl @[to_additive] theorem mrangeRestrict_surjective (f : M →* N) : Function.Surjective f.mrangeRestrict := fun ⟨_, ⟨x, rfl⟩⟩ => ⟨x, rfl⟩ /-- The multiplicative kernel of a monoid hom is the submonoid of elements `x : G` such that `f x = 1` -/ @[to_additive "The additive kernel of an `AddMonoid` hom is the `AddSubmonoid` of elements such that `f x = 0`"] def mker (f : F) : Submonoid M := (⊥ : Submonoid N).comap f @[to_additive (attr := simp)] theorem mem_mker {f : F} {x : M} : x ∈ mker f ↔ f x = 1 := Iff.rfl @[to_additive] theorem coe_mker (f : F) : (mker f : Set M) = (f : M → N) ⁻¹' {1} := rfl @[to_additive] instance decidableMemMker [DecidableEq N] (f : F) : DecidablePred (· ∈ mker f) := fun x => decidable_of_iff (f x = 1) mem_mker @[to_additive] theorem comap_mker (g : N →* P) (f : M →* N) : (mker g).comap f = mker (comp g f) := rfl @[to_additive (attr := simp)] theorem comap_bot' (f : F) : (⊥ : Submonoid N).comap f = mker f := rfl @[to_additive (attr := simp)] theorem restrict_mker (f : M →* N) : mker (f.restrict S) = (MonoidHom.mker f).comap S.subtype := rfl @[to_additive] theorem mrangeRestrict_mker (f : M →* N) : mker (mrangeRestrict f) = mker f := by ext x change (⟨f x, _⟩ : mrange f) = ⟨1, _⟩ ↔ f x = 1 simp @[to_additive (attr := simp)] theorem mker_one : mker (1 : M →* N) = ⊤ := by ext simp [mem_mker] @[to_additive prod_map_comap_prod'] theorem prod_map_comap_prod' {M' : Type} {N' : Type} [MulOneClass M'] [MulOneClass N'] (f : M →* N) (g : M' →* N') (S : Submonoid N) (S' : Submonoid 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 _ _ @[to_additive mker_prod_map] theorem mker_prod_map {M' : Type} {N' : Type} [MulOneClass M'] [MulOneClass N'] (f : M →* N) (g : M' →* N') : mker (prodMap f g) = (mker f).prod (mker g) := by rw [← comap_bot', ← comap_bot', ← comap_bot', ← prod_map_comap_prod', bot_prod_bot] @[to_additive (attr := simp)] theorem mker_inl : mker (inl M N) = ⊥ := by ext x simp [mem_mker] @[to_additive (attr := simp)] theorem mker_inr : mker (inr M N) = ⊥ := by ext x simp [mem_mker] @[to_additive (attr := simp)] lemma mker_fst : mker (fst M N) = .prod ⊥ ⊤ := SetLike.ext fun _ => (iff_of_eq (and_true _)).symm @[to_additive (attr := simp)] lemma mker_snd : mker (snd M N) = .prod ⊤ ⊥ := SetLike.ext fun _ => (iff_of_eq (true_and _)).symm /-- The `MonoidHom` from the preimage of a submonoid to itself. -/ @[to_additive (attr := simps) "the `AddMonoidHom` from the preimage of an additive submonoid to itself."] def submonoidComap (f : M →* N) (N' : Submonoid N) : N'.comap f →* N' where toFun x := ⟨f x, x.2⟩ map_one' := Subtype.eq f.map_one map_mul' x y := Subtype.eq (f.map_mul x y) @[to_additive] lemma submonoidComap_surjective_of_surjective (f : M →* N) (N' : Submonoid N) (hf : Surjective f) : Surjective (f.submonoidComap N') := fun y ↦ by obtain ⟨x, hx⟩ := hf y use ⟨x, mem_comap.mpr (hx ▸ y.2)⟩ apply Subtype.val_injective simp [hx] /-- The `MonoidHom` from a submonoid to its image. See `MulEquiv.SubmonoidMap` for a variant for `MulEquiv`s. -/ @[to_additive (attr := simps) "the `AddMonoidHom` from an additive submonoid to its image. See `AddEquiv.AddSubmonoidMap` for a variant for `AddEquiv`s."] def submonoidMap (f : M →* N) (M' : Submonoid M) : M' →* M'.map f where toFun x := ⟨f x, ⟨x, x.2, rfl⟩⟩ map_one' := Subtype.eq <\| f.map_one map_mul' x y := Subtype.eq <\| f.map_mul x y @[to_additive] theorem submonoidMap_surjective (f : M →* N) (M' : Submonoid M) : Function.Surjective (f.submonoidMap M') := by rintro ⟨_, x, hx, rfl⟩ exact ⟨⟨x, hx⟩, rfl⟩ end MonoidHom namespace Submonoid open MonoidHom @[to_additive] theorem mrange_inl : mrange (inl M N) = prod ⊤ ⊥ := by simpa only [mrange_eq_map] using map_inl ⊤ @[to_additive] theorem mrange_inr : mrange (inr M N) = prod ⊥ ⊤ := by simpa only [mrange_eq_map] using map_inr ⊤ @[to_additive] theorem mrange_inl' : mrange (inl M N) = comap (snd M N) ⊥ := mrange_inl.trans (top_prod _) @[to_additive] theorem mrange_inr' : mrange (inr M N) = comap (fst M N) ⊥ := mrange_inr.trans (prod_top _) @[to_additive (attr := simp)] theorem mrange_fst : mrange (fst M N) = ⊤ := mrange_eq_top_of_surjective (fst M N) <\| @Prod.fst_surjective _ _ ⟨1⟩ @[to_additive (attr := simp)] theorem mrange_snd : mrange (snd M N) = ⊤ := mrange_eq_top_of_surjective (snd M N) <\| @Prod.snd_surjective _ _ ⟨1⟩ @[to_additive prod_eq_bot_iff] theorem prod_eq_bot_iff {s : Submonoid M} {t : Submonoid N} : s.prod t = ⊥ ↔ s = ⊥ ∧ t = ⊥ := by simp only [eq_bot_iff, prod_le_iff, (gc_map_comap _).le_iff_le, comap_bot', mker_inl, mker_inr]	@[to_additive prod_eq_top_iff] theorem prod_eq_top_iff {s : Submonoid M} {t : Submonoid N} : s.prod t = ⊤ ↔ s = ⊤ ∧ t = ⊤ := by simp only [eq_top_iff, le_prod_iff, ← (gc_map_comap _).le_iff_le, ← mrange_eq_map, mrange_fst, mrange_snd] @[to_additive (attr := simp)] theorem mrange_inl_sup_mrange_inr : mrange (inl M N) ⊔ mrange (inr M N) = ⊤ := by simp only [mrange_inl, mrange_inr, prod_bot_sup_bot_prod, top_prod_top] /-- The monoid hom associated to an inclusion of submonoids. -/ @[to_additive	Mathlib/Algebra/Group/Submonoid/Operations.lean	883	893
/- Copyright (c) 2017 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Kim Morrison -/ import Mathlib.Algebra.BigOperators.Finsupp.Basic import Mathlib.Algebra.BigOperators.Group.Finset.Preimage import Mathlib.Algebra.Module.Defs import Mathlib.Data.Rat.BigOperators /-! # Miscellaneous definitions, lemmas, and constructions using finsupp ## Main declarations * `Finsupp.graph`: the finset of input and output pairs with non-zero outputs. * `Finsupp.mapRange.equiv`: `Finsupp.mapRange` as an equiv. * `Finsupp.mapDomain`: maps the domain of a `Finsupp` by a function and by summing. * `Finsupp.comapDomain`: postcomposition of a `Finsupp` with a function injective on the preimage of its support. * `Finsupp.some`: restrict a finitely supported function on `Option α` to a finitely supported function on `α`. * `Finsupp.filter`: `filter p f` is the finitely supported function that is `f a` if `p a` is true and 0 otherwise. * `Finsupp.frange`: the image of a finitely supported function on its support. * `Finsupp.subtype_domain`: the restriction of a finitely supported function `f` to a subtype. ## Implementation notes This file is a `noncomputable theory` and uses classical logic throughout. ## TODO * This file is currently ~1600 lines long and is quite a miscellany of definitions and lemmas, so it should be divided into smaller pieces. * Expand the list of definitions and important lemmas to the module docstring. -/ noncomputable section open Finset Function variable {α β γ ι M M' N P G H R S : Type} namespace Finsupp /-! ### Declarations about `graph` -/ section Graph variable [Zero M] /-- The graph of a finitely supported function over its support, i.e. the finset of input and output pairs with non-zero outputs. -/ def graph (f : α →₀ M) : Finset (α × M) := f.support.map ⟨fun a => Prod.mk a (f a), fun _ _ h => (Prod.mk.inj h).1⟩ theorem mk_mem_graph_iff {a : α} {m : M} {f : α →₀ M} : (a, m) ∈ f.graph ↔ f a = m ∧ m ≠ 0 := by simp_rw [graph, mem_map, mem_support_iff] constructor · rintro ⟨b, ha, rfl, -⟩ exact ⟨rfl, ha⟩ · rintro ⟨rfl, ha⟩ exact ⟨a, ha, rfl⟩ @[simp] theorem mem_graph_iff {c : α × M} {f : α →₀ M} : c ∈ f.graph ↔ f c.1 = c.2 ∧ c.2 ≠ 0 := by cases c exact mk_mem_graph_iff theorem mk_mem_graph (f : α →₀ M) {a : α} (ha : a ∈ f.support) : (a, f a) ∈ f.graph := mk_mem_graph_iff.2 ⟨rfl, mem_support_iff.1 ha⟩ theorem apply_eq_of_mem_graph {a : α} {m : M} {f : α →₀ M} (h : (a, m) ∈ f.graph) : f a = m := (mem_graph_iff.1 h).1 @[simp 1100] -- Higher priority shortcut instance for `mem_graph_iff`. theorem not_mem_graph_snd_zero (a : α) (f : α →₀ M) : (a, (0 : M)) ∉ f.graph := fun h => (mem_graph_iff.1 h).2.irrefl @[simp] theorem image_fst_graph [DecidableEq α] (f : α →₀ M) : f.graph.image Prod.fst = f.support := by classical simp only [graph, map_eq_image, image_image, Embedding.coeFn_mk, Function.comp_def, image_id'] theorem graph_injective (α M) [Zero M] : Injective (@graph α M _) := by intro f g h classical have hsup : f.support = g.support := by rw [← image_fst_graph, h, image_fst_graph] refine ext_iff'.2 ⟨hsup, fun x hx => apply_eq_of_mem_graph <\| h.symm ▸ ?_⟩ exact mk_mem_graph _ (hsup ▸ hx) @[simp] theorem graph_inj {f g : α →₀ M} : f.graph = g.graph ↔ f = g := (graph_injective α M).eq_iff @[simp] theorem graph_zero : graph (0 : α →₀ M) = ∅ := by simp [graph] @[simp] theorem graph_eq_empty {f : α →₀ M} : f.graph = ∅ ↔ f = 0 := (graph_injective α M).eq_iff' graph_zero end Graph end Finsupp /-! ### Declarations about `mapRange` -/ section MapRange namespace Finsupp section Equiv variable [Zero M] [Zero N] [Zero P] /-- `Finsupp.mapRange` as an equiv. -/ @[simps apply] def mapRange.equiv (f : M ≃ N) (hf : f 0 = 0) (hf' : f.symm 0 = 0) : (α →₀ M) ≃ (α →₀ N) where toFun := (mapRange f hf : (α →₀ M) → α →₀ N) invFun := (mapRange f.symm hf' : (α →₀ N) → α →₀ M) left_inv x := by rw [← mapRange_comp _ _ _ _] <;> simp_rw [Equiv.symm_comp_self] · exact mapRange_id _ · rfl right_inv x := by rw [← mapRange_comp _ _ _ _] <;> simp_rw [Equiv.self_comp_symm] · exact mapRange_id _ · rfl @[simp] theorem mapRange.equiv_refl : mapRange.equiv (Equiv.refl M) rfl rfl = Equiv.refl (α →₀ M) := Equiv.ext mapRange_id theorem mapRange.equiv_trans (f : M ≃ N) (hf : f 0 = 0) (hf') (f₂ : N ≃ P) (hf₂ : f₂ 0 = 0) (hf₂') : (mapRange.equiv (f.trans f₂) (by rw [Equiv.trans_apply, hf, hf₂]) (by rw [Equiv.symm_trans_apply, hf₂', hf']) : (α →₀ _) ≃ _) = (mapRange.equiv f hf hf').trans (mapRange.equiv f₂ hf₂ hf₂') := Equiv.ext <\| mapRange_comp f₂ hf₂ f hf ((congrArg f₂ hf).trans hf₂) @[simp] theorem mapRange.equiv_symm (f : M ≃ N) (hf hf') : ((mapRange.equiv f hf hf').symm : (α →₀ _) ≃ _) = mapRange.equiv f.symm hf' hf := Equiv.ext fun _ => rfl end Equiv section ZeroHom variable [Zero M] [Zero N] [Zero P] /-- Composition with a fixed zero-preserving homomorphism is itself a zero-preserving homomorphism on functions. -/ @[simps] def mapRange.zeroHom (f : ZeroHom M N) : ZeroHom (α →₀ M) (α →₀ N) where toFun := (mapRange f f.map_zero : (α →₀ M) → α →₀ N) map_zero' := mapRange_zero @[simp] theorem mapRange.zeroHom_id : mapRange.zeroHom (ZeroHom.id M) = ZeroHom.id (α →₀ M) := ZeroHom.ext mapRange_id theorem mapRange.zeroHom_comp (f : ZeroHom N P) (f₂ : ZeroHom M N) : (mapRange.zeroHom (f.comp f₂) : ZeroHom (α →₀ _) _) = (mapRange.zeroHom f).comp (mapRange.zeroHom f₂) := ZeroHom.ext <\| mapRange_comp f (map_zero f) f₂ (map_zero f₂) (by simp only [comp_apply, map_zero]) end ZeroHom section AddMonoidHom variable [AddCommMonoid M] [AddCommMonoid N] [AddCommMonoid P] variable {F : Type} [FunLike F M N] [AddMonoidHomClass F M N] /-- Composition with a fixed additive homomorphism is itself an additive homomorphism on functions. -/ @[simps] def mapRange.addMonoidHom (f : M →+ N) : (α →₀ M) →+ α →₀ N where toFun := (mapRange f f.map_zero : (α →₀ M) → α →₀ N) map_zero' := mapRange_zero -- Porting note: need either `dsimp only` or to specify `hf`: -- see also: https://github.com/leanprover-community/mathlib4/issues/12129 map_add' := mapRange_add (hf := f.map_zero) f.map_add @[simp] theorem mapRange.addMonoidHom_id : mapRange.addMonoidHom (AddMonoidHom.id M) = AddMonoidHom.id (α →₀ M) := AddMonoidHom.ext mapRange_id theorem mapRange.addMonoidHom_comp (f : N →+ P) (f₂ : M →+ N) : (mapRange.addMonoidHom (f.comp f₂) : (α →₀ _) →+ _) = (mapRange.addMonoidHom f).comp (mapRange.addMonoidHom f₂) := AddMonoidHom.ext <\| mapRange_comp f (map_zero f) f₂ (map_zero f₂) (by simp only [comp_apply, map_zero]) @[simp] theorem mapRange.addMonoidHom_toZeroHom (f : M →+ N) : (mapRange.addMonoidHom f).toZeroHom = (mapRange.zeroHom f.toZeroHom : ZeroHom (α →₀ _) _) := ZeroHom.ext fun _ => rfl theorem mapRange_multiset_sum (f : F) (m : Multiset (α →₀ M)) : mapRange f (map_zero f) m.sum = (m.map fun x => mapRange f (map_zero f) x).sum := (mapRange.addMonoidHom (f : M →+ N) : (α →₀ _) →+ _).map_multiset_sum _ theorem mapRange_finset_sum (f : F) (s : Finset ι) (g : ι → α →₀ M) : mapRange f (map_zero f) (∑ x ∈ s, g x) = ∑ x ∈ s, mapRange f (map_zero f) (g x) := map_sum (mapRange.addMonoidHom (f : M →+ N)) _ _ /-- `Finsupp.mapRange.AddMonoidHom` as an equiv. -/ @[simps apply] def mapRange.addEquiv (f : M ≃+ N) : (α →₀ M) ≃+ (α →₀ N) := { mapRange.addMonoidHom f.toAddMonoidHom with toFun := (mapRange f f.map_zero : (α →₀ M) → α →₀ N) invFun := (mapRange f.symm f.symm.map_zero : (α →₀ N) → α →₀ M) left_inv := fun x => by rw [← mapRange_comp _ _ _ _] <;> simp_rw [AddEquiv.symm_comp_self] · exact mapRange_id _ · rfl right_inv := fun x => by rw [← mapRange_comp _ _ _ _] <;> simp_rw [AddEquiv.self_comp_symm] · exact mapRange_id _ · rfl } @[simp] theorem mapRange.addEquiv_refl : mapRange.addEquiv (AddEquiv.refl M) = AddEquiv.refl (α →₀ M) := AddEquiv.ext mapRange_id theorem mapRange.addEquiv_trans (f : M ≃+ N) (f₂ : N ≃+ P) : (mapRange.addEquiv (f.trans f₂) : (α →₀ M) ≃+ (α →₀ P)) = (mapRange.addEquiv f).trans (mapRange.addEquiv f₂) := AddEquiv.ext (mapRange_comp _ f₂.map_zero _ f.map_zero (by simp)) @[simp] theorem mapRange.addEquiv_symm (f : M ≃+ N) : ((mapRange.addEquiv f).symm : (α →₀ _) ≃+ _) = mapRange.addEquiv f.symm := AddEquiv.ext fun _ => rfl @[simp] theorem mapRange.addEquiv_toAddMonoidHom (f : M ≃+ N) : ((mapRange.addEquiv f : (α →₀ _) ≃+ _) : _ →+ _) = (mapRange.addMonoidHom f.toAddMonoidHom : (α →₀ _) →+ _) := AddMonoidHom.ext fun _ => rfl @[simp] theorem mapRange.addEquiv_toEquiv (f : M ≃+ N) : ↑(mapRange.addEquiv f : (α →₀ _) ≃+ _) = (mapRange.equiv (f : M ≃ N) f.map_zero f.symm.map_zero : (α →₀ _) ≃ _) := Equiv.ext fun _ => rfl end AddMonoidHom end Finsupp end MapRange /-! ### Declarations about `equivCongrLeft` -/ section EquivCongrLeft variable [Zero M] namespace Finsupp /-- Given `f : α ≃ β`, we can map `l : α →₀ M` to `equivMapDomain f l : β →₀ M` (computably) by mapping the support forwards and the function backwards. -/ def equivMapDomain (f : α ≃ β) (l : α →₀ M) : β →₀ M where support := l.support.map f.toEmbedding toFun a := l (f.symm a) mem_support_toFun a := by simp only [Finset.mem_map_equiv, mem_support_toFun]; rfl @[simp] theorem equivMapDomain_apply (f : α ≃ β) (l : α →₀ M) (b : β) : equivMapDomain f l b = l (f.symm b) := rfl theorem equivMapDomain_symm_apply (f : α ≃ β) (l : β →₀ M) (a : α) : equivMapDomain f.symm l a = l (f a) := rfl @[simp] theorem equivMapDomain_refl (l : α →₀ M) : equivMapDomain (Equiv.refl _) l = l := by ext x; rfl theorem equivMapDomain_refl' : equivMapDomain (Equiv.refl _) = @id (α →₀ M) := by ext x; rfl theorem equivMapDomain_trans (f : α ≃ β) (g : β ≃ γ) (l : α →₀ M) : equivMapDomain (f.trans g) l = equivMapDomain g (equivMapDomain f l) := by ext x; rfl theorem equivMapDomain_trans' (f : α ≃ β) (g : β ≃ γ) : @equivMapDomain _ _ M _ (f.trans g) = equivMapDomain g ∘ equivMapDomain f := by ext x; rfl @[simp] theorem equivMapDomain_single (f : α ≃ β) (a : α) (b : M) : equivMapDomain f (single a b) = single (f a) b := by classical ext x simp only [single_apply, Equiv.apply_eq_iff_eq_symm_apply, equivMapDomain_apply] @[simp] theorem equivMapDomain_zero {f : α ≃ β} : equivMapDomain f (0 : α →₀ M) = (0 : β →₀ M) := by ext; simp only [equivMapDomain_apply, coe_zero, Pi.zero_apply] @[to_additive (attr := simp)] theorem prod_equivMapDomain [CommMonoid N] (f : α ≃ β) (l : α →₀ M) (g : β → M → N) : prod (equivMapDomain f l) g = prod l (fun a m => g (f a) m) := by simp [prod, equivMapDomain] /-- Given `f : α ≃ β`, the finitely supported function spaces are also in bijection: `(α →₀ M) ≃ (β →₀ M)`. This is the finitely-supported version of `Equiv.piCongrLeft`. -/ def equivCongrLeft (f : α ≃ β) : (α →₀ M) ≃ (β →₀ M) := by refine ⟨equivMapDomain f, equivMapDomain f.symm, fun f => ?_, fun f => ?_⟩ <;> ext x <;> simp only [equivMapDomain_apply, Equiv.symm_symm, Equiv.symm_apply_apply, Equiv.apply_symm_apply] @[simp] theorem equivCongrLeft_apply (f : α ≃ β) (l : α →₀ M) : equivCongrLeft f l = equivMapDomain f l := rfl @[simp] theorem equivCongrLeft_symm (f : α ≃ β) : (@equivCongrLeft _ _ M _ f).symm = equivCongrLeft f.symm := rfl end Finsupp end EquivCongrLeft section CastFinsupp variable [Zero M] (f : α →₀ M) namespace Nat @[simp, norm_cast] theorem cast_finsuppProd [CommSemiring R] (g : α → M → ℕ) : (↑(f.prod g) : R) = f.prod fun a b => ↑(g a b) := Nat.cast_prod _ _ @[deprecated (since := "2025-04-06")] alias cast_finsupp_prod := cast_finsuppProd @[simp, norm_cast] theorem cast_finsupp_sum [AddCommMonoidWithOne R] (g : α → M → ℕ) : (↑(f.sum g) : R) = f.sum fun a b => ↑(g a b) := Nat.cast_sum _ _ end Nat namespace Int @[simp, norm_cast] theorem cast_finsuppProd [CommRing R] (g : α → M → ℤ) : (↑(f.prod g) : R) = f.prod fun a b => ↑(g a b) := Int.cast_prod _ _ @[deprecated (since := "2025-04-06")] alias cast_finsupp_prod := cast_finsuppProd @[simp, norm_cast] theorem cast_finsupp_sum [AddCommGroupWithOne R] (g : α → M → ℤ) : (↑(f.sum g) : R) = f.sum fun a b => ↑(g a b) := Int.cast_sum _ _ end Int namespace Rat @[simp, norm_cast] theorem cast_finsupp_sum [DivisionRing R] [CharZero R] (g : α → M → ℚ) : (↑(f.sum g) : R) = f.sum fun a b => ↑(g a b) := cast_sum _ _ @[simp, norm_cast] theorem cast_finsuppProd [Field R] [CharZero R] (g : α → M → ℚ) : (↑(f.prod g) : R) = f.prod fun a b => ↑(g a b) := cast_prod _ _ @[deprecated (since := "2025-04-06")] alias cast_finsupp_prod := cast_finsuppProd end Rat end CastFinsupp /-! ### Declarations about `mapDomain` -/ namespace Finsupp section MapDomain variable [AddCommMonoid M] {v v₁ v₂ : α →₀ M} /-- Given `f : α → β` and `v : α →₀ M`, `mapDomain f v : β →₀ M` is the finitely supported function whose value at `a : β` is the sum of `v x` over all `x` such that `f x = a`. -/ def mapDomain (f : α → β) (v : α →₀ M) : β →₀ M := v.sum fun a => single (f a) theorem mapDomain_apply {f : α → β} (hf : Function.Injective f) (x : α →₀ M) (a : α) : mapDomain f x (f a) = x a := by rw [mapDomain, sum_apply, sum_eq_single a, single_eq_same] · intro b _ hba exact single_eq_of_ne (hf.ne hba) · intro _ rw [single_zero, coe_zero, Pi.zero_apply] theorem mapDomain_notin_range {f : α → β} (x : α →₀ M) (a : β) (h : a ∉ Set.range f) : mapDomain f x a = 0 := by rw [mapDomain, sum_apply, sum] exact Finset.sum_eq_zero fun a' _ => single_eq_of_ne fun eq => h <\| eq ▸ Set.mem_range_self _ @[simp] theorem mapDomain_id : mapDomain id v = v := sum_single _ theorem mapDomain_comp {f : α → β} {g : β → γ} : mapDomain (g ∘ f) v = mapDomain g (mapDomain f v) := by refine ((sum_sum_index ?_ ?_).trans ?_).symm · intro exact single_zero _ · intro exact single_add _ refine sum_congr fun _ _ => sum_single_index ?_ exact single_zero _ @[simp] theorem mapDomain_single {f : α → β} {a : α} {b : M} : mapDomain f (single a b) = single (f a) b := sum_single_index <\| single_zero _ @[simp] theorem mapDomain_zero {f : α → β} : mapDomain f (0 : α →₀ M) = (0 : β →₀ M) := sum_zero_index theorem mapDomain_congr {f g : α → β} (h : ∀ x ∈ v.support, f x = g x) : v.mapDomain f = v.mapDomain g := Finset.sum_congr rfl fun _ H => by simp only [h _ H] theorem mapDomain_add {f : α → β} : mapDomain f (v₁ + v₂) = mapDomain f v₁ + mapDomain f v₂ := sum_add_index' (fun _ => single_zero _) fun _ => single_add _ @[simp] theorem mapDomain_equiv_apply {f : α ≃ β} (x : α →₀ M) (a : β) : mapDomain f x a = x (f.symm a) := by conv_lhs => rw [← f.apply_symm_apply a] exact mapDomain_apply f.injective _ _ /-- `Finsupp.mapDomain` is an `AddMonoidHom`. -/ @[simps] def mapDomain.addMonoidHom (f : α → β) : (α →₀ M) →+ β →₀ M where toFun := mapDomain f map_zero' := mapDomain_zero map_add' _ _ := mapDomain_add @[simp] theorem mapDomain.addMonoidHom_id : mapDomain.addMonoidHom id = AddMonoidHom.id (α →₀ M) := AddMonoidHom.ext fun _ => mapDomain_id theorem mapDomain.addMonoidHom_comp (f : β → γ) (g : α → β) : (mapDomain.addMonoidHom (f ∘ g) : (α →₀ M) →+ γ →₀ M) = (mapDomain.addMonoidHom f).comp (mapDomain.addMonoidHom g) := AddMonoidHom.ext fun _ => mapDomain_comp theorem mapDomain_finset_sum {f : α → β} {s : Finset ι} {v : ι → α →₀ M} :	mapDomain f (∑ i ∈ s, v i) = ∑ i ∈ s, mapDomain f (v i) := map_sum (mapDomain.addMonoidHom f) _ _ theorem mapDomain_sum [Zero N] {f : α → β} {s : α →₀ N} {v : α → N → α →₀ M} : mapDomain f (s.sum v) = s.sum fun a b => mapDomain f (v a b) := map_finsuppSum (mapDomain.addMonoidHom f : (α →₀ M) →+ β →₀ M) _ _ theorem mapDomain_support [DecidableEq β] {f : α → β} {s : α →₀ M} : (s.mapDomain f).support ⊆ s.support.image f :=	Mathlib/Data/Finsupp/Basic.lean	471	479
/- Copyright (c) 2022 Anatole Dedecker. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Anatole Dedecker -/ import Mathlib.Topology.UniformSpace.UniformConvergenceTopology /-! # Equicontinuity of a family of functions Let `X` be a topological space and `α` a `UniformSpace`. A family of functions `F : ι → X → α` is said to be equicontinuous at a point `x₀ : X` when, for any entourage `U` in `α`, there is a neighborhood `V` of `x₀` such that, for all `x ∈ V`, and for all `i`, `F i x` is `U`-close to `F i x₀`. In other words, one has `∀ U ∈ 𝓤 α, ∀ᶠ x in 𝓝 x₀, ∀ i, (F i x₀, F i x) ∈ U`. For maps between metric spaces, this corresponds to `∀ ε > 0, ∃ δ > 0, ∀ x, ∀ i, dist x₀ x < δ → dist (F i x₀) (F i x) < ε`. `F` is said to be equicontinuous if it is equicontinuous at each point. A closely related concept is that of *uniform* equicontinuity of a family of functions `F : ι → β → α` between uniform spaces, which means that, for any entourage `U` in `α`, there is an entourage `V` in `β` such that, if `x` and `y` are `V`-close, then for all `i`, `F i x` and `F i y` are `U`-close. In other words, one has `∀ U ∈ 𝓤 α, ∀ᶠ xy in 𝓤 β, ∀ i, (F i xy.1, F i xy.2) ∈ U`. For maps between metric spaces, this corresponds to `∀ ε > 0, ∃ δ > 0, ∀ x y, ∀ i, dist x y < δ → dist (F i x₀) (F i x) < ε`. ## Main definitions * `EquicontinuousAt`: equicontinuity of a family of functions at a point * `Equicontinuous`: equicontinuity of a family of functions on the whole domain * `UniformEquicontinuous`: uniform equicontinuity of a family of functions on the whole domain We also introduce relative versions, namely `EquicontinuousWithinAt`, `EquicontinuousOn` and `UniformEquicontinuousOn`, akin to `ContinuousWithinAt`, `ContinuousOn` and `UniformContinuousOn` respectively. ## Main statements * `equicontinuous_iff_continuous`: equicontinuity can be expressed as a simple continuity condition between well-chosen function spaces. This is really useful for building up the theory. * `Equicontinuous.closure`: if a set of functions is equicontinuous, its closure for the topology of pointwise convergence is also equicontinuous. ## Notations Throughout this file, we use : - `ι`, `κ` for indexing types - `X`, `Y`, `Z` for topological spaces - `α`, `β`, `γ` for uniform spaces ## Implementation details We choose to express equicontinuity as a properties of indexed families of functions rather than sets of functions for the following reasons: - it is really easy to express equicontinuity of `H : Set (X → α)` using our setup: it is just equicontinuity of the family `(↑) : ↥H → (X → α)`. On the other hand, going the other way around would require working with the range of the family, which is always annoying because it introduces useless existentials. - in most applications, one doesn't work with bare functions but with a more specific hom type `hom`. Equicontinuity of a set `H : Set hom` would then have to be expressed as equicontinuity of `coe_fn '' H`, which is super annoying to work with. This is much simpler with families, because equicontinuity of a family `𝓕 : ι → hom` would simply be expressed as equicontinuity of `coe_fn ∘ 𝓕`, which doesn't introduce any nasty existentials. To simplify statements, we do provide abbreviations `Set.EquicontinuousAt`, `Set.Equicontinuous` and `Set.UniformEquicontinuous` asserting the corresponding fact about the family `(↑) : ↥H → (X → α)` where `H : Set (X → α)`. Note however that these won't work for sets of hom types, and in that case one should go back to the family definition rather than using `Set.image`. ## References * [N. Bourbaki, General Topology, Chapter X][bourbaki1966] ## Tags equicontinuity, uniform convergence, ascoli -/ section open UniformSpace Filter Set Uniformity Topology UniformConvergence Function variable {ι κ X X' Y α α' β β' γ : Type} [tX : TopologicalSpace X] [tY : TopologicalSpace Y] [uα : UniformSpace α] [uβ : UniformSpace β] [uγ : UniformSpace γ] /-- A family `F : ι → X → α` of functions from a topological space to a uniform space is equicontinuous at `x₀ : X`* if, for all entourages `U ∈ 𝓤 α`, there is a neighborhood `V` of `x₀` such that, for all `x ∈ V` and for all `i : ι`, `F i x` is `U`-close to `F i x₀`. -/ def EquicontinuousAt (F : ι → X → α) (x₀ : X) : Prop := ∀ U ∈ 𝓤 α, ∀ᶠ x in 𝓝 x₀, ∀ i, (F i x₀, F i x) ∈ U /-- We say that a set `H : Set (X → α)` of functions is equicontinuous at a point if the family `(↑) : ↥H → (X → α)` is equicontinuous at that point. -/ protected abbrev Set.EquicontinuousAt (H : Set <\| X → α) (x₀ : X) : Prop := EquicontinuousAt ((↑) : H → X → α) x₀ /-- A family `F : ι → X → α` of functions from a topological space to a uniform space is equicontinuous at `x₀ : X` within `S : Set X` if, for all entourages `U ∈ 𝓤 α`, there is a neighborhood `V` of `x₀` within `S` such that, for all `x ∈ V` and for all `i : ι`, `F i x` is `U`-close to `F i x₀`. -/ def EquicontinuousWithinAt (F : ι → X → α) (S : Set X) (x₀ : X) : Prop := ∀ U ∈ 𝓤 α, ∀ᶠ x in 𝓝[S] x₀, ∀ i, (F i x₀, F i x) ∈ U /-- We say that a set `H : Set (X → α)` of functions is equicontinuous at a point within a subset if the family `(↑) : ↥H → (X → α)` is equicontinuous at that point within that same subset. -/ protected abbrev Set.EquicontinuousWithinAt (H : Set <\| X → α) (S : Set X) (x₀ : X) : Prop := EquicontinuousWithinAt ((↑) : H → X → α) S x₀ /-- A family `F : ι → X → α` of functions from a topological space to a uniform space is equicontinuous on all of `X` if it is equicontinuous at each point of `X`. -/ def Equicontinuous (F : ι → X → α) : Prop := ∀ x₀, EquicontinuousAt F x₀ /-- We say that a set `H : Set (X → α)` of functions is equicontinuous if the family `(↑) : ↥H → (X → α)` is equicontinuous. -/ protected abbrev Set.Equicontinuous (H : Set <\| X → α) : Prop := Equicontinuous ((↑) : H → X → α) /-- A family `F : ι → X → α` of functions from a topological space to a uniform space is equicontinuous on `S : Set X` if it is equicontinuous within `S` at each point of `S`. -/ def EquicontinuousOn (F : ι → X → α) (S : Set X) : Prop := ∀ x₀ ∈ S, EquicontinuousWithinAt F S x₀ /-- We say that a set `H : Set (X → α)` of functions is equicontinuous on a subset if the family `(↑) : ↥H → (X → α)` is equicontinuous on that subset. -/ protected abbrev Set.EquicontinuousOn (H : Set <\| X → α) (S : Set X) : Prop := EquicontinuousOn ((↑) : H → X → α) S /-- A family `F : ι → β → α` of functions between uniform spaces is uniformly equicontinuous if, for all entourages `U ∈ 𝓤 α`, there is an entourage `V ∈ 𝓤 β` such that, whenever `x` and `y` are `V`-close, we have that, for all `i : ι`, `F i x` is `U`-close to `F i y`. -/ def UniformEquicontinuous (F : ι → β → α) : Prop := ∀ U ∈ 𝓤 α, ∀ᶠ xy : β × β in 𝓤 β, ∀ i, (F i xy.1, F i xy.2) ∈ U /-- We say that a set `H : Set (X → α)` of functions is uniformly equicontinuous if the family `(↑) : ↥H → (X → α)` is uniformly equicontinuous. -/ protected abbrev Set.UniformEquicontinuous (H : Set <\| β → α) : Prop := UniformEquicontinuous ((↑) : H → β → α) /-- A family `F : ι → β → α` of functions between uniform spaces is uniformly equicontinuous on `S : Set β` if, for all entourages `U ∈ 𝓤 α`, there is a relative entourage `V ∈ 𝓤 β ⊓ 𝓟 (S ×ˢ S)` such that, whenever `x` and `y` are `V`-close, we have that, for all `i : ι`, `F i x` is `U`-close to `F i y`. -/ def UniformEquicontinuousOn (F : ι → β → α) (S : Set β) : Prop := ∀ U ∈ 𝓤 α, ∀ᶠ xy : β × β in 𝓤 β ⊓ 𝓟 (S ×ˢ S), ∀ i, (F i xy.1, F i xy.2) ∈ U /-- We say that a set `H : Set (X → α)` of functions is uniformly equicontinuous on a subset if the family `(↑) : ↥H → (X → α)` is uniformly equicontinuous on that subset. -/ protected abbrev Set.UniformEquicontinuousOn (H : Set <\| β → α) (S : Set β) : Prop := UniformEquicontinuousOn ((↑) : H → β → α) S lemma EquicontinuousAt.equicontinuousWithinAt {F : ι → X → α} {x₀ : X} (H : EquicontinuousAt F x₀) (S : Set X) : EquicontinuousWithinAt F S x₀ := fun U hU ↦ (H U hU).filter_mono inf_le_left lemma EquicontinuousWithinAt.mono {F : ι → X → α} {x₀ : X} {S T : Set X} (H : EquicontinuousWithinAt F T x₀) (hST : S ⊆ T) : EquicontinuousWithinAt F S x₀ := fun U hU ↦ (H U hU).filter_mono <\| nhdsWithin_mono x₀ hST @[simp] lemma equicontinuousWithinAt_univ (F : ι → X → α) (x₀ : X) : EquicontinuousWithinAt F univ x₀ ↔ EquicontinuousAt F x₀ := by rw [EquicontinuousWithinAt, EquicontinuousAt, nhdsWithin_univ] lemma equicontinuousAt_restrict_iff (F : ι → X → α) {S : Set X} (x₀ : S) : EquicontinuousAt (S.restrict ∘ F) x₀ ↔ EquicontinuousWithinAt F S x₀ := by simp [EquicontinuousWithinAt, EquicontinuousAt, ← eventually_nhds_subtype_iff] lemma Equicontinuous.equicontinuousOn {F : ι → X → α} (H : Equicontinuous F) (S : Set X) : EquicontinuousOn F S := fun x _ ↦ (H x).equicontinuousWithinAt S lemma EquicontinuousOn.mono {F : ι → X → α} {S T : Set X} (H : EquicontinuousOn F T) (hST : S ⊆ T) : EquicontinuousOn F S := fun x hx ↦ (H x (hST hx)).mono hST lemma equicontinuousOn_univ (F : ι → X → α) : EquicontinuousOn F univ ↔ Equicontinuous F := by simp [EquicontinuousOn, Equicontinuous] lemma equicontinuous_restrict_iff (F : ι → X → α) {S : Set X} : Equicontinuous (S.restrict ∘ F) ↔ EquicontinuousOn F S := by simp [Equicontinuous, EquicontinuousOn, equicontinuousAt_restrict_iff] lemma UniformEquicontinuous.uniformEquicontinuousOn {F : ι → β → α} (H : UniformEquicontinuous F) (S : Set β) : UniformEquicontinuousOn F S := fun U hU ↦ (H U hU).filter_mono inf_le_left lemma UniformEquicontinuousOn.mono {F : ι → β → α} {S T : Set β} (H : UniformEquicontinuousOn F T) (hST : S ⊆ T) : UniformEquicontinuousOn F S := fun U hU ↦ (H U hU).filter_mono <\| by gcongr lemma uniformEquicontinuousOn_univ (F : ι → β → α) : UniformEquicontinuousOn F univ ↔ UniformEquicontinuous F := by simp [UniformEquicontinuousOn, UniformEquicontinuous] lemma uniformEquicontinuous_restrict_iff (F : ι → β → α) {S : Set β} : UniformEquicontinuous (S.restrict ∘ F) ↔ UniformEquicontinuousOn F S := by rw [UniformEquicontinuous, UniformEquicontinuousOn] conv in _ ⊓ _ => rw [← Subtype.range_val (s := S), ← range_prodMap, ← map_comap] rfl /-! ### Empty index type -/ @[simp] lemma equicontinuousAt_empty [h : IsEmpty ι] (F : ι → X → α) (x₀ : X) : EquicontinuousAt F x₀ := fun _ _ ↦ Eventually.of_forall (fun _ ↦ h.elim) @[simp] lemma equicontinuousWithinAt_empty [h : IsEmpty ι] (F : ι → X → α) (S : Set X) (x₀ : X) : EquicontinuousWithinAt F S x₀ := fun _ _ ↦ Eventually.of_forall (fun _ ↦ h.elim) @[simp] lemma equicontinuous_empty [IsEmpty ι] (F : ι → X → α) : Equicontinuous F := equicontinuousAt_empty F @[simp] lemma equicontinuousOn_empty [IsEmpty ι] (F : ι → X → α) (S : Set X) : EquicontinuousOn F S := fun x₀ _ ↦ equicontinuousWithinAt_empty F S x₀ @[simp] lemma uniformEquicontinuous_empty [h : IsEmpty ι] (F : ι → β → α) : UniformEquicontinuous F := fun _ _ ↦ Eventually.of_forall (fun _ ↦ h.elim) @[simp] lemma uniformEquicontinuousOn_empty [h : IsEmpty ι] (F : ι → β → α) (S : Set β) : UniformEquicontinuousOn F S := fun _ _ ↦ Eventually.of_forall (fun _ ↦ h.elim) /-! ### Finite index type -/ theorem equicontinuousAt_finite [Finite ι] {F : ι → X → α} {x₀ : X} : EquicontinuousAt F x₀ ↔ ∀ i, ContinuousAt (F i) x₀ := by simp [EquicontinuousAt, ContinuousAt, (nhds_basis_uniformity' (𝓤 α).basis_sets).tendsto_right_iff, UniformSpace.ball, @forall_swap _ ι] theorem equicontinuousWithinAt_finite [Finite ι] {F : ι → X → α} {S : Set X} {x₀ : X} : EquicontinuousWithinAt F S x₀ ↔ ∀ i, ContinuousWithinAt (F i) S x₀ := by simp [EquicontinuousWithinAt, ContinuousWithinAt, (nhds_basis_uniformity' (𝓤 α).basis_sets).tendsto_right_iff, UniformSpace.ball, @forall_swap _ ι] theorem equicontinuous_finite [Finite ι] {F : ι → X → α} : Equicontinuous F ↔ ∀ i, Continuous (F i) := by simp only [Equicontinuous, equicontinuousAt_finite, continuous_iff_continuousAt, @forall_swap ι] theorem equicontinuousOn_finite [Finite ι] {F : ι → X → α} {S : Set X} : EquicontinuousOn F S ↔ ∀ i, ContinuousOn (F i) S := by simp only [EquicontinuousOn, equicontinuousWithinAt_finite, ContinuousOn, @forall_swap ι] theorem uniformEquicontinuous_finite [Finite ι] {F : ι → β → α} : UniformEquicontinuous F ↔ ∀ i, UniformContinuous (F i) := by simp only [UniformEquicontinuous, eventually_all, @forall_swap _ ι]; rfl theorem uniformEquicontinuousOn_finite [Finite ι] {F : ι → β → α} {S : Set β} : UniformEquicontinuousOn F S ↔ ∀ i, UniformContinuousOn (F i) S := by simp only [UniformEquicontinuousOn, eventually_all, @forall_swap _ ι]; rfl /-! ### Index type with a unique element -/ theorem equicontinuousAt_unique [Unique ι] {F : ι → X → α} {x : X} : EquicontinuousAt F x ↔ ContinuousAt (F default) x := equicontinuousAt_finite.trans Unique.forall_iff theorem equicontinuousWithinAt_unique [Unique ι] {F : ι → X → α} {S : Set X} {x : X} : EquicontinuousWithinAt F S x ↔ ContinuousWithinAt (F default) S x := equicontinuousWithinAt_finite.trans Unique.forall_iff theorem equicontinuous_unique [Unique ι] {F : ι → X → α} : Equicontinuous F ↔ Continuous (F default) := equicontinuous_finite.trans Unique.forall_iff theorem equicontinuousOn_unique [Unique ι] {F : ι → X → α} {S : Set X} : EquicontinuousOn F S ↔ ContinuousOn (F default) S := equicontinuousOn_finite.trans Unique.forall_iff theorem uniformEquicontinuous_unique [Unique ι] {F : ι → β → α} : UniformEquicontinuous F ↔ UniformContinuous (F default) := uniformEquicontinuous_finite.trans Unique.forall_iff theorem uniformEquicontinuousOn_unique [Unique ι] {F : ι → β → α} {S : Set β} : UniformEquicontinuousOn F S ↔ UniformContinuousOn (F default) S := uniformEquicontinuousOn_finite.trans Unique.forall_iff /-- Reformulation of equicontinuity at `x₀` within a set `S`, comparing two variables near `x₀` instead of comparing only one with `x₀`. -/ theorem equicontinuousWithinAt_iff_pair {F : ι → X → α} {S : Set X} {x₀ : X} (hx₀ : x₀ ∈ S) : EquicontinuousWithinAt F S x₀ ↔ ∀ U ∈ 𝓤 α, ∃ V ∈ 𝓝[S] x₀, ∀ x ∈ V, ∀ y ∈ V, ∀ i, (F i x, F i y) ∈ U := by constructor <;> intro H U hU · rcases comp_symm_mem_uniformity_sets hU with ⟨V, hV, hVsymm, hVU⟩ refine ⟨_, H V hV, fun x hx y hy i => hVU (prodMk_mem_compRel ?_ (hy i))⟩ exact hVsymm.mk_mem_comm.mp (hx i) · rcases H U hU with ⟨V, hV, hVU⟩ filter_upwards [hV] using fun x hx i => hVU x₀ (mem_of_mem_nhdsWithin hx₀ hV) x hx i /-- Reformulation of equicontinuity at `x₀` comparing two variables near `x₀` instead of comparing only one with `x₀`. -/ theorem equicontinuousAt_iff_pair {F : ι → X → α} {x₀ : X} : EquicontinuousAt F x₀ ↔ ∀ U ∈ 𝓤 α, ∃ V ∈ 𝓝 x₀, ∀ x ∈ V, ∀ y ∈ V, ∀ i, (F i x, F i y) ∈ U := by simp_rw [← equicontinuousWithinAt_univ, equicontinuousWithinAt_iff_pair (mem_univ x₀), nhdsWithin_univ] /-- Uniform equicontinuity implies equicontinuity. -/ theorem UniformEquicontinuous.equicontinuous {F : ι → β → α} (h : UniformEquicontinuous F) : Equicontinuous F := fun x₀ U hU ↦ mem_of_superset (ball_mem_nhds x₀ (h U hU)) fun _ hx i ↦ hx i /-- Uniform equicontinuity on a subset implies equicontinuity on that subset. -/ theorem UniformEquicontinuousOn.equicontinuousOn {F : ι → β → α} {S : Set β} (h : UniformEquicontinuousOn F S) : EquicontinuousOn F S := fun _ hx₀ U hU ↦ mem_of_superset (ball_mem_nhdsWithin hx₀ (h U hU)) fun _ hx i ↦ hx i /-- Each function of a family equicontinuous at `x₀` is continuous at `x₀`. -/ theorem EquicontinuousAt.continuousAt {F : ι → X → α} {x₀ : X} (h : EquicontinuousAt F x₀) (i : ι) : ContinuousAt (F i) x₀ := (UniformSpace.hasBasis_nhds _).tendsto_right_iff.2 fun U ⟨hU, _⟩ ↦ (h U hU).mono fun _x hx ↦ hx i /-- Each function of a family equicontinuous at `x₀` within `S` is continuous at `x₀` within `S`. -/ theorem EquicontinuousWithinAt.continuousWithinAt {F : ι → X → α} {S : Set X} {x₀ : X} (h : EquicontinuousWithinAt F S x₀) (i : ι) : ContinuousWithinAt (F i) S x₀ := (UniformSpace.hasBasis_nhds _).tendsto_right_iff.2 fun U ⟨hU, _⟩ ↦ (h U hU).mono fun _x hx ↦ hx i protected theorem Set.EquicontinuousAt.continuousAt_of_mem {H : Set <\| X → α} {x₀ : X} (h : H.EquicontinuousAt x₀) {f : X → α} (hf : f ∈ H) : ContinuousAt f x₀ := h.continuousAt ⟨f, hf⟩ protected theorem Set.EquicontinuousWithinAt.continuousWithinAt_of_mem {H : Set <\| X → α} {S : Set X} {x₀ : X} (h : H.EquicontinuousWithinAt S x₀) {f : X → α} (hf : f ∈ H) : ContinuousWithinAt f S x₀ := h.continuousWithinAt ⟨f, hf⟩ /-- Each function of an equicontinuous family is continuous. -/ theorem Equicontinuous.continuous {F : ι → X → α} (h : Equicontinuous F) (i : ι) : Continuous (F i) := continuous_iff_continuousAt.mpr fun x => (h x).continuousAt i /-- Each function of a family equicontinuous on `S` is continuous on `S`. -/ theorem EquicontinuousOn.continuousOn {F : ι → X → α} {S : Set X} (h : EquicontinuousOn F S) (i : ι) : ContinuousOn (F i) S := fun x hx ↦ (h x hx).continuousWithinAt i protected theorem Set.Equicontinuous.continuous_of_mem {H : Set <\| X → α} (h : H.Equicontinuous) {f : X → α} (hf : f ∈ H) : Continuous f := h.continuous ⟨f, hf⟩ protected theorem Set.EquicontinuousOn.continuousOn_of_mem {H : Set <\| X → α} {S : Set X} (h : H.EquicontinuousOn S) {f : X → α} (hf : f ∈ H) : ContinuousOn f S := h.continuousOn ⟨f, hf⟩ /-- Each function of a uniformly equicontinuous family is uniformly continuous. -/ theorem UniformEquicontinuous.uniformContinuous {F : ι → β → α} (h : UniformEquicontinuous F) (i : ι) : UniformContinuous (F i) := fun U hU => mem_map.mpr (mem_of_superset (h U hU) fun _ hxy => hxy i) /-- Each function of a family uniformly equicontinuous on `S` is uniformly continuous on `S`. -/ theorem UniformEquicontinuousOn.uniformContinuousOn {F : ι → β → α} {S : Set β} (h : UniformEquicontinuousOn F S) (i : ι) : UniformContinuousOn (F i) S := fun U hU => mem_map.mpr (mem_of_superset (h U hU) fun _ hxy => hxy i) protected theorem Set.UniformEquicontinuous.uniformContinuous_of_mem {H : Set <\| β → α} (h : H.UniformEquicontinuous) {f : β → α} (hf : f ∈ H) : UniformContinuous f := h.uniformContinuous ⟨f, hf⟩ protected theorem Set.UniformEquicontinuousOn.uniformContinuousOn_of_mem {H : Set <\| β → α} {S : Set β} (h : H.UniformEquicontinuousOn S) {f : β → α} (hf : f ∈ H) : UniformContinuousOn f S := h.uniformContinuousOn ⟨f, hf⟩ /-- Taking sub-families preserves equicontinuity at a point. -/ theorem EquicontinuousAt.comp {F : ι → X → α} {x₀ : X} (h : EquicontinuousAt F x₀) (u : κ → ι) : EquicontinuousAt (F ∘ u) x₀ := fun U hU => (h U hU).mono fun _ H k => H (u k) /-- Taking sub-families preserves equicontinuity at a point within a subset. -/ theorem EquicontinuousWithinAt.comp {F : ι → X → α} {S : Set X} {x₀ : X} (h : EquicontinuousWithinAt F S x₀) (u : κ → ι) : EquicontinuousWithinAt (F ∘ u) S x₀ := fun U hU ↦ (h U hU).mono fun _ H k => H (u k) protected theorem Set.EquicontinuousAt.mono {H H' : Set <\| X → α} {x₀ : X} (h : H.EquicontinuousAt x₀) (hH : H' ⊆ H) : H'.EquicontinuousAt x₀ := h.comp (inclusion hH) protected theorem Set.EquicontinuousWithinAt.mono {H H' : Set <\| X → α} {S : Set X} {x₀ : X} (h : H.EquicontinuousWithinAt S x₀) (hH : H' ⊆ H) : H'.EquicontinuousWithinAt S x₀ := h.comp (inclusion hH) /-- Taking sub-families preserves equicontinuity. -/ theorem Equicontinuous.comp {F : ι → X → α} (h : Equicontinuous F) (u : κ → ι) : Equicontinuous (F ∘ u) := fun x => (h x).comp u /-- Taking sub-families preserves equicontinuity on a subset. -/ theorem EquicontinuousOn.comp {F : ι → X → α} {S : Set X} (h : EquicontinuousOn F S) (u : κ → ι) : EquicontinuousOn (F ∘ u) S := fun x hx ↦ (h x hx).comp u protected theorem Set.Equicontinuous.mono {H H' : Set <\| X → α} (h : H.Equicontinuous) (hH : H' ⊆ H) : H'.Equicontinuous := h.comp (inclusion hH) protected theorem Set.EquicontinuousOn.mono {H H' : Set <\| X → α} {S : Set X} (h : H.EquicontinuousOn S) (hH : H' ⊆ H) : H'.EquicontinuousOn S := h.comp (inclusion hH) /-- Taking sub-families preserves uniform equicontinuity. -/ theorem UniformEquicontinuous.comp {F : ι → β → α} (h : UniformEquicontinuous F) (u : κ → ι) : UniformEquicontinuous (F ∘ u) := fun U hU => (h U hU).mono fun _ H k => H (u k) /-- Taking sub-families preserves uniform equicontinuity on a subset. -/ theorem UniformEquicontinuousOn.comp {F : ι → β → α} {S : Set β} (h : UniformEquicontinuousOn F S) (u : κ → ι) : UniformEquicontinuousOn (F ∘ u) S := fun U hU ↦ (h U hU).mono fun _ H k => H (u k) protected theorem Set.UniformEquicontinuous.mono {H H' : Set <\| β → α} (h : H.UniformEquicontinuous) (hH : H' ⊆ H) : H'.UniformEquicontinuous := h.comp (inclusion hH) protected theorem Set.UniformEquicontinuousOn.mono {H H' : Set <\| β → α} {S : Set β} (h : H.UniformEquicontinuousOn S) (hH : H' ⊆ H) : H'.UniformEquicontinuousOn S := h.comp (inclusion hH) /-- A family `𝓕 : ι → X → α` is equicontinuous at `x₀` iff `range 𝓕` is equicontinuous at `x₀`, i.e the family `(↑) : range F → X → α` is equicontinuous at `x₀`. -/ theorem equicontinuousAt_iff_range {F : ι → X → α} {x₀ : X} : EquicontinuousAt F x₀ ↔ EquicontinuousAt ((↑) : range F → X → α) x₀ := by simp only [EquicontinuousAt, forall_subtype_range_iff] /-- A family `𝓕 : ι → X → α` is equicontinuous at `x₀` within `S` iff `range 𝓕` is equicontinuous at `x₀` within `S`, i.e the family `(↑) : range F → X → α` is equicontinuous at `x₀` within `S`. -/ theorem equicontinuousWithinAt_iff_range {F : ι → X → α} {S : Set X} {x₀ : X} : EquicontinuousWithinAt F S x₀ ↔ EquicontinuousWithinAt ((↑) : range F → X → α) S x₀ := by simp only [EquicontinuousWithinAt, forall_subtype_range_iff] /-- A family `𝓕 : ι → X → α` is equicontinuous iff `range 𝓕` is equicontinuous, i.e the family `(↑) : range F → X → α` is equicontinuous. -/ theorem equicontinuous_iff_range {F : ι → X → α} : Equicontinuous F ↔ Equicontinuous ((↑) : range F → X → α) := forall_congr' fun _ => equicontinuousAt_iff_range /-- A family `𝓕 : ι → X → α` is equicontinuous on `S` iff `range 𝓕` is equicontinuous on `S`, i.e the family `(↑) : range F → X → α` is equicontinuous on `S`. -/ theorem equicontinuousOn_iff_range {F : ι → X → α} {S : Set X} : EquicontinuousOn F S ↔ EquicontinuousOn ((↑) : range F → X → α) S := forall_congr' fun _ ↦ forall_congr' fun _ ↦ equicontinuousWithinAt_iff_range /-- A family `𝓕 : ι → β → α` is uniformly equicontinuous iff `range 𝓕` is uniformly equicontinuous, i.e the family `(↑) : range F → β → α` is uniformly equicontinuous. -/ theorem uniformEquicontinuous_iff_range {F : ι → β → α} : UniformEquicontinuous F ↔ UniformEquicontinuous ((↑) : range F → β → α) := ⟨fun h => by rw [← comp_rangeSplitting F]; exact h.comp _, fun h => h.comp (rangeFactorization F)⟩ /-- A family `𝓕 : ι → β → α` is uniformly equicontinuous on `S` iff `range 𝓕` is uniformly equicontinuous on `S`, i.e the family `(↑) : range F → β → α` is uniformly equicontinuous on `S`. -/ theorem uniformEquicontinuousOn_iff_range {F : ι → β → α} {S : Set β} : UniformEquicontinuousOn F S ↔ UniformEquicontinuousOn ((↑) : range F → β → α) S := ⟨fun h => by rw [← comp_rangeSplitting F]; exact h.comp _, fun h => h.comp (rangeFactorization F)⟩ section open UniformFun /-- A family `𝓕 : ι → X → α` is equicontinuous at `x₀` iff the function `swap 𝓕 : X → ι → α` is continuous at `x₀` when `ι → α` is equipped with the topology of uniform convergence. This is very useful for developing the equicontinuity API, but it should not be used directly for other purposes. -/ theorem equicontinuousAt_iff_continuousAt {F : ι → X → α} {x₀ : X} : EquicontinuousAt F x₀ ↔ ContinuousAt (ofFun ∘ Function.swap F : X → ι →ᵤ α) x₀ := by rw [ContinuousAt, (UniformFun.hasBasis_nhds ι α _).tendsto_right_iff] rfl /-- A family `𝓕 : ι → X → α` is equicontinuous at `x₀` within `S` iff the function `swap 𝓕 : X → ι → α` is continuous at `x₀` within `S` when `ι → α` is equipped with the topology of uniform convergence. This is very useful for developing the equicontinuity API, but it should not be used directly for other purposes. -/ theorem equicontinuousWithinAt_iff_continuousWithinAt {F : ι → X → α} {S : Set X} {x₀ : X} : EquicontinuousWithinAt F S x₀ ↔ ContinuousWithinAt (ofFun ∘ Function.swap F : X → ι →ᵤ α) S x₀ := by rw [ContinuousWithinAt, (UniformFun.hasBasis_nhds ι α _).tendsto_right_iff] rfl /-- A family `𝓕 : ι → X → α` is equicontinuous iff the function `swap 𝓕 : X → ι → α` is continuous when `ι → α` is equipped with the topology of uniform convergence. This is very useful for developing the equicontinuity API, but it should not be used directly for other purposes. -/ theorem equicontinuous_iff_continuous {F : ι → X → α} : Equicontinuous F ↔ Continuous (ofFun ∘ Function.swap F : X → ι →ᵤ α) := by simp_rw [Equicontinuous, continuous_iff_continuousAt, equicontinuousAt_iff_continuousAt] /-- A family `𝓕 : ι → X → α` is equicontinuous on `S` iff the function `swap 𝓕 : X → ι → α` is continuous on `S` when `ι → α` is equipped with the topology of uniform convergence. This is very useful for developing the equicontinuity API, but it should not be used directly for other purposes. -/ theorem equicontinuousOn_iff_continuousOn {F : ι → X → α} {S : Set X} : EquicontinuousOn F S ↔ ContinuousOn (ofFun ∘ Function.swap F : X → ι →ᵤ α) S := by simp_rw [EquicontinuousOn, ContinuousOn, equicontinuousWithinAt_iff_continuousWithinAt] /-- A family `𝓕 : ι → β → α` is uniformly equicontinuous iff the function `swap 𝓕 : β → ι → α` is uniformly continuous when `ι → α` is equipped with the uniform structure of uniform convergence. This is very useful for developing the equicontinuity API, but it should not be used directly for other purposes. -/ theorem uniformEquicontinuous_iff_uniformContinuous {F : ι → β → α} : UniformEquicontinuous F ↔ UniformContinuous (ofFun ∘ Function.swap F : β → ι →ᵤ α) := by rw [UniformContinuous, (UniformFun.hasBasis_uniformity ι α).tendsto_right_iff] rfl /-- A family `𝓕 : ι → β → α` is uniformly equicontinuous on `S` iff the function `swap 𝓕 : β → ι → α` is uniformly continuous on `S` when `ι → α` is equipped with the uniform structure of uniform convergence. This is very useful for developing the equicontinuity API, but it should not be used directly for other purposes. -/ theorem uniformEquicontinuousOn_iff_uniformContinuousOn {F : ι → β → α} {S : Set β} : UniformEquicontinuousOn F S ↔ UniformContinuousOn (ofFun ∘ Function.swap F : β → ι →ᵤ α) S := by rw [UniformContinuousOn, (UniformFun.hasBasis_uniformity ι α).tendsto_right_iff] rfl theorem equicontinuousWithinAt_iInf_rng {u : κ → UniformSpace α'} {F : ι → X → α'} {S : Set X} {x₀ : X} : EquicontinuousWithinAt (uα := ⨅ k, u k) F S x₀ ↔ ∀ k, EquicontinuousWithinAt (uα := u k) F S x₀ := by simp only [equicontinuousWithinAt_iff_continuousWithinAt (uα := _), topologicalSpace] unfold ContinuousWithinAt rw [UniformFun.iInf_eq, toTopologicalSpace_iInf, nhds_iInf, tendsto_iInf] theorem equicontinuousAt_iInf_rng {u : κ → UniformSpace α'} {F : ι → X → α'} {x₀ : X} : EquicontinuousAt (uα := ⨅ k, u k) F x₀ ↔ ∀ k, EquicontinuousAt (uα := u k) F x₀ := by simp only [← equicontinuousWithinAt_univ (uα := _), equicontinuousWithinAt_iInf_rng] theorem equicontinuous_iInf_rng {u : κ → UniformSpace α'} {F : ι → X → α'} : Equicontinuous (uα := ⨅ k, u k) F ↔ ∀ k, Equicontinuous (uα := u k) F := by simp_rw [equicontinuous_iff_continuous (uα := _), UniformFun.topologicalSpace] rw [UniformFun.iInf_eq, toTopologicalSpace_iInf, continuous_iInf_rng] theorem equicontinuousOn_iInf_rng {u : κ → UniformSpace α'} {F : ι → X → α'} {S : Set X} : EquicontinuousOn (uα := ⨅ k, u k) F S ↔ ∀ k, EquicontinuousOn (uα := u k) F S := by simp_rw [EquicontinuousOn, equicontinuousWithinAt_iInf_rng, @forall_swap _ κ] theorem uniformEquicontinuous_iInf_rng {u : κ → UniformSpace α'} {F : ι → β → α'} : UniformEquicontinuous (uα := ⨅ k, u k) F ↔ ∀ k, UniformEquicontinuous (uα := u k) F := by simp_rw [uniformEquicontinuous_iff_uniformContinuous (uα := _)] rw [UniformFun.iInf_eq, uniformContinuous_iInf_rng] theorem uniformEquicontinuousOn_iInf_rng {u : κ → UniformSpace α'} {F : ι → β → α'} {S : Set β} : UniformEquicontinuousOn (uα := ⨅ k, u k) F S ↔ ∀ k, UniformEquicontinuousOn (uα := u k) F S := by simp_rw [uniformEquicontinuousOn_iff_uniformContinuousOn (uα := _)] unfold UniformContinuousOn rw [UniformFun.iInf_eq, iInf_uniformity, tendsto_iInf] theorem equicontinuousWithinAt_iInf_dom {t : κ → TopologicalSpace X'} {F : ι → X' → α} {S : Set X'} {x₀ : X'} {k : κ} (hk : EquicontinuousWithinAt (tX := t k) F S x₀) : EquicontinuousWithinAt (tX := ⨅ k, t k) F S x₀ := by simp only [equicontinuousWithinAt_iff_continuousWithinAt (tX := _)] at hk ⊢ unfold ContinuousWithinAt nhdsWithin at hk ⊢ rw [nhds_iInf] exact hk.mono_left <\| inf_le_inf_right _ <\| iInf_le _ k theorem equicontinuousAt_iInf_dom {t : κ → TopologicalSpace X'} {F : ι → X' → α} {x₀ : X'} {k : κ} (hk : EquicontinuousAt (tX := t k) F x₀) : EquicontinuousAt (tX := ⨅ k, t k) F x₀ := by rw [← equicontinuousWithinAt_univ (tX := _)] at hk ⊢ exact equicontinuousWithinAt_iInf_dom hk theorem equicontinuous_iInf_dom {t : κ → TopologicalSpace X'} {F : ι → X' → α} {k : κ} (hk : Equicontinuous (tX := t k) F) : Equicontinuous (tX := ⨅ k, t k) F := fun x ↦ equicontinuousAt_iInf_dom (hk x) theorem equicontinuousOn_iInf_dom {t : κ → TopologicalSpace X'} {F : ι → X' → α} {S : Set X'} {k : κ} (hk : EquicontinuousOn (tX := t k) F S) : EquicontinuousOn (tX := ⨅ k, t k) F S := fun x hx ↦ equicontinuousWithinAt_iInf_dom (hk x hx) theorem uniformEquicontinuous_iInf_dom {u : κ → UniformSpace β'} {F : ι → β' → α} {k : κ} (hk : UniformEquicontinuous (uβ := u k) F) : UniformEquicontinuous (uβ := ⨅ k, u k) F := by simp_rw [uniformEquicontinuous_iff_uniformContinuous (uβ := _)] at hk ⊢	exact uniformContinuous_iInf_dom hk theorem uniformEquicontinuousOn_iInf_dom {u : κ → UniformSpace β'} {F : ι → β' → α} {S : Set β'} {k : κ} (hk : UniformEquicontinuousOn (uβ := u k) F S) : UniformEquicontinuousOn (uβ := ⨅ k, u k) F S := by simp_rw [uniformEquicontinuousOn_iff_uniformContinuousOn (uβ := _)] at hk ⊢ unfold UniformContinuousOn	Mathlib/Topology/UniformSpace/Equicontinuity.lean	595	601
/- 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, Mario Carneiro, Floris van Doorn -/ import Mathlib.Algebra.Field.Basic import Mathlib.Algebra.GroupWithZero.Units.Lemmas import Mathlib.Algebra.Order.Ring.Abs import Mathlib.Order.Bounds.Basic import Mathlib.Order.Bounds.OrderIso import Mathlib.Tactic.Positivity.Core /-! # Lemmas about linear ordered (semi)fields -/ open Function OrderDual variable {ι α β : Type} section LinearOrderedSemifield variable [Semifield α] [LinearOrder α] [IsStrictOrderedRing α] {a b c d e : α} {m n : ℤ} /-! ### Relating two divisions. -/ @[deprecated div_le_div_iff_of_pos_right (since := "2024-11-12")] theorem div_le_div_right (hc : 0 < c) : a / c ≤ b / c ↔ a ≤ b := div_le_div_iff_of_pos_right hc @[deprecated div_lt_div_iff_of_pos_right (since := "2024-11-12")] theorem div_lt_div_right (hc : 0 < c) : a / c < b / c ↔ a < b := div_lt_div_iff_of_pos_right hc @[deprecated div_lt_div_iff_of_pos_left (since := "2024-11-13")] theorem div_lt_div_left (ha : 0 < a) (hb : 0 < b) (hc : 0 < c) : a / b < a / c ↔ c < b := div_lt_div_iff_of_pos_left ha hb hc @[deprecated div_le_div_iff_of_pos_left (since := "2024-11-12")] theorem div_le_div_left (ha : 0 < a) (hb : 0 < b) (hc : 0 < c) : a / b ≤ a / c ↔ c ≤ b := div_le_div_iff_of_pos_left ha hb hc @[deprecated div_lt_div_iff₀ (since := "2024-11-12")] theorem div_lt_div_iff (b0 : 0 < b) (d0 : 0 < d) : a / b < c / d ↔ a d < c * b := div_lt_div_iff₀ b0 d0 @[deprecated div_le_div_iff₀ (since := "2024-11-12")] theorem div_le_div_iff (b0 : 0 < b) (d0 : 0 < d) : a / b ≤ c / d ↔ a * d ≤ c * b := div_le_div_iff₀ b0 d0 @[deprecated div_le_div₀ (since := "2024-11-12")] theorem div_le_div (hc : 0 ≤ c) (hac : a ≤ c) (hd : 0 < d) (hbd : d ≤ b) : a / b ≤ c / d := div_le_div₀ hc hac hd hbd @[deprecated div_lt_div₀ (since := "2024-11-12")] theorem div_lt_div (hac : a < c) (hbd : d ≤ b) (c0 : 0 ≤ c) (d0 : 0 < d) : a / b < c / d := div_lt_div₀ hac hbd c0 d0 @[deprecated div_lt_div₀' (since := "2024-11-12")] theorem div_lt_div' (hac : a ≤ c) (hbd : d < b) (c0 : 0 < c) (d0 : 0 < d) : a / b < c / d := div_lt_div₀' hac hbd c0 d0 /-! ### Relating one division and involving `1` -/ @[bound] theorem div_le_self (ha : 0 ≤ a) (hb : 1 ≤ b) : a / b ≤ a := by simpa only [div_one] using div_le_div_of_nonneg_left ha zero_lt_one hb @[bound] theorem div_lt_self (ha : 0 < a) (hb : 1 < b) : a / b < a := by simpa only [div_one] using div_lt_div_of_pos_left ha zero_lt_one hb @[bound] theorem le_div_self (ha : 0 ≤ a) (hb₀ : 0 < b) (hb₁ : b ≤ 1) : a ≤ a / b := by simpa only [div_one] using div_le_div_of_nonneg_left ha hb₀ hb₁ theorem one_le_div (hb : 0 < b) : 1 ≤ a / b ↔ b ≤ a := by rw [le_div_iff₀ hb, one_mul] theorem div_le_one (hb : 0 < b) : a / b ≤ 1 ↔ a ≤ b := by rw [div_le_iff₀ hb, one_mul] theorem one_lt_div (hb : 0 < b) : 1 < a / b ↔ b < a := by rw [lt_div_iff₀ hb, one_mul] theorem div_lt_one (hb : 0 < b) : a / b < 1 ↔ a < b := by rw [div_lt_iff₀ hb, one_mul] theorem one_div_le (ha : 0 < a) (hb : 0 < b) : 1 / a ≤ b ↔ 1 / b ≤ a := by simpa using inv_le_comm₀ ha hb theorem one_div_lt (ha : 0 < a) (hb : 0 < b) : 1 / a < b ↔ 1 / b < a := by simpa using inv_lt_comm₀ ha hb theorem le_one_div (ha : 0 < a) (hb : 0 < b) : a ≤ 1 / b ↔ b ≤ 1 / a := by simpa using le_inv_comm₀ ha hb theorem lt_one_div (ha : 0 < a) (hb : 0 < b) : a < 1 / b ↔ b < 1 / a := by simpa using lt_inv_comm₀ ha hb @[bound] lemma Bound.one_lt_div_of_pos_of_lt (b0 : 0 < b) : b < a → 1 < a / b := (one_lt_div b0).mpr @[bound] lemma Bound.div_lt_one_of_pos_of_lt (b0 : 0 < b) : a < b → a / b < 1 := (div_lt_one b0).mpr /-! ### Relating two divisions, involving `1` -/ theorem one_div_le_one_div_of_le (ha : 0 < a) (h : a ≤ b) : 1 / b ≤ 1 / a := by simpa using inv_anti₀ ha h theorem one_div_lt_one_div_of_lt (ha : 0 < a) (h : a < b) : 1 / b < 1 / a := by rwa [lt_div_iff₀' ha, ← div_eq_mul_one_div, div_lt_one (ha.trans h)] theorem le_of_one_div_le_one_div (ha : 0 < a) (h : 1 / a ≤ 1 / b) : b ≤ a := le_imp_le_of_lt_imp_lt (one_div_lt_one_div_of_lt ha) h theorem lt_of_one_div_lt_one_div (ha : 0 < a) (h : 1 / a < 1 / b) : b < a := lt_imp_lt_of_le_imp_le (one_div_le_one_div_of_le ha) h /-- For the single implications with fewer assumptions, see `one_div_le_one_div_of_le` and `le_of_one_div_le_one_div` -/ theorem one_div_le_one_div (ha : 0 < a) (hb : 0 < b) : 1 / a ≤ 1 / b ↔ b ≤ a := div_le_div_iff_of_pos_left zero_lt_one ha hb /-- For the single implications with fewer assumptions, see `one_div_lt_one_div_of_lt` and `lt_of_one_div_lt_one_div` -/ theorem one_div_lt_one_div (ha : 0 < a) (hb : 0 < b) : 1 / a < 1 / b ↔ b < a := div_lt_div_iff_of_pos_left zero_lt_one ha hb theorem one_lt_one_div (h1 : 0 < a) (h2 : a < 1) : 1 < 1 / a := by rwa [lt_one_div (@zero_lt_one α _ _ _ _ _) h1, one_div_one] theorem one_le_one_div (h1 : 0 < a) (h2 : a ≤ 1) : 1 ≤ 1 / a := by rwa [le_one_div (@zero_lt_one α _ _ _ _ _) h1, one_div_one] /-! ### Results about halving. The equalities also hold in semifields of characteristic `0`. -/ theorem half_pos (h : 0 < a) : 0 < a / 2 := div_pos h zero_lt_two theorem one_half_pos : (0 : α) < 1 / 2 := half_pos zero_lt_one @[simp] theorem half_le_self_iff : a / 2 ≤ a ↔ 0 ≤ a := by rw [div_le_iff₀ (zero_lt_two' α), mul_two, le_add_iff_nonneg_left] @[simp] theorem half_lt_self_iff : a / 2 < a ↔ 0 < a := by rw [div_lt_iff₀ (zero_lt_two' α), mul_two, lt_add_iff_pos_left] alias ⟨_, half_le_self⟩ := half_le_self_iff alias ⟨_, half_lt_self⟩ := half_lt_self_iff alias div_two_lt_of_pos := half_lt_self theorem one_half_lt_one : (1 / 2 : α) < 1 := half_lt_self zero_lt_one theorem two_inv_lt_one : (2⁻¹ : α) < 1 := (one_div _).symm.trans_lt one_half_lt_one theorem left_lt_add_div_two : a < (a + b) / 2 ↔ a < b := by simp [lt_div_iff₀, mul_two] theorem add_div_two_lt_right : (a + b) / 2 < b ↔ a < b := by simp [div_lt_iff₀, mul_two] theorem add_thirds (a : α) : a / 3 + a / 3 + a / 3 = a := by rw [div_add_div_same, div_add_div_same, ← two_mul, ← add_one_mul 2 a, two_add_one_eq_three, mul_div_cancel_left₀ a three_ne_zero] /-! ### Miscellaneous lemmas -/ @[simp] lemma div_pos_iff_of_pos_left (ha : 0 < a) : 0 < a / b ↔ 0 < b := by simp only [div_eq_mul_inv, mul_pos_iff_of_pos_left ha, inv_pos] @[simp] lemma div_pos_iff_of_pos_right (hb : 0 < b) : 0 < a / b ↔ 0 < a := by simp only [div_eq_mul_inv, mul_pos_iff_of_pos_right (inv_pos.2 hb)] theorem mul_le_mul_of_mul_div_le (h : a * (b / c) ≤ d) (hc : 0 < c) : b * a ≤ d * c := by rw [← mul_div_assoc] at h rwa [mul_comm b, ← div_le_iff₀ hc] theorem div_mul_le_div_mul_of_div_le_div (h : a / b ≤ c / d) (he : 0 ≤ e) : a / (b * e) ≤ c / (d * e) := by rw [div_mul_eq_div_mul_one_div, div_mul_eq_div_mul_one_div] exact mul_le_mul_of_nonneg_right h (one_div_nonneg.2 he) theorem exists_pos_mul_lt {a : α} (h : 0 < a) (b : α) : ∃ c : α, 0 < c ∧ b * c < a := by have : 0 < a / max (b + 1) 1 := div_pos h (lt_max_iff.2 (Or.inr zero_lt_one)) refine ⟨a / max (b + 1) 1, this, ?_⟩ rw [← lt_div_iff₀ this, div_div_cancel₀ h.ne'] exact lt_max_iff.2 (Or.inl <\| lt_add_one _) theorem exists_pos_lt_mul {a : α} (h : 0 < a) (b : α) : ∃ c : α, 0 < c ∧ b < c * a := let ⟨c, hc₀, hc⟩ := exists_pos_mul_lt h b; ⟨c⁻¹, inv_pos.2 hc₀, by rwa [← div_eq_inv_mul, lt_div_iff₀ hc₀]⟩ lemma monotone_div_right_of_nonneg (ha : 0 ≤ a) : Monotone (· / a) := fun _b _c hbc ↦ div_le_div_of_nonneg_right hbc ha lemma strictMono_div_right_of_pos (ha : 0 < a) : StrictMono (· / a) := fun _b _c hbc ↦ div_lt_div_of_pos_right hbc ha theorem Monotone.div_const {β : Type} [Preorder β] {f : β → α} (hf : Monotone f) {c : α} (hc : 0 ≤ c) : Monotone fun x => f x / c := (monotone_div_right_of_nonneg hc).comp hf theorem StrictMono.div_const {β : Type} [Preorder β] {f : β → α} (hf : StrictMono f) {c : α} (hc : 0 < c) : StrictMono fun x => f x / c := by simpa only [div_eq_mul_inv] using hf.mul_const (inv_pos.2 hc) -- see Note [lower instance priority] instance (priority := 100) LinearOrderedSemiField.toDenselyOrdered : DenselyOrdered α where dense a₁ a₂ h := ⟨(a₁ + a₂) / 2, calc a₁ = (a₁ + a₁) / 2 := (add_self_div_two a₁).symm _ < (a₁ + a₂) / 2 := div_lt_div_of_pos_right (add_lt_add_left h _) zero_lt_two , calc (a₁ + a₂) / 2 < (a₂ + a₂) / 2 := div_lt_div_of_pos_right (add_lt_add_right h _) zero_lt_two _ = a₂ := add_self_div_two a₂ ⟩ theorem min_div_div_right {c : α} (hc : 0 ≤ c) (a b : α) : min (a / c) (b / c) = min a b / c := (monotone_div_right_of_nonneg hc).map_min.symm theorem max_div_div_right {c : α} (hc : 0 ≤ c) (a b : α) : max (a / c) (b / c) = max a b / c := (monotone_div_right_of_nonneg hc).map_max.symm theorem one_div_strictAntiOn : StrictAntiOn (fun x : α => 1 / x) (Set.Ioi 0) := fun _ x1 _ y1 xy => (one_div_lt_one_div (Set.mem_Ioi.mp y1) (Set.mem_Ioi.mp x1)).mpr xy theorem one_div_pow_le_one_div_pow_of_le (a1 : 1 ≤ a) {m n : ℕ} (mn : m ≤ n) : 1 / a ^ n ≤ 1 / a ^ m := by refine (one_div_le_one_div ?_ ?_).mpr (pow_right_mono₀ a1 mn) <;> exact pow_pos (zero_lt_one.trans_le a1) _ theorem one_div_pow_lt_one_div_pow_of_lt (a1 : 1 < a) {m n : ℕ} (mn : m < n) : 1 / a ^ n < 1 / a ^ m := by refine (one_div_lt_one_div ?_ ?_).2 (pow_lt_pow_right₀ a1 mn) <;> exact pow_pos (zero_lt_one.trans a1) _ theorem one_div_pow_anti (a1 : 1 ≤ a) : Antitone fun n : ℕ => 1 / a ^ n := fun _ _ => one_div_pow_le_one_div_pow_of_le a1 theorem one_div_pow_strictAnti (a1 : 1 < a) : StrictAnti fun n : ℕ => 1 / a ^ n := fun _ _ => one_div_pow_lt_one_div_pow_of_lt a1 theorem inv_strictAntiOn : StrictAntiOn (fun x : α => x⁻¹) (Set.Ioi 0) := fun _ hx _ hy xy => (inv_lt_inv₀ hy hx).2 xy theorem inv_pow_le_inv_pow_of_le (a1 : 1 ≤ a) {m n : ℕ} (mn : m ≤ n) : (a ^ n)⁻¹ ≤ (a ^ m)⁻¹ := by convert one_div_pow_le_one_div_pow_of_le a1 mn using 1 <;> simp theorem inv_pow_lt_inv_pow_of_lt (a1 : 1 < a) {m n : ℕ} (mn : m < n) : (a ^ n)⁻¹ < (a ^ m)⁻¹ := by convert one_div_pow_lt_one_div_pow_of_lt a1 mn using 1 <;> simp theorem inv_pow_anti (a1 : 1 ≤ a) : Antitone fun n : ℕ => (a ^ n)⁻¹ := fun _ _ => inv_pow_le_inv_pow_of_le a1 theorem inv_pow_strictAnti (a1 : 1 < a) : StrictAnti fun n : ℕ => (a ^ n)⁻¹ := fun _ _ => inv_pow_lt_inv_pow_of_lt a1 theorem le_iff_forall_one_lt_le_mul₀ {α : Type} [Semifield α] [LinearOrder α] [IsStrictOrderedRing α] {a b : α} (hb : 0 ≤ b) : a ≤ b ↔ ∀ ε, 1 < ε → a ≤ b ε := by refine ⟨fun h _ hε ↦ h.trans <\| le_mul_of_one_le_right hb hε.le, fun h ↦ ?_⟩ obtain rfl\|hb := hb.eq_or_lt · simp_rw [zero_mul] at h exact h 2 one_lt_two refine le_of_forall_gt_imp_ge_of_dense fun x hbx => ?_ convert h (x / b) ((one_lt_div hb).mpr hbx) rw [mul_div_cancel₀ _ hb.ne'] /-! ### Results about `IsGLB` -/ theorem IsGLB.mul_left {s : Set α} (ha : 0 ≤ a) (hs : IsGLB s b) : IsGLB ((fun b => a * b) '' s) (a * b) := by rcases lt_or_eq_of_le ha with (ha \| rfl) · exact (OrderIso.mulLeft₀ _ ha).isGLB_image'.2 hs · simp_rw [zero_mul] rw [hs.nonempty.image_const] exact isGLB_singleton theorem IsGLB.mul_right {s : Set α} (ha : 0 ≤ a) (hs : IsGLB s b) : IsGLB ((fun b => b * a) '' s) (b * a) := by simpa [mul_comm] using hs.mul_left ha end LinearOrderedSemifield section variable [Field α] [LinearOrder α] [IsStrictOrderedRing α] {a b c d : α} {n : ℤ} /-! ### Lemmas about pos, nonneg, nonpos, neg -/ theorem div_pos_iff : 0 < a / b ↔ 0 < a ∧ 0 < b ∨ a < 0 ∧ b < 0 := by simp only [division_def, mul_pos_iff, inv_pos, inv_lt_zero] theorem div_neg_iff : a / b < 0 ↔ 0 < a ∧ b < 0 ∨ a < 0 ∧ 0 < b := by simp [division_def, mul_neg_iff] theorem div_nonneg_iff : 0 ≤ a / b ↔ 0 ≤ a ∧ 0 ≤ b ∨ a ≤ 0 ∧ b ≤ 0 := by simp [division_def, mul_nonneg_iff] theorem div_nonpos_iff : a / b ≤ 0 ↔ 0 ≤ a ∧ b ≤ 0 ∨ a ≤ 0 ∧ 0 ≤ b := by simp [division_def, mul_nonpos_iff] theorem div_nonneg_of_nonpos (ha : a ≤ 0) (hb : b ≤ 0) : 0 ≤ a / b := div_nonneg_iff.2 <\| Or.inr ⟨ha, hb⟩ theorem div_pos_of_neg_of_neg (ha : a < 0) (hb : b < 0) : 0 < a / b := div_pos_iff.2 <\| Or.inr ⟨ha, hb⟩ theorem div_neg_of_neg_of_pos (ha : a < 0) (hb : 0 < b) : a / b < 0 := div_neg_iff.2 <\| Or.inr ⟨ha, hb⟩ theorem div_neg_of_pos_of_neg (ha : 0 < a) (hb : b < 0) : a / b < 0 := div_neg_iff.2 <\| Or.inl ⟨ha, hb⟩ /-! ### Relating one division with another term -/ theorem div_le_iff_of_neg (hc : c < 0) : b / c ≤ a ↔ a * c ≤ b := ⟨fun h => div_mul_cancel₀ b (ne_of_lt hc) ▸ mul_le_mul_of_nonpos_right h hc.le, fun h => calc a = a * c * (1 / c) := mul_mul_div a (ne_of_lt hc) _ ≥ b * (1 / c) := mul_le_mul_of_nonpos_right h (one_div_neg.2 hc).le _ = b / c := (div_eq_mul_one_div b c).symm ⟩ theorem div_le_iff_of_neg' (hc : c < 0) : b / c ≤ a ↔ c * a ≤ b := by rw [mul_comm, div_le_iff_of_neg hc] theorem le_div_iff_of_neg (hc : c < 0) : a ≤ b / c ↔ b ≤ a * c := by rw [← neg_neg c, mul_neg, div_neg, le_neg, div_le_iff₀ (neg_pos.2 hc), neg_mul] theorem le_div_iff_of_neg' (hc : c < 0) : a ≤ b / c ↔ b ≤ c * a := by rw [mul_comm, le_div_iff_of_neg hc] theorem div_lt_iff_of_neg (hc : c < 0) : b / c < a ↔ a * c < b := lt_iff_lt_of_le_iff_le <\| le_div_iff_of_neg hc theorem div_lt_iff_of_neg' (hc : c < 0) : b / c < a ↔ c * a < b := by rw [mul_comm, div_lt_iff_of_neg hc] theorem lt_div_iff_of_neg (hc : c < 0) : a < b / c ↔ b < a * c := lt_iff_lt_of_le_iff_le <\| div_le_iff_of_neg hc theorem lt_div_iff_of_neg' (hc : c < 0) : a < b / c ↔ b < c * a := by rw [mul_comm, lt_div_iff_of_neg hc] theorem div_le_one_of_ge (h : b ≤ a) (hb : b ≤ 0) : a / b ≤ 1 := by simpa only [neg_div_neg_eq] using div_le_one_of_le₀ (neg_le_neg h) (neg_nonneg_of_nonpos hb) /-! ### Bi-implications of inequalities using inversions -/ theorem inv_le_inv_of_neg (ha : a < 0) (hb : b < 0) : a⁻¹ ≤ b⁻¹ ↔ b ≤ a := by rw [← one_div, div_le_iff_of_neg ha, ← div_eq_inv_mul, div_le_iff_of_neg hb, one_mul] theorem inv_le_of_neg (ha : a < 0) (hb : b < 0) : a⁻¹ ≤ b ↔ b⁻¹ ≤ a := by rw [← inv_le_inv_of_neg hb (inv_lt_zero.2 ha), inv_inv] theorem le_inv_of_neg (ha : a < 0) (hb : b < 0) : a ≤ b⁻¹ ↔ b ≤ a⁻¹ := by rw [← inv_le_inv_of_neg (inv_lt_zero.2 hb) ha, inv_inv] theorem inv_lt_inv_of_neg (ha : a < 0) (hb : b < 0) : a⁻¹ < b⁻¹ ↔ b < a := lt_iff_lt_of_le_iff_le (inv_le_inv_of_neg hb ha) theorem inv_lt_of_neg (ha : a < 0) (hb : b < 0) : a⁻¹ < b ↔ b⁻¹ < a := lt_iff_lt_of_le_iff_le (le_inv_of_neg hb ha) theorem lt_inv_of_neg (ha : a < 0) (hb : b < 0) : a < b⁻¹ ↔ b < a⁻¹ := lt_iff_lt_of_le_iff_le (inv_le_of_neg hb ha) /-! ### Monotonicity results involving inversion -/ theorem sub_inv_antitoneOn_Ioi : AntitoneOn (fun x ↦ (x-c)⁻¹) (Set.Ioi c) := antitoneOn_iff_forall_lt.mpr fun _ ha _ hb hab ↦ inv_le_inv₀ (sub_pos.mpr hb) (sub_pos.mpr ha) \|>.mpr <\| sub_le_sub (le_of_lt hab) le_rfl theorem sub_inv_antitoneOn_Iio : AntitoneOn (fun x ↦ (x-c)⁻¹) (Set.Iio c) := antitoneOn_iff_forall_lt.mpr fun _ ha _ hb hab ↦ inv_le_inv_of_neg (sub_neg.mpr hb) (sub_neg.mpr ha) \|>.mpr <\| sub_le_sub (le_of_lt hab) le_rfl theorem sub_inv_antitoneOn_Icc_right (ha : c < a) : AntitoneOn (fun x ↦ (x-c)⁻¹) (Set.Icc a b) := by by_cases hab : a ≤ b · exact sub_inv_antitoneOn_Ioi.mono <\| (Set.Icc_subset_Ioi_iff hab).mpr ha · simp [hab, Set.Subsingleton.antitoneOn] theorem sub_inv_antitoneOn_Icc_left (ha : b < c) : AntitoneOn (fun x ↦ (x-c)⁻¹) (Set.Icc a b) := by by_cases hab : a ≤ b · exact sub_inv_antitoneOn_Iio.mono <\| (Set.Icc_subset_Iio_iff hab).mpr ha · simp [hab, Set.Subsingleton.antitoneOn] theorem inv_antitoneOn_Ioi : AntitoneOn (fun x : α ↦ x⁻¹) (Set.Ioi 0) := by convert sub_inv_antitoneOn_Ioi (α := α) exact (sub_zero _).symm theorem inv_antitoneOn_Iio : AntitoneOn (fun x : α ↦ x⁻¹) (Set.Iio 0) := by convert sub_inv_antitoneOn_Iio (α := α) exact (sub_zero _).symm theorem inv_antitoneOn_Icc_right (ha : 0 < a) : AntitoneOn (fun x : α ↦ x⁻¹) (Set.Icc a b) := by convert sub_inv_antitoneOn_Icc_right ha exact (sub_zero _).symm theorem inv_antitoneOn_Icc_left (hb : b < 0) : AntitoneOn (fun x : α ↦ x⁻¹) (Set.Icc a b) := by convert sub_inv_antitoneOn_Icc_left hb exact (sub_zero _).symm /-! ### Relating two divisions -/ theorem div_le_div_of_nonpos_of_le (hc : c ≤ 0) (h : b ≤ a) : a / c ≤ b / c := by rw [div_eq_mul_one_div a c, div_eq_mul_one_div b c] exact mul_le_mul_of_nonpos_right h (one_div_nonpos.2 hc) theorem div_lt_div_of_neg_of_lt (hc : c < 0) (h : b < a) : a / c < b / c := by rw [div_eq_mul_one_div a c, div_eq_mul_one_div b c] exact mul_lt_mul_of_neg_right h (one_div_neg.2 hc) theorem div_le_div_right_of_neg (hc : c < 0) : a / c ≤ b / c ↔ b ≤ a := ⟨le_imp_le_of_lt_imp_lt <\| div_lt_div_of_neg_of_lt hc, div_le_div_of_nonpos_of_le <\| hc.le⟩ theorem div_lt_div_right_of_neg (hc : c < 0) : a / c < b / c ↔ b < a := lt_iff_lt_of_le_iff_le <\| div_le_div_right_of_neg hc /-! ### Relating one division and involving `1` -/ theorem one_le_div_of_neg (hb : b < 0) : 1 ≤ a / b ↔ a ≤ b := by rw [le_div_iff_of_neg hb, one_mul] theorem div_le_one_of_neg (hb : b < 0) : a / b ≤ 1 ↔ b ≤ a := by rw [div_le_iff_of_neg hb, one_mul] theorem one_lt_div_of_neg (hb : b < 0) : 1 < a / b ↔ a < b := by rw [lt_div_iff_of_neg hb, one_mul] theorem div_lt_one_of_neg (hb : b < 0) : a / b < 1 ↔ b < a := by rw [div_lt_iff_of_neg hb, one_mul] theorem one_div_le_of_neg (ha : a < 0) (hb : b < 0) : 1 / a ≤ b ↔ 1 / b ≤ a := by simpa using inv_le_of_neg ha hb theorem one_div_lt_of_neg (ha : a < 0) (hb : b < 0) : 1 / a < b ↔ 1 / b < a := by simpa using inv_lt_of_neg ha hb theorem le_one_div_of_neg (ha : a < 0) (hb : b < 0) : a ≤ 1 / b ↔ b ≤ 1 / a := by simpa using le_inv_of_neg ha hb theorem lt_one_div_of_neg (ha : a < 0) (hb : b < 0) : a < 1 / b ↔ b < 1 / a := by simpa using lt_inv_of_neg ha hb theorem one_lt_div_iff : 1 < a / b ↔ 0 < b ∧ b < a ∨ b < 0 ∧ a < b := by rcases lt_trichotomy b 0 with (hb \| rfl \| hb) · simp [hb, hb.not_lt, one_lt_div_of_neg] · simp [lt_irrefl, zero_le_one] · simp [hb, hb.not_lt, one_lt_div] theorem one_le_div_iff : 1 ≤ a / b ↔ 0 < b ∧ b ≤ a ∨ b < 0 ∧ a ≤ b := by rcases lt_trichotomy b 0 with (hb \| rfl \| hb) · simp [hb, hb.not_lt, one_le_div_of_neg] · simp [lt_irrefl, zero_lt_one.not_le, zero_lt_one] · simp [hb, hb.not_lt, one_le_div] theorem div_lt_one_iff : a / b < 1 ↔ 0 < b ∧ a < b ∨ b = 0 ∨ b < 0 ∧ b < a := by rcases lt_trichotomy b 0 with (hb \| rfl \| hb) · simp [hb, hb.not_lt, hb.ne, div_lt_one_of_neg] · simp [zero_lt_one] · simp [hb, hb.not_lt, div_lt_one, hb.ne.symm] theorem div_le_one_iff : a / b ≤ 1 ↔ 0 < b ∧ a ≤ b ∨ b = 0 ∨ b < 0 ∧ b ≤ a := by rcases lt_trichotomy b 0 with (hb \| rfl \| hb) · simp [hb, hb.not_lt, hb.ne, div_le_one_of_neg] · simp [zero_le_one] · simp [hb, hb.not_lt, div_le_one, hb.ne.symm] /-! ### Relating two divisions, involving `1` -/ theorem one_div_le_one_div_of_neg_of_le (hb : b < 0) (h : a ≤ b) : 1 / b ≤ 1 / a := by rwa [div_le_iff_of_neg' hb, ← div_eq_mul_one_div, div_le_one_of_neg (h.trans_lt hb)] theorem one_div_lt_one_div_of_neg_of_lt (hb : b < 0) (h : a < b) : 1 / b < 1 / a := by rwa [div_lt_iff_of_neg' hb, ← div_eq_mul_one_div, div_lt_one_of_neg (h.trans hb)] theorem le_of_neg_of_one_div_le_one_div (hb : b < 0) (h : 1 / a ≤ 1 / b) : b ≤ a := le_imp_le_of_lt_imp_lt (one_div_lt_one_div_of_neg_of_lt hb) h theorem lt_of_neg_of_one_div_lt_one_div (hb : b < 0) (h : 1 / a < 1 / b) : b < a := lt_imp_lt_of_le_imp_le (one_div_le_one_div_of_neg_of_le hb) h /-- For the single implications with fewer assumptions, see `one_div_lt_one_div_of_neg_of_lt` and `lt_of_one_div_lt_one_div` -/ theorem one_div_le_one_div_of_neg (ha : a < 0) (hb : b < 0) : 1 / a ≤ 1 / b ↔ b ≤ a := by simpa [one_div] using inv_le_inv_of_neg ha hb /-- For the single implications with fewer assumptions, see `one_div_lt_one_div_of_lt` and `lt_of_one_div_lt_one_div` -/ theorem one_div_lt_one_div_of_neg (ha : a < 0) (hb : b < 0) : 1 / a < 1 / b ↔ b < a := lt_iff_lt_of_le_iff_le (one_div_le_one_div_of_neg hb ha) theorem one_div_lt_neg_one (h1 : a < 0) (h2 : -1 < a) : 1 / a < -1 := suffices 1 / a < 1 / -1 by rwa [one_div_neg_one_eq_neg_one] at this one_div_lt_one_div_of_neg_of_lt h1 h2 theorem one_div_le_neg_one (h1 : a < 0) (h2 : -1 ≤ a) : 1 / a ≤ -1 := suffices 1 / a ≤ 1 / -1 by rwa [one_div_neg_one_eq_neg_one] at this one_div_le_one_div_of_neg_of_le h1 h2 /-! ### Results about halving -/ theorem sub_self_div_two (a : α) : a - a / 2 = a / 2 := by suffices a / 2 + a / 2 - a / 2 = a / 2 by rwa [add_halves] at this rw [add_sub_cancel_right] theorem div_two_sub_self (a : α) : a / 2 - a = -(a / 2) := by suffices a / 2 - (a / 2 + a / 2) = -(a / 2) by rwa [add_halves] at this rw [sub_add_eq_sub_sub, sub_self, zero_sub] theorem add_sub_div_two_lt (h : a < b) : a + (b - a) / 2 < b := by rwa [← div_sub_div_same, sub_eq_add_neg, add_comm (b / 2), ← add_assoc, ← sub_eq_add_neg, ← lt_sub_iff_add_lt, sub_self_div_two, sub_self_div_two, div_lt_div_iff_of_pos_right (zero_lt_two' α)] /-- An inequality involving `2`. -/ theorem sub_one_div_inv_le_two (a2 : 2 ≤ a) : (1 - 1 / a)⁻¹ ≤ 2 := by -- Take inverses on both sides to obtain `2⁻¹ ≤ 1 - 1 / a` refine (inv_anti₀ (inv_pos.2 <\| zero_lt_two' α) ?_).trans_eq (inv_inv (2 : α)) -- move `1 / a` to the left and `2⁻¹` to the right. rw [le_sub_iff_add_le, add_comm, ← le_sub_iff_add_le] -- take inverses on both sides and use the assumption `2 ≤ a`. convert (one_div a).le.trans (inv_anti₀ zero_lt_two a2) using 1 -- show `1 - 1 / 2 = 1 / 2`. rw [sub_eq_iff_eq_add, ← two_mul, mul_inv_cancel₀ two_ne_zero] /-! ### Results about `IsLUB` -/ -- TODO: Generalize to `LinearOrderedSemifield` theorem IsLUB.mul_left {s : Set α} (ha : 0 ≤ a) (hs : IsLUB s b) : IsLUB ((fun b => a * b) '' s) (a * b) := by rcases lt_or_eq_of_le ha with (ha \| rfl) · exact (OrderIso.mulLeft₀ _ ha).isLUB_image'.2 hs · simp_rw [zero_mul] rw [hs.nonempty.image_const] exact isLUB_singleton -- TODO: Generalize to `LinearOrderedSemifield` theorem IsLUB.mul_right {s : Set α} (ha : 0 ≤ a) (hs : IsLUB s b) : IsLUB ((fun b => b * a) '' s) (b * a) := by simpa [mul_comm] using hs.mul_left ha /-! ### Miscellaneous lemmas -/ theorem mul_sub_mul_div_mul_neg_iff (hc : c ≠ 0) (hd : d ≠ 0) : (a * d - b * c) / (c * d) < 0 ↔ a / c < b / d := by rw [mul_comm b c, ← div_sub_div _ _ hc hd, sub_lt_zero] theorem mul_sub_mul_div_mul_nonpos_iff (hc : c ≠ 0) (hd : d ≠ 0) : (a * d - b * c) / (c * d) ≤ 0 ↔ a / c ≤ b / d := by rw [mul_comm b c, ← div_sub_div _ _ hc hd, sub_nonpos] alias ⟨div_lt_div_of_mul_sub_mul_div_neg, mul_sub_mul_div_mul_neg⟩ := mul_sub_mul_div_mul_neg_iff alias ⟨div_le_div_of_mul_sub_mul_div_nonpos, mul_sub_mul_div_mul_nonpos⟩ := mul_sub_mul_div_mul_nonpos_iff theorem exists_add_lt_and_pos_of_lt (h : b < a) : ∃ c, b + c < a ∧ 0 < c := ⟨(a - b) / 2, add_sub_div_two_lt h, div_pos (sub_pos_of_lt h) zero_lt_two⟩ theorem le_of_forall_sub_le (h : ∀ ε > 0, b - ε ≤ a) : b ≤ a := by contrapose! h simpa only [@and_comm ((0 : α) < _), lt_sub_iff_add_lt, gt_iff_lt] using exists_add_lt_and_pos_of_lt h private lemma exists_lt_mul_left_of_nonneg {a b c : α} (ha : 0 ≤ a) (hc : 0 ≤ c) (h : c < a * b) : ∃ a' ∈ Set.Ico 0 a, c < a' * b := by have hb : 0 < b := pos_of_mul_pos_right (hc.trans_lt h) ha obtain ⟨a', ha', a_a'⟩ := exists_between ((div_lt_iff₀ hb).2 h) exact ⟨a', ⟨(div_nonneg hc hb.le).trans ha'.le, a_a'⟩, (div_lt_iff₀ hb).1 ha'⟩ private lemma exists_lt_mul_right_of_nonneg {a b c : α} (ha : 0 ≤ a) (hc : 0 ≤ c) (h : c < a * b) : ∃ b' ∈ Set.Ico 0 b, c < a * b' := by have hb : 0 < b := pos_of_mul_pos_right (hc.trans_lt h) ha simp_rw [mul_comm a] at h ⊢ exact exists_lt_mul_left_of_nonneg hb.le hc h private lemma exists_mul_left_lt₀ {a b c : α} (hc : a * b < c) : ∃ a' > a, a' * b < c := by rcases le_or_lt b 0 with hb \| hb · obtain ⟨a', ha'⟩ := exists_gt a exact ⟨a', ha', hc.trans_le' (antitone_mul_right hb ha'.le)⟩ · obtain ⟨a', ha', hc'⟩ := exists_between ((lt_div_iff₀ hb).2 hc) exact ⟨a', ha', (lt_div_iff₀ hb).1 hc'⟩ private lemma exists_mul_right_lt₀ {a b c : α} (hc : a * b < c) : ∃ b' > b, a * b' < c := by simp_rw [mul_comm a] at hc ⊢; exact exists_mul_left_lt₀ hc lemma le_mul_of_forall_lt₀ {a b c : α} (h : ∀ a' > a, ∀ b' > b, c ≤ a' * b') : c ≤ a * b := by refine le_of_forall_gt_imp_ge_of_dense fun d hd ↦ ?_ obtain ⟨a', ha', hd⟩ := exists_mul_left_lt₀ hd obtain ⟨b', hb', hd⟩ := exists_mul_right_lt₀ hd exact (h a' ha' b' hb').trans hd.le lemma mul_le_of_forall_lt_of_nonneg {a b c : α} (ha : 0 ≤ a) (hc : 0 ≤ c) (h : ∀ a' ≥ 0, a' < a → ∀ b' ≥ 0, b' < b → a' * b' ≤ c) : a * b ≤ c := by refine le_of_forall_lt_imp_le_of_dense fun d d_ab ↦ ?_ rcases lt_or_le d 0 with hd \| hd · exact hd.le.trans hc obtain ⟨a', ha', d_ab⟩ := exists_lt_mul_left_of_nonneg ha hd d_ab obtain ⟨b', hb', d_ab⟩ := exists_lt_mul_right_of_nonneg ha'.1 hd d_ab exact d_ab.le.trans (h a' ha'.1 ha'.2 b' hb'.1 hb'.2) theorem mul_self_inj_of_nonneg (a0 : 0 ≤ a) (b0 : 0 ≤ b) : a * a = b * b ↔ a = b := mul_self_eq_mul_self_iff.trans <\| or_iff_left_of_imp fun h => by subst a have : b = 0 := le_antisymm (neg_nonneg.1 a0) b0 rw [this, neg_zero] theorem min_div_div_right_of_nonpos (hc : c ≤ 0) (a b : α) : min (a / c) (b / c) = max a b / c := Eq.symm <\| Antitone.map_max fun _ _ => div_le_div_of_nonpos_of_le hc theorem max_div_div_right_of_nonpos (hc : c ≤ 0) (a b : α) : max (a / c) (b / c) = min a b / c := Eq.symm <\| Antitone.map_min fun _ _ => div_le_div_of_nonpos_of_le hc theorem abs_inv (a : α) : \|a⁻¹\| = \|a\|⁻¹ := map_inv₀ (absHom : α →₀ α) a theorem abs_div (a b : α) : \|a / b\| = \|a\| / \|b\| := map_div₀ (absHom : α →₀ α) a b theorem abs_one_div (a : α) : \|1 / a\| = 1 / \|a\| := by rw [abs_div, abs_one] theorem uniform_continuous_npow_on_bounded (B : α) {ε : α} (hε : 0 < ε) (n : ℕ) : ∃ δ > 0, ∀ q r : α, \|r\| ≤ B → \|q - r\| ≤ δ → \|q ^ n - r ^ n\| < ε := by wlog B_pos : 0 < B generalizing B · have ⟨δ, δ_pos, cont⟩ := this 1 zero_lt_one exact ⟨δ, δ_pos, fun q r hr ↦ cont q r (hr.trans ((le_of_not_lt B_pos).trans zero_le_one))⟩ have pos : 0 < 1 + ↑n * (B + 1) ^ (n - 1) := zero_lt_one.trans_le <\| le_add_of_nonneg_right <\| mul_nonneg n.cast_nonneg <\| (pow_pos (B_pos.trans <\| lt_add_of_pos_right _ zero_lt_one) _).le refine ⟨min 1 (ε / (1 + n * (B + 1) ^ (n - 1))), lt_min zero_lt_one (div_pos hε pos), fun q r hr hqr ↦ (abs_pow_sub_pow_le ..).trans_lt ?_⟩ rw [le_inf_iff, le_div_iff₀ pos, mul_one_add, ← mul_assoc] at hqr obtain h \| h := (abs_nonneg (q - r)).eq_or_lt · simpa only [← h, zero_mul] using hε refine (lt_of_le_of_lt ?_ <\| lt_add_of_pos_left _ h).trans_le hqr.2 refine mul_le_mul_of_nonneg_left (pow_le_pow_left₀ ((abs_nonneg _).trans le_sup_left) ?_ _) (mul_nonneg (abs_nonneg _) n.cast_nonneg) refine max_le ?_ (hr.trans <\| le_add_of_nonneg_right zero_le_one) exact add_sub_cancel r q ▸ (abs_add_le ..).trans (add_le_add hr hqr.1) end namespace Mathlib.Meta.Positivity open Lean Meta Qq Function section LinearOrderedSemifield variable {α : Type*} [Semifield α] [LinearOrder α] [IsStrictOrderedRing α] {a b : α} private lemma div_nonneg_of_pos_of_nonneg (ha : 0 < a) (hb : 0 ≤ b) : 0 ≤ a / b := div_nonneg ha.le hb private lemma div_nonneg_of_nonneg_of_pos (ha : 0 ≤ a) (hb : 0 < b) : 0 ≤ a / b := div_nonneg ha hb.le omit [IsStrictOrderedRing α] in private lemma div_ne_zero_of_pos_of_ne_zero (ha : 0 < a) (hb : b ≠ 0) : a / b ≠ 0 := div_ne_zero ha.ne' hb omit [IsStrictOrderedRing α] in private lemma div_ne_zero_of_ne_zero_of_pos (ha : a ≠ 0) (hb : 0 < b) : a / b ≠ 0 := div_ne_zero ha hb.ne' private lemma zpow_zero_pos (a : α) : 0 < a ^ (0 : ℤ) := zero_lt_one.trans_eq (zpow_zero a).symm end LinearOrderedSemifield /-- The `positivity` extension which identifies expressions of the form `a / b`, such that `positivity` successfully recognises both `a` and `b`. -/ @[positivity _ / _] def evalDiv : PositivityExt where eval {u α} zα pα e := do let .app (.app (f : Q($α → $α → $α)) (a : Q($α))) (b : Q($α)) ← withReducible (whnf e) \| throwError "not /" let _e_eq : $e =Q $f $a $b := ⟨⟩ let _a ← synthInstanceQ q(Semifield $α) let _a ← synthInstanceQ q(LinearOrder $α) let _a ← synthInstanceQ q(IsStrictOrderedRing $α) assumeInstancesCommute let ⟨_f_eq⟩ ← withDefault <\| withNewMCtxDepth <\| assertDefEqQ q($f) q(HDiv.hDiv) let ra ← core zα pα a; let rb ← core zα pα b match ra, rb with \| .positive pa, .positive pb => pure (.positive q(div_pos $pa $pb)) \| .positive pa, .nonnegative pb => pure (.nonnegative q(div_nonneg_of_pos_of_nonneg $pa $pb)) \| .nonnegative pa, .positive pb => pure (.nonnegative q(div_nonneg_of_nonneg_of_pos $pa $pb)) \| .nonnegative pa, .nonnegative pb => pure (.nonnegative q(div_nonneg $pa $pb)) \| .positive pa, .nonzero pb => pure (.nonzero q(div_ne_zero_of_pos_of_ne_zero $pa $pb)) \| .nonzero pa, .positive pb => pure (.nonzero q(div_ne_zero_of_ne_zero_of_pos $pa $pb)) \| .nonzero pa, .nonzero pb => pure (.nonzero q(div_ne_zero $pa $pb)) \| _, _ => pure .none /-- The `positivity` extension which identifies expressions of the form `a⁻¹`, such that `positivity` successfully recognises `a`. -/ @[positivity _⁻¹] def evalInv : PositivityExt where eval {u α} zα pα e := do let .app (f : Q($α → $α)) (a : Q($α)) ← withReducible (whnf e) \| throwError "not ⁻¹" let _e_eq : $e =Q $f $a := ⟨⟩ let _a ← synthInstanceQ q(Semifield $α) let _a ← synthInstanceQ q(LinearOrder $α) let _a ← synthInstanceQ q(IsStrictOrderedRing $α) assumeInstancesCommute let ⟨_f_eq⟩ ← withDefault <\| withNewMCtxDepth <\| assertDefEqQ q($f) q(Inv.inv) let ra ← core zα pα a match ra with \| .positive pa => pure (.positive q(inv_pos_of_pos $pa)) \| .nonnegative pa => pure (.nonnegative q(inv_nonneg_of_nonneg $pa)) \| .nonzero pa => pure (.nonzero q(inv_ne_zero $pa)) \| .none => pure .none /-- The `positivity` extension which identifies expressions of the form `a ^ (0:ℤ)`. -/ @[positivity _ ^ (0 : ℤ), Pow.pow _ (0 : ℤ)] def evalPowZeroInt : PositivityExt where eval {u α} _zα _pα e := do let .app (.app _ (a : Q($α))) _ ← withReducible (whnf e) \| throwError "not ^" let _a ← synthInstanceQ q(Semifield $α) let _a ← synthInstanceQ q(LinearOrder $α) let _a ← synthInstanceQ q(IsStrictOrderedRing $α) assumeInstancesCommute let ⟨_a⟩ ← Qq.assertDefEqQ q($e) q($a ^ (0 : ℤ)) pure (.positive q(zpow_zero_pos $a)) end Mathlib.Meta.Positivity		Mathlib/Algebra/Order/Field/Basic.lean	862	863
/- 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	3,652	3,658
/- 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.Fin.VecNotation import Mathlib.SetTheory.Cardinal.Basic /-! # Basics on First-Order Structures This file defines first-order languages and structures in the style of the [Flypitch project](https://flypitch.github.io/), as well as several important maps between structures. ## Main Definitions - A `FirstOrder.Language` defines a language as a pair of functions from the natural numbers to `Type l`. One sends `n` to the type of `n`-ary functions, and the other sends `n` to the type of `n`-ary relations. - A `FirstOrder.Language.Structure` interprets the symbols of a given `FirstOrder.Language` in the context of a given type. - A `FirstOrder.Language.Hom`, denoted `M →[L] N`, is a map from the `L`-structure `M` to the `L`-structure `N` that commutes with the interpretations of functions, and which preserves the interpretations of relations (although only in the forward direction). - A `FirstOrder.Language.Embedding`, denoted `M ↪[L] N`, is an embedding from the `L`-structure `M` to the `L`-structure `N` that commutes with the interpretations of functions, and which preserves the interpretations of relations in both directions. - A `FirstOrder.Language.Equiv`, denoted `M ≃[L] N`, is an equivalence from the `L`-structure `M` to the `L`-structure `N` that commutes with the interpretations of functions, and which preserves the interpretations of relations in both directions. ## 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 u' v' w w' open Cardinal namespace FirstOrder /-! ### Languages and Structures -/ -- intended to be used with explicit universe parameters /-- A first-order language consists of a type of functions of every natural-number arity and a type of relations of every natural-number arity. -/ @[nolint checkUnivs] structure Language where /-- For every arity, a `Type` of functions of that arity -/ Functions : ℕ → Type u /-- For every arity, a `Type` of relations of that arity -/ Relations : ℕ → Type v namespace Language variable (L : Language.{u, v}) /-- A language is relational when it has no function symbols. -/ abbrev IsRelational : Prop := ∀ n, IsEmpty (L.Functions n) /-- A language is algebraic when it has no relation symbols. -/ abbrev IsAlgebraic : Prop := ∀ n, IsEmpty (L.Relations n) /-- The empty language has no symbols. -/ protected def empty : Language := ⟨fun _ => Empty, fun _ => Empty⟩ deriving IsAlgebraic, IsRelational instance : Inhabited Language := ⟨Language.empty⟩ /-- The sum of two languages consists of the disjoint union of their symbols. -/ protected def sum (L' : Language.{u', v'}) : Language := ⟨fun n => L.Functions n ⊕ L'.Functions n, fun n => L.Relations n ⊕ L'.Relations n⟩ /-- The type of constants in a given language. -/ protected abbrev Constants := L.Functions 0 /-- The type of symbols in a given language. -/ abbrev Symbols := (Σ l, L.Functions l) ⊕ (Σ l, L.Relations l) /-- The cardinality of a language is the cardinality of its type of symbols. -/ def card : Cardinal := #L.Symbols variable {L} {L' : Language.{u', v'}} theorem card_eq_card_functions_add_card_relations : L.card = (Cardinal.sum fun l => Cardinal.lift.{v} #(L.Functions l)) + Cardinal.sum fun l => Cardinal.lift.{u} #(L.Relations l) := by simp only [card, mk_sum, mk_sigma, lift_sum] instance isRelational_sum [L.IsRelational] [L'.IsRelational] : IsRelational (L.sum L') := fun _ => instIsEmptySum instance isAlgebraic_sum [L.IsAlgebraic] [L'.IsAlgebraic] : IsAlgebraic (L.sum L') := fun _ => instIsEmptySum @[simp] theorem card_empty : Language.empty.card = 0 := by simp only [card, mk_sum, mk_sigma, mk_eq_zero, sum_const, mk_eq_aleph0, lift_id', mul_zero, add_zero] @[deprecated (since := "2025-02-05")] alias empty_card := card_empty instance isEmpty_empty : IsEmpty Language.empty.Symbols := by simp only [Language.Symbols, isEmpty_sum, isEmpty_sigma] exact ⟨fun _ => inferInstance, fun _ => inferInstance⟩ instance Countable.countable_functions [h : Countable L.Symbols] : Countable (Σl, L.Functions l) := @Function.Injective.countable _ _ h _ Sum.inl_injective @[simp] theorem card_functions_sum (i : ℕ) : #((L.sum L').Functions i) = (Cardinal.lift.{u'} #(L.Functions i) + Cardinal.lift.{u} #(L'.Functions i) : Cardinal) := by simp [Language.sum] @[simp] theorem card_relations_sum (i : ℕ) : #((L.sum L').Relations i) = Cardinal.lift.{v'} #(L.Relations i) + Cardinal.lift.{v} #(L'.Relations i) := by simp [Language.sum] theorem card_sum : (L.sum L').card = Cardinal.lift.{max u' v'} L.card + Cardinal.lift.{max u v} L'.card := by simp only [card, mk_sum, mk_sigma, card_functions_sum, sum_add_distrib', lift_add, lift_sum, lift_lift, card_relations_sum, add_assoc, add_comm (Cardinal.sum fun i => (#(L'.Functions i)).lift)] /-- Passes a `DecidableEq` instance on a type of function symbols through the `Language` constructor. Despite the fact that this is proven by `inferInstance`, it is still needed - see the `example`s in `ModelTheory/Ring/Basic`. -/ instance instDecidableEqFunctions {f : ℕ → Type} {R : ℕ → Type} (n : ℕ) [DecidableEq (f n)] : DecidableEq ((⟨f, R⟩ : Language).Functions n) := inferInstance /-- Passes a `DecidableEq` instance on a type of relation symbols through the `Language` constructor. Despite the fact that this is proven by `inferInstance`, it is still needed - see the `example`s in `ModelTheory/Ring/Basic`. -/ instance instDecidableEqRelations {f : ℕ → Type} {R : ℕ → Type} (n : ℕ) [DecidableEq (R n)] : DecidableEq ((⟨f, R⟩ : Language).Relations n) := inferInstance variable (L) (M : Type w) /-- A first-order structure on a type `M` consists of interpretations of all the symbols in a given language. Each function of arity `n` is interpreted as a function sending tuples of length `n` (modeled as `(Fin n → M)`) to `M`, and a relation of arity `n` is a function from tuples of length `n` to `Prop`. -/ @[ext] class Structure where /-- Interpretation of the function symbols -/ funMap : ∀ {n}, L.Functions n → (Fin n → M) → M := by exact fun {n} => isEmptyElim /-- Interpretation of the relation symbols -/ RelMap : ∀ {n}, L.Relations n → (Fin n → M) → Prop := by exact fun {n} => isEmptyElim variable (N : Type w') [L.Structure M] [L.Structure N] open Structure /-- Used for defining `FirstOrder.Language.Theory.ModelType.instInhabited`. -/ def Inhabited.trivialStructure {α : Type} [Inhabited α] : L.Structure α := ⟨default, default⟩ /-! ### Maps -/ /-- A homomorphism between first-order structures is a function that commutes with the interpretations of functions and maps tuples in one structure where a given relation is true to tuples in the second structure where that relation is still true. -/ structure Hom where /-- The underlying function of a homomorphism of structures -/ toFun : M → N /-- The homomorphism commutes with the interpretations of the function symbols -/ -- Porting note: -- The autoparam here used to be `obviously`. We would like to replace it with `aesop` -- but that isn't currently sufficient. -- See https://leanprover.zulipchat.com/#narrow/stream/287929-mathlib4/topic/Aesop.20and.20cases -- If that can be improved, we should change this to `by aesop` and remove the proofs below. map_fun' : ∀ {n} (f : L.Functions n) (x), toFun (funMap f x) = funMap f (toFun ∘ x) := by intros; trivial /-- The homomorphism sends related elements to related elements -/ map_rel' : ∀ {n} (r : L.Relations n) (x), RelMap r x → RelMap r (toFun ∘ x) := by -- Porting note: see porting note on `Hom.map_fun'` intros; trivial @[inherit_doc] scoped[FirstOrder] notation:25 A " →[" L "] " B => FirstOrder.Language.Hom L A B /-- An embedding of first-order structures is an embedding that commutes with the interpretations of functions and relations. -/ structure Embedding extends M ↪ N where map_fun' : ∀ {n} (f : L.Functions n) (x), toFun (funMap f x) = funMap f (toFun ∘ x) := by -- Porting note: see porting note on `Hom.map_fun'` intros; trivial map_rel' : ∀ {n} (r : L.Relations n) (x), RelMap r (toFun ∘ x) ↔ RelMap r x := by -- Porting note: see porting note on `Hom.map_fun'` intros; trivial @[inherit_doc] scoped[FirstOrder] notation:25 A " ↪[" L "] " B => FirstOrder.Language.Embedding L A B /-- An equivalence of first-order structures is an equivalence that commutes with the interpretations of functions and relations. -/ structure Equiv extends M ≃ N where map_fun' : ∀ {n} (f : L.Functions n) (x), toFun (funMap f x) = funMap f (toFun ∘ x) := by -- Porting note: see porting note on `Hom.map_fun'` intros; trivial map_rel' : ∀ {n} (r : L.Relations n) (x), RelMap r (toFun ∘ x) ↔ RelMap r x := by -- Porting note: see porting note on `Hom.map_fun'` intros; trivial @[inherit_doc] scoped[FirstOrder] notation:25 A " ≃[" L "] " B => FirstOrder.Language.Equiv L A B variable {L M N} {P : Type} [L.Structure P] {Q : Type} [L.Structure Q] /-- Interpretation of a constant symbol -/ @[coe] def constantMap (c : L.Constants) : M := funMap c default instance : CoeTC L.Constants M := ⟨constantMap⟩ theorem funMap_eq_coe_constants {c : L.Constants} {x : Fin 0 → M} : funMap c x = c := congr rfl (funext finZeroElim) /-- Given a language with a nonempty type of constants, any structure will be nonempty. This cannot be a global instance, because `L` becomes a metavariable. -/ theorem nonempty_of_nonempty_constants [h : Nonempty L.Constants] : Nonempty M := h.map (↑) /-- `HomClass L F M N` states that `F` is a type of `L`-homomorphisms. You should extend this typeclass when you extend `FirstOrder.Language.Hom`. -/ class HomClass (L : outParam Language) (F : Type) (M N : outParam Type*) [FunLike F M N] [L.Structure M] [L.Structure N] : Prop where map_fun : ∀ (φ : F) {n} (f : L.Functions n) (x), φ (funMap f x) = funMap f (φ ∘ x)	map_rel : ∀ (φ : F) {n} (r : L.Relations n) (x), RelMap r x → RelMap r (φ ∘ x) /-- `StrongHomClass L F M N` states that `F` is a type of `L`-homomorphisms which preserve relations in both directions. -/	Mathlib/ModelTheory/Basic.lean	248	251
/- 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.Measure.Comap import Mathlib.MeasureTheory.Measure.QuasiMeasurePreserving /-! # Restricting a measure to a subset or a subtype Given a measure `μ` on a type `α` and a subset `s` of `α`, we define a measure `μ.restrict s` as the restriction of `μ` to `s` (still as a measure on `α`). We investigate how this notion interacts with usual operations on measures (sum, pushforward, pullback), and on sets (inclusion, union, Union). We also study the relationship between the restriction of a measure to a subtype (given by the pullback under `Subtype.val`) and the restriction to a set as above. -/ open scoped ENNReal NNReal Topology open Set MeasureTheory Measure Filter MeasurableSpace ENNReal Function variable {R α β δ γ ι : Type} namespace MeasureTheory variable {m0 : MeasurableSpace α} [MeasurableSpace β] [MeasurableSpace γ] variable {μ μ₁ μ₂ μ₃ ν ν' ν₁ ν₂ : Measure α} {s s' t : Set α} namespace Measure /-! ### Restricting a measure -/ /-- Restrict a measure `μ` to a set `s` as an `ℝ≥0∞`-linear map. -/ noncomputable def restrictₗ {m0 : MeasurableSpace α} (s : Set α) : Measure α →ₗ[ℝ≥0∞] Measure α := liftLinear (OuterMeasure.restrict s) fun μ s' hs' t => by suffices μ (s ∩ t) = μ (s ∩ t ∩ s') + μ ((s ∩ t) \ s') by simpa [← Set.inter_assoc, Set.inter_comm _ s, ← inter_diff_assoc] exact le_toOuterMeasure_caratheodory _ _ hs' _ /-- Restrict a measure `μ` to a set `s`. -/ noncomputable def restrict {_m0 : MeasurableSpace α} (μ : Measure α) (s : Set α) : Measure α := restrictₗ s μ @[simp] theorem restrictₗ_apply {_m0 : MeasurableSpace α} (s : Set α) (μ : Measure α) : restrictₗ s μ = μ.restrict s := rfl /-- This lemma shows that `restrict` and `toOuterMeasure` commute. Note that the LHS has a restrict on measures and the RHS has a restrict on outer measures. -/ theorem restrict_toOuterMeasure_eq_toOuterMeasure_restrict (h : MeasurableSet s) : (μ.restrict s).toOuterMeasure = OuterMeasure.restrict s μ.toOuterMeasure := by simp_rw [restrict, restrictₗ, liftLinear, LinearMap.coe_mk, AddHom.coe_mk, toMeasure_toOuterMeasure, OuterMeasure.restrict_trim h, μ.trimmed] theorem restrict_apply₀ (ht : NullMeasurableSet t (μ.restrict s)) : μ.restrict s t = μ (t ∩ s) := by rw [← restrictₗ_apply, restrictₗ, liftLinear_apply₀ _ ht, OuterMeasure.restrict_apply, coe_toOuterMeasure] /-- If `t` is a measurable set, then the measure of `t` with respect to the restriction of the measure to `s` equals the outer measure of `t ∩ s`. An alternate version requiring that `s` be measurable instead of `t` exists as `Measure.restrict_apply'`. -/ @[simp] theorem restrict_apply (ht : MeasurableSet t) : μ.restrict s t = μ (t ∩ s) := restrict_apply₀ ht.nullMeasurableSet /-- Restriction of a measure to a subset is monotone both in set and in measure. -/ theorem restrict_mono' {_m0 : MeasurableSpace α} ⦃s s' : Set α⦄ ⦃μ ν : Measure α⦄ (hs : s ≤ᵐ[μ] s') (hμν : μ ≤ ν) : μ.restrict s ≤ ν.restrict s' := Measure.le_iff.2 fun t ht => calc μ.restrict s t = μ (t ∩ s) := restrict_apply ht _ ≤ μ (t ∩ s') := (measure_mono_ae <\| hs.mono fun _x hx ⟨hxt, hxs⟩ => ⟨hxt, hx hxs⟩) _ ≤ ν (t ∩ s') := le_iff'.1 hμν (t ∩ s') _ = ν.restrict s' t := (restrict_apply ht).symm /-- Restriction of a measure to a subset is monotone both in set and in measure. -/ @[mono, gcongr] theorem restrict_mono {_m0 : MeasurableSpace α} ⦃s s' : Set α⦄ (hs : s ⊆ s') ⦃μ ν : Measure α⦄ (hμν : μ ≤ ν) : μ.restrict s ≤ ν.restrict s' := restrict_mono' (ae_of_all _ hs) hμν @[gcongr] theorem restrict_mono_measure {_ : MeasurableSpace α} {μ ν : Measure α} (h : μ ≤ ν) (s : Set α) : μ.restrict s ≤ ν.restrict s := restrict_mono subset_rfl h @[gcongr] theorem restrict_mono_set {_ : MeasurableSpace α} (μ : Measure α) {s t : Set α} (h : s ⊆ t) : μ.restrict s ≤ μ.restrict t := restrict_mono h le_rfl theorem restrict_mono_ae (h : s ≤ᵐ[μ] t) : μ.restrict s ≤ μ.restrict t := restrict_mono' h (le_refl μ) theorem restrict_congr_set (h : s =ᵐ[μ] t) : μ.restrict s = μ.restrict t := le_antisymm (restrict_mono_ae h.le) (restrict_mono_ae h.symm.le) /-- If `s` is a measurable set, then the outer measure of `t` with respect to the restriction of the measure to `s` equals the outer measure of `t ∩ s`. This is an alternate version of `Measure.restrict_apply`, requiring that `s` is measurable instead of `t`. -/ @[simp] theorem restrict_apply' (hs : MeasurableSet s) : μ.restrict s t = μ (t ∩ s) := by rw [← toOuterMeasure_apply, Measure.restrict_toOuterMeasure_eq_toOuterMeasure_restrict hs, OuterMeasure.restrict_apply s t _, toOuterMeasure_apply] theorem restrict_apply₀' (hs : NullMeasurableSet s μ) : μ.restrict s t = μ (t ∩ s) := by rw [← restrict_congr_set hs.toMeasurable_ae_eq, restrict_apply' (measurableSet_toMeasurable _ _), measure_congr ((ae_eq_refl t).inter hs.toMeasurable_ae_eq)] theorem restrict_le_self : μ.restrict s ≤ μ := Measure.le_iff.2 fun t ht => calc μ.restrict s t = μ (t ∩ s) := restrict_apply ht _ ≤ μ t := measure_mono inter_subset_left variable (μ) theorem restrict_eq_self (h : s ⊆ t) : μ.restrict t s = μ s := (le_iff'.1 restrict_le_self s).antisymm <\| calc μ s ≤ μ (toMeasurable (μ.restrict t) s ∩ t) := measure_mono (subset_inter (subset_toMeasurable _ _) h) _ = μ.restrict t s := by rw [← restrict_apply (measurableSet_toMeasurable _ _), measure_toMeasurable] @[simp] theorem restrict_apply_self (s : Set α) : (μ.restrict s) s = μ s := restrict_eq_self μ Subset.rfl variable {μ} theorem restrict_apply_univ (s : Set α) : μ.restrict s univ = μ s := by rw [restrict_apply MeasurableSet.univ, Set.univ_inter] theorem le_restrict_apply (s t : Set α) : μ (t ∩ s) ≤ μ.restrict s t := calc μ (t ∩ s) = μ.restrict s (t ∩ s) := (restrict_eq_self μ inter_subset_right).symm _ ≤ μ.restrict s t := measure_mono inter_subset_left theorem restrict_apply_le (s t : Set α) : μ.restrict s t ≤ μ t := Measure.le_iff'.1 restrict_le_self _ theorem restrict_apply_superset (h : s ⊆ t) : μ.restrict s t = μ s := ((measure_mono (subset_univ _)).trans_eq <\| restrict_apply_univ _).antisymm ((restrict_apply_self μ s).symm.trans_le <\| measure_mono h) @[simp] theorem restrict_add {_m0 : MeasurableSpace α} (μ ν : Measure α) (s : Set α) : (μ + ν).restrict s = μ.restrict s + ν.restrict s := (restrictₗ s).map_add μ ν @[simp] theorem restrict_zero {_m0 : MeasurableSpace α} (s : Set α) : (0 : Measure α).restrict s = 0 := (restrictₗ s).map_zero @[simp] theorem restrict_smul {_m0 : MeasurableSpace α} {R : Type} [SMul R ℝ≥0∞] [IsScalarTower R ℝ≥0∞ ℝ≥0∞] (c : R) (μ : Measure α) (s : Set α) : (c • μ).restrict s = c • μ.restrict s := by simpa only [smul_one_smul] using (restrictₗ s).map_smul (c • 1) μ theorem restrict_restrict₀ (hs : NullMeasurableSet s (μ.restrict t)) : (μ.restrict t).restrict s = μ.restrict (s ∩ t) := ext fun u hu => by simp only [Set.inter_assoc, restrict_apply hu, restrict_apply₀ (hu.nullMeasurableSet.inter hs)] @[simp] theorem restrict_restrict (hs : MeasurableSet s) : (μ.restrict t).restrict s = μ.restrict (s ∩ t) := restrict_restrict₀ hs.nullMeasurableSet theorem restrict_restrict_of_subset (h : s ⊆ t) : (μ.restrict t).restrict s = μ.restrict s := by ext1 u hu rw [restrict_apply hu, restrict_apply hu, restrict_eq_self] exact inter_subset_right.trans h theorem restrict_restrict₀' (ht : NullMeasurableSet t μ) : (μ.restrict t).restrict s = μ.restrict (s ∩ t) := ext fun u hu => by simp only [restrict_apply hu, restrict_apply₀' ht, inter_assoc] theorem restrict_restrict' (ht : MeasurableSet t) : (μ.restrict t).restrict s = μ.restrict (s ∩ t) := restrict_restrict₀' ht.nullMeasurableSet theorem restrict_comm (hs : MeasurableSet s) : (μ.restrict t).restrict s = (μ.restrict s).restrict t := by rw [restrict_restrict hs, restrict_restrict' hs, inter_comm] theorem restrict_apply_eq_zero (ht : MeasurableSet t) : μ.restrict s t = 0 ↔ μ (t ∩ s) = 0 := by rw [restrict_apply ht] theorem measure_inter_eq_zero_of_restrict (h : μ.restrict s t = 0) : μ (t ∩ s) = 0 := nonpos_iff_eq_zero.1 (h ▸ le_restrict_apply _ _) theorem restrict_apply_eq_zero' (hs : MeasurableSet s) : μ.restrict s t = 0 ↔ μ (t ∩ s) = 0 := by rw [restrict_apply' hs] @[simp] theorem restrict_eq_zero : μ.restrict s = 0 ↔ μ s = 0 := by rw [← measure_univ_eq_zero, restrict_apply_univ] /-- If `μ s ≠ 0`, then `μ.restrict s ≠ 0`, in terms of `NeZero` instances. -/ instance restrict.neZero [NeZero (μ s)] : NeZero (μ.restrict s) := ⟨mt restrict_eq_zero.mp <\| NeZero.ne _⟩ theorem restrict_zero_set {s : Set α} (h : μ s = 0) : μ.restrict s = 0 := restrict_eq_zero.2 h @[simp] theorem restrict_empty : μ.restrict ∅ = 0 := restrict_zero_set measure_empty @[simp] theorem restrict_univ : μ.restrict univ = μ := ext fun s hs => by simp [hs] theorem restrict_inter_add_diff₀ (s : Set α) (ht : NullMeasurableSet t μ) : μ.restrict (s ∩ t) + μ.restrict (s \ t) = μ.restrict s := by ext1 u hu simp only [add_apply, restrict_apply hu, ← inter_assoc, diff_eq] exact measure_inter_add_diff₀ (u ∩ s) ht theorem restrict_inter_add_diff (s : Set α) (ht : MeasurableSet t) : μ.restrict (s ∩ t) + μ.restrict (s \ t) = μ.restrict s := restrict_inter_add_diff₀ s ht.nullMeasurableSet theorem restrict_union_add_inter₀ (s : Set α) (ht : NullMeasurableSet t μ) : μ.restrict (s ∪ t) + μ.restrict (s ∩ t) = μ.restrict s + μ.restrict t := by rw [← restrict_inter_add_diff₀ (s ∪ t) ht, union_inter_cancel_right, union_diff_right, ← restrict_inter_add_diff₀ s ht, add_comm, ← add_assoc, add_right_comm] theorem restrict_union_add_inter (s : Set α) (ht : MeasurableSet t) : μ.restrict (s ∪ t) + μ.restrict (s ∩ t) = μ.restrict s + μ.restrict t := restrict_union_add_inter₀ s ht.nullMeasurableSet theorem restrict_union_add_inter' (hs : MeasurableSet s) (t : Set α) : μ.restrict (s ∪ t) + μ.restrict (s ∩ t) = μ.restrict s + μ.restrict t := by simpa only [union_comm, inter_comm, add_comm] using restrict_union_add_inter t hs theorem restrict_union₀ (h : AEDisjoint μ s t) (ht : NullMeasurableSet t μ) : μ.restrict (s ∪ t) = μ.restrict s + μ.restrict t := by simp [← restrict_union_add_inter₀ s ht, restrict_zero_set h] theorem restrict_union (h : Disjoint s t) (ht : MeasurableSet t) : μ.restrict (s ∪ t) = μ.restrict s + μ.restrict t := restrict_union₀ h.aedisjoint ht.nullMeasurableSet theorem restrict_union' (h : Disjoint s t) (hs : MeasurableSet s) : μ.restrict (s ∪ t) = μ.restrict s + μ.restrict t := by rw [union_comm, restrict_union h.symm hs, add_comm] @[simp] theorem restrict_add_restrict_compl (hs : MeasurableSet s) : μ.restrict s + μ.restrict sᶜ = μ := by rw [← restrict_union (@disjoint_compl_right (Set α) _ _) hs.compl, union_compl_self, restrict_univ] @[simp] theorem restrict_compl_add_restrict (hs : MeasurableSet s) : μ.restrict sᶜ + μ.restrict s = μ := by rw [add_comm, restrict_add_restrict_compl hs] theorem restrict_union_le (s s' : Set α) : μ.restrict (s ∪ s') ≤ μ.restrict s + μ.restrict s' := le_iff.2 fun t ht ↦ by simpa [ht, inter_union_distrib_left] using measure_union_le (t ∩ s) (t ∩ s') theorem restrict_iUnion_apply_ae [Countable ι] {s : ι → Set α} (hd : Pairwise (AEDisjoint μ on s)) (hm : ∀ i, NullMeasurableSet (s i) μ) {t : Set α} (ht : MeasurableSet t) : μ.restrict (⋃ i, s i) t = ∑' i, μ.restrict (s i) t := by simp only [restrict_apply, ht, inter_iUnion] exact measure_iUnion₀ (hd.mono fun i j h => h.mono inter_subset_right inter_subset_right) fun i => ht.nullMeasurableSet.inter (hm i) theorem restrict_iUnion_apply [Countable ι] {s : ι → Set α} (hd : Pairwise (Disjoint on s)) (hm : ∀ i, MeasurableSet (s i)) {t : Set α} (ht : MeasurableSet t) : μ.restrict (⋃ i, s i) t = ∑' i, μ.restrict (s i) t := restrict_iUnion_apply_ae hd.aedisjoint (fun i => (hm i).nullMeasurableSet) ht theorem restrict_iUnion_apply_eq_iSup [Countable ι] {s : ι → Set α} (hd : Directed (· ⊆ ·) s) {t : Set α} (ht : MeasurableSet t) : μ.restrict (⋃ i, s i) t = ⨆ i, μ.restrict (s i) t := by simp only [restrict_apply ht, inter_iUnion] rw [Directed.measure_iUnion] exacts [hd.mono_comp _ fun s₁ s₂ => inter_subset_inter_right _] /-- The restriction of the pushforward measure is the pushforward of the restriction. For a version assuming only `AEMeasurable`, see `restrict_map_of_aemeasurable`. -/ theorem restrict_map {f : α → β} (hf : Measurable f) {s : Set β} (hs : MeasurableSet s) : (μ.map f).restrict s = (μ.restrict <\| f ⁻¹' s).map f := ext fun t ht => by simp [, hf ht] theorem restrict_toMeasurable (h : μ s ≠ ∞) : μ.restrict (toMeasurable μ s) = μ.restrict s := ext fun t ht => by rw [restrict_apply ht, restrict_apply ht, inter_comm, measure_toMeasurable_inter ht h, inter_comm] theorem restrict_eq_self_of_ae_mem {_m0 : MeasurableSpace α} ⦃s : Set α⦄ ⦃μ : Measure α⦄ (hs : ∀ᵐ x ∂μ, x ∈ s) : μ.restrict s = μ := calc μ.restrict s = μ.restrict univ := restrict_congr_set (eventuallyEq_univ.mpr hs) _ = μ := restrict_univ theorem restrict_congr_meas (hs : MeasurableSet s) : μ.restrict s = ν.restrict s ↔ ∀ t ⊆ s, MeasurableSet t → μ t = ν t := ⟨fun H t hts ht => by rw [← inter_eq_self_of_subset_left hts, ← restrict_apply ht, H, restrict_apply ht], fun H => ext fun t ht => by rw [restrict_apply ht, restrict_apply ht, H _ inter_subset_right (ht.inter hs)]⟩ theorem restrict_congr_mono (hs : s ⊆ t) (h : μ.restrict t = ν.restrict t) : μ.restrict s = ν.restrict s := by rw [← restrict_restrict_of_subset hs, h, restrict_restrict_of_subset hs] /-- If two measures agree on all measurable subsets of `s` and `t`, then they agree on all measurable subsets of `s ∪ t`. -/ theorem restrict_union_congr : μ.restrict (s ∪ t) = ν.restrict (s ∪ t) ↔ μ.restrict s = ν.restrict s ∧ μ.restrict t = ν.restrict t := by refine ⟨fun h ↦ ⟨restrict_congr_mono subset_union_left h, restrict_congr_mono subset_union_right h⟩, ?_⟩ rintro ⟨hs, ht⟩ ext1 u hu simp only [restrict_apply hu, inter_union_distrib_left] rcases exists_measurable_superset₂ μ ν (u ∩ s) with ⟨US, hsub, hm, hμ, hν⟩ calc μ (u ∩ s ∪ u ∩ t) = μ (US ∪ u ∩ t) := measure_union_congr_of_subset hsub hμ.le Subset.rfl le_rfl _ = μ US + μ ((u ∩ t) \ US) := (measure_add_diff hm.nullMeasurableSet _).symm _ = restrict μ s u + restrict μ t (u \ US) := by simp only [restrict_apply, hu, hu.diff hm, hμ, ← inter_comm t, inter_diff_assoc] _ = restrict ν s u + restrict ν t (u \ US) := by rw [hs, ht] _ = ν US + ν ((u ∩ t) \ US) := by simp only [restrict_apply, hu, hu.diff hm, hν, ← inter_comm t, inter_diff_assoc] _ = ν (US ∪ u ∩ t) := measure_add_diff hm.nullMeasurableSet _ _ = ν (u ∩ s ∪ u ∩ t) := .symm <\| measure_union_congr_of_subset hsub hν.le Subset.rfl le_rfl theorem restrict_finset_biUnion_congr {s : Finset ι} {t : ι → Set α} : μ.restrict (⋃ i ∈ s, t i) = ν.restrict (⋃ i ∈ s, t i) ↔ ∀ i ∈ s, μ.restrict (t i) = ν.restrict (t i) := by classical induction' s using Finset.induction_on with i s _ hs; · simp simp only [forall_eq_or_imp, iUnion_iUnion_eq_or_left, Finset.mem_insert] rw [restrict_union_congr, ← hs] theorem restrict_iUnion_congr [Countable ι] {s : ι → Set α} : μ.restrict (⋃ i, s i) = ν.restrict (⋃ i, s i) ↔ ∀ i, μ.restrict (s i) = ν.restrict (s i) := by refine ⟨fun h i => restrict_congr_mono (subset_iUnion _ _) h, fun h => ?_⟩ ext1 t ht have D : Directed (· ⊆ ·) fun t : Finset ι => ⋃ i ∈ t, s i := Monotone.directed_le fun t₁ t₂ ht => biUnion_subset_biUnion_left ht rw [iUnion_eq_iUnion_finset] simp only [restrict_iUnion_apply_eq_iSup D ht, restrict_finset_biUnion_congr.2 fun i _ => h i] theorem restrict_biUnion_congr {s : Set ι} {t : ι → Set α} (hc : s.Countable) : μ.restrict (⋃ i ∈ s, t i) = ν.restrict (⋃ i ∈ s, t i) ↔ ∀ i ∈ s, μ.restrict (t i) = ν.restrict (t i) := by haveI := hc.toEncodable simp only [biUnion_eq_iUnion, SetCoe.forall', restrict_iUnion_congr] theorem restrict_sUnion_congr {S : Set (Set α)} (hc : S.Countable) : μ.restrict (⋃₀ S) = ν.restrict (⋃₀ S) ↔ ∀ s ∈ S, μ.restrict s = ν.restrict s := by rw [sUnion_eq_biUnion, restrict_biUnion_congr hc] /-- This lemma shows that `Inf` and `restrict` commute for measures. -/ theorem restrict_sInf_eq_sInf_restrict {m0 : MeasurableSpace α} {m : Set (Measure α)} (hm : m.Nonempty) (ht : MeasurableSet t) : (sInf m).restrict t = sInf ((fun μ : Measure α => μ.restrict t) '' m) := by ext1 s hs simp_rw [sInf_apply hs, restrict_apply hs, sInf_apply (MeasurableSet.inter hs ht), Set.image_image, restrict_toOuterMeasure_eq_toOuterMeasure_restrict ht, ← Set.image_image _ toOuterMeasure, ← OuterMeasure.restrict_sInf_eq_sInf_restrict _ (hm.image _), OuterMeasure.restrict_apply] theorem exists_mem_of_measure_ne_zero_of_ae (hs : μ s ≠ 0) {p : α → Prop} (hp : ∀ᵐ x ∂μ.restrict s, p x) : ∃ x, x ∈ s ∧ p x := by rw [← μ.restrict_apply_self, ← frequently_ae_mem_iff] at hs exact (hs.and_eventually hp).exists /-- If a quasi measure preserving map `f` maps a set `s` to a set `t`, then it is quasi measure preserving with respect to the restrictions of the measures. -/ theorem QuasiMeasurePreserving.restrict {ν : Measure β} {f : α → β} (hf : QuasiMeasurePreserving f μ ν) {t : Set β} (hmaps : MapsTo f s t) : QuasiMeasurePreserving f (μ.restrict s) (ν.restrict t) where measurable := hf.measurable absolutelyContinuous := by refine AbsolutelyContinuous.mk fun u hum ↦ ?_ suffices ν (u ∩ t) = 0 → μ (f ⁻¹' u ∩ s) = 0 by simpa [hum, hf.measurable, hf.measurable hum] refine fun hu ↦ measure_mono_null ?_ (hf.preimage_null hu) rw [preimage_inter] gcongr assumption /-! ### Extensionality results -/ /-- Two measures are equal if they have equal restrictions on a spanning collection of sets (formulated using `Union`). -/ theorem ext_iff_of_iUnion_eq_univ [Countable ι] {s : ι → Set α} (hs : ⋃ i, s i = univ) : μ = ν ↔ ∀ i, μ.restrict (s i) = ν.restrict (s i) := by rw [← restrict_iUnion_congr, hs, restrict_univ, restrict_univ] alias ⟨_, ext_of_iUnion_eq_univ⟩ := ext_iff_of_iUnion_eq_univ /-- Two measures are equal if they have equal restrictions on a spanning collection of sets (formulated using `biUnion`). -/ theorem ext_iff_of_biUnion_eq_univ {S : Set ι} {s : ι → Set α} (hc : S.Countable) (hs : ⋃ i ∈ S, s i = univ) : μ = ν ↔ ∀ i ∈ S, μ.restrict (s i) = ν.restrict (s i) := by rw [← restrict_biUnion_congr hc, hs, restrict_univ, restrict_univ] alias ⟨_, ext_of_biUnion_eq_univ⟩ := ext_iff_of_biUnion_eq_univ /-- Two measures are equal if they have equal restrictions on a spanning collection of sets (formulated using `sUnion`). -/ theorem ext_iff_of_sUnion_eq_univ {S : Set (Set α)} (hc : S.Countable) (hs : ⋃₀ S = univ) : μ = ν ↔ ∀ s ∈ S, μ.restrict s = ν.restrict s := ext_iff_of_biUnion_eq_univ hc <\| by rwa [← sUnion_eq_biUnion] alias ⟨_, ext_of_sUnion_eq_univ⟩ := ext_iff_of_sUnion_eq_univ theorem ext_of_generateFrom_of_cover {S T : Set (Set α)} (h_gen : ‹_› = generateFrom S) (hc : T.Countable) (h_inter : IsPiSystem S) (hU : ⋃₀ T = univ) (htop : ∀ t ∈ T, μ t ≠ ∞) (ST_eq : ∀ t ∈ T, ∀ s ∈ S, μ (s ∩ t) = ν (s ∩ t)) (T_eq : ∀ t ∈ T, μ t = ν t) : μ = ν := by refine ext_of_sUnion_eq_univ hc hU fun t ht => ?_ ext1 u hu simp only [restrict_apply hu] induction u, hu using induction_on_inter h_gen h_inter with \| empty => simp only [Set.empty_inter, measure_empty] \| basic u hu => exact ST_eq _ ht _ hu \| compl u hu ihu => have := T_eq t ht rw [Set.inter_comm] at ihu ⊢ rwa [← measure_inter_add_diff t hu, ← measure_inter_add_diff t hu, ← ihu, ENNReal.add_right_inj] at this exact ne_top_of_le_ne_top (htop t ht) (measure_mono Set.inter_subset_left) \| iUnion f hfd hfm ihf => simp only [← restrict_apply (hfm _), ← restrict_apply (MeasurableSet.iUnion hfm)] at ihf ⊢ simp only [measure_iUnion hfd hfm, ihf] /-- Two measures are equal if they are equal on the π-system generating the σ-algebra, and they are both finite on an increasing spanning sequence of sets in the π-system. This lemma is formulated using `sUnion`. -/ theorem ext_of_generateFrom_of_cover_subset {S T : Set (Set α)} (h_gen : ‹_› = generateFrom S) (h_inter : IsPiSystem S) (h_sub : T ⊆ S) (hc : T.Countable) (hU : ⋃₀ T = univ) (htop : ∀ s ∈ T, μ s ≠ ∞) (h_eq : ∀ s ∈ S, μ s = ν s) : μ = ν := by refine ext_of_generateFrom_of_cover h_gen hc h_inter hU htop ?_ fun t ht => h_eq t (h_sub ht) intro t ht s hs; rcases (s ∩ t).eq_empty_or_nonempty with H \| H · simp only [H, measure_empty] · exact h_eq _ (h_inter _ hs _ (h_sub ht) H) /-- Two measures are equal if they are equal on the π-system generating the σ-algebra, and they are both finite on an increasing spanning sequence of sets in the π-system. This lemma is formulated using `iUnion`. `FiniteSpanningSetsIn.ext` is a reformulation of this lemma. -/ theorem ext_of_generateFrom_of_iUnion (C : Set (Set α)) (B : ℕ → Set α) (hA : ‹_› = generateFrom C) (hC : IsPiSystem C) (h1B : ⋃ i, B i = univ) (h2B : ∀ i, B i ∈ C) (hμB : ∀ i, μ (B i) ≠ ∞) (h_eq : ∀ s ∈ C, μ s = ν s) : μ = ν := by refine ext_of_generateFrom_of_cover_subset hA hC ?_ (countable_range B) h1B ?_ h_eq · rintro _ ⟨i, rfl⟩ apply h2B · rintro _ ⟨i, rfl⟩ apply hμB @[simp] theorem restrict_sum (μ : ι → Measure α) {s : Set α} (hs : MeasurableSet s) : (sum μ).restrict s = sum fun i => (μ i).restrict s := ext fun t ht => by simp only [sum_apply, restrict_apply, ht, ht.inter hs] @[simp] theorem restrict_sum_of_countable [Countable ι] (μ : ι → Measure α) (s : Set α) : (sum μ).restrict s = sum fun i => (μ i).restrict s := by ext t ht simp_rw [sum_apply _ ht, restrict_apply ht, sum_apply_of_countable] lemma AbsolutelyContinuous.restrict (h : μ ≪ ν) (s : Set α) : μ.restrict s ≪ ν.restrict s := by refine Measure.AbsolutelyContinuous.mk (fun t ht htν ↦ ?_) rw [restrict_apply ht] at htν ⊢ exact h htν theorem restrict_iUnion_ae [Countable ι] {s : ι → Set α} (hd : Pairwise (AEDisjoint μ on s)) (hm : ∀ i, NullMeasurableSet (s i) μ) : μ.restrict (⋃ i, s i) = sum fun i => μ.restrict (s i) := ext fun t ht => by simp only [sum_apply _ ht, restrict_iUnion_apply_ae hd hm ht] theorem restrict_iUnion [Countable ι] {s : ι → Set α} (hd : Pairwise (Disjoint on s)) (hm : ∀ i, MeasurableSet (s i)) : μ.restrict (⋃ i, s i) = sum fun i => μ.restrict (s i) := restrict_iUnion_ae hd.aedisjoint fun i => (hm i).nullMeasurableSet theorem restrict_iUnion_le [Countable ι] {s : ι → Set α} : μ.restrict (⋃ i, s i) ≤ sum fun i => μ.restrict (s i) := le_iff.2 fun t ht ↦ by simpa [ht, inter_iUnion] using measure_iUnion_le (t ∩ s ·) end Measure @[simp] theorem ae_restrict_iUnion_eq [Countable ι] (s : ι → Set α) : ae (μ.restrict (⋃ i, s i)) = ⨆ i, ae (μ.restrict (s i)) := le_antisymm ((ae_sum_eq fun i => μ.restrict (s i)) ▸ ae_mono restrict_iUnion_le) <\| iSup_le fun i => ae_mono <\| restrict_mono (subset_iUnion s i) le_rfl @[simp] theorem ae_restrict_union_eq (s t : Set α) : ae (μ.restrict (s ∪ t)) = ae (μ.restrict s) ⊔ ae (μ.restrict t) := by simp [union_eq_iUnion, iSup_bool_eq] theorem ae_restrict_biUnion_eq (s : ι → Set α) {t : Set ι} (ht : t.Countable) : ae (μ.restrict (⋃ i ∈ t, s i)) = ⨆ i ∈ t, ae (μ.restrict (s i)) := by haveI := ht.to_subtype rw [biUnion_eq_iUnion, ae_restrict_iUnion_eq, ← iSup_subtype''] theorem ae_restrict_biUnion_finset_eq (s : ι → Set α) (t : Finset ι) : ae (μ.restrict (⋃ i ∈ t, s i)) = ⨆ i ∈ t, ae (μ.restrict (s i)) := ae_restrict_biUnion_eq s t.countable_toSet theorem ae_restrict_iUnion_iff [Countable ι] (s : ι → Set α) (p : α → Prop) : (∀ᵐ x ∂μ.restrict (⋃ i, s i), p x) ↔ ∀ i, ∀ᵐ x ∂μ.restrict (s i), p x := by simp theorem ae_restrict_union_iff (s t : Set α) (p : α → Prop) : (∀ᵐ x ∂μ.restrict (s ∪ t), p x) ↔ (∀ᵐ x ∂μ.restrict s, p x) ∧ ∀ᵐ x ∂μ.restrict t, p x := by simp theorem ae_restrict_biUnion_iff (s : ι → Set α) {t : Set ι} (ht : t.Countable) (p : α → Prop) : (∀ᵐ x ∂μ.restrict (⋃ i ∈ t, s i), p x) ↔ ∀ i ∈ t, ∀ᵐ x ∂μ.restrict (s i), p x := by simp_rw [Filter.Eventually, ae_restrict_biUnion_eq s ht, mem_iSup] @[simp] theorem ae_restrict_biUnion_finset_iff (s : ι → Set α) (t : Finset ι) (p : α → Prop) : (∀ᵐ x ∂μ.restrict (⋃ i ∈ t, s i), p x) ↔ ∀ i ∈ t, ∀ᵐ x ∂μ.restrict (s i), p x := by simp_rw [Filter.Eventually, ae_restrict_biUnion_finset_eq s, mem_iSup] theorem ae_eq_restrict_iUnion_iff [Countable ι] (s : ι → Set α) (f g : α → δ) : f =ᵐ[μ.restrict (⋃ i, s i)] g ↔ ∀ i, f =ᵐ[μ.restrict (s i)] g := by simp_rw [EventuallyEq, ae_restrict_iUnion_eq, eventually_iSup] theorem ae_eq_restrict_biUnion_iff (s : ι → Set α) {t : Set ι} (ht : t.Countable) (f g : α → δ) : f =ᵐ[μ.restrict (⋃ i ∈ t, s i)] g ↔ ∀ i ∈ t, f =ᵐ[μ.restrict (s i)] g := by simp_rw [ae_restrict_biUnion_eq s ht, EventuallyEq, eventually_iSup] theorem ae_eq_restrict_biUnion_finset_iff (s : ι → Set α) (t : Finset ι) (f g : α → δ) : f =ᵐ[μ.restrict (⋃ i ∈ t, s i)] g ↔ ∀ i ∈ t, f =ᵐ[μ.restrict (s i)] g := ae_eq_restrict_biUnion_iff s t.countable_toSet f g open scoped Interval in theorem ae_restrict_uIoc_eq [LinearOrder α] (a b : α) : ae (μ.restrict (Ι a b)) = ae (μ.restrict (Ioc a b)) ⊔ ae (μ.restrict (Ioc b a)) := by simp only [uIoc_eq_union, ae_restrict_union_eq] open scoped Interval in /-- See also `MeasureTheory.ae_uIoc_iff`. -/ theorem ae_restrict_uIoc_iff [LinearOrder α] {a b : α} {P : α → Prop} : (∀ᵐ x ∂μ.restrict (Ι a b), P x) ↔ (∀ᵐ x ∂μ.restrict (Ioc a b), P x) ∧ ∀ᵐ x ∂μ.restrict (Ioc b a), P x := by rw [ae_restrict_uIoc_eq, eventually_sup] theorem ae_restrict_iff₀ {p : α → Prop} (hp : NullMeasurableSet { x \| p x } (μ.restrict s)) : (∀ᵐ x ∂μ.restrict s, p x) ↔ ∀ᵐ x ∂μ, x ∈ s → p x := by simp only [ae_iff, ← compl_setOf, Measure.restrict_apply₀ hp.compl] rw [iff_iff_eq]; congr with x; simp [and_comm] theorem ae_restrict_iff {p : α → Prop} (hp : MeasurableSet { x \| p x }) : (∀ᵐ x ∂μ.restrict s, p x) ↔ ∀ᵐ x ∂μ, x ∈ s → p x := ae_restrict_iff₀ hp.nullMeasurableSet theorem ae_imp_of_ae_restrict {s : Set α} {p : α → Prop} (h : ∀ᵐ x ∂μ.restrict s, p x) : ∀ᵐ x ∂μ, x ∈ s → p x := by simp only [ae_iff] at h ⊢ simpa [setOf_and, inter_comm] using measure_inter_eq_zero_of_restrict h theorem ae_restrict_iff'₀ {p : α → Prop} (hs : NullMeasurableSet s μ) : (∀ᵐ x ∂μ.restrict s, p x) ↔ ∀ᵐ x ∂μ, x ∈ s → p x := by simp only [ae_iff, ← compl_setOf, restrict_apply₀' hs] rw [iff_iff_eq]; congr with x; simp [and_comm] theorem ae_restrict_iff' {p : α → Prop} (hs : MeasurableSet s) : (∀ᵐ x ∂μ.restrict s, p x) ↔ ∀ᵐ x ∂μ, x ∈ s → p x := ae_restrict_iff'₀ hs.nullMeasurableSet theorem _root_.Filter.EventuallyEq.restrict {f g : α → δ} {s : Set α} (hfg : f =ᵐ[μ] g) : f =ᵐ[μ.restrict s] g := by -- note that we cannot use `ae_restrict_iff` since we do not require measurability refine hfg.filter_mono ?_ rw [Measure.ae_le_iff_absolutelyContinuous] exact Measure.absolutelyContinuous_of_le Measure.restrict_le_self theorem ae_restrict_mem₀ (hs : NullMeasurableSet s μ) : ∀ᵐ x ∂μ.restrict s, x ∈ s := (ae_restrict_iff'₀ hs).2 (Filter.Eventually.of_forall fun _ => id) theorem ae_restrict_mem (hs : MeasurableSet s) : ∀ᵐ x ∂μ.restrict s, x ∈ s := ae_restrict_mem₀ hs.nullMeasurableSet theorem ae_restrict_of_forall_mem {μ : Measure α} {s : Set α} (hs : MeasurableSet s) {p : α → Prop} (h : ∀ x ∈ s, p x) : ∀ᵐ (x : α) ∂μ.restrict s, p x := (ae_restrict_mem hs).mono h theorem ae_restrict_of_ae {s : Set α} {p : α → Prop} (h : ∀ᵐ x ∂μ, p x) : ∀ᵐ x ∂μ.restrict s, p x := h.filter_mono (ae_mono Measure.restrict_le_self) theorem ae_restrict_of_ae_restrict_of_subset {s t : Set α} {p : α → Prop} (hst : s ⊆ t) (h : ∀ᵐ x ∂μ.restrict t, p x) : ∀ᵐ x ∂μ.restrict s, p x := h.filter_mono (ae_mono <\| Measure.restrict_mono hst (le_refl μ)) theorem ae_of_ae_restrict_of_ae_restrict_compl (t : Set α) {p : α → Prop} (ht : ∀ᵐ x ∂μ.restrict t, p x) (htc : ∀ᵐ x ∂μ.restrict tᶜ, p x) : ∀ᵐ x ∂μ, p x := nonpos_iff_eq_zero.1 <\| calc μ { x \| ¬p x } ≤ μ ({ x \| ¬p x } ∩ t) + μ ({ x \| ¬p x } ∩ tᶜ) := measure_le_inter_add_diff _ _ _ _ ≤ μ.restrict t { x \| ¬p x } + μ.restrict tᶜ { x \| ¬p x } := add_le_add (le_restrict_apply _ _) (le_restrict_apply _ _) _ = 0 := by rw [ae_iff.1 ht, ae_iff.1 htc, zero_add] theorem mem_map_restrict_ae_iff {β} {s : Set α} {t : Set β} {f : α → β} (hs : MeasurableSet s) : t ∈ Filter.map f (ae (μ.restrict s)) ↔ μ ((f ⁻¹' t)ᶜ ∩ s) = 0 := by rw [mem_map, mem_ae_iff, Measure.restrict_apply' hs] theorem ae_add_measure_iff {p : α → Prop} {ν} : (∀ᵐ x ∂μ + ν, p x) ↔ (∀ᵐ x ∂μ, p x) ∧ ∀ᵐ x ∂ν, p x := add_eq_zero theorem ae_eq_comp' {ν : Measure β} {f : α → β} {g g' : β → δ} (hf : AEMeasurable f μ) (h : g =ᵐ[ν] g') (h2 : μ.map f ≪ ν) : g ∘ f =ᵐ[μ] g' ∘ f := (tendsto_ae_map hf).mono_right h2.ae_le h theorem Measure.QuasiMeasurePreserving.ae_eq_comp {ν : Measure β} {f : α → β} {g g' : β → δ} (hf : QuasiMeasurePreserving f μ ν) (h : g =ᵐ[ν] g') : g ∘ f =ᵐ[μ] g' ∘ f := ae_eq_comp' hf.aemeasurable h hf.absolutelyContinuous theorem ae_eq_comp {f : α → β} {g g' : β → δ} (hf : AEMeasurable f μ) (h : g =ᵐ[μ.map f] g') : g ∘ f =ᵐ[μ] g' ∘ f := ae_eq_comp' hf h AbsolutelyContinuous.rfl @[to_additive] theorem div_ae_eq_one {β} [Group β] (f g : α → β) : f / g =ᵐ[μ] 1 ↔ f =ᵐ[μ] g := by refine ⟨fun h ↦ h.mono fun x hx ↦ ?_, fun h ↦ h.mono fun x hx ↦ ?_⟩ · rwa [Pi.div_apply, Pi.one_apply, div_eq_one] at hx · rwa [Pi.div_apply, Pi.one_apply, div_eq_one] @[to_additive sub_nonneg_ae] lemma one_le_div_ae {β : Type} [Group β] [LE β] [MulRightMono β] (f g : α → β) : 1 ≤ᵐ[μ] g / f ↔ f ≤ᵐ[μ] g := by refine ⟨fun h ↦ h.mono fun a ha ↦ ?_, fun h ↦ h.mono fun a ha ↦ ?_⟩ · rwa [Pi.one_apply, Pi.div_apply, one_le_div'] at ha · rwa [Pi.one_apply, Pi.div_apply, one_le_div'] theorem le_ae_restrict : ae μ ⊓ 𝓟 s ≤ ae (μ.restrict s) := fun _s hs => eventually_inf_principal.2 (ae_imp_of_ae_restrict hs) @[simp] theorem ae_restrict_eq (hs : MeasurableSet s) : ae (μ.restrict s) = ae μ ⊓ 𝓟 s := by ext t simp only [mem_inf_principal, mem_ae_iff, restrict_apply_eq_zero' hs, compl_setOf, Classical.not_imp, fun a => and_comm (a := a ∈ s) (b := ¬a ∈ t)] rfl lemma ae_restrict_le : ae (μ.restrict s) ≤ ae μ := ae_mono restrict_le_self theorem ae_restrict_eq_bot {s} : ae (μ.restrict s) = ⊥ ↔ μ s = 0 := ae_eq_bot.trans restrict_eq_zero theorem ae_restrict_neBot {s} : (ae <\| μ.restrict s).NeBot ↔ μ s ≠ 0 := neBot_iff.trans ae_restrict_eq_bot.not theorem self_mem_ae_restrict {s} (hs : MeasurableSet s) : s ∈ ae (μ.restrict s) := by simp only [ae_restrict_eq hs, exists_prop, mem_principal, mem_inf_iff] exact ⟨_, univ_mem, s, Subset.rfl, (univ_inter s).symm⟩	/-- If two measurable sets are ae_eq then any proposition that is almost everywhere true on one is almost everywhere true on the other -/ theorem ae_restrict_of_ae_eq_of_ae_restrict {s t} (hst : s =ᵐ[μ] t) {p : α → Prop} : (∀ᵐ x ∂μ.restrict s, p x) → ∀ᵐ x ∂μ.restrict t, p x := by simp [Measure.restrict_congr_set hst] /-- If two measurable sets are ae_eq then any proposition that is almost everywhere true on one is almost everywhere true on the other -/ theorem ae_restrict_congr_set {s t} (hst : s =ᵐ[μ] t) {p : α → Prop} :	Mathlib/MeasureTheory/Measure/Restrict.lean	666	674
/- Copyright (c) 2021 Sébastien Gouëzel. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Sébastien Gouëzel, Floris van Doorn, Yury Kudryashov -/ import Mathlib.MeasureTheory.Constructions.BorelSpace.Order import Mathlib.MeasureTheory.Group.MeasurableEquiv import Mathlib.Topology.MetricSpace.HausdorffDistance /-! # Regular measures A measure is `OuterRegular` if the measure of any measurable set `A` is the infimum of `μ U` over all open sets `U` containing `A`. A measure is `WeaklyRegular` if it satisfies the following properties: * it is outer regular; * it is inner regular for open sets with respect to closed sets: the measure of any open set `U` is the supremum of `μ F` over all closed sets `F` contained in `U`. A measure is `Regular` if it satisfies the following properties: * it is finite on compact sets; * it is outer regular; * it is inner regular for open sets with respect to compacts closed sets: the measure of any open set `U` is the supremum of `μ K` over all compact sets `K` contained in `U`. A measure is `InnerRegular` if it is inner regular for measurable sets with respect to compact sets: the measure of any measurable set `s` is the supremum of `μ K` over all compact sets contained in `s`. A measure is `InnerRegularCompactLTTop` if it is inner regular for measurable sets of finite measure with respect to compact sets: the measure of any measurable set `s` is the supremum of `μ K` over all compact sets contained in `s`. There is a reason for this zoo of regularity classes: * A finite measure on a metric space is always weakly regular. Therefore, in probability theory, weakly regular measures play a prominent role. * In locally compact topological spaces, there are two competing notions of Radon measures: the ones that are regular, and the ones that are inner regular. For any of these two notions, there is a Riesz representation theorem, and an existence and uniqueness statement for the Haar measure in locally compact topological groups. The two notions coincide in sigma-compact spaces, but they differ in general, so it is worth having the two of them. * Both notions of Haar measure satisfy the weaker notion `InnerRegularCompactLTTop`, so it is worth trying to express theorems using this weaker notion whenever possible, to make sure that it applies to both Haar measures simultaneously. While traditional textbooks on measure theory on locally compact spaces emphasize regular measures, more recent textbooks emphasize that inner regular Haar measures are better behaved than regular Haar measures, so we will develop both notions. The five conditions above are registered as typeclasses for a measure `μ`, and implications between them are recorded as instances. For example, in a Hausdorff topological space, regularity implies weak regularity. Also, regularity or inner regularity both imply `InnerRegularCompactLTTop`. In a regular locally compact finite measure space, then regularity, inner regularity and `InnerRegularCompactLTTop` are all equivalent. In order to avoid code duplication, we also define a measure `μ` to be `InnerRegularWRT` for sets satisfying a predicate `q` with respect to sets satisfying a predicate `p` if for any set `U ∈ {U \| q U}` and a number `r < μ U` there exists `F ⊆ U` such that `p F` and `r < μ F`. There are two main nontrivial results in the development below: * `InnerRegularWRT.measurableSet_of_isOpen` shows that, for an outer regular measure, inner regularity for open sets with respect to compact sets or closed sets implies inner regularity for all measurable sets of finite measure (with respect to compact sets or closed sets respectively). * `InnerRegularWRT.weaklyRegular_of_finite` shows that a finite measure which is inner regular for open sets with respect to closed sets (for instance a finite measure on a metric space) is weakly regular. All other results are deduced from these ones. Here is an example showing how regularity and inner regularity may differ even on locally compact spaces. Consider the group `ℝ × ℝ` where the first factor has the discrete topology and the second one the usual topology. It is a locally compact Hausdorff topological group, with Haar measure equal to Lebesgue measure on each vertical fiber. Let us consider the regular version of Haar measure. Then the set `ℝ × {0}` has infinite measure (by outer regularity), but any compact set it contains has zero measure (as it is finite). In fact, this set only contains subset with measure zero or infinity. The inner regular version of Haar measure, on the other hand, gives zero mass to the set `ℝ × {0}`. Another interesting example is the sum of the Dirac masses at rational points in the real line. It is a σ-finite measure on a locally compact metric space, but it is not outer regular: for outer regularity, one needs additional locally finite assumptions. On the other hand, it is inner regular. Several authors require both regularity and inner regularity for their measures. We have opted for the more fine grained definitions above as they apply more generally. ## Main definitions * `MeasureTheory.Measure.OuterRegular μ`: a typeclass registering that a measure `μ` on a topological space is outer regular. * `MeasureTheory.Measure.Regular μ`: a typeclass registering that a measure `μ` on a topological space is regular. * `MeasureTheory.Measure.WeaklyRegular μ`: a typeclass registering that a measure `μ` on a topological space is weakly regular. * `MeasureTheory.Measure.InnerRegularWRT μ p q`: a non-typeclass predicate saying that a measure `μ` is inner regular for sets satisfying `q` with respect to sets satisfying `p`. * `MeasureTheory.Measure.InnerRegular μ`: a typeclass registering that a measure `μ` on a topological space is inner regular for measurable sets with respect to compact sets. * `MeasureTheory.Measure.InnerRegularCompactLTTop μ`: a typeclass registering that a measure `μ` on a topological space is inner regular for measurable sets of finite measure with respect to compact sets. ## Main results ### Outer regular measures * `Set.measure_eq_iInf_isOpen` asserts that, when `μ` is outer regular, the measure of a set is the infimum of the measure of open sets containing it. * `Set.exists_isOpen_lt_of_lt` asserts that, when `μ` is outer regular, for every set `s` and `r > μ s` there exists an open superset `U ⊇ s` of measure less than `r`. * push forward of an outer regular measure is outer regular, and scalar multiplication of a regular measure by a finite number is outer regular. ### Weakly regular measures * `IsOpen.measure_eq_iSup_isClosed` asserts that the measure of an open set is the supremum of the measure of closed sets it contains. * `IsOpen.exists_lt_isClosed`: for an open set `U` and `r < μ U`, there exists a closed `F ⊆ U` of measure greater than `r`; * `MeasurableSet.measure_eq_iSup_isClosed_of_ne_top` asserts that the measure of a measurable set of finite measure is the supremum of the measure of closed sets it contains. * `MeasurableSet.exists_lt_isClosed_of_ne_top` and `MeasurableSet.exists_isClosed_lt_add`: a measurable set of finite measure can be approximated by a closed subset (stated as `r < μ F` and `μ s < μ F + ε`, respectively). * `MeasureTheory.Measure.WeaklyRegular.of_pseudoMetrizableSpace_of_isFiniteMeasure` is an instance registering that a finite measure on a metric space is weakly regular (in fact, a pseudo metrizable space is enough); * `MeasureTheory.Measure.WeaklyRegular.of_pseudoMetrizableSpace_secondCountable_of_locallyFinite` is an instance registering that a locally finite measure on a second countable metric space (or even a pseudo metrizable space) is weakly regular. ### Regular measures * `IsOpen.measure_eq_iSup_isCompact` asserts that the measure of an open set is the supremum of the measure of compact sets it contains. * `IsOpen.exists_lt_isCompact`: for an open set `U` and `r < μ U`, there exists a compact `K ⊆ U` of measure greater than `r`; * `MeasureTheory.Measure.Regular.of_sigmaCompactSpace_of_isLocallyFiniteMeasure` is an instance registering that a locally finite measure on a `σ`-compact metric space is regular (in fact, an emetric space is enough). ### Inner regular measures * `MeasurableSet.measure_eq_iSup_isCompact` asserts that the measure of a measurable set is the supremum of the measure of compact sets it contains. * `MeasurableSet.exists_lt_isCompact`: for a measurable set `s` and `r < μ s`, there exists a compact `K ⊆ s` of measure greater than `r`; ### Inner regular measures for finite measure sets with respect to compact sets * `MeasurableSet.measure_eq_iSup_isCompact_of_ne_top` asserts that the measure of a measurable set of finite measure is the supremum of the measure of compact sets it contains. * `MeasurableSet.exists_lt_isCompact_of_ne_top` and `MeasurableSet.exists_isCompact_lt_add`: a measurable set of finite measure can be approximated by a compact subset (stated as `r < μ K` and `μ s < μ K + ε`, respectively). ## Implementation notes The main nontrivial statement is `MeasureTheory.Measure.InnerRegular.weaklyRegular_of_finite`, expressing that in a finite measure space, if every open set can be approximated from inside by closed sets, then the measure is in fact weakly regular. To prove that we show that any measurable set can be approximated from inside by closed sets and from outside by open sets. This statement is proved by measurable induction, starting from open sets and checking that it is stable by taking complements (this is the point of this condition, being symmetrical between inside and outside) and countable disjoint unions. Once this statement is proved, one deduces results for `σ`-finite measures from this statement, by restricting them to finite measure sets (and proving that this restriction is weakly regular, using again the same statement). For non-Hausdorff spaces, one may argue whether the right condition for inner regularity is with respect to compact sets, or to compact closed sets. For instance, [Fremlin, Measure Theory (volume 4, 411J)][fremlin_vol4] considers measures which are inner regular with respect to compact closed sets (and calls them tight). However, since most of the literature uses mere compact sets, we have chosen to follow this convention. It doesn't make a difference in Hausdorff spaces, of course. In locally compact topological groups, the two conditions coincide, since if a compact set `k` is contained in a measurable set `u`, then the closure of `k` is a compact closed set still contained in `u`, see `IsCompact.closure_subset_of_measurableSet_of_group`. ## References [Halmos, Measure Theory, §52][halmos1950measure]. Note that Halmos uses an unusual definition of Borel sets (for him, they are elements of the `σ`-algebra generated by compact sets!), so his proofs or statements do not apply directly. [Billingsley, Convergence of Probability Measures][billingsley1999] [Bogachev, Measure Theory, volume 2, Theorem 7.11.1][bogachev2007] -/ open Set Filter ENNReal NNReal TopologicalSpace open scoped symmDiff Topology namespace MeasureTheory namespace Measure /-- We say that a measure `μ` is inner regular with respect to predicates `p q : Set α → Prop`, if for every `U` such that `q U` and `r < μ U`, there exists a subset `K ⊆ U` satisfying `p K` of measure greater than `r`. This definition is used to prove some facts about regular and weakly regular measures without repeating the proofs. -/ def InnerRegularWRT {α} {_ : MeasurableSpace α} (μ : Measure α) (p q : Set α → Prop) := ∀ ⦃U⦄, q U → ∀ r < μ U, ∃ K, K ⊆ U ∧ p K ∧ r < μ K namespace InnerRegularWRT variable {α : Type} {m : MeasurableSpace α} {μ : Measure α} {p q : Set α → Prop} {U : Set α} {ε : ℝ≥0∞} theorem measure_eq_iSup (H : InnerRegularWRT μ p q) (hU : q U) : μ U = ⨆ (K) (_ : K ⊆ U) (_ : p K), μ K := by refine le_antisymm (le_of_forall_lt fun r hr => ?_) (iSup₂_le fun K hK => iSup_le fun _ => μ.mono hK) simpa only [lt_iSup_iff, exists_prop] using H hU r hr theorem exists_subset_lt_add (H : InnerRegularWRT μ p q) (h0 : p ∅) (hU : q U) (hμU : μ U ≠ ∞) (hε : ε ≠ 0) : ∃ K, K ⊆ U ∧ p K ∧ μ U < μ K + ε := by rcases eq_or_ne (μ U) 0 with h₀ \| h₀ · refine ⟨∅, empty_subset _, h0, ?_⟩ rwa [measure_empty, h₀, zero_add, pos_iff_ne_zero] · rcases H hU _ (ENNReal.sub_lt_self hμU h₀ hε) with ⟨K, hKU, hKc, hrK⟩ exact ⟨K, hKU, hKc, ENNReal.lt_add_of_sub_lt_right (Or.inl hμU) hrK⟩ protected theorem map {α β} [MeasurableSpace α] [MeasurableSpace β] {μ : Measure α} {pa qa : Set α → Prop} (H : InnerRegularWRT μ pa qa) {f : α → β} (hf : AEMeasurable f μ) {pb qb : Set β → Prop} (hAB : ∀ U, qb U → qa (f ⁻¹' U)) (hAB' : ∀ K, pa K → pb (f '' K)) (hB₂ : ∀ U, qb U → MeasurableSet U) : InnerRegularWRT (map f μ) pb qb := by intro U hU r hr rw [map_apply_of_aemeasurable hf (hB₂ _ hU)] at hr rcases H (hAB U hU) r hr with ⟨K, hKU, hKc, hK⟩ refine ⟨f '' K, image_subset_iff.2 hKU, hAB' _ hKc, ?_⟩ exact hK.trans_le (le_map_apply_image hf _) theorem map' {α β} [MeasurableSpace α] [MeasurableSpace β] {μ : Measure α} {pa qa : Set α → Prop} (H : InnerRegularWRT μ pa qa) (f : α ≃ᵐ β) {pb qb : Set β → Prop} (hAB : ∀ U, qb U → qa (f ⁻¹' U)) (hAB' : ∀ K, pa K → pb (f '' K)) : InnerRegularWRT (map f μ) pb qb := by intro U hU r hr rw [f.map_apply U] at hr rcases H (hAB U hU) r hr with ⟨K, hKU, hKc, hK⟩ refine ⟨f '' K, image_subset_iff.2 hKU, hAB' _ hKc, ?_⟩ rwa [f.map_apply, f.preimage_image] theorem smul (H : InnerRegularWRT μ p q) (c : ℝ≥0∞) : InnerRegularWRT (c • μ) p q := by intro U hU r hr rw [smul_apply, H.measure_eq_iSup hU, smul_eq_mul] at hr simpa only [ENNReal.mul_iSup, lt_iSup_iff, exists_prop] using hr theorem trans {q' : Set α → Prop} (H : InnerRegularWRT μ p q) (H' : InnerRegularWRT μ q q') : InnerRegularWRT μ p q' := by intro U hU r hr rcases H' hU r hr with ⟨F, hFU, hqF, hF⟩; rcases H hqF _ hF with ⟨K, hKF, hpK, hrK⟩ exact ⟨K, hKF.trans hFU, hpK, hrK⟩ theorem rfl {p : Set α → Prop} : InnerRegularWRT μ p p := fun U hU _r hr ↦ ⟨U, Subset.rfl, hU, hr⟩ theorem of_imp (h : ∀ s, q s → p s) : InnerRegularWRT μ p q := fun U hU _ hr ↦ ⟨U, Subset.rfl, h U hU, hr⟩ theorem mono {p' q' : Set α → Prop} (H : InnerRegularWRT μ p q) (h : ∀ s, q' s → q s) (h' : ∀ s, p s → p' s) : InnerRegularWRT μ p' q' := of_imp h' \|>.trans H \|>.trans (of_imp h) end InnerRegularWRT variable {α β : Type} [MeasurableSpace α] {μ : Measure α} section Classes variable [TopologicalSpace α] /-- A measure `μ` is outer regular if `μ(A) = inf {μ(U) \| A ⊆ U open}` for a measurable set `A`. This definition implies the same equality for any (not necessarily measurable) set, see `Set.measure_eq_iInf_isOpen`. -/ class OuterRegular (μ : Measure α) : Prop where protected outerRegular : ∀ ⦃A : Set α⦄, MeasurableSet A → ∀ r > μ A, ∃ U, U ⊇ A ∧ IsOpen U ∧ μ U < r /-- A measure `μ` is regular if - it is finite on all compact sets; - it is outer regular: `μ(A) = inf {μ(U) \| A ⊆ U open}` for `A` measurable; - it is inner regular for open sets, using compact sets: `μ(U) = sup {μ(K) \| K ⊆ U compact}` for `U` open. -/ class Regular (μ : Measure α) : Prop extends IsFiniteMeasureOnCompacts μ, OuterRegular μ where innerRegular : InnerRegularWRT μ IsCompact IsOpen /-- A measure `μ` is weakly regular if - it is outer regular: `μ(A) = inf {μ(U) \| A ⊆ U open}` for `A` measurable; - it is inner regular for open sets, using closed sets: `μ(U) = sup {μ(F) \| F ⊆ U closed}` for `U` open. -/ class WeaklyRegular (μ : Measure α) : Prop extends OuterRegular μ where protected innerRegular : InnerRegularWRT μ IsClosed IsOpen /-- A measure `μ` is inner regular if, for any measurable set `s`, then `μ(s) = sup {μ(K) \| K ⊆ s compact}`. -/ class InnerRegular (μ : Measure α) : Prop where protected innerRegular : InnerRegularWRT μ IsCompact MeasurableSet /-- A measure `μ` is inner regular for finite measure sets with respect to compact sets: for any measurable set `s` with finite measure, then `μ(s) = sup {μ(K) \| K ⊆ s compact}`. The main interest of this class is that it is satisfied for both natural Haar measures (the regular one and the inner regular one). -/ class InnerRegularCompactLTTop (μ : Measure α) : Prop where protected innerRegular : InnerRegularWRT μ IsCompact (fun s ↦ MeasurableSet s ∧ μ s ≠ ∞) -- see Note [lower instance priority] /-- A regular measure is weakly regular in an R₁ space. -/ instance (priority := 100) Regular.weaklyRegular [R1Space α] [Regular μ] : WeaklyRegular μ where innerRegular := fun _U hU r hr ↦ let ⟨K, KU, K_comp, hK⟩ := Regular.innerRegular hU r hr ⟨closure K, K_comp.closure_subset_of_isOpen hU KU, isClosed_closure, hK.trans_le (measure_mono subset_closure)⟩ end Classes namespace OuterRegular variable [TopologicalSpace α] instance zero : OuterRegular (0 : Measure α) := ⟨fun A _ _r hr => ⟨univ, subset_univ A, isOpen_univ, hr⟩⟩ /-- Given `r` larger than the measure of a set `A`, there exists an open superset of `A` with measure less than `r`. -/ theorem _root_.Set.exists_isOpen_lt_of_lt [OuterRegular μ] (A : Set α) (r : ℝ≥0∞) (hr : μ A < r) : ∃ U, U ⊇ A ∧ IsOpen U ∧ μ U < r := by rcases OuterRegular.outerRegular (measurableSet_toMeasurable μ A) r (by rwa [measure_toMeasurable]) with ⟨U, hAU, hUo, hU⟩ exact ⟨U, (subset_toMeasurable _ _).trans hAU, hUo, hU⟩ /-- For an outer regular measure, the measure of a set is the infimum of the measures of open sets containing it. -/ theorem _root_.Set.measure_eq_iInf_isOpen (A : Set α) (μ : Measure α) [OuterRegular μ] : μ A = ⨅ (U : Set α) (_ : A ⊆ U) (_ : IsOpen U), μ U := by refine le_antisymm (le_iInf₂ fun s hs => le_iInf fun _ => μ.mono hs) ?_ refine le_of_forall_lt' fun r hr => ?_ simpa only [iInf_lt_iff, exists_prop] using A.exists_isOpen_lt_of_lt r hr theorem _root_.Set.exists_isOpen_lt_add [OuterRegular μ] (A : Set α) (hA : μ A ≠ ∞) {ε : ℝ≥0∞} (hε : ε ≠ 0) : ∃ U, U ⊇ A ∧ IsOpen U ∧ μ U < μ A + ε := A.exists_isOpen_lt_of_lt _ (ENNReal.lt_add_right hA hε) theorem _root_.Set.exists_isOpen_le_add (A : Set α) (μ : Measure α) [OuterRegular μ] {ε : ℝ≥0∞} (hε : ε ≠ 0) : ∃ U, U ⊇ A ∧ IsOpen U ∧ μ U ≤ μ A + ε := by rcases eq_or_ne (μ A) ∞ with (H \| H) · exact ⟨univ, subset_univ _, isOpen_univ, by simp only [H, _root_.top_add, le_top]⟩ · rcases A.exists_isOpen_lt_add H hε with ⟨U, AU, U_open, hU⟩ exact ⟨U, AU, U_open, hU.le⟩ theorem _root_.MeasurableSet.exists_isOpen_diff_lt [OuterRegular μ] {A : Set α} (hA : MeasurableSet A) (hA' : μ A ≠ ∞) {ε : ℝ≥0∞} (hε : ε ≠ 0) : ∃ U, U ⊇ A ∧ IsOpen U ∧ μ U < ∞ ∧ μ (U \ A) < ε := by rcases A.exists_isOpen_lt_add hA' hε with ⟨U, hAU, hUo, hU⟩ use U, hAU, hUo, hU.trans_le le_top exact measure_diff_lt_of_lt_add hA.nullMeasurableSet hAU hA' hU protected theorem map [OpensMeasurableSpace α] [MeasurableSpace β] [TopologicalSpace β] [BorelSpace β] (f : α ≃ₜ β) (μ : Measure α) [OuterRegular μ] :	(Measure.map f μ).OuterRegular := by refine ⟨fun A hA r hr => ?_⟩ rw [map_apply f.measurable hA, ← f.image_symm] at hr rcases Set.exists_isOpen_lt_of_lt _ r hr with ⟨U, hAU, hUo, hU⟩ have : IsOpen (f.symm ⁻¹' U) := hUo.preimage f.symm.continuous refine ⟨f.symm ⁻¹' U, image_subset_iff.1 hAU, this, ?_⟩	Mathlib/MeasureTheory/Measure/Regular.lean	369	374
/- 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.Analysis.InnerProductSpace.Adjoint import Mathlib.Topology.Algebra.Module.Equiv /-! # Partially defined linear operators on Hilbert spaces We will develop the basics of the theory of unbounded operators on Hilbert spaces. ## Main definitions * `LinearPMap.IsFormalAdjoint`: An operator `T` is a formal adjoint of `S` if for all `x` in the domain of `T` and `y` in the domain of `S`, we have that `⟪T x, y⟫ = ⟪x, S y⟫`. * `LinearPMap.adjoint`: The adjoint of a map `E →ₗ.[𝕜] F` as a map `F →ₗ.[𝕜] E`. ## Main statements * `LinearPMap.adjoint_isFormalAdjoint`: The adjoint is a formal adjoint * `LinearPMap.IsFormalAdjoint.le_adjoint`: Every formal adjoint is contained in the adjoint * `ContinuousLinearMap.toPMap_adjoint_eq_adjoint_toPMap_of_dense`: The adjoint on `ContinuousLinearMap` and `LinearPMap` coincide. ## Notation * For `T : E →ₗ.[𝕜] F` the adjoint can be written as `T†`. This notation is localized in `LinearPMap`. ## Implementation notes We use the junk value pattern to define the adjoint for all `LinearPMap`s. In the case that `T : E →ₗ.[𝕜] F` is not densely defined the adjoint `T†` is the zero map from `T.adjoint.domain` to `E`. ## References * [J. Weidmann, Linear Operators in Hilbert Spaces][weidmann_linear] ## Tags Unbounded operators, closed operators -/ noncomputable section open RCLike open scoped ComplexConjugate variable {𝕜 E F : Type} [RCLike 𝕜] variable [NormedAddCommGroup E] [InnerProductSpace 𝕜 E] variable [NormedAddCommGroup F] [InnerProductSpace 𝕜 F] local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y namespace LinearPMap /-- An operator `T` is a formal adjoint of `S` if for all `x` in the domain of `T` and `y` in the domain of `S`, we have that `⟪T x, y⟫ = ⟪x, S y⟫`. -/ def IsFormalAdjoint (T : E →ₗ.[𝕜] F) (S : F →ₗ.[𝕜] E) : Prop := ∀ (x : T.domain) (y : S.domain), ⟪T x, y⟫ = ⟪(x : E), S y⟫ variable {T : E →ₗ.[𝕜] F} {S : F →ₗ.[𝕜] E} @[symm] protected theorem IsFormalAdjoint.symm (h : T.IsFormalAdjoint S) : S.IsFormalAdjoint T := fun y _ => by rw [← inner_conj_symm, ← inner_conj_symm (y : F), h] variable (T) /-- The domain of the adjoint operator. This definition is needed to construct the adjoint operator and the preferred version to use is `T.adjoint.domain` instead of `T.adjointDomain`. -/ def adjointDomain : Submodule 𝕜 F where carrier := {y \| Continuous ((innerₛₗ 𝕜 y).comp T.toFun)} zero_mem' := by rw [Set.mem_setOf_eq, LinearMap.map_zero, LinearMap.zero_comp] exact continuous_zero add_mem' hx hy := by rw [Set.mem_setOf_eq, LinearMap.map_add] at ; exact hx.add hy smul_mem' a x hx := by rw [Set.mem_setOf_eq, LinearMap.map_smulₛₗ] at * exact hx.const_smul (conj a) /-- The operator `fun x ↦ ⟪y, T x⟫` considered as a continuous linear operator from `T.adjointDomain` to `𝕜`. -/ def adjointDomainMkCLM (y : T.adjointDomain) : T.domain →L[𝕜] 𝕜 := ⟨(innerₛₗ 𝕜 (y : F)).comp T.toFun, y.prop⟩ theorem adjointDomainMkCLM_apply (y : T.adjointDomain) (x : T.domain) : adjointDomainMkCLM T y x = ⟪(y : F), T x⟫ := rfl variable {T} variable (hT : Dense (T.domain : Set E)) /-- The unique continuous extension of the operator `adjointDomainMkCLM` to `E`. -/ def adjointDomainMkCLMExtend (y : T.adjointDomain) : E →L[𝕜] 𝕜 := (T.adjointDomainMkCLM y).extend (Submodule.subtypeL T.domain) hT.denseRange_val isUniformEmbedding_subtype_val.isUniformInducing @[simp] theorem adjointDomainMkCLMExtend_apply (y : T.adjointDomain) (x : T.domain) : adjointDomainMkCLMExtend hT y (x : E) = ⟪(y : F), T x⟫ := ContinuousLinearMap.extend_eq _ _ _ _ _ variable [CompleteSpace E] /-- The adjoint as a linear map from its domain to `E`. This is an auxiliary definition needed to define the adjoint operator as a `LinearPMap` without the assumption that `T.domain` is dense. -/ def adjointAux : T.adjointDomain →ₗ[𝕜] E where toFun y := (InnerProductSpace.toDual 𝕜 E).symm (adjointDomainMkCLMExtend hT y) map_add' x y := hT.eq_of_inner_left fun _ => by simp only [inner_add_left, Submodule.coe_add, InnerProductSpace.toDual_symm_apply, adjointDomainMkCLMExtend_apply] map_smul' _ _ := hT.eq_of_inner_left fun _ => by simp only [inner_smul_left, Submodule.coe_smul_of_tower, RingHom.id_apply, InnerProductSpace.toDual_symm_apply, adjointDomainMkCLMExtend_apply] theorem adjointAux_inner (y : T.adjointDomain) (x : T.domain) : ⟪adjointAux hT y, x⟫ = ⟪(y : F), T x⟫ := by simp [adjointAux] theorem adjointAux_unique (y : T.adjointDomain) {x₀ : E} (hx₀ : ∀ x : T.domain, ⟪x₀, x⟫ = ⟪(y : F), T x⟫) : adjointAux hT y = x₀ := hT.eq_of_inner_left fun v => (adjointAux_inner hT _ _).trans (hx₀ v).symm variable (T)	open scoped Classical in /-- The adjoint operator as a partially defined linear operator, denoted as `T†`. -/ def adjoint : F →ₗ.[𝕜] E where domain := T.adjointDomain toFun := if hT : Dense (T.domain : Set E) then adjointAux hT else 0 @[inherit_doc] scoped postfix:1024 "†" => LinearPMap.adjoint	Mathlib/Analysis/InnerProductSpace/LinearPMap.lean	140	147
/- Copyright (c) 2019 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Mario Carneiro -/ import Batteries.Data.Rat.Lemmas import Mathlib.Algebra.Group.Defs import Mathlib.Data.Rat.Init import Mathlib.Order.Basic import Mathlib.Tactic.Common import Mathlib.Data.Int.Init import Mathlib.Data.Nat.Basic /-! # Basics for the Rational Numbers ## Summary We define the integral domain structure on `ℚ` and prove basic lemmas about it. The definition of the field structure on `ℚ` will be done in `Mathlib.Data.Rat.Basic` once the `Field` class has been defined. ## Main Definitions - `Rat.divInt n d` constructs a rational number `q = n / d` from `n d : ℤ`. ## Notations - `/.` is infix notation for `Rat.divInt`. -/ -- TODO: If `Inv` was defined earlier than `Algebra.Group.Defs`, we could have -- assert_not_exists Monoid assert_not_exists MonoidWithZero Lattice PNat Nat.gcd_greatest open Function namespace Rat variable {q : ℚ} theorem pos (a : ℚ) : 0 < a.den := Nat.pos_of_ne_zero a.den_nz lemma mk'_num_den (q : ℚ) : mk' q.num q.den q.den_nz q.reduced = q := rfl @[simp] theorem ofInt_eq_cast (n : ℤ) : ofInt n = Int.cast n := rfl -- TODO: Replace `Rat.ofNat_num`/`Rat.ofNat_den` in Batteries @[simp] lemma num_ofNat (n : ℕ) : num ofNat(n) = ofNat(n) := rfl @[simp] lemma den_ofNat (n : ℕ) : den ofNat(n) = 1 := rfl @[simp, norm_cast] lemma num_natCast (n : ℕ) : num n = n := rfl @[simp, norm_cast] lemma den_natCast (n : ℕ) : den n = 1 := rfl -- TODO: Replace `intCast_num`/`intCast_den` the names in Batteries @[simp, norm_cast] lemma num_intCast (n : ℤ) : (n : ℚ).num = n := rfl @[simp, norm_cast] lemma den_intCast (n : ℤ) : (n : ℚ).den = 1 := rfl lemma intCast_injective : Injective (Int.cast : ℤ → ℚ) := fun _ _ ↦ congr_arg num lemma natCast_injective : Injective (Nat.cast : ℕ → ℚ) := intCast_injective.comp fun _ _ ↦ Int.natCast_inj.1 @[simp high, norm_cast] lemma natCast_inj {m n : ℕ} : (m : ℚ) = n ↔ m = n := natCast_injective.eq_iff @[simp high, norm_cast] lemma intCast_eq_zero {n : ℤ} : (n : ℚ) = 0 ↔ n = 0 := intCast_inj @[simp high, norm_cast] lemma natCast_eq_zero {n : ℕ} : (n : ℚ) = 0 ↔ n = 0 := natCast_inj @[simp high, norm_cast] lemma intCast_eq_one {n : ℤ} : (n : ℚ) = 1 ↔ n = 1 := intCast_inj @[simp high, norm_cast] lemma natCast_eq_one {n : ℕ} : (n : ℚ) = 1 ↔ n = 1 := natCast_inj lemma mkRat_eq_divInt (n d) : mkRat n d = n /. d := rfl @[simp] lemma mk'_zero (d) (h : d ≠ 0) (w) : mk' 0 d h w = 0 := by congr; simp_all @[simp] lemma num_eq_zero {q : ℚ} : q.num = 0 ↔ q = 0 := by induction q constructor · rintro rfl exact mk'_zero _ _ _ · exact congr_arg num lemma num_ne_zero {q : ℚ} : q.num ≠ 0 ↔ q ≠ 0 := num_eq_zero.not @[simp] lemma den_ne_zero (q : ℚ) : q.den ≠ 0 := q.den_pos.ne' @[simp] lemma num_nonneg : 0 ≤ q.num ↔ 0 ≤ q := by simp [Int.le_iff_lt_or_eq, instLE, Rat.blt, Int.not_lt]; tauto @[simp] theorem divInt_eq_zero {a b : ℤ} (b0 : b ≠ 0) : a /. b = 0 ↔ a = 0 := by rw [← zero_divInt b, divInt_eq_iff b0 b0, Int.zero_mul, Int.mul_eq_zero, or_iff_left b0] theorem divInt_ne_zero {a b : ℤ} (b0 : b ≠ 0) : a /. b ≠ 0 ↔ a ≠ 0 := (divInt_eq_zero b0).not -- TODO: this can move to Batteries theorem normalize_eq_mk' (n : Int) (d : Nat) (h : d ≠ 0) (c : Nat.gcd (Int.natAbs n) d = 1) : normalize n d h = mk' n d h c := (mk_eq_normalize ..).symm -- TODO: Rename `mkRat_num_den` in Batteries @[simp] alias mkRat_num_den' := mkRat_self -- TODO: Rename `Rat.divInt_self` to `Rat.num_divInt_den` in Batteries lemma num_divInt_den (q : ℚ) : q.num /. q.den = q := divInt_self _ lemma mk'_eq_divInt {n d h c} : (⟨n, d, h, c⟩ : ℚ) = n /. d := (num_divInt_den _).symm theorem intCast_eq_divInt (z : ℤ) : (z : ℚ) = z /. 1 := mk'_eq_divInt -- TODO: Rename `divInt_self` in Batteries to `num_divInt_den` @[simp] lemma divInt_self' {n : ℤ} (hn : n ≠ 0) : n /. n = 1 := by simpa using divInt_mul_right (n := 1) (d := 1) hn /-- Define a (dependent) function or prove `∀ r : ℚ, p r` by dealing with rational numbers of the form `n /. d` with `0 < d` and coprime `n`, `d`. -/ @[elab_as_elim] def numDenCasesOn.{u} {C : ℚ → Sort u} : ∀ (a : ℚ) (_ : ∀ n d, 0 < d → (Int.natAbs n).Coprime d → C (n /. d)), C a \| ⟨n, d, h, c⟩, H => by rw [mk'_eq_divInt]; exact H n d (Nat.pos_of_ne_zero h) c /-- Define a (dependent) function or prove `∀ r : ℚ, p r` by dealing with rational numbers of the form `n /. d` with `d ≠ 0`. -/ @[elab_as_elim] def numDenCasesOn'.{u} {C : ℚ → Sort u} (a : ℚ) (H : ∀ (n : ℤ) (d : ℕ), d ≠ 0 → C (n /. d)) : C a := numDenCasesOn a fun n d h _ => H n d h.ne' /-- Define a (dependent) function or prove `∀ r : ℚ, p r` by dealing with rational numbers of the form `mk' n d` with `d ≠ 0`. -/ @[elab_as_elim] def numDenCasesOn''.{u} {C : ℚ → Sort u} (a : ℚ) (H : ∀ (n : ℤ) (d : ℕ) (nz red), C (mk' n d nz red)) : C a := numDenCasesOn a fun n d h h' ↦ by rw [← mk_eq_divInt _ _ h.ne' h']; exact H n d h.ne' _ theorem lift_binop_eq (f : ℚ → ℚ → ℚ) (f₁ : ℤ → ℤ → ℤ → ℤ → ℤ) (f₂ : ℤ → ℤ → ℤ → ℤ → ℤ) (fv : ∀ {n₁ d₁ h₁ c₁ n₂ d₂ h₂ c₂}, f ⟨n₁, d₁, h₁, c₁⟩ ⟨n₂, d₂, h₂, c₂⟩ = f₁ n₁ d₁ n₂ d₂ /. f₂ n₁ d₁ n₂ d₂) (f0 : ∀ {n₁ d₁ n₂ d₂}, d₁ ≠ 0 → d₂ ≠ 0 → f₂ n₁ d₁ n₂ d₂ ≠ 0) (a b c d : ℤ) (b0 : b ≠ 0) (d0 : d ≠ 0) (H : ∀ {n₁ d₁ n₂ d₂}, a * d₁ = n₁ * b → c * d₂ = n₂ * d → f₁ n₁ d₁ n₂ d₂ * f₂ a b c d = f₁ a b c d * f₂ n₁ d₁ n₂ d₂) : f (a /. b) (c /. d) = f₁ a b c d /. f₂ a b c d := by generalize ha : a /. b = x; obtain ⟨n₁, d₁, h₁, c₁⟩ := x; rw [mk'_eq_divInt] at ha generalize hc : c /. d = x; obtain ⟨n₂, d₂, h₂, c₂⟩ := x; rw [mk'_eq_divInt] at hc rw [fv] have d₁0 := Int.ofNat_ne_zero.2 h₁ have d₂0 := Int.ofNat_ne_zero.2 h₂ exact (divInt_eq_iff (f0 d₁0 d₂0) (f0 b0 d0)).2 (H ((divInt_eq_iff b0 d₁0).1 ha) ((divInt_eq_iff d0 d₂0).1 hc)) attribute [simp] divInt_add_divInt attribute [simp] neg_divInt lemma neg_def (q : ℚ) : -q = -q.num /. q.den := by rw [← neg_divInt, num_divInt_den] @[simp] lemma divInt_neg (n d : ℤ) : n /. -d = -n /. d := divInt_neg' .. attribute [simp] divInt_sub_divInt @[simp] lemma divInt_mul_divInt' (n₁ d₁ n₂ d₂ : ℤ) : (n₁ /. d₁) * (n₂ /. d₂) = (n₁ * n₂) /. (d₁ * d₂) := by obtain rfl \| h₁ := eq_or_ne d₁ 0 · simp obtain rfl \| h₂ := eq_or_ne d₂ 0 · simp exact divInt_mul_divInt _ _ h₁ h₂ attribute [simp] mkRat_mul_mkRat lemma mk'_mul_mk' (n₁ n₂ : ℤ) (d₁ d₂ : ℕ) (hd₁ hd₂ hnd₁ hnd₂) (h₁₂ : n₁.natAbs.Coprime d₂) (h₂₁ : n₂.natAbs.Coprime d₁) : mk' n₁ d₁ hd₁ hnd₁ * mk' n₂ d₂ hd₂ hnd₂ = mk' (n₁ * n₂) (d₁ * d₂) (Nat.mul_ne_zero hd₁ hd₂) (by rw [Int.natAbs_mul]; exact (hnd₁.mul h₂₁).mul_right (h₁₂.mul hnd₂)) := by rw [mul_def]; dsimp; simp [mk_eq_normalize] lemma mul_eq_mkRat (q r : ℚ) : q * r = mkRat (q.num * r.num) (q.den * r.den) := by rw [mul_def, normalize_eq_mkRat] -- TODO: Rename `divInt_eq_iff` in Batteries to `divInt_eq_divInt` alias divInt_eq_divInt := divInt_eq_iff instance instPowNat : Pow ℚ ℕ where pow q n := ⟨q.num ^ n, q.den ^ n, by simp [Nat.pow_eq_zero], by rw [Int.natAbs_pow]; exact q.reduced.pow _ _⟩ lemma pow_def (q : ℚ) (n : ℕ) : q ^ n = ⟨q.num ^ n, q.den ^ n, by simp [Nat.pow_eq_zero], by rw [Int.natAbs_pow]; exact q.reduced.pow _ _⟩ := rfl lemma pow_eq_mkRat (q : ℚ) (n : ℕ) : q ^ n = mkRat (q.num ^ n) (q.den ^ n) := by rw [pow_def, mk_eq_mkRat] lemma pow_eq_divInt (q : ℚ) (n : ℕ) : q ^ n = q.num ^ n /. q.den ^ n := by rw [pow_def, mk_eq_divInt, Int.natCast_pow] @[simp] lemma num_pow (q : ℚ) (n : ℕ) : (q ^ n).num = q.num ^ n := rfl @[simp] lemma den_pow (q : ℚ) (n : ℕ) : (q ^ n).den = q.den ^ n := rfl @[simp] lemma mk'_pow (num : ℤ) (den : ℕ) (hd hdn) (n : ℕ) : mk' num den hd hdn ^ n = mk' (num ^ n) (den ^ n) (by simp [Nat.pow_eq_zero, hd]) (by rw [Int.natAbs_pow]; exact hdn.pow _ _) := rfl instance : Inv ℚ := ⟨Rat.inv⟩ @[simp] lemma inv_divInt' (a b : ℤ) : (a /. b)⁻¹ = b /. a := inv_divInt .. @[simp] lemma inv_mkRat (a : ℤ) (b : ℕ) : (mkRat a b)⁻¹ = b /. a := by rw [mkRat_eq_divInt, inv_divInt'] lemma inv_def' (q : ℚ) : q⁻¹ = q.den /. q.num := by rw [← inv_divInt', num_divInt_den] @[simp] lemma divInt_div_divInt (n₁ d₁ n₂ d₂) : (n₁ /. d₁) / (n₂ /. d₂) = (n₁ * d₂) /. (d₁ * n₂) := by rw [div_def, inv_divInt, divInt_mul_divInt'] lemma div_def' (q r : ℚ) : q / r = (q.num * r.den) /. (q.den * r.num) := by rw [← divInt_div_divInt, num_divInt_den, num_divInt_den] variable (a b c : ℚ) protected lemma add_zero : a + 0 = a := by simp [add_def, normalize_eq_mkRat] protected lemma zero_add : 0 + a = a := by simp [add_def, normalize_eq_mkRat] protected lemma add_comm : a + b = b + a := by simp [add_def, Int.add_comm, Int.mul_comm, Nat.mul_comm] protected theorem add_assoc : a + b + c = a + (b + c) := numDenCasesOn' a fun n₁ d₁ h₁ ↦ numDenCasesOn' b fun n₂ d₂ h₂ ↦ numDenCasesOn' c fun n₃ d₃ h₃ ↦ by simp only [ne_eq, Int.natCast_eq_zero, h₁, not_false_eq_true, h₂, divInt_add_divInt, Int.mul_eq_zero, or_self, h₃] rw [Int.mul_assoc, Int.add_mul, Int.add_mul, Int.mul_assoc, Int.add_assoc] congr 2 ac_rfl protected lemma neg_add_cancel : -a + a = 0 := by simp [add_def, normalize_eq_mkRat, Int.neg_mul, Int.add_comm, ← Int.sub_eq_add_neg] @[simp] lemma divInt_one (n : ℤ) : n /. 1 = n := by simp [divInt, mkRat, normalize] @[simp] lemma mkRat_one (n : ℤ) : mkRat n 1 = n := by simp [mkRat_eq_divInt] lemma divInt_one_one : 1 /. 1 = 1 := by rw [divInt_one, intCast_one] protected theorem mul_assoc : a * b * c = a * (b * c) := numDenCasesOn' a fun n₁ d₁ h₁ => numDenCasesOn' b fun n₂ d₂ h₂ => numDenCasesOn' c fun n₃ d₃ h₃ => by simp [h₁, h₂, h₃, Int.mul_comm, Nat.mul_assoc, Int.mul_left_comm] protected theorem add_mul : (a + b) * c = a * c + b * c := numDenCasesOn' a fun n₁ d₁ h₁ ↦ numDenCasesOn' b fun n₂ d₂ h₂ ↦ numDenCasesOn' c fun n₃ d₃ h₃ ↦ by simp only [ne_eq, Int.natCast_eq_zero, h₁, not_false_eq_true, h₂, divInt_add_divInt, Int.mul_eq_zero, or_self, h₃, divInt_mul_divInt] rw [← divInt_mul_right (Int.natCast_ne_zero.2 h₃), Int.add_mul, Int.add_mul] ac_rfl protected theorem mul_add : a * (b + c) = a * b + a * c := by rw [Rat.mul_comm, Rat.add_mul, Rat.mul_comm, Rat.mul_comm c a] protected theorem zero_ne_one : 0 ≠ (1 : ℚ) := by rw [ne_comm, ← divInt_one_one, divInt_ne_zero] <;> omega attribute [simp] mkRat_eq_zero protected theorem mul_inv_cancel : a ≠ 0 → a * a⁻¹ = 1 := numDenCasesOn' a fun n d hd hn ↦ by simp only [divInt_ofNat, ne_eq, hd, not_false_eq_true, mkRat_eq_zero] at hn simp [-divInt_ofNat, mkRat_eq_divInt, Int.mul_comm, Int.mul_ne_zero hn (Int.ofNat_ne_zero.2 hd)] protected theorem inv_mul_cancel (h : a ≠ 0) : a⁻¹ * a = 1 := Eq.trans (Rat.mul_comm _ _) (Rat.mul_inv_cancel _ h) -- Extra instances to short-circuit type class resolution -- TODO(Mario): this instance slows down Mathlib.Data.Real.Basic instance nontrivial : Nontrivial ℚ where exists_pair_ne := ⟨1, 0, by decide⟩ /-! ### The rational numbers are a group -/ instance addCommGroup : AddCommGroup ℚ where zero := 0 add := (· + ·) neg := Neg.neg zero_add := Rat.zero_add add_zero := Rat.add_zero add_comm := Rat.add_comm add_assoc := Rat.add_assoc neg_add_cancel := Rat.neg_add_cancel sub_eq_add_neg := Rat.sub_eq_add_neg nsmul := nsmulRec zsmul := zsmulRec instance addGroup : AddGroup ℚ := by infer_instance instance addCommMonoid : AddCommMonoid ℚ := by infer_instance instance addMonoid : AddMonoid ℚ := by infer_instance instance addLeftCancelSemigroup : AddLeftCancelSemigroup ℚ := by infer_instance instance addRightCancelSemigroup : AddRightCancelSemigroup ℚ := by infer_instance instance addCommSemigroup : AddCommSemigroup ℚ := by infer_instance instance addSemigroup : AddSemigroup ℚ := by infer_instance instance commMonoid : CommMonoid ℚ where one := 1 mul := (· * ·) mul_one := Rat.mul_one one_mul := Rat.one_mul mul_comm := Rat.mul_comm mul_assoc := Rat.mul_assoc npow n q := q ^ n npow_zero := by intros; apply Rat.ext <;> simp [Int.pow_zero] npow_succ n q := by rw [← q.mk'_num_den, mk'_pow, mk'_mul_mk'] · congr · rw [mk'_pow, Int.natAbs_pow] exact q.reduced.pow_left _ · rw [mk'_pow] exact q.reduced.pow_right _ instance monoid : Monoid ℚ := by infer_instance instance commSemigroup : CommSemigroup ℚ := by infer_instance instance semigroup : Semigroup ℚ := by infer_instance theorem eq_iff_mul_eq_mul {p q : ℚ} : p = q ↔ p.num * q.den = q.num * p.den := by conv => lhs rw [← num_divInt_den p, ← num_divInt_den q] apply Rat.divInt_eq_iff <;> · rw [← Int.natCast_zero, Ne, Int.ofNat_inj] apply den_nz @[simp] theorem den_neg_eq_den (q : ℚ) : (-q).den = q.den := rfl @[simp] theorem num_neg_eq_neg_num (q : ℚ) : (-q).num = -q.num := rfl -- Not `@[simp]` as `num_ofNat` is stronger. theorem num_zero : Rat.num 0 = 0 := rfl -- Not `@[simp]` as `den_ofNat` is stronger. theorem den_zero : Rat.den 0 = 1 := rfl lemma zero_of_num_zero {q : ℚ} (hq : q.num = 0) : q = 0 := by simpa [hq] using q.num_divInt_den.symm theorem zero_iff_num_zero {q : ℚ} : q = 0 ↔ q.num = 0 := ⟨fun _ => by simp [*], zero_of_num_zero⟩	-- `Not `@[simp]` as `num_ofNat` is stronger. theorem num_one : (1 : ℚ).num = 1 :=	Mathlib/Data/Rat/Defs.lean	367	368
/- Copyright (c) 2018 Sean Leather. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Sean Leather, Mario Carneiro -/ import Mathlib.Data.List.AList import Mathlib.Data.Finset.Sigma import Mathlib.Data.Part /-! # Finite maps over `Multiset` -/ universe u v w open List variable {α : Type u} {β : α → Type v} /-! ### Multisets of sigma types -/ namespace Multiset /-- Multiset of keys of an association multiset. -/ def keys (s : Multiset (Sigma β)) : Multiset α := s.map Sigma.fst @[simp] theorem coe_keys {l : List (Sigma β)} : keys (l : Multiset (Sigma β)) = (l.keys : Multiset α) := rfl @[simp] theorem keys_zero : keys (0 : Multiset (Sigma β)) = 0 := rfl @[simp] theorem keys_cons {a : α} {b : β a} {s : Multiset (Sigma β)} : keys (⟨a, b⟩ ::ₘ s) = a ::ₘ keys s := by simp [keys] @[simp] theorem keys_singleton {a : α} {b : β a} : keys ({⟨a, b⟩} : Multiset (Sigma β)) = {a} := rfl /-- `NodupKeys s` means that `s` has no duplicate keys. -/ def NodupKeys (s : Multiset (Sigma β)) : Prop := Quot.liftOn s List.NodupKeys fun _ _ p => propext <\| perm_nodupKeys p @[simp] theorem coe_nodupKeys {l : List (Sigma β)} : @NodupKeys α β l ↔ l.NodupKeys := Iff.rfl lemma nodup_keys {m : Multiset (Σ a, β a)} : m.keys.Nodup ↔ m.NodupKeys := by rcases m with ⟨l⟩; rfl alias ⟨_, NodupKeys.nodup_keys⟩ := nodup_keys protected lemma NodupKeys.nodup {m : Multiset (Σ a, β a)} (h : m.NodupKeys) : m.Nodup := h.nodup_keys.of_map _ end Multiset /-! ### Finmap -/ /-- `Finmap β` is the type of finite maps over a multiset. It is effectively a quotient of `AList β` by permutation of the underlying list. -/ structure Finmap (β : α → Type v) : Type max u v where /-- The underlying `Multiset` of a `Finmap` -/ entries : Multiset (Sigma β) /-- There are no duplicate keys in `entries` -/ nodupKeys : entries.NodupKeys /-- The quotient map from `AList` to `Finmap`. -/ def AList.toFinmap (s : AList β) : Finmap β := ⟨s.entries, s.nodupKeys⟩ local notation:arg "⟦" a "⟧" => AList.toFinmap a theorem AList.toFinmap_eq {s₁ s₂ : AList β} : toFinmap s₁ = toFinmap s₂ ↔ s₁.entries ~ s₂.entries := by cases s₁ cases s₂ simp [AList.toFinmap] @[simp] theorem AList.toFinmap_entries (s : AList β) : ⟦s⟧.entries = s.entries := rfl /-- Given `l : List (Sigma β)`, create a term of type `Finmap β` by removing entries with duplicate keys. -/ def List.toFinmap [DecidableEq α] (s : List (Sigma β)) : Finmap β := s.toAList.toFinmap namespace Finmap open AList lemma nodup_entries (f : Finmap β) : f.entries.Nodup := f.nodupKeys.nodup /-! ### Lifting from AList -/ /-- Lift a permutation-respecting function on `AList` to `Finmap`. -/ def liftOn {γ} (s : Finmap β) (f : AList β → γ) (H : ∀ a b : AList β, a.entries ~ b.entries → f a = f b) : γ := by refine (Quotient.liftOn s.entries (fun (l : List (Sigma β)) => (⟨_, fun nd => f ⟨l, nd⟩⟩ : Part γ)) (fun l₁ l₂ p => Part.ext' (perm_nodupKeys p) ?_) : Part γ).get ?_ · exact fun h1 h2 => H _ _ p · have := s.nodupKeys revert this rcases s.entries with ⟨l⟩ exact id @[simp] theorem liftOn_toFinmap {γ} (s : AList β) (f : AList β → γ) (H) : liftOn ⟦s⟧ f H = f s := by cases s rfl /-- Lift a permutation-respecting function on 2 `AList`s to 2 `Finmap`s. -/ def liftOn₂ {γ} (s₁ s₂ : Finmap β) (f : AList β → AList β → γ) (H : ∀ a₁ b₁ a₂ b₂ : AList β, a₁.entries ~ a₂.entries → b₁.entries ~ b₂.entries → f a₁ b₁ = f a₂ b₂) : γ := liftOn s₁ (fun l₁ => liftOn s₂ (f l₁) fun _ _ p => H _ _ _ _ (Perm.refl _) p) fun a₁ a₂ p => by have H' : f a₁ = f a₂ := funext fun _ => H _ _ _ _ p (Perm.refl _) simp only [H'] @[simp] theorem liftOn₂_toFinmap {γ} (s₁ s₂ : AList β) (f : AList β → AList β → γ) (H) : liftOn₂ ⟦s₁⟧ ⟦s₂⟧ f H = f s₁ s₂ := by cases s₁; cases s₂; rfl /-! ### Induction -/ @[elab_as_elim] theorem induction_on {C : Finmap β → Prop} (s : Finmap β) (H : ∀ a : AList β, C ⟦a⟧) : C s := by rcases s with ⟨⟨a⟩, h⟩; exact H ⟨a, h⟩ @[elab_as_elim] theorem induction_on₂ {C : Finmap β → Finmap β → Prop} (s₁ s₂ : Finmap β) (H : ∀ a₁ a₂ : AList β, C ⟦a₁⟧ ⟦a₂⟧) : C s₁ s₂ := induction_on s₁ fun l₁ => induction_on s₂ fun l₂ => H l₁ l₂ @[elab_as_elim] theorem induction_on₃ {C : Finmap β → Finmap β → Finmap β → Prop} (s₁ s₂ s₃ : Finmap β) (H : ∀ a₁ a₂ a₃ : AList β, C ⟦a₁⟧ ⟦a₂⟧ ⟦a₃⟧) : C s₁ s₂ s₃ := induction_on₂ s₁ s₂ fun l₁ l₂ => induction_on s₃ fun l₃ => H l₁ l₂ l₃ /-! ### extensionality -/ @[ext] theorem ext : ∀ {s t : Finmap β}, s.entries = t.entries → s = t \| ⟨l₁, h₁⟩, ⟨l₂, _⟩, H => by congr @[simp] theorem ext_iff' {s t : Finmap β} : s.entries = t.entries ↔ s = t := Finmap.ext_iff.symm /-! ### mem -/ /-- The predicate `a ∈ s` means that `s` has a value associated to the key `a`. -/ instance : Membership α (Finmap β) := ⟨fun s a => a ∈ s.entries.keys⟩ theorem mem_def {a : α} {s : Finmap β} : a ∈ s ↔ a ∈ s.entries.keys := Iff.rfl @[simp] theorem mem_toFinmap {a : α} {s : AList β} : a ∈ toFinmap s ↔ a ∈ s := Iff.rfl /-! ### keys -/ /-- The set of keys of a finite map. -/ def keys (s : Finmap β) : Finset α := ⟨s.entries.keys, s.nodupKeys.nodup_keys⟩ @[simp] theorem keys_val (s : AList β) : (keys ⟦s⟧).val = s.keys := rfl @[simp] theorem keys_ext {s₁ s₂ : AList β} : keys ⟦s₁⟧ = keys ⟦s₂⟧ ↔ s₁.keys ~ s₂.keys := by simp [keys, AList.keys] theorem mem_keys {a : α} {s : Finmap β} : a ∈ s.keys ↔ a ∈ s := induction_on s fun _ => AList.mem_keys /-! ### empty -/ /-- The empty map. -/ instance : EmptyCollection (Finmap β) := ⟨⟨0, nodupKeys_nil⟩⟩ instance : Inhabited (Finmap β) := ⟨∅⟩ @[simp] theorem empty_toFinmap : (⟦∅⟧ : Finmap β) = ∅ := rfl @[simp] theorem toFinmap_nil [DecidableEq α] : ([].toFinmap : Finmap β) = ∅ := rfl theorem not_mem_empty {a : α} : a ∉ (∅ : Finmap β) := Multiset.not_mem_zero a @[simp] theorem keys_empty : (∅ : Finmap β).keys = ∅ := rfl /-! ### singleton -/ /-- The singleton map. -/ def singleton (a : α) (b : β a) : Finmap β := ⟦AList.singleton a b⟧ @[simp] theorem keys_singleton (a : α) (b : β a) : (singleton a b).keys = {a} := rfl @[simp] theorem mem_singleton (x y : α) (b : β y) : x ∈ singleton y b ↔ x = y := by simp [singleton, mem_def] section variable [DecidableEq α] instance decidableEq [∀ a, DecidableEq (β a)] : DecidableEq (Finmap β) \| _, _ => decidable_of_iff _ Finmap.ext_iff.symm /-! ### lookup -/ /-- Look up the value associated to a key in a map. -/ def lookup (a : α) (s : Finmap β) : Option (β a) := liftOn s (AList.lookup a) fun _ _ => perm_lookup @[simp] theorem lookup_toFinmap (a : α) (s : AList β) : lookup a ⟦s⟧ = s.lookup a := rfl @[simp] theorem dlookup_list_toFinmap (a : α) (s : List (Sigma β)) : lookup a s.toFinmap = s.dlookup a := by rw [List.toFinmap, lookup_toFinmap, lookup_to_alist] @[simp] theorem lookup_empty (a) : lookup a (∅ : Finmap β) = none := rfl theorem lookup_isSome {a : α} {s : Finmap β} : (s.lookup a).isSome ↔ a ∈ s := induction_on s fun _ => AList.lookup_isSome theorem lookup_eq_none {a} {s : Finmap β} : lookup a s = none ↔ a ∉ s := induction_on s fun _ => AList.lookup_eq_none lemma mem_lookup_iff {s : Finmap β} {a : α} {b : β a} : b ∈ s.lookup a ↔ Sigma.mk a b ∈ s.entries := by rcases s with ⟨⟨l⟩, hl⟩; exact List.mem_dlookup_iff hl lemma lookup_eq_some_iff {s : Finmap β} {a : α} {b : β a} : s.lookup a = b ↔ Sigma.mk a b ∈ s.entries := mem_lookup_iff @[simp] lemma sigma_keys_lookup (s : Finmap β) : s.keys.sigma (fun i => (s.lookup i).toFinset) = ⟨s.entries, s.nodup_entries⟩ := by ext x have : x ∈ s.entries → x.1 ∈ s.keys := Multiset.mem_map_of_mem _ simpa [lookup_eq_some_iff] @[simp] theorem lookup_singleton_eq {a : α} {b : β a} : (singleton a b).lookup a = some b := by rw [singleton, lookup_toFinmap, AList.singleton, AList.lookup, dlookup_cons_eq] instance (a : α) (s : Finmap β) : Decidable (a ∈ s) := decidable_of_iff _ lookup_isSome theorem mem_iff {a : α} {s : Finmap β} : a ∈ s ↔ ∃ b, s.lookup a = some b := induction_on s fun s => Iff.trans List.mem_keys <\| exists_congr fun _ => (mem_dlookup_iff s.nodupKeys).symm theorem mem_of_lookup_eq_some {a : α} {b : β a} {s : Finmap β} (h : s.lookup a = some b) : a ∈ s := mem_iff.mpr ⟨_, h⟩ theorem ext_lookup {s₁ s₂ : Finmap β} : (∀ x, s₁.lookup x = s₂.lookup x) → s₁ = s₂ := induction_on₂ s₁ s₂ fun s₁ s₂ h => by simp only [AList.lookup, lookup_toFinmap] at h rw [AList.toFinmap_eq] apply lookup_ext s₁.nodupKeys s₂.nodupKeys intro x y rw [h] /-- An equivalence between `Finmap β` and pairs `(keys : Finset α, lookup : ∀ a, Option (β a))` such that `(lookup a).isSome ↔ a ∈ keys`. -/ @[simps apply_coe_fst apply_coe_snd] def keysLookupEquiv : Finmap β ≃ { f : Finset α × (∀ a, Option (β a)) // ∀ i, (f.2 i).isSome ↔ i ∈ f.1 } where toFun s := ⟨(s.keys, fun i => s.lookup i), fun _ => lookup_isSome⟩ invFun f := mk (f.1.1.sigma fun i => (f.1.2 i).toFinset).val <\| by refine Multiset.nodup_keys.1 ((Finset.nodup _).map_on ?_) simp only [Finset.mem_val, Finset.mem_sigma, Option.mem_toFinset, Option.mem_def] rintro ⟨i, x⟩ ⟨_, hx⟩ ⟨j, y⟩ ⟨_, hy⟩ (rfl : i = j) simpa using hx.symm.trans hy left_inv f := ext <\| by simp right_inv := fun ⟨(s, f), hf⟩ => by dsimp only at hf ext · simp [keys, Multiset.keys, ← hf, Option.isSome_iff_exists] · simp +contextual [lookup_eq_some_iff, ← hf] @[simp] lemma keysLookupEquiv_symm_apply_keys : ∀ f : {f : Finset α × (∀ a, Option (β a)) // ∀ i, (f.2 i).isSome ↔ i ∈ f.1}, (keysLookupEquiv.symm f).keys = f.1.1 := keysLookupEquiv.surjective.forall.2 fun _ => by simp only [Equiv.symm_apply_apply, keysLookupEquiv_apply_coe_fst] @[simp] lemma keysLookupEquiv_symm_apply_lookup : ∀ (f : {f : Finset α × (∀ a, Option (β a)) // ∀ i, (f.2 i).isSome ↔ i ∈ f.1}) a, (keysLookupEquiv.symm f).lookup a = f.1.2 a := keysLookupEquiv.surjective.forall.2 fun _ _ => by simp only [Equiv.symm_apply_apply, keysLookupEquiv_apply_coe_snd]	/-! ### replace -/ /-- Replace a key with a given value in a finite map. If the key is not present it does nothing. -/ def replace (a : α) (b : β a) (s : Finmap β) : Finmap β := (liftOn s fun t => AList.toFinmap (AList.replace a b t))	Mathlib/Data/Finmap.lean	320	326
/- Copyright (c) 2020 Anatole Dedecker. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Anatole Dedecker, Alexey Soloyev, Junyan Xu, Kamila Szewczyk -/ import Mathlib.Algebra.EuclideanDomain.Basic import Mathlib.Algebra.LinearRecurrence import Mathlib.Data.Fin.VecNotation import Mathlib.Data.Nat.Fib.Basic import Mathlib.Data.Real.Irrational import Mathlib.Tactic.NormNum.NatFib import Mathlib.Tactic.NormNum.Prime /-! # The golden ratio and its conjugate This file defines the golden ratio `φ := (1 + √5)/2` and its conjugate `ψ := (1 - √5)/2`, which are the two real roots of `X² - X - 1`. Along with various computational facts about them, we prove their irrationality, and we link them to the Fibonacci sequence by proving Binet's formula. -/ noncomputable section open Polynomial /-- The golden ratio `φ := (1 + √5)/2`. -/ abbrev goldenRatio : ℝ := (1 + √5) / 2 /-- The conjugate of the golden ratio `ψ := (1 - √5)/2`. -/ abbrev goldenConj : ℝ := (1 - √5) / 2 @[inherit_doc goldenRatio] scoped[goldenRatio] notation "φ" => goldenRatio @[inherit_doc goldenConj] scoped[goldenRatio] notation "ψ" => goldenConj open Real goldenRatio /-- The inverse of the golden ratio is the opposite of its conjugate. -/ theorem inv_gold : φ⁻¹ = -ψ := by have : 1 + √5 ≠ 0 := ne_of_gt (add_pos (by norm_num) <\| Real.sqrt_pos.mpr (by norm_num)) field_simp [sub_mul, mul_add] norm_num /-- The opposite of the golden ratio is the inverse of its conjugate. -/ theorem inv_goldConj : ψ⁻¹ = -φ := by rw [inv_eq_iff_eq_inv, ← neg_inv, ← neg_eq_iff_eq_neg] exact inv_gold.symm @[simp] theorem gold_mul_goldConj : φ * ψ = -1 := by field_simp rw [← sq_sub_sq] norm_num @[simp] theorem goldConj_mul_gold : ψ * φ = -1 := by rw [mul_comm] exact gold_mul_goldConj @[simp] theorem gold_add_goldConj : φ + ψ = 1 := by rw [goldenRatio, goldenConj] ring theorem one_sub_goldConj : 1 - φ = ψ := by linarith [gold_add_goldConj] theorem one_sub_gold : 1 - ψ = φ := by linarith [gold_add_goldConj] @[simp] theorem gold_sub_goldConj : φ - ψ = √5 := by ring theorem gold_pow_sub_gold_pow (n : ℕ) : φ ^ (n + 2) - φ ^ (n + 1) = φ ^ n := by rw [goldenRatio]; ring_nf; norm_num; ring @[simp 1200] theorem gold_sq : φ ^ 2 = φ + 1 := by rw [goldenRatio, ← sub_eq_zero] ring_nf rw [Real.sq_sqrt] <;> norm_num @[simp 1200] theorem goldConj_sq : ψ ^ 2 = ψ + 1 := by rw [goldenConj, ← sub_eq_zero] ring_nf rw [Real.sq_sqrt] <;> norm_num theorem gold_pos : 0 < φ := mul_pos (by apply add_pos <;> norm_num) <\| inv_pos.2 zero_lt_two theorem gold_ne_zero : φ ≠ 0 := ne_of_gt gold_pos theorem one_lt_gold : 1 < φ := by refine lt_of_mul_lt_mul_left ?_ (le_of_lt gold_pos) simp [← sq, gold_pos, zero_lt_one] theorem gold_lt_two : φ < 2 := by calc (1 + sqrt 5) / 2 < (1 + 3) / 2 := by gcongr; rw [sqrt_lt'] <;> norm_num _ = 2 := by norm_num theorem goldConj_neg : ψ < 0 := by linarith [one_sub_goldConj, one_lt_gold] theorem goldConj_ne_zero : ψ ≠ 0 := ne_of_lt goldConj_neg theorem neg_one_lt_goldConj : -1 < ψ := by rw [neg_lt, ← inv_gold] exact inv_lt_one_of_one_lt₀ one_lt_gold /-! ## Irrationality -/ /-- The golden ratio is irrational. -/ theorem gold_irrational : Irrational φ := by have := Nat.Prime.irrational_sqrt (show Nat.Prime 5 by norm_num) have := this.ratCast_add 1 convert this.ratCast_mul (show (0.5 : ℚ) ≠ 0 by norm_num) norm_num field_simp /-- The conjugate of the golden ratio is irrational. -/ theorem goldConj_irrational : Irrational ψ := by have := Nat.Prime.irrational_sqrt (show Nat.Prime 5 by norm_num) have := this.ratCast_sub 1 convert this.ratCast_mul (show (0.5 : ℚ) ≠ 0 by norm_num) norm_num field_simp /-! ## Links with Fibonacci sequence -/ section Fibrec variable {α : Type} [CommSemiring α] /-- The recurrence relation satisfied by the Fibonacci sequence. -/ def fibRec : LinearRecurrence α where order := 2 coeffs := ![1, 1] section Poly open Polynomial /-- The characteristic polynomial of `fibRec` is `X² - (X + 1)`. -/ theorem fibRec_charPoly_eq {β : Type} [CommRing β] : fibRec.charPoly = X ^ 2 - (X + (1 : β[X])) := by rw [fibRec, LinearRecurrence.charPoly] simp [Finset.sum_fin_eq_sum_range, Finset.sum_range_succ', ← smul_X_eq_monomial] end Poly /-- As expected, the Fibonacci sequence is a solution of `fibRec`. -/ theorem fib_isSol_fibRec : fibRec.IsSolution (fun x => x.fib : ℕ → α) := by rw [fibRec] intro n simp only rw [Nat.fib_add_two, add_comm] simp [Finset.sum_fin_eq_sum_range, Finset.sum_range_succ'] /-- The geometric sequence `fun n ↦ φ^n` is a solution of `fibRec`. -/ theorem geom_gold_isSol_fibRec : fibRec.IsSolution (φ ^ ·) := by rw [fibRec.geom_sol_iff_root_charPoly, fibRec_charPoly_eq] simp [sub_eq_zero] /-- The geometric sequence `fun n ↦ ψ^n` is a solution of `fibRec`. -/ theorem geom_goldConj_isSol_fibRec : fibRec.IsSolution (ψ ^ ·) := by rw [fibRec.geom_sol_iff_root_charPoly, fibRec_charPoly_eq] simp [sub_eq_zero] end Fibrec /-- Binet's formula as a function equality. -/ theorem Real.coe_fib_eq' : (fun n => Nat.fib n : ℕ → ℝ) = fun n => (φ ^ n - ψ ^ n) / √5 := by rw [fibRec.sol_eq_of_eq_init] · intro i hi norm_cast at hi	fin_cases hi · simp · simp only [goldenRatio, goldenConj] ring_nf rw [mul_inv_cancel₀]; norm_num · exact fib_isSol_fibRec	Mathlib/Data/Real/GoldenRatio.lean	187	192
/- 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.Analysis.Normed.Group.Basic import Mathlib.Topology.MetricSpace.ProperSpace.Real import Mathlib.Analysis.Normed.Ring.Lemmas /-! # Bounded operations This file introduces type classes for bornologically bounded operations. In particular, when combined with type classes which guarantee continuity of the same operations, we can equip bounded continuous functions with the corresponding operations. ## Main definitions * `BoundedAdd R`: a class guaranteeing boundedness of addition. * `BoundedSub R`: a class guaranteeing boundedness of subtraction. * `BoundedMul R`: a class guaranteeing boundedness of multiplication. -/ open scoped NNReal section bounded_sub /-! ### Bounded subtraction -/ open Pointwise /-- A typeclass saying that `(p : R × R) ↦ p.1 - p.2` maps any product of bounded sets to a bounded set. This property automatically holds for seminormed additive groups, but it also holds, e.g., for `ℝ≥0`. -/ class BoundedSub (R : Type) [Bornology R] [Sub R] : Prop where isBounded_sub : ∀ {s t : Set R}, Bornology.IsBounded s → Bornology.IsBounded t → Bornology.IsBounded (s - t) variable {R : Type} lemma isBounded_sub [Bornology R] [Sub R] [BoundedSub R] {s t : Set R} (hs : Bornology.IsBounded s) (ht : Bornology.IsBounded t) : Bornology.IsBounded (s - t) := BoundedSub.isBounded_sub hs ht lemma sub_bounded_of_bounded_of_bounded {X : Type} [PseudoMetricSpace R] [Sub R] [BoundedSub R] {f g : X → R} (f_bdd : ∃ C, ∀ x y, dist (f x) (f y) ≤ C) (g_bdd : ∃ C, ∀ x y, dist (g x) (g y) ≤ C) : ∃ C, ∀ x y, dist ((f - g) x) ((f - g) y) ≤ C := by obtain ⟨C, hC⟩ := Metric.isBounded_iff.mp <\| isBounded_sub (Metric.isBounded_range_iff.mpr f_bdd) (Metric.isBounded_range_iff.mpr g_bdd) use C intro x y exact hC (Set.sub_mem_sub (Set.mem_range_self (f := f) x) (Set.mem_range_self (f := g) x)) (Set.sub_mem_sub (Set.mem_range_self (f := f) y) (Set.mem_range_self (f := g) y)) lemma boundedSub_of_lipschitzWith_sub [PseudoMetricSpace R] [Sub R] {K : NNReal} (lip : LipschitzWith K (fun (p : R × R) ↦ p.1 - p.2)) : BoundedSub R where isBounded_sub {s t} s_bdd t_bdd := by have bdd : Bornology.IsBounded (s ×ˢ t) := Bornology.IsBounded.prod s_bdd t_bdd convert lip.isBounded_image bdd ext p simp only [Set.mem_image, Set.mem_prod, Prod.exists] constructor · intro ⟨a, a_in_s, b, b_in_t, eq_p⟩ exact ⟨a, b, ⟨a_in_s, b_in_t⟩, eq_p⟩ · intro ⟨a, b, ⟨a_in_s, b_in_t⟩, eq_p⟩ simpa [← eq_p] using Set.sub_mem_sub a_in_s b_in_t end bounded_sub section bounded_mul /-! ### Bounded multiplication and addition -/ open Pointwise Set /-- A typeclass saying that `(p : R × R) ↦ p.1 + p.2` maps any product of bounded sets to a bounded set. This property follows from `LipschitzAdd`, and thus automatically holds, e.g., for seminormed additive groups. -/ class BoundedAdd (R : Type) [Bornology R] [Add R] : Prop where isBounded_add : ∀ {s t : Set R}, Bornology.IsBounded s → Bornology.IsBounded t → Bornology.IsBounded (s + t) /-- A typeclass saying that `(p : R × R) ↦ p.1 * p.2` maps any product of bounded sets to a bounded set. This property automatically holds for non-unital seminormed rings, but it also holds, e.g., for `ℝ≥0`. -/ @[to_additive] class BoundedMul (R : Type) [Bornology R] [Mul R] : Prop where isBounded_mul : ∀ {s t : Set R}, Bornology.IsBounded s → Bornology.IsBounded t → Bornology.IsBounded (s t) variable {R : Type} @[to_additive] lemma isBounded_mul [Bornology R] [Mul R] [BoundedMul R] {s t : Set R} (hs : Bornology.IsBounded s) (ht : Bornology.IsBounded t) : Bornology.IsBounded (s t) := BoundedMul.isBounded_mul hs ht	@[to_additive] lemma isBounded_pow {R : Type} [Bornology R] [Monoid R] [BoundedMul R] {s : Set R} (s_bdd : Bornology.IsBounded s) (n : ℕ) : Bornology.IsBounded ((fun x ↦ x ^ n) '' s) := by induction n with \| zero => by_cases s_empty : s = ∅ · simp [s_empty] simp_rw [← nonempty_iff_ne_empty] at s_empty simp [s_empty] \| succ n hn => have obs : ((fun x ↦ x ^ (n + 1)) '' s) ⊆ ((fun x ↦ x ^ n) '' s) s := by intro x hx	Mathlib/Topology/Bornology/BoundedOperation.lean	105	117
/- 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.ModelTheory.Basic /-! # Language Maps Maps between first-order languages in the style of the [Flypitch project](https://flypitch.github.io/), as well as several important maps between structures. ## Main Definitions - A `FirstOrder.Language.LHom`, denoted `L →ᴸ L'`, is a map between languages, sending the symbols of one to symbols of the same kind and arity in the other. - A `FirstOrder.Language.LEquiv`, denoted `L ≃ᴸ L'`, is an invertible language homomorphism. - `FirstOrder.Language.withConstants` is defined so that if `M` is an `L.Structure` and `A : Set M`, `L.withConstants A`, denoted `L[[A]]`, is a language which adds constant symbols for elements of `A` to `L`. ## 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 u' v' w w' namespace FirstOrder namespace Language open Structure Cardinal open Cardinal variable (L : Language.{u, v}) (L' : Language.{u', v'}) {M : Type w} [L.Structure M] /-- A language homomorphism maps the symbols of one language to symbols of another. -/ structure LHom where /-- The mapping of functions -/ onFunction : ∀ ⦃n⦄, L.Functions n → L'.Functions n := by exact fun {n} => isEmptyElim /-- The mapping of relations -/ onRelation : ∀ ⦃n⦄, L.Relations n → L'.Relations n :=by exact fun {n} => isEmptyElim @[inherit_doc FirstOrder.Language.LHom] infixl:10 " →ᴸ " => LHom -- \^L variable {L L'} namespace LHom variable (ϕ : L →ᴸ L') /-- Pulls a structure back along a language map. -/ def reduct (M : Type*) [L'.Structure M] : L.Structure M where funMap f xs := funMap (ϕ.onFunction f) xs RelMap r xs := RelMap (ϕ.onRelation r) xs /-- The identity language homomorphism. -/ @[simps] protected def id (L : Language) : L →ᴸ L := ⟨fun _n => id, fun _n => id⟩ instance : Inhabited (L →ᴸ L) := ⟨LHom.id L⟩ /-- The inclusion of the left factor into the sum of two languages. -/ @[simps] protected def sumInl : L →ᴸ L.sum L' := ⟨fun _n => Sum.inl, fun _n => Sum.inl⟩ /-- The inclusion of the right factor into the sum of two languages. -/ @[simps] protected def sumInr : L' →ᴸ L.sum L' := ⟨fun _n => Sum.inr, fun _n => Sum.inr⟩ variable (L L') /-- The inclusion of an empty language into any other language. -/ @[simps] protected def ofIsEmpty [L.IsAlgebraic] [L.IsRelational] : L →ᴸ L' where variable {L L'} {L'' : Language} @[ext] protected theorem funext {F G : L →ᴸ L'} (h_fun : F.onFunction = G.onFunction) (h_rel : F.onRelation = G.onRelation) : F = G := by obtain ⟨Ff, Fr⟩ := F obtain ⟨Gf, Gr⟩ := G simp only [mk.injEq] exact And.intro h_fun h_rel instance [L.IsAlgebraic] [L.IsRelational] : Unique (L →ᴸ L') := ⟨⟨LHom.ofIsEmpty L L'⟩, fun _ => LHom.funext (Subsingleton.elim _ _) (Subsingleton.elim _ _)⟩ /-- The composition of two language homomorphisms. -/ @[simps] def comp (g : L' →ᴸ L'') (f : L →ᴸ L') : L →ᴸ L'' := ⟨fun _n F => g.1 (f.1 F), fun _ R => g.2 (f.2 R)⟩	-- added ᴸ to avoid clash with function composition @[inherit_doc] local infixl:60 " ∘ᴸ " => LHom.comp @[simp]	Mathlib/ModelTheory/LanguageMap.lean	113	118
/- Copyright (c) 2021 Aaron Anderson. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Aaron Anderson -/ import Mathlib.ModelTheory.Ultraproducts import Mathlib.ModelTheory.Bundled import Mathlib.ModelTheory.Skolem import Mathlib.Order.Filter.AtTopBot.Basic /-! # First-Order Satisfiability This file deals with the satisfiability of first-order theories, as well as equivalence over them. ## Main Definitions - `FirstOrder.Language.Theory.IsSatisfiable`: `T.IsSatisfiable` indicates that `T` has a nonempty model. - `FirstOrder.Language.Theory.IsFinitelySatisfiable`: `T.IsFinitelySatisfiable` indicates that every finite subset of `T` is satisfiable. - `FirstOrder.Language.Theory.IsComplete`: `T.IsComplete` indicates that `T` is satisfiable and models each sentence or its negation. - `Cardinal.Categorical`: A theory is `κ`-categorical if all models of size `κ` are isomorphic. ## Main Results - The Compactness Theorem, `FirstOrder.Language.Theory.isSatisfiable_iff_isFinitelySatisfiable`, shows that a theory is satisfiable iff it is finitely satisfiable. - `FirstOrder.Language.completeTheory.isComplete`: The complete theory of a structure is complete. - `FirstOrder.Language.Theory.exists_large_model_of_infinite_model` shows that any theory with an infinite model has arbitrarily large models. - `FirstOrder.Language.Theory.exists_elementaryEmbedding_card_eq`: The Upward Löwenheim–Skolem Theorem: If `κ` is a cardinal greater than the cardinalities of `L` and an infinite `L`-structure `M`, then `M` has an elementary extension of cardinality `κ`. ## Implementation Details - Satisfiability of an `L.Theory` `T` is defined in the minimal universe containing all the symbols of `L`. By Löwenheim-Skolem, this is equivalent to satisfiability in any universe. -/ universe u v w w' open Cardinal CategoryTheory open Cardinal FirstOrder namespace FirstOrder namespace Language variable {L : Language.{u, v}} {T : L.Theory} {α : Type w} {n : ℕ} namespace Theory variable (T) /-- A theory is satisfiable if a structure models it. -/ def IsSatisfiable : Prop := Nonempty (ModelType.{u, v, max u v} T) /-- A theory is finitely satisfiable if all of its finite subtheories are satisfiable. -/ def IsFinitelySatisfiable : Prop := ∀ T0 : Finset L.Sentence, (T0 : L.Theory) ⊆ T → IsSatisfiable (T0 : L.Theory) variable {T} {T' : L.Theory} theorem Model.isSatisfiable (M : Type w) [Nonempty M] [L.Structure M] [M ⊨ T] : T.IsSatisfiable := ⟨((⊥ : Substructure _ (ModelType.of T M)).elementarySkolem₁Reduct.toModel T).shrink⟩ theorem IsSatisfiable.mono (h : T'.IsSatisfiable) (hs : T ⊆ T') : T.IsSatisfiable := ⟨(Theory.Model.mono (ModelType.is_model h.some) hs).bundled⟩ theorem isSatisfiable_empty (L : Language.{u, v}) : IsSatisfiable (∅ : L.Theory) := ⟨default⟩ theorem isSatisfiable_of_isSatisfiable_onTheory {L' : Language.{w, w'}} (φ : L →ᴸ L') (h : (φ.onTheory T).IsSatisfiable) : T.IsSatisfiable := Model.isSatisfiable (h.some.reduct φ) theorem isSatisfiable_onTheory_iff {L' : Language.{w, w'}} {φ : L →ᴸ L'} (h : φ.Injective) : (φ.onTheory T).IsSatisfiable ↔ T.IsSatisfiable := by classical refine ⟨isSatisfiable_of_isSatisfiable_onTheory φ, fun h' => ?_⟩ haveI : Inhabited h'.some := Classical.inhabited_of_nonempty' exact Model.isSatisfiable (h'.some.defaultExpansion h) theorem IsSatisfiable.isFinitelySatisfiable (h : T.IsSatisfiable) : T.IsFinitelySatisfiable := fun _ => h.mono /-- The Compactness Theorem of first-order logic: A theory is satisfiable if and only if it is finitely satisfiable. -/ theorem isSatisfiable_iff_isFinitelySatisfiable {T : L.Theory} : T.IsSatisfiable ↔ T.IsFinitelySatisfiable := ⟨Theory.IsSatisfiable.isFinitelySatisfiable, fun h => by classical set M : Finset T → Type max u v := fun T0 : Finset T => (h (T0.map (Function.Embedding.subtype fun x => x ∈ T)) T0.map_subtype_subset).some.Carrier let M' := Filter.Product (Ultrafilter.of (Filter.atTop : Filter (Finset T))) M have h' : M' ⊨ T := by refine ⟨fun φ hφ => ?_⟩ rw [Ultraproduct.sentence_realize] refine Filter.Eventually.filter_mono (Ultrafilter.of_le _) (Filter.eventually_atTop.2 ⟨{⟨φ, hφ⟩}, fun s h' => Theory.realize_sentence_of_mem (s.map (Function.Embedding.subtype fun x => x ∈ T)) ?_⟩) simp only [Finset.coe_map, Function.Embedding.coe_subtype, Set.mem_image, Finset.mem_coe, Subtype.exists, Subtype.coe_mk, exists_and_right, exists_eq_right] exact ⟨hφ, h' (Finset.mem_singleton_self _)⟩ exact ⟨ModelType.of T M'⟩⟩ theorem isSatisfiable_directed_union_iff {ι : Type*} [Nonempty ι] {T : ι → L.Theory} (h : Directed (· ⊆ ·) T) : Theory.IsSatisfiable (⋃ i, T i) ↔ ∀ i, (T i).IsSatisfiable := by refine ⟨fun h' i => h'.mono (Set.subset_iUnion _ _), fun h' => ?_⟩ rw [isSatisfiable_iff_isFinitelySatisfiable, IsFinitelySatisfiable] intro T0 hT0 obtain ⟨i, hi⟩ := h.exists_mem_subset_of_finset_subset_biUnion hT0 exact (h' i).mono hi theorem isSatisfiable_union_distinctConstantsTheory_of_card_le (T : L.Theory) (s : Set α) (M : Type w') [Nonempty M] [L.Structure M] [M ⊨ T]	(h : Cardinal.lift.{w'} #s ≤ Cardinal.lift.{w} #M) : ((L.lhomWithConstants α).onTheory T ∪ L.distinctConstantsTheory s).IsSatisfiable := by haveI : Inhabited M := Classical.inhabited_of_nonempty inferInstance rw [Cardinal.lift_mk_le'] at h letI : (constantsOn α).Structure M := constantsOn.structure (Function.extend (↑) h.some default) have : M ⊨ (L.lhomWithConstants α).onTheory T ∪ L.distinctConstantsTheory s := by refine ((LHom.onTheory_model _ _).2 inferInstance).union ?_	Mathlib/ModelTheory/Satisfiability.lean	129	135
/- Copyright (c) 2022 Alex Kontorovich and Heather Macbeth. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Alex Kontorovich, Heather Macbeth -/ import Mathlib.Algebra.Group.Opposite import Mathlib.MeasureTheory.Constructions.Polish.Basic import Mathlib.MeasureTheory.Group.FundamentalDomain import Mathlib.MeasureTheory.Integral.DominatedConvergence import Mathlib.MeasureTheory.Measure.Haar.Basic /-! # Haar quotient measure In this file, we consider properties of fundamental domains and measures for the action of a subgroup `Γ` of a topological group `G` on `G` itself. Let `μ` be a measure on `G ⧸ Γ`. ## Main results * `MeasureTheory.QuotientMeasureEqMeasurePreimage.smulInvariantMeasure_quotient`: If `μ` satisfies `QuotientMeasureEqMeasurePreimage` relative to a both left- and right-invariant measure on `G`, then it is a `G` invariant measure on `G ⧸ Γ`. The next two results assume that `Γ` is normal, and that `G` is equipped with a left- and right-invariant measure. * `MeasureTheory.QuotientMeasureEqMeasurePreimage.mulInvariantMeasure_quotient`: If `μ` satisfies `QuotientMeasureEqMeasurePreimage`, then `μ` is a left-invariant measure. * `MeasureTheory.leftInvariantIsQuotientMeasureEqMeasurePreimage`: If `μ` is left-invariant, and the action of `Γ` on `G` has finite covolume, and `μ` satisfies the right scaling condition, then it satisfies `QuotientMeasureEqMeasurePreimage`. This is a converse to `MeasureTheory.QuotientMeasureEqMeasurePreimage.mulInvariantMeasure_quotient`. The last result assumes that `G` is locally compact, that `Γ` is countable and normal, that its action on `G` has a fundamental domain, and that `μ` is a finite measure. We also assume that `G` is equipped with a sigma-finite Haar measure. * `MeasureTheory.QuotientMeasureEqMeasurePreimage.haarMeasure_quotient`: If `μ` satisfies `QuotientMeasureEqMeasurePreimage`, then it is itself Haar. This is a variant of `MeasureTheory.QuotientMeasureEqMeasurePreimage.mulInvariantMeasure_quotient`. Note that a group `G` with Haar measure that is both left and right invariant is called unimodular. -/ open Set MeasureTheory TopologicalSpace MeasureTheory.Measure open scoped Pointwise NNReal ENNReal section /-- Measurability of the action of the topological group `G` on the left-coset space `G / Γ`. -/ @[to_additive "Measurability of the action of the additive topological group `G` on the left-coset space `G / Γ`."] instance QuotientGroup.measurableSMul {G : Type} [Group G] {Γ : Subgroup G} [MeasurableSpace G] [TopologicalSpace G] [IsTopologicalGroup G] [BorelSpace G] [BorelSpace (G ⧸ Γ)] : MeasurableSMul G (G ⧸ Γ) where measurable_const_smul g := (continuous_const_smul g).measurable measurable_smul_const _ := (continuous_id.smul continuous_const).measurable end section smulInvariantMeasure variable {G : Type} [Group G] [MeasurableSpace G] (ν : Measure G) {Γ : Subgroup G} {μ : Measure (G ⧸ Γ)} [QuotientMeasureEqMeasurePreimage ν μ] /-- Given a subgroup `Γ` of a topological group `G` with measure `ν`, and a measure 'μ' on the quotient `G ⧸ Γ` satisfying `QuotientMeasureEqMeasurePreimage`, the restriction of `ν` to a fundamental domain is measure-preserving with respect to `μ`. -/ @[to_additive] theorem measurePreserving_quotientGroup_mk_of_QuotientMeasureEqMeasurePreimage {𝓕 : Set G} (h𝓕 : IsFundamentalDomain Γ.op 𝓕 ν) (μ : Measure (G ⧸ Γ)) [QuotientMeasureEqMeasurePreimage ν μ] : MeasurePreserving (@QuotientGroup.mk G _ Γ) (ν.restrict 𝓕) μ := h𝓕.measurePreserving_quotient_mk μ local notation "π" => @QuotientGroup.mk G _ Γ variable [TopologicalSpace G] [IsTopologicalGroup G] [BorelSpace G] [PolishSpace G] [T2Space (G ⧸ Γ)] [SecondCountableTopology (G ⧸ Γ)] /-- If `μ` satisfies `QuotientMeasureEqMeasurePreimage` relative to a both left- and right- invariant measure `ν` on `G`, then it is a `G` invariant measure on `G ⧸ Γ`. -/ @[to_additive] lemma MeasureTheory.QuotientMeasureEqMeasurePreimage.smulInvariantMeasure_quotient [IsMulLeftInvariant ν] [hasFun : HasFundamentalDomain Γ.op G ν] : SMulInvariantMeasure G (G ⧸ Γ) μ where measure_preimage_smul g A hA := by have meas_π : Measurable π := continuous_quotient_mk'.measurable obtain ⟨𝓕, h𝓕⟩ := hasFun.ExistsIsFundamentalDomain have h𝓕_translate_fundom : IsFundamentalDomain Γ.op (g • 𝓕) ν := h𝓕.smul_of_comm g -- TODO: why `rw` fails with both of these rewrites? erw [h𝓕.projection_respects_measure_apply (μ := μ) (meas_π (measurableSet_preimage (measurable_const_smul g) hA)), h𝓕_translate_fundom.projection_respects_measure_apply (μ := μ) hA] change ν ((π ⁻¹' _) ∩ _) = ν ((π ⁻¹' _) ∩ _) set π_preA := π ⁻¹' A have : π ⁻¹' ((fun x : G ⧸ Γ => g • x) ⁻¹' A) = (g * ·) ⁻¹' π_preA := by ext1; simp [π_preA] rw [this] have : ν ((g * ·) ⁻¹' π_preA ∩ 𝓕) = ν (π_preA ∩ (g⁻¹ * ·) ⁻¹' 𝓕) := by trans ν ((g * ·) ⁻¹' (π_preA ∩ (g⁻¹ * ·) ⁻¹' 𝓕)) · rw [preimage_inter] congr 2 simp [Set.preimage] rw [measure_preimage_mul] rw [this, ← preimage_smul_inv]; rfl end smulInvariantMeasure section normal variable {G : Type} [Group G] [MeasurableSpace G] [TopologicalSpace G] [IsTopologicalGroup G] [BorelSpace G] [PolishSpace G] {Γ : Subgroup G} [Subgroup.Normal Γ] [T2Space (G ⧸ Γ)] [SecondCountableTopology (G ⧸ Γ)] {μ : Measure (G ⧸ Γ)} section mulInvariantMeasure variable (ν : Measure G) [IsMulLeftInvariant ν] /-- If `μ` on `G ⧸ Γ` satisfies `QuotientMeasureEqMeasurePreimage` relative to a both left- and right-invariant measure on `G` and `Γ` is a normal subgroup, then `μ` is a left-invariant measure. -/ @[to_additive "If `μ` on `G ⧸ Γ` satisfies `AddQuotientMeasureEqMeasurePreimage` relative to a both left- and right-invariant measure on `G` and `Γ` is a normal subgroup, then `μ` is a left-invariant measure."] lemma MeasureTheory.QuotientMeasureEqMeasurePreimage.mulInvariantMeasure_quotient [hasFun : HasFundamentalDomain Γ.op G ν] [QuotientMeasureEqMeasurePreimage ν μ] : μ.IsMulLeftInvariant where map_mul_left_eq_self x := by ext A hA obtain ⟨x₁, h⟩ := @Quotient.exists_rep _ (QuotientGroup.leftRel Γ) x convert measure_preimage_smul μ x₁ A using 1 · rw [← h, Measure.map_apply (measurable_const_mul _) hA] simp [← MulAction.Quotient.coe_smul_out, ← Quotient.mk''_eq_mk] exact smulInvariantMeasure_quotient ν variable [Countable Γ] [IsMulRightInvariant ν] [SigmaFinite ν] [IsMulLeftInvariant μ] [SigmaFinite μ] local notation "π" => @QuotientGroup.mk G _ Γ /-- Assume that a measure `μ` is `IsMulLeftInvariant`, that the action of `Γ` on `G` has a measurable fundamental domain `s` with positive finite volume, and that there is a single measurable set `V ⊆ G ⧸ Γ` along which the pullback of `μ` and `ν` agree (so the scaling is right). Then `μ` satisfies `QuotientMeasureEqMeasurePreimage`. The main tool of the proof is the uniqueness of left invariant measures, if normalized by a single positive finite-measured set. -/ @[to_additive "Assume that a measure `μ` is `IsAddLeftInvariant`, that the action of `Γ` on `G` has a measurable fundamental domain `s` with positive finite volume, and that there is a single measurable set `V ⊆ G ⧸ Γ` along which the pullback of `μ` and `ν` agree (so the scaling is right). Then `μ` satisfies `AddQuotientMeasureEqMeasurePreimage`. The main tool of the proof is the uniqueness of left invariant measures, if normalized by a single positive finite-measured set."] theorem MeasureTheory.Measure.IsMulLeftInvariant.quotientMeasureEqMeasurePreimage_of_set {s : Set G} (fund_dom_s : IsFundamentalDomain Γ.op s ν) {V : Set (G ⧸ Γ)} (meas_V : MeasurableSet V) (neZeroV : μ V ≠ 0) (hV : μ V = ν (π ⁻¹' V ∩ s)) (neTopV : μ V ≠ ⊤) : QuotientMeasureEqMeasurePreimage ν μ := by apply fund_dom_s.quotientMeasureEqMeasurePreimage ext U _ have meas_π : Measurable (QuotientGroup.mk : G → G ⧸ Γ) := continuous_quotient_mk'.measurable let μ' : Measure (G ⧸ Γ) := (ν.restrict s).map π haveI has_fund : HasFundamentalDomain Γ.op G ν := ⟨⟨s, fund_dom_s⟩⟩ have i : QuotientMeasureEqMeasurePreimage ν μ' := fund_dom_s.quotientMeasureEqMeasurePreimage_quotientMeasure have : μ'.IsMulLeftInvariant := MeasureTheory.QuotientMeasureEqMeasurePreimage.mulInvariantMeasure_quotient ν suffices μ = μ' by rw [this] rfl have : SigmaFinite μ' := i.sigmaFiniteQuotient rw [measure_eq_div_smul μ' μ neZeroV neTopV, hV] symm suffices (μ' V / ν (QuotientGroup.mk ⁻¹' V ∩ s)) = 1 by rw [this, one_smul] rw [Measure.map_apply meas_π meas_V, Measure.restrict_apply] · convert ENNReal.div_self .. · exact trans hV.symm neZeroV · exact trans hV.symm neTopV exact measurableSet_quotient.mp meas_V /-- If a measure `μ` is left-invariant and satisfies the right scaling condition, then it satisfies `QuotientMeasureEqMeasurePreimage`. -/ @[to_additive "If a measure `μ` is left-invariant and satisfies the right scaling condition, then it satisfies `AddQuotientMeasureEqMeasurePreimage`."] theorem MeasureTheory.leftInvariantIsQuotientMeasureEqMeasurePreimage [IsFiniteMeasure μ] [hasFun : HasFundamentalDomain Γ.op G ν] (h : covolume Γ.op G ν = μ univ) : QuotientMeasureEqMeasurePreimage ν μ := by obtain ⟨s, fund_dom_s⟩ := hasFun.ExistsIsFundamentalDomain have finiteCovol : μ univ < ⊤ := measure_lt_top μ univ rw [fund_dom_s.covolume_eq_volume] at h by_cases meas_s_ne_zero : ν s = 0 · convert fund_dom_s.quotientMeasureEqMeasurePreimage_of_zero meas_s_ne_zero rw [← @measure_univ_eq_zero, ← h, meas_s_ne_zero] apply IsMulLeftInvariant.quotientMeasureEqMeasurePreimage_of_set (fund_dom_s := fund_dom_s) (meas_V := MeasurableSet.univ) · rw [← h] exact meas_s_ne_zero · rw [← h] simp · rw [← h] convert finiteCovol.ne end mulInvariantMeasure section haarMeasure variable [Countable Γ] (ν : Measure G) [IsHaarMeasure ν] [IsMulRightInvariant ν] local notation "π" => @QuotientGroup.mk G _ Γ /-- If a measure `μ` on the quotient `G ⧸ Γ` of a group `G` by a discrete normal subgroup `Γ` having fundamental domain, satisfies `QuotientMeasureEqMeasurePreimage` relative to a standardized choice of Haar measure on `G`, and assuming `μ` is finite, then `μ` is itself Haar. TODO: Is it possible to drop the assumption that `μ` is finite? -/ @[to_additive "If a measure `μ` on the quotient `G ⧸ Γ` of an additive group `G` by a discrete normal subgroup `Γ` having fundamental domain, satisfies `AddQuotientMeasureEqMeasurePreimage` relative to a standardized choice of Haar measure on `G`, and assuming `μ` is finite, then `μ` is itself Haar."] theorem MeasureTheory.QuotientMeasureEqMeasurePreimage.haarMeasure_quotient [LocallyCompactSpace G] [QuotientMeasureEqMeasurePreimage ν μ] [i : HasFundamentalDomain Γ.op G ν] [IsFiniteMeasure μ] : IsHaarMeasure μ := by obtain ⟨K⟩ := PositiveCompacts.nonempty' (α := G) let K' : PositiveCompacts (G ⧸ Γ) := K.map π QuotientGroup.continuous_mk QuotientGroup.isOpenMap_coe haveI : IsMulLeftInvariant μ := MeasureTheory.QuotientMeasureEqMeasurePreimage.mulInvariantMeasure_quotient ν rw [haarMeasure_unique μ K'] have finiteCovol : covolume Γ.op G ν ≠ ⊤ := ne_top_of_lt <\| QuotientMeasureEqMeasurePreimage.covolume_ne_top μ (ν := ν) obtain ⟨s, fund_dom_s⟩ := i rw [fund_dom_s.covolume_eq_volume] at finiteCovol -- TODO: why `rw` fails? erw [fund_dom_s.projection_respects_measure_apply μ K'.isCompact.measurableSet] apply IsHaarMeasure.smul · intro h haveI i' : IsOpenPosMeasure (ν : Measure G) := inferInstance apply IsOpenPosMeasure.open_pos (interior K) (μ := ν) (self := i') · exact isOpen_interior · exact K.interior_nonempty rw [← le_zero_iff, ← fund_dom_s.measure_zero_of_invariant _ (fun g ↦ QuotientGroup.sound _ _ g) h] apply measure_mono refine interior_subset.trans ?_ rw [QuotientGroup.coe_mk'] show (K : Set G) ⊆ π ⁻¹' (π '' K) exact subset_preimage_image π K · show ν (π ⁻¹' (π '' K) ∩ s) ≠ ⊤ apply ne_of_lt refine lt_of_le_of_lt ?_ finiteCovol.lt_top apply measure_mono exact inter_subset_right variable [SigmaFinite ν] /-- Given a normal subgroup `Γ` of a topological group `G` with Haar measure `μ`, which is also right-invariant, and a finite volume fundamental domain `𝓕`, the quotient map to `G ⧸ Γ`, properly normalized, satisfies `QuotientMeasureEqMeasurePreimage`. -/ @[to_additive "Given a normal subgroup `Γ` of an additive topological group `G` with Haar measure `μ`, which is also right-invariant, and a finite volume fundamental domain `𝓕`, the quotient map to `G ⧸ Γ`, properly normalized, satisfies `AddQuotientMeasureEqMeasurePreimage`."] theorem IsFundamentalDomain.QuotientMeasureEqMeasurePreimage_HaarMeasure {𝓕 : Set G} (h𝓕 : IsFundamentalDomain Γ.op 𝓕 ν) [IsMulLeftInvariant μ] [SigmaFinite μ] {V : Set (G ⧸ Γ)} (hV : (interior V).Nonempty) (meas_V : MeasurableSet V) (hμK : μ V = ν ((π ⁻¹' V) ∩ 𝓕)) (neTopV : μ V ≠ ⊤) : QuotientMeasureEqMeasurePreimage ν μ := by apply IsMulLeftInvariant.quotientMeasureEqMeasurePreimage_of_set (fund_dom_s := h𝓕) (meas_V := meas_V) · rw [hμK] intro c_eq_zero apply IsOpenPosMeasure.open_pos (interior (π ⁻¹' V)) (μ := ν) · simp · apply Set.Nonempty.mono (preimage_interior_subset_interior_preimage continuous_coinduced_rng) apply hV.preimage' simp · apply measure_mono_null (h := interior_subset) apply h𝓕.measure_zero_of_invariant (ht := fun g ↦ QuotientGroup.sound _ _ g) exact c_eq_zero · exact hμK · exact neTopV variable (K : PositiveCompacts (G ⧸ Γ)) /-- Given a normal subgroup `Γ` of a topological group `G` with Haar measure `μ`, which is also right-invariant, and a finite volume fundamental domain `𝓕`, the quotient map to `G ⧸ Γ`, properly normalized, satisfies `QuotientMeasureEqMeasurePreimage`. -/ @[to_additive "Given a normal subgroup `Γ` of an additive topological group `G` with Haar measure `μ`, which is also right-invariant, and a finite volume fundamental domain `𝓕`, the quotient map to `G ⧸ Γ`, properly normalized, satisfies `AddQuotientMeasureEqMeasurePreimage`."] theorem IsFundamentalDomain.QuotientMeasureEqMeasurePreimage_smulHaarMeasure {𝓕 : Set G} (h𝓕 : IsFundamentalDomain Γ.op 𝓕 ν) (h𝓕_finite : ν 𝓕 ≠ ⊤) : QuotientMeasureEqMeasurePreimage ν ((ν ((π ⁻¹' (K : Set (G ⧸ Γ))) ∩ 𝓕)) • haarMeasure K) := by set c := ν ((π ⁻¹' (K : Set (G ⧸ Γ))) ∩ 𝓕) have c_ne_top : c ≠ ∞ := by contrapose! h𝓕_finite have : c ≤ ν 𝓕 := measure_mono (Set.inter_subset_right) rw [h𝓕_finite] at this exact top_unique this set μ := c • haarMeasure K have hμK : μ K = c := by simp [μ, haarMeasure_self] haveI : SigmaFinite μ := by clear_value c lift c to NNReal using c_ne_top exact SMul.sigmaFinite c apply IsFundamentalDomain.QuotientMeasureEqMeasurePreimage_HaarMeasure (h𝓕 := h𝓕) (meas_V := K.isCompact.measurableSet) (μ := μ) · exact K.interior_nonempty · exact hμK · rw [hμK] exact c_ne_top end haarMeasure end normal section UnfoldingTrick variable {G : Type} [Group G] [MeasurableSpace G] [TopologicalSpace G] [IsTopologicalGroup G] [BorelSpace G] {μ : Measure G} {Γ : Subgroup G} variable {𝓕 : Set G} (h𝓕 : IsFundamentalDomain Γ.op 𝓕 μ) include h𝓕 variable [Countable Γ] [MeasurableSpace (G ⧸ Γ)] [BorelSpace (G ⧸ Γ)] local notation "μ_𝓕" => Measure.map (@QuotientGroup.mk G _ Γ) (μ.restrict 𝓕) /-- The `essSup` of a function `g` on the quotient space `G ⧸ Γ` with respect to the pushforward	of the restriction, `μ_𝓕`, of a right-invariant measure `μ` to a fundamental domain `𝓕`, is the same as the `essSup` of `g`'s lift to the universal cover `G` with respect to `μ`. -/ @[to_additive "The `essSup` of a function `g` on the additive quotient space `G ⧸ Γ` with respect to the pushforward of the restriction, `μ_𝓕`, of a right-invariant measure `μ` to a fundamental domain `𝓕`, is the same as the `essSup` of `g`'s lift to the universal cover `G` with respect to `μ`."] lemma essSup_comp_quotientGroup_mk [μ.IsMulRightInvariant] {g : G ⧸ Γ → ℝ≥0∞} (g_ae_measurable : AEMeasurable g μ_𝓕) : essSup g μ_𝓕 = essSup (fun (x : G) ↦ g x) μ := by have hπ : Measurable (QuotientGroup.mk : G → G ⧸ Γ) := continuous_quotient_mk'.measurable rw [essSup_map_measure g_ae_measurable hπ.aemeasurable] refine h𝓕.essSup_measure_restrict ?_ intro ⟨γ, hγ⟩ x dsimp congr 1 exact QuotientGroup.mk_mul_of_mem x hγ	Mathlib/MeasureTheory/Measure/Haar/Quotient.lean	333	348
/- 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	Mathlib/SetTheory/Game/Nim.lean	59	64
/- Copyright (c) 2018 Chris Hughes. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Chris Hughes, Johannes Hölzl, Kim Morrison, Jens Wagemaker -/ import Mathlib.Algebra.Polynomial.Reverse import Mathlib.Algebra.Regular.SMul /-! # Theory of monic polynomials We give several tools for proving that polynomials are monic, e.g. `Monic.mul`, `Monic.map`, `Monic.pow`. -/ noncomputable section open Finset open Polynomial namespace Polynomial universe u v y variable {R : Type u} {S : Type v} {a b : R} {m n : ℕ} {ι : Type y} section Semiring variable [Semiring R] {p q r : R[X]} theorem monic_zero_iff_subsingleton : Monic (0 : R[X]) ↔ Subsingleton R := subsingleton_iff_zero_eq_one theorem not_monic_zero_iff : ¬Monic (0 : R[X]) ↔ (0 : R) ≠ 1 := (monic_zero_iff_subsingleton.trans subsingleton_iff_zero_eq_one.symm).not theorem monic_zero_iff_subsingleton' : Monic (0 : R[X]) ↔ (∀ f g : R[X], f = g) ∧ ∀ a b : R, a = b := Polynomial.monic_zero_iff_subsingleton.trans ⟨by intro simp [eq_iff_true_of_subsingleton], fun h => subsingleton_iff.mpr h.2⟩ theorem Monic.as_sum (hp : p.Monic) : p = X ^ p.natDegree + ∑ i ∈ range p.natDegree, C (p.coeff i) * X ^ i := by conv_lhs => rw [p.as_sum_range_C_mul_X_pow, sum_range_succ_comm] suffices C (p.coeff p.natDegree) = 1 by rw [this, one_mul] exact congr_arg C hp theorem ne_zero_of_ne_zero_of_monic (hp : p ≠ 0) (hq : Monic q) : q ≠ 0 := by rintro rfl rw [Monic.def, leadingCoeff_zero] at hq rw [← mul_one p, ← C_1, ← hq, C_0, mul_zero] at hp exact hp rfl theorem Monic.map [Semiring S] (f : R →+* S) (hp : Monic p) : Monic (p.map f) := by unfold Monic nontriviality have : f p.leadingCoeff ≠ 0 := by rw [show _ = _ from hp, f.map_one] exact one_ne_zero rw [Polynomial.leadingCoeff, coeff_map] suffices p.coeff (p.map f).natDegree = 1 by simp [this] rwa [natDegree_eq_of_degree_eq (degree_map_eq_of_leadingCoeff_ne_zero f this)] theorem monic_C_mul_of_mul_leadingCoeff_eq_one {b : R} (hp : b * p.leadingCoeff = 1) : Monic (C b * p) := by unfold Monic nontriviality rw [leadingCoeff_mul' _] <;> simp [leadingCoeff_C b, hp] theorem monic_mul_C_of_leadingCoeff_mul_eq_one {b : R} (hp : p.leadingCoeff * b = 1) : Monic (p * C b) := by unfold Monic nontriviality rw [leadingCoeff_mul' _] <;> simp [leadingCoeff_C b, hp] theorem monic_of_degree_le (n : ℕ) (H1 : degree p ≤ n) (H2 : coeff p n = 1) : Monic p := Decidable.byCases (fun H : degree p < n => eq_of_zero_eq_one (H2 ▸ (coeff_eq_zero_of_degree_lt H).symm) _ _) fun H : ¬degree p < n => by rwa [Monic, Polynomial.leadingCoeff, natDegree, (lt_or_eq_of_le H1).resolve_left H] theorem monic_X_pow_add {n : ℕ} (H : degree p < n) : Monic (X ^ n + p) := monic_of_degree_le n (le_trans (degree_add_le _ _) (max_le (degree_X_pow_le _) (le_of_lt H))) (by rw [coeff_add, coeff_X_pow, if_pos rfl, coeff_eq_zero_of_degree_lt H, add_zero]) variable (a) in theorem monic_X_pow_add_C {n : ℕ} (h : n ≠ 0) : (X ^ n + C a).Monic := monic_X_pow_add <\| (lt_of_le_of_lt degree_C_le (by simp only [Nat.cast_pos, Nat.pos_iff_ne_zero, ne_eq, h, not_false_eq_true])) theorem monic_X_add_C (x : R) : Monic (X + C x) := pow_one (X : R[X]) ▸ monic_X_pow_add_C x one_ne_zero theorem Monic.mul (hp : Monic p) (hq : Monic q) : Monic (p * q) := letI := Classical.decEq R if h0 : (0 : R) = 1 then haveI := subsingleton_of_zero_eq_one h0 Subsingleton.elim _ _ else by have : p.leadingCoeff * q.leadingCoeff ≠ 0 := by simp [Monic.def.1 hp, Monic.def.1 hq, Ne.symm h0] rw [Monic.def, leadingCoeff_mul' this, Monic.def.1 hp, Monic.def.1 hq, one_mul] theorem Monic.pow (hp : Monic p) : ∀ n : ℕ, Monic (p ^ n) \| 0 => monic_one \| n + 1 => by rw [pow_succ] exact (Monic.pow hp n).mul hp theorem Monic.add_of_left (hp : Monic p) (hpq : degree q < degree p) : Monic (p + q) := by rwa [Monic, add_comm, leadingCoeff_add_of_degree_lt hpq] theorem Monic.add_of_right (hq : Monic q) (hpq : degree p < degree q) : Monic (p + q) := by rwa [Monic, leadingCoeff_add_of_degree_lt hpq] theorem Monic.of_mul_monic_left (hp : p.Monic) (hpq : (p * q).Monic) : q.Monic := by contrapose! hpq rw [Monic.def] at hpq ⊢ rwa [leadingCoeff_monic_mul hp] theorem Monic.of_mul_monic_right (hq : q.Monic) (hpq : (p * q).Monic) : p.Monic := by contrapose! hpq rw [Monic.def] at hpq ⊢ rwa [leadingCoeff_mul_monic hq] namespace Monic lemma comp (hp : p.Monic) (hq : q.Monic) (h : q.natDegree ≠ 0) : (p.comp q).Monic := by nontriviality R have : (p.comp q).natDegree = p.natDegree * q.natDegree := natDegree_comp_eq_of_mul_ne_zero <\| by simp [hp.leadingCoeff, hq.leadingCoeff] rw [Monic.def, Polynomial.leadingCoeff, this, coeff_comp_degree_mul_degree h, hp.leadingCoeff, hq.leadingCoeff, one_pow, mul_one] lemma comp_X_add_C (hp : p.Monic) (r : R) : (p.comp (X + C r)).Monic := by nontriviality R refine hp.comp (monic_X_add_C _) fun ha ↦ ?_	rw [natDegree_X_add_C] at ha exact one_ne_zero ha @[simp]	Mathlib/Algebra/Polynomial/Monic.lean	143	146
/- Copyright (c) 2018 Mario Carneiro. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro, Johannes Hölzl -/ import Mathlib.MeasureTheory.Integral.Lebesgue.Basic import Mathlib.MeasureTheory.Integral.Lebesgue.Countable import Mathlib.MeasureTheory.Integral.Lebesgue.MeasurePreserving import Mathlib.MeasureTheory.Integral.Lebesgue.Norm deprecated_module (since := "2025-04-13")		Mathlib/MeasureTheory/Integral/Lebesgue.lean	2,023	2,026
/- Copyright (c) 2015, 2017 Jeremy Avigad. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jeremy Avigad, Robert Y. Lewis, Johannes Hölzl, Mario Carneiro, Sébastien Gouëzel -/ import Mathlib.Algebra.Order.BigOperators.Group.Finset import Mathlib.Order.Interval.Finset.Nat import Mathlib.Topology.EMetricSpace.Defs import Mathlib.Topology.UniformSpace.Compact import Mathlib.Topology.UniformSpace.LocallyUniformConvergence import Mathlib.Topology.UniformSpace.UniformEmbedding /-! # Extended metric spaces Further results about extended metric spaces. -/ open Set Filter universe u v w variable {α : Type u} {β : Type v} {X : Type} open scoped Uniformity Topology NNReal ENNReal Pointwise variable [PseudoEMetricSpace α] /-- The triangle (polygon) inequality for sequences of points; `Finset.Ico` version. -/ theorem edist_le_Ico_sum_edist (f : ℕ → α) {m n} (h : m ≤ n) : edist (f m) (f n) ≤ ∑ i ∈ Finset.Ico m n, edist (f i) (f (i + 1)) := by induction n, h using Nat.le_induction with \| base => rw [Finset.Ico_self, Finset.sum_empty, edist_self] \| succ n hle ihn => calc edist (f m) (f (n + 1)) ≤ edist (f m) (f n) + edist (f n) (f (n + 1)) := edist_triangle _ _ _ _ ≤ (∑ i ∈ Finset.Ico m n, _) + _ := add_le_add ihn le_rfl _ = ∑ i ∈ Finset.Ico m (n + 1), _ := by { rw [Nat.Ico_succ_right_eq_insert_Ico hle, Finset.sum_insert, add_comm]; simp } /-- The triangle (polygon) inequality for sequences of points; `Finset.range` version. -/ theorem edist_le_range_sum_edist (f : ℕ → α) (n : ℕ) : edist (f 0) (f n) ≤ ∑ i ∈ Finset.range n, edist (f i) (f (i + 1)) := Nat.Ico_zero_eq_range ▸ edist_le_Ico_sum_edist f (Nat.zero_le n) /-- A version of `edist_le_Ico_sum_edist` with each intermediate distance replaced with an upper estimate. -/ theorem edist_le_Ico_sum_of_edist_le {f : ℕ → α} {m n} (hmn : m ≤ n) {d : ℕ → ℝ≥0∞} (hd : ∀ {k}, m ≤ k → k < n → edist (f k) (f (k + 1)) ≤ d k) : edist (f m) (f n) ≤ ∑ i ∈ Finset.Ico m n, d i := le_trans (edist_le_Ico_sum_edist f hmn) <\| Finset.sum_le_sum fun _k hk => hd (Finset.mem_Ico.1 hk).1 (Finset.mem_Ico.1 hk).2 /-- A version of `edist_le_range_sum_edist` with each intermediate distance replaced with an upper estimate. -/ theorem edist_le_range_sum_of_edist_le {f : ℕ → α} (n : ℕ) {d : ℕ → ℝ≥0∞} (hd : ∀ {k}, k < n → edist (f k) (f (k + 1)) ≤ d k) : edist (f 0) (f n) ≤ ∑ i ∈ Finset.range n, d i := Nat.Ico_zero_eq_range ▸ edist_le_Ico_sum_of_edist_le (zero_le n) fun _ => hd namespace EMetric theorem isUniformInducing_iff [PseudoEMetricSpace β] {f : α → β} : IsUniformInducing f ↔ UniformContinuous f ∧ ∀ δ > 0, ∃ ε > 0, ∀ {a b : α}, edist (f a) (f b) < ε → edist a b < δ := isUniformInducing_iff'.trans <\| Iff.rfl.and <\| ((uniformity_basis_edist.comap _).le_basis_iff uniformity_basis_edist).trans <\| by simp only [subset_def, Prod.forall]; rfl /-- ε-δ characterization of uniform embeddings on pseudoemetric spaces -/ nonrec theorem isUniformEmbedding_iff [PseudoEMetricSpace β] {f : α → β} : IsUniformEmbedding f ↔ Function.Injective f ∧ UniformContinuous f ∧ ∀ δ > 0, ∃ ε > 0, ∀ {a b : α}, edist (f a) (f b) < ε → edist a b < δ := (isUniformEmbedding_iff _).trans <\| and_comm.trans <\| Iff.rfl.and isUniformInducing_iff /-- If a map between pseudoemetric spaces is a uniform embedding then the edistance between `f x` and `f y` is controlled in terms of the distance between `x` and `y`. In fact, this lemma holds for a `IsUniformInducing` map. TODO: generalize? -/ theorem controlled_of_isUniformEmbedding [PseudoEMetricSpace β] {f : α → β} (h : IsUniformEmbedding f) : (∀ ε > 0, ∃ δ > 0, ∀ {a b : α}, edist a b < δ → edist (f a) (f b) < ε) ∧ ∀ δ > 0, ∃ ε > 0, ∀ {a b : α}, edist (f a) (f b) < ε → edist a b < δ := ⟨uniformContinuous_iff.1 h.uniformContinuous, (isUniformEmbedding_iff.1 h).2.2⟩ /-- ε-δ characterization of Cauchy sequences on pseudoemetric spaces -/ protected theorem cauchy_iff {f : Filter α} : Cauchy f ↔ f ≠ ⊥ ∧ ∀ ε > 0, ∃ t ∈ f, ∀ x, x ∈ t → ∀ y, y ∈ t → edist x y < ε := by rw [← neBot_iff]; exact uniformity_basis_edist.cauchy_iff /-- A very useful criterion to show that a space is complete is to show that all sequences which satisfy a bound of the form `edist (u n) (u m) < B N` for all `n m ≥ N` are converging. This is often applied for `B N = 2^{-N}`, i.e., with a very fast convergence to `0`, which makes it possible to use arguments of converging series, while this is impossible to do in general for arbitrary Cauchy sequences. -/ theorem complete_of_convergent_controlled_sequences (B : ℕ → ℝ≥0∞) (hB : ∀ n, 0 < B n) (H : ∀ u : ℕ → α, (∀ N n m : ℕ, N ≤ n → N ≤ m → edist (u n) (u m) < B N) → ∃ x, Tendsto u atTop (𝓝 x)) : CompleteSpace α := UniformSpace.complete_of_convergent_controlled_sequences (fun n => { p : α × α \| edist p.1 p.2 < B n }) (fun n => edist_mem_uniformity <\| hB n) H /-- A sequentially complete pseudoemetric space is complete. -/ theorem complete_of_cauchySeq_tendsto : (∀ u : ℕ → α, CauchySeq u → ∃ a, Tendsto u atTop (𝓝 a)) → CompleteSpace α := UniformSpace.complete_of_cauchySeq_tendsto /-- Expressing locally uniform convergence on a set using `edist`. -/ theorem tendstoLocallyUniformlyOn_iff {ι : Type} [TopologicalSpace β] {F : ι → β → α} {f : β → α} {p : Filter ι} {s : Set β} : TendstoLocallyUniformlyOn F f p s ↔ ∀ ε > 0, ∀ x ∈ s, ∃ t ∈ 𝓝[s] x, ∀ᶠ n in p, ∀ y ∈ t, edist (f y) (F n y) < ε := by refine ⟨fun H ε hε => H _ (edist_mem_uniformity hε), fun H u hu x hx => ?_⟩ rcases mem_uniformity_edist.1 hu with ⟨ε, εpos, hε⟩ rcases H ε εpos x hx with ⟨t, ht, Ht⟩ exact ⟨t, ht, Ht.mono fun n hs x hx => hε (hs x hx)⟩ /-- Expressing uniform convergence on a set using `edist`. -/ theorem tendstoUniformlyOn_iff {ι : Type} {F : ι → β → α} {f : β → α} {p : Filter ι} {s : Set β} : TendstoUniformlyOn F f p s ↔ ∀ ε > 0, ∀ᶠ n in p, ∀ x ∈ s, edist (f x) (F n x) < ε := by refine ⟨fun H ε hε => H _ (edist_mem_uniformity hε), fun H u hu => ?_⟩ rcases mem_uniformity_edist.1 hu with ⟨ε, εpos, hε⟩ exact (H ε εpos).mono fun n hs x hx => hε (hs x hx) /-- Expressing locally uniform convergence using `edist`. -/ theorem tendstoLocallyUniformly_iff {ι : Type} [TopologicalSpace β] {F : ι → β → α} {f : β → α} {p : Filter ι} : TendstoLocallyUniformly F f p ↔ ∀ ε > 0, ∀ x : β, ∃ t ∈ 𝓝 x, ∀ᶠ n in p, ∀ y ∈ t, edist (f y) (F n y) < ε := by simp only [← tendstoLocallyUniformlyOn_univ, tendstoLocallyUniformlyOn_iff, mem_univ, forall_const, exists_prop, nhdsWithin_univ] /-- Expressing uniform convergence using `edist`. -/ theorem tendstoUniformly_iff {ι : Type} {F : ι → β → α} {f : β → α} {p : Filter ι} : TendstoUniformly F f p ↔ ∀ ε > 0, ∀ᶠ n in p, ∀ x, edist (f x) (F n x) < ε := by simp only [← tendstoUniformlyOn_univ, tendstoUniformlyOn_iff, mem_univ, forall_const] end EMetric open EMetric namespace EMetric variable {x y z : α} {ε ε₁ ε₂ : ℝ≥0∞} {s t : Set α} theorem inseparable_iff : Inseparable x y ↔ edist x y = 0 := by simp [inseparable_iff_mem_closure, mem_closure_iff, edist_comm, forall_lt_iff_le'] alias ⟨_root_.Inseparable.edist_eq_zero, _⟩ := EMetric.inseparable_iff -- see Note [nolint_ge] /-- In a pseudoemetric space, Cauchy sequences are characterized by the fact that, eventually, the pseudoedistance between its elements is arbitrarily small -/ theorem cauchySeq_iff [Nonempty β] [SemilatticeSup β] {u : β → α} : CauchySeq u ↔ ∀ ε > 0, ∃ N, ∀ m, N ≤ m → ∀ n, N ≤ n → edist (u m) (u n) < ε := uniformity_basis_edist.cauchySeq_iff /-- A variation around the emetric characterization of Cauchy sequences -/ theorem cauchySeq_iff' [Nonempty β] [SemilatticeSup β] {u : β → α} : CauchySeq u ↔ ∀ ε > (0 : ℝ≥0∞), ∃ N, ∀ n ≥ N, edist (u n) (u N) < ε := uniformity_basis_edist.cauchySeq_iff' /-- A variation of the emetric characterization of Cauchy sequences that deals with `ℝ≥0` upper bounds. -/ theorem cauchySeq_iff_NNReal [Nonempty β] [SemilatticeSup β] {u : β → α} : CauchySeq u ↔ ∀ ε : ℝ≥0, 0 < ε → ∃ N, ∀ n, N ≤ n → edist (u n) (u N) < ε := uniformity_basis_edist_nnreal.cauchySeq_iff' theorem totallyBounded_iff {s : Set α} : TotallyBounded s ↔ ∀ ε > 0, ∃ t : Set α, t.Finite ∧ s ⊆ ⋃ y ∈ t, ball y ε := ⟨fun H _ε ε0 => H _ (edist_mem_uniformity ε0), fun H _r ru => let ⟨ε, ε0, hε⟩ := mem_uniformity_edist.1 ru let ⟨t, ft, h⟩ := H ε ε0 ⟨t, ft, h.trans <\| iUnion₂_mono fun _ _ _ => hε⟩⟩ theorem totallyBounded_iff' {s : Set α} : TotallyBounded s ↔ ∀ ε > 0, ∃ t, t ⊆ s ∧ Set.Finite t ∧ s ⊆ ⋃ y ∈ t, ball y ε := ⟨fun H _ε ε0 => (totallyBounded_iff_subset.1 H) _ (edist_mem_uniformity ε0), fun H _r ru => let ⟨ε, ε0, hε⟩ := mem_uniformity_edist.1 ru let ⟨t, _, ft, h⟩ := H ε ε0 ⟨t, ft, h.trans <\| iUnion₂_mono fun _ _ _ => hε⟩⟩ section Compact -- TODO: generalize to metrizable spaces /-- A compact set in a pseudo emetric space is separable, i.e., it is a subset of the closure of a countable set. -/ theorem subset_countable_closure_of_compact {s : Set α} (hs : IsCompact s) : ∃ t, t ⊆ s ∧ t.Countable ∧ s ⊆ closure t := by refine subset_countable_closure_of_almost_dense_set s fun ε hε => ?_ rcases totallyBounded_iff'.1 hs.totallyBounded ε hε with ⟨t, -, htf, hst⟩ exact ⟨t, htf.countable, hst.trans <\| iUnion₂_mono fun _ _ => ball_subset_closedBall⟩ end Compact section SecondCountable open TopologicalSpace variable (α) in /-- A sigma compact pseudo emetric space has second countable topology. -/ instance (priority := 90) secondCountable_of_sigmaCompact [SigmaCompactSpace α] : SecondCountableTopology α := by suffices SeparableSpace α by exact UniformSpace.secondCountable_of_separable α choose T _ hTc hsubT using fun n => subset_countable_closure_of_compact (isCompact_compactCovering α n) refine ⟨⟨⋃ n, T n, countable_iUnion hTc, fun x => ?_⟩⟩ rcases iUnion_eq_univ_iff.1 (iUnion_compactCovering α) x with ⟨n, hn⟩ exact closure_mono (subset_iUnion _ n) (hsubT _ hn) theorem secondCountable_of_almost_dense_set (hs : ∀ ε > 0, ∃ t : Set α, t.Countable ∧ ⋃ x ∈ t, closedBall x ε = univ) : SecondCountableTopology α := by suffices SeparableSpace α from UniformSpace.secondCountable_of_separable α have : ∀ ε > 0, ∃ t : Set α, Set.Countable t ∧ univ ⊆ ⋃ x ∈ t, closedBall x ε := by simpa only [univ_subset_iff] using hs rcases subset_countable_closure_of_almost_dense_set (univ : Set α) this with ⟨t, -, htc, ht⟩ exact ⟨⟨t, htc, fun x => ht (mem_univ x)⟩⟩ end SecondCountable end EMetric variable {γ : Type w} [EMetricSpace γ] -- see Note [lower instance priority] /-- An emetric space is separated -/ instance (priority := 100) EMetricSpace.instT0Space : T0Space γ where t0 _ _ h := eq_of_edist_eq_zero <\| inseparable_iff.1 h /-- A map between emetric spaces is a uniform embedding if and only if the edistance between `f x` and `f y` is controlled in terms of the distance between `x` and `y` and conversely. -/ theorem EMetric.isUniformEmbedding_iff' [PseudoEMetricSpace β] {f : γ → β} : IsUniformEmbedding f ↔ (∀ ε > 0, ∃ δ > 0, ∀ {a b : γ}, edist a b < δ → edist (f a) (f b) < ε) ∧ ∀ δ > 0, ∃ ε > 0, ∀ {a b : γ}, edist (f a) (f b) < ε → edist a b < δ := by rw [isUniformEmbedding_iff_isUniformInducing, isUniformInducing_iff, uniformContinuous_iff] /-- If a `PseudoEMetricSpace` is a T₀ space, then it is an `EMetricSpace`. -/ -- TODO: make it an instance? abbrev EMetricSpace.ofT0PseudoEMetricSpace (α : Type) [PseudoEMetricSpace α] [T0Space α] : EMetricSpace α := { ‹PseudoEMetricSpace α› with eq_of_edist_eq_zero := fun h => (EMetric.inseparable_iff.2 h).eq } /-- The product of two emetric spaces, with the max distance, is an extended metric spaces. We make sure that the uniform structure thus constructed is the one corresponding to the product of uniform spaces, to avoid diamond problems. -/ instance Prod.emetricSpaceMax [EMetricSpace β] : EMetricSpace (γ × β) := .ofT0PseudoEMetricSpace _ namespace EMetric /-- A compact set in an emetric space is separable, i.e., it is the closure of a countable set. -/ theorem countable_closure_of_compact {s : Set γ} (hs : IsCompact s) : ∃ t, t ⊆ s ∧ t.Countable ∧ s = closure t := by rcases subset_countable_closure_of_compact hs with ⟨t, hts, htc, hsub⟩ exact ⟨t, hts, htc, hsub.antisymm (closure_minimal hts hs.isClosed)⟩ end EMetric /-! ### Separation quotient -/ instance [PseudoEMetricSpace X] : EDist (SeparationQuotient X) where edist := SeparationQuotient.lift₂ edist fun _ _ _ _ hx hy => edist_congr (EMetric.inseparable_iff.1 hx) (EMetric.inseparable_iff.1 hy) @[simp] theorem SeparationQuotient.edist_mk [PseudoEMetricSpace X] (x y : X) : edist (mk x) (mk y) = edist x y := rfl open SeparationQuotient in instance [PseudoEMetricSpace X] : EMetricSpace (SeparationQuotient X) := @EMetricSpace.ofT0PseudoEMetricSpace (SeparationQuotient X) { edist_self := surjective_mk.forall.2 edist_self, edist_comm := surjective_mk.forall₂.2 edist_comm, edist_triangle := surjective_mk.forall₃.2 edist_triangle, toUniformSpace := inferInstance, uniformity_edist := comap_injective (surjective_mk.prodMap surjective_mk) <\| by simp [comap_mk_uniformity, PseudoEMetricSpace.uniformity_edist] } _ namespace TopologicalSpace section Compact open Topology /-- If a set `s` is separable in a (pseudo extended) metric space, then it admits a countable dense subset. This is not obvious, as the countable set whose closure covers `s` given by the definition of separability does not need in general to be contained in `s`. -/ theorem IsSeparable.exists_countable_dense_subset {s : Set α} (hs : IsSeparable s) : ∃ t, t ⊆ s ∧ t.Countable ∧ s ⊆ closure t := by have : ∀ ε > 0, ∃ t : Set α, t.Countable ∧ s ⊆ ⋃ x ∈ t, closedBall x ε := fun ε ε0 => by rcases hs with ⟨t, htc, hst⟩ refine ⟨t, htc, hst.trans fun x hx => ?_⟩ rcases mem_closure_iff.1 hx ε ε0 with ⟨y, hyt, hxy⟩ exact mem_iUnion₂.2 ⟨y, hyt, mem_closedBall.2 hxy.le⟩ exact subset_countable_closure_of_almost_dense_set _ this /-- If a set `s` is separable, then the corresponding subtype is separable in a (pseudo extended) metric space. This is not obvious, as the countable set whose closure covers `s` does not need in general to be contained in `s`. -/ theorem IsSeparable.separableSpace {s : Set α} (hs : IsSeparable s) : SeparableSpace s := by rcases hs.exists_countable_dense_subset with ⟨t, hts, htc, hst⟩ lift t to Set s using hts refine ⟨⟨t, countable_of_injective_of_countable_image Subtype.coe_injective.injOn htc, ?_⟩⟩ rwa [IsInducing.subtypeVal.dense_iff, Subtype.forall] end Compact end TopologicalSpace section LebesgueNumberLemma variable {s : Set α} theorem lebesgue_number_lemma_of_emetric {ι : Sort*} {c : ι → Set α} (hs : IsCompact s) (hc₁ : ∀ i, IsOpen (c i)) (hc₂ : s ⊆ ⋃ i, c i) : ∃ δ > 0, ∀ x ∈ s, ∃ i, ball x δ ⊆ c i := by simpa only [ball, UniformSpace.ball, preimage_setOf_eq, edist_comm] using uniformity_basis_edist.lebesgue_number_lemma hs hc₁ hc₂ theorem lebesgue_number_lemma_of_emetric_nhds' {c : (x : α) → x ∈ s → Set α} (hs : IsCompact s) (hc : ∀ x hx, c x hx ∈ 𝓝 x) : ∃ δ > 0, ∀ x ∈ s, ∃ y : s, ball x δ ⊆ c y y.2 := by simpa only [ball, UniformSpace.ball, preimage_setOf_eq, edist_comm] using uniformity_basis_edist.lebesgue_number_lemma_nhds' hs hc theorem lebesgue_number_lemma_of_emetric_nhds {c : α → Set α} (hs : IsCompact s) (hc : ∀ x ∈ s, c x ∈ 𝓝 x) : ∃ δ > 0, ∀ x ∈ s, ∃ y, ball x δ ⊆ c y := by simpa only [ball, UniformSpace.ball, preimage_setOf_eq, edist_comm] using uniformity_basis_edist.lebesgue_number_lemma_nhds hs hc theorem lebesgue_number_lemma_of_emetric_nhdsWithin' {c : (x : α) → x ∈ s → Set α} (hs : IsCompact s) (hc : ∀ x hx, c x hx ∈ 𝓝[s] x) : ∃ δ > 0, ∀ x ∈ s, ∃ y : s, ball x δ ∩ s ⊆ c y y.2 := by simpa only [ball, UniformSpace.ball, preimage_setOf_eq, edist_comm] using uniformity_basis_edist.lebesgue_number_lemma_nhdsWithin' hs hc theorem lebesgue_number_lemma_of_emetric_nhdsWithin {c : α → Set α} (hs : IsCompact s) (hc : ∀ x ∈ s, c x ∈ 𝓝[s] x) : ∃ δ > 0, ∀ x ∈ s, ∃ y, ball x δ ∩ s ⊆ c y := by simpa only [ball, UniformSpace.ball, preimage_setOf_eq, edist_comm] using uniformity_basis_edist.lebesgue_number_lemma_nhdsWithin hs hc theorem lebesgue_number_lemma_of_emetric_sUnion {c : Set (Set α)} (hs : IsCompact s) (hc₁ : ∀ t ∈ c, IsOpen t) (hc₂ : s ⊆ ⋃₀ c) : ∃ δ > 0, ∀ x ∈ s, ∃ t ∈ c, ball x δ ⊆ t := by rw [sUnion_eq_iUnion] at hc₂; simpa using lebesgue_number_lemma_of_emetric hs (by simpa) hc₂ end LebesgueNumberLemma		Mathlib/Topology/EMetricSpace/Basic.lean	976	994
/- 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. -/	Mathlib/Geometry/Euclidean/Angle/Oriented/Affine.lean	49	55
/- Copyright (c) 2022 Yaël Dillies. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yaël Dillies -/ import Mathlib.Data.Finset.Lattice.Prod import Mathlib.Data.Finite.Prod import Mathlib.Data.Set.Lattice.Image /-! # N-ary images of finsets This file defines `Finset.image₂`, the binary image of finsets. This is the finset version of `Set.image2`. This is mostly useful to define pointwise operations. ## Notes This file is very similar to `Data.Set.NAry`, `Order.Filter.NAry` and `Data.Option.NAry`. Please keep them in sync. We do not define `Finset.image₃` as its only purpose would be to prove properties of `Finset.image₂` and `Set.image2` already fulfills this task. -/ open Function Set variable {α α' β β' γ γ' δ δ' ε ε' ζ ζ' ν : Type} namespace Finset variable [DecidableEq α'] [DecidableEq β'] [DecidableEq γ] [DecidableEq γ'] [DecidableEq δ'] [DecidableEq ε] [DecidableEq ε'] {f f' : α → β → γ} {g g' : α → β → γ → δ} {s s' : Finset α} {t t' : Finset β} {u u' : Finset γ} {a a' : α} {b b' : β} {c : γ} /-- The image of a binary function `f : α → β → γ` as a function `Finset α → Finset β → Finset γ`. Mathematically this should be thought of as the image of the corresponding function `α × β → γ`. -/ def image₂ (f : α → β → γ) (s : Finset α) (t : Finset β) : Finset γ := (s ×ˢ t).image <\| uncurry f @[simp] theorem mem_image₂ : c ∈ image₂ f s t ↔ ∃ a ∈ s, ∃ b ∈ t, f a b = c := by simp [image₂, and_assoc] @[simp, norm_cast] theorem coe_image₂ (f : α → β → γ) (s : Finset α) (t : Finset β) : (image₂ f s t : Set γ) = Set.image2 f s t := Set.ext fun _ => mem_image₂ theorem card_image₂_le (f : α → β → γ) (s : Finset α) (t : Finset β) : #(image₂ f s t) ≤ #s #t := card_image_le.trans_eq <\| card_product _ _ theorem card_image₂_iff : #(image₂ f s t) = #s * #t ↔ (s ×ˢ t : Set (α × β)).InjOn fun x => f x.1 x.2 := by rw [← card_product, ← coe_product] exact card_image_iff theorem card_image₂ (hf : Injective2 f) (s : Finset α) (t : Finset β) : #(image₂ f s t) = #s * #t := (card_image_of_injective _ hf.uncurry).trans <\| card_product _ _ theorem mem_image₂_of_mem (ha : a ∈ s) (hb : b ∈ t) : f a b ∈ image₂ f s t := mem_image₂.2 ⟨a, ha, b, hb, rfl⟩ theorem mem_image₂_iff (hf : Injective2 f) : f a b ∈ image₂ f s t ↔ a ∈ s ∧ b ∈ t := by rw [← mem_coe, coe_image₂, mem_image2_iff hf, mem_coe, mem_coe] @[gcongr] theorem image₂_subset (hs : s ⊆ s') (ht : t ⊆ t') : image₂ f s t ⊆ image₂ f s' t' := by rw [← coe_subset, coe_image₂, coe_image₂] exact image2_subset hs ht @[gcongr] theorem image₂_subset_left (ht : t ⊆ t') : image₂ f s t ⊆ image₂ f s t' := image₂_subset Subset.rfl ht @[gcongr] theorem image₂_subset_right (hs : s ⊆ s') : image₂ f s t ⊆ image₂ f s' t := image₂_subset hs Subset.rfl theorem image_subset_image₂_left (hb : b ∈ t) : s.image (fun a => f a b) ⊆ image₂ f s t := image_subset_iff.2 fun _ ha => mem_image₂_of_mem ha hb theorem image_subset_image₂_right (ha : a ∈ s) : t.image (fun b => f a b) ⊆ image₂ f s t := image_subset_iff.2 fun _ => mem_image₂_of_mem ha lemma forall_mem_image₂ {p : γ → Prop} : (∀ z ∈ image₂ f s t, p z) ↔ ∀ x ∈ s, ∀ y ∈ t, p (f x y) := by simp_rw [← mem_coe, coe_image₂, forall_mem_image2] lemma exists_mem_image₂ {p : γ → Prop} : (∃ z ∈ image₂ f s t, p z) ↔ ∃ x ∈ s, ∃ y ∈ t, p (f x y) := by simp_rw [← mem_coe, coe_image₂, exists_mem_image2] @[deprecated (since := "2024-11-23")] alias forall_image₂_iff := forall_mem_image₂ @[simp] theorem image₂_subset_iff : image₂ f s t ⊆ u ↔ ∀ x ∈ s, ∀ y ∈ t, f x y ∈ u := forall_mem_image₂ theorem image₂_subset_iff_left : image₂ f s t ⊆ u ↔ ∀ a ∈ s, (t.image fun b => f a b) ⊆ u := by simp_rw [image₂_subset_iff, image_subset_iff] theorem image₂_subset_iff_right : image₂ f s t ⊆ u ↔ ∀ b ∈ t, (s.image fun a => f a b) ⊆ u := by simp_rw [image₂_subset_iff, image_subset_iff, @forall₂_swap α] @[simp] theorem image₂_nonempty_iff : (image₂ f s t).Nonempty ↔ s.Nonempty ∧ t.Nonempty := by rw [← coe_nonempty, coe_image₂] exact image2_nonempty_iff @[aesop safe apply (rule_sets := [finsetNonempty])] theorem Nonempty.image₂ (hs : s.Nonempty) (ht : t.Nonempty) : (image₂ f s t).Nonempty := image₂_nonempty_iff.2 ⟨hs, ht⟩ theorem Nonempty.of_image₂_left (h : (s.image₂ f t).Nonempty) : s.Nonempty := (image₂_nonempty_iff.1 h).1 theorem Nonempty.of_image₂_right (h : (s.image₂ f t).Nonempty) : t.Nonempty := (image₂_nonempty_iff.1 h).2 @[simp] theorem image₂_empty_left : image₂ f ∅ t = ∅ := coe_injective <\| by simp @[simp] theorem image₂_empty_right : image₂ f s ∅ = ∅ := coe_injective <\| by simp @[simp] theorem image₂_eq_empty_iff : image₂ f s t = ∅ ↔ s = ∅ ∨ t = ∅ := by simp_rw [← not_nonempty_iff_eq_empty, image₂_nonempty_iff, not_and_or] @[simp] theorem image₂_singleton_left : image₂ f {a} t = t.image fun b => f a b := ext fun x => by simp @[simp] theorem image₂_singleton_right : image₂ f s {b} = s.image fun a => f a b := ext fun x => by simp theorem image₂_singleton_left' : image₂ f {a} t = t.image (f a) := image₂_singleton_left theorem image₂_singleton : image₂ f {a} {b} = {f a b} := by simp theorem image₂_union_left [DecidableEq α] : image₂ f (s ∪ s') t = image₂ f s t ∪ image₂ f s' t := coe_injective <\| by push_cast exact image2_union_left theorem image₂_union_right [DecidableEq β] : image₂ f s (t ∪ t') = image₂ f s t ∪ image₂ f s t' := coe_injective <\| by push_cast exact image2_union_right @[simp] theorem image₂_insert_left [DecidableEq α] : image₂ f (insert a s) t = (t.image fun b => f a b) ∪ image₂ f s t := coe_injective <\| by push_cast exact image2_insert_left @[simp] theorem image₂_insert_right [DecidableEq β] : image₂ f s (insert b t) = (s.image fun a => f a b) ∪ image₂ f s t := coe_injective <\| by push_cast exact image2_insert_right theorem image₂_inter_left [DecidableEq α] (hf : Injective2 f) : image₂ f (s ∩ s') t = image₂ f s t ∩ image₂ f s' t := coe_injective <\| by push_cast exact image2_inter_left hf theorem image₂_inter_right [DecidableEq β] (hf : Injective2 f) : image₂ f s (t ∩ t') = image₂ f s t ∩ image₂ f s t' := coe_injective <\| by push_cast exact image2_inter_right hf theorem image₂_inter_subset_left [DecidableEq α] : image₂ f (s ∩ s') t ⊆ image₂ f s t ∩ image₂ f s' t := coe_subset.1 <\| by push_cast exact image2_inter_subset_left theorem image₂_inter_subset_right [DecidableEq β] : image₂ f s (t ∩ t') ⊆ image₂ f s t ∩ image₂ f s t' := coe_subset.1 <\| by push_cast exact image2_inter_subset_right theorem image₂_congr (h : ∀ a ∈ s, ∀ b ∈ t, f a b = f' a b) : image₂ f s t = image₂ f' s t := coe_injective <\| by push_cast exact image2_congr h /-- A common special case of `image₂_congr` -/ theorem image₂_congr' (h : ∀ a b, f a b = f' a b) : image₂ f s t = image₂ f' s t := image₂_congr fun a _ b _ => h a b variable (s t) theorem card_image₂_singleton_left (hf : Injective (f a)) : #(image₂ f {a} t) = #t := by rw [image₂_singleton_left, card_image_of_injective _ hf] theorem card_image₂_singleton_right (hf : Injective fun a => f a b) : #(image₂ f s {b}) = #s := by rw [image₂_singleton_right, card_image_of_injective _ hf] theorem image₂_singleton_inter [DecidableEq β] (t₁ t₂ : Finset β) (hf : Injective (f a)) : image₂ f {a} (t₁ ∩ t₂) = image₂ f {a} t₁ ∩ image₂ f {a} t₂ := by simp_rw [image₂_singleton_left, image_inter _ _ hf] theorem image₂_inter_singleton [DecidableEq α] (s₁ s₂ : Finset α) (hf : Injective fun a => f a b) : image₂ f (s₁ ∩ s₂) {b} = image₂ f s₁ {b} ∩ image₂ f s₂ {b} := by simp_rw [image₂_singleton_right, image_inter _ _ hf] theorem card_le_card_image₂_left {s : Finset α} (hs : s.Nonempty) (hf : ∀ a, Injective (f a)) : #t ≤ #(image₂ f s t) := by obtain ⟨a, ha⟩ := hs rw [← card_image₂_singleton_left _ (hf a)] exact card_le_card (image₂_subset_right <\| singleton_subset_iff.2 ha) theorem card_le_card_image₂_right {t : Finset β} (ht : t.Nonempty) (hf : ∀ b, Injective fun a => f a b) : #s ≤ #(image₂ f s t) := by obtain ⟨b, hb⟩ := ht rw [← card_image₂_singleton_right _ (hf b)] exact card_le_card (image₂_subset_left <\| singleton_subset_iff.2 hb) variable {s t} theorem biUnion_image_left : (s.biUnion fun a => t.image <\| f a) = image₂ f s t := coe_injective <\| by push_cast exact Set.iUnion_image_left _ theorem biUnion_image_right : (t.biUnion fun b => s.image fun a => f a b) = image₂ f s t := coe_injective <\| by push_cast exact Set.iUnion_image_right _ /-! ### Algebraic replacement rules A collection of lemmas to transfer associativity, commutativity, distributivity, ... of operations to the associativity, commutativity, distributivity, ... of `Finset.image₂` of those operations. The proof pattern is `image₂_lemma operation_lemma`. For example, `image₂_comm mul_comm` proves that `image₂ () f g = image₂ () g f` in a `CommSemigroup`. -/ section variable [DecidableEq δ] theorem image_image₂ (f : α → β → γ) (g : γ → δ) : (image₂ f s t).image g = image₂ (fun a b => g (f a b)) s t := coe_injective <\| by push_cast exact image_image2 _ _ theorem image₂_image_left (f : γ → β → δ) (g : α → γ) : image₂ f (s.image g) t = image₂ (fun a b => f (g a) b) s t := coe_injective <\| by push_cast exact image2_image_left _ _ theorem image₂_image_right (f : α → γ → δ) (g : β → γ) : image₂ f s (t.image g) = image₂ (fun a b => f a (g b)) s t := coe_injective <\| by push_cast exact image2_image_right _ _ @[simp] theorem image₂_mk_eq_product [DecidableEq α] [DecidableEq β] (s : Finset α) (t : Finset β) : image₂ Prod.mk s t = s ×ˢ t := by ext; simp [Prod.ext_iff] @[simp] theorem image₂_curry (f : α × β → γ) (s : Finset α) (t : Finset β) : image₂ (curry f) s t = (s ×ˢ t).image f := rfl @[simp] theorem image_uncurry_product (f : α → β → γ) (s : Finset α) (t : Finset β) : (s ×ˢ t).image (uncurry f) = image₂ f s t := rfl theorem image₂_swap (f : α → β → γ) (s : Finset α) (t : Finset β) : image₂ f s t = image₂ (fun a b => f b a) t s := coe_injective <\| by push_cast exact image2_swap _ _ _ @[simp] theorem image₂_left [DecidableEq α] (h : t.Nonempty) : image₂ (fun x _ => x) s t = s := coe_injective <\| by push_cast exact image2_left h @[simp] theorem image₂_right [DecidableEq β] (h : s.Nonempty) : image₂ (fun _ y => y) s t = t := coe_injective <\| by push_cast exact image2_right h theorem image₂_assoc {γ : Type} {u : Finset γ} {f : δ → γ → ε} {g : α → β → δ} {f' : α → ε' → ε} {g' : β → γ → ε'} (h_assoc : ∀ a b c, f (g a b) c = f' a (g' b c)) : image₂ f (image₂ g s t) u = image₂ f' s (image₂ g' t u) := coe_injective <\| by push_cast exact image2_assoc h_assoc theorem image₂_comm {g : β → α → γ} (h_comm : ∀ a b, f a b = g b a) : image₂ f s t = image₂ g t s := (image₂_swap _ _ _).trans <\| by simp_rw [h_comm] theorem image₂_left_comm {γ : Type} {u : Finset γ} {f : α → δ → ε} {g : β → γ → δ} {f' : α → γ → δ'} {g' : β → δ' → ε} (h_left_comm : ∀ a b c, f a (g b c) = g' b (f' a c)) : image₂ f s (image₂ g t u) = image₂ g' t (image₂ f' s u) := coe_injective <\| by push_cast exact image2_left_comm h_left_comm theorem image₂_right_comm {γ : Type} {u : Finset γ} {f : δ → γ → ε} {g : α → β → δ} {f' : α → γ → δ'} {g' : δ' → β → ε} (h_right_comm : ∀ a b c, f (g a b) c = g' (f' a c) b) : image₂ f (image₂ g s t) u = image₂ g' (image₂ f' s u) t := coe_injective <\| by push_cast exact image2_right_comm h_right_comm theorem image₂_image₂_image₂_comm {γ δ : Type} {u : Finset γ} {v : Finset δ} [DecidableEq ζ] [DecidableEq ζ'] [DecidableEq ν] {f : ε → ζ → ν} {g : α → β → ε} {h : γ → δ → ζ} {f' : ε' → ζ' → ν} {g' : α → γ → ε'} {h' : β → δ → ζ'} (h_comm : ∀ a b c d, f (g a b) (h c d) = f' (g' a c) (h' b d)) : image₂ f (image₂ g s t) (image₂ h u v) = image₂ f' (image₂ g' s u) (image₂ h' t v) := coe_injective <\| by push_cast exact image2_image2_image2_comm h_comm theorem image_image₂_distrib {g : γ → δ} {f' : α' → β' → δ} {g₁ : α → α'} {g₂ : β → β'} (h_distrib : ∀ a b, g (f a b) = f' (g₁ a) (g₂ b)) : (image₂ f s t).image g = image₂ f' (s.image g₁) (t.image g₂) := coe_injective <\| by push_cast exact image_image2_distrib h_distrib /-- Symmetric statement to `Finset.image₂_image_left_comm`. -/ theorem image_image₂_distrib_left {g : γ → δ} {f' : α' → β → δ} {g' : α → α'} (h_distrib : ∀ a b, g (f a b) = f' (g' a) b) : (image₂ f s t).image g = image₂ f' (s.image g') t := coe_injective <\| by push_cast exact image_image2_distrib_left h_distrib /-- Symmetric statement to `Finset.image_image₂_right_comm`. -/ theorem image_image₂_distrib_right {g : γ → δ} {f' : α → β' → δ} {g' : β → β'} (h_distrib : ∀ a b, g (f a b) = f' a (g' b)) : (image₂ f s t).image g = image₂ f' s (t.image g') := coe_injective <\| by push_cast exact image_image2_distrib_right h_distrib /-- Symmetric statement to `Finset.image_image₂_distrib_left`. -/ theorem image₂_image_left_comm {f : α' → β → γ} {g : α → α'} {f' : α → β → δ} {g' : δ → γ} (h_left_comm : ∀ a b, f (g a) b = g' (f' a b)) : image₂ f (s.image g) t = (image₂ f' s t).image g' := (image_image₂_distrib_left fun a b => (h_left_comm a b).symm).symm /-- Symmetric statement to `Finset.image_image₂_distrib_right`. -/ theorem image_image₂_right_comm {f : α → β' → γ} {g : β → β'} {f' : α → β → δ} {g' : δ → γ} (h_right_comm : ∀ a b, f a (g b) = g' (f' a b)) : image₂ f s (t.image g) = (image₂ f' s t).image g' := (image_image₂_distrib_right fun a b => (h_right_comm a b).symm).symm /-- The other direction does not hold because of the `s`-`s` cross terms on the RHS. -/ theorem image₂_distrib_subset_left {γ : Type} {u : Finset γ} {f : α → δ → ε} {g : β → γ → δ} {f₁ : α → β → β'} {f₂ : α → γ → γ'} {g' : β' → γ' → ε} (h_distrib : ∀ a b c, f a (g b c) = g' (f₁ a b) (f₂ a c)) : image₂ f s (image₂ g t u) ⊆ image₂ g' (image₂ f₁ s t) (image₂ f₂ s u) := coe_subset.1 <\| by push_cast exact Set.image2_distrib_subset_left h_distrib /-- The other direction does not hold because of the `u`-`u` cross terms on the RHS. -/ theorem image₂_distrib_subset_right {γ : Type} {u : Finset γ} {f : δ → γ → ε} {g : α → β → δ} {f₁ : α → γ → α'} {f₂ : β → γ → β'} {g' : α' → β' → ε} (h_distrib : ∀ a b c, f (g a b) c = g' (f₁ a c) (f₂ b c)) : image₂ f (image₂ g s t) u ⊆ image₂ g' (image₂ f₁ s u) (image₂ f₂ t u) := coe_subset.1 <\| by push_cast exact Set.image2_distrib_subset_right h_distrib theorem image_image₂_antidistrib {g : γ → δ} {f' : β' → α' → δ} {g₁ : β → β'} {g₂ : α → α'} (h_antidistrib : ∀ a b, g (f a b) = f' (g₁ b) (g₂ a)) : (image₂ f s t).image g = image₂ f' (t.image g₁) (s.image g₂) := by rw [image₂_swap f] exact image_image₂_distrib fun _ _ => h_antidistrib _ _ /-- Symmetric statement to `Finset.image₂_image_left_anticomm`. -/ theorem image_image₂_antidistrib_left {g : γ → δ} {f' : β' → α → δ} {g' : β → β'} (h_antidistrib : ∀ a b, g (f a b) = f' (g' b) a) : (image₂ f s t).image g = image₂ f' (t.image g') s := coe_injective <\| by push_cast exact image_image2_antidistrib_left h_antidistrib /-- Symmetric statement to `Finset.image_image₂_right_anticomm`. -/ theorem image_image₂_antidistrib_right {g : γ → δ} {f' : β → α' → δ} {g' : α → α'} (h_antidistrib : ∀ a b, g (f a b) = f' b (g' a)) : (image₂ f s t).image g = image₂ f' t (s.image g') := coe_injective <\| by push_cast exact image_image2_antidistrib_right h_antidistrib /-- Symmetric statement to `Finset.image_image₂_antidistrib_left`. -/ theorem image₂_image_left_anticomm {f : α' → β → γ} {g : α → α'} {f' : β → α → δ} {g' : δ → γ} (h_left_anticomm : ∀ a b, f (g a) b = g' (f' b a)) : image₂ f (s.image g) t = (image₂ f' t s).image g' := (image_image₂_antidistrib_left fun a b => (h_left_anticomm b a).symm).symm /-- Symmetric statement to `Finset.image_image₂_antidistrib_right`. -/ theorem image_image₂_right_anticomm {f : α → β' → γ} {g : β → β'} {f' : β → α → δ} {g' : δ → γ} (h_right_anticomm : ∀ a b, f a (g b) = g' (f' b a)) : image₂ f s (t.image g) = (image₂ f' t s).image g' := (image_image₂_antidistrib_right fun a b => (h_right_anticomm b a).symm).symm /-- If `a` is a left identity for `f : α → β → β`, then `{a}` is a left identity for `Finset.image₂ f`. -/ theorem image₂_left_identity {f : α → γ → γ} {a : α} (h : ∀ b, f a b = b) (t : Finset γ) : image₂ f {a} t = t := coe_injective <\| by rw [coe_image₂, coe_singleton, Set.image2_left_identity h] /-- If `b` is a right identity for `f : α → β → α`, then `{b}` is a right identity for `Finset.image₂ f`. -/ theorem image₂_right_identity {f : γ → β → γ} {b : β} (h : ∀ a, f a b = a) (s : Finset γ) : image₂ f s {b} = s := by rw [image₂_singleton_right, funext h, image_id'] /-- If each partial application of `f` is injective, and images of `s` under those partial applications are disjoint (but not necessarily distinct!), then the size of `t` divides the size of `Finset.image₂ f s t`. -/ theorem card_dvd_card_image₂_right (hf : ∀ a ∈ s, Injective (f a)) (hs : ((fun a => t.image <\| f a) '' s).PairwiseDisjoint id) : #t ∣ #(image₂ f s t) := by classical induction' s using Finset.induction with a s _ ih · simp specialize ih (forall_of_forall_insert hf) (hs.subset <\| Set.image_subset _ <\| coe_subset.2 <\| subset_insert _ _) rw [image₂_insert_left] by_cases h : Disjoint (image (f a) t) (image₂ f s t) · rw [card_union_of_disjoint h] exact Nat.dvd_add (card_image_of_injective _ <\| hf _ <\| mem_insert_self _ _).symm.dvd ih simp_rw [← biUnion_image_left, disjoint_biUnion_right, not_forall] at h obtain ⟨b, hb, h⟩ := h rwa [union_eq_right.2] exact (hs.eq (Set.mem_image_of_mem _ <\| mem_insert_self _ _) (Set.mem_image_of_mem _ <\| mem_insert_of_mem hb) h).trans_subset (image_subset_image₂_right hb) /-- If each partial application of `f` is injective, and images of `t` under those partial applications are disjoint (but not necessarily distinct!), then the size of `s` divides the size of `Finset.image₂ f s t`. -/ theorem card_dvd_card_image₂_left (hf : ∀ b ∈ t, Injective fun a => f a b) (ht : ((fun b => s.image fun a => f a b) '' t).PairwiseDisjoint id) : #s ∣ #(image₂ f s t) := by rw [← image₂_swap]; exact card_dvd_card_image₂_right hf ht /-- If a `Finset` is a subset of the image of two `Set`s under a binary operation, then it is a subset of the `Finset.image₂` of two `Finset` subsets of these `Set`s. -/ theorem subset_set_image₂ {s : Set α} {t : Set β} (hu : ↑u ⊆ image2 f s t) : ∃ (s' : Finset α) (t' : Finset β), ↑s' ⊆ s ∧ ↑t' ⊆ t ∧ u ⊆ image₂ f s' t' := by rw [← Set.image_prod, subset_set_image_iff] at hu rcases hu with ⟨u, hu, rfl⟩ classical use u.image Prod.fst, u.image Prod.snd simp only [coe_image, Set.image_subset_iff, image₂_image_left, image₂_image_right, image_subset_iff] exact ⟨fun _ h ↦ (hu h).1, fun _ h ↦ (hu h).2, fun x hx ↦ mem_image₂_of_mem hx hx⟩ end section UnionInter variable [DecidableEq α] [DecidableEq β] theorem image₂_inter_union_subset_union : image₂ f (s ∩ s') (t ∪ t') ⊆ image₂ f s t ∪ image₂ f s' t' := coe_subset.1 <\| by push_cast exact Set.image2_inter_union_subset_union theorem image₂_union_inter_subset_union : image₂ f (s ∪ s') (t ∩ t') ⊆ image₂ f s t ∪ image₂ f s' t' := coe_subset.1 <\| by push_cast exact Set.image2_union_inter_subset_union theorem image₂_inter_union_subset {f : α → α → β} {s t : Finset α} (hf : ∀ a b, f a b = f b a) : image₂ f (s ∩ t) (s ∪ t) ⊆ image₂ f s t := coe_subset.1 <\| by push_cast exact image2_inter_union_subset hf theorem image₂_union_inter_subset {f : α → α → β} {s t : Finset α} (hf : ∀ a b, f a b = f b a) : image₂ f (s ∪ t) (s ∩ t) ⊆ image₂ f s t := coe_subset.1 <\| by push_cast exact image2_union_inter_subset hf end UnionInter section SemilatticeSup variable [SemilatticeSup δ] @[simp (default + 1)] -- otherwise `simp` doesn't use `forall_mem_image₂` lemma sup'_image₂_le {g : γ → δ} {a : δ} (h : (image₂ f s t).Nonempty) : sup' (image₂ f s t) h g ≤ a ↔ ∀ x ∈ s, ∀ y ∈ t, g (f x y) ≤ a := by rw [sup'_le_iff, forall_mem_image₂] lemma sup'_image₂_left (g : γ → δ) (h : (image₂ f s t).Nonempty) : sup' (image₂ f s t) h g = sup' s h.of_image₂_left fun x ↦ sup' t h.of_image₂_right (g <\| f x ·) := by simp only [image₂, sup'_image, sup'_product_left]; rfl lemma sup'_image₂_right (g : γ → δ) (h : (image₂ f s t).Nonempty) : sup' (image₂ f s t) h g = sup' t h.of_image₂_right fun y ↦ sup' s h.of_image₂_left (g <\| f · y) := by simp only [image₂, sup'_image, sup'_product_right]; rfl variable [OrderBot δ] @[simp (default + 1)] -- otherwise `simp` doesn't use `forall_mem_image₂` lemma sup_image₂_le {g : γ → δ} {a : δ} : sup (image₂ f s t) g ≤ a ↔ ∀ x ∈ s, ∀ y ∈ t, g (f x y) ≤ a := by rw [Finset.sup_le_iff, forall_mem_image₂] variable (s t) lemma sup_image₂_left (g : γ → δ) : sup (image₂ f s t) g = sup s fun x ↦ sup t (g <\| f x ·) := by simp only [image₂, sup_image, sup_product_left]; rfl lemma sup_image₂_right (g : γ → δ) : sup (image₂ f s t) g = sup t fun y ↦ sup s (g <\| f · y) := by simp only [image₂, sup_image, sup_product_right]; rfl end SemilatticeSup section SemilatticeInf variable [SemilatticeInf δ] @[simp (default + 1)] -- otherwise `simp` doesn't use `forall_mem_image₂` lemma le_inf'_image₂ {g : γ → δ} {a : δ} (h : (image₂ f s t).Nonempty) : a ≤ inf' (image₂ f s t) h g ↔ ∀ x ∈ s, ∀ y ∈ t, a ≤ g (f x y) := by rw [le_inf'_iff, forall_mem_image₂] lemma inf'_image₂_left (g : γ → δ) (h : (image₂ f s t).Nonempty) : inf' (image₂ f s t) h g = inf' s h.of_image₂_left fun x ↦ inf' t h.of_image₂_right (g <\| f x ·) := sup'_image₂_left (δ := δᵒᵈ) g h lemma inf'_image₂_right (g : γ → δ) (h : (image₂ f s t).Nonempty) : inf' (image₂ f s t) h g = inf' t h.of_image₂_right fun y ↦ inf' s h.of_image₂_left (g <\| f · y) := sup'_image₂_right (δ := δᵒᵈ) g h variable [OrderTop δ] @[simp (default + 1)] -- otherwise `simp` doesn't use `forall_mem_image₂` lemma le_inf_image₂ {g : γ → δ} {a : δ} : a ≤ inf (image₂ f s t) g ↔ ∀ x ∈ s, ∀ y ∈ t, a ≤ g (f x y) := sup_image₂_le (δ := δᵒᵈ) variable (s t) lemma inf_image₂_left (g : γ → δ) : inf (image₂ f s t) g = inf s fun x ↦ inf t (g ∘ f x) := sup_image₂_left (δ := δᵒᵈ) .. lemma inf_image₂_right (g : γ → δ) : inf (image₂ f s t) g = inf t fun y ↦ inf s (g <\| f · y) := sup_image₂_right (δ := δᵒᵈ) .. end SemilatticeInf end Finset open Finset namespace Fintype variable {ι : Type} {α β γ : ι → Type} [DecidableEq ι] [Fintype ι] [∀ i, DecidableEq (γ i)] lemma piFinset_image₂ (f : ∀ i, α i → β i → γ i) (s : ∀ i, Finset (α i)) (t : ∀ i, Finset (β i)) : piFinset (fun i ↦ image₂ (f i) (s i) (t i)) = image₂ (fun a b i ↦ f _ (a i) (b i)) (piFinset s) (piFinset t) := by ext; simp only [mem_piFinset, mem_image₂, Classical.skolem, forall_and, funext_iff] end Fintype namespace Set	variable [DecidableEq γ] {s : Set α} {t : Set β} @[simp] theorem toFinset_image2 (f : α → β → γ) (s : Set α) (t : Set β) [Fintype s] [Fintype t]	Mathlib/Data/Finset/NAry.lean	596	599
/- Copyright (c) 2020 Johan Commelin. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johan Commelin, Julian Kuelshammer, Heather Macbeth, Mitchell Lee -/ import Mathlib.Algebra.Polynomial.AlgebraMap import Mathlib.Algebra.Polynomial.Derivative import Mathlib.Algebra.Ring.NegOnePow import Mathlib.Tactic.LinearCombination /-! # Chebyshev polynomials The Chebyshev polynomials are families of polynomials indexed by `ℤ`, with integral coefficients. ## Main definitions * `Polynomial.Chebyshev.T`: the Chebyshev polynomials of the first kind. * `Polynomial.Chebyshev.U`: the Chebyshev polynomials of the second kind. * `Polynomial.Chebyshev.C`: the rescaled Chebyshev polynomials of the first kind (also known as the Vieta–Lucas polynomials), given by $C_n(2x) = 2T_n(x)$. * `Polynomial.Chebyshev.S`: the rescaled Chebyshev polynomials of the second kind (also known as the Vieta–Fibonacci polynomials), given by $S_n(2x) = U_n(x)$. ## Main statements * The formal derivative of the Chebyshev polynomials of the first kind is a scalar multiple of the Chebyshev polynomials of the second kind. * `Polynomial.Chebyshev.T_mul_T`, twice the product of the `m`-th and `k`-th Chebyshev polynomials of the first kind is the sum of the `m + k`-th and `m - k`-th Chebyshev polynomials of the first kind. There is a similar statement `Polynomial.Chebyshev.C_mul_C` for the `C` polynomials. * `Polynomial.Chebyshev.T_mul`, the `(m * n)`-th Chebyshev polynomial of the first kind is the composition of the `m`-th and `n`-th Chebyshev polynomials of the first kind. There is a similar statement `Polynomial.Chebyshev.C_mul` for the `C` polynomials. ## Implementation details Since Chebyshev polynomials have interesting behaviour over the complex numbers and modulo `p`, we define them to have coefficients in an arbitrary commutative ring, even though technically `ℤ` would suffice. The benefit of allowing arbitrary coefficient rings, is that the statements afterwards are clean, and do not have `map (Int.castRingHom R)` interfering all the time. ## References [Lionel Ponton, _Roots of the Chebyshev polynomials: A purely algebraic approach_] [ponton2020chebyshev] ## TODO * Redefine and/or relate the definition of Chebyshev polynomials to `LinearRecurrence`. * Add explicit formula involving square roots for Chebyshev polynomials * Compute zeroes and extrema of Chebyshev polynomials. * Prove that the roots of the Chebyshev polynomials (except 0) are irrational. * Prove minimax properties of Chebyshev polynomials. -/ namespace Polynomial.Chebyshev open Polynomial variable (R R' : Type) [CommRing R] [CommRing R'] /-- `T n` is the `n`-th Chebyshev polynomial of the first kind. -/ -- Well-founded definitions are now irreducible by default; -- as this was implemented before this change, -- we just set it back to semireducible to avoid needing to change any proofs. @[semireducible] noncomputable def T : ℤ → R[X] \| 0 => 1 \| 1 => X \| (n : ℕ) + 2 => 2 X * T (n + 1) - T n \| -((n : ℕ) + 1) => 2 * X * T (-n) - T (-n + 1) termination_by n => Int.natAbs n + Int.natAbs (n - 1) /-- Induction principle used for proving facts about Chebyshev polynomials. -/ @[elab_as_elim] protected theorem induct (motive : ℤ → Prop) (zero : motive 0) (one : motive 1) (add_two : ∀ (n : ℕ), motive (↑n + 1) → motive ↑n → motive (↑n + 2)) (neg_add_one : ∀ (n : ℕ), motive (-↑n) → motive (-↑n + 1) → motive (-↑n - 1)) : ∀ (a : ℤ), motive a := T.induct motive zero one add_two fun n hn hnm => by simpa only [Int.negSucc_eq, neg_add] using neg_add_one n hn hnm @[simp] theorem T_add_two : ∀ n, T R (n + 2) = 2 * X * T R (n + 1) - T R n \| (k : ℕ) => T.eq_3 R k	\| -(k + 1 : ℕ) => by linear_combination (norm := (simp [Int.negSucc_eq]; ring_nf)) T.eq_4 R k	Mathlib/RingTheory/Polynomial/Chebyshev.lean	90	91
/- Copyright (c) 2020 Kenny Lau. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kenny Lau, Devon Tuma, Oliver Nash -/ import Mathlib.Algebra.Group.Action.Opposite import Mathlib.Algebra.Group.Submonoid.Membership import Mathlib.Algebra.GroupWithZero.Associated import Mathlib.Algebra.GroupWithZero.Opposite /-! # Non-zero divisors and smul-divisors In this file we define the submonoid `nonZeroDivisors` and `nonZeroSMulDivisors` of a `MonoidWithZero`. We also define `nonZeroDivisorsLeft` and `nonZeroDivisorsRight` for non-commutative monoids. ## Notations This file declares the notations: - `M₀⁰` for the submonoid of non-zero-divisors of `M₀`, in the locale `nonZeroDivisors`. - `M₀⁰[M]` for the submonoid of non-zero smul-divisors of `M₀` with respect to `M`, in the locale `nonZeroSMulDivisors` Use the statement `open scoped nonZeroDivisors nonZeroSMulDivisors` to access this notation in your own code. -/ assert_not_exists Ring open Function section variable (M₀ : Type) [MonoidWithZero M₀] {x : M₀} /-- The collection of elements of a `MonoidWithZero` that are not left zero divisors form a `Submonoid`. -/ def nonZeroDivisorsLeft : Submonoid M₀ where carrier := {x \| ∀ y, y x = 0 → y = 0} one_mem' := by simp mul_mem' {x} {y} hx hy := fun z hz ↦ hx _ <\| hy _ (mul_assoc z x y ▸ hz) @[simp] lemma mem_nonZeroDivisorsLeft_iff : x ∈ nonZeroDivisorsLeft M₀ ↔ ∀ y, y * x = 0 → y = 0 := .rfl lemma nmem_nonZeroDivisorsLeft_iff : x ∉ nonZeroDivisorsLeft M₀ ↔ {y \| y * x = 0 ∧ y ≠ 0}.Nonempty := by simpa [mem_nonZeroDivisorsLeft_iff] using Set.nonempty_def.symm /-- The collection of elements of a `MonoidWithZero` that are not right zero divisors form a `Submonoid`. -/ def nonZeroDivisorsRight : Submonoid M₀ where carrier := {x \| ∀ y, x * y = 0 → y = 0} one_mem' := by simp mul_mem' := fun {x} {y} hx hy z hz ↦ hy _ (hx _ ((mul_assoc x y z).symm ▸ hz)) @[simp] lemma mem_nonZeroDivisorsRight_iff : x ∈ nonZeroDivisorsRight M₀ ↔ ∀ y, x * y = 0 → y = 0 := .rfl lemma nmem_nonZeroDivisorsRight_iff : x ∉ nonZeroDivisorsRight M₀ ↔ {y \| x * y = 0 ∧ y ≠ 0}.Nonempty := by simpa [mem_nonZeroDivisorsRight_iff] using Set.nonempty_def.symm lemma nonZeroDivisorsLeft_eq_right (M₀ : Type) [CommMonoidWithZero M₀] : nonZeroDivisorsLeft M₀ = nonZeroDivisorsRight M₀ := by ext x; simp [mul_comm x] @[simp] lemma coe_nonZeroDivisorsLeft_eq [NoZeroDivisors M₀] [Nontrivial M₀] : nonZeroDivisorsLeft M₀ = {x : M₀ \| x ≠ 0} := by ext x simp only [SetLike.mem_coe, mem_nonZeroDivisorsLeft_iff, mul_eq_zero, forall_eq_or_imp, true_and, Set.mem_setOf_eq] refine ⟨fun h ↦ ?_, fun hx y hx' ↦ by contradiction⟩ contrapose! h exact ⟨1, h, one_ne_zero⟩ @[simp] lemma coe_nonZeroDivisorsRight_eq [NoZeroDivisors M₀] [Nontrivial M₀] : nonZeroDivisorsRight M₀ = {x : M₀ \| x ≠ 0} := by ext x simp only [SetLike.mem_coe, mem_nonZeroDivisorsRight_iff, mul_eq_zero, Set.mem_setOf_eq] refine ⟨fun h ↦ ?_, fun hx y hx' ↦ by aesop⟩ contrapose! h exact ⟨1, Or.inl h, one_ne_zero⟩ end /-- The submonoid of non-zero-divisors of a `MonoidWithZero` `M₀`. -/ def nonZeroDivisors (M₀ : Type) [MonoidWithZero M₀] : Submonoid M₀ where carrier := { x \| ∀ z, z * x = 0 → z = 0 } one_mem' _ hz := by rwa [mul_one] at hz mul_mem' hx₁ hx₂ _ hz := by rw [← mul_assoc] at hz exact hx₁ _ (hx₂ _ hz) /-- The notation for the submonoid of non-zero divisors. -/ scoped[nonZeroDivisors] notation:9000 M₀ "⁰" => nonZeroDivisors M₀ /-- Let `M₀` be a monoid with zero and `M` an additive monoid with an `M₀`-action, then the collection of non-zero smul-divisors forms a submonoid. These elements are also called `M`-regular. -/ def nonZeroSMulDivisors (M₀ : Type) [MonoidWithZero M₀] (M : Type) [Zero M] [MulAction M₀ M] : Submonoid M₀ where carrier := { r \| ∀ m : M, r • m = 0 → m = 0} one_mem' m h := (one_smul M₀ m) ▸ h mul_mem' {r₁ r₂} h₁ h₂ m H := h₂ _ <\| h₁ _ <\| mul_smul r₁ r₂ m ▸ H /-- The notation for the submonoid of non-zero smul-divisors. -/ scoped[nonZeroSMulDivisors] notation:9000 M₀ "⁰[" M "]" => nonZeroSMulDivisors M₀ M open nonZeroDivisors section MonoidWithZero variable {F M₀ M₀' : Type} [MonoidWithZero M₀] [MonoidWithZero M₀'] {r x y : M₀} -- this lemma reflects symmetry-breaking in the definition of `nonZeroDivisors` lemma nonZeroDivisorsLeft_eq_nonZeroDivisors : nonZeroDivisorsLeft M₀ = nonZeroDivisors M₀ := rfl lemma nonZeroDivisorsRight_eq_nonZeroSMulDivisors : nonZeroDivisorsRight M₀ = nonZeroSMulDivisors M₀ M₀ := rfl theorem mem_nonZeroDivisors_iff : r ∈ M₀⁰ ↔ ∀ x, x r = 0 → x = 0 := Iff.rfl lemma nmem_nonZeroDivisors_iff : r ∉ M₀⁰ ↔ {s \| s * r = 0 ∧ s ≠ 0}.Nonempty := by simpa [mem_nonZeroDivisors_iff] using Set.nonempty_def.symm theorem mul_right_mem_nonZeroDivisors_eq_zero_iff (hr : r ∈ M₀⁰) : x * r = 0 ↔ x = 0 := ⟨hr _, by simp +contextual⟩ @[simp] theorem mul_right_coe_nonZeroDivisors_eq_zero_iff {c : M₀⁰} : x * c = 0 ↔ x = 0 := mul_right_mem_nonZeroDivisors_eq_zero_iff c.prop lemma IsUnit.mem_nonZeroDivisors (hx : IsUnit x) : x ∈ M₀⁰ := fun _ ↦ hx.mul_left_eq_zero.mp section Nontrivial variable [Nontrivial M₀] theorem zero_not_mem_nonZeroDivisors : 0 ∉ M₀⁰ := fun h ↦ one_ne_zero <\| h 1 <\| mul_zero _ theorem nonZeroDivisors.ne_zero (hx : x ∈ M₀⁰) : x ≠ 0 := ne_of_mem_of_not_mem hx zero_not_mem_nonZeroDivisors @[simp] theorem nonZeroDivisors.coe_ne_zero (x : M₀⁰) : (x : M₀) ≠ 0 := nonZeroDivisors.ne_zero x.2 instance [IsLeftCancelMulZero M₀] : LeftCancelMonoid M₀⁰ where mul_left_cancel _ _ _ h := Subtype.ext <\| mul_left_cancel₀ (nonZeroDivisors.coe_ne_zero _) (by simpa only [Subtype.ext_iff, Submonoid.coe_mul] using h) instance [IsRightCancelMulZero M₀] : RightCancelMonoid M₀⁰ where mul_right_cancel _ _ _ h := Subtype.ext <\| mul_right_cancel₀ (nonZeroDivisors.coe_ne_zero _) (by simpa only [Subtype.ext_iff, Submonoid.coe_mul] using h) end Nontrivial section NoZeroDivisors variable [NoZeroDivisors M₀] theorem eq_zero_of_ne_zero_of_mul_right_eq_zero (hx : x ≠ 0) (hxy : y * x = 0) : y = 0 := Or.resolve_right (eq_zero_or_eq_zero_of_mul_eq_zero hxy) hx theorem eq_zero_of_ne_zero_of_mul_left_eq_zero (hx : x ≠ 0) (hxy : x * y = 0) : y = 0 := Or.resolve_left (eq_zero_or_eq_zero_of_mul_eq_zero hxy) hx theorem mem_nonZeroDivisors_of_ne_zero (hx : x ≠ 0) : x ∈ M₀⁰ := fun _ ↦ eq_zero_of_ne_zero_of_mul_right_eq_zero hx @[simp] lemma mem_nonZeroDivisors_iff_ne_zero [Nontrivial M₀] : x ∈ M₀⁰ ↔ x ≠ 0 := ⟨nonZeroDivisors.ne_zero, mem_nonZeroDivisors_of_ne_zero⟩ theorem le_nonZeroDivisors_of_noZeroDivisors {S : Submonoid M₀} (hS : (0 : M₀) ∉ S) : S ≤ M₀⁰ := fun _ hx _ hy ↦ (eq_zero_or_eq_zero_of_mul_eq_zero hy).resolve_right (ne_of_mem_of_not_mem hx hS) theorem powers_le_nonZeroDivisors_of_noZeroDivisors (hx : x ≠ 0) : Submonoid.powers x ≤ M₀⁰ := le_nonZeroDivisors_of_noZeroDivisors fun h ↦ hx (h.recOn fun _ ↦ pow_eq_zero) end NoZeroDivisors variable [FunLike F M₀ M₀'] theorem map_ne_zero_of_mem_nonZeroDivisors [Nontrivial M₀] [ZeroHomClass F M₀ M₀'] (g : F) (hg : Injective (g : M₀ → M₀')) {x : M₀} (h : x ∈ M₀⁰) : g x ≠ 0 := fun h0 ↦ one_ne_zero (h 1 ((one_mul x).symm ▸ hg (h0.trans (map_zero g).symm))) theorem map_mem_nonZeroDivisors [Nontrivial M₀] [NoZeroDivisors M₀'] [ZeroHomClass F M₀ M₀'] (g : F) (hg : Injective g) {x : M₀} (h : x ∈ M₀⁰) : g x ∈ M₀'⁰ := fun _ hz ↦ eq_zero_of_ne_zero_of_mul_right_eq_zero (map_ne_zero_of_mem_nonZeroDivisors g hg h) hz theorem MulEquivClass.map_nonZeroDivisors {M₀ S F : Type} [MonoidWithZero M₀] [MonoidWithZero S] [EquivLike F M₀ S] [MulEquivClass F M₀ S] (h : F) : Submonoid.map h (nonZeroDivisors M₀) = nonZeroDivisors S := by let h : M₀ ≃ S := h show Submonoid.map h _ = _ ext simp_rw [Submonoid.map_equiv_eq_comap_symm, Submonoid.mem_comap, mem_nonZeroDivisors_iff, ← h.symm.forall_congr_right, h.symm.toEquiv_eq_coe, h.symm.coe_toEquiv, ← map_mul, map_eq_zero_iff _ h.symm.injective] theorem map_le_nonZeroDivisors_of_injective [NoZeroDivisors M₀'] [MonoidWithZeroHomClass F M₀ M₀'] (f : F) (hf : Injective f) {S : Submonoid M₀} (hS : S ≤ M₀⁰) : S.map f ≤ M₀'⁰ := by cases subsingleton_or_nontrivial M₀ · simp [Subsingleton.elim S ⊥] · refine le_nonZeroDivisors_of_noZeroDivisors ?_ rintro ⟨x, hx, hx0⟩ exact zero_not_mem_nonZeroDivisors <\| hS <\| map_eq_zero_iff f hf \|>.mp hx0 ▸ hx theorem nonZeroDivisors_le_comap_nonZeroDivisors_of_injective [NoZeroDivisors M₀'] [MonoidWithZeroHomClass F M₀ M₀'] (f : F) (hf : Injective f) : M₀⁰ ≤ M₀'⁰.comap f := Submonoid.le_comap_of_map_le _ (map_le_nonZeroDivisors_of_injective _ hf le_rfl) /-- If an element maps to a non-zero-divisor via injective homomorphism, then it is a non-zero-divisor. -/ theorem mem_nonZeroDivisors_of_injective [MonoidWithZeroHomClass F M₀ M₀'] {f : F} (hf : Injective f) (hx : f x ∈ M₀'⁰) : x ∈ M₀⁰ := fun y hy ↦ hf <\| map_zero f ▸ hx (f y) (map_mul f y x ▸ map_zero f ▸ congrArg f hy) @[deprecated (since := "2025-02-03")] alias mem_nonZeroDivisor_of_injective := mem_nonZeroDivisors_of_injective theorem comap_nonZeroDivisors_le_of_injective [MonoidWithZeroHomClass F M₀ M₀'] {f : F} (hf : Injective f) : M₀'⁰.comap f ≤ M₀⁰ := fun _ ha ↦ mem_nonZeroDivisors_of_injective hf (Submonoid.mem_comap.mp ha) @[deprecated (since := "2025-02-03")] alias comap_nonZeroDivisor_le_of_injective := comap_nonZeroDivisors_le_of_injective end MonoidWithZero section CommMonoidWithZero variable {M₀ : Type} [CommMonoidWithZero M₀] {a b r x : M₀} lemma mul_left_mem_nonZeroDivisors_eq_zero_iff (hr : r ∈ M₀⁰) : r x = 0 ↔ x = 0 := by rw [mul_comm, mul_right_mem_nonZeroDivisors_eq_zero_iff hr] @[simp] lemma mul_left_coe_nonZeroDivisors_eq_zero_iff {c : M₀⁰} : (c : M₀) * x = 0 ↔ x = 0 := mul_left_mem_nonZeroDivisors_eq_zero_iff c.prop lemma mul_mem_nonZeroDivisors : a * b ∈ M₀⁰ ↔ a ∈ M₀⁰ ∧ b ∈ M₀⁰ where mp h := by constructor <;> intro x h' <;> apply h · rw [← mul_assoc, h', zero_mul] · rw [mul_comm a b, ← mul_assoc, h', zero_mul] mpr := by rintro ⟨ha, hb⟩ x hx apply ha apply hb rw [mul_assoc, hx] end CommMonoidWithZero section GroupWithZero variable {G₀ : Type} [GroupWithZero G₀] {x : G₀} /-- Canonical isomorphism between the non-zero-divisors and units of a group with zero. -/ @[simps] noncomputable def nonZeroDivisorsEquivUnits : G₀⁰ ≃ G₀ˣ where toFun u := .mk0 _ <\| mem_nonZeroDivisors_iff_ne_zero.1 u.2 invFun u := ⟨u, u.isUnit.mem_nonZeroDivisors⟩ left_inv u := rfl right_inv u := by simp map_mul' u v := by simp lemma isUnit_of_mem_nonZeroDivisors (hx : x ∈ nonZeroDivisors G₀) : IsUnit x := (nonZeroDivisorsEquivUnits ⟨x, hx⟩).isUnit end GroupWithZero section nonZeroSMulDivisors open nonZeroSMulDivisors nonZeroDivisors variable {M₀ M : Type*} [MonoidWithZero M₀] [Zero M] [MulAction M₀ M] {x : M₀} lemma mem_nonZeroSMulDivisors_iff : x ∈ M₀⁰[M] ↔ ∀ (m : M), x • m = 0 → m = 0 := Iff.rfl variable (M₀) @[simp] lemma unop_nonZeroSMulDivisors_mulOpposite_eq_nonZeroDivisors : (M₀ᵐᵒᵖ ⁰[M₀]).unop = M₀⁰ := rfl /-- The non-zero `•`-divisors with `•` as right multiplication correspond with the non-zero divisors. Note that the `MulOpposite` is needed because we defined `nonZeroDivisors` with multiplication on the right. -/ lemma nonZeroSMulDivisors_mulOpposite_eq_op_nonZeroDivisors : M₀ᵐᵒᵖ ⁰[M₀] = M₀⁰.op := rfl end nonZeroSMulDivisors open scoped nonZeroDivisors variable {M₀} section MonoidWithZero variable [MonoidWithZero M₀] {a b : M₀⁰} /-- The units of the monoid of non-zero divisors of `M₀` are equivalent to the units of `M₀`. -/ @[simps]	def unitsNonZeroDivisorsEquiv : M₀⁰ˣ ≃* M₀ˣ where __ := Units.map M₀⁰.subtype	Mathlib/Algebra/GroupWithZero/NonZeroDivisors.lean	307	308
/- Copyright (c) 2023 Luke Mantle. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Luke Mantle -/ import Mathlib.Algebra.Polynomial.Derivative import Mathlib.Data.Nat.Factorial.DoubleFactorial /-! # Hermite polynomials This file defines `Polynomial.hermite n`, the `n`th probabilists' Hermite polynomial. ## Main definitions * `Polynomial.hermite n`: the `n`th probabilists' Hermite polynomial, defined recursively as a `Polynomial ℤ` ## Results * `Polynomial.hermite_succ`: the recursion `hermite (n+1) = (x - d/dx) (hermite n)` * `Polynomial.coeff_hermite_explicit`: a closed formula for (nonvanishing) coefficients in terms of binomial coefficients and double factorials. * `Polynomial.coeff_hermite_of_odd_add`: for `n`,`k` where `n+k` is odd, `(hermite n).coeff k` is zero. * `Polynomial.coeff_hermite_of_even_add`: a closed formula for `(hermite n).coeff k` when `n+k` is even, equivalent to `Polynomial.coeff_hermite_explicit`. * `Polynomial.monic_hermite`: for all `n`, `hermite n` is monic. * `Polynomial.degree_hermite`: for all `n`, `hermite n` has degree `n`. ## References * [Hermite Polynomials](https://en.wikipedia.org/wiki/Hermite_polynomials) -/ noncomputable section open Polynomial namespace Polynomial /-- the probabilists' Hermite polynomials. -/ noncomputable def hermite : ℕ → Polynomial ℤ \| 0 => 1 \| n + 1 => X * hermite n - derivative (hermite n) /-- The recursion `hermite (n+1) = (x - d/dx) (hermite n)` -/ @[simp] theorem hermite_succ (n : ℕ) : hermite (n + 1) = X * hermite n - derivative (hermite n) := by rw [hermite] theorem hermite_eq_iterate (n : ℕ) : hermite n = (fun p => X * p - derivative p)^[n] 1 := by induction n with \| zero => rfl \| succ n ih => rw [Function.iterate_succ_apply', ← ih, hermite_succ] @[simp] theorem hermite_zero : hermite 0 = C 1 := rfl theorem hermite_one : hermite 1 = X := by rw [hermite_succ, hermite_zero] simp only [map_one, mul_one, derivative_one, sub_zero] /-! ### Lemmas about `Polynomial.coeff` -/ section coeff theorem coeff_hermite_succ_zero (n : ℕ) : coeff (hermite (n + 1)) 0 = -coeff (hermite n) 1 := by simp [coeff_derivative] theorem coeff_hermite_succ_succ (n k : ℕ) : coeff (hermite (n + 1)) (k + 1) = coeff (hermite n) k - (k + 2) * coeff (hermite n) (k + 2) := by rw [hermite_succ, coeff_sub, coeff_X_mul, coeff_derivative, mul_comm] norm_cast theorem coeff_hermite_of_lt {n k : ℕ} (hnk : n < k) : coeff (hermite n) k = 0 := by obtain ⟨k, rfl⟩ := Nat.exists_eq_add_of_lt hnk clear hnk induction n generalizing k with \| zero => exact coeff_C \| succ n ih => have : n + k + 1 + 2 = n + (k + 2) + 1 := by ring rw [coeff_hermite_succ_succ, add_right_comm, this, ih k, ih (k + 2), mul_zero, sub_zero] @[simp] theorem coeff_hermite_self (n : ℕ) : coeff (hermite n) n = 1 := by induction n with \| zero => exact coeff_C \| succ n ih => rw [coeff_hermite_succ_succ, ih, coeff_hermite_of_lt, mul_zero, sub_zero] simp @[simp] theorem degree_hermite (n : ℕ) : (hermite n).degree = n := by rw [degree_eq_of_le_of_coeff_ne_zero] · simp_rw [degree_le_iff_coeff_zero, Nat.cast_lt] rintro m hnm exact coeff_hermite_of_lt hnm · simp [coeff_hermite_self n] @[simp] theorem natDegree_hermite {n : ℕ} : (hermite n).natDegree = n := natDegree_eq_of_degree_eq_some (degree_hermite n) @[simp] theorem leadingCoeff_hermite (n : ℕ) : (hermite n).leadingCoeff = 1 := by rw [← coeff_natDegree, natDegree_hermite, coeff_hermite_self]	theorem hermite_monic (n : ℕ) : (hermite n).Monic := leadingCoeff_hermite n theorem coeff_hermite_of_odd_add {n k : ℕ} (hnk : Odd (n + k)) : coeff (hermite n) k = 0 := by induction n generalizing k with	Mathlib/RingTheory/Polynomial/Hermite/Basic.lean	111	116
/- Copyright (c) 2020 Bhavik Mehta. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Bhavik Mehta, Alena Gusakov, Yaël Dillies -/ import Mathlib.Algebra.GeomSum import Mathlib.Data.Finset.Slice import Mathlib.Data.Nat.BitIndices import Mathlib.Order.SupClosed import Mathlib.Order.UpperLower.Closure /-! # Colexigraphic order We define the colex order for finite sets, and give a couple of important lemmas and properties relating to it. The colex ordering likes to avoid large values: If the biggest element of `t` is bigger than all elements of `s`, then `s < t`. In the special case of `ℕ`, it can be thought of as the "binary" ordering. That is, order `s` based on $∑_{i ∈ s} 2^i$. It's defined here on `Finset α` for any linear order `α`. In the context of the Kruskal-Katona theorem, we are interested in how colex behaves for sets of a fixed size. For example, for size 3, the colex order on ℕ starts `012, 013, 023, 123, 014, 024, 124, 034, 134, 234, ...` ## Main statements * Colex order properties - linearity, decidability and so on. * `Finset.Colex.forall_lt_mono`: if `s < t` in colex, and everything in `t` is `< a`, then everything in `s` is `< a`. This confirms the idea that an enumeration under colex will exhaust all sets using elements `< a` before allowing `a` to be included. * `Finset.toColex_image_le_toColex_image`: Strictly monotone functions preserve colex. * `Finset.geomSum_le_geomSum_iff_toColex_le_toColex`: Colex for α = ℕ is the same as binary. This also proves binary expansions are unique. ## See also Related files are: * `Data.List.Lex`: Lexicographic order on lists. * `Data.Pi.Lex`: Lexicographic order on `Πₗ i, α i`. * `Data.PSigma.Order`: Lexicographic order on `Σ' i, α i`. * `Data.Sigma.Order`: Lexicographic order on `Σ i, α i`. * `Data.Prod.Lex`: Lexicographic order on `α × β`. ## TODO * Generalise `Colex.initSeg` so that it applies to `ℕ`. ## References * https://github.com/b-mehta/maths-notes/blob/master/iii/mich/combinatorics.pdf ## Tags colex, colexicographic, binary -/ open Finset Function variable {α β : Type*} namespace Finset /-- Type synonym of `Finset α` equipped with the colexicographic order rather than the inclusion order. -/ @[ext] structure Colex (α) where /-- `toColex` is the "identity" function between `Finset α` and `Finset.Colex α`. -/ toColex :: /-- `ofColex` is the "identity" function between `Finset.Colex α` and `Finset α`. -/ (ofColex : Finset α) -- TODO: Why can't we export? --export Colex (toColex) open Colex instance : Inhabited (Colex α) := ⟨⟨∅⟩⟩ @[simp] lemma toColex_ofColex (s : Colex α) : toColex (ofColex s) = s := rfl lemma ofColex_toColex (s : Finset α) : ofColex (toColex s) = s := rfl lemma toColex_inj {s t : Finset α} : toColex s = toColex t ↔ s = t := by simp @[simp] lemma ofColex_inj {s t : Colex α} : ofColex s = ofColex t ↔ s = t := by cases s; cases t; simp lemma toColex_ne_toColex {s t : Finset α} : toColex s ≠ toColex t ↔ s ≠ t := by simp lemma ofColex_ne_ofColex {s t : Colex α} : ofColex s ≠ ofColex t ↔ s ≠ t := by simp lemma toColex_injective : Injective (toColex : Finset α → Colex α) := fun _ _ ↦ toColex_inj.1 lemma ofColex_injective : Injective (ofColex : Colex α → Finset α) := fun _ _ ↦ ofColex_inj.1 namespace Colex section PartialOrder variable [PartialOrder α] [PartialOrder β] {f : α → β} {𝒜 𝒜₁ 𝒜₂ : Finset (Finset α)} {s t u : Finset α} {a b : α} instance instLE : LE (Colex α) where le s t := ∀ ⦃a⦄, a ∈ ofColex s → a ∉ ofColex t → ∃ b, b ∈ ofColex t ∧ b ∉ ofColex s ∧ a ≤ b -- TODO: This lemma is weirdly useful given how strange its statement is. -- Is there a nicer statement? Should this lemma be made public? private lemma trans_aux (hst : toColex s ≤ toColex t) (htu : toColex t ≤ toColex u) (has : a ∈ s) (hat : a ∉ t) : ∃ b, b ∈ u ∧ b ∉ s ∧ a ≤ b := by classical let s' : Finset α := {b ∈ s \| b ∉ t ∧ a ≤ b} have ⟨b, hb, hbmax⟩ := exists_maximal s' ⟨a, by simp [s', has, hat]⟩ simp only [s', mem_filter, and_imp] at hb hbmax have ⟨c, hct, hcs, hbc⟩ := hst hb.1 hb.2.1 by_cases hcu : c ∈ u · exact ⟨c, hcu, hcs, hb.2.2.trans hbc⟩ have ⟨d, hdu, hdt, hcd⟩ := htu hct hcu have had : a ≤ d := hb.2.2.trans <\| hbc.trans hcd refine ⟨d, hdu, fun hds ↦ ?_, had⟩ exact hbmax d hds hdt had <\| hbc.trans_lt <\| hcd.lt_of_ne <\| ne_of_mem_of_not_mem hct hdt private lemma antisymm_aux (hst : toColex s ≤ toColex t) (hts : toColex t ≤ toColex s) : s ⊆ t := by intro a has by_contra! hat have ⟨_b, hb₁, hb₂, _⟩ := trans_aux hst hts has hat exact hb₂ hb₁ instance instPartialOrder : PartialOrder (Colex α) where le_refl _ _ ha ha' := (ha' ha).elim le_antisymm _ _ hst hts := Colex.ext <\| (antisymm_aux hst hts).antisymm (antisymm_aux hts hst) le_trans s t u hst htu a has hau := by by_cases hat : a ∈ ofColex t · have ⟨b, hbu, hbt, hab⟩ := htu hat hau by_cases hbs : b ∈ ofColex s · have ⟨c, hcu, hcs, hbc⟩ := trans_aux hst htu hbs hbt exact ⟨c, hcu, hcs, hab.trans hbc⟩ · exact ⟨b, hbu, hbs, hab⟩ · exact trans_aux hst htu has hat lemma le_def {s t : Colex α} : s ≤ t ↔ ∀ ⦃a⦄, a ∈ ofColex s → a ∉ ofColex t → ∃ b, b ∈ ofColex t ∧ b ∉ ofColex s ∧ a ≤ b := Iff.rfl lemma toColex_le_toColex : toColex s ≤ toColex t ↔ ∀ ⦃a⦄, a ∈ s → a ∉ t → ∃ b, b ∈ t ∧ b ∉ s ∧ a ≤ b := Iff.rfl lemma toColex_lt_toColex : toColex s < toColex t ↔ s ≠ t ∧ ∀ ⦃a⦄, a ∈ s → a ∉ t → ∃ b, b ∈ t ∧ b ∉ s ∧ a ≤ b := by simp [lt_iff_le_and_ne, toColex_le_toColex, and_comm] /-- If `s ⊆ t`, then `s ≤ t` in the colex order. Note the converse does not hold, as inclusion does not form a linear order. -/ lemma toColex_mono : Monotone (toColex : Finset α → Colex α) := fun _s _t hst _a has hat ↦ (hat <\| hst has).elim /-- If `s ⊂ t`, then `s < t` in the colex order. Note the converse does not hold, as inclusion does not form a linear order. -/ lemma toColex_strictMono : StrictMono (toColex : Finset α → Colex α) := toColex_mono.strictMono_of_injective toColex_injective /-- If `s ⊆ t`, then `s ≤ t` in the colex order. Note the converse does not hold, as inclusion does not form a linear order. -/ lemma toColex_le_toColex_of_subset (h : s ⊆ t) : toColex s ≤ toColex t := toColex_mono h /-- If `s ⊂ t`, then `s < t` in the colex order. Note the converse does not hold, as inclusion does not form a linear order. -/ lemma toColex_lt_toColex_of_ssubset (h : s ⊂ t) : toColex s < toColex t := toColex_strictMono h instance instOrderBot : OrderBot (Colex α) where bot := toColex ∅ bot_le s a ha := by cases ha @[simp] lemma toColex_empty : toColex (∅ : Finset α) = ⊥ := rfl @[simp] lemma ofColex_bot : ofColex (⊥ : Colex α) = ∅ := rfl /-- If `s ≤ t` in colex, and all elements in `t` are small, then all elements in `s` are small. -/ lemma forall_le_mono (hst : toColex s ≤ toColex t) (ht : ∀ b ∈ t, b ≤ a) : ∀ b ∈ s, b ≤ a := by rintro b hb by_cases b ∈ t · exact ht _ ‹_› · obtain ⟨c, hct, -, hbc⟩ := hst hb ‹_› exact hbc.trans <\| ht _ hct /-- If `s ≤ t` in colex, and all elements in `t` are small, then all elements in `s` are small. -/ lemma forall_lt_mono (hst : toColex s ≤ toColex t) (ht : ∀ b ∈ t, b < a) : ∀ b ∈ s, b < a := by rintro b hb by_cases b ∈ t · exact ht _ ‹_› · obtain ⟨c, hct, -, hbc⟩ := hst hb ‹_› exact hbc.trans_lt <\| ht _ hct /-- `s ≤ {a}` in colex iff all elements of `s` are strictly less than `a`, except possibly `a` in which case `s = {a}`. -/ lemma toColex_le_singleton : toColex s ≤ toColex {a} ↔ ∀ b ∈ s, b ≤ a ∧ (a ∈ s → b = a) := by simp only [toColex_le_toColex, mem_singleton, and_assoc, exists_eq_left] refine forall₂_congr fun b _ ↦ ?_; obtain rfl \| hba := eq_or_ne b a <;> aesop /-- `s < {a}` in colex iff all elements of `s` are strictly less than `a`. -/ lemma toColex_lt_singleton : toColex s < toColex {a} ↔ ∀ b ∈ s, b < a := by rw [lt_iff_le_and_ne, toColex_le_singleton, toColex_ne_toColex] refine ⟨fun h b hb ↦ (h.1 _ hb).1.lt_of_ne ?_, fun h ↦ ⟨fun b hb ↦ ⟨(h _ hb).le, fun ha ↦ (lt_irrefl _ <\| h _ ha).elim⟩, ?_⟩⟩ <;> rintro rfl · refine h.2 <\| eq_singleton_iff_unique_mem.2 ⟨hb, fun c hc ↦ (h.1 _ hc).2 hb⟩ · simp at h /-- `{a} ≤ s` in colex iff `s` contains an element greater than or equal to `a`. -/ lemma singleton_le_toColex : (toColex {a} : Colex α) ≤ toColex s ↔ ∃ x ∈ s, a ≤ x := by simp [toColex_le_toColex]; by_cases a ∈ s <;> aesop /-- Colex is an extension of the base order. -/ lemma singleton_le_singleton : (toColex {a} : Colex α) ≤ toColex {b} ↔ a ≤ b := by simp [toColex_le_singleton, eq_comm] /-- Colex is an extension of the base order. -/ lemma singleton_lt_singleton : (toColex {a} : Colex α) < toColex {b} ↔ a < b := by simp [toColex_lt_singleton] lemma le_iff_sdiff_subset_lowerClosure {s t : Colex α} : s ≤ t ↔ (ofColex s : Set α) \ ofColex t ⊆ lowerClosure (ofColex t \ ofColex s : Set α) := by simp [le_def, Set.subset_def, and_assoc] section DecidableEq variable [DecidableEq α] instance instDecidableEq : DecidableEq (Colex α) := fun s t ↦ decidable_of_iff' (s.ofColex = t.ofColex) Colex.ext_iff instance instDecidableLE [DecidableLE α] : DecidableLE (Colex α) := fun s t ↦ decidable_of_iff' (∀ ⦃a⦄, a ∈ ofColex s → a ∉ ofColex t → ∃ b, b ∈ ofColex t ∧ b ∉ ofColex s ∧ a ≤ b) Iff.rfl instance instDecidableLT [DecidableLE α] : DecidableLT (Colex α) := decidableLTOfDecidableLE /-- The colexigraphic order is insensitive to removing the same elements from both sets. -/ lemma toColex_sdiff_le_toColex_sdiff (hus : u ⊆ s) (hut : u ⊆ t) : toColex (s \ u) ≤ toColex (t \ u) ↔ toColex s ≤ toColex t := by simp_rw [toColex_le_toColex, ← and_imp, ← and_assoc, ← mem_sdiff, sdiff_sdiff_sdiff_cancel_right (show u ≤ s from hus), sdiff_sdiff_sdiff_cancel_right (show u ≤ t from hut)] /-- The colexigraphic order is insensitive to removing the same elements from both sets. -/ lemma toColex_sdiff_lt_toColex_sdiff (hus : u ⊆ s) (hut : u ⊆ t) : toColex (s \ u) < toColex (t \ u) ↔ toColex s < toColex t := lt_iff_lt_of_le_iff_le' (toColex_sdiff_le_toColex_sdiff hut hus) <\| toColex_sdiff_le_toColex_sdiff hus hut @[simp] lemma toColex_sdiff_le_toColex_sdiff' : toColex (s \ t) ≤ toColex (t \ s) ↔ toColex s ≤ toColex t := by simpa using toColex_sdiff_le_toColex_sdiff (inter_subset_left (s₁ := s)) inter_subset_right	@[simp] lemma toColex_sdiff_lt_toColex_sdiff' : toColex (s \ t) < toColex (t \ s) ↔ toColex s < toColex t := by simpa using toColex_sdiff_lt_toColex_sdiff (inter_subset_left (s₁ := s)) inter_subset_right	Mathlib/Combinatorics/Colex.lean	247	249
/- 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.Geometry.Euclidean.Altitude import Mathlib.Geometry.Euclidean.Circumcenter /-! # Monge point and orthocenter This file defines the orthocenter of a triangle, via its n-dimensional generalization, the Monge point of a simplex. ## Main definitions * `mongePoint` is the Monge point of a simplex, defined in terms of its position on the Euler line and then shown to be the point of concurrence of the Monge planes. * `mongePlane` is a Monge plane of an (n+2)-simplex, which is the (n+1)-dimensional affine subspace of the subspace spanned by the simplex that passes through the centroid of an n-dimensional face and is orthogonal to the opposite edge (in 2 dimensions, this is the same as an altitude). * `orthocenter` is defined, for the case of a triangle, to be the same as its Monge point, then shown to be the point of concurrence of the altitudes. * `OrthocentricSystem` is a predicate on sets of points that says whether they are four points, one of which is the orthocenter of the other three (in which case various other properties hold, including that each is the orthocenter of the other three). ## References * <https://en.wikipedia.org/wiki/Monge_point> * <https://en.wikipedia.org/wiki/Orthocentric_system> * Małgorzata Buba-Brzozowa, [The Monge Point and the 3(n+1) Point Sphere of an n-Simplex](https://pdfs.semanticscholar.org/6f8b/0f623459c76dac2e49255737f8f0f4725d16.pdf) -/ noncomputable section open scoped RealInnerProductSpace namespace Affine namespace Simplex open Finset AffineSubspace EuclideanGeometry PointsWithCircumcenterIndex variable {V : Type} {P : Type} [NormedAddCommGroup V] [InnerProductSpace ℝ V] [MetricSpace P] [NormedAddTorsor V P] /-- The Monge point of a simplex (in 2 or more dimensions) is a generalization of the orthocenter of a triangle. It is defined to be the intersection of the Monge planes, where a Monge plane is the (n-1)-dimensional affine subspace of the subspace spanned by the simplex that passes through the centroid of an (n-2)-dimensional face and is orthogonal to the opposite edge (in 2 dimensions, this is the same as an altitude). The circumcenter O, centroid G and Monge point M are collinear in that order on the Euler line, with OG : GM = (n-1): 2. Here, we use that ratio to define the Monge point (so resulting in a point that equals the centroid in 0 or 1 dimensions), and then show in subsequent lemmas that the point so defined lies in the Monge planes and is their unique point of intersection. -/ def mongePoint {n : ℕ} (s : Simplex ℝ P n) : P := (((n + 1 : ℕ) : ℝ) / ((n - 1 : ℕ) : ℝ)) • ((univ : Finset (Fin (n + 1))).centroid ℝ s.points -ᵥ s.circumcenter) +ᵥ s.circumcenter /-- The position of the Monge point in relation to the circumcenter and centroid. -/ theorem mongePoint_eq_smul_vsub_vadd_circumcenter {n : ℕ} (s : Simplex ℝ P n) : s.mongePoint = (((n + 1 : ℕ) : ℝ) / ((n - 1 : ℕ) : ℝ)) • ((univ : Finset (Fin (n + 1))).centroid ℝ s.points -ᵥ s.circumcenter) +ᵥ s.circumcenter := rfl /-- The Monge point lies in the affine span. -/ theorem mongePoint_mem_affineSpan {n : ℕ} (s : Simplex ℝ P n) : s.mongePoint ∈ affineSpan ℝ (Set.range s.points) := smul_vsub_vadd_mem _ _ (centroid_mem_affineSpan_of_card_eq_add_one ℝ _ (card_fin (n + 1))) s.circumcenter_mem_affineSpan s.circumcenter_mem_affineSpan /-- Two simplices with the same points have the same Monge point. -/ theorem mongePoint_eq_of_range_eq {n : ℕ} {s₁ s₂ : Simplex ℝ P n} (h : Set.range s₁.points = Set.range s₂.points) : s₁.mongePoint = s₂.mongePoint := by simp_rw [mongePoint_eq_smul_vsub_vadd_circumcenter, centroid_eq_of_range_eq h, circumcenter_eq_of_range_eq h] /-- The weights for the Monge point of an (n+2)-simplex, in terms of `pointsWithCircumcenter`. -/ def mongePointWeightsWithCircumcenter (n : ℕ) : PointsWithCircumcenterIndex (n + 2) → ℝ \| pointIndex _ => ((n + 1 : ℕ) : ℝ)⁻¹ \| circumcenterIndex => -2 / ((n + 1 : ℕ) : ℝ) /-- `mongePointWeightsWithCircumcenter` sums to 1. -/ @[simp] theorem sum_mongePointWeightsWithCircumcenter (n : ℕ) : ∑ i, mongePointWeightsWithCircumcenter n i = 1 := by simp_rw [sum_pointsWithCircumcenter, mongePointWeightsWithCircumcenter, sum_const, card_fin, nsmul_eq_mul] field_simp ring /-- The Monge point of an (n+2)-simplex, in terms of `pointsWithCircumcenter`. -/ theorem mongePoint_eq_affineCombination_of_pointsWithCircumcenter {n : ℕ} (s : Simplex ℝ P (n + 2)) : s.mongePoint = (univ : Finset (PointsWithCircumcenterIndex (n + 2))).affineCombination ℝ s.pointsWithCircumcenter (mongePointWeightsWithCircumcenter n) := by rw [mongePoint_eq_smul_vsub_vadd_circumcenter, centroid_eq_affineCombination_of_pointsWithCircumcenter, circumcenter_eq_affineCombination_of_pointsWithCircumcenter, affineCombination_vsub, ← LinearMap.map_smul, weightedVSub_vadd_affineCombination] congr with i rw [Pi.add_apply, Pi.smul_apply, smul_eq_mul, Pi.sub_apply] -- Porting note: replaced -- have hn1 : (n + 1 : ℝ) ≠ 0 := mod_cast Nat.succ_ne_zero _ have hn1 : (n + 1 : ℝ) ≠ 0 := n.cast_add_one_ne_zero cases i <;> simp_rw [centroidWeightsWithCircumcenter, circumcenterWeightsWithCircumcenter, mongePointWeightsWithCircumcenter] <;> rw [add_tsub_assoc_of_le (by decide : 1 ≤ 2), (by decide : 2 - 1 = 1)] · rw [if_pos (mem_univ _), sub_zero, add_zero, card_fin] -- Porting note: replaced -- have hn3 : (n + 2 + 1 : ℝ) ≠ 0 := mod_cast Nat.succ_ne_zero _ have hn3 : (n + 2 + 1 : ℝ) ≠ 0 := by norm_cast field_simp [hn1, hn3, mul_comm] · field_simp [hn1] ring /-- The weights for the Monge point of an (n+2)-simplex, minus the centroid of an n-dimensional face, in terms of `pointsWithCircumcenter`. This definition is only valid when `i₁ ≠ i₂`. -/ def mongePointVSubFaceCentroidWeightsWithCircumcenter {n : ℕ} (i₁ i₂ : Fin (n + 3)) : PointsWithCircumcenterIndex (n + 2) → ℝ \| pointIndex i => if i = i₁ ∨ i = i₂ then ((n + 1 : ℕ) : ℝ)⁻¹ else 0 \| circumcenterIndex => -2 / ((n + 1 : ℕ) : ℝ) /-- `mongePointVSubFaceCentroidWeightsWithCircumcenter` is the result of subtracting `centroidWeightsWithCircumcenter` from `mongePointWeightsWithCircumcenter`. -/ theorem mongePointVSubFaceCentroidWeightsWithCircumcenter_eq_sub {n : ℕ} {i₁ i₂ : Fin (n + 3)} (h : i₁ ≠ i₂) : mongePointVSubFaceCentroidWeightsWithCircumcenter i₁ i₂ = mongePointWeightsWithCircumcenter n - centroidWeightsWithCircumcenter {i₁, i₂}ᶜ := by ext i obtain i \| i := i · rw [Pi.sub_apply, mongePointWeightsWithCircumcenter, centroidWeightsWithCircumcenter, mongePointVSubFaceCentroidWeightsWithCircumcenter] have hu : #{i₁, i₂}ᶜ = n + 1 := by simp [card_compl, Fintype.card_fin, h] rw [hu] by_cases hi : i = i₁ ∨ i = i₂ <;> simp [compl_eq_univ_sdiff, hi] · simp [mongePointWeightsWithCircumcenter, centroidWeightsWithCircumcenter, mongePointVSubFaceCentroidWeightsWithCircumcenter] /-- `mongePointVSubFaceCentroidWeightsWithCircumcenter` sums to 0. -/ @[simp] theorem sum_mongePointVSubFaceCentroidWeightsWithCircumcenter {n : ℕ} {i₁ i₂ : Fin (n + 3)} (h : i₁ ≠ i₂) : ∑ i, mongePointVSubFaceCentroidWeightsWithCircumcenter i₁ i₂ i = 0 := by rw [mongePointVSubFaceCentroidWeightsWithCircumcenter_eq_sub h] simp_rw [Pi.sub_apply, sum_sub_distrib, sum_mongePointWeightsWithCircumcenter] rw [sum_centroidWeightsWithCircumcenter, sub_self] simp [← card_pos, card_compl, h] /-- The Monge point of an (n+2)-simplex, minus the centroid of an n-dimensional face, in terms of `pointsWithCircumcenter`. -/ theorem mongePoint_vsub_face_centroid_eq_weightedVSub_of_pointsWithCircumcenter {n : ℕ} (s : Simplex ℝ P (n + 2)) {i₁ i₂ : Fin (n + 3)} (h : i₁ ≠ i₂) : s.mongePoint -ᵥ ({i₁, i₂}ᶜ : Finset (Fin (n + 3))).centroid ℝ s.points = (univ : Finset (PointsWithCircumcenterIndex (n + 2))).weightedVSub s.pointsWithCircumcenter (mongePointVSubFaceCentroidWeightsWithCircumcenter i₁ i₂) := by simp_rw [mongePoint_eq_affineCombination_of_pointsWithCircumcenter, centroid_eq_affineCombination_of_pointsWithCircumcenter, affineCombination_vsub, mongePointVSubFaceCentroidWeightsWithCircumcenter_eq_sub h] /-- The Monge point of an (n+2)-simplex, minus the centroid of an n-dimensional face, is orthogonal to the difference of the two vertices not in that face. -/ theorem inner_mongePoint_vsub_face_centroid_vsub {n : ℕ} (s : Simplex ℝ P (n + 2)) {i₁ i₂ : Fin (n + 3)} : ⟪s.mongePoint -ᵥ ({i₁, i₂}ᶜ : Finset (Fin (n + 3))).centroid ℝ s.points, s.points i₁ -ᵥ s.points i₂⟫ = 0 := by by_cases h : i₁ = i₂ · simp [h] simp_rw [mongePoint_vsub_face_centroid_eq_weightedVSub_of_pointsWithCircumcenter s h, point_eq_affineCombination_of_pointsWithCircumcenter, affineCombination_vsub] have hs : ∑ i, (pointWeightsWithCircumcenter i₁ - pointWeightsWithCircumcenter i₂) i = 0 := by simp rw [inner_weightedVSub _ (sum_mongePointVSubFaceCentroidWeightsWithCircumcenter h) _ hs, sum_pointsWithCircumcenter, pointsWithCircumcenter_eq_circumcenter] simp only [mongePointVSubFaceCentroidWeightsWithCircumcenter, pointsWithCircumcenter_point] let fs : Finset (Fin (n + 3)) := {i₁, i₂} have hfs : ∀ i : Fin (n + 3), i ∉ fs → i ≠ i₁ ∧ i ≠ i₂ := by intro i hi constructor <;> · intro hj; simp [fs, ← hj] at hi rw [← sum_subset fs.subset_univ _] · simp_rw [sum_pointsWithCircumcenter, pointsWithCircumcenter_eq_circumcenter, pointsWithCircumcenter_point, Pi.sub_apply, pointWeightsWithCircumcenter] rw [← sum_subset fs.subset_univ _] · simp_rw [fs, sum_insert (not_mem_singleton.2 h), sum_singleton] repeat rw [← sum_subset fs.subset_univ _] · simp_rw [fs, sum_insert (not_mem_singleton.2 h), sum_singleton] simp [h, Ne.symm h, dist_comm (s.points i₁)] all_goals intro i _ hi; simp [hfs i hi] · intro i _ hi simp [hfs i hi, pointsWithCircumcenter] · intro i _ hi simp [hfs i hi] /-- A Monge plane of an (n+2)-simplex is the (n+1)-dimensional affine subspace of the subspace spanned by the simplex that passes through the centroid of an n-dimensional face and is orthogonal to the opposite edge (in 2 dimensions, this is the same as an altitude). This definition is only intended to be used when `i₁ ≠ i₂`. -/ def mongePlane {n : ℕ} (s : Simplex ℝ P (n + 2)) (i₁ i₂ : Fin (n + 3)) : AffineSubspace ℝ P := mk' (({i₁, i₂}ᶜ : Finset (Fin (n + 3))).centroid ℝ s.points) (ℝ ∙ s.points i₁ -ᵥ s.points i₂)ᗮ ⊓ affineSpan ℝ (Set.range s.points) /-- The definition of a Monge plane. -/ theorem mongePlane_def {n : ℕ} (s : Simplex ℝ P (n + 2)) (i₁ i₂ : Fin (n + 3)) : s.mongePlane i₁ i₂ = mk' (({i₁, i₂}ᶜ : Finset (Fin (n + 3))).centroid ℝ s.points) (ℝ ∙ s.points i₁ -ᵥ s.points i₂)ᗮ ⊓ affineSpan ℝ (Set.range s.points) := rfl /-- The Monge plane associated with vertices `i₁` and `i₂` equals that associated with `i₂` and `i₁`. -/ theorem mongePlane_comm {n : ℕ} (s : Simplex ℝ P (n + 2)) (i₁ i₂ : Fin (n + 3)) : s.mongePlane i₁ i₂ = s.mongePlane i₂ i₁ := by simp_rw [mongePlane_def] congr 3 · congr 1 exact pair_comm _ _ · ext simp_rw [Submodule.mem_span_singleton] constructor all_goals rintro ⟨r, rfl⟩; use -r; rw [neg_smul, ← smul_neg, neg_vsub_eq_vsub_rev] /-- The Monge point lies in the Monge planes. -/ theorem mongePoint_mem_mongePlane {n : ℕ} (s : Simplex ℝ P (n + 2)) {i₁ i₂ : Fin (n + 3)} : s.mongePoint ∈ s.mongePlane i₁ i₂ := by rw [mongePlane_def, mem_inf_iff, ← vsub_right_mem_direction_iff_mem (self_mem_mk' _ _), direction_mk', Submodule.mem_orthogonal'] refine ⟨?_, s.mongePoint_mem_affineSpan⟩ intro v hv rcases Submodule.mem_span_singleton.mp hv with ⟨r, rfl⟩ rw [inner_smul_right, s.inner_mongePoint_vsub_face_centroid_vsub, mul_zero] /-- The direction of a Monge plane. -/ theorem direction_mongePlane {n : ℕ} (s : Simplex ℝ P (n + 2)) {i₁ i₂ : Fin (n + 3)} : (s.mongePlane i₁ i₂).direction = (ℝ ∙ s.points i₁ -ᵥ s.points i₂)ᗮ ⊓ vectorSpan ℝ (Set.range s.points) := by rw [mongePlane_def, direction_inf_of_mem_inf s.mongePoint_mem_mongePlane, direction_mk', direction_affineSpan] /-- The Monge point is the only point in all the Monge planes from any one vertex. -/ theorem eq_mongePoint_of_forall_mem_mongePlane {n : ℕ} {s : Simplex ℝ P (n + 2)} {i₁ : Fin (n + 3)} {p : P} (h : ∀ i₂, i₁ ≠ i₂ → p ∈ s.mongePlane i₁ i₂) : p = s.mongePoint := by rw [← @vsub_eq_zero_iff_eq V] have h' : ∀ i₂, i₁ ≠ i₂ → p -ᵥ s.mongePoint ∈ (ℝ ∙ s.points i₁ -ᵥ s.points i₂)ᗮ ⊓ vectorSpan ℝ (Set.range s.points) := by intro i₂ hne rw [← s.direction_mongePlane, vsub_right_mem_direction_iff_mem s.mongePoint_mem_mongePlane] exact h i₂ hne have hi : p -ᵥ s.mongePoint ∈ ⨅ i₂ : { i // i₁ ≠ i }, (ℝ ∙ s.points i₁ -ᵥ s.points i₂)ᗮ := by rw [Submodule.mem_iInf] exact fun i => (Submodule.mem_inf.1 (h' i i.property)).1 rw [Submodule.iInf_orthogonal, ← Submodule.span_iUnion] at hi have hu : ⋃ i : { i // i₁ ≠ i }, ({s.points i₁ -ᵥ s.points i} : Set V) = (s.points i₁ -ᵥ ·) '' (s.points '' (Set.univ \ {i₁})) := by rw [Set.image_image] ext x simp_rw [Set.mem_iUnion, Set.mem_image, Set.mem_singleton_iff, Set.mem_diff_singleton] constructor · rintro ⟨i, rfl⟩ use i, ⟨Set.mem_univ _, i.property.symm⟩ · rintro ⟨i, ⟨-, hi⟩, rfl⟩ use ⟨i, hi.symm⟩ rw [hu, ← vectorSpan_image_eq_span_vsub_set_left_ne ℝ _ (Set.mem_univ _), Set.image_univ] at hi have hv : p -ᵥ s.mongePoint ∈ vectorSpan ℝ (Set.range s.points) := by let s₁ : Finset (Fin (n + 3)) := univ.erase i₁ obtain ⟨i₂, h₂⟩ := card_pos.1 (show 0 < #s₁ by simp [s₁, card_erase_of_mem]) have h₁₂ : i₁ ≠ i₂ := (ne_of_mem_erase h₂).symm exact (Submodule.mem_inf.1 (h' i₂ h₁₂)).2 exact Submodule.disjoint_def.1 (vectorSpan ℝ (Set.range s.points)).orthogonal_disjoint _ hv hi end Simplex namespace Triangle open EuclideanGeometry Finset Simplex AffineSubspace Module variable {V : Type} {P : Type} [NormedAddCommGroup V] [InnerProductSpace ℝ V] [MetricSpace P] [NormedAddTorsor V P] /-- The orthocenter of a triangle is the intersection of its altitudes. It is defined here as the 2-dimensional case of the Monge point. -/ def orthocenter (t : Triangle ℝ P) : P := t.mongePoint /-- The orthocenter equals the Monge point. -/ theorem orthocenter_eq_mongePoint (t : Triangle ℝ P) : t.orthocenter = t.mongePoint := rfl /-- The position of the orthocenter in relation to the circumcenter and centroid. -/ theorem orthocenter_eq_smul_vsub_vadd_circumcenter (t : Triangle ℝ P) : t.orthocenter = (3 : ℝ) • ((univ : Finset (Fin 3)).centroid ℝ t.points -ᵥ t.circumcenter : V) +ᵥ t.circumcenter := by rw [orthocenter_eq_mongePoint, mongePoint_eq_smul_vsub_vadd_circumcenter] norm_num /-- The orthocenter lies in the affine span. -/ theorem orthocenter_mem_affineSpan (t : Triangle ℝ P) : t.orthocenter ∈ affineSpan ℝ (Set.range t.points) := t.mongePoint_mem_affineSpan /-- Two triangles with the same points have the same orthocenter. -/ theorem orthocenter_eq_of_range_eq {t₁ t₂ : Triangle ℝ P} (h : Set.range t₁.points = Set.range t₂.points) : t₁.orthocenter = t₂.orthocenter := mongePoint_eq_of_range_eq h /-- In the case of a triangle, altitudes are the same thing as Monge planes. -/ theorem altitude_eq_mongePlane (t : Triangle ℝ P) {i₁ i₂ i₃ : Fin 3} (h₁₂ : i₁ ≠ i₂) (h₁₃ : i₁ ≠ i₃) (h₂₃ : i₂ ≠ i₃) : t.altitude i₁ = t.mongePlane i₂ i₃ := by have hs : ({i₂, i₃}ᶜ : Finset (Fin 3)) = {i₁} := by decide +revert have he : univ.erase i₁ = {i₂, i₃} := by decide +revert rw [mongePlane_def, altitude_def, direction_affineSpan, hs, he, centroid_singleton, coe_insert, coe_singleton, vectorSpan_image_eq_span_vsub_set_left_ne ℝ _ (Set.mem_insert i₂ _)] simp [h₂₃, Submodule.span_insert_eq_span] /-- The orthocenter lies in the altitudes. -/ theorem orthocenter_mem_altitude (t : Triangle ℝ P) {i₁ : Fin 3} : t.orthocenter ∈ t.altitude i₁ := by obtain ⟨i₂, i₃, h₁₂, h₂₃, h₁₃⟩ : ∃ i₂ i₃, i₁ ≠ i₂ ∧ i₂ ≠ i₃ ∧ i₁ ≠ i₃ := by decide +revert rw [orthocenter_eq_mongePoint, t.altitude_eq_mongePlane h₁₂ h₁₃ h₂₃] exact t.mongePoint_mem_mongePlane /-- The orthocenter is the only point lying in any two of the altitudes. -/ theorem eq_orthocenter_of_forall_mem_altitude {t : Triangle ℝ P} {i₁ i₂ : Fin 3} {p : P} (h₁₂ : i₁ ≠ i₂) (h₁ : p ∈ t.altitude i₁) (h₂ : p ∈ t.altitude i₂) : p = t.orthocenter := by obtain ⟨i₃, h₂₃, h₁₃⟩ : ∃ i₃, i₂ ≠ i₃ ∧ i₁ ≠ i₃ := by clear h₁ h₂ decide +revert rw [t.altitude_eq_mongePlane h₁₃ h₁₂ h₂₃.symm] at h₁ rw [t.altitude_eq_mongePlane h₂₃ h₁₂.symm h₁₃.symm] at h₂ rw [orthocenter_eq_mongePoint] have ha : ∀ i, i₃ ≠ i → p ∈ t.mongePlane i₃ i := by intro i hi obtain rfl \| rfl : i₁ = i ∨ i₂ = i := by omega all_goals assumption exact eq_mongePoint_of_forall_mem_mongePlane ha /-- The distance from the orthocenter to the reflection of the circumcenter in a side equals the circumradius. -/ theorem dist_orthocenter_reflection_circumcenter (t : Triangle ℝ P) {i₁ i₂ : Fin 3} (h : i₁ ≠ i₂) : dist t.orthocenter (reflection (affineSpan ℝ (t.points '' {i₁, i₂})) t.circumcenter) = t.circumradius := by rw [← mul_self_inj_of_nonneg dist_nonneg t.circumradius_nonneg, t.reflection_circumcenter_eq_affineCombination_of_pointsWithCircumcenter h, t.orthocenter_eq_mongePoint, mongePoint_eq_affineCombination_of_pointsWithCircumcenter, dist_affineCombination t.pointsWithCircumcenter (sum_mongePointWeightsWithCircumcenter _) (sum_reflectionCircumcenterWeightsWithCircumcenter h)] simp_rw [sum_pointsWithCircumcenter, Pi.sub_apply, mongePointWeightsWithCircumcenter, reflectionCircumcenterWeightsWithCircumcenter] have hu : ({i₁, i₂} : Finset (Fin 3)) ⊆ univ := subset_univ _ obtain ⟨i₃, hi₃, hi₃₁, hi₃₂⟩ : ∃ i₃, univ \ ({i₁, i₂} : Finset (Fin 3)) = {i₃} ∧ i₃ ≠ i₁ ∧ i₃ ≠ i₂ := by decide +revert simp_rw [← sum_sdiff hu, hi₃] norm_num [hi₃₁, hi₃₂] /-- The distance from the orthocenter to the reflection of the circumcenter in a side equals the circumradius, variant using a `Finset`. -/ theorem dist_orthocenter_reflection_circumcenter_finset (t : Triangle ℝ P) {i₁ i₂ : Fin 3} (h : i₁ ≠ i₂) : dist t.orthocenter (reflection (affineSpan ℝ (t.points '' ↑({i₁, i₂} : Finset (Fin 3)))) t.circumcenter) = t.circumradius := by simp only [mem_singleton, coe_insert, coe_singleton, Set.mem_singleton_iff] exact dist_orthocenter_reflection_circumcenter _ h /-- The affine span of the orthocenter and a vertex is contained in the altitude. -/ theorem affineSpan_orthocenter_point_le_altitude (t : Triangle ℝ P) (i : Fin 3) : line[ℝ, t.orthocenter, t.points i] ≤ t.altitude i := by refine affineSpan_le_of_subset_coe ?_ rw [Set.insert_subset_iff, Set.singleton_subset_iff] exact ⟨t.orthocenter_mem_altitude, t.mem_altitude i⟩ /-- Suppose we are given a triangle `t₁`, and replace one of its vertices by its orthocenter, yielding triangle `t₂` (with vertices not necessarily listed in the same order). Then an altitude of `t₂` from a vertex that was not replaced is the corresponding side of `t₁`. -/ theorem altitude_replace_orthocenter_eq_affineSpan {t₁ t₂ : Triangle ℝ P} {i₁ i₂ i₃ j₁ j₂ j₃ : Fin 3} (hi₁₂ : i₁ ≠ i₂) (hi₁₃ : i₁ ≠ i₃) (hi₂₃ : i₂ ≠ i₃) (hj₁₂ : j₁ ≠ j₂) (hj₁₃ : j₁ ≠ j₃) (hj₂₃ : j₂ ≠ j₃) (h₁ : t₂.points j₁ = t₁.orthocenter) (h₂ : t₂.points j₂ = t₁.points i₂) (h₃ : t₂.points j₃ = t₁.points i₃) : t₂.altitude j₂ = line[ℝ, t₁.points i₁, t₁.points i₂] := by symm rw [← h₂, t₂.affineSpan_pair_eq_altitude_iff] rw [h₂] use t₁.independent.injective.ne hi₁₂ have he : affineSpan ℝ (Set.range t₂.points) = affineSpan ℝ (Set.range t₁.points) := by refine ext_of_direction_eq ?_ ⟨t₁.points i₃, mem_affineSpan ℝ ⟨j₃, h₃⟩, mem_affineSpan ℝ (Set.mem_range_self _)⟩ refine Submodule.eq_of_le_of_finrank_eq (direction_le (affineSpan_le_of_subset_coe ?_)) ?_ · have hu : (Finset.univ : Finset (Fin 3)) = {j₁, j₂, j₃} := by clear h₁ h₂ h₃ decide +revert rw [← Set.image_univ, ← Finset.coe_univ, hu, Finset.coe_insert, Finset.coe_insert, Finset.coe_singleton, Set.image_insert_eq, Set.image_insert_eq, Set.image_singleton, h₁, h₂, h₃, Set.insert_subset_iff, Set.insert_subset_iff, Set.singleton_subset_iff] exact ⟨t₁.orthocenter_mem_affineSpan, mem_affineSpan ℝ (Set.mem_range_self _), mem_affineSpan ℝ (Set.mem_range_self _)⟩ · rw [direction_affineSpan, direction_affineSpan, t₁.independent.finrank_vectorSpan (Fintype.card_fin _), t₂.independent.finrank_vectorSpan (Fintype.card_fin _)] rw [he] use mem_affineSpan ℝ (Set.mem_range_self _) have hu : Finset.univ.erase j₂ = {j₁, j₃} := by clear h₁ h₂ h₃ decide +revert rw [hu, Finset.coe_insert, Finset.coe_singleton, Set.image_insert_eq, Set.image_singleton, h₁, h₃] have hle : (t₁.altitude i₃).directionᗮ ≤ line[ℝ, t₁.orthocenter, t₁.points i₃].directionᗮ := Submodule.orthogonal_le (direction_le (affineSpan_orthocenter_point_le_altitude _ _)) refine hle ((t₁.vectorSpan_isOrtho_altitude_direction i₃) ?_) have hui : Finset.univ.erase i₃ = {i₁, i₂} := by clear hle h₂ h₃ decide +revert rw [hui, Finset.coe_insert, Finset.coe_singleton, Set.image_insert_eq, Set.image_singleton] exact vsub_mem_vectorSpan ℝ (Set.mem_insert _ _) (Set.mem_insert_of_mem _ (Set.mem_singleton _)) /-- Suppose we are given a triangle `t₁`, and replace one of its vertices by its orthocenter, yielding triangle `t₂` (with vertices not necessarily listed in the same order). Then the orthocenter of `t₂` is the vertex of `t₁` that was replaced. -/ theorem orthocenter_replace_orthocenter_eq_point {t₁ t₂ : Triangle ℝ P} {i₁ i₂ i₃ j₁ j₂ j₃ : Fin 3} (hi₁₂ : i₁ ≠ i₂) (hi₁₃ : i₁ ≠ i₃) (hi₂₃ : i₂ ≠ i₃) (hj₁₂ : j₁ ≠ j₂) (hj₁₃ : j₁ ≠ j₃) (hj₂₃ : j₂ ≠ j₃) (h₁ : t₂.points j₁ = t₁.orthocenter) (h₂ : t₂.points j₂ = t₁.points i₂) (h₃ : t₂.points j₃ = t₁.points i₃) : t₂.orthocenter = t₁.points i₁ := by refine (Triangle.eq_orthocenter_of_forall_mem_altitude hj₂₃ ?_ ?_).symm · rw [altitude_replace_orthocenter_eq_affineSpan hi₁₂ hi₁₃ hi₂₃ hj₁₂ hj₁₃ hj₂₃ h₁ h₂ h₃] exact mem_affineSpan ℝ (Set.mem_insert _ _) · rw [altitude_replace_orthocenter_eq_affineSpan hi₁₃ hi₁₂ hi₂₃.symm hj₁₃ hj₁₂ hj₂₃.symm h₁ h₃ h₂] exact mem_affineSpan ℝ (Set.mem_insert _ _) end Triangle end Affine namespace EuclideanGeometry open Affine AffineSubspace Module variable {V : Type} {P : Type} [NormedAddCommGroup V] [InnerProductSpace ℝ V] [MetricSpace P] [NormedAddTorsor V P] /-- Four points form an orthocentric system if they consist of the vertices of a triangle and its orthocenter. -/ def OrthocentricSystem (s : Set P) : Prop := ∃ t : Triangle ℝ P, t.orthocenter ∉ Set.range t.points ∧ s = insert t.orthocenter (Set.range t.points) /-- This is an auxiliary lemma giving information about the relation of two triangles in an orthocentric system; it abstracts some reasoning, with no geometric content, that is common to some other lemmas. Suppose the orthocentric system is generated by triangle `t`, and we are given three points `p` in the orthocentric system. Then either we can find indices `i₁`, `i₂` and `i₃` for `p` such that `p i₁` is the orthocenter of `t` and `p i₂` and `p i₃` are points `j₂` and `j₃` of `t`, or `p` has the same points as `t`. -/ theorem exists_of_range_subset_orthocentricSystem {t : Triangle ℝ P} (ho : t.orthocenter ∉ Set.range t.points) {p : Fin 3 → P} (hps : Set.range p ⊆ insert t.orthocenter (Set.range t.points)) (hpi : Function.Injective p) : (∃ i₁ i₂ i₃ j₂ j₃ : Fin 3, i₁ ≠ i₂ ∧ i₁ ≠ i₃ ∧ i₂ ≠ i₃ ∧ (∀ i : Fin 3, i = i₁ ∨ i = i₂ ∨ i = i₃) ∧ p i₁ = t.orthocenter ∧ j₂ ≠ j₃ ∧ t.points j₂ = p i₂ ∧ t.points j₃ = p i₃) ∨ Set.range p = Set.range t.points := by by_cases h : t.orthocenter ∈ Set.range p · left rcases h with ⟨i₁, h₁⟩ obtain ⟨i₂, i₃, h₁₂, h₁₃, h₂₃, h₁₂₃⟩ : ∃ i₂ i₃ : Fin 3, i₁ ≠ i₂ ∧ i₁ ≠ i₃ ∧ i₂ ≠ i₃ ∧ ∀ i : Fin 3, i = i₁ ∨ i = i₂ ∨ i = i₃ := by clear h₁ decide +revert have h : ∀ i, i₁ ≠ i → ∃ j : Fin 3, t.points j = p i := by intro i hi replace hps := Set.mem_of_mem_insert_of_ne (Set.mem_of_mem_of_subset (Set.mem_range_self i) hps) (h₁ ▸ hpi.ne hi.symm) exact hps rcases h i₂ h₁₂ with ⟨j₂, h₂⟩ rcases h i₃ h₁₃ with ⟨j₃, h₃⟩ have hj₂₃ : j₂ ≠ j₃ := by intro he rw [he, h₃] at h₂ exact h₂₃.symm (hpi h₂) exact ⟨i₁, i₂, i₃, j₂, j₃, h₁₂, h₁₃, h₂₃, h₁₂₃, h₁, hj₂₃, h₂, h₃⟩ · right have hs := Set.subset_diff_singleton hps h rw [Set.insert_diff_self_of_not_mem ho] at hs classical refine Set.eq_of_subset_of_card_le hs ?_ rw [Set.card_range_of_injective hpi, Set.card_range_of_injective t.independent.injective] /-- For any three points in an orthocentric system generated by triangle `t`, there is a point in the subspace spanned by the triangle from which the distance of all those three points equals the circumradius. -/ theorem exists_dist_eq_circumradius_of_subset_insert_orthocenter {t : Triangle ℝ P} (ho : t.orthocenter ∉ Set.range t.points) {p : Fin 3 → P} (hps : Set.range p ⊆ insert t.orthocenter (Set.range t.points)) (hpi : Function.Injective p) : ∃ c ∈ affineSpan ℝ (Set.range t.points), ∀ p₁ ∈ Set.range p, dist p₁ c = t.circumradius := by rcases exists_of_range_subset_orthocentricSystem ho hps hpi with (⟨i₁, i₂, i₃, j₂, j₃, _, _, _, h₁₂₃, h₁, hj₂₃, h₂, h₃⟩ \| hs) · use reflection (affineSpan ℝ (t.points '' {j₂, j₃})) t.circumcenter, reflection_mem_of_le_of_mem (affineSpan_mono ℝ (Set.image_subset_range _ _)) t.circumcenter_mem_affineSpan intro p₁ hp₁ rcases hp₁ with ⟨i, rfl⟩ have h₁₂₃ := h₁₂₃ i repeat' rcases h₁₂₃ with h₁₂₃ \| h₁₂₃ · convert Triangle.dist_orthocenter_reflection_circumcenter t hj₂₃ · rw [← h₂, dist_reflection_eq_of_mem _ (mem_affineSpan ℝ (Set.mem_image_of_mem _ (Set.mem_insert _ _)))] exact t.dist_circumcenter_eq_circumradius _ · rw [← h₃, dist_reflection_eq_of_mem _ (mem_affineSpan ℝ (Set.mem_image_of_mem _ (Set.mem_insert_of_mem _ (Set.mem_singleton _))))] exact t.dist_circumcenter_eq_circumradius _ · use t.circumcenter, t.circumcenter_mem_affineSpan intro p₁ hp₁ rw [hs] at hp₁ rcases hp₁ with ⟨i, rfl⟩ exact t.dist_circumcenter_eq_circumradius _ /-- Any three points in an orthocentric system are affinely independent. -/ theorem OrthocentricSystem.affineIndependent {s : Set P} (ho : OrthocentricSystem s) {p : Fin 3 → P} (hps : Set.range p ⊆ s) (hpi : Function.Injective p) : AffineIndependent ℝ p := by rcases ho with ⟨t, hto, hst⟩ rw [hst] at hps rcases exists_dist_eq_circumradius_of_subset_insert_orthocenter hto hps hpi with ⟨c, _, hc⟩ exact Cospherical.affineIndependent ⟨c, t.circumradius, hc⟩ Set.Subset.rfl hpi /-- Any three points in an orthocentric system span the same subspace as the whole orthocentric system. -/ theorem affineSpan_of_orthocentricSystem {s : Set P} (ho : OrthocentricSystem s) {p : Fin 3 → P} (hps : Set.range p ⊆ s) (hpi : Function.Injective p) : affineSpan ℝ (Set.range p) = affineSpan ℝ s := by have ha := ho.affineIndependent hps hpi rcases ho with ⟨t, _, hts⟩ have hs : affineSpan ℝ s = affineSpan ℝ (Set.range t.points) := by rw [hts, affineSpan_insert_eq_affineSpan ℝ t.orthocenter_mem_affineSpan] refine ext_of_direction_eq ?_ ⟨p 0, mem_affineSpan ℝ (Set.mem_range_self _), mem_affineSpan ℝ (hps (Set.mem_range_self _))⟩ have hfd : FiniteDimensional ℝ (affineSpan ℝ s).direction := by rw [hs]; infer_instance haveI := hfd refine Submodule.eq_of_le_of_finrank_eq (direction_le (affineSpan_mono ℝ hps)) ?_ rw [hs, direction_affineSpan, direction_affineSpan, ha.finrank_vectorSpan (Fintype.card_fin _), t.independent.finrank_vectorSpan (Fintype.card_fin _)] /-- All triangles in an orthocentric system have the same circumradius. -/ theorem OrthocentricSystem.exists_circumradius_eq {s : Set P} (ho : OrthocentricSystem s) : ∃ r : ℝ, ∀ t : Triangle ℝ P, Set.range t.points ⊆ s → t.circumradius = r := by rcases ho with ⟨t, hto, hts⟩ use t.circumradius intro t₂ ht₂ have ht₂s := ht₂ rw [hts] at ht₂ rcases exists_dist_eq_circumradius_of_subset_insert_orthocenter hto ht₂ t₂.independent.injective with ⟨c, hc, h⟩ rw [Set.forall_mem_range] at h have hs : Set.range t.points ⊆ s := by rw [hts] exact Set.subset_insert _ _ rw [affineSpan_of_orthocentricSystem ⟨t, hto, hts⟩ hs t.independent.injective, ← affineSpan_of_orthocentricSystem ⟨t, hto, hts⟩ ht₂s t₂.independent.injective] at hc exact (t₂.eq_circumradius_of_dist_eq hc h).symm /-- Given any triangle in an orthocentric system, the fourth point is its orthocenter. -/ theorem OrthocentricSystem.eq_insert_orthocenter {s : Set P} (ho : OrthocentricSystem s) {t : Triangle ℝ P} (ht : Set.range t.points ⊆ s) : s = insert t.orthocenter (Set.range t.points) := by rcases ho with ⟨t₀, ht₀o, ht₀s⟩ rw [ht₀s] at ht rcases exists_of_range_subset_orthocentricSystem ht₀o ht t.independent.injective with (⟨i₁, i₂, i₃, j₂, j₃, h₁₂, h₁₃, h₂₃, h₁₂₃, h₁, hj₂₃, h₂, h₃⟩ \| hs) · obtain ⟨j₁, hj₁₂, hj₁₃, hj₁₂₃⟩ : ∃ j₁ : Fin 3, j₁ ≠ j₂ ∧ j₁ ≠ j₃ ∧ ∀ j : Fin 3, j = j₁ ∨ j = j₂ ∨ j = j₃ := by clear h₂ h₃ decide +revert suffices h : t₀.points j₁ = t.orthocenter by have hui : (Set.univ : Set (Fin 3)) = {i₁, i₂, i₃} := by ext x; simpa using h₁₂₃ x have huj : (Set.univ : Set (Fin 3)) = {j₁, j₂, j₃} := by ext x; simpa using hj₁₂₃ x rw [← h, ht₀s, ← Set.image_univ, huj, ← Set.image_univ, hui] simp_rw [Set.image_insert_eq, Set.image_singleton, h₁, ← h₂, ← h₃] rw [Set.insert_comm] exact (Triangle.orthocenter_replace_orthocenter_eq_point hj₁₂ hj₁₃ hj₂₃ h₁₂ h₁₃ h₂₃ h₁ h₂.symm h₃.symm).symm · rw [hs] convert ht₀s using 2 exact Triangle.orthocenter_eq_of_range_eq hs end EuclideanGeometry		Mathlib/Geometry/Euclidean/MongePoint.lean	775	798
/- Copyright (c) 2018 Mario Carneiro. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro -/ import Mathlib.Data.Fin.VecNotation import Mathlib.Logic.Small.Basic import Mathlib.SetTheory.ZFC.PSet /-! # A model of ZFC In this file, we model Zermelo-Fraenkel set theory (+ choice) using Lean's underlying type theory, building on the pre-sets defined in `Mathlib.SetTheory.ZFC.PSet`. The theory of classes is developed in `Mathlib.SetTheory.ZFC.Class`. ## Main definitions * `ZFSet`: ZFC set. Defined as `PSet` quotiented by `PSet.Equiv`, the extensional equivalence. * `ZFSet.choice`: Axiom of choice. Proved from Lean's axiom of choice. * `ZFSet.omega`: The von Neumann ordinal `ω` as a `Set`. * `Classical.allZFSetDefinable`: All functions are classically definable. * `ZFSet.IsFunc` : Predicate that a ZFC set is a subset of `x × y` that can be considered as a ZFC function `x → y`. That is, each member of `x` is related by the ZFC set to exactly one member of `y`. * `ZFSet.funs`: ZFC set of ZFC functions `x → y`. * `ZFSet.Hereditarily p x`: Predicate that every set in the transitive closure of `x` has property `p`. ## Notes To avoid confusion between the Lean `Set` and the ZFC `Set`, docstrings in this file refer to them respectively as "`Set`" and "ZFC set". -/ universe u /-- The ZFC universe of sets consists of the type of pre-sets, quotiented by extensional equivalence. -/ @[pp_with_univ] def ZFSet : Type (u + 1) := Quotient PSet.setoid.{u} namespace ZFSet /-- Turns a pre-set into a ZFC set. -/ def mk : PSet → ZFSet := Quotient.mk'' @[simp] theorem mk_eq (x : PSet) : @Eq ZFSet ⟦x⟧ (mk x) := rfl @[simp] theorem mk_out : ∀ x : ZFSet, mk x.out = x := Quotient.out_eq /-- A set function is "definable" if it is the image of some n-ary `PSet` function. This isn't exactly definability, but is useful as a sufficient condition for functions that have a computable image. -/ class Definable (n) (f : (Fin n → ZFSet.{u}) → ZFSet.{u}) where /-- Turns a definable function into an n-ary `PSet` function. -/ out : (Fin n → PSet.{u}) → PSet.{u} /-- A set function `f` is the image of `Definable.out f`. -/ mk_out xs : mk (out xs) = f (mk <\| xs ·) := by simp attribute [simp] Definable.mk_out /-- An abbrev of `ZFSet.Definable` for unary functions. -/ abbrev Definable₁ (f : ZFSet.{u} → ZFSet.{u}) := Definable 1 (fun s ↦ f (s 0)) /-- A simpler constructor for `ZFSet.Definable₁`. -/ abbrev Definable₁.mk {f : ZFSet.{u} → ZFSet.{u}} (out : PSet.{u} → PSet.{u}) (mk_out : ∀ x, ⟦out x⟧ = f ⟦x⟧) : Definable₁ f where out xs := out (xs 0) mk_out xs := mk_out (xs 0) /-- Turns a unary definable function into a unary `PSet` function. -/ abbrev Definable₁.out (f : ZFSet.{u} → ZFSet.{u}) [Definable₁ f] : PSet.{u} → PSet.{u} := fun x ↦ Definable.out (fun s ↦ f (s 0)) ![x] lemma Definable₁.mk_out {f : ZFSet.{u} → ZFSet.{u}} [Definable₁ f] {x : PSet} : .mk (out f x) = f (.mk x) := Definable.mk_out ![x] /-- An abbrev of `ZFSet.Definable` for binary functions. -/ abbrev Definable₂ (f : ZFSet.{u} → ZFSet.{u} → ZFSet.{u}) := Definable 2 (fun s ↦ f (s 0) (s 1)) /-- A simpler constructor for `ZFSet.Definable₂`. -/ abbrev Definable₂.mk {f : ZFSet.{u} → ZFSet.{u} → ZFSet.{u}} (out : PSet.{u} → PSet.{u} → PSet.{u}) (mk_out : ∀ x y, ⟦out x y⟧ = f ⟦x⟧ ⟦y⟧) : Definable₂ f where out xs := out (xs 0) (xs 1) mk_out xs := mk_out (xs 0) (xs 1) /-- Turns a binary definable function into a binary `PSet` function. -/ abbrev Definable₂.out (f : ZFSet.{u} → ZFSet.{u} → ZFSet.{u}) [Definable₂ f] : PSet.{u} → PSet.{u} → PSet.{u} := fun x y ↦ Definable.out (fun s ↦ f (s 0) (s 1)) ![x, y] lemma Definable₂.mk_out {f : ZFSet.{u} → ZFSet.{u} → ZFSet.{u}} [Definable₂ f] {x y : PSet} : .mk (out f x y) = f (.mk x) (.mk y) := Definable.mk_out ![x, y] instance (f) [Definable₁ f] (n g) [Definable n g] : Definable n (fun s ↦ f (g s)) where out xs := Definable₁.out f (Definable.out g xs) instance (f) [Definable₂ f] (n g₁ g₂) [Definable n g₁] [Definable n g₂] : Definable n (fun s ↦ f (g₁ s) (g₂ s)) where out xs := Definable₂.out f (Definable.out g₁ xs) (Definable.out g₂ xs) instance (n) (i) : Definable n (fun s ↦ s i) where out s := s i lemma Definable.out_equiv {n} (f : (Fin n → ZFSet.{u}) → ZFSet.{u}) [Definable n f] {xs ys : Fin n → PSet} (h : ∀ i, xs i ≈ ys i) : out f xs ≈ out f ys := by rw [← Quotient.eq_iff_equiv, mk_eq, mk_eq, mk_out, mk_out] exact congrArg _ (funext fun i ↦ Quotient.sound (h i)) lemma Definable₁.out_equiv (f : ZFSet.{u} → ZFSet.{u}) [Definable₁ f] {x y : PSet} (h : x ≈ y) : out f x ≈ out f y := Definable.out_equiv _ (by simp [h]) lemma Definable₂.out_equiv (f : ZFSet.{u} → ZFSet.{u} → ZFSet.{u}) [Definable₂ f] {x₁ y₁ x₂ y₂ : PSet} (h₁ : x₁ ≈ y₁) (h₂ : x₂ ≈ y₂) : out f x₁ x₂ ≈ out f y₁ y₂ := Definable.out_equiv _ (by simp [Fin.forall_fin_succ, h₁, h₂]) end ZFSet namespace Classical open PSet ZFSet /-- All functions are classically definable. -/ noncomputable def allZFSetDefinable {n} (F : (Fin n → ZFSet.{u}) → ZFSet.{u}) : Definable n F where out xs := (F (mk <\| xs ·)).out end Classical namespace ZFSet open PSet theorem eq {x y : PSet} : mk x = mk y ↔ Equiv x y := Quotient.eq theorem sound {x y : PSet} (h : PSet.Equiv x y) : mk x = mk y := Quotient.sound h theorem exact {x y : PSet} : mk x = mk y → PSet.Equiv x y := Quotient.exact /-- The membership relation for ZFC sets is inherited from the membership relation for pre-sets. -/ protected def Mem : ZFSet → ZFSet → Prop := Quotient.lift₂ (· ∈ ·) fun _ _ _ _ hx hy => propext ((Mem.congr_left hx).trans (Mem.congr_right hy)) instance : Membership ZFSet ZFSet where mem t s := ZFSet.Mem s t @[simp] theorem mk_mem_iff {x y : PSet} : mk x ∈ mk y ↔ x ∈ y := Iff.rfl /-- Convert a ZFC set into a `Set` of ZFC sets -/ def toSet (u : ZFSet.{u}) : Set ZFSet.{u} := { x \| x ∈ u } @[simp] theorem mem_toSet (a u : ZFSet.{u}) : a ∈ u.toSet ↔ a ∈ u := Iff.rfl instance small_toSet (x : ZFSet.{u}) : Small.{u} x.toSet := Quotient.inductionOn x fun a => by let f : a.Type → (mk a).toSet := fun i => ⟨mk <\| a.Func i, func_mem a i⟩ suffices Function.Surjective f by exact small_of_surjective this rintro ⟨y, hb⟩ induction y using Quotient.inductionOn obtain ⟨i, h⟩ := hb exact ⟨i, Subtype.coe_injective (Quotient.sound h.symm)⟩ /-- A nonempty set is one that contains some element. -/ protected def Nonempty (u : ZFSet) : Prop := u.toSet.Nonempty theorem nonempty_def (u : ZFSet) : u.Nonempty ↔ ∃ x, x ∈ u := Iff.rfl theorem nonempty_of_mem {x u : ZFSet} (h : x ∈ u) : u.Nonempty := ⟨x, h⟩ @[simp] theorem nonempty_toSet_iff {u : ZFSet} : u.toSet.Nonempty ↔ u.Nonempty := Iff.rfl /-- `x ⊆ y` as ZFC sets means that all members of `x` are members of `y`. -/ protected def Subset (x y : ZFSet.{u}) := ∀ ⦃z⦄, z ∈ x → z ∈ y instance hasSubset : HasSubset ZFSet := ⟨ZFSet.Subset⟩ theorem subset_def {x y : ZFSet.{u}} : x ⊆ y ↔ ∀ ⦃z⦄, z ∈ x → z ∈ y := Iff.rfl instance : IsRefl ZFSet (· ⊆ ·) := ⟨fun _ _ => id⟩ instance : IsTrans ZFSet (· ⊆ ·) := ⟨fun _ _ _ hxy hyz _ ha => hyz (hxy ha)⟩ @[simp] theorem subset_iff : ∀ {x y : PSet}, mk x ⊆ mk y ↔ x ⊆ y \| ⟨_, A⟩, ⟨_, _⟩ => ⟨fun h a => @h ⟦A a⟧ (Mem.mk A a), fun h z => Quotient.inductionOn z fun _ ⟨a, za⟩ => let ⟨b, ab⟩ := h a ⟨b, za.trans ab⟩⟩ @[simp] theorem toSet_subset_iff {x y : ZFSet} : x.toSet ⊆ y.toSet ↔ x ⊆ y := by simp [subset_def, Set.subset_def] @[ext] theorem ext {x y : ZFSet.{u}} : (∀ z : ZFSet.{u}, z ∈ x ↔ z ∈ y) → x = y := Quotient.inductionOn₂ x y fun _ _ h => Quotient.sound (Mem.ext fun w => h ⟦w⟧) theorem toSet_injective : Function.Injective toSet := fun _ _ h => ext <\| Set.ext_iff.1 h @[simp] theorem toSet_inj {x y : ZFSet} : x.toSet = y.toSet ↔ x = y := toSet_injective.eq_iff instance : IsAntisymm ZFSet (· ⊆ ·) := ⟨fun _ _ hab hba => ext fun c => ⟨@hab c, @hba c⟩⟩ /-- The empty ZFC set -/ protected def empty : ZFSet := mk ∅ instance : EmptyCollection ZFSet := ⟨ZFSet.empty⟩ instance : Inhabited ZFSet := ⟨∅⟩ @[simp] theorem not_mem_empty (x) : x ∉ (∅ : ZFSet.{u}) := Quotient.inductionOn x PSet.not_mem_empty @[simp] theorem toSet_empty : toSet ∅ = ∅ := by simp [toSet] @[simp] theorem empty_subset (x : ZFSet.{u}) : (∅ : ZFSet) ⊆ x := Quotient.inductionOn x fun y => subset_iff.2 <\| PSet.empty_subset y @[simp] theorem not_nonempty_empty : ¬ZFSet.Nonempty ∅ := by simp [ZFSet.Nonempty] @[simp] theorem nonempty_mk_iff {x : PSet} : (mk x).Nonempty ↔ x.Nonempty := by refine ⟨?_, fun ⟨a, h⟩ => ⟨mk a, h⟩⟩ rintro ⟨a, h⟩ induction a using Quotient.inductionOn exact ⟨_, h⟩ theorem eq_empty (x : ZFSet.{u}) : x = ∅ ↔ ∀ y : ZFSet.{u}, y ∉ x := by simp [ZFSet.ext_iff] theorem eq_empty_or_nonempty (u : ZFSet) : u = ∅ ∨ u.Nonempty := by rw [eq_empty, ← not_exists] apply em' /-- `Insert x y` is the set `{x} ∪ y` -/ protected def Insert : ZFSet → ZFSet → ZFSet := Quotient.map₂ PSet.insert fun _ _ uv ⟨_, _⟩ ⟨_, _⟩ ⟨αβ, βα⟩ => ⟨fun o => match o with \| some a => let ⟨b, hb⟩ := αβ a ⟨some b, hb⟩ \| none => ⟨none, uv⟩, fun o => match o with \| some b => let ⟨a, ha⟩ := βα b ⟨some a, ha⟩ \| none => ⟨none, uv⟩⟩ instance : Insert ZFSet ZFSet := ⟨ZFSet.Insert⟩ instance : Singleton ZFSet ZFSet := ⟨fun x => insert x ∅⟩ instance : LawfulSingleton ZFSet ZFSet := ⟨fun _ => rfl⟩ @[simp] theorem mem_insert_iff {x y z : ZFSet.{u}} : x ∈ insert y z ↔ x = y ∨ x ∈ z := Quotient.inductionOn₃ x y z fun _ _ _ => PSet.mem_insert_iff.trans (or_congr_left eq.symm) theorem mem_insert (x y : ZFSet) : x ∈ insert x y := mem_insert_iff.2 <\| Or.inl rfl theorem mem_insert_of_mem {y z : ZFSet} (x) (h : z ∈ y) : z ∈ insert x y := mem_insert_iff.2 <\| Or.inr h @[simp] theorem toSet_insert (x y : ZFSet) : (insert x y).toSet = insert x y.toSet := by ext simp @[simp] theorem mem_singleton {x y : ZFSet.{u}} : x ∈ @singleton ZFSet.{u} ZFSet.{u} _ y ↔ x = y := Quotient.inductionOn₂ x y fun _ _ => PSet.mem_singleton.trans eq.symm @[simp] theorem toSet_singleton (x : ZFSet) : ({x} : ZFSet).toSet = {x} := by ext simp theorem insert_nonempty (u v : ZFSet) : (insert u v).Nonempty := ⟨u, mem_insert u v⟩ theorem singleton_nonempty (u : ZFSet) : ZFSet.Nonempty {u} := insert_nonempty u ∅ theorem mem_pair {x y z : ZFSet.{u}} : x ∈ ({y, z} : ZFSet) ↔ x = y ∨ x = z := by simp @[simp] theorem pair_eq_singleton (x : ZFSet) : {x, x} = ({x} : ZFSet) := by ext simp @[simp] theorem pair_eq_singleton_iff {x y z : ZFSet} : ({x, y} : ZFSet) = {z} ↔ x = z ∧ y = z := by refine ⟨fun h ↦ ?_, ?_⟩ · rw [← mem_singleton, ← mem_singleton] simp [← h] · rintro ⟨rfl, rfl⟩ exact pair_eq_singleton y @[simp] theorem singleton_eq_pair_iff {x y z : ZFSet} : ({x} : ZFSet) = {y, z} ↔ x = y ∧ x = z := by rw [eq_comm, pair_eq_singleton_iff] simp_rw [eq_comm] /-- `omega` is the first infinite von Neumann ordinal -/ def omega : ZFSet := mk PSet.omega @[simp] theorem omega_zero : ∅ ∈ omega := ⟨⟨0⟩, Equiv.rfl⟩ @[simp] theorem omega_succ {n} : n ∈ omega.{u} → insert n n ∈ omega.{u} := Quotient.inductionOn n fun x ⟨⟨n⟩, h⟩ => ⟨⟨n + 1⟩, ZFSet.exact <\| show insert (mk x) (mk x) = insert (mk <\| ofNat n) (mk <\| ofNat n) by rw [ZFSet.sound h] rfl⟩ /-- `{x ∈ a \| p x}` is the set of elements in `a` satisfying `p` -/ protected def sep (p : ZFSet → Prop) : ZFSet → ZFSet := Quotient.map (PSet.sep fun y => p (mk y)) fun ⟨α, A⟩ ⟨β, B⟩ ⟨αβ, βα⟩ => ⟨fun ⟨a, pa⟩ => let ⟨b, hb⟩ := αβ a ⟨⟨b, by simpa only [mk_func, ← ZFSet.sound hb]⟩, hb⟩, fun ⟨b, pb⟩ => let ⟨a, ha⟩ := βα b ⟨⟨a, by simpa only [mk_func, ZFSet.sound ha]⟩, ha⟩⟩ -- Porting note: the { x \| p x } notation appears to be disabled in Lean 4. instance : Sep ZFSet ZFSet := ⟨ZFSet.sep⟩ @[simp] theorem mem_sep {p : ZFSet.{u} → Prop} {x y : ZFSet.{u}} : y ∈ ZFSet.sep p x ↔ y ∈ x ∧ p y := Quotient.inductionOn₂ x y fun _ _ => PSet.mem_sep (p := p ∘ mk) fun _ _ h => (Quotient.sound h).subst @[simp] theorem sep_empty (p : ZFSet → Prop) : (∅ : ZFSet).sep p = ∅ := (eq_empty _).mpr fun _ h ↦ not_mem_empty _ (mem_sep.mp h).1 @[simp] theorem toSet_sep (a : ZFSet) (p : ZFSet → Prop) : (ZFSet.sep p a).toSet = { x ∈ a.toSet \| p x } := by ext simp /-- The powerset operation, the collection of subsets of a ZFC set -/ def powerset : ZFSet → ZFSet := Quotient.map PSet.powerset fun ⟨_, A⟩ ⟨_, B⟩ ⟨αβ, βα⟩ => ⟨fun p => ⟨{ b \| ∃ a, p a ∧ Equiv (A a) (B b) }, fun ⟨a, pa⟩ => let ⟨b, ab⟩ := αβ a ⟨⟨b, a, pa, ab⟩, ab⟩, fun ⟨_, a, pa, ab⟩ => ⟨⟨a, pa⟩, ab⟩⟩, fun q => ⟨{ a \| ∃ b, q b ∧ Equiv (A a) (B b) }, fun ⟨_, b, qb, ab⟩ => ⟨⟨b, qb⟩, ab⟩, fun ⟨b, qb⟩ => let ⟨a, ab⟩ := βα b ⟨⟨a, b, qb, ab⟩, ab⟩⟩⟩ @[simp] theorem mem_powerset {x y : ZFSet.{u}} : y ∈ powerset x ↔ y ⊆ x := Quotient.inductionOn₂ x y fun _ _ => PSet.mem_powerset.trans subset_iff.symm theorem sUnion_lem {α β : Type u} (A : α → PSet) (B : β → PSet) (αβ : ∀ a, ∃ b, Equiv (A a) (B b)) : ∀ a, ∃ b, Equiv ((sUnion ⟨α, A⟩).Func a) ((sUnion ⟨β, B⟩).Func b) \| ⟨a, c⟩ => by let ⟨b, hb⟩ := αβ a induction' ea : A a with γ Γ induction' eb : B b with δ Δ rw [ea, eb] at hb obtain ⟨γδ, δγ⟩ := hb let c : (A a).Type := c let ⟨d, hd⟩ := γδ (by rwa [ea] at c) use ⟨b, Eq.ndrec d (Eq.symm eb)⟩ change PSet.Equiv ((A a).Func c) ((B b).Func (Eq.ndrec d eb.symm)) match A a, B b, ea, eb, c, d, hd with \| _, _, rfl, rfl, _, _, hd => exact hd /-- The union operator, the collection of elements of elements of a ZFC set -/ def sUnion : ZFSet → ZFSet := Quotient.map PSet.sUnion fun ⟨_, A⟩ ⟨_, B⟩ ⟨αβ, βα⟩ => ⟨sUnion_lem A B αβ, fun a => Exists.elim (sUnion_lem B A (fun b => Exists.elim (βα b) fun c hc => ⟨c, PSet.Equiv.symm hc⟩) a) fun b hb => ⟨b, PSet.Equiv.symm hb⟩⟩ @[inherit_doc] prefix:110 "⋃₀ " => ZFSet.sUnion /-- The intersection operator, the collection of elements in all of the elements of a ZFC set. We define `⋂₀ ∅ = ∅`. -/ def sInter (x : ZFSet) : ZFSet := (⋃₀ x).sep (fun y => ∀ z ∈ x, y ∈ z) @[inherit_doc] prefix:110 "⋂₀ " => ZFSet.sInter @[simp] theorem mem_sUnion {x y : ZFSet.{u}} : y ∈ ⋃₀ x ↔ ∃ z ∈ x, y ∈ z := Quotient.inductionOn₂ x y fun _ _ => PSet.mem_sUnion.trans ⟨fun ⟨z, h⟩ => ⟨⟦z⟧, h⟩, fun ⟨z, h⟩ => Quotient.inductionOn z (fun z h => ⟨z, h⟩) h⟩ theorem mem_sInter {x y : ZFSet} (h : x.Nonempty) : y ∈ ⋂₀ x ↔ ∀ z ∈ x, y ∈ z := by unfold sInter simp only [and_iff_right_iff_imp, mem_sep] intro mem apply mem_sUnion.mpr replace ⟨s, h⟩ := h exact ⟨_, h, mem _ h⟩ @[simp] theorem sUnion_empty : ⋃₀ (∅ : ZFSet.{u}) = ∅ := by ext simp @[simp] theorem sInter_empty : ⋂₀ (∅ : ZFSet) = ∅ := by simp [sInter] theorem mem_of_mem_sInter {x y z : ZFSet} (hy : y ∈ ⋂₀ x) (hz : z ∈ x) : y ∈ z := by rcases eq_empty_or_nonempty x with (rfl \| hx) · exact (not_mem_empty z hz).elim · exact (mem_sInter hx).1 hy z hz theorem mem_sUnion_of_mem {x y z : ZFSet} (hy : y ∈ z) (hz : z ∈ x) : y ∈ ⋃₀ x := mem_sUnion.2 ⟨z, hz, hy⟩ theorem not_mem_sInter_of_not_mem {x y z : ZFSet} (hy : ¬y ∈ z) (hz : z ∈ x) : ¬y ∈ ⋂₀ x := fun hx => hy <\| mem_of_mem_sInter hx hz @[simp] theorem sUnion_singleton {x : ZFSet.{u}} : ⋃₀ ({x} : ZFSet) = x := ext fun y => by simp_rw [mem_sUnion, mem_singleton, exists_eq_left] @[simp] theorem sInter_singleton {x : ZFSet.{u}} : ⋂₀ ({x} : ZFSet) = x := ext fun y => by simp_rw [mem_sInter (singleton_nonempty x), mem_singleton, forall_eq] @[simp] theorem toSet_sUnion (x : ZFSet.{u}) : (⋃₀ x).toSet = ⋃₀ (toSet '' x.toSet) := by ext simp theorem toSet_sInter {x : ZFSet.{u}} (h : x.Nonempty) : (⋂₀ x).toSet = ⋂₀ (toSet '' x.toSet) := by ext simp [mem_sInter h] theorem singleton_injective : Function.Injective (@singleton ZFSet ZFSet _) := fun x y H => by let this := congr_arg sUnion H rwa [sUnion_singleton, sUnion_singleton] at this @[simp] theorem singleton_inj {x y : ZFSet} : ({x} : ZFSet) = {y} ↔ x = y := singleton_injective.eq_iff /-- The binary union operation -/ protected def union (x y : ZFSet.{u}) : ZFSet.{u} := ⋃₀ {x, y} /-- The binary intersection operation -/ protected def inter (x y : ZFSet.{u}) : ZFSet.{u} := ZFSet.sep (fun z => z ∈ y) x -- { z ∈ x \| z ∈ y } /-- The set difference operation -/ protected def diff (x y : ZFSet.{u}) : ZFSet.{u} := ZFSet.sep (fun z => z ∉ y) x -- { z ∈ x \| z ∉ y } instance : Union ZFSet := ⟨ZFSet.union⟩ instance : Inter ZFSet := ⟨ZFSet.inter⟩ instance : SDiff ZFSet := ⟨ZFSet.diff⟩ @[simp] theorem toSet_union (x y : ZFSet.{u}) : (x ∪ y).toSet = x.toSet ∪ y.toSet := by change (⋃₀ {x, y}).toSet = _ simp @[simp] theorem toSet_inter (x y : ZFSet.{u}) : (x ∩ y).toSet = x.toSet ∩ y.toSet := by change (ZFSet.sep (fun z => z ∈ y) x).toSet = _ ext simp @[simp] theorem toSet_sdiff (x y : ZFSet.{u}) : (x \ y).toSet = x.toSet \ y.toSet := by change (ZFSet.sep (fun z => z ∉ y) x).toSet = _ ext simp @[simp] theorem mem_union {x y z : ZFSet.{u}} : z ∈ x ∪ y ↔ z ∈ x ∨ z ∈ y := by rw [← mem_toSet] simp @[simp] theorem mem_inter {x y z : ZFSet.{u}} : z ∈ x ∩ y ↔ z ∈ x ∧ z ∈ y := @mem_sep (fun z : ZFSet.{u} => z ∈ y) x z @[simp] theorem mem_diff {x y z : ZFSet.{u}} : z ∈ x \ y ↔ z ∈ x ∧ z ∉ y := @mem_sep (fun z : ZFSet.{u} => z ∉ y) x z @[simp] theorem sUnion_pair {x y : ZFSet.{u}} : ⋃₀ ({x, y} : ZFSet.{u}) = x ∪ y := rfl theorem mem_wf : @WellFounded ZFSet (· ∈ ·) := (wellFounded_lift₂_iff (H := fun a b c d hx hy => propext ((@Mem.congr_left a c hx).trans (@Mem.congr_right b d hy _)))).mpr PSet.mem_wf /-- Induction on the `∈` relation. -/ @[elab_as_elim] theorem inductionOn {p : ZFSet → Prop} (x) (h : ∀ x, (∀ y ∈ x, p y) → p x) : p x := mem_wf.induction x h instance : IsWellFounded ZFSet (· ∈ ·) := ⟨mem_wf⟩ instance : WellFoundedRelation ZFSet := ⟨_, mem_wf⟩ theorem mem_asymm {x y : ZFSet} : x ∈ y → y ∉ x := asymm_of (· ∈ ·) theorem mem_irrefl (x : ZFSet) : x ∉ x := irrefl_of (· ∈ ·) x theorem not_subset_of_mem {x y : ZFSet} (h : x ∈ y) : ¬ y ⊆ x := fun h' ↦ mem_irrefl _ (h' h) theorem not_mem_of_subset {x y : ZFSet} (h : x ⊆ y) : y ∉ x := imp_not_comm.2 not_subset_of_mem h theorem regularity (x : ZFSet.{u}) (h : x ≠ ∅) : ∃ y ∈ x, x ∩ y = ∅ := by_contradiction fun ne => h <\| (eq_empty x).2 fun y => @inductionOn (fun z => z ∉ x) y fun z IH zx => ne ⟨z, zx, (eq_empty _).2 fun w wxz => let ⟨wx, wz⟩ := mem_inter.1 wxz IH w wz wx⟩ /-- The image of a (definable) ZFC set function -/ def image (f : ZFSet → ZFSet) [Definable₁ f] : ZFSet → ZFSet := let r := Definable₁.out f Quotient.map (PSet.image r) fun _ _ e => Mem.ext fun _ => (mem_image (fun _ _ ↦ Definable₁.out_equiv _)).trans <\| Iff.trans ⟨fun ⟨w, h1, h2⟩ => ⟨w, (Mem.congr_right e).1 h1, h2⟩, fun ⟨w, h1, h2⟩ => ⟨w, (Mem.congr_right e).2 h1, h2⟩⟩ <\| (mem_image (fun _ _ ↦ Definable₁.out_equiv _)).symm theorem image.mk (f : ZFSet.{u} → ZFSet.{u}) [Definable₁ f] (x) {y} : y ∈ x → f y ∈ image f x := Quotient.inductionOn₂ x y fun ⟨_, _⟩ _ ⟨a, ya⟩ => by simp only [mk_eq, ← Definable₁.mk_out (f := f)] exact ⟨a, Definable₁.out_equiv f ya⟩ @[simp] theorem mem_image {f : ZFSet.{u} → ZFSet.{u}} [Definable₁ f] {x y : ZFSet.{u}} : y ∈ image f x ↔ ∃ z ∈ x, f z = y := Quotient.inductionOn₂ x y fun ⟨_, A⟩ _ => ⟨fun ⟨a, ya⟩ => ⟨⟦A a⟧, Mem.mk A a, ((Quotient.sound ya).trans Definable₁.mk_out).symm⟩, fun ⟨_, hz, e⟩ => e ▸ image.mk _ _ hz⟩ @[simp] theorem toSet_image (f : ZFSet → ZFSet) [Definable₁ f] (x : ZFSet) : (image f x).toSet = f '' x.toSet := by ext simp /-- The range of a type-indexed family of sets. -/ noncomputable def range {α} [Small.{u} α] (f : α → ZFSet.{u}) : ZFSet.{u} := ⟦⟨_, Quotient.out ∘ f ∘ (equivShrink α).symm⟩⟧ @[simp] theorem mem_range {α} [Small.{u} α] {f : α → ZFSet.{u}} {x : ZFSet.{u}} : x ∈ range f ↔ x ∈ Set.range f := Quotient.inductionOn x fun y => by constructor · rintro ⟨z, hz⟩ exact ⟨(equivShrink α).symm z, Quotient.eq_mk_iff_out.2 hz.symm⟩ · rintro ⟨z, hz⟩ use equivShrink α z simpa [hz] using PSet.Equiv.symm (Quotient.mk_out y) @[simp] theorem toSet_range {α} [Small.{u} α] (f : α → ZFSet.{u}) : (range f).toSet = Set.range f := by ext simp /-- Kuratowski ordered pair -/ def pair (x y : ZFSet.{u}) : ZFSet.{u} := {{x}, {x, y}} @[simp] theorem toSet_pair (x y : ZFSet.{u}) : (pair x y).toSet = {{x}, {x, y}} := by simp [pair] /-- A subset of pairs `{(a, b) ∈ x × y \| p a b}` -/ def pairSep (p : ZFSet.{u} → ZFSet.{u} → Prop) (x y : ZFSet.{u}) : ZFSet.{u} := (powerset (powerset (x ∪ y))).sep fun z => ∃ a ∈ x, ∃ b ∈ y, z = pair a b ∧ p a b @[simp] theorem mem_pairSep {p} {x y z : ZFSet.{u}} : z ∈ pairSep p x y ↔ ∃ a ∈ x, ∃ b ∈ y, z = pair a b ∧ p a b := by refine mem_sep.trans ⟨And.right, fun e => ⟨?_, e⟩⟩ rcases e with ⟨a, ax, b, bY, rfl, pab⟩ simp only [mem_powerset, subset_def, mem_union, pair, mem_pair] rintro u (rfl \| rfl) v <;> simp only [mem_singleton, mem_pair] · rintro rfl exact Or.inl ax · rintro (rfl \| rfl) <;> [left; right] <;> assumption theorem pair_injective : Function.Injective2 pair := by intro x x' y y' H simp_rw [ZFSet.ext_iff, pair, mem_pair] at H obtain rfl : x = x' := And.left <\| by simpa [or_and_left] using (H {x}).1 (Or.inl rfl) have he : y = x → y = y' := by rintro rfl simpa [eq_comm] using H {y, y'} have hx := H {x, y} simp_rw [pair_eq_singleton_iff, true_and, or_true, true_iff] at hx refine ⟨rfl, hx.elim he fun hy ↦ Or.elim ?_ he id⟩ simpa using ZFSet.ext_iff.1 hy y @[simp] theorem pair_inj {x y x' y' : ZFSet} : pair x y = pair x' y' ↔ x = x' ∧ y = y' := pair_injective.eq_iff /-- The cartesian product, `{(a, b) \| a ∈ x, b ∈ y}` -/ def prod : ZFSet.{u} → ZFSet.{u} → ZFSet.{u} := pairSep fun _ _ => True @[simp] theorem mem_prod {x y z : ZFSet.{u}} : z ∈ prod x y ↔ ∃ a ∈ x, ∃ b ∈ y, z = pair a b := by simp [prod] theorem pair_mem_prod {x y a b : ZFSet.{u}} : pair a b ∈ prod x y ↔ a ∈ x ∧ b ∈ y := by simp /-- `isFunc x y f` is the assertion that `f` is a subset of `x × y` which relates to each element of `x` a unique element of `y`, so that we can consider `f` as a ZFC function `x → y`. -/ def IsFunc (x y f : ZFSet.{u}) : Prop := f ⊆ prod x y ∧ ∀ z : ZFSet.{u}, z ∈ x → ∃! w, pair z w ∈ f /-- `funs x y` is `y ^ x`, the set of all set functions `x → y` -/ def funs (x y : ZFSet.{u}) : ZFSet.{u} := ZFSet.sep (IsFunc x y) (powerset (prod x y)) @[simp] theorem mem_funs {x y f : ZFSet.{u}} : f ∈ funs x y ↔ IsFunc x y f := by simp [funs, IsFunc] instance : Definable₁ ({·}) := .mk ({·}) (fun _ ↦ rfl) instance : Definable₂ insert := .mk insert (fun _ _ ↦ rfl) instance : Definable₂ pair := by unfold pair; infer_instance /-- Graph of a function: `map f x` is the ZFC function which maps `a ∈ x` to `f a` -/ def map (f : ZFSet → ZFSet) [Definable₁ f] : ZFSet → ZFSet := image fun y => pair y (f y) @[simp] theorem mem_map {f : ZFSet → ZFSet} [Definable₁ f] {x y : ZFSet} : y ∈ map f x ↔ ∃ z ∈ x, pair z (f z) = y := mem_image theorem map_unique {f : ZFSet.{u} → ZFSet.{u}} [Definable₁ f] {x z : ZFSet.{u}} (zx : z ∈ x) : ∃! w, pair z w ∈ map f x := ⟨f z, image.mk _ _ zx, fun y yx => by let ⟨w, _, we⟩ := mem_image.1 yx let ⟨wz, fy⟩ := pair_injective we rw [← fy, wz]⟩ @[simp] theorem map_isFunc {f : ZFSet → ZFSet} [Definable₁ f] {x y : ZFSet} : IsFunc x y (map f x) ↔ ∀ z ∈ x, f z ∈ y := ⟨fun ⟨ss, h⟩ z zx => let ⟨_, t1, t2⟩ := h z zx (t2 (f z) (image.mk _ _ zx)).symm ▸ (pair_mem_prod.1 (ss t1)).right, fun h => ⟨fun _ yx => let ⟨z, zx, ze⟩ := mem_image.1 yx ze ▸ pair_mem_prod.2 ⟨zx, h z zx⟩,	fun _ => map_unique⟩⟩	Mathlib/SetTheory/ZFC/Basic.lean	751	752
/- 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.BoxIntegral.Partition.Filter import Mathlib.Analysis.BoxIntegral.Partition.Measure import Mathlib.Analysis.Oscillation import Mathlib.Data.Bool.Basic import Mathlib.MeasureTheory.Measure.Real import Mathlib.Topology.UniformSpace.Compact /-! # Integrals of Riemann, Henstock-Kurzweil, and McShane In this file we define the integral of a function over a box in `ℝⁿ`. The same definition works for Riemann, Henstock-Kurzweil, and McShane integrals. As usual, we represent `ℝⁿ` as the type of functions `ι → ℝ` for some finite type `ι`. A rectangular box `(l, u]` in `ℝⁿ` is defined to be the set `{x : ι → ℝ \| ∀ i, l i < x i ∧ x i ≤ u i}`, see `BoxIntegral.Box`. Let `vol` be a box-additive function on boxes in `ℝⁿ` with codomain `E →L[ℝ] F`. Given a function `f : ℝⁿ → E`, a box `I` and a tagged partition `π` of this box, the integral sum of `f` over `π` with respect to the volume `vol` is the sum of `vol J (f (π.tag J))` over all boxes of `π`. Here `π.tag J` is the point (tag) in `ℝⁿ` associated with the box `J`. The integral is defined as the limit of integral sums along a filter. Different filters correspond to different integration theories. In order to avoid code duplication, all our definitions and theorems take an argument `l : BoxIntegral.IntegrationParams`. This is a type that holds three boolean values, and encodes eight filters including those corresponding to Riemann, Henstock-Kurzweil, and McShane integrals. Following the design of infinite sums (see `hasSum` and `tsum`), we define a predicate `BoxIntegral.HasIntegral` and a function `BoxIntegral.integral` that returns a vector satisfying the predicate or zero if the function is not integrable. Then we prove some basic properties of box integrals (linearity, a formula for the integral of a constant). We also prove a version of the Henstock-Sacks inequality (see `BoxIntegral.Integrable.dist_integralSum_le_of_memBaseSet` and `BoxIntegral.Integrable.dist_integralSum_sum_integral_le_of_memBaseSet_of_iUnion_eq`), prove integrability of continuous functions, and provide a criterion for integrability w.r.t. a non-Riemann filter (e.g., Henstock-Kurzweil and McShane). ## Notation - `ℝⁿ`: local notation for `ι → ℝ` ## Tags integral -/ open scoped Topology NNReal Filter Uniformity BoxIntegral open Set Finset Function Filter Metric BoxIntegral.IntegrationParams noncomputable section namespace BoxIntegral universe u v w variable {ι : Type u} {E : Type v} {F : Type w} [NormedAddCommGroup E] [NormedSpace ℝ E] [NormedAddCommGroup F] [NormedSpace ℝ F] {I J : Box ι} {π : TaggedPrepartition I} open TaggedPrepartition local notation "ℝⁿ" => ι → ℝ /-! ### Integral sum and its basic properties -/ /-- The integral sum of `f : ℝⁿ → E` over a tagged prepartition `π` w.r.t. box-additive volume `vol` with codomain `E →L[ℝ] F` is the sum of `vol J (f (π.tag J))` over all boxes of `π`. -/ def integralSum (f : ℝⁿ → E) (vol : ι →ᵇᵃ E →L[ℝ] F) (π : TaggedPrepartition I) : F := ∑ J ∈ π.boxes, vol J (f (π.tag J)) theorem integralSum_biUnionTagged (f : ℝⁿ → E) (vol : ι →ᵇᵃ E →L[ℝ] F) (π : Prepartition I) (πi : ∀ J, TaggedPrepartition J) : integralSum f vol (π.biUnionTagged πi) = ∑ J ∈ π.boxes, integralSum f vol (πi J) := by refine (π.sum_biUnion_boxes _ _).trans <\| sum_congr rfl fun J hJ => sum_congr rfl fun J' hJ' => ?_ rw [π.tag_biUnionTagged hJ hJ'] theorem integralSum_biUnion_partition (f : ℝⁿ → E) (vol : ι →ᵇᵃ E →L[ℝ] F) (π : TaggedPrepartition I) (πi : ∀ J, Prepartition J) (hπi : ∀ J ∈ π, (πi J).IsPartition) : integralSum f vol (π.biUnionPrepartition πi) = integralSum f vol π := by refine (π.sum_biUnion_boxes _ _).trans (sum_congr rfl fun J hJ => ?_) calc (∑ J' ∈ (πi J).boxes, vol J' (f (π.tag <\| π.toPrepartition.biUnionIndex πi J'))) = ∑ J' ∈ (πi J).boxes, vol J' (f (π.tag J)) := sum_congr rfl fun J' hJ' => by rw [Prepartition.biUnionIndex_of_mem _ hJ hJ'] _ = vol J (f (π.tag J)) := (vol.map ⟨⟨fun g : E →L[ℝ] F => g (f (π.tag J)), rfl⟩, fun _ _ => rfl⟩).sum_partition_boxes le_top (hπi J hJ) theorem integralSum_inf_partition (f : ℝⁿ → E) (vol : ι →ᵇᵃ E →L[ℝ] F) (π : TaggedPrepartition I) {π' : Prepartition I} (h : π'.IsPartition) : integralSum f vol (π.infPrepartition π') = integralSum f vol π := integralSum_biUnion_partition f vol π _ fun _J hJ => h.restrict (Prepartition.le_of_mem _ hJ) open Classical in theorem integralSum_fiberwise {α} (g : Box ι → α) (f : ℝⁿ → E) (vol : ι →ᵇᵃ E →L[ℝ] F) (π : TaggedPrepartition I) : (∑ y ∈ π.boxes.image g, integralSum f vol (π.filter (g · = y))) = integralSum f vol π := π.sum_fiberwise g fun J => vol J (f <\| π.tag J) theorem integralSum_sub_partitions (f : ℝⁿ → E) (vol : ι →ᵇᵃ E →L[ℝ] F) {π₁ π₂ : TaggedPrepartition I} (h₁ : π₁.IsPartition) (h₂ : π₂.IsPartition) : integralSum f vol π₁ - integralSum f vol π₂ = ∑ J ∈ (π₁.toPrepartition ⊓ π₂.toPrepartition).boxes, (vol J (f <\| (π₁.infPrepartition π₂.toPrepartition).tag J) - vol J (f <\| (π₂.infPrepartition π₁.toPrepartition).tag J)) := by rw [← integralSum_inf_partition f vol π₁ h₂, ← integralSum_inf_partition f vol π₂ h₁, integralSum, integralSum, Finset.sum_sub_distrib] simp only [infPrepartition_toPrepartition, inf_comm] @[simp] theorem integralSum_disjUnion (f : ℝⁿ → E) (vol : ι →ᵇᵃ E →L[ℝ] F) {π₁ π₂ : TaggedPrepartition I} (h : Disjoint π₁.iUnion π₂.iUnion) : integralSum f vol (π₁.disjUnion π₂ h) = integralSum f vol π₁ + integralSum f vol π₂ := by refine (Prepartition.sum_disj_union_boxes h _).trans (congr_arg₂ (· + ·) (sum_congr rfl fun J hJ => ?_) (sum_congr rfl fun J hJ => ?_)) · rw [disjUnion_tag_of_mem_left _ hJ] · rw [disjUnion_tag_of_mem_right _ hJ] @[simp] theorem integralSum_add (f g : ℝⁿ → E) (vol : ι →ᵇᵃ E →L[ℝ] F) (π : TaggedPrepartition I) : integralSum (f + g) vol π = integralSum f vol π + integralSum g vol π := by simp only [integralSum, Pi.add_apply, (vol _).map_add, Finset.sum_add_distrib] @[simp] theorem integralSum_neg (f : ℝⁿ → E) (vol : ι →ᵇᵃ E →L[ℝ] F) (π : TaggedPrepartition I) : integralSum (-f) vol π = -integralSum f vol π := by simp only [integralSum, Pi.neg_apply, (vol _).map_neg, Finset.sum_neg_distrib] @[simp] theorem integralSum_smul (c : ℝ) (f : ℝⁿ → E) (vol : ι →ᵇᵃ E →L[ℝ] F) (π : TaggedPrepartition I) : integralSum (c • f) vol π = c • integralSum f vol π := by simp only [integralSum, Finset.smul_sum, Pi.smul_apply, ContinuousLinearMap.map_smul] variable [Fintype ι] /-! ### Basic integrability theory -/	/-- The predicate `HasIntegral I l f vol y` says that `y` is the integral of `f` over `I` along `l`	Mathlib/Analysis/BoxIntegral/Basic.lean	149	151
/- Copyright (c) 2019 Johannes Hölzl. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Johannes Hölzl, Mario Carneiro -/ import Batteries.Data.Rat.Lemmas import Mathlib.Algebra.Group.Defs import Mathlib.Data.Rat.Init import Mathlib.Order.Basic import Mathlib.Tactic.Common import Mathlib.Data.Int.Init import Mathlib.Data.Nat.Basic /-! # Basics for the Rational Numbers ## Summary We define the integral domain structure on `ℚ` and prove basic lemmas about it. The definition of the field structure on `ℚ` will be done in `Mathlib.Data.Rat.Basic` once the `Field` class has been defined. ## Main Definitions - `Rat.divInt n d` constructs a rational number `q = n / d` from `n d : ℤ`. ## Notations - `/.` is infix notation for `Rat.divInt`. -/ -- TODO: If `Inv` was defined earlier than `Algebra.Group.Defs`, we could have -- assert_not_exists Monoid assert_not_exists MonoidWithZero Lattice PNat Nat.gcd_greatest open Function namespace Rat variable {q : ℚ} theorem pos (a : ℚ) : 0 < a.den := Nat.pos_of_ne_zero a.den_nz lemma mk'_num_den (q : ℚ) : mk' q.num q.den q.den_nz q.reduced = q := rfl @[simp] theorem ofInt_eq_cast (n : ℤ) : ofInt n = Int.cast n := rfl -- TODO: Replace `Rat.ofNat_num`/`Rat.ofNat_den` in Batteries @[simp] lemma num_ofNat (n : ℕ) : num ofNat(n) = ofNat(n) := rfl @[simp] lemma den_ofNat (n : ℕ) : den ofNat(n) = 1 := rfl @[simp, norm_cast] lemma num_natCast (n : ℕ) : num n = n := rfl @[simp, norm_cast] lemma den_natCast (n : ℕ) : den n = 1 := rfl -- TODO: Replace `intCast_num`/`intCast_den` the names in Batteries @[simp, norm_cast] lemma num_intCast (n : ℤ) : (n : ℚ).num = n := rfl @[simp, norm_cast] lemma den_intCast (n : ℤ) : (n : ℚ).den = 1 := rfl lemma intCast_injective : Injective (Int.cast : ℤ → ℚ) := fun _ _ ↦ congr_arg num lemma natCast_injective : Injective (Nat.cast : ℕ → ℚ) := intCast_injective.comp fun _ _ ↦ Int.natCast_inj.1 @[simp high, norm_cast] lemma natCast_inj {m n : ℕ} : (m : ℚ) = n ↔ m = n := natCast_injective.eq_iff @[simp high, norm_cast] lemma intCast_eq_zero {n : ℤ} : (n : ℚ) = 0 ↔ n = 0 := intCast_inj @[simp high, norm_cast] lemma natCast_eq_zero {n : ℕ} : (n : ℚ) = 0 ↔ n = 0 := natCast_inj @[simp high, norm_cast] lemma intCast_eq_one {n : ℤ} : (n : ℚ) = 1 ↔ n = 1 := intCast_inj @[simp high, norm_cast] lemma natCast_eq_one {n : ℕ} : (n : ℚ) = 1 ↔ n = 1 := natCast_inj lemma mkRat_eq_divInt (n d) : mkRat n d = n /. d := rfl @[simp] lemma mk'_zero (d) (h : d ≠ 0) (w) : mk' 0 d h w = 0 := by congr; simp_all @[simp] lemma num_eq_zero {q : ℚ} : q.num = 0 ↔ q = 0 := by induction q constructor · rintro rfl exact mk'_zero _ _ _ · exact congr_arg num lemma num_ne_zero {q : ℚ} : q.num ≠ 0 ↔ q ≠ 0 := num_eq_zero.not @[simp] lemma den_ne_zero (q : ℚ) : q.den ≠ 0 := q.den_pos.ne' @[simp] lemma num_nonneg : 0 ≤ q.num ↔ 0 ≤ q := by simp [Int.le_iff_lt_or_eq, instLE, Rat.blt, Int.not_lt]; tauto @[simp] theorem divInt_eq_zero {a b : ℤ} (b0 : b ≠ 0) : a /. b = 0 ↔ a = 0 := by rw [← zero_divInt b, divInt_eq_iff b0 b0, Int.zero_mul, Int.mul_eq_zero, or_iff_left b0] theorem divInt_ne_zero {a b : ℤ} (b0 : b ≠ 0) : a /. b ≠ 0 ↔ a ≠ 0 := (divInt_eq_zero b0).not -- TODO: this can move to Batteries theorem normalize_eq_mk' (n : Int) (d : Nat) (h : d ≠ 0) (c : Nat.gcd (Int.natAbs n) d = 1) : normalize n d h = mk' n d h c := (mk_eq_normalize ..).symm -- TODO: Rename `mkRat_num_den` in Batteries @[simp] alias mkRat_num_den' := mkRat_self -- TODO: Rename `Rat.divInt_self` to `Rat.num_divInt_den` in Batteries lemma num_divInt_den (q : ℚ) : q.num /. q.den = q := divInt_self _ lemma mk'_eq_divInt {n d h c} : (⟨n, d, h, c⟩ : ℚ) = n /. d := (num_divInt_den _).symm theorem intCast_eq_divInt (z : ℤ) : (z : ℚ) = z /. 1 := mk'_eq_divInt -- TODO: Rename `divInt_self` in Batteries to `num_divInt_den` @[simp] lemma divInt_self' {n : ℤ} (hn : n ≠ 0) : n /. n = 1 := by simpa using divInt_mul_right (n := 1) (d := 1) hn /-- Define a (dependent) function or prove `∀ r : ℚ, p r` by dealing with rational numbers of the form `n /. d` with `0 < d` and coprime `n`, `d`. -/ @[elab_as_elim] def numDenCasesOn.{u} {C : ℚ → Sort u} : ∀ (a : ℚ) (_ : ∀ n d, 0 < d → (Int.natAbs n).Coprime d → C (n /. d)), C a \| ⟨n, d, h, c⟩, H => by rw [mk'_eq_divInt]; exact H n d (Nat.pos_of_ne_zero h) c /-- Define a (dependent) function or prove `∀ r : ℚ, p r` by dealing with rational numbers of the form `n /. d` with `d ≠ 0`. -/ @[elab_as_elim] def numDenCasesOn'.{u} {C : ℚ → Sort u} (a : ℚ) (H : ∀ (n : ℤ) (d : ℕ), d ≠ 0 → C (n /. d)) : C a := numDenCasesOn a fun n d h _ => H n d h.ne' /-- Define a (dependent) function or prove `∀ r : ℚ, p r` by dealing with rational numbers of the form `mk' n d` with `d ≠ 0`. -/ @[elab_as_elim] def numDenCasesOn''.{u} {C : ℚ → Sort u} (a : ℚ) (H : ∀ (n : ℤ) (d : ℕ) (nz red), C (mk' n d nz red)) : C a := numDenCasesOn a fun n d h h' ↦ by rw [← mk_eq_divInt _ _ h.ne' h']; exact H n d h.ne' _ theorem lift_binop_eq (f : ℚ → ℚ → ℚ) (f₁ : ℤ → ℤ → ℤ → ℤ → ℤ) (f₂ : ℤ → ℤ → ℤ → ℤ → ℤ) (fv : ∀ {n₁ d₁ h₁ c₁ n₂ d₂ h₂ c₂}, f ⟨n₁, d₁, h₁, c₁⟩ ⟨n₂, d₂, h₂, c₂⟩ = f₁ n₁ d₁ n₂ d₂ /. f₂ n₁ d₁ n₂ d₂) (f0 : ∀ {n₁ d₁ n₂ d₂}, d₁ ≠ 0 → d₂ ≠ 0 → f₂ n₁ d₁ n₂ d₂ ≠ 0) (a b c d : ℤ) (b0 : b ≠ 0) (d0 : d ≠ 0) (H : ∀ {n₁ d₁ n₂ d₂}, a * d₁ = n₁ * b → c * d₂ = n₂ * d → f₁ n₁ d₁ n₂ d₂ * f₂ a b c d = f₁ a b c d * f₂ n₁ d₁ n₂ d₂) : f (a /. b) (c /. d) = f₁ a b c d /. f₂ a b c d := by generalize ha : a /. b = x; obtain ⟨n₁, d₁, h₁, c₁⟩ := x; rw [mk'_eq_divInt] at ha generalize hc : c /. d = x; obtain ⟨n₂, d₂, h₂, c₂⟩ := x; rw [mk'_eq_divInt] at hc rw [fv] have d₁0 := Int.ofNat_ne_zero.2 h₁ have d₂0 := Int.ofNat_ne_zero.2 h₂ exact (divInt_eq_iff (f0 d₁0 d₂0) (f0 b0 d0)).2 (H ((divInt_eq_iff b0 d₁0).1 ha) ((divInt_eq_iff d0 d₂0).1 hc)) attribute [simp] divInt_add_divInt attribute [simp] neg_divInt lemma neg_def (q : ℚ) : -q = -q.num /. q.den := by rw [← neg_divInt, num_divInt_den] @[simp] lemma divInt_neg (n d : ℤ) : n /. -d = -n /. d := divInt_neg' .. attribute [simp] divInt_sub_divInt @[simp] lemma divInt_mul_divInt' (n₁ d₁ n₂ d₂ : ℤ) : (n₁ /. d₁) * (n₂ /. d₂) = (n₁ * n₂) /. (d₁ * d₂) := by obtain rfl \| h₁ := eq_or_ne d₁ 0 · simp obtain rfl \| h₂ := eq_or_ne d₂ 0 · simp exact divInt_mul_divInt _ _ h₁ h₂ attribute [simp] mkRat_mul_mkRat lemma mk'_mul_mk' (n₁ n₂ : ℤ) (d₁ d₂ : ℕ) (hd₁ hd₂ hnd₁ hnd₂) (h₁₂ : n₁.natAbs.Coprime d₂) (h₂₁ : n₂.natAbs.Coprime d₁) : mk' n₁ d₁ hd₁ hnd₁ * mk' n₂ d₂ hd₂ hnd₂ = mk' (n₁ * n₂) (d₁ * d₂) (Nat.mul_ne_zero hd₁ hd₂) (by rw [Int.natAbs_mul]; exact (hnd₁.mul h₂₁).mul_right (h₁₂.mul hnd₂)) := by rw [mul_def]; dsimp; simp [mk_eq_normalize] lemma mul_eq_mkRat (q r : ℚ) : q * r = mkRat (q.num * r.num) (q.den * r.den) := by rw [mul_def, normalize_eq_mkRat] -- TODO: Rename `divInt_eq_iff` in Batteries to `divInt_eq_divInt` alias divInt_eq_divInt := divInt_eq_iff instance instPowNat : Pow ℚ ℕ where pow q n := ⟨q.num ^ n, q.den ^ n, by simp [Nat.pow_eq_zero], by rw [Int.natAbs_pow]; exact q.reduced.pow _ _⟩ lemma pow_def (q : ℚ) (n : ℕ) : q ^ n = ⟨q.num ^ n, q.den ^ n, by simp [Nat.pow_eq_zero], by rw [Int.natAbs_pow]; exact q.reduced.pow _ _⟩ := rfl lemma pow_eq_mkRat (q : ℚ) (n : ℕ) : q ^ n = mkRat (q.num ^ n) (q.den ^ n) := by rw [pow_def, mk_eq_mkRat] lemma pow_eq_divInt (q : ℚ) (n : ℕ) : q ^ n = q.num ^ n /. q.den ^ n := by rw [pow_def, mk_eq_divInt, Int.natCast_pow] @[simp] lemma num_pow (q : ℚ) (n : ℕ) : (q ^ n).num = q.num ^ n := rfl @[simp] lemma den_pow (q : ℚ) (n : ℕ) : (q ^ n).den = q.den ^ n := rfl @[simp] lemma mk'_pow (num : ℤ) (den : ℕ) (hd hdn) (n : ℕ) : mk' num den hd hdn ^ n = mk' (num ^ n) (den ^ n) (by simp [Nat.pow_eq_zero, hd]) (by rw [Int.natAbs_pow]; exact hdn.pow _ _) := rfl instance : Inv ℚ := ⟨Rat.inv⟩ @[simp] lemma inv_divInt' (a b : ℤ) : (a /. b)⁻¹ = b /. a := inv_divInt .. @[simp] lemma inv_mkRat (a : ℤ) (b : ℕ) : (mkRat a b)⁻¹ = b /. a := by rw [mkRat_eq_divInt, inv_divInt'] lemma inv_def' (q : ℚ) : q⁻¹ = q.den /. q.num := by rw [← inv_divInt', num_divInt_den] @[simp] lemma divInt_div_divInt (n₁ d₁ n₂ d₂) : (n₁ /. d₁) / (n₂ /. d₂) = (n₁ * d₂) /. (d₁ * n₂) := by rw [div_def, inv_divInt, divInt_mul_divInt'] lemma div_def' (q r : ℚ) : q / r = (q.num * r.den) /. (q.den * r.num) := by rw [← divInt_div_divInt, num_divInt_den, num_divInt_den] variable (a b c : ℚ) protected lemma add_zero : a + 0 = a := by simp [add_def, normalize_eq_mkRat] protected lemma zero_add : 0 + a = a := by simp [add_def, normalize_eq_mkRat] protected lemma add_comm : a + b = b + a := by simp [add_def, Int.add_comm, Int.mul_comm, Nat.mul_comm] protected theorem add_assoc : a + b + c = a + (b + c) := numDenCasesOn' a fun n₁ d₁ h₁ ↦ numDenCasesOn' b fun n₂ d₂ h₂ ↦ numDenCasesOn' c fun n₃ d₃ h₃ ↦ by simp only [ne_eq, Int.natCast_eq_zero, h₁, not_false_eq_true, h₂, divInt_add_divInt, Int.mul_eq_zero, or_self, h₃] rw [Int.mul_assoc, Int.add_mul, Int.add_mul, Int.mul_assoc, Int.add_assoc] congr 2 ac_rfl protected lemma neg_add_cancel : -a + a = 0 := by simp [add_def, normalize_eq_mkRat, Int.neg_mul, Int.add_comm, ← Int.sub_eq_add_neg] @[simp] lemma divInt_one (n : ℤ) : n /. 1 = n := by simp [divInt, mkRat, normalize] @[simp] lemma mkRat_one (n : ℤ) : mkRat n 1 = n := by simp [mkRat_eq_divInt] lemma divInt_one_one : 1 /. 1 = 1 := by rw [divInt_one, intCast_one] protected theorem mul_assoc : a * b * c = a * (b * c) := numDenCasesOn' a fun n₁ d₁ h₁ => numDenCasesOn' b fun n₂ d₂ h₂ => numDenCasesOn' c fun n₃ d₃ h₃ => by simp [h₁, h₂, h₃, Int.mul_comm, Nat.mul_assoc, Int.mul_left_comm] protected theorem add_mul : (a + b) * c = a * c + b * c := numDenCasesOn' a fun n₁ d₁ h₁ ↦ numDenCasesOn' b fun n₂ d₂ h₂ ↦ numDenCasesOn' c fun n₃ d₃ h₃ ↦ by simp only [ne_eq, Int.natCast_eq_zero, h₁, not_false_eq_true, h₂, divInt_add_divInt, Int.mul_eq_zero, or_self, h₃, divInt_mul_divInt] rw [← divInt_mul_right (Int.natCast_ne_zero.2 h₃), Int.add_mul, Int.add_mul] ac_rfl protected theorem mul_add : a * (b + c) = a * b + a * c := by rw [Rat.mul_comm, Rat.add_mul, Rat.mul_comm, Rat.mul_comm c a] protected theorem zero_ne_one : 0 ≠ (1 : ℚ) := by rw [ne_comm, ← divInt_one_one, divInt_ne_zero] <;> omega attribute [simp] mkRat_eq_zero protected theorem mul_inv_cancel : a ≠ 0 → a * a⁻¹ = 1 := numDenCasesOn' a fun n d hd hn ↦ by simp only [divInt_ofNat, ne_eq, hd, not_false_eq_true, mkRat_eq_zero] at hn simp [-divInt_ofNat, mkRat_eq_divInt, Int.mul_comm, Int.mul_ne_zero hn (Int.ofNat_ne_zero.2 hd)] protected theorem inv_mul_cancel (h : a ≠ 0) : a⁻¹ * a = 1 := Eq.trans (Rat.mul_comm _ _) (Rat.mul_inv_cancel _ h) -- Extra instances to short-circuit type class resolution -- TODO(Mario): this instance slows down Mathlib.Data.Real.Basic instance nontrivial : Nontrivial ℚ where exists_pair_ne := ⟨1, 0, by decide⟩ /-! ### The rational numbers are a group -/ instance addCommGroup : AddCommGroup ℚ where zero := 0 add := (· + ·) neg := Neg.neg zero_add := Rat.zero_add add_zero := Rat.add_zero add_comm := Rat.add_comm add_assoc := Rat.add_assoc neg_add_cancel := Rat.neg_add_cancel sub_eq_add_neg := Rat.sub_eq_add_neg nsmul := nsmulRec zsmul := zsmulRec instance addGroup : AddGroup ℚ := by infer_instance instance addCommMonoid : AddCommMonoid ℚ := by infer_instance instance addMonoid : AddMonoid ℚ := by infer_instance instance addLeftCancelSemigroup : AddLeftCancelSemigroup ℚ := by infer_instance instance addRightCancelSemigroup : AddRightCancelSemigroup ℚ := by infer_instance instance addCommSemigroup : AddCommSemigroup ℚ := by infer_instance instance addSemigroup : AddSemigroup ℚ := by infer_instance instance commMonoid : CommMonoid ℚ where one := 1 mul := (· * ·) mul_one := Rat.mul_one one_mul := Rat.one_mul mul_comm := Rat.mul_comm mul_assoc := Rat.mul_assoc npow n q := q ^ n npow_zero := by intros; apply Rat.ext <;> simp [Int.pow_zero] npow_succ n q := by rw [← q.mk'_num_den, mk'_pow, mk'_mul_mk'] · congr · rw [mk'_pow, Int.natAbs_pow] exact q.reduced.pow_left _ · rw [mk'_pow] exact q.reduced.pow_right _ instance monoid : Monoid ℚ := by infer_instance instance commSemigroup : CommSemigroup ℚ := by infer_instance		Mathlib/Data/Rat/Defs.lean	335	335
/- Copyright (c) 2024 Lean FRO LLC. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kim Morrison -/ import Mathlib.CategoryTheory.Monoidal.Mon_ import Mathlib.CategoryTheory.Monoidal.Braided.Opposite import Mathlib.CategoryTheory.Monoidal.Transport import Mathlib.CategoryTheory.Monoidal.CoherenceLemmas import Mathlib.CategoryTheory.Limits.Shapes.Terminal /-! # The category of comonoids in a monoidal category. We define comonoids in a monoidal category `C`, and show that they are equivalently monoid objects in the opposite category. We construct the monoidal structure on `Comon_ C`, when `C` is braided. An oplax monoidal functor takes comonoid objects to comonoid objects. That is, a oplax monoidal functor `F : C ⥤ D` induces a functor `Comon_ C ⥤ Comon_ D`. ## TODO * Comonoid objects in `C` are "just" oplax monoidal functors from the trivial monoidal category to `C`. -/ universe v₁ v₂ u₁ u₂ u open CategoryTheory MonoidalCategory variable {C : Type u₁} [Category.{v₁} C] [MonoidalCategory.{v₁} C] /-- A comonoid object internal to a monoidal category. When the monoidal category is preadditive, this is also sometimes called a "coalgebra object". -/ class Comon_Class (X : C) where /-- The counit morphism of a comonoid object. -/ counit : X ⟶ 𝟙_ C /-- The comultiplication morphism of a comonoid object. -/ comul : X ⟶ X ⊗ X /- For the names of the conditions below, the unprimed names are reserved for the version where the argument `X` is explicit. -/ counit_comul' : comul ≫ counit ▷ X = (λ_ X).inv := by aesop_cat comul_counit' : comul ≫ X ◁ counit = (ρ_ X).inv := by aesop_cat comul_assoc' : comul ≫ X ◁ comul = comul ≫ (comul ▷ X) ≫ (α_ X X X).hom := by aesop_cat namespace Comon_Class @[inherit_doc] scoped notation "Δ" => Comon_Class.comul @[inherit_doc] scoped notation "Δ["M"]" => Comon_Class.comul (X := M) @[inherit_doc] scoped notation "ε" => Comon_Class.counit @[inherit_doc] scoped notation "ε["M"]" => Comon_Class.counit (X := M) /- The simp attribute is reserved for the unprimed versions. -/ attribute [reassoc] counit_comul' comul_counit' comul_assoc' @[reassoc (attr := simp)] theorem counit_comul (X : C) [Comon_Class X] : Δ ≫ ε ▷ X = (λ_ X).inv := counit_comul' @[reassoc (attr := simp)] theorem comul_counit (X : C) [Comon_Class X] : Δ ≫ X ◁ ε = (ρ_ X).inv := comul_counit' @[reassoc (attr := simp)] theorem comul_assoc (X : C) [Comon_Class X] : Δ ≫ X ◁ Δ = Δ ≫ Δ ▷ X ≫ (α_ X X X).hom := comul_assoc' end Comon_Class open scoped Comon_Class variable {M N : C} [Comon_Class M] [Comon_Class N] /-- The property that a morphism between comonoid objects is a comonoid morphism. -/ class IsComon_Hom (f : M ⟶ N) : Prop where hom_counit : f ≫ ε = ε := by aesop_cat hom_comul : f ≫ Δ = Δ ≫ (f ⊗ f) := by aesop_cat attribute [reassoc (attr := simp)] IsComon_Hom.hom_counit IsComon_Hom.hom_comul variable (C) /-- A comonoid object internal to a monoidal category. When the monoidal category is preadditive, this is also sometimes called a "coalgebra object". -/ structure Comon_ where /-- The underlying object of a comonoid object. -/ X : C /-- The counit of a comonoid object. -/ counit : X ⟶ 𝟙_ C /-- The comultiplication morphism of a comonoid object. -/ comul : X ⟶ X ⊗ X counit_comul : comul ≫ (counit ▷ X) = (λ_ X).inv := by aesop_cat comul_counit : comul ≫ (X ◁ counit) = (ρ_ X).inv := by aesop_cat comul_assoc : comul ≫ (X ◁ comul) = comul ≫ (comul ▷ X) ≫ (α_ X X X).hom := by aesop_cat attribute [reassoc (attr := simp)] Comon_.counit_comul Comon_.comul_counit attribute [reassoc (attr := simp)] Comon_.comul_assoc namespace Comon_ variable {C} /-- Construct an object of `Comon_ C` from an object `X : C` and `Comon_Class X` instance. -/ @[simps] def mk' (X : C) [Comon_Class X] : Comon_ C where X := X counit := ε comul := Δ instance {M : Comon_ C} : Comon_Class M.X where counit := M.counit comul := M.comul counit_comul' := M.counit_comul comul_counit' := M.comul_counit comul_assoc' := M.comul_assoc variable (C) /-- The trivial comonoid object. We later show this is terminal in `Comon_ C`. -/ @[simps] def trivial : Comon_ C where X := 𝟙_ C counit := 𝟙 _ comul := (λ_ _).inv comul_assoc := by monoidal_coherence counit_comul := by monoidal_coherence comul_counit := by monoidal_coherence instance : Inhabited (Comon_ C) := ⟨trivial C⟩ variable {C} variable {M : Comon_ C} @[reassoc (attr := simp)] theorem counit_comul_hom {Z : C} (f : M.X ⟶ Z) : M.comul ≫ (M.counit ⊗ f) = f ≫ (λ_ Z).inv := by rw [leftUnitor_inv_naturality, tensorHom_def, counit_comul_assoc] @[reassoc (attr := simp)] theorem comul_counit_hom {Z : C} (f : M.X ⟶ Z) : M.comul ≫ (f ⊗ M.counit) = f ≫ (ρ_ Z).inv := by rw [rightUnitor_inv_naturality, tensorHom_def', comul_counit_assoc] @[reassoc] theorem comul_assoc_flip : M.comul ≫ (M.comul ▷ M.X) = M.comul ≫ (M.X ◁ M.comul) ≫ (α_ M.X M.X M.X).inv := by simp /-- A morphism of comonoid objects. -/ @[ext] structure Hom (M N : Comon_ C) where /-- The underlying morphism of a morphism of comonoid objects. -/ hom : M.X ⟶ N.X hom_counit : hom ≫ N.counit = M.counit := by aesop_cat hom_comul : hom ≫ N.comul = M.comul ≫ (hom ⊗ hom) := by aesop_cat attribute [reassoc (attr := simp)] Hom.hom_counit Hom.hom_comul /-- The identity morphism on a comonoid object. -/ @[simps] def id (M : Comon_ C) : Hom M M where hom := 𝟙 M.X instance homInhabited (M : Comon_ C) : Inhabited (Hom M M) := ⟨id M⟩ /-- Composition of morphisms of monoid objects. -/ @[simps] def comp {M N O : Comon_ C} (f : Hom M N) (g : Hom N O) : Hom M O where hom := f.hom ≫ g.hom instance : Category (Comon_ C) where Hom M N := Hom M N id := id comp f g := comp f g @[ext] lemma ext {X Y : Comon_ C} {f g : X ⟶ Y} (w : f.hom = g.hom) : f = g := Hom.ext w @[simp] theorem id_hom' (M : Comon_ C) : (𝟙 M : Hom M M).hom = 𝟙 M.X := rfl @[simp] theorem comp_hom' {M N K : Comon_ C} (f : M ⟶ N) (g : N ⟶ K) : (f ≫ g).hom = f.hom ≫ g.hom := rfl section variable (C) /-- The forgetful functor from comonoid objects to the ambient category. -/ @[simps] def forget : Comon_ C ⥤ C where obj A := A.X map f := f.hom end instance forget_faithful : (@forget C _ _).Faithful where instance {A B : Comon_ C} (f : A ⟶ B) [e : IsIso ((forget C).map f)] : IsIso f.hom := e /-- The forgetful functor from comonoid objects to the ambient category reflects isomorphisms. -/ instance : (forget C).ReflectsIsomorphisms where reflects f e := ⟨⟨{ hom := inv f.hom }, by aesop_cat⟩⟩ /-- Construct an isomorphism of comonoids by giving an isomorphism between the underlying objects and checking compatibility with counit and comultiplication only in the forward direction. -/ @[simps] def mkIso {M N : Comon_ C} (f : M.X ≅ N.X) (f_counit : f.hom ≫ N.counit = M.counit := by aesop_cat) (f_comul : f.hom ≫ N.comul = M.comul ≫ (f.hom ⊗ f.hom) := by aesop_cat) : M ≅ N where hom := { hom := f.hom hom_counit := f_counit hom_comul := f_comul } inv := { hom := f.inv hom_counit := by rw [← f_counit]; simp hom_comul := by rw [← cancel_epi f.hom] slice_rhs 1 2 => rw [f_comul] simp } @[simps] instance uniqueHomToTrivial (A : Comon_ C) : Unique (A ⟶ trivial C) where default := { hom := A.counit hom_comul := by simp [A.comul_counit, unitors_inv_equal] } uniq f := by ext; simp rw [← Category.comp_id f.hom] erw [f.hom_counit] open CategoryTheory.Limits instance : HasTerminal (Comon_ C) := hasTerminal_of_unique (trivial C) open Opposite variable (C) /-- Turn a comonoid object into a monoid object in the opposite category. -/ @[simps] def Comon_ToMon_OpOp_obj' (A : Comon_ C) : Mon_ (Cᵒᵖ) where X := op A.X one := A.counit.op mul := A.comul.op one_mul := by rw [← op_whiskerRight, ← op_comp, counit_comul] rfl mul_one := by rw [← op_whiskerLeft, ← op_comp, comul_counit] rfl mul_assoc := by rw [← op_inv_associator, ← op_whiskerRight, ← op_comp, ← op_whiskerLeft, ← op_comp, comul_assoc_flip, op_comp, op_comp_assoc] rfl /-- The contravariant functor turning comonoid objects into monoid objects in the opposite category. -/ @[simps] def Comon_ToMon_OpOp : Comon_ C ⥤ (Mon_ (Cᵒᵖ))ᵒᵖ where obj A := op (Comon_ToMon_OpOp_obj' C A) map := fun f => op <\|	{ hom := f.hom.op one_hom := by apply Quiver.Hom.unop_inj; simp mul_hom := by apply Quiver.Hom.unop_inj; simp [op_tensorHom] } /-- Turn a monoid object in the opposite category into a comonoid object. -/ @[simps] def Mon_OpOpToComon_obj' (A : (Mon_ (Cᵒᵖ))) : Comon_ C where	Mathlib/CategoryTheory/Monoidal/Comon_.lean	271	278
/- Copyright (c) 2022 Nicolò Cavalleri. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Nicolò Cavalleri, Sébastien Gouëzel, Heather Macbeth, Floris van Doorn -/ import Mathlib.Topology.FiberBundle.Basic /-! # Standard constructions on fiber bundles This file contains several standard constructions on fiber bundles: * `Bundle.Trivial.fiberBundle 𝕜 B F`: the trivial fiber bundle with model fiber `F` over the base `B` * `FiberBundle.prod`: for fiber bundles `E₁` and `E₂` over a common base, a fiber bundle structure on their fiberwise product `E₁ ×ᵇ E₂` (the notation stands for `fun x ↦ E₁ x × E₂ x`). * `FiberBundle.pullback`: for a fiber bundle `E` over `B`, a fiber bundle structure on its pullback `f ᵖ E` by a map `f : B' → B` (the notation is a type synonym for `E ∘ f`). ## Tags fiber bundle, fibre bundle, fiberwise product, pullback -/ open Bundle Filter Set TopologicalSpace Topology /-! ### The trivial bundle -/ namespace Bundle namespace Trivial variable (B : Type) (F : Type) -- TODO: use `TotalSpace.toProd` instance topologicalSpace [t₁ : TopologicalSpace B] [t₂ : TopologicalSpace F] : TopologicalSpace (TotalSpace F (Trivial B F)) := induced TotalSpace.proj t₁ ⊓ induced (TotalSpace.trivialSnd B F) t₂ variable [TopologicalSpace B] [TopologicalSpace F] theorem isInducing_toProd : IsInducing (TotalSpace.toProd B F) := ⟨by simp only [instTopologicalSpaceProd, induced_inf, induced_compose]; rfl⟩ @[deprecated (since := "2024-10-28")] alias inducing_toProd := isInducing_toProd /-- Homeomorphism between the total space of the trivial bundle and the Cartesian product. -/ def homeomorphProd : TotalSpace F (Trivial B F) ≃ₜ B × F := (TotalSpace.toProd _ _).toHomeomorphOfIsInducing (isInducing_toProd B F) /-- Local trivialization for trivial bundle. -/ def trivialization : Trivialization F (π F (Bundle.Trivial B F)) where toPartialHomeomorph := (homeomorphProd B F).toPartialHomeomorph baseSet := univ open_baseSet := isOpen_univ source_eq := rfl target_eq := univ_prod_univ.symm proj_toFun _ _ := rfl @[simp] theorem trivialization_source : (trivialization B F).source = univ := rfl @[simp] theorem trivialization_target : (trivialization B F).target = univ := rfl /-- Fiber bundle instance on the trivial bundle. -/ instance fiberBundle : FiberBundle F (Bundle.Trivial B F) where trivializationAtlas' := {trivialization B F} trivializationAt' _ := trivialization B F mem_baseSet_trivializationAt' := mem_univ trivialization_mem_atlas' _ := mem_singleton _ totalSpaceMk_isInducing' _ := (homeomorphProd B F).symm.isInducing.comp (isInducing_const_prod.2 .id) theorem eq_trivialization (e : Trivialization F (π F (Bundle.Trivial B F))) [i : MemTrivializationAtlas e] : e = trivialization B F := i.out end Trivial end Bundle /-! ### Fibrewise product of two bundles -/ section Prod variable {B : Type} section Defs variable (F₁ : Type) (E₁ : B → Type) (F₂ : Type) (E₂ : B → Type) variable [TopologicalSpace (TotalSpace F₁ E₁)] [TopologicalSpace (TotalSpace F₂ E₂)] /-- Equip the total space of the fiberwise product of two fiber bundles `E₁`, `E₂` with the induced topology from the diagonal embedding into `TotalSpace F₁ E₁ × TotalSpace F₂ E₂`. -/ instance FiberBundle.Prod.topologicalSpace : TopologicalSpace (TotalSpace (F₁ × F₂) (E₁ ×ᵇ E₂)) := TopologicalSpace.induced (fun p ↦ ((⟨p.1, p.2.1⟩ : TotalSpace F₁ E₁), (⟨p.1, p.2.2⟩ : TotalSpace F₂ E₂))) inferInstance /-- The diagonal map from the total space of the fiberwise product of two fiber bundles `E₁`, `E₂` into `TotalSpace F₁ E₁ × TotalSpace F₂ E₂` is an inducing map. -/ theorem FiberBundle.Prod.isInducing_diag : IsInducing (fun p ↦ (⟨p.1, p.2.1⟩, ⟨p.1, p.2.2⟩) : TotalSpace (F₁ × F₂) (E₁ ×ᵇ E₂) → TotalSpace F₁ E₁ × TotalSpace F₂ E₂) := ⟨rfl⟩ @[deprecated (since := "2024-10-28")] alias FiberBundle.Prod.inducing_diag := FiberBundle.Prod.isInducing_diag end Defs open FiberBundle variable [TopologicalSpace B] (F₁ : Type) [TopologicalSpace F₁] (E₁ : B → Type) [TopologicalSpace (TotalSpace F₁ E₁)] (F₂ : Type) [TopologicalSpace F₂] (E₂ : B → Type) [TopologicalSpace (TotalSpace F₂ E₂)] namespace Trivialization variable {F₁ E₁ F₂ E₂} variable (e₁ : Trivialization F₁ (π F₁ E₁)) (e₂ : Trivialization F₂ (π F₂ E₂)) /-- Given trivializations `e₁`, `e₂` for fiber bundles `E₁`, `E₂` over a base `B`, the forward function for the construction `Trivialization.prod`, the induced trivialization for the fiberwise product of `E₁` and `E₂`. -/ def Prod.toFun' : TotalSpace (F₁ × F₂) (E₁ ×ᵇ E₂) → B × F₁ × F₂ := fun p ↦ ⟨p.1, (e₁ ⟨p.1, p.2.1⟩).2, (e₂ ⟨p.1, p.2.2⟩).2⟩ variable {e₁ e₂} theorem Prod.continuous_to_fun : ContinuousOn (Prod.toFun' e₁ e₂) (π (F₁ × F₂) (E₁ ×ᵇ E₂) ⁻¹' (e₁.baseSet ∩ e₂.baseSet)) := by let f₁ : TotalSpace (F₁ × F₂) (E₁ ×ᵇ E₂) → TotalSpace F₁ E₁ × TotalSpace F₂ E₂ := fun p ↦ ((⟨p.1, p.2.1⟩ : TotalSpace F₁ E₁), (⟨p.1, p.2.2⟩ : TotalSpace F₂ E₂)) let f₂ : TotalSpace F₁ E₁ × TotalSpace F₂ E₂ → (B × F₁) × B × F₂ := fun p ↦ ⟨e₁ p.1, e₂ p.2⟩ let f₃ : (B × F₁) × B × F₂ → B × F₁ × F₂ := fun p ↦ ⟨p.1.1, p.1.2, p.2.2⟩ have hf₁ : Continuous f₁ := (Prod.isInducing_diag F₁ E₁ F₂ E₂).continuous have hf₂ : ContinuousOn f₂ (e₁.source ×ˢ e₂.source) := e₁.toPartialHomeomorph.continuousOn.prodMap e₂.toPartialHomeomorph.continuousOn have hf₃ : Continuous f₃ := by fun_prop refine ((hf₃.comp_continuousOn hf₂).comp hf₁.continuousOn ?_).congr ?_ · rw [e₁.source_eq, e₂.source_eq] exact mapsTo_preimage _ _ rintro ⟨b, v₁, v₂⟩ ⟨hb₁, _⟩ simp only [f₁, f₂, f₃, Prod.toFun', Prod.mk_inj, Function.comp_apply, and_true] rw [e₁.coe_fst] rw [e₁.source_eq, mem_preimage] exact hb₁ variable (e₁ e₂) [∀ x, Zero (E₁ x)] [∀ x, Zero (E₂ x)] /-- Given trivializations `e₁`, `e₂` for fiber bundles `E₁`, `E₂` over a base `B`, the inverse function for the construction `Trivialization.prod`, the induced trivialization for the fiberwise product of `E₁` and `E₂`. -/ noncomputable def Prod.invFun' (p : B × F₁ × F₂) : TotalSpace (F₁ × F₂) (E₁ ×ᵇ E₂) := ⟨p.1, e₁.symm p.1 p.2.1, e₂.symm p.1 p.2.2⟩ variable {e₁ e₂} theorem Prod.left_inv {x : TotalSpace (F₁ × F₂) (E₁ ×ᵇ E₂)} (h : x ∈ π (F₁ × F₂) (E₁ ×ᵇ E₂) ⁻¹' (e₁.baseSet ∩ e₂.baseSet)) : Prod.invFun' e₁ e₂ (Prod.toFun' e₁ e₂ x) = x := by obtain ⟨x, v₁, v₂⟩ := x obtain ⟨h₁ : x ∈ e₁.baseSet, h₂ : x ∈ e₂.baseSet⟩ := h simp only [Prod.toFun', Prod.invFun', symm_apply_apply_mk, h₁, h₂] theorem Prod.right_inv {x : B × F₁ × F₂} (h : x ∈ (e₁.baseSet ∩ e₂.baseSet) ×ˢ (univ : Set (F₁ × F₂))) : Prod.toFun' e₁ e₂ (Prod.invFun' e₁ e₂ x) = x := by obtain ⟨x, w₁, w₂⟩ := x obtain ⟨⟨h₁ : x ∈ e₁.baseSet, h₂ : x ∈ e₂.baseSet⟩, -⟩ := h simp only [Prod.toFun', Prod.invFun', apply_mk_symm, h₁, h₂] theorem Prod.continuous_inv_fun : ContinuousOn (Prod.invFun' e₁ e₂) ((e₁.baseSet ∩ e₂.baseSet) ×ˢ univ) := by rw [(Prod.isInducing_diag F₁ E₁ F₂ E₂).continuousOn_iff] have H₁ : Continuous fun p : B × F₁ × F₂ ↦ ((p.1, p.2.1), (p.1, p.2.2)) := by fun_prop refine (e₁.continuousOn_symm.prodMap e₂.continuousOn_symm).comp H₁.continuousOn ?_ exact fun x h ↦ ⟨⟨h.1.1, mem_univ _⟩, ⟨h.1.2, mem_univ _⟩⟩ variable (e₁ e₂) /-- Given trivializations `e₁`, `e₂` for bundle types `E₁`, `E₂` over a base `B`, the induced trivialization for the fiberwise product of `E₁` and `E₂`, whose base set is `e₁.baseSet ∩ e₂.baseSet`. -/ noncomputable def prod : Trivialization (F₁ × F₂) (π (F₁ × F₂) (E₁ ×ᵇ E₂)) where toFun := Prod.toFun' e₁ e₂ invFun := Prod.invFun' e₁ e₂ source := π (F₁ × F₂) (E₁ ×ᵇ E₂) ⁻¹' (e₁.baseSet ∩ e₂.baseSet) target := (e₁.baseSet ∩ e₂.baseSet) ×ˢ Set.univ map_source' _ h := ⟨h, Set.mem_univ _⟩ map_target' _ h := h.1 left_inv' _ := Prod.left_inv right_inv' _ := Prod.right_inv open_source := by convert (e₁.open_source.prod e₂.open_source).preimage (FiberBundle.Prod.isInducing_diag F₁ E₁ F₂ E₂).continuous ext x simp only [Trivialization.source_eq, mfld_simps] open_target := (e₁.open_baseSet.inter e₂.open_baseSet).prod isOpen_univ continuousOn_toFun := Prod.continuous_to_fun continuousOn_invFun := Prod.continuous_inv_fun baseSet := e₁.baseSet ∩ e₂.baseSet open_baseSet := e₁.open_baseSet.inter e₂.open_baseSet source_eq := rfl target_eq := rfl proj_toFun _ _ := rfl @[simp] theorem baseSet_prod : (prod e₁ e₂).baseSet = e₁.baseSet ∩ e₂.baseSet := rfl theorem prod_symm_apply (x : B) (w₁ : F₁) (w₂ : F₂) : (prod e₁ e₂).toPartialEquiv.symm (x, w₁, w₂) = ⟨x, e₁.symm x w₁, e₂.symm x w₂⟩ := rfl end Trivialization open Trivialization variable [∀ x, Zero (E₁ x)] [∀ x, Zero (E₂ x)] [∀ x : B, TopologicalSpace (E₁ x)] [∀ x : B, TopologicalSpace (E₂ x)] [FiberBundle F₁ E₁] [FiberBundle F₂ E₂] /-- The product of two fiber bundles is a fiber bundle. -/ noncomputable instance FiberBundle.prod : FiberBundle (F₁ × F₂) (E₁ ×ᵇ E₂) where totalSpaceMk_isInducing' b := by rw [← (Prod.isInducing_diag F₁ E₁ F₂ E₂).of_comp_iff] exact (totalSpaceMk_isInducing F₁ E₁ b).prodMap (totalSpaceMk_isInducing F₂ E₂ b) trivializationAtlas' := { e \| ∃ (e₁ : Trivialization F₁ (π F₁ E₁)) (e₂ : Trivialization F₂ (π F₂ E₂)) (_ : MemTrivializationAtlas e₁) (_ : MemTrivializationAtlas e₂), e = Trivialization.prod e₁ e₂ } trivializationAt' b := (trivializationAt F₁ E₁ b).prod (trivializationAt F₂ E₂ b) mem_baseSet_trivializationAt' b := ⟨mem_baseSet_trivializationAt F₁ E₁ b, mem_baseSet_trivializationAt F₂ E₂ b⟩ trivialization_mem_atlas' b := ⟨trivializationAt F₁ E₁ b, trivializationAt F₂ E₂ b, inferInstance, inferInstance, rfl⟩ instance {e₁ : Trivialization F₁ (π F₁ E₁)} {e₂ : Trivialization F₂ (π F₂ E₂)} [MemTrivializationAtlas e₁] [MemTrivializationAtlas e₂] : MemTrivializationAtlas (e₁.prod e₂ : Trivialization (F₁ × F₂) (π (F₁ × F₂) (E₁ ×ᵇ E₂))) where out := ⟨e₁, e₂, inferInstance, inferInstance, rfl⟩ end Prod /-! ### Pullbacks of fiber bundles -/ section universe u v w₁ w₂ U variable {B : Type u} (F : Type v) (E : B → Type w₁) {B' : Type w₂} (f : B' → B) instance [∀ x : B, TopologicalSpace (E x)] : ∀ x : B', TopologicalSpace ((f ᵖ E) x) := inferInstanceAs (∀ x, TopologicalSpace (E (f x))) variable [TopologicalSpace B'] [TopologicalSpace (TotalSpace F E)] /-- Definition of `Pullback.TotalSpace.topologicalSpace`, which we make irreducible. -/ irreducible_def pullbackTopology : TopologicalSpace (TotalSpace F (f ᵖ E)) := induced TotalSpace.proj ‹TopologicalSpace B'› ⊓ induced (Pullback.lift f) ‹TopologicalSpace (TotalSpace F E)› /-- The topology on the total space of a pullback bundle is the coarsest topology for which both the projections to the base and the map to the original bundle are continuous. -/ instance Pullback.TotalSpace.topologicalSpace : TopologicalSpace (TotalSpace F (f ᵖ E)) := pullbackTopology F E f theorem Pullback.continuous_proj (f : B' → B) : Continuous (π F (f ᵖ E)) := by rw [continuous_iff_le_induced, Pullback.TotalSpace.topologicalSpace, pullbackTopology_def] exact inf_le_left theorem Pullback.continuous_lift (f : B' → B) : Continuous (@Pullback.lift B F E B' f) := by rw [continuous_iff_le_induced, Pullback.TotalSpace.topologicalSpace, pullbackTopology_def] exact inf_le_right theorem inducing_pullbackTotalSpaceEmbedding (f : B' → B) : IsInducing (@pullbackTotalSpaceEmbedding B F E B' f) := by constructor simp_rw [instTopologicalSpaceProd, induced_inf, induced_compose, Pullback.TotalSpace.topologicalSpace, pullbackTopology_def] rfl section FiberBundle variable [TopologicalSpace F] [TopologicalSpace B] theorem Pullback.continuous_totalSpaceMk [∀ x, TopologicalSpace (E x)] [FiberBundle F E] {f : B' → B} {x : B'} : Continuous (@TotalSpace.mk _ F (f *ᵖ E) x) := by simp only [continuous_iff_le_induced, Pullback.TotalSpace.topologicalSpace, induced_compose, induced_inf, Function.comp_def, induced_const, top_inf_eq, pullbackTopology_def] exact (FiberBundle.totalSpaceMk_isInducing F E (f x)).eq_induced.le variable {E F} variable [∀ _b, Zero (E _b)] {K : Type U} [FunLike K B' B] [ContinuousMapClass K B' B] /-- A fiber bundle trivialization can be pulled back to a trivialization on the pullback bundle. -/	noncomputable def Trivialization.pullback (e : Trivialization F (π F E)) (f : K) : Trivialization F (π F ((f : B' → B) *ᵖ E)) where toFun z := (z.proj, (e (Pullback.lift f z)).2)	Mathlib/Topology/FiberBundle/Constructions.lean	300	302
/- 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.Comma.Arrow import Mathlib.Order.CompleteBooleanAlgebra /-! # Properties of morphisms We provide the basic framework for talking about properties of morphisms. The following meta-property is defined * `RespectsLeft P Q`: `P` respects the property `Q` on the left if `P f → P (i ≫ f)` where `i` satisfies `Q`. * `RespectsRight P Q`: `P` respects the property `Q` on the right if `P f → P (f ≫ i)` where `i` satisfies `Q`. * `Respects`: `P` respects `Q` if `P` respects `Q` both on the left and on the right. -/ universe w v v' u u' open CategoryTheory Opposite noncomputable section namespace CategoryTheory variable (C : Type u) [Category.{v} C] {D : Type} [Category D] /-- A `MorphismProperty C` is a class of morphisms between objects in `C`. -/ def MorphismProperty := ∀ ⦃X Y : C⦄ (_ : X ⟶ Y), Prop instance : CompleteBooleanAlgebra (MorphismProperty C) where le P₁ P₂ := ∀ ⦃X Y : C⦄ (f : X ⟶ Y), P₁ f → P₂ f __ := inferInstanceAs (CompleteBooleanAlgebra (∀ ⦃X Y : C⦄ (_ : X ⟶ Y), Prop)) lemma MorphismProperty.le_def {P Q : MorphismProperty C} : P ≤ Q ↔ ∀ {X Y : C} (f : X ⟶ Y), P f → Q f := Iff.rfl instance : Inhabited (MorphismProperty C) := ⟨⊤⟩ lemma MorphismProperty.top_eq : (⊤ : MorphismProperty C) = fun _ _ _ => True := rfl variable {C} namespace MorphismProperty @[ext] lemma ext (W W' : MorphismProperty C) (h : ∀ ⦃X Y : C⦄ (f : X ⟶ Y), W f ↔ W' f) : W = W' := by funext X Y f rw [h] @[simp] lemma top_apply {X Y : C} (f : X ⟶ Y) : (⊤ : MorphismProperty C) f := by simp only [top_eq] lemma of_eq_top {P : MorphismProperty C} (h : P = ⊤) {X Y : C} (f : X ⟶ Y) : P f := by simp [h] @[simp] lemma sSup_iff (S : Set (MorphismProperty C)) {X Y : C} (f : X ⟶ Y) : sSup S f ↔ ∃ (W : S), W.1 f := by dsimp [sSup, iSup] constructor · rintro ⟨_, ⟨⟨_, ⟨⟨_, ⟨_, h⟩, rfl⟩, rfl⟩⟩, rfl⟩, hf⟩ exact ⟨⟨_, h⟩, hf⟩ · rintro ⟨⟨W, hW⟩, hf⟩ exact ⟨_, ⟨⟨_, ⟨_, ⟨⟨W, hW⟩, rfl⟩⟩, rfl⟩, rfl⟩, hf⟩ @[simp] lemma iSup_iff {ι : Sort} (W : ι → MorphismProperty C) {X Y : C} (f : X ⟶ Y) : iSup W f ↔ ∃ i, W i f := by apply (sSup_iff (Set.range W) f).trans constructor · rintro ⟨⟨_, i, rfl⟩, hf⟩ exact ⟨i, hf⟩ · rintro ⟨i, hf⟩ exact ⟨⟨_, i, rfl⟩, hf⟩ /-- The morphism property in `Cᵒᵖ` associated to a morphism property in `C` -/	@[simp] def op (P : MorphismProperty C) : MorphismProperty Cᵒᵖ := fun _ _ f => P f.unop	Mathlib/CategoryTheory/MorphismProperty/Basic.lean	88	90
/- Copyright (c) 2018 Mario Carneiro. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro, Johannes Hölzl, Sander Dahmen, Kim Morrison -/ import Mathlib.SetTheory.Cardinal.Cofinality import Mathlib.LinearAlgebra.FreeModule.Finite.Basic import Mathlib.LinearAlgebra.Dimension.StrongRankCondition import Mathlib.LinearAlgebra.Dimension.Constructions /-! # Conditions for rank to be finite Also contains characterization for when rank equals zero or rank equals one. -/ noncomputable section universe u v v' w variable {R : Type u} {M M₁ : Type v} {M' : Type v'} {ι : Type w} variable [Ring R] [AddCommGroup M] [AddCommGroup M'] [AddCommGroup M₁] variable [Module R M] [Module R M'] [Module R M₁] attribute [local instance] nontrivial_of_invariantBasisNumber open Basis Cardinal Function Module Set Submodule /-- If every finite set of linearly independent vectors has cardinality at most `n`, then the same is true for arbitrary sets of linearly independent vectors. -/ theorem linearIndependent_bounded_of_finset_linearIndependent_bounded {n : ℕ} (H : ∀ s : Finset M, (LinearIndependent R fun i : s => (i : M)) → s.card ≤ n) : ∀ s : Set M, LinearIndependent R ((↑) : s → M) → #s ≤ n := by intro s li apply Cardinal.card_le_of intro t rw [← Finset.card_map (Embedding.subtype s)] apply H apply linearIndependent_finset_map_embedding_subtype _ li theorem rank_le {n : ℕ} (H : ∀ s : Finset M, (LinearIndependent R fun i : s => (i : M)) → s.card ≤ n) : Module.rank R M ≤ n := by rw [Module.rank_def] apply ciSup_le' rintro ⟨s, li⟩ exact linearIndependent_bounded_of_finset_linearIndependent_bounded H _ li section RankZero /-- See `rank_zero_iff` for a stronger version with `NoZeroSMulDivisor R M`. -/ lemma rank_eq_zero_iff : Module.rank R M = 0 ↔ ∀ x : M, ∃ a : R, a ≠ 0 ∧ a • x = 0 := by nontriviality R constructor · contrapose! rintro ⟨x, hx⟩ rw [← Cardinal.one_le_iff_ne_zero] have : LinearIndependent R (fun _ : Unit ↦ x) := linearIndependent_iff.mpr (fun l hl ↦ Finsupp.unique_ext <\| not_not.mp fun H ↦ hx _ H ((Finsupp.linearCombination_unique _ _ _).symm.trans hl)) simpa using this.cardinal_lift_le_rank · intro h rw [← le_zero_iff, Module.rank_def] apply ciSup_le' intro ⟨s, hs⟩ rw [nonpos_iff_eq_zero, Cardinal.mk_eq_zero_iff, ← not_nonempty_iff] rintro ⟨i : s⟩ obtain ⟨a, ha, ha'⟩ := h i apply ha simpa using DFunLike.congr_fun (linearIndependent_iff.mp hs (Finsupp.single i a) (by simpa)) i theorem rank_pos_of_free [Module.Free R M] [Nontrivial M] : 0 < Module.rank R M := have := Module.nontrivial R M (pos_of_ne_zero <\| Cardinal.mk_ne_zero _).trans_le (Free.chooseBasis R M).linearIndependent.cardinal_le_rank variable [Nontrivial R] section variable [NoZeroSMulDivisors R M] theorem rank_zero_iff_forall_zero : Module.rank R M = 0 ↔ ∀ x : M, x = 0 := by simp_rw [rank_eq_zero_iff, smul_eq_zero, and_or_left, not_and_self_iff, false_or, exists_and_right, and_iff_right (exists_ne (0 : R))] /-- See `rank_subsingleton` for the reason that `Nontrivial R` is needed. Also see `rank_eq_zero_iff` for the version without `NoZeroSMulDivisor R M`. -/ theorem rank_zero_iff : Module.rank R M = 0 ↔ Subsingleton M := rank_zero_iff_forall_zero.trans (subsingleton_iff_forall_eq 0).symm theorem rank_pos_iff_exists_ne_zero : 0 < Module.rank R M ↔ ∃ x : M, x ≠ 0 := by rw [← not_iff_not] simpa using rank_zero_iff_forall_zero theorem rank_pos_iff_nontrivial : 0 < Module.rank R M ↔ Nontrivial M := rank_pos_iff_exists_ne_zero.trans (nontrivial_iff_exists_ne 0).symm theorem rank_pos [Nontrivial M] : 0 < Module.rank R M := rank_pos_iff_nontrivial.mpr ‹_› end variable (R M) /-- See `rank_subsingleton` that assumes `Subsingleton R` instead. -/ @[nontriviality] theorem rank_subsingleton' [Subsingleton M] : Module.rank R M = 0 := rank_eq_zero_iff.mpr fun _ ↦ ⟨1, one_ne_zero, Subsingleton.elim _ _⟩ @[simp] theorem rank_punit : Module.rank R PUnit = 0 := rank_subsingleton' _ _ @[simp] theorem rank_bot : Module.rank R (⊥ : Submodule R M) = 0 := rank_subsingleton' _ _ variable {R M} theorem exists_mem_ne_zero_of_rank_pos {s : Submodule R M} (h : 0 < Module.rank R s) : ∃ b : M, b ∈ s ∧ b ≠ 0 := exists_mem_ne_zero_of_ne_bot fun eq => by rw [eq, rank_bot] at h; exact lt_irrefl _ h end RankZero section Finite theorem Module.finite_of_rank_eq_nat [Module.Free R M] {n : ℕ} (h : Module.rank R M = n) : Module.Finite R M := by nontriviality R obtain ⟨⟨ι, b⟩⟩ := Module.Free.exists_basis (R := R) (M := M) have := mk_lt_aleph0_iff.mp <\| b.linearIndependent.cardinal_le_rank \|>.trans_eq h \|>.trans_lt <\| nat_lt_aleph0 n exact Module.Finite.of_basis b theorem Module.finite_of_rank_eq_zero [NoZeroSMulDivisors R M] (h : Module.rank R M = 0) : Module.Finite R M := by nontriviality R rw [rank_zero_iff] at h infer_instance theorem Module.finite_of_rank_eq_one [Module.Free R M] (h : Module.rank R M = 1) : Module.Finite R M := Module.finite_of_rank_eq_nat <\| h.trans Nat.cast_one.symm section variable [StrongRankCondition R] /-- If a module has a finite dimension, all bases are indexed by a finite type. -/ theorem Basis.nonempty_fintype_index_of_rank_lt_aleph0 {ι : Type} (b : Basis ι R M) (h : Module.rank R M < ℵ₀) : Nonempty (Fintype ι) := by rwa [← Cardinal.lift_lt, ← b.mk_eq_rank, Cardinal.lift_aleph0, Cardinal.lift_lt_aleph0, Cardinal.lt_aleph0_iff_fintype] at h /-- If a module has a finite dimension, all bases are indexed by a finite type. -/ noncomputable def Basis.fintypeIndexOfRankLtAleph0 {ι : Type} (b : Basis ι R M) (h : Module.rank R M < ℵ₀) : Fintype ι := Classical.choice (b.nonempty_fintype_index_of_rank_lt_aleph0 h) /-- If a module has a finite dimension, all bases are indexed by a finite set. -/ theorem Basis.finite_index_of_rank_lt_aleph0 {ι : Type} {s : Set ι} (b : Basis s R M) (h : Module.rank R M < ℵ₀) : s.Finite := finite_def.2 (b.nonempty_fintype_index_of_rank_lt_aleph0 h) end namespace LinearIndependent variable [StrongRankCondition R] theorem cardinalMk_le_finrank [Module.Finite R M] {ι : Type w} {b : ι → M} (h : LinearIndependent R b) : #ι ≤ finrank R M := by rw [← lift_le.{max v w}] simpa only [← finrank_eq_rank, lift_natCast, lift_le_nat_iff] using h.cardinal_lift_le_rank @[deprecated (since := "2024-11-10")] alias cardinal_mk_le_finrank := cardinalMk_le_finrank theorem fintype_card_le_finrank [Module.Finite R M] {ι : Type} [Fintype ι] {b : ι → M} (h : LinearIndependent R b) : Fintype.card ι ≤ finrank R M := by simpa using h.cardinalMk_le_finrank theorem finset_card_le_finrank [Module.Finite R M] {b : Finset M} (h : LinearIndependent R (fun x => x : b → M)) : b.card ≤ finrank R M := by rw [← Fintype.card_coe] exact h.fintype_card_le_finrank theorem lt_aleph0_of_finite {ι : Type w} [Module.Finite R M] {v : ι → M} (h : LinearIndependent R v) : #ι < ℵ₀ := by apply Cardinal.lift_lt.1 apply lt_of_le_of_lt · apply h.cardinal_lift_le_rank · rw [← finrank_eq_rank, Cardinal.lift_aleph0, Cardinal.lift_natCast] apply Cardinal.nat_lt_aleph0 theorem finite [Module.Finite R M] {ι : Type} {f : ι → M} (h : LinearIndependent R f) : Finite ι := Cardinal.lt_aleph0_iff_finite.1 <\| h.lt_aleph0_of_finite theorem setFinite [Module.Finite R M] {b : Set M} (h : LinearIndependent R fun x : b => (x : M)) : b.Finite := Cardinal.lt_aleph0_iff_set_finite.mp h.lt_aleph0_of_finite end LinearIndependent lemma exists_set_linearIndependent_of_lt_rank {n : Cardinal} (hn : n < Module.rank R M) : ∃ s : Set M, #s = n ∧ LinearIndepOn R id s := by obtain ⟨⟨s, hs⟩, hs'⟩ := exists_lt_of_lt_ciSup' (hn.trans_eq (Module.rank_def R M)) obtain ⟨t, ht, ht'⟩ := le_mk_iff_exists_subset.mp hs'.le exact ⟨t, ht', hs.mono ht⟩ lemma exists_finset_linearIndependent_of_le_rank {n : ℕ} (hn : n ≤ Module.rank R M) : ∃ s : Finset M, s.card = n ∧ LinearIndepOn R id (s : Set M) := by have := nonempty_linearIndependent_set rcases hn.eq_or_lt with h \| h · obtain ⟨⟨s, hs⟩, hs'⟩ := Cardinal.exists_eq_natCast_of_iSup_eq _ (Cardinal.bddAbove_range _) _ (h.trans (Module.rank_def R M)).symm have : Finite s := lt_aleph0_iff_finite.mp (hs' ▸ nat_lt_aleph0 n) cases nonempty_fintype s refine ⟨s.toFinset, by simpa using hs', by simpa⟩ · obtain ⟨s, hs, hs'⟩ := exists_set_linearIndependent_of_lt_rank h have : Finite s := lt_aleph0_iff_finite.mp (hs ▸ nat_lt_aleph0 n) cases nonempty_fintype s exact ⟨s.toFinset, by simpa using hs, by simpa⟩ lemma exists_linearIndependent_of_le_rank {n : ℕ} (hn : n ≤ Module.rank R M) : ∃ f : Fin n → M, LinearIndependent R f := have ⟨_, hs, hs'⟩ := exists_finset_linearIndependent_of_le_rank hn ⟨_, (linearIndependent_equiv (Finset.equivFinOfCardEq hs).symm).mpr hs'⟩ lemma natCast_le_rank_iff [Nontrivial R] {n : ℕ} : n ≤ Module.rank R M ↔ ∃ f : Fin n → M, LinearIndependent R f := ⟨exists_linearIndependent_of_le_rank, fun H ↦ by simpa using H.choose_spec.cardinal_lift_le_rank⟩ lemma natCast_le_rank_iff_finset [Nontrivial R] {n : ℕ} : n ≤ Module.rank R M ↔ ∃ s : Finset M, s.card = n ∧ LinearIndependent R ((↑) : s → M) := ⟨exists_finset_linearIndependent_of_le_rank, fun ⟨s, h₁, h₂⟩ ↦ by simpa [h₁] using h₂.cardinal_le_rank⟩ lemma exists_finset_linearIndependent_of_le_finrank {n : ℕ} (hn : n ≤ finrank R M) : ∃ s : Finset M, s.card = n ∧ LinearIndependent R ((↑) : s → M) := by by_cases h : finrank R M = 0 · rw [le_zero_iff.mp (hn.trans_eq h)] exact ⟨∅, rfl, by convert linearIndependent_empty R M using 2 <;> aesop⟩ exact exists_finset_linearIndependent_of_le_rank ((Nat.cast_le.mpr hn).trans_eq (cast_toNat_of_lt_aleph0 (toNat_ne_zero.mp h).2)) lemma exists_linearIndependent_of_le_finrank {n : ℕ} (hn : n ≤ finrank R M) : ∃ f : Fin n → M, LinearIndependent R f := have ⟨_, hs, hs'⟩ := exists_finset_linearIndependent_of_le_finrank hn ⟨_, (linearIndependent_equiv (Finset.equivFinOfCardEq hs).symm).mpr hs'⟩ variable [Module.Finite R M] [StrongRankCondition R] in theorem Module.Finite.not_linearIndependent_of_infinite {ι : Type} [Infinite ι] (v : ι → M) : ¬LinearIndependent R v := mt LinearIndependent.finite <\| @not_finite _ _ section variable [NoZeroSMulDivisors R M] theorem iSupIndep.subtype_ne_bot_le_rank [Nontrivial R] {V : ι → Submodule R M} (hV : iSupIndep V) : Cardinal.lift.{v} #{ i : ι // V i ≠ ⊥ } ≤ Cardinal.lift.{w} (Module.rank R M) := by set I := { i : ι // V i ≠ ⊥ } have hI : ∀ i : I, ∃ v ∈ V i, v ≠ (0 : M) := by intro i rw [← Submodule.ne_bot_iff] exact i.prop choose v hvV hv using hI have : LinearIndependent R v := (hV.comp Subtype.coe_injective).linearIndependent _ hvV hv exact this.cardinal_lift_le_rank @[deprecated (since := "2024-11-24")] alias CompleteLattice.Independent.subtype_ne_bot_le_rank := iSupIndep.subtype_ne_bot_le_rank variable [Module.Finite R M] [StrongRankCondition R] theorem iSupIndep.subtype_ne_bot_le_finrank_aux {p : ι → Submodule R M} (hp : iSupIndep p) : #{ i // p i ≠ ⊥ } ≤ (finrank R M : Cardinal.{w}) := by suffices Cardinal.lift.{v} #{ i // p i ≠ ⊥ } ≤ Cardinal.lift.{v} (finrank R M : Cardinal.{w}) by rwa [Cardinal.lift_le] at this calc Cardinal.lift.{v} #{ i // p i ≠ ⊥ } ≤ Cardinal.lift.{w} (Module.rank R M) := hp.subtype_ne_bot_le_rank _ = Cardinal.lift.{w} (finrank R M : Cardinal.{v}) := by rw [finrank_eq_rank] _ = Cardinal.lift.{v} (finrank R M : Cardinal.{w}) := by simp /-- If `p` is an independent family of submodules of a `R`-finite module `M`, then the number of nontrivial subspaces in the family `p` is finite. -/ noncomputable def iSupIndep.fintypeNeBotOfFiniteDimensional {p : ι → Submodule R M} (hp : iSupIndep p) : Fintype { i : ι // p i ≠ ⊥ } := by suffices #{ i // p i ≠ ⊥ } < (ℵ₀ : Cardinal.{w}) by rw [Cardinal.lt_aleph0_iff_fintype] at this exact this.some refine lt_of_le_of_lt hp.subtype_ne_bot_le_finrank_aux ?_ simp [Cardinal.nat_lt_aleph0] /-- If `p` is an independent family of submodules of a `R`-finite module `M`, then the number of nontrivial subspaces in the family `p` is bounded above by the dimension of `M`. Note that the `Fintype` hypothesis required here can be provided by `iSupIndep.fintypeNeBotOfFiniteDimensional`. -/ theorem iSupIndep.subtype_ne_bot_le_finrank {p : ι → Submodule R M} (hp : iSupIndep p) [Fintype { i // p i ≠ ⊥ }] : Fintype.card { i // p i ≠ ⊥ } ≤ finrank R M := by simpa using hp.subtype_ne_bot_le_finrank_aux end variable [Module.Finite R M] [StrongRankCondition R] section open Finset /-- If a finset has cardinality larger than the rank of a module, then there is a nontrivial linear relation amongst its elements. -/ theorem Module.exists_nontrivial_relation_of_finrank_lt_card {t : Finset M} (h : finrank R M < t.card) : ∃ f : M → R, ∑ e ∈ t, f e • e = 0 ∧ ∃ x ∈ t, f x ≠ 0 := by obtain ⟨g, sum, z, nonzero⟩ := Fintype.not_linearIndependent_iff.mp (mt LinearIndependent.finset_card_le_finrank h.not_le) refine ⟨Subtype.val.extend g 0, ?_, z, z.2, by rwa [Subtype.val_injective.extend_apply]⟩ rw [← Finset.sum_finset_coe]; convert sum; apply Subtype.val_injective.extend_apply /-- If a finset has cardinality larger than `finrank + 1`, then there is a nontrivial linear relation amongst its elements, such that the coefficients of the relation sum to zero. -/ theorem Module.exists_nontrivial_relation_sum_zero_of_finrank_succ_lt_card {t : Finset M} (h : finrank R M + 1 < t.card) : ∃ f : M → R, ∑ e ∈ t, f e • e = 0 ∧ ∑ e ∈ t, f e = 0 ∧ ∃ x ∈ t, f x ≠ 0 := by -- Pick an element x₀ ∈ t, obtain ⟨x₀, x₀_mem⟩ := card_pos.1 ((Nat.succ_pos _).trans h) -- and apply the previous lemma to the {xᵢ - x₀} let shift : M ↪ M := ⟨(· - x₀), sub_left_injective⟩ classical let t' := (t.erase x₀).map shift have h' : finrank R M < t'.card := by rw [card_map, card_erase_of_mem x₀_mem] exact Nat.lt_pred_iff.mpr h -- to obtain a function `g`. obtain ⟨g, gsum, x₁, x₁_mem, nz⟩ := exists_nontrivial_relation_of_finrank_lt_card h' -- Then obtain `f` by translating back by `x₀`, -- and setting the value of `f` at `x₀` to ensure `∑ e ∈ t, f e = 0`. let f : M → R := fun z ↦ if z = x₀ then -∑ z ∈ t.erase x₀, g (z - x₀) else g (z - x₀) refine ⟨f, ?_, ?_, ?_⟩ -- After this, it's a matter of verifying the properties, -- based on the corresponding properties for `g`. · rw [sum_map, Embedding.coeFn_mk] at gsum simp_rw [f, ← t.sum_erase_add _ x₀_mem, if_pos, neg_smul, sum_smul, ← sub_eq_add_neg, ← sum_sub_distrib, ← gsum, smul_sub] refine sum_congr rfl fun x x_mem ↦ ?_ rw [if_neg (mem_erase.mp x_mem).1] · simp_rw [f, ← t.sum_erase_add _ x₀_mem, if_pos, add_neg_eq_zero] exact sum_congr rfl fun x x_mem ↦ if_neg (mem_erase.mp x_mem).1 · obtain ⟨x₁, x₁_mem', rfl⟩ := Finset.mem_map.mp x₁_mem have := mem_erase.mp x₁_mem' exact ⟨x₁, by simpa only [f, Embedding.coeFn_mk, sub_add_cancel, this.2, true_and, if_neg this.1]⟩ end end Finite section FinrankZero section variable [Nontrivial R] /-- A (finite dimensional) space that is a subsingleton has zero `finrank`. -/ @[nontriviality] theorem Module.finrank_zero_of_subsingleton [Subsingleton M] : finrank R M = 0 := by rw [finrank, rank_subsingleton', map_zero] lemma LinearIndependent.finrank_eq_zero_of_infinite {ι} [Infinite ι] {v : ι → M} (hv : LinearIndependent R v) : finrank R M = 0 := toNat_eq_zero.mpr <\| .inr hv.aleph0_le_rank section variable [NoZeroSMulDivisors R M] /-- A finite dimensional space is nontrivial if it has positive `finrank`. -/ theorem Module.nontrivial_of_finrank_pos (h : 0 < finrank R M) : Nontrivial M := rank_pos_iff_nontrivial.mp (lt_rank_of_lt_finrank h) /-- A finite dimensional space is nontrivial if it has `finrank` equal to the successor of a natural number. -/ theorem Module.nontrivial_of_finrank_eq_succ {n : ℕ} (hn : finrank R M = n.succ) : Nontrivial M := nontrivial_of_finrank_pos (R := R) (by rw [hn]; exact n.succ_pos) end variable (R M) @[simp] theorem finrank_bot : finrank R (⊥ : Submodule R M) = 0 := finrank_eq_of_rank_eq (rank_bot _ _) end section StrongRankCondition variable [StrongRankCondition R] [Module.Finite R M] /-- A finite rank torsion-free module has positive `finrank` iff it has a nonzero element. -/ theorem Module.finrank_pos_iff_exists_ne_zero [NoZeroSMulDivisors R M] : 0 < finrank R M ↔ ∃ x : M, x ≠ 0 := by rw [← @rank_pos_iff_exists_ne_zero R M, ← finrank_eq_rank] norm_cast /-- An `R`-finite torsion-free module has positive `finrank` iff it is nontrivial. -/ theorem Module.finrank_pos_iff [NoZeroSMulDivisors R M] : 0 < finrank R M ↔ Nontrivial M := by rw [← rank_pos_iff_nontrivial (R := R), ← finrank_eq_rank] norm_cast /-- A nontrivial finite dimensional space has positive `finrank`. -/ theorem Module.finrank_pos [NoZeroSMulDivisors R M] [h : Nontrivial M] : 0 < finrank R M := finrank_pos_iff.mpr h /-- See `Module.finrank_zero_iff` for the stronger version with `NoZeroSMulDivisors R M`. -/ theorem Module.finrank_eq_zero_iff : finrank R M = 0 ↔ ∀ x : M, ∃ a : R, a ≠ 0 ∧ a • x = 0 := by rw [← rank_eq_zero_iff (R := R), ← finrank_eq_rank] norm_cast /-- A finite dimensional space has zero `finrank` iff it is a subsingleton. This is the `finrank` version of `rank_zero_iff`. -/ theorem Module.finrank_zero_iff [NoZeroSMulDivisors R M] : finrank R M = 0 ↔ Subsingleton M := by rw [← rank_zero_iff (R := R), ← finrank_eq_rank] norm_cast /-- Similar to `rank_quotient_add_rank_le` but for `finrank` and a finite `M`. -/ lemma Module.finrank_quotient_add_finrank_le (N : Submodule R M) : finrank R (M ⧸ N) + finrank R N ≤ finrank R M := by haveI := nontrivial_of_invariantBasisNumber R have := rank_quotient_add_rank_le N rw [← finrank_eq_rank R M, ← finrank_eq_rank R, ← N.finrank_eq_rank] at this exact mod_cast this end StrongRankCondition theorem Module.finrank_eq_zero_of_rank_eq_zero (h : Module.rank R M = 0) : finrank R M = 0 := by delta finrank rw [h, zero_toNat] theorem Submodule.bot_eq_top_of_rank_eq_zero [NoZeroSMulDivisors R M] (h : Module.rank R M = 0) : (⊥ : Submodule R M) = ⊤ := by nontriviality R rw [rank_zero_iff] at h subsingleton /-- See `rank_subsingleton` for the reason that `Nontrivial R` is needed. -/ @[simp] theorem Submodule.rank_eq_zero [Nontrivial R] [NoZeroSMulDivisors R M] {S : Submodule R M} : Module.rank R S = 0 ↔ S = ⊥ := ⟨fun h => (Submodule.eq_bot_iff _).2 fun x hx =>	congr_arg Subtype.val <\| ((Submodule.eq_bot_iff _).1 <\| Eq.symm <\| Submodule.bot_eq_top_of_rank_eq_zero h) ⟨x, hx⟩ Submodule.mem_top, fun h => by rw [h, rank_bot]⟩ @[simp] theorem Submodule.finrank_eq_zero [StrongRankCondition R] [NoZeroSMulDivisors R M] {S : Submodule R M} [Module.Finite R S] :	Mathlib/LinearAlgebra/Dimension/Finite.lean	468	475
/- Copyright (c) 2018 Chris Hughes. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Chris Hughes, Johannes Hölzl, Kim Morrison, Jens Wagemaker -/ import Mathlib.Algebra.MonoidAlgebra.Degree import Mathlib.Algebra.Order.Ring.WithTop import Mathlib.Algebra.Polynomial.Basic import Mathlib.Data.Nat.Cast.WithTop import Mathlib.Data.Nat.SuccPred import Mathlib.Order.SuccPred.WithBot /-! # Degree of univariate polynomials ## Main definitions * `Polynomial.degree`: the degree of a polynomial, where `0` has degree `⊥` * `Polynomial.natDegree`: the degree of a polynomial, where `0` has degree `0` * `Polynomial.leadingCoeff`: the leading coefficient of a polynomial * `Polynomial.Monic`: a polynomial is monic if its leading coefficient is 0 * `Polynomial.nextCoeff`: the next coefficient after the leading coefficient ## Main results * `Polynomial.degree_eq_natDegree`: the degree and natDegree coincide for nonzero polynomials -/ noncomputable section open Finsupp Finset open Polynomial namespace Polynomial universe u v variable {R : Type u} {S : Type v} {a b c d : R} {n m : ℕ} section Semiring variable [Semiring R] {p q r : R[X]} /-- `degree p` is the degree of the polynomial `p`, i.e. the largest `X`-exponent in `p`. `degree p = some n` when `p ≠ 0` and `n` is the highest power of `X` that appears in `p`, otherwise `degree 0 = ⊥`. -/ def degree (p : R[X]) : WithBot ℕ := p.support.max /-- `natDegree p` forces `degree p` to ℕ, by defining `natDegree 0 = 0`. -/ def natDegree (p : R[X]) : ℕ := (degree p).unbotD 0 /-- `leadingCoeff p` gives the coefficient of the highest power of `X` in `p`. -/ def leadingCoeff (p : R[X]) : R := coeff p (natDegree p) /-- a polynomial is `Monic` if its leading coefficient is 1 -/ def Monic (p : R[X]) := leadingCoeff p = (1 : R) theorem Monic.def : Monic p ↔ leadingCoeff p = 1 := Iff.rfl instance Monic.decidable [DecidableEq R] : Decidable (Monic p) := by unfold Monic; infer_instance @[simp] theorem Monic.leadingCoeff {p : R[X]} (hp : p.Monic) : leadingCoeff p = 1 := hp theorem Monic.coeff_natDegree {p : R[X]} (hp : p.Monic) : p.coeff p.natDegree = 1 := hp @[simp] theorem degree_zero : degree (0 : R[X]) = ⊥ := rfl @[simp] theorem natDegree_zero : natDegree (0 : R[X]) = 0 := rfl @[simp] theorem coeff_natDegree : coeff p (natDegree p) = leadingCoeff p := rfl @[simp] theorem degree_eq_bot : degree p = ⊥ ↔ p = 0 := ⟨fun h => support_eq_empty.1 (Finset.max_eq_bot.1 h), fun h => h.symm ▸ rfl⟩ theorem degree_ne_bot : degree p ≠ ⊥ ↔ p ≠ 0 := degree_eq_bot.not theorem degree_eq_natDegree (hp : p ≠ 0) : degree p = (natDegree p : WithBot ℕ) := by let ⟨n, hn⟩ := not_forall.1 (mt Option.eq_none_iff_forall_not_mem.2 (mt degree_eq_bot.1 hp)) have hn : degree p = some n := Classical.not_not.1 hn rw [natDegree, hn]; rfl theorem degree_eq_iff_natDegree_eq {p : R[X]} {n : ℕ} (hp : p ≠ 0) : p.degree = n ↔ p.natDegree = n := by rw [degree_eq_natDegree hp]; exact WithBot.coe_eq_coe theorem degree_eq_iff_natDegree_eq_of_pos {p : R[X]} {n : ℕ} (hn : 0 < n) : p.degree = n ↔ p.natDegree = n := by obtain rfl\|h := eq_or_ne p 0 · simp [hn.ne] · exact degree_eq_iff_natDegree_eq h theorem natDegree_eq_of_degree_eq_some {p : R[X]} {n : ℕ} (h : degree p = n) : natDegree p = n := by rw [natDegree, h, Nat.cast_withBot, WithBot.unbotD_coe] theorem degree_ne_of_natDegree_ne {n : ℕ} : p.natDegree ≠ n → degree p ≠ n := mt natDegree_eq_of_degree_eq_some @[simp] theorem degree_le_natDegree : degree p ≤ natDegree p := WithBot.giUnbotDBot.gc.le_u_l _ theorem natDegree_eq_of_degree_eq [Semiring S] {q : S[X]} (h : degree p = degree q) : natDegree p = natDegree q := by unfold natDegree; rw [h] theorem le_degree_of_ne_zero (h : coeff p n ≠ 0) : (n : WithBot ℕ) ≤ degree p := by rw [Nat.cast_withBot] exact Finset.le_sup (mem_support_iff.2 h) theorem degree_mono [Semiring S] {f : R[X]} {g : S[X]} (h : f.support ⊆ g.support) : f.degree ≤ g.degree := Finset.sup_mono h theorem degree_le_degree (h : coeff q (natDegree p) ≠ 0) : degree p ≤ degree q := by by_cases hp : p = 0 · rw [hp, degree_zero] exact bot_le · rw [degree_eq_natDegree hp] exact le_degree_of_ne_zero h theorem natDegree_le_iff_degree_le {n : ℕ} : natDegree p ≤ n ↔ degree p ≤ n := WithBot.unbotD_le_iff (fun _ ↦ bot_le) theorem natDegree_lt_iff_degree_lt (hp : p ≠ 0) : p.natDegree < n ↔ p.degree < ↑n := WithBot.unbotD_lt_iff (absurd · (degree_eq_bot.not.mpr hp)) alias ⟨degree_le_of_natDegree_le, natDegree_le_of_degree_le⟩ := natDegree_le_iff_degree_le theorem natDegree_le_natDegree [Semiring S] {q : S[X]} (hpq : p.degree ≤ q.degree) : p.natDegree ≤ q.natDegree := WithBot.giUnbotDBot.gc.monotone_l hpq @[simp] theorem degree_C (ha : a ≠ 0) : degree (C a) = (0 : WithBot ℕ) := by rw [degree, ← monomial_zero_left, support_monomial 0 ha, max_eq_sup_coe, sup_singleton, WithBot.coe_zero] theorem degree_C_le : degree (C a) ≤ 0 := by by_cases h : a = 0 · rw [h, C_0] exact bot_le · rw [degree_C h] theorem degree_C_lt : degree (C a) < 1 := degree_C_le.trans_lt <\| WithBot.coe_lt_coe.mpr zero_lt_one theorem degree_one_le : degree (1 : R[X]) ≤ (0 : WithBot ℕ) := by rw [← C_1]; exact degree_C_le @[simp] theorem natDegree_C (a : R) : natDegree (C a) = 0 := by by_cases ha : a = 0 · have : C a = 0 := by rw [ha, C_0] rw [natDegree, degree_eq_bot.2 this, WithBot.unbotD_bot] · rw [natDegree, degree_C ha, WithBot.unbotD_zero] @[simp] theorem natDegree_one : natDegree (1 : R[X]) = 0 := natDegree_C 1 @[simp] theorem natDegree_natCast (n : ℕ) : natDegree (n : R[X]) = 0 := by simp only [← C_eq_natCast, natDegree_C] @[simp] theorem natDegree_ofNat (n : ℕ) [Nat.AtLeastTwo n] : natDegree (ofNat(n) : R[X]) = 0 := natDegree_natCast _ theorem degree_natCast_le (n : ℕ) : degree (n : R[X]) ≤ 0 := degree_le_of_natDegree_le (by simp) @[simp] theorem degree_monomial (n : ℕ) (ha : a ≠ 0) : degree (monomial n a) = n := by rw [degree, support_monomial n ha, max_singleton, Nat.cast_withBot] @[simp] theorem degree_C_mul_X_pow (n : ℕ) (ha : a ≠ 0) : degree (C a * X ^ n) = n := by rw [C_mul_X_pow_eq_monomial, degree_monomial n ha] theorem degree_C_mul_X (ha : a ≠ 0) : degree (C a * X) = 1 := by simpa only [pow_one] using degree_C_mul_X_pow 1 ha theorem degree_monomial_le (n : ℕ) (a : R) : degree (monomial n a) ≤ n := letI := Classical.decEq R if h : a = 0 then by rw [h, (monomial n).map_zero, degree_zero]; exact bot_le else le_of_eq (degree_monomial n h) theorem degree_C_mul_X_pow_le (n : ℕ) (a : R) : degree (C a * X ^ n) ≤ n := by rw [C_mul_X_pow_eq_monomial] apply degree_monomial_le theorem degree_C_mul_X_le (a : R) : degree (C a * X) ≤ 1 := by simpa only [pow_one] using degree_C_mul_X_pow_le 1 a @[simp] theorem natDegree_C_mul_X_pow (n : ℕ) (a : R) (ha : a ≠ 0) : natDegree (C a * X ^ n) = n := natDegree_eq_of_degree_eq_some (degree_C_mul_X_pow n ha) @[simp] theorem natDegree_C_mul_X (a : R) (ha : a ≠ 0) : natDegree (C a * X) = 1 := by simpa only [pow_one] using natDegree_C_mul_X_pow 1 a ha @[simp] theorem natDegree_monomial [DecidableEq R] (i : ℕ) (r : R) : natDegree (monomial i r) = if r = 0 then 0 else i := by split_ifs with hr · simp [hr] · rw [← C_mul_X_pow_eq_monomial, natDegree_C_mul_X_pow i r hr] theorem natDegree_monomial_le (a : R) {m : ℕ} : (monomial m a).natDegree ≤ m := by classical rw [Polynomial.natDegree_monomial] split_ifs exacts [Nat.zero_le _, le_rfl] theorem natDegree_monomial_eq (i : ℕ) {r : R} (r0 : r ≠ 0) : (monomial i r).natDegree = i := letI := Classical.decEq R Eq.trans (natDegree_monomial _ _) (if_neg r0) theorem coeff_ne_zero_of_eq_degree (hn : degree p = n) : coeff p n ≠ 0 := fun h => mem_support_iff.mp (mem_of_max hn) h theorem degree_X_pow_le (n : ℕ) : degree (X ^ n : R[X]) ≤ n := by simpa only [C_1, one_mul] using degree_C_mul_X_pow_le n (1 : R) theorem degree_X_le : degree (X : R[X]) ≤ 1 := degree_monomial_le _ _ theorem natDegree_X_le : (X : R[X]).natDegree ≤ 1 := natDegree_le_of_degree_le degree_X_le theorem withBotSucc_degree_eq_natDegree_add_one (h : p ≠ 0) : p.degree.succ = p.natDegree + 1 := by rw [degree_eq_natDegree h] exact WithBot.succ_coe p.natDegree end Semiring section NonzeroSemiring variable [Semiring R] [Nontrivial R] {p q : R[X]} @[simp] theorem degree_one : degree (1 : R[X]) = (0 : WithBot ℕ) := degree_C one_ne_zero @[simp] theorem degree_X : degree (X : R[X]) = 1 := degree_monomial _ one_ne_zero @[simp] theorem natDegree_X : (X : R[X]).natDegree = 1 := natDegree_eq_of_degree_eq_some degree_X end NonzeroSemiring section Ring variable [Ring R] @[simp] theorem degree_neg (p : R[X]) : degree (-p) = degree p := by unfold degree; rw [support_neg] theorem degree_neg_le_of_le {a : WithBot ℕ} {p : R[X]} (hp : degree p ≤ a) : degree (-p) ≤ a := p.degree_neg.le.trans hp @[simp] theorem natDegree_neg (p : R[X]) : natDegree (-p) = natDegree p := by simp [natDegree] theorem natDegree_neg_le_of_le {p : R[X]} (hp : natDegree p ≤ m) : natDegree (-p) ≤ m := (natDegree_neg p).le.trans hp @[simp] theorem natDegree_intCast (n : ℤ) : natDegree (n : R[X]) = 0 := by rw [← C_eq_intCast, natDegree_C] theorem degree_intCast_le (n : ℤ) : degree (n : R[X]) ≤ 0 := degree_le_of_natDegree_le (by simp) @[simp] theorem leadingCoeff_neg (p : R[X]) : (-p).leadingCoeff = -p.leadingCoeff := by rw [leadingCoeff, leadingCoeff, natDegree_neg, coeff_neg] end Ring section Semiring variable [Semiring R] {p : R[X]} /-- The second-highest coefficient, or 0 for constants -/ def nextCoeff (p : R[X]) : R := if p.natDegree = 0 then 0 else p.coeff (p.natDegree - 1) lemma nextCoeff_eq_zero : p.nextCoeff = 0 ↔ p.natDegree = 0 ∨ 0 < p.natDegree ∧ p.coeff (p.natDegree - 1) = 0 := by simp [nextCoeff, or_iff_not_imp_left, pos_iff_ne_zero]; aesop lemma nextCoeff_ne_zero : p.nextCoeff ≠ 0 ↔ p.natDegree ≠ 0 ∧ p.coeff (p.natDegree - 1) ≠ 0 := by simp [nextCoeff] @[simp] theorem nextCoeff_C_eq_zero (c : R) : nextCoeff (C c) = 0 := by rw [nextCoeff] simp theorem nextCoeff_of_natDegree_pos (hp : 0 < p.natDegree) : nextCoeff p = p.coeff (p.natDegree - 1) := by rw [nextCoeff, if_neg] contrapose! hp simpa variable {p q : R[X]} {ι : Type} theorem degree_add_le (p q : R[X]) : degree (p + q) ≤ max (degree p) (degree q) := by simpa only [degree, ← support_toFinsupp, toFinsupp_add] using AddMonoidAlgebra.sup_support_add_le _ _ _ theorem degree_add_le_of_degree_le {p q : R[X]} {n : ℕ} (hp : degree p ≤ n) (hq : degree q ≤ n) : degree (p + q) ≤ n := (degree_add_le p q).trans <\| max_le hp hq theorem degree_add_le_of_le {a b : WithBot ℕ} (hp : degree p ≤ a) (hq : degree q ≤ b) : degree (p + q) ≤ max a b := (p.degree_add_le q).trans <\| max_le_max ‹_› ‹_› theorem natDegree_add_le (p q : R[X]) : natDegree (p + q) ≤ max (natDegree p) (natDegree q) := by rcases le_max_iff.1 (degree_add_le p q) with h \| h <;> simp [natDegree_le_natDegree h] theorem natDegree_add_le_of_degree_le {p q : R[X]} {n : ℕ} (hp : natDegree p ≤ n) (hq : natDegree q ≤ n) : natDegree (p + q) ≤ n := (natDegree_add_le p q).trans <\| max_le hp hq theorem natDegree_add_le_of_le (hp : natDegree p ≤ m) (hq : natDegree q ≤ n) : natDegree (p + q) ≤ max m n := (p.natDegree_add_le q).trans <\| max_le_max ‹_› ‹_› @[simp] theorem leadingCoeff_zero : leadingCoeff (0 : R[X]) = 0 := rfl @[simp] theorem leadingCoeff_eq_zero : leadingCoeff p = 0 ↔ p = 0 := ⟨fun h => Classical.by_contradiction fun hp => mt mem_support_iff.1 (Classical.not_not.2 h) (mem_of_max (degree_eq_natDegree hp)), fun h => h.symm ▸ leadingCoeff_zero⟩ theorem leadingCoeff_ne_zero : leadingCoeff p ≠ 0 ↔ p ≠ 0 := by rw [Ne, leadingCoeff_eq_zero] theorem leadingCoeff_eq_zero_iff_deg_eq_bot : leadingCoeff p = 0 ↔ degree p = ⊥ := by rw [leadingCoeff_eq_zero, degree_eq_bot] theorem natDegree_C_mul_X_pow_le (a : R) (n : ℕ) : natDegree (C a X ^ n) ≤ n := natDegree_le_iff_degree_le.2 <\| degree_C_mul_X_pow_le _ _ theorem degree_erase_le (p : R[X]) (n : ℕ) : degree (p.erase n) ≤ degree p := by rcases p with ⟨p⟩ simp only [erase_def, degree, coeff, support] apply sup_mono rw [Finsupp.support_erase] apply Finset.erase_subset theorem degree_erase_lt (hp : p ≠ 0) : degree (p.erase (natDegree p)) < degree p := by apply lt_of_le_of_ne (degree_erase_le _ _) rw [degree_eq_natDegree hp, degree, support_erase] exact fun h => not_mem_erase _ _ (mem_of_max h) theorem degree_update_le (p : R[X]) (n : ℕ) (a : R) : degree (p.update n a) ≤ max (degree p) n := by classical rw [degree, support_update] split_ifs · exact (Finset.max_mono (erase_subset _ _)).trans (le_max_left _ _) · rw [max_insert, max_comm] exact le_rfl theorem degree_sum_le (s : Finset ι) (f : ι → R[X]) : degree (∑ i ∈ s, f i) ≤ s.sup fun b => degree (f b) := Finset.cons_induction_on s (by simp only [sum_empty, sup_empty, degree_zero, le_refl]) fun a s has ih => calc degree (∑ i ∈ cons a s has, f i) ≤ max (degree (f a)) (degree (∑ i ∈ s, f i)) := by rw [Finset.sum_cons]; exact degree_add_le _ _ _ ≤ _ := by rw [sup_cons]; exact max_le_max le_rfl ih theorem degree_mul_le (p q : R[X]) : degree (p * q) ≤ degree p + degree q := by simpa only [degree, ← support_toFinsupp, toFinsupp_mul] using AddMonoidAlgebra.sup_support_mul_le (WithBot.coe_add _ _).le _ _ theorem degree_mul_le_of_le {a b : WithBot ℕ} (hp : degree p ≤ a) (hq : degree q ≤ b) : degree (p * q) ≤ a + b := (p.degree_mul_le _).trans <\| add_le_add ‹_› ‹_› theorem degree_pow_le (p : R[X]) : ∀ n : ℕ, degree (p ^ n) ≤ n • degree p \| 0 => by rw [pow_zero, zero_nsmul]; exact degree_one_le \| n + 1 => calc degree (p ^ (n + 1)) ≤ degree (p ^ n) + degree p := by rw [pow_succ]; exact degree_mul_le _ _ _ ≤ _ := by rw [succ_nsmul]; exact add_le_add_right (degree_pow_le _ _) _ theorem degree_pow_le_of_le {a : WithBot ℕ} (b : ℕ) (hp : degree p ≤ a) : degree (p ^ b) ≤ b * a := by induction b with \| zero => simp [degree_one_le] \| succ n hn => rw [Nat.cast_succ, add_mul, one_mul, pow_succ] exact degree_mul_le_of_le hn hp @[simp] theorem leadingCoeff_monomial (a : R) (n : ℕ) : leadingCoeff (monomial n a) = a := by classical by_cases ha : a = 0 · simp only [ha, (monomial n).map_zero, leadingCoeff_zero] · rw [leadingCoeff, natDegree_monomial, if_neg ha, coeff_monomial] simp theorem leadingCoeff_C_mul_X_pow (a : R) (n : ℕ) : leadingCoeff (C a * X ^ n) = a := by rw [C_mul_X_pow_eq_monomial, leadingCoeff_monomial] theorem leadingCoeff_C_mul_X (a : R) : leadingCoeff (C a * X) = a := by simpa only [pow_one] using leadingCoeff_C_mul_X_pow a 1 @[simp] theorem leadingCoeff_C (a : R) : leadingCoeff (C a) = a := leadingCoeff_monomial a 0 theorem leadingCoeff_X_pow (n : ℕ) : leadingCoeff ((X : R[X]) ^ n) = 1 := by simpa only [C_1, one_mul] using leadingCoeff_C_mul_X_pow (1 : R) n theorem leadingCoeff_X : leadingCoeff (X : R[X]) = 1 := by simpa only [pow_one] using @leadingCoeff_X_pow R _ 1 @[simp] theorem monic_X_pow (n : ℕ) : Monic (X ^ n : R[X]) := leadingCoeff_X_pow n @[simp] theorem monic_X : Monic (X : R[X]) := leadingCoeff_X theorem leadingCoeff_one : leadingCoeff (1 : R[X]) = 1 := leadingCoeff_C 1 @[simp] theorem monic_one : Monic (1 : R[X]) := leadingCoeff_C _ theorem Monic.ne_zero {R : Type} [Semiring R] [Nontrivial R] {p : R[X]} (hp : p.Monic) : p ≠ 0 := by rintro rfl simp [Monic] at hp theorem Monic.ne_zero_of_ne (h : (0 : R) ≠ 1) {p : R[X]} (hp : p.Monic) : p ≠ 0 := by nontriviality R exact hp.ne_zero theorem Monic.ne_zero_of_polynomial_ne {r} (hp : Monic p) (hne : q ≠ r) : p ≠ 0 := haveI := Nontrivial.of_polynomial_ne hne hp.ne_zero theorem natDegree_mul_le {p q : R[X]} : natDegree (p q) ≤ natDegree p + natDegree q := by apply natDegree_le_of_degree_le apply le_trans (degree_mul_le p q) rw [Nat.cast_add] apply add_le_add <;> apply degree_le_natDegree theorem natDegree_mul_le_of_le (hp : natDegree p ≤ m) (hg : natDegree q ≤ n) : natDegree (p * q) ≤ m + n := natDegree_mul_le.trans <\| add_le_add ‹_› ‹_› theorem natDegree_pow_le {p : R[X]} {n : ℕ} : (p ^ n).natDegree ≤ n * p.natDegree := by induction n with \| zero => simp \| succ i hi => rw [pow_succ, Nat.succ_mul] apply le_trans natDegree_mul_le (add_le_add_right hi _) theorem natDegree_pow_le_of_le (n : ℕ) (hp : natDegree p ≤ m) : natDegree (p ^ n) ≤ n * m := natDegree_pow_le.trans (Nat.mul_le_mul le_rfl ‹_›) theorem natDegree_eq_zero_iff_degree_le_zero : p.natDegree = 0 ↔ p.degree ≤ 0 := by rw [← nonpos_iff_eq_zero, natDegree_le_iff_degree_le, Nat.cast_zero] theorem degree_zero_le : degree (0 : R[X]) ≤ 0 := natDegree_eq_zero_iff_degree_le_zero.mp rfl theorem degree_le_iff_coeff_zero (f : R[X]) (n : WithBot ℕ) : degree f ≤ n ↔ ∀ m : ℕ, n < m → coeff f m = 0 := by simp only [degree, Finset.max, Finset.sup_le_iff, mem_support_iff, Ne, ← not_le, not_imp_comm, Nat.cast_withBot] theorem degree_lt_iff_coeff_zero (f : R[X]) (n : ℕ) : degree f < n ↔ ∀ m : ℕ, n ≤ m → coeff f m = 0 := by simp only [degree, Finset.sup_lt_iff (WithBot.bot_lt_coe n), mem_support_iff, WithBot.coe_lt_coe, ← @not_le ℕ, max_eq_sup_coe, Nat.cast_withBot, Ne, not_imp_not] theorem natDegree_pos_iff_degree_pos : 0 < natDegree p ↔ 0 < degree p := lt_iff_lt_of_le_iff_le natDegree_le_iff_degree_le end Semiring section NontrivialSemiring variable [Semiring R] [Nontrivial R] {p q : R[X]} (n : ℕ) @[simp] theorem degree_X_pow : degree ((X : R[X]) ^ n) = n := by rw [X_pow_eq_monomial, degree_monomial _ (one_ne_zero' R)] @[simp] theorem natDegree_X_pow : natDegree ((X : R[X]) ^ n) = n := natDegree_eq_of_degree_eq_some (degree_X_pow n) end NontrivialSemiring section Ring variable [Ring R] {p q : R[X]} theorem degree_sub_le (p q : R[X]) : degree (p - q) ≤ max (degree p) (degree q) := by simpa only [degree_neg q] using degree_add_le p (-q) theorem degree_sub_le_of_le {a b : WithBot ℕ} (hp : degree p ≤ a) (hq : degree q ≤ b) : degree (p - q) ≤ max a b := (p.degree_sub_le q).trans <\| max_le_max ‹_› ‹_› theorem natDegree_sub_le (p q : R[X]) : natDegree (p - q) ≤ max (natDegree p) (natDegree q) := by simpa only [← natDegree_neg q] using natDegree_add_le p (-q) theorem natDegree_sub_le_of_le (hp : natDegree p ≤ m) (hq : natDegree q ≤ n) : natDegree (p - q) ≤ max m n := (p.natDegree_sub_le q).trans <\| max_le_max ‹_› ‹_› theorem degree_sub_lt (hd : degree p = degree q) (hp0 : p ≠ 0) (hlc : leadingCoeff p = leadingCoeff q) : degree (p - q) < degree p := have hp : monomial (natDegree p) (leadingCoeff p) + p.erase (natDegree p) = p := monomial_add_erase _ _ have hq : monomial (natDegree q) (leadingCoeff q) + q.erase (natDegree q) = q := monomial_add_erase _ _ have hd' : natDegree p = natDegree q := by unfold natDegree; rw [hd] have hq0 : q ≠ 0 := mt degree_eq_bot.2 (hd ▸ mt degree_eq_bot.1 hp0) calc degree (p - q) = degree (erase (natDegree q) p + -erase (natDegree q) q) := by conv => lhs rw [← hp, ← hq, hlc, hd', add_sub_add_left_eq_sub, sub_eq_add_neg] _ ≤ max (degree (erase (natDegree q) p)) (degree (erase (natDegree q) q)) := (degree_neg (erase (natDegree q) q) ▸ degree_add_le _ _) _ < degree p := max_lt_iff.2 ⟨hd' ▸ degree_erase_lt hp0, hd.symm ▸ degree_erase_lt hq0⟩ theorem degree_X_sub_C_le (r : R) : (X - C r).degree ≤ 1 := (degree_sub_le _ _).trans (max_le degree_X_le (degree_C_le.trans zero_le_one)) theorem natDegree_X_sub_C_le (r : R) : (X - C r).natDegree ≤ 1 := natDegree_le_iff_degree_le.2 <\| degree_X_sub_C_le r end Ring end Polynomial		Mathlib/Algebra/Polynomial/Degree/Definitions.lean	1,173	1,176
/- 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.Data.Finset.Lattice.Fold import Mathlib.Logic.Encodable.Basic import Mathlib.Order.Atoms import Mathlib.Order.Cofinal import Mathlib.Order.UpperLower.Principal /-! # Order ideals, cofinal sets, and the Rasiowa–Sikorski lemma ## Main definitions Throughout this file, `P` is at least a preorder, but some sections require more structure, such as a bottom element, a top element, or a join-semilattice structure. - `Order.Ideal P`: the type of nonempty, upward directed, and downward closed subsets of `P`. Dual to the notion of a filter on a preorder. - `Order.IsIdeal I`: a predicate for when a `Set P` is an ideal. - `Order.Ideal.principal p`: the principal ideal generated by `p : P`. - `Order.Ideal.IsProper I`: a predicate for proper ideals. Dual to the notion of a proper filter. - `Order.Ideal.IsMaximal I`: a predicate for maximal ideals. Dual to the notion of an ultrafilter. - `Order.Cofinal P`: the type of subsets of `P` containing arbitrarily large elements. Dual to the notion of 'dense set' used in forcing. - `Order.idealOfCofinals p 𝒟`, where `p : P`, and `𝒟` is a countable family of cofinal subsets of `P`: an ideal in `P` which contains `p` and intersects every set in `𝒟`. (This a form of the Rasiowa–Sikorski lemma.) ## References - <https://en.wikipedia.org/wiki/Ideal_(order_theory)> - <https://en.wikipedia.org/wiki/Cofinal_(mathematics)> - <https://en.wikipedia.org/wiki/Rasiowa%E2%80%93Sikorski_lemma> Note that for the Rasiowa–Sikorski lemma, Wikipedia uses the opposite ordering on `P`, in line with most presentations of forcing. ## Tags ideal, cofinal, dense, countable, generic -/ open Function Set namespace Order variable {P : Type*} /-- An ideal on an order `P` is a subset of `P` that is - nonempty - upward directed (any pair of elements in the ideal has an upper bound in the ideal) - downward closed (any element less than an element of the ideal is in the ideal). -/ structure Ideal (P) [LE P] extends LowerSet P where /-- The ideal is nonempty. -/ nonempty' : carrier.Nonempty /-- The ideal is upward directed. -/ directed' : DirectedOn (· ≤ ·) carrier -- TODO: remove this configuration and use the default configuration. -- We keep this to be consistent with Lean 3. initialize_simps_projections Ideal (+toLowerSet, -carrier) /-- A subset of a preorder `P` is an ideal if it is - nonempty - upward directed (any pair of elements in the ideal has an upper bound in the ideal) - downward closed (any element less than an element of the ideal is in the ideal). -/ @[mk_iff] structure IsIdeal {P} [LE P] (I : Set P) : Prop where /-- The ideal is downward closed. -/ IsLowerSet : IsLowerSet I /-- The ideal is nonempty. -/ Nonempty : I.Nonempty /-- The ideal is upward directed. -/ Directed : DirectedOn (· ≤ ·) I /-- Create an element of type `Order.Ideal` from a set satisfying the predicate `Order.IsIdeal`. -/ def IsIdeal.toIdeal [LE P] {I : Set P} (h : IsIdeal I) : Ideal P := ⟨⟨I, h.IsLowerSet⟩, h.Nonempty, h.Directed⟩ namespace Ideal section LE variable [LE P] section variable {I s t : Ideal P} {x : P} theorem toLowerSet_injective : Injective (toLowerSet : Ideal P → LowerSet P) := fun s t _ ↦ by cases s cases t congr instance : SetLike (Ideal P) P where coe s := s.carrier coe_injective' _ _ h := toLowerSet_injective <\| SetLike.coe_injective h @[ext] theorem ext {s t : Ideal P} : (s : Set P) = t → s = t := SetLike.ext' @[simp] theorem carrier_eq_coe (s : Ideal P) : s.carrier = s := rfl @[simp] theorem coe_toLowerSet (s : Ideal P) : (s.toLowerSet : Set P) = s := rfl protected theorem lower (s : Ideal P) : IsLowerSet (s : Set P) := s.lower' protected theorem nonempty (s : Ideal P) : (s : Set P).Nonempty := s.nonempty' protected theorem directed (s : Ideal P) : DirectedOn (· ≤ ·) (s : Set P) := s.directed' protected theorem isIdeal (s : Ideal P) : IsIdeal (s : Set P) := ⟨s.lower, s.nonempty, s.directed⟩ theorem mem_compl_of_ge {x y : P} : x ≤ y → x ∈ (I : Set P)ᶜ → y ∈ (I : Set P)ᶜ := fun h ↦ mt <\| I.lower h /-- The partial ordering by subset inclusion, inherited from `Set P`. -/ instance instPartialOrderIdeal : PartialOrder (Ideal P) := PartialOrder.lift SetLike.coe SetLike.coe_injective theorem coe_subset_coe : (s : Set P) ⊆ t ↔ s ≤ t := Iff.rfl theorem coe_ssubset_coe : (s : Set P) ⊂ t ↔ s < t := Iff.rfl @[trans] theorem mem_of_mem_of_le {x : P} {I J : Ideal P} : x ∈ I → I ≤ J → x ∈ J := @Set.mem_of_mem_of_subset P x I J /-- A proper ideal is one that is not the whole set. Note that the whole set might not be an ideal. -/ @[mk_iff] class IsProper (I : Ideal P) : Prop where /-- This ideal is not the whole set. -/ ne_univ : (I : Set P) ≠ univ theorem isProper_of_not_mem {I : Ideal P} {p : P} (nmem : p ∉ I) : IsProper I := ⟨fun hp ↦ by have := mem_univ p rw [← hp] at this exact nmem this⟩ /-- An ideal is maximal if it is maximal in the collection of proper ideals. Note that `IsCoatom` is less general because ideals only have a top element when `P` is directed and nonempty. -/ @[mk_iff] class IsMaximal (I : Ideal P) : Prop extends IsProper I where /-- This ideal is maximal in the collection of proper ideals. -/ maximal_proper : ∀ ⦃J : Ideal P⦄, I < J → (J : Set P) = univ theorem inter_nonempty [IsDirected P (· ≥ ·)] (I J : Ideal P) : (I ∩ J : Set P).Nonempty := by obtain ⟨a, ha⟩ := I.nonempty obtain ⟨b, hb⟩ := J.nonempty obtain ⟨c, hac, hbc⟩ := exists_le_le a b exact ⟨c, I.lower hac ha, J.lower hbc hb⟩	end section Directed	Mathlib/Order/Ideal.lean	174	178
/- 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)	Mathlib/Topology/Constructions.lean	647	650
/- 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 $e (nat_lit 0))) /-- The expression `e` (the sum of monomials) is equal to another monomial (with nonzero leading coefficient). -/ \| nonzero (_ : Result (ExProd sα) e) variable {a a' a₁ a₂ a₃ b b' b₁ b₂ b₃ c c₁ c₂ : R} theorem add_overlap_pf (x : R) (e) (pq_pf : a + b = c) : x ^ e * a + x ^ e * b = x ^ e * c := by subst_vars; simp [mul_add] theorem add_overlap_pf_zero (x : R) (e) : IsNat (a + b) (nat_lit 0) → IsNat (x ^ e * a + x ^ e * b) (nat_lit 0) \| ⟨h⟩ => ⟨by simp [h, ← mul_add]⟩ -- TODO: decide if this is a good idea globally in -- https://leanprover.zulipchat.com/#narrow/stream/270676-lean4/topic/.60MonadLift.20Option.20.28OptionT.20m.29.60/near/469097834 private local instance {m} [Pure m] : MonadLift Option (OptionT m) where monadLift f := .mk <\| pure f /-- Given monomials `va, vb`, attempts to add them together to get another monomial. If the monomials are not compatible, returns `none`. For example, `xy + 2xy = 3xy` is a `.nonzero` overlap, while `xy + xz` returns `none` and `xy + -xy = 0` is a `.zero` overlap. -/ def evalAddOverlap {a b : Q($α)} (va : ExProd sα a) (vb : ExProd sα b) : OptionT Lean.Core.CoreM (Overlap sα q($a + $b)) := do Lean.Core.checkSystem decl_name%.toString match va, vb with \| .const za ha, .const zb hb => do let ra := Result.ofRawRat za a ha; let rb := Result.ofRawRat zb b hb let res ← NormNum.evalAdd.core q($a + $b) q(HAdd.hAdd) a b ra rb match res with \| .isNat _ (.lit (.natVal 0)) p => pure <\| .zero p \| rc => let ⟨zc, hc⟩ ← rc.toRatNZ let ⟨c, pc⟩ := rc.toRawEq pure <\| .nonzero ⟨c, .const zc hc, pc⟩ \| .mul (x := a₁) (e := a₂) va₁ va₂ va₃, .mul vb₁ vb₂ vb₃ => do guard (va₁.eq vb₁ && va₂.eq vb₂) match ← evalAddOverlap va₃ vb₃ with \| .zero p => pure <\| .zero (q(add_overlap_pf_zero $a₁ $a₂ $p) : Expr) \| .nonzero ⟨_, vc, p⟩ => pure <\| .nonzero ⟨_, .mul va₁ va₂ vc, (q(add_overlap_pf $a₁ $a₂ $p) : Expr)⟩ \| _, _ => OptionT.fail theorem add_pf_zero_add (b : R) : 0 + b = b := by simp theorem add_pf_add_zero (a : R) : a + 0 = a := by simp theorem add_pf_add_overlap (_ : a₁ + b₁ = c₁) (_ : a₂ + b₂ = c₂) : (a₁ + a₂ : R) + (b₁ + b₂) = c₁ + c₂ := by subst_vars; simp [add_assoc, add_left_comm] theorem add_pf_add_overlap_zero (h : IsNat (a₁ + b₁) (nat_lit 0)) (h₄ : a₂ + b₂ = c) : (a₁ + a₂ : R) + (b₁ + b₂) = c := by subst_vars; rw [add_add_add_comm, h.1, Nat.cast_zero, add_pf_zero_add] theorem add_pf_add_lt (a₁ : R) (_ : a₂ + b = c) : (a₁ + a₂) + b = a₁ + c := by simp [, add_assoc] theorem add_pf_add_gt (b₁ : R) (_ : a + b₂ = c) : a + (b₁ + b₂) = b₁ + c := by subst_vars; simp [add_left_comm] /-- Adds two polynomials `va, vb` together to get a normalized result polynomial. `0 + b = b` * `a + 0 = a` * `a * x + a * y = a * (x + y)` (for `x`, `y` coefficients; uses `evalAddOverlap`) * `(a₁ + a₂) + (b₁ + b₂) = a₁ + (a₂ + (b₁ + b₂))` (if `a₁.lt b₁`) * `(a₁ + a₂) + (b₁ + b₂) = b₁ + ((a₁ + a₂) + b₂)` (if not `a₁.lt b₁`) -/ partial def evalAdd {a b : Q($α)} (va : ExSum sα a) (vb : ExSum sα b) : Lean.Core.CoreM <\| Result (ExSum sα) q($a + $b) := do Lean.Core.checkSystem decl_name%.toString match va, vb with \| .zero, vb => return ⟨b, vb, q(add_pf_zero_add $b)⟩ \| va, .zero => return ⟨a, va, q(add_pf_add_zero $a)⟩ \| .add (a := a₁) (b := _a₂) va₁ va₂, .add (a := b₁) (b := _b₂) vb₁ vb₂ => match ← (evalAddOverlap sα va₁ vb₁).run with \| some (.nonzero ⟨_, vc₁, pc₁⟩) => let ⟨_, vc₂, pc₂⟩ ← evalAdd va₂ vb₂ return ⟨_, .add vc₁ vc₂, q(add_pf_add_overlap $pc₁ $pc₂)⟩ \| some (.zero pc₁) => let ⟨c₂, vc₂, pc₂⟩ ← evalAdd va₂ vb₂ return ⟨c₂, vc₂, q(add_pf_add_overlap_zero $pc₁ $pc₂)⟩ \| none => if let .lt := va₁.cmp vb₁ then let ⟨_c, vc, (pc : Q($_a₂ + ($b₁ + $_b₂) = $_c))⟩ ← evalAdd va₂ vb return ⟨_, .add va₁ vc, q(add_pf_add_lt $a₁ $pc)⟩ else let ⟨_c, vc, (pc : Q($a₁ + $_a₂ + $_b₂ = $_c))⟩ ← evalAdd va vb₂ return ⟨_, .add vb₁ vc, q(add_pf_add_gt $b₁ $pc)⟩ theorem one_mul (a : R) : (nat_lit 1).rawCast * a = a := by simp [Nat.rawCast] theorem mul_one (a : R) : a * (nat_lit 1).rawCast = a := by simp [Nat.rawCast] theorem mul_pf_left (a₁ : R) (a₂) (_ : a₃ * b = c) : (a₁ ^ a₂ * a₃ : R) * b = a₁ ^ a₂ * c := by subst_vars; rw [mul_assoc] theorem mul_pf_right (b₁ : R) (b₂) (_ : a * b₃ = c) : a * (b₁ ^ b₂ * b₃) = b₁ ^ b₂ * c := by subst_vars; rw [mul_left_comm] theorem mul_pp_pf_overlap {ea eb e : ℕ} (x : R) (_ : ea + eb = e) (_ : a₂ * b₂ = c) : (x ^ ea * a₂ : R) * (x ^ eb * b₂) = x ^ e * c := by subst_vars; simp [pow_add, mul_mul_mul_comm] /-- Multiplies two monomials `va, vb` together to get a normalized result monomial. * `x * y = (x * y)` (for `x`, `y` coefficients) * `x * (b₁ * b₂) = b₁ * (b₂ * x)` (for `x` coefficient) * `(a₁ * a₂) * y = a₁ * (a₂ * y)` (for `y` coefficient) * `(x ^ ea * a₂) * (x ^ eb * b₂) = x ^ (ea + eb) * (a₂ * b₂)` (if `ea` and `eb` are identical except coefficient) * `(a₁ * a₂) * (b₁ * b₂) = a₁ * (a₂ * (b₁ * b₂))` (if `a₁.lt b₁`) * `(a₁ * a₂) * (b₁ * b₂) = b₁ * ((a₁ * a₂) * b₂)` (if not `a₁.lt b₁`) -/ partial def evalMulProd {a b : Q($α)} (va : ExProd sα a) (vb : ExProd sα b) : Lean.Core.CoreM <\| Result (ExProd sα) q($a * $b) := do Lean.Core.checkSystem decl_name%.toString match va, vb with \| .const za ha, .const zb hb => if za = 1 then return ⟨b, .const zb hb, (q(one_mul $b) : Expr)⟩ else if zb = 1 then return ⟨a, .const za ha, (q(mul_one $a) : Expr)⟩ else let ra := Result.ofRawRat za a ha; let rb := Result.ofRawRat zb b hb let rc := (NormNum.evalMul.core q($a * $b) q(HMul.hMul) _ _ q(CommSemiring.toSemiring) ra rb).get! let ⟨zc, hc⟩ := rc.toRatNZ.get! let ⟨c, pc⟩ := rc.toRawEq return ⟨c, .const zc hc, pc⟩ \| .mul (x := a₁) (e := a₂) va₁ va₂ va₃, .const _ _ => let ⟨_, vc, pc⟩ ← evalMulProd va₃ vb return ⟨_, .mul va₁ va₂ vc, (q(mul_pf_left $a₁ $a₂ $pc) : Expr)⟩ \| .const _ _, .mul (x := b₁) (e := b₂) vb₁ vb₂ vb₃ => let ⟨_, vc, pc⟩ ← evalMulProd va vb₃ return ⟨_, .mul vb₁ vb₂ vc, (q(mul_pf_right $b₁ $b₂ $pc) : Expr)⟩ \| .mul (x := xa) (e := ea) vxa vea va₂, .mul (x := xb) (e := eb) vxb veb vb₂ => do if vxa.eq vxb then if let some (.nonzero ⟨_, ve, pe⟩) ← (evalAddOverlap sℕ vea veb).run then let ⟨_, vc, pc⟩ ← evalMulProd va₂ vb₂ return ⟨_, .mul vxa ve vc, (q(mul_pp_pf_overlap $xa $pe $pc) : Expr)⟩ if let .lt := (vxa.cmp vxb).then (vea.cmp veb) then let ⟨_, vc, pc⟩ ← evalMulProd va₂ vb return ⟨_, .mul vxa vea vc, (q(mul_pf_left $xa $ea $pc) : Expr)⟩ else let ⟨_, vc, pc⟩ ← evalMulProd va vb₂ return ⟨_, .mul vxb veb vc, (q(mul_pf_right $xb $eb $pc) : Expr)⟩ theorem mul_zero (a : R) : a * 0 = 0 := by simp theorem mul_add {d : R} (_ : (a : R) * b₁ = c₁) (_ : a * b₂ = c₂) (_ : c₁ + 0 + c₂ = d) : a * (b₁ + b₂) = d := by subst_vars; simp [_root_.mul_add] /-- Multiplies a monomial `va` to a polynomial `vb` to get a normalized result polynomial. * `a * 0 = 0` * `a * (b₁ + b₂) = (a * b₁) + (a * b₂)` -/ def evalMul₁ {a b : Q($α)} (va : ExProd sα a) (vb : ExSum sα b) : Lean.Core.CoreM <\| Result (ExSum sα) q($a * $b) := do match vb with \| .zero => return ⟨_, .zero, q(mul_zero $a)⟩ \| .add vb₁ vb₂ => let ⟨_, vc₁, pc₁⟩ ← evalMulProd sα va vb₁ let ⟨_, vc₂, pc₂⟩ ← evalMul₁ va vb₂ let ⟨_, vd, pd⟩ ← evalAdd sα vc₁.toSum vc₂ return ⟨_, vd, q(mul_add $pc₁ $pc₂ $pd)⟩ theorem zero_mul (b : R) : 0 * b = 0 := by simp theorem add_mul {d : R} (_ : (a₁ : R) * b = c₁) (_ : a₂ * b = c₂) (_ : c₁ + c₂ = d) : (a₁ + a₂) * b = d := by subst_vars; simp [_root_.add_mul] /-- Multiplies two polynomials `va, vb` together to get a normalized result polynomial. * `0 * b = 0` * `(a₁ + a₂) * b = (a₁ * b) + (a₂ * b)` -/ def evalMul {a b : Q($α)} (va : ExSum sα a) (vb : ExSum sα b) : Lean.Core.CoreM <\| Result (ExSum sα) q($a * $b) := do match va with \| .zero => return ⟨_, .zero, q(zero_mul $b)⟩ \| .add va₁ va₂ => let ⟨_, vc₁, pc₁⟩ ← evalMul₁ sα va₁ vb let ⟨_, vc₂, pc₂⟩ ← evalMul va₂ vb let ⟨_, vd, pd⟩ ← evalAdd sα vc₁ vc₂ return ⟨_, vd, q(add_mul $pc₁ $pc₂ $pd)⟩ theorem natCast_nat (n) : ((Nat.rawCast n : ℕ) : R) = Nat.rawCast n := by simp theorem natCast_mul {a₁ a₃ : ℕ} (a₂) (_ : ((a₁ : ℕ) : R) = b₁) (_ : ((a₃ : ℕ) : R) = b₃) : ((a₁ ^ a₂ * a₃ : ℕ) : R) = b₁ ^ a₂ * b₃ := by subst_vars; simp theorem natCast_zero : ((0 : ℕ) : R) = 0 := Nat.cast_zero theorem natCast_add {a₁ a₂ : ℕ} (_ : ((a₁ : ℕ) : R) = b₁) (_ : ((a₂ : ℕ) : R) = b₂) : ((a₁ + a₂ : ℕ) : R) = b₁ + b₂ := by subst_vars; simp mutual /-- Applies `Nat.cast` to a nat polynomial to produce a polynomial in `α`. * An atom `e` causes `↑e` to be allocated as a new atom. * A sum delegates to `ExSum.evalNatCast`. -/ partial def ExBase.evalNatCast {a : Q(ℕ)} (va : ExBase sℕ a) : AtomM (Result (ExBase sα) q($a)) := match va with \| .atom _ => do let (i, ⟨b', _⟩) ← addAtomQ q($a) pure ⟨b', ExBase.atom i, q(Eq.refl $b')⟩ \| .sum va => do let ⟨_, vc, p⟩ ← va.evalNatCast pure ⟨_, .sum vc, p⟩ /-- Applies `Nat.cast` to a nat monomial to produce a monomial in `α`. * `↑c = c` if `c` is a numeric literal * `↑(a ^ n * b) = ↑a ^ n * ↑b` -/ partial def ExProd.evalNatCast {a : Q(ℕ)} (va : ExProd sℕ a) : AtomM (Result (ExProd sα) q($a)) := match va with \| .const c hc => have n : Q(ℕ) := a.appArg! pure ⟨q(Nat.rawCast $n), .const c hc, (q(natCast_nat (R := $α) $n) : Expr)⟩ \| .mul (e := a₂) va₁ va₂ va₃ => do let ⟨_, vb₁, pb₁⟩ ← va₁.evalNatCast let ⟨_, vb₃, pb₃⟩ ← va₃.evalNatCast pure ⟨_, .mul vb₁ va₂ vb₃, q(natCast_mul $a₂ $pb₁ $pb₃)⟩ /-- Applies `Nat.cast` to a nat polynomial to produce a polynomial in `α`. * `↑0 = 0` * `↑(a + b) = ↑a + ↑b` -/ partial def ExSum.evalNatCast {a : Q(ℕ)} (va : ExSum sℕ a) : AtomM (Result (ExSum sα) q($a)) := match va with \| .zero => pure ⟨_, .zero, q(natCast_zero (R := $α))⟩ \| .add va₁ va₂ => do let ⟨_, vb₁, pb₁⟩ ← va₁.evalNatCast let ⟨_, vb₂, pb₂⟩ ← va₂.evalNatCast pure ⟨_, .add vb₁ vb₂, q(natCast_add $pb₁ $pb₂)⟩ end theorem smul_nat {a b c : ℕ} (_ : (a * b : ℕ) = c) : a • b = c := by subst_vars; simp theorem smul_eq_cast {a : ℕ} (_ : ((a : ℕ) : R) = a') (_ : a' * b = c) : a • b = c := by subst_vars; simp /-- Constructs the scalar multiplication `n • a`, where both `n : ℕ` and `a : α` are normalized polynomial expressions. * `a • b = a * b` if `α = ℕ` * `a • b = ↑a * b` otherwise -/ def evalNSMul {a : Q(ℕ)} {b : Q($α)} (va : ExSum sℕ a) (vb : ExSum sα b) : AtomM (Result (ExSum sα) q($a • $b)) := do if ← isDefEq sα sℕ then let ⟨_, va'⟩ := va.cast have _b : Q(ℕ) := b let ⟨(_c : Q(ℕ)), vc, (pc : Q($a * $_b = $_c))⟩ ← evalMul sα va' vb pure ⟨_, vc, (q(smul_nat $pc) : Expr)⟩ else let ⟨_, va', pa'⟩ ← va.evalNatCast sα let ⟨_, vc, pc⟩ ← evalMul sα va' vb pure ⟨_, vc, (q(smul_eq_cast $pa' $pc) : Expr)⟩ theorem neg_one_mul {R} [Ring R] {a b : R} (_ : (Int.negOfNat (nat_lit 1)).rawCast * a = b) : -a = b := by subst_vars; simp [Int.negOfNat] theorem neg_mul {R} [Ring R] (a₁ : R) (a₂) {a₃ b : R} (_ : -a₃ = b) : -(a₁ ^ a₂ * a₃) = a₁ ^ a₂ * b := by subst_vars; simp /-- Negates a monomial `va` to get another monomial. * `-c = (-c)` (for `c` coefficient) * `-(a₁ * a₂) = a₁ * -a₂` -/ def evalNegProd {a : Q($α)} (rα : Q(Ring $α)) (va : ExProd sα a) : Lean.Core.CoreM <\| Result (ExProd sα) q(-$a) := do Lean.Core.checkSystem decl_name%.toString match va with \| .const za ha => let lit : Q(ℕ) := mkRawNatLit 1 let ⟨m1, _⟩ := ExProd.mkNegNat sα rα 1 let rm := Result.isNegNat rα lit (q(IsInt.of_raw $α (.negOfNat $lit)) : Expr) let ra := Result.ofRawRat za a ha let rb := (NormNum.evalMul.core q($m1 * $a) q(HMul.hMul) _ _ q(CommSemiring.toSemiring) rm ra).get! let ⟨zb, hb⟩ := rb.toRatNZ.get! let ⟨b, (pb : Q((Int.negOfNat (nat_lit 1)).rawCast * $a = $b))⟩ := rb.toRawEq return ⟨b, .const zb hb, (q(neg_one_mul (R := $α) $pb) : Expr)⟩ \| .mul (x := a₁) (e := a₂) va₁ va₂ va₃ => let ⟨_, vb, pb⟩ ← evalNegProd rα va₃ return ⟨_, .mul va₁ va₂ vb, (q(neg_mul $a₁ $a₂ $pb) : Expr)⟩ theorem neg_zero {R} [Ring R] : -(0 : R) = 0 := by simp theorem neg_add {R} [Ring R] {a₁ a₂ b₁ b₂ : R} (_ : -a₁ = b₁) (_ : -a₂ = b₂) : -(a₁ + a₂) = b₁ + b₂ := by subst_vars; simp [add_comm] /-- Negates a polynomial `va` to get another polynomial. * `-0 = 0` (for `c` coefficient) * `-(a₁ + a₂) = -a₁ + -a₂` -/ def evalNeg {a : Q($α)} (rα : Q(Ring $α)) (va : ExSum sα a) : Lean.Core.CoreM <\| Result (ExSum sα) q(-$a) := do match va with \| .zero => return ⟨_, .zero, (q(neg_zero (R := $α)) : Expr)⟩ \| .add va₁ va₂ => let ⟨_, vb₁, pb₁⟩ ← evalNegProd sα rα va₁ let ⟨_, vb₂, pb₂⟩ ← evalNeg rα va₂ return ⟨_, .add vb₁ vb₂, (q(neg_add $pb₁ $pb₂) : Expr)⟩ theorem sub_pf {R} [Ring R] {a b c d : R} (_ : -b = c) (_ : a + c = d) : a - b = d := by subst_vars; simp [sub_eq_add_neg] /-- Subtracts two polynomials `va, vb` to get a normalized result polynomial. * `a - b = a + -b` -/ def evalSub {α : Q(Type u)} (sα : Q(CommSemiring $α)) {a b : Q($α)} (rα : Q(Ring $α)) (va : ExSum sα a) (vb : ExSum sα b) : Lean.Core.CoreM <\| Result (ExSum sα) q($a - $b) := do let ⟨_c, vc, pc⟩ ← evalNeg sα rα vb let ⟨d, vd, (pd : Q($a + $_c = $d))⟩ ← evalAdd sα va vc return ⟨d, vd, (q(sub_pf $pc $pd) : Expr)⟩ theorem pow_prod_atom (a : R) (b) : a ^ b = (a + 0) ^ b * (nat_lit 1).rawCast := by simp /-- The fallback case for exponentiating polynomials is to use `ExBase.toProd` to just build an exponent expression. (This has a slightly different normalization than `evalPowAtom` because the input types are different.) * `x ^ e = (x + 0) ^ e * 1` -/ def evalPowProdAtom {a : Q($α)} {b : Q(ℕ)} (va : ExProd sα a) (vb : ExProd sℕ b) : Result (ExProd sα) q($a ^ $b) := ⟨_, (ExBase.sum va.toSum).toProd vb, q(pow_prod_atom $a $b)⟩ theorem pow_atom (a : R) (b) : a ^ b = a ^ b * (nat_lit 1).rawCast + 0 := by simp /-- The fallback case for exponentiating polynomials is to use `ExBase.toProd` to just build an exponent expression. * `x ^ e = x ^ e * 1 + 0` -/ def evalPowAtom {a : Q($α)} {b : Q(ℕ)} (va : ExBase sα a) (vb : ExProd sℕ b) : Result (ExSum sα) q($a ^ $b) := ⟨_, (va.toProd vb).toSum, q(pow_atom $a $b)⟩ theorem const_pos (n : ℕ) (h : Nat.ble 1 n = true) : 0 < (n.rawCast : ℕ) := Nat.le_of_ble_eq_true h theorem mul_exp_pos {a₁ a₂ : ℕ} (n) (h₁ : 0 < a₁) (h₂ : 0 < a₂) : 0 < a₁ ^ n * a₂ := Nat.mul_pos (Nat.pow_pos h₁) h₂ theorem add_pos_left {a₁ : ℕ} (a₂) (h : 0 < a₁) : 0 < a₁ + a₂ := Nat.lt_of_lt_of_le h (Nat.le_add_right ..) theorem add_pos_right {a₂ : ℕ} (a₁) (h : 0 < a₂) : 0 < a₁ + a₂ := Nat.lt_of_lt_of_le h (Nat.le_add_left ..) mutual /-- Attempts to prove that a polynomial expression in `ℕ` is positive. * Atoms are not (necessarily) positive * Sums defer to `ExSum.evalPos` -/ partial def ExBase.evalPos {a : Q(ℕ)} (va : ExBase sℕ a) : Option Q(0 < $a) := match va with \| .atom _ => none \| .sum va => va.evalPos /-- Attempts to prove that a monomial expression in `ℕ` is positive. * `0 < c` (where `c` is a numeral) is true by the normalization invariant (`c` is not zero) * `0 < x ^ e * b` if `0 < x` and `0 < b` -/ partial def ExProd.evalPos {a : Q(ℕ)} (va : ExProd sℕ a) : Option Q(0 < $a) := match va with \| .const _ _ => -- it must be positive because it is a nonzero nat literal have lit : Q(ℕ) := a.appArg! haveI : $a =Q Nat.rawCast $lit := ⟨⟩ haveI p : Nat.ble 1 $lit =Q true := ⟨⟩ some q(const_pos $lit $p) \| .mul (e := ea₁) vxa₁ _ va₂ => do let pa₁ ← vxa₁.evalPos let pa₂ ← va₂.evalPos some q(mul_exp_pos $ea₁ $pa₁ $pa₂) /-- Attempts to prove that a polynomial expression in `ℕ` is positive. * `0 < 0` fails * `0 < a + b` if `0 < a` or `0 < b` -/ partial def ExSum.evalPos {a : Q(ℕ)} (va : ExSum sℕ a) : Option Q(0 < $a) := match va with \| .zero => none \| .add (a := a₁) (b := a₂) va₁ va₂ => do match va₁.evalPos with \| some p => some q(add_pos_left $a₂ $p) \| none => let p ← va₂.evalPos; some q(add_pos_right $a₁ $p) end theorem pow_one (a : R) : a ^ nat_lit 1 = a := by simp theorem pow_bit0 {k : ℕ} (_ : (a : R) ^ k = b) (_ : b * b = c) : a ^ (Nat.mul (nat_lit 2) k) = c := by subst_vars; simp [Nat.succ_mul, pow_add] theorem pow_bit1 {k : ℕ} {d : R} (_ : (a : R) ^ k = b) (_ : b * b = c) (_ : c * a = d) : a ^ (Nat.add (Nat.mul (nat_lit 2) k) (nat_lit 1)) = d := by subst_vars; simp [Nat.succ_mul, pow_add] /-- The main case of exponentiation of ring expressions is when `va` is a polynomial and `n` is a nonzero literal expression, like `(x + y)^5`. In this case we work out the polynomial completely into a sum of monomials. * `x ^ 1 = x` * `x ^ (2n) = x ^ n x ^ n` * `x ^ (2n+1) = x ^ n x ^ n * x` -/ partial def evalPowNat {a : Q($α)} (va : ExSum sα a) (n : Q(ℕ)) : Lean.Core.CoreM <\| Result (ExSum sα) q($a ^ $n) := do let nn := n.natLit! if nn = 1 then return ⟨_, va, (q(pow_one $a) : Expr)⟩ else let nm := nn >>> 1 have m : Q(ℕ) := mkRawNatLit nm if nn &&& 1 = 0 then let ⟨_, vb, pb⟩ ← evalPowNat va m let ⟨_, vc, pc⟩ ← evalMul sα vb vb return ⟨_, vc, (q(pow_bit0 $pb $pc) : Expr)⟩ else let ⟨_, vb, pb⟩ ← evalPowNat va m let ⟨_, vc, pc⟩ ← evalMul sα vb vb let ⟨_, vd, pd⟩ ← evalMul sα vc va return ⟨_, vd, (q(pow_bit1 $pb $pc $pd) : Expr)⟩ theorem one_pow (b : ℕ) : ((nat_lit 1).rawCast : R) ^ b = (nat_lit 1).rawCast := by simp theorem mul_pow {ea₁ b c₁ : ℕ} {xa₁ : R} (_ : ea₁ * b = c₁) (_ : a₂ ^ b = c₂) : (xa₁ ^ ea₁ * a₂ : R) ^ b = xa₁ ^ c₁ * c₂ := by subst_vars; simp [_root_.mul_pow, pow_mul] /-- There are several special cases when exponentiating monomials: * `1 ^ n = 1` * `x ^ y = (x ^ y)` when `x` and `y` are constants * `(a * b) ^ e = a ^ e * b ^ e` In all other cases we use `evalPowProdAtom`. -/ def evalPowProd {a : Q($α)} {b : Q(ℕ)} (va : ExProd sα a) (vb : ExProd sℕ b) : Lean.Core.CoreM <\| Result (ExProd sα) q($a ^ $b) := do Lean.Core.checkSystem decl_name%.toString let res : OptionT Lean.Core.CoreM (Result (ExProd sα) q($a ^ $b)) := do match va, vb with \| .const 1, _ => return ⟨_, va, (q(one_pow (R := $α) $b) : Expr)⟩ \| .const za ha, .const zb hb => assert! 0 ≤ zb let ra := Result.ofRawRat za a ha have lit : Q(ℕ) := b.appArg! let rb := (q(IsNat.of_raw ℕ $lit) : Expr) let rc ← NormNum.evalPow.core q($a ^ $b) q(HPow.hPow) q($a) q($b) lit rb q(CommSemiring.toSemiring) ra let ⟨zc, hc⟩ ← rc.toRatNZ let ⟨c, pc⟩ := rc.toRawEq return ⟨c, .const zc hc, pc⟩ \| .mul vxa₁ vea₁ va₂, vb => let ⟨_, vc₁, pc₁⟩ ← evalMulProd sℕ vea₁ vb let ⟨_, vc₂, pc₂⟩ ← evalPowProd va₂ vb return ⟨_, .mul vxa₁ vc₁ vc₂, q(mul_pow $pc₁ $pc₂)⟩ \| _, _ => OptionT.fail return (← res.run).getD (evalPowProdAtom sα va vb) /-- The result of `extractCoeff` is a numeral and a proof that the original expression factors by this numeral. -/ structure ExtractCoeff (e : Q(ℕ)) where /-- A raw natural number literal. -/ k : Q(ℕ) /-- The result of extracting the coefficient is a monic monomial. -/ e' : Q(ℕ) /-- `e'` is a monomial. -/ ve' : ExProd sℕ e' /-- The proof that `e` splits into the coefficient `k` and the monic monomial `e'`. -/ p : Q($e = $e' * $k) theorem coeff_one (k : ℕ) : k.rawCast = (nat_lit 1).rawCast * k := by simp theorem coeff_mul {a₃ c₂ k : ℕ} (a₁ a₂ : ℕ) (_ : a₃ = c₂ * k) : a₁ ^ a₂ * a₃ = (a₁ ^ a₂ * c₂) * k := by subst_vars; rw [mul_assoc] /-- Given a monomial expression `va`, splits off the leading coefficient `k` and the remainder `e'`, stored in the `ExtractCoeff` structure. * `c = 1 * c` (if `c` is a constant) * `a * b = (a * b') * k` if `b = b' * k` -/ def extractCoeff {a : Q(ℕ)} (va : ExProd sℕ a) : ExtractCoeff a := match va with \| .const _ _ => have k : Q(ℕ) := a.appArg! ⟨k, q((nat_lit 1).rawCast), .const 1, (q(coeff_one $k) : Expr)⟩ \| .mul (x := a₁) (e := a₂) va₁ va₂ va₃ => let ⟨k, _, vc, pc⟩ := extractCoeff va₃ ⟨k, _, .mul va₁ va₂ vc, q(coeff_mul $a₁ $a₂ $pc)⟩ theorem pow_one_cast (a : R) : a ^ (nat_lit 1).rawCast = a := by simp theorem zero_pow {b : ℕ} (_ : 0 < b) : (0 : R) ^ b = 0 := match b with \| b+1 => by simp [pow_succ] theorem single_pow {b : ℕ} (_ : (a : R) ^ b = c) : (a + 0) ^ b = c + 0 := by simp [] theorem pow_nat {b c k : ℕ} {d e : R} (_ : b = c k) (_ : a ^ c = d) (_ : d ^ k = e) : (a : R) ^ b = e := by subst_vars; simp [pow_mul] /-- Exponentiates a polynomial `va` by a monomial `vb`, including several special cases.	* `a ^ 1 = a` * `0 ^ e = 0` if `0 < e`	Mathlib/Tactic/Ring/Basic.lean	841	842
/- Copyright (c) 2018 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.Limits.HasLimits import Mathlib.CategoryTheory.Discrete.Basic /-! # Categorical (co)products This file defines (co)products as special cases of (co)limits. A product is the categorical generalization of the object `Π i, f i` where `f : ι → C`. It is a limit cone over the diagram formed by `f`, implemented by converting `f` into a functor `Discrete ι ⥤ C`. A coproduct is the dual concept. ## Main definitions * a `Fan` is a cone over a discrete category * `Fan.mk` constructs a fan from an indexed collection of maps * a `Pi` is a `limit (Discrete.functor f)` Each of these has a dual. ## Implementation notes As with the other special shapes in the limits library, all the definitions here are given as `abbreviation`s of the general statements for limits, so all the `simp` lemmas and theorems about general limits can be used. -/ noncomputable section universe w w' w₂ w₃ v v₂ u u₂ open CategoryTheory namespace CategoryTheory.Limits variable {β : Type w} {α : Type w₂} {γ : Type w₃} variable {C : Type u} [Category.{v} C] -- We don't need an analogue of `Pair` (for binary products), `ParallelPair` (for equalizers), -- or `(Co)span`, since we already have `Discrete.functor`. /-- A fan over `f : β → C` consists of a collection of maps from an object `P` to every `f b`. -/ abbrev Fan (f : β → C) := Cone (Discrete.functor f) /-- A cofan over `f : β → C` consists of a collection of maps from every `f b` to an object `P`. -/ abbrev Cofan (f : β → C) := Cocone (Discrete.functor f) /-- A fan over `f : β → C` consists of a collection of maps from an object `P` to every `f b`. -/ @[simps! pt π_app] def Fan.mk {f : β → C} (P : C) (p : ∀ b, P ⟶ f b) : Fan f where pt := P π := Discrete.natTrans (fun X => p X.as) /-- A cofan over `f : β → C` consists of a collection of maps from every `f b` to an object `P`. -/ @[simps! pt ι_app] def Cofan.mk {f : β → C} (P : C) (p : ∀ b, f b ⟶ P) : Cofan f where pt := P ι := Discrete.natTrans (fun X => p X.as) /-- Get the `j`th "projection" in the fan. (Note that the initial letter of `proj` matches the greek letter in `Cone.π`.) -/ def Fan.proj {f : β → C} (p : Fan f) (j : β) : p.pt ⟶ f j := p.π.app (Discrete.mk j) /-- Get the `j`th "injection" in the cofan. (Note that the initial letter of `inj` matches the greek letter in `Cocone.ι`.) -/ def Cofan.inj {f : β → C} (p : Cofan f) (j : β) : f j ⟶ p.pt := p.ι.app (Discrete.mk j) @[simp] theorem fan_mk_proj {f : β → C} (P : C) (p : ∀ b, P ⟶ f b) : (Fan.mk P p).proj = p := rfl @[simp] theorem cofan_mk_inj {f : β → C} (P : C) (p : ∀ b, f b ⟶ P) : (Cofan.mk P p).inj = p := rfl /-- An abbreviation for `HasLimit (Discrete.functor f)`. -/ abbrev HasProduct (f : β → C) := HasLimit (Discrete.functor f) /-- An abbreviation for `HasColimit (Discrete.functor f)`. -/ abbrev HasCoproduct (f : β → C) := HasColimit (Discrete.functor f) lemma hasCoproduct_of_equiv_of_iso (f : α → C) (g : β → C) [HasCoproduct f] (e : β ≃ α) (iso : ∀ j, g j ≅ f (e j)) : HasCoproduct g := by have : HasColimit ((Discrete.equivalence e).functor ⋙ Discrete.functor f) := hasColimit_equivalence_comp _ have α : Discrete.functor g ≅ (Discrete.equivalence e).functor ⋙ Discrete.functor f := Discrete.natIso (fun ⟨j⟩ => iso j) exact hasColimit_of_iso α lemma hasProduct_of_equiv_of_iso (f : α → C) (g : β → C) [HasProduct f] (e : β ≃ α) (iso : ∀ j, g j ≅ f (e j)) : HasProduct g := by have : HasLimit ((Discrete.equivalence e).functor ⋙ Discrete.functor f) := hasLimitEquivalenceComp _ have α : Discrete.functor g ≅ (Discrete.equivalence e).functor ⋙ Discrete.functor f := Discrete.natIso (fun ⟨j⟩ => iso j) exact hasLimit_of_iso α.symm /-- Make a fan `f` into a limit fan by providing `lift`, `fac`, and `uniq` -- just a convenience lemma to avoid having to go through `Discrete` -/ @[simps] def mkFanLimit {f : β → C} (t : Fan f) (lift : ∀ s : Fan f, s.pt ⟶ t.pt) (fac : ∀ (s : Fan f) (j : β), lift s ≫ t.proj j = s.proj j := by aesop_cat) (uniq : ∀ (s : Fan f) (m : s.pt ⟶ t.pt) (_ : ∀ j : β, m ≫ t.proj j = s.proj j), m = lift s := by aesop_cat) : IsLimit t := { lift } /-- Constructor for morphisms to the point of a limit fan. -/ def Fan.IsLimit.desc {F : β → C} {c : Fan F} (hc : IsLimit c) {A : C} (f : ∀ i, A ⟶ F i) : A ⟶ c.pt := hc.lift (Fan.mk A f) @[reassoc (attr := simp)] lemma Fan.IsLimit.fac {F : β → C} {c : Fan F} (hc : IsLimit c) {A : C} (f : ∀ i, A ⟶ F i) (i : β) : Fan.IsLimit.desc hc f ≫ c.proj i = f i := hc.fac (Fan.mk A f) ⟨i⟩ lemma Fan.IsLimit.hom_ext {I : Type} {F : I → C} {c : Fan F} (hc : IsLimit c) {A : C} (f g : A ⟶ c.pt) (h : ∀ i, f ≫ c.proj i = g ≫ c.proj i) : f = g := hc.hom_ext (fun ⟨i⟩ => h i) /-- Make a cofan `f` into a colimit cofan by providing `desc`, `fac`, and `uniq` -- just a convenience lemma to avoid having to go through `Discrete` -/ @[simps] def mkCofanColimit {f : β → C} (s : Cofan f) (desc : ∀ t : Cofan f, s.pt ⟶ t.pt) (fac : ∀ (t : Cofan f) (j : β), s.inj j ≫ desc t = t.inj j := by aesop_cat) (uniq : ∀ (t : Cofan f) (m : s.pt ⟶ t.pt) (_ : ∀ j : β, s.inj j ≫ m = t.inj j), m = desc t := by aesop_cat) : IsColimit s := { desc } /-- Constructor for morphisms from the point of a colimit cofan. -/ def Cofan.IsColimit.desc {F : β → C} {c : Cofan F} (hc : IsColimit c) {A : C} (f : ∀ i, F i ⟶ A) : c.pt ⟶ A := hc.desc (Cofan.mk A f) @[reassoc (attr := simp)] lemma Cofan.IsColimit.fac {F : β → C} {c : Cofan F} (hc : IsColimit c) {A : C} (f : ∀ i, F i ⟶ A) (i : β) : c.inj i ≫ Cofan.IsColimit.desc hc f = f i := hc.fac (Cofan.mk A f) ⟨i⟩ lemma Cofan.IsColimit.hom_ext {I : Type} {F : I → C} {c : Cofan F} (hc : IsColimit c) {A : C} (f g : c.pt ⟶ A) (h : ∀ i, c.inj i ≫ f = c.inj i ≫ g) : f = g := hc.hom_ext (fun ⟨i⟩ => h i) section variable (C) /-- An abbreviation for `HasLimitsOfShape (Discrete f)`. -/ abbrev HasProductsOfShape (β : Type v) := HasLimitsOfShape.{v} (Discrete β) /-- An abbreviation for `HasColimitsOfShape (Discrete f)`. -/ abbrev HasCoproductsOfShape (β : Type v) := HasColimitsOfShape.{v} (Discrete β) end /-- `piObj f` computes the product of a family of elements `f`. (It is defined as an abbreviation for `limit (Discrete.functor f)`, so for most facts about `piObj f`, you will just use general facts about limits.) -/ abbrev piObj (f : β → C) [HasProduct f] := limit (Discrete.functor f) /-- `sigmaObj f` computes the coproduct of a family of elements `f`. (It is defined as an abbreviation for `colimit (Discrete.functor f)`, so for most facts about `sigmaObj f`, you will just use general facts about colimits.) -/ abbrev sigmaObj (f : β → C) [HasCoproduct f] := colimit (Discrete.functor f) /-- notation for categorical products. We need `ᶜ` to avoid conflict with `Finset.prod`. -/ notation "∏ᶜ " f:60 => piObj f /-- notation for categorical coproducts -/ notation "∐ " f:60 => sigmaObj f /-- The `b`-th projection from the pi object over `f` has the form `∏ᶜ f ⟶ f b`. -/ abbrev Pi.π (f : β → C) [HasProduct f] (b : β) : ∏ᶜ f ⟶ f b := limit.π (Discrete.functor f) (Discrete.mk b) /-- The `b`-th inclusion into the sigma object over `f` has the form `f b ⟶ ∐ f`. -/ abbrev Sigma.ι (f : β → C) [HasCoproduct f] (b : β) : f b ⟶ ∐ f := colimit.ι (Discrete.functor f) (Discrete.mk b) -- Porting note (https://github.com/leanprover-community/mathlib4/issues/10688): added the next two lemmas to ease automation; without these lemmas, -- `limit.hom_ext` would be applied, but the goal would involve terms -- in `Discrete β` rather than `β` itself @[ext 1050] lemma Pi.hom_ext {f : β → C} [HasProduct f] {X : C} (g₁ g₂ : X ⟶ ∏ᶜ f) (h : ∀ (b : β), g₁ ≫ Pi.π f b = g₂ ≫ Pi.π f b) : g₁ = g₂ := limit.hom_ext (fun ⟨j⟩ => h j) @[ext 1050] lemma Sigma.hom_ext {f : β → C} [HasCoproduct f] {X : C} (g₁ g₂ : ∐ f ⟶ X) (h : ∀ (b : β), Sigma.ι f b ≫ g₁ = Sigma.ι f b ≫ g₂) : g₁ = g₂ := colimit.hom_ext (fun ⟨j⟩ => h j) /-- The fan constructed of the projections from the product is limiting. -/ def productIsProduct (f : β → C) [HasProduct f] : IsLimit (Fan.mk _ (Pi.π f)) := IsLimit.ofIsoLimit (limit.isLimit (Discrete.functor f)) (Cones.ext (Iso.refl _)) /-- The cofan constructed of the inclusions from the coproduct is colimiting. -/ def coproductIsCoproduct (f : β → C) [HasCoproduct f] : IsColimit (Cofan.mk _ (Sigma.ι f)) := IsColimit.ofIsoColimit (colimit.isColimit (Discrete.functor f)) (Cocones.ext (Iso.refl _)) -- The `simpNF` linter incorrectly identifies these as simp lemmas that could never apply. -- It seems the side condition `w` is not applied by `simpNF`. -- https://github.com/leanprover-community/mathlib4/issues/5049 -- They are used by `simp` in `Pi.whiskerEquiv` below. @[reassoc (attr := simp, nolint simpNF)] theorem Pi.π_comp_eqToHom {J : Type} (f : J → C) [HasProduct f] {j j' : J} (w : j = j') : Pi.π f j ≫ eqToHom (by simp [w]) = Pi.π f j' := by cases w simp -- The `simpNF` linter incorrectly identifies these as simp lemmas that could never apply. -- It seems the side condition `w` is not applied by `simpNF`. -- https://github.com/leanprover-community/mathlib4/issues/5049 -- They are used by `simp` in `Sigma.whiskerEquiv` below. @[reassoc (attr := simp, nolint simpNF)] theorem Sigma.eqToHom_comp_ι {J : Type} (f : J → C) [HasCoproduct f] {j j' : J} (w : j = j') : eqToHom (by simp [w]) ≫ Sigma.ι f j' = Sigma.ι f j := by cases w simp /-- A collection of morphisms `P ⟶ f b` induces a morphism `P ⟶ ∏ᶜ f`. -/ abbrev Pi.lift {f : β → C} [HasProduct f] {P : C} (p : ∀ b, P ⟶ f b) : P ⟶ ∏ᶜ f := limit.lift _ (Fan.mk P p) theorem Pi.lift_π {β : Type w} {f : β → C} [HasProduct f] {P : C} (p : ∀ b, P ⟶ f b) (b : β) : Pi.lift p ≫ Pi.π f b = p b := by simp only [limit.lift_π, Fan.mk_pt, Fan.mk_π_app] /-- A version of `Cones.ext` for `Fan`s. -/ @[simps!] def Fan.ext {f : β → C} {c₁ c₂ : Fan f} (e : c₁.pt ≅ c₂.pt) (w : ∀ (b : β), c₁.proj b = e.hom ≫ c₂.proj b := by aesop_cat) : c₁ ≅ c₂ := Cones.ext e (fun ⟨j⟩ => w j) /-- A collection of morphisms `f b ⟶ P` induces a morphism `∐ f ⟶ P`. -/ abbrev Sigma.desc {f : β → C} [HasCoproduct f] {P : C} (p : ∀ b, f b ⟶ P) : ∐ f ⟶ P := colimit.desc _ (Cofan.mk P p) theorem Sigma.ι_desc {β : Type w} {f : β → C} [HasCoproduct f] {P : C} (p : ∀ b, f b ⟶ P) (b : β) : Sigma.ι f b ≫ Sigma.desc p = p b := by simp only [colimit.ι_desc, Cofan.mk_pt, Cofan.mk_ι_app] instance {f : β → C} [HasCoproduct f] : IsIso (Sigma.desc (fun a ↦ Sigma.ι f a)) := by convert IsIso.id _ ext simp /-- A version of `Cocones.ext` for `Cofan`s. -/ @[simps!] def Cofan.ext {f : β → C} {c₁ c₂ : Cofan f} (e : c₁.pt ≅ c₂.pt) (w : ∀ (b : β), c₁.inj b ≫ e.hom = c₂.inj b := by aesop_cat) : c₁ ≅ c₂ := Cocones.ext e (fun ⟨j⟩ => w j) /-- A cofan `c` on `f` such that the induced map `∐ f ⟶ c.pt` is an iso, is a coproduct. -/ def Cofan.isColimitOfIsIsoSigmaDesc {f : β → C} [HasCoproduct f] (c : Cofan f) [hc : IsIso (Sigma.desc c.inj)] : IsColimit c := IsColimit.ofIsoColimit (colimit.isColimit (Discrete.functor f)) (Cofan.ext (@asIso _ _ _ _ _ hc) (fun _ => colimit.ι_desc _ _)) lemma Cofan.isColimit_iff_isIso_sigmaDesc {f : β → C} [HasCoproduct f] (c : Cofan f) : IsIso (Sigma.desc c.inj) ↔ Nonempty (IsColimit c) := by refine ⟨fun h ↦ ⟨isColimitOfIsIsoSigmaDesc c⟩, fun ⟨hc⟩ ↦ ?_⟩ have : IsIso (((coproductIsCoproduct f).coconePointUniqueUpToIso hc).hom ≫ hc.desc c) := by simp; infer_instance convert this ext simp only [colimit.ι_desc, mk_pt, mk_ι_app, IsColimit.coconePointUniqueUpToIso, coproductIsCoproduct, colimit.cocone_x, Functor.mapIso_hom, IsColimit.uniqueUpToIso_hom, Cocones.forget_map, IsColimit.descCoconeMorphism_hom, IsColimit.ofIsoColimit_desc, Cocones.ext_inv_hom, Iso.refl_inv, colimit.isColimit_desc, Category.id_comp, IsColimit.desc_self, Category.comp_id] rfl /-- A coproduct of coproducts is a coproduct -/ def Cofan.isColimitTrans {X : α → C} (c : Cofan X) (hc : IsColimit c) {β : α → Type*} {Y : (a : α) → β a → C} (π : (a : α) → (b : β a) → Y a b ⟶ X a) (hs : ∀ a, IsColimit (Cofan.mk (X a) (π a))) : IsColimit (Cofan.mk (f := fun ⟨a,b⟩ => Y a b) c.pt (fun (⟨a, b⟩ : Σ a, _) ↦ π a b ≫ c.inj a)) := by refine mkCofanColimit _ ?_ ?_ ?_ · exact fun t ↦ hc.desc (Cofan.mk _ fun a ↦ (hs a).desc (Cofan.mk t.pt (fun b ↦ t.inj ⟨a, b⟩))) · intro t ⟨a, b⟩ simp only [mk_pt, cofan_mk_inj, Category.assoc] erw [hc.fac, (hs a).fac] rfl · intro t m h refine hc.hom_ext fun ⟨a⟩ ↦ (hs a).hom_ext fun ⟨b⟩ ↦ ?_ erw [hc.fac, (hs a).fac] simpa using h ⟨a, b⟩ /-- Construct a morphism between categorical products (indexed by the same type) from a family of morphisms between the factors. -/ abbrev Pi.map {f g : β → C} [HasProduct f] [HasProduct g] (p : ∀ b, f b ⟶ g b) : ∏ᶜ f ⟶ ∏ᶜ g := limMap (Discrete.natTrans fun X => p X.as) @[simp] lemma Pi.map_id {f : α → C} [HasProduct f] : Pi.map (fun a => 𝟙 (f a)) = 𝟙 (∏ᶜ f) := by ext; simp lemma Pi.map_comp_map {f g h : α → C} [HasProduct f] [HasProduct g] [HasProduct h] (q : ∀ (a : α), f a ⟶ g a) (q' : ∀ (a : α), g a ⟶ h a) : Pi.map q ≫ Pi.map q' = Pi.map (fun a => q a ≫ q' a) := by ext; simp instance Pi.map_mono {f g : β → C} [HasProduct f] [HasProduct g] (p : ∀ b, f b ⟶ g b) [∀ i, Mono (p i)] : Mono <\| Pi.map p := @Limits.limMap_mono _ _ _ _ (Discrete.functor f) (Discrete.functor g) _ _ (Discrete.natTrans fun X => p X.as) (by dsimp; infer_instance) /-- Construct a morphism between categorical products from a family of morphisms between the factors. -/ def Pi.map' {f : α → C} {g : β → C} [HasProduct f] [HasProduct g] (p : β → α) (q : ∀ (b : β), f (p b) ⟶ g b) : ∏ᶜ f ⟶ ∏ᶜ g := Pi.lift (fun a => Pi.π _ _ ≫ q a) @[reassoc (attr := simp)] lemma Pi.map'_comp_π {f : α → C} {g : β → C} [HasProduct f] [HasProduct g] (p : β → α) (q : ∀ (b : β), f (p b) ⟶ g b) (b : β) : Pi.map' p q ≫ Pi.π g b = Pi.π f (p b) ≫ q b := limit.lift_π _ _ lemma Pi.map'_id_id {f : α → C} [HasProduct f] : Pi.map' id (fun a => 𝟙 (f a)) = 𝟙 (∏ᶜ f) := by ext; simp @[simp] lemma Pi.map'_id {f g : α → C} [HasProduct f] [HasProduct g] (p : ∀ b, f b ⟶ g b) : Pi.map' id p = Pi.map p := rfl lemma Pi.map'_comp_map' {f : α → C} {g : β → C} {h : γ → C} [HasProduct f] [HasProduct g] [HasProduct h] (p : β → α) (p' : γ → β) (q : ∀ (b : β), f (p b) ⟶ g b) (q' : ∀ (c : γ), g (p' c) ⟶ h c) : Pi.map' p q ≫ Pi.map' p' q' = Pi.map' (p ∘ p') (fun c => q (p' c) ≫ q' c) := by ext; simp lemma Pi.map'_comp_map {f : α → C} {g h : β → C} [HasProduct f] [HasProduct g] [HasProduct h] (p : β → α) (q : ∀ (b : β), f (p b) ⟶ g b) (q' : ∀ (b : β), g b ⟶ h b) : Pi.map' p q ≫ Pi.map q' = Pi.map' p (fun b => q b ≫ q' b) := by ext; simp lemma Pi.map_comp_map' {f g : α → C} {h : β → C} [HasProduct f] [HasProduct g] [HasProduct h] (p : β → α) (q : ∀ (a : α), f a ⟶ g a) (q' : ∀ (b : β), g (p b) ⟶ h b) : Pi.map q ≫ Pi.map' p q' = Pi.map' p (fun b => q (p b) ≫ q' b) := by ext; simp lemma Pi.map'_eq {f : α → C} {g : β → C} [HasProduct f] [HasProduct g] {p p' : β → α} {q : ∀ (b : β), f (p b) ⟶ g b} {q' : ∀ (b : β), f (p' b) ⟶ g b} (hp : p = p') (hq : ∀ (b : β), eqToHom (hp ▸ rfl) ≫ q b = q' b) : Pi.map' p q = Pi.map' p' q' := by aesop_cat /-- Construct an isomorphism between categorical products (indexed by the same type) from a family of isomorphisms between the factors. -/ abbrev Pi.mapIso {f g : β → C} [HasProductsOfShape β C] (p : ∀ b, f b ≅ g b) : ∏ᶜ f ≅ ∏ᶜ g := lim.mapIso (Discrete.natIso fun X => p X.as) instance Pi.map_isIso {f g : β → C} [HasProductsOfShape β C] (p : ∀ b, f b ⟶ g b) [∀ b, IsIso <\| p b] : IsIso <\| Pi.map p := inferInstanceAs (IsIso (Pi.mapIso (fun b ↦ asIso (p b))).hom) section /- In this section, we provide some API for products when we are given a functor `Discrete α ⥤ C` instead of a map `α → C`. -/ variable (X : Discrete α ⥤ C) [HasProduct (fun j => X.obj (Discrete.mk j))] /-- A limit cone for `X : Discrete α ⥤ C` that is given by `∏ᶜ (fun j => X.obj (Discrete.mk j))`. -/ @[simps] def Pi.cone : Cone X where pt := ∏ᶜ (fun j => X.obj (Discrete.mk j)) π := Discrete.natTrans (fun _ => Pi.π _ _) /-- The cone `Pi.cone X` is a limit cone. -/ def productIsProduct' : IsLimit (Pi.cone X) where lift s := Pi.lift (fun j => s.π.app ⟨j⟩) fac s := by simp uniq s m hm := by dsimp ext simp only [limit.lift_π, Fan.mk_pt, Fan.mk_π_app] apply hm variable [HasLimit X] /-- The isomorphism `∏ᶜ (fun j => X.obj (Discrete.mk j)) ≅ limit X`. -/ def Pi.isoLimit : ∏ᶜ (fun j => X.obj (Discrete.mk j)) ≅ limit X := IsLimit.conePointUniqueUpToIso (productIsProduct' X) (limit.isLimit X) @[reassoc (attr := simp)] lemma Pi.isoLimit_inv_π (j : α) : (Pi.isoLimit X).inv ≫ Pi.π _ j = limit.π _ (Discrete.mk j) := IsLimit.conePointUniqueUpToIso_inv_comp _ _ _ @[reassoc (attr := simp)] lemma Pi.isoLimit_hom_π (j : α) : (Pi.isoLimit X).hom ≫ limit.π _ (Discrete.mk j) = Pi.π _ j := IsLimit.conePointUniqueUpToIso_hom_comp _ _ _ end /-- Construct a morphism between categorical coproducts (indexed by the same type) from a family of morphisms between the factors. -/ abbrev Sigma.map {f g : β → C} [HasCoproduct f] [HasCoproduct g] (p : ∀ b, f b ⟶ g b) : ∐ f ⟶ ∐ g := colimMap (Discrete.natTrans fun X => p X.as) @[simp] lemma Sigma.map_id {f : α → C} [HasCoproduct f] : Sigma.map (fun a => 𝟙 (f a)) = 𝟙 (∐ f) := by ext; simp lemma Sigma.map_comp_map {f g h : α → C} [HasCoproduct f] [HasCoproduct g] [HasCoproduct h] (q : ∀ (a : α), f a ⟶ g a) (q' : ∀ (a : α), g a ⟶ h a) : Sigma.map q ≫ Sigma.map q' = Sigma.map (fun a => q a ≫ q' a) := by ext; simp instance Sigma.map_epi {f g : β → C} [HasCoproduct f] [HasCoproduct g] (p : ∀ b, f b ⟶ g b) [∀ i, Epi (p i)] : Epi <\| Sigma.map p := @Limits.colimMap_epi _ _ _ _ (Discrete.functor f) (Discrete.functor g) _ _ (Discrete.natTrans fun X => p X.as) (by dsimp; infer_instance) /-- Construct a morphism between categorical coproducts from a family of morphisms between the factors. -/ def Sigma.map' {f : α → C} {g : β → C} [HasCoproduct f] [HasCoproduct g] (p : α → β) (q : ∀ (a : α), f a ⟶ g (p a)) : ∐ f ⟶ ∐ g := Sigma.desc (fun a => q a ≫ Sigma.ι _ _) @[reassoc (attr := simp)] lemma Sigma.ι_comp_map' {f : α → C} {g : β → C} [HasCoproduct f] [HasCoproduct g] (p : α → β) (q : ∀ (a : α), f a ⟶ g (p a)) (a : α) : Sigma.ι f a ≫ Sigma.map' p q = q a ≫ Sigma.ι g (p a) := colimit.ι_desc _ _ lemma Sigma.map'_id_id {f : α → C} [HasCoproduct f] : Sigma.map' id (fun a => 𝟙 (f a)) = 𝟙 (∐ f) := by ext; simp @[simp] lemma Sigma.map'_id {f g : α → C} [HasCoproduct f] [HasCoproduct g] (p : ∀ b, f b ⟶ g b) : Sigma.map' id p = Sigma.map p := rfl lemma Sigma.map'_comp_map' {f : α → C} {g : β → C} {h : γ → C} [HasCoproduct f] [HasCoproduct g] [HasCoproduct h] (p : α → β) (p' : β → γ) (q : ∀ (a : α), f a ⟶ g (p a)) (q' : ∀ (b : β), g b ⟶ h (p' b)) : Sigma.map' p q ≫ Sigma.map' p' q' = Sigma.map' (p' ∘ p) (fun a => q a ≫ q' (p a)) := by ext; simp lemma Sigma.map'_comp_map {f : α → C} {g h : β → C} [HasCoproduct f] [HasCoproduct g] [HasCoproduct h] (p : α → β) (q : ∀ (a : α), f a ⟶ g (p a)) (q' : ∀ (b : β), g b ⟶ h b) : Sigma.map' p q ≫ Sigma.map q' = Sigma.map' p (fun a => q a ≫ q' (p a)) := by ext; simp lemma Sigma.map_comp_map' {f g : α → C} {h : β → C} [HasCoproduct f] [HasCoproduct g] [HasCoproduct h] (p : α → β) (q : ∀ (a : α), f a ⟶ g a) (q' : ∀ (a : α), g a ⟶ h (p a)) : Sigma.map q ≫ Sigma.map' p q' = Sigma.map' p (fun a => q a ≫ q' a) := by ext; simp lemma Sigma.map'_eq {f : α → C} {g : β → C} [HasCoproduct f] [HasCoproduct g] {p p' : α → β} {q : ∀ (a : α), f a ⟶ g (p a)} {q' : ∀ (a : α), f a ⟶ g (p' a)} (hp : p = p') (hq : ∀ (a : α), q a ≫ eqToHom (hp ▸ rfl) = q' a) : Sigma.map' p q = Sigma.map' p' q' := by aesop_cat /-- Construct an isomorphism between categorical coproducts (indexed by the same type) from a family of isomorphisms between the factors. -/ abbrev Sigma.mapIso {f g : β → C} [HasCoproductsOfShape β C] (p : ∀ b, f b ≅ g b) : ∐ f ≅ ∐ g := colim.mapIso (Discrete.natIso fun X => p X.as) instance Sigma.map_isIso {f g : β → C} [HasCoproductsOfShape β C] (p : ∀ b, f b ⟶ g b) [∀ b, IsIso <\| p b] : IsIso (Sigma.map p) := inferInstanceAs (IsIso (Sigma.mapIso (fun b ↦ asIso (p b))).hom)	section /- In this section, we provide some API for coproducts when we are given a functor `Discrete α ⥤ C` instead of a map `α → C`. -/	Mathlib/CategoryTheory/Limits/Shapes/Products.lean	498	502
/- Copyright (c) 2018 Reid Barton. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Reid Barton, Kim Morrison -/ import Mathlib.CategoryTheory.Opposites /-! # Morphisms from equations between objects. When working categorically, sometimes one encounters an equation `h : X = Y` between objects. Your initial aversion to this is natural and appropriate: you're in for some trouble, and if there is another way to approach the problem that won't rely on this equality, it may be worth pursuing. You have two options: 1. Use the equality `h` as one normally would in Lean (e.g. using `rw` and `subst`). This may immediately cause difficulties, because in category theory everything is dependently typed, and equations between objects quickly lead to nasty goals with `eq.rec`. 2. Promote `h` to a morphism using `eqToHom h : X ⟶ Y`, or `eqToIso h : X ≅ Y`. This file introduces various `simp` lemmas which in favourable circumstances result in the various `eqToHom` morphisms to drop out at the appropriate moment! -/ universe v₁ v₂ v₃ u₁ u₂ u₃ -- morphism levels before object levels. See note [CategoryTheory universes]. namespace CategoryTheory open Opposite variable {C : Type u₁} [Category.{v₁} C] /-- An equality `X = Y` gives us a morphism `X ⟶ Y`. It is typically better to use this, rather than rewriting by the equality then using `𝟙 _` which usually leads to dependent type theory hell. -/ def eqToHom {X Y : C} (p : X = Y) : X ⟶ Y := by rw [p]; exact 𝟙 _ @[simp] theorem eqToHom_refl (X : C) (p : X = X) : eqToHom p = 𝟙 X := rfl @[reassoc (attr := simp)] theorem eqToHom_trans {X Y Z : C} (p : X = Y) (q : Y = Z) : eqToHom p ≫ eqToHom q = eqToHom (p.trans q) := by cases p cases q simp /-- `eqToHom h` is heterogeneously equal to the identity of its domain. -/ lemma eqToHom_heq_id_dom (X Y : C) (h : X = Y) : HEq (eqToHom h) (𝟙 X) := by subst h; rfl /-- `eqToHom h` is heterogeneously equal to the identity of its codomain. -/ lemma eqToHom_heq_id_cod (X Y : C) (h : X = Y) : HEq (eqToHom h) (𝟙 Y) := by subst h; rfl /-- Two morphisms are conjugate via eqToHom if and only if they are heterogeneously equal. Note this used to be in the Functor namespace, where it doesn't belong. -/ theorem conj_eqToHom_iff_heq {W X Y Z : C} (f : W ⟶ X) (g : Y ⟶ Z) (h : W = Y) (h' : X = Z) : f = eqToHom h ≫ g ≫ eqToHom h'.symm ↔ HEq f g := by cases h cases h' simp theorem conj_eqToHom_iff_heq' {C} [Category C] {W X Y Z : C} (f : W ⟶ X) (g : Y ⟶ Z) (h : W = Y) (h' : Z = X) : f = eqToHom h ≫ g ≫ eqToHom h' ↔ HEq f g := conj_eqToHom_iff_heq _ _ _ h'.symm theorem comp_eqToHom_iff {X Y Y' : C} (p : Y = Y') (f : X ⟶ Y) (g : X ⟶ Y') : f ≫ eqToHom p = g ↔ f = g ≫ eqToHom p.symm := { mp := fun h => h ▸ by simp	mpr := fun h => by simp [eq_whisker h (eqToHom p)] } theorem eqToHom_comp_iff {X X' Y : C} (p : X = X') (f : X ⟶ Y) (g : X' ⟶ Y) : eqToHom p ≫ g = f ↔ g = eqToHom p.symm ≫ f :=	Mathlib/CategoryTheory/EqToHom.lean	77	80
/- Copyright (c) 2019 Neil Strickland. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Neil Strickland -/ import Mathlib.Algebra.BigOperators.Group.Multiset.Basic import Mathlib.Data.PNat.Prime import Mathlib.Data.Nat.Factors import Mathlib.Data.Multiset.OrderedMonoid import Mathlib.Data.Multiset.Sort /-! # Prime factors of nonzero naturals This file defines the factorization of a nonzero natural number `n` as a multiset of primes, the multiplicity of `p` in this factors multiset being the p-adic valuation of `n`. ## Main declarations * `PrimeMultiset`: Type of multisets of prime numbers. * `FactorMultiset n`: Multiset of prime factors of `n`. -/ /-- The type of multisets of prime numbers. Unique factorization gives an equivalence between this set and ℕ+, as we will formalize below. -/ def PrimeMultiset := Multiset Nat.Primes deriving Inhabited, AddCommMonoid, DistribLattice, SemilatticeSup, Sub -- The `CanonicallyOrderedAdd, OrderBot, OrderedSub` instances should be constructed by a deriving -- handler. -- https://github.com/leanprover-community/mathlib4/issues/380 instance : IsOrderedCancelAddMonoid PrimeMultiset := inferInstanceAs (IsOrderedCancelAddMonoid (Multiset Nat.Primes)) instance : CanonicallyOrderedAdd PrimeMultiset := inferInstanceAs (CanonicallyOrderedAdd (Multiset Nat.Primes)) instance : OrderBot PrimeMultiset := inferInstanceAs (OrderBot (Multiset Nat.Primes)) instance : OrderedSub PrimeMultiset := inferInstanceAs (OrderedSub (Multiset Nat.Primes)) namespace PrimeMultiset -- `@[derive]` doesn't work for `meta` instances unsafe instance : Repr PrimeMultiset := by delta PrimeMultiset; infer_instance /-- The multiset consisting of a single prime -/ def ofPrime (p : Nat.Primes) : PrimeMultiset := ({p} : Multiset Nat.Primes) theorem card_ofPrime (p : Nat.Primes) : Multiset.card (ofPrime p) = 1 := rfl /-- We can forget the primality property and regard a multiset of primes as just a multiset of positive integers, or a multiset of natural numbers. In the opposite direction, if we have a multiset of positive integers or natural numbers, together with a proof that all the elements are prime, then we can regard it as a multiset of primes. The next block of results records obvious properties of these coercions. -/ def toNatMultiset : PrimeMultiset → Multiset ℕ := fun v => v.map (↑) instance coeNat : Coe PrimeMultiset (Multiset ℕ) := ⟨toNatMultiset⟩ /-- `PrimeMultiset.coe`, the coercion from a multiset of primes to a multiset of naturals, promoted to an `AddMonoidHom`. -/ def coeNatMonoidHom : PrimeMultiset →+ Multiset ℕ := Multiset.mapAddMonoidHom (↑) @[simp] theorem coe_coeNatMonoidHom : (coeNatMonoidHom : PrimeMultiset → Multiset ℕ) = (↑) := rfl theorem coeNat_injective : Function.Injective ((↑) : PrimeMultiset → Multiset ℕ) := Multiset.map_injective Nat.Primes.coe_nat_injective theorem coeNat_ofPrime (p : Nat.Primes) : (ofPrime p : Multiset ℕ) = {(p : ℕ)} := rfl theorem coeNat_prime (v : PrimeMultiset) (p : ℕ) (h : p ∈ (v : Multiset ℕ)) : p.Prime := by rcases Multiset.mem_map.mp h with ⟨⟨_, hp'⟩, ⟨_, h_eq⟩⟩ exact h_eq ▸ hp' /-- Converts a `PrimeMultiset` to a `Multiset ℕ+`. -/ def toPNatMultiset : PrimeMultiset → Multiset ℕ+ := fun v => v.map (↑) instance coePNat : Coe PrimeMultiset (Multiset ℕ+) := ⟨toPNatMultiset⟩ /-- `coePNat`, the coercion from a multiset of primes to a multiset of positive naturals, regarded as an `AddMonoidHom`. -/ def coePNatMonoidHom : PrimeMultiset →+ Multiset ℕ+ := Multiset.mapAddMonoidHom (↑) @[simp] theorem coe_coePNatMonoidHom : (coePNatMonoidHom : PrimeMultiset → Multiset ℕ+) = (↑) := rfl theorem coePNat_injective : Function.Injective ((↑) : PrimeMultiset → Multiset ℕ+) := Multiset.map_injective Nat.Primes.coe_pnat_injective theorem coePNat_ofPrime (p : Nat.Primes) : (ofPrime p : Multiset ℕ+) = {(p : ℕ+)} := rfl theorem coePNat_prime (v : PrimeMultiset) (p : ℕ+) (h : p ∈ (v : Multiset ℕ+)) : p.Prime := by rcases Multiset.mem_map.mp h with ⟨⟨_, hp'⟩, ⟨_, h_eq⟩⟩ exact h_eq ▸ hp' instance coeMultisetPNatNat : Coe (Multiset ℕ+) (Multiset ℕ) := ⟨fun v => v.map (↑)⟩ theorem coePNat_nat (v : PrimeMultiset) : ((v : Multiset ℕ+) : Multiset ℕ) = (v : Multiset ℕ) := by change (v.map ((↑) : Nat.Primes → ℕ+)).map Subtype.val = v.map Subtype.val rw [Multiset.map_map] congr /-- The product of a `PrimeMultiset`, as a `ℕ+`. -/ def prod (v : PrimeMultiset) : ℕ+ := (v : Multiset PNat).prod theorem coe_prod (v : PrimeMultiset) : (v.prod : ℕ) = (v : Multiset ℕ).prod := by have h : (v.prod : ℕ) = ((v.map (↑) : Multiset ℕ+).map (↑)).prod := PNat.coeMonoidHom.map_multiset_prod v.toPNatMultiset simpa [Multiset.map_map] using h theorem prod_ofPrime (p : Nat.Primes) : (ofPrime p).prod = (p : ℕ+) := Multiset.prod_singleton _ /-- If a `Multiset ℕ` consists only of primes, it can be recast as a `PrimeMultiset`. -/ def ofNatMultiset (v : Multiset ℕ) (h : ∀ p : ℕ, p ∈ v → p.Prime) : PrimeMultiset := @Multiset.pmap ℕ Nat.Primes Nat.Prime (fun p hp => ⟨p, hp⟩) v h theorem to_ofNatMultiset (v : Multiset ℕ) (h) : (ofNatMultiset v h : Multiset ℕ) = v := by dsimp [ofNatMultiset, toNatMultiset] rw [Multiset.map_pmap, Multiset.pmap_eq_map, Multiset.map_id'] theorem prod_ofNatMultiset (v : Multiset ℕ) (h) : ((ofNatMultiset v h).prod : ℕ) = (v.prod : ℕ) := by rw [coe_prod, to_ofNatMultiset] /-- If a `Multiset ℕ+` consists only of primes, it can be recast as a `PrimeMultiset`. -/ def ofPNatMultiset (v : Multiset ℕ+) (h : ∀ p : ℕ+, p ∈ v → p.Prime) : PrimeMultiset := @Multiset.pmap ℕ+ Nat.Primes PNat.Prime (fun p hp => ⟨(p : ℕ), hp⟩) v h theorem to_ofPNatMultiset (v : Multiset ℕ+) (h) : (ofPNatMultiset v h : Multiset ℕ+) = v := by dsimp [ofPNatMultiset, toPNatMultiset] have : (fun (p : ℕ+) (h : p.Prime) => ((↑) : Nat.Primes → ℕ+) ⟨p, h⟩) = fun p _ => id p := by funext p h apply Subtype.eq rfl rw [Multiset.map_pmap, this, Multiset.pmap_eq_map, Multiset.map_id] theorem prod_ofPNatMultiset (v : Multiset ℕ+) (h) : ((ofPNatMultiset v h).prod : ℕ+) = v.prod := by dsimp [prod] rw [to_ofPNatMultiset] /-- Lists can be coerced to multisets; here we have some results about how this interacts with our constructions on multisets. -/ def ofNatList (l : List ℕ) (h : ∀ p : ℕ, p ∈ l → p.Prime) : PrimeMultiset := ofNatMultiset (l : Multiset ℕ) h theorem prod_ofNatList (l : List ℕ) (h) : ((ofNatList l h).prod : ℕ) = l.prod := by have := prod_ofNatMultiset (l : Multiset ℕ) h rw [Multiset.prod_coe] at this exact this /-- If a `List ℕ+` consists only of primes, it can be recast as a `PrimeMultiset` with the coercion from lists to multisets. -/ def ofPNatList (l : List ℕ+) (h : ∀ p : ℕ+, p ∈ l → p.Prime) : PrimeMultiset := ofPNatMultiset (l : Multiset ℕ+) h theorem prod_ofPNatList (l : List ℕ+) (h) : (ofPNatList l h).prod = l.prod := by have := prod_ofPNatMultiset (l : Multiset ℕ+) h rw [Multiset.prod_coe] at this exact this /-- The product map gives a homomorphism from the additive monoid of multisets to the multiplicative monoid ℕ+. -/ theorem prod_zero : (0 : PrimeMultiset).prod = 1 := by exact Multiset.prod_zero theorem prod_add (u v : PrimeMultiset) : (u + v).prod = u.prod * v.prod := by change (coePNatMonoidHom (u + v)).prod = _ rw [coePNatMonoidHom.map_add] exact Multiset.prod_add _ _ theorem prod_smul (d : ℕ) (u : PrimeMultiset) : (d • u).prod = u.prod ^ d := by induction d with \| zero => simp only [zero_nsmul, pow_zero, prod_zero] \| succ n ih => rw [succ_nsmul, prod_add, ih, pow_succ] end PrimeMultiset namespace PNat /-- The prime factors of n, regarded as a multiset -/ def factorMultiset (n : ℕ+) : PrimeMultiset := PrimeMultiset.ofNatList (Nat.primeFactorsList n) (@Nat.prime_of_mem_primeFactorsList n) /-- The product of the factors is the original number -/ theorem prod_factorMultiset (n : ℕ+) : (factorMultiset n).prod = n := eq <\| by dsimp [factorMultiset] rw [PrimeMultiset.prod_ofNatList] exact Nat.prod_primeFactorsList n.ne_zero theorem coeNat_factorMultiset (n : ℕ+) : (factorMultiset n : Multiset ℕ) = (Nat.primeFactorsList n : Multiset ℕ) := PrimeMultiset.to_ofNatMultiset (Nat.primeFactorsList n) (@Nat.prime_of_mem_primeFactorsList n) end PNat namespace PrimeMultiset /-- If we start with a multiset of primes, take the product and then factor it, we get back the original multiset. -/ theorem factorMultiset_prod (v : PrimeMultiset) : v.prod.factorMultiset = v := by apply PrimeMultiset.coeNat_injective rw [v.prod.coeNat_factorMultiset, PrimeMultiset.coe_prod] rcases v with ⟨l⟩ dsimp [PrimeMultiset.toNatMultiset] let l' := l.map ((↑) : Nat.Primes → ℕ) have (p : ℕ) (hp : p ∈ l') : p.Prime := by simp only [List.map_subtype, List.map_id_fun', id_eq, List.mem_unattach, l'] at hp obtain ⟨hp', -⟩ := hp exact hp' exact Multiset.coe_eq_coe.mpr (@Nat.primeFactorsList_unique _ l' rfl this).symm end PrimeMultiset namespace PNat /-- Positive integers biject with multisets of primes. -/ def factorMultisetEquiv : ℕ+ ≃ PrimeMultiset where toFun := factorMultiset invFun := PrimeMultiset.prod left_inv := prod_factorMultiset right_inv := PrimeMultiset.factorMultiset_prod /-- Factoring gives a homomorphism from the multiplicative monoid ℕ+ to the additive monoid of multisets. -/ theorem factorMultiset_one : factorMultiset 1 = 0 := by simp [factorMultiset, PrimeMultiset.ofNatList, PrimeMultiset.ofNatMultiset] theorem factorMultiset_mul (n m : ℕ+) : factorMultiset (n * m) = factorMultiset n + factorMultiset m := by let u := factorMultiset n let v := factorMultiset m have : n = u.prod := (prod_factorMultiset n).symm; rw [this] have : m = v.prod := (prod_factorMultiset m).symm; rw [this] rw [← PrimeMultiset.prod_add] repeat' rw [PrimeMultiset.factorMultiset_prod] theorem factorMultiset_pow (n : ℕ+) (m : ℕ) : factorMultiset (n ^ m) = m • factorMultiset n := by let u := factorMultiset n have : n = u.prod := (prod_factorMultiset n).symm rw [this, ← PrimeMultiset.prod_smul] repeat' rw [PrimeMultiset.factorMultiset_prod] /-- Factoring a prime gives the corresponding one-element multiset. -/ theorem factorMultiset_ofPrime (p : Nat.Primes) : (p : ℕ+).factorMultiset = PrimeMultiset.ofPrime p := by apply factorMultisetEquiv.symm.injective change (p : ℕ+).factorMultiset.prod = (PrimeMultiset.ofPrime p).prod rw [(p : ℕ+).prod_factorMultiset, PrimeMultiset.prod_ofPrime] /-- We now have four different results that all encode the idea that inequality of multisets corresponds to divisibility of positive integers. -/ theorem factorMultiset_le_iff {m n : ℕ+} : factorMultiset m ≤ factorMultiset n ↔ m ∣ n := by constructor · intro h rw [← prod_factorMultiset m, ← prod_factorMultiset m] apply Dvd.intro (n.factorMultiset - m.factorMultiset).prod rw [← PrimeMultiset.prod_add, PrimeMultiset.factorMultiset_prod, add_tsub_cancel_of_le h, prod_factorMultiset] · intro h rw [← mul_div_exact h, factorMultiset_mul] exact le_self_add theorem factorMultiset_le_iff' {m : ℕ+} {v : PrimeMultiset} : factorMultiset m ≤ v ↔ m ∣ v.prod := by let h := @factorMultiset_le_iff m v.prod rw [v.factorMultiset_prod] at h exact h end PNat namespace PrimeMultiset theorem prod_dvd_iff {u v : PrimeMultiset} : u.prod ∣ v.prod ↔ u ≤ v := by let h := @PNat.factorMultiset_le_iff' u.prod v rw [u.factorMultiset_prod] at h exact h.symm theorem prod_dvd_iff' {u : PrimeMultiset} {n : ℕ+} : u.prod ∣ n ↔ u ≤ n.factorMultiset := by let h := @prod_dvd_iff u n.factorMultiset rw [n.prod_factorMultiset] at h exact h end PrimeMultiset namespace PNat /-- The gcd and lcm operations on positive integers correspond to the inf and sup operations on multisets. -/ theorem factorMultiset_gcd (m n : ℕ+) : factorMultiset (gcd m n) = factorMultiset m ⊓ factorMultiset n := by apply le_antisymm · apply le_inf_iff.mpr; constructor <;> apply factorMultiset_le_iff.mpr · exact gcd_dvd_left m n · exact gcd_dvd_right m n · rw [← PrimeMultiset.prod_dvd_iff, prod_factorMultiset] apply dvd_gcd <;> rw [PrimeMultiset.prod_dvd_iff'] · exact inf_le_left · exact inf_le_right theorem factorMultiset_lcm (m n : ℕ+) : factorMultiset (lcm m n) = factorMultiset m ⊔ factorMultiset n := by apply le_antisymm · rw [← PrimeMultiset.prod_dvd_iff, prod_factorMultiset] apply lcm_dvd <;> rw [← factorMultiset_le_iff'] · exact le_sup_left · exact le_sup_right · apply sup_le_iff.mpr; constructor <;> apply factorMultiset_le_iff.mpr · exact dvd_lcm_left m n · exact dvd_lcm_right m n /-- The number of occurrences of p in the factor multiset of m is the same as the p-adic valuation of m. -/ theorem count_factorMultiset (m : ℕ+) (p : Nat.Primes) (k : ℕ) : (p : ℕ+) ^ k ∣ m ↔ k ≤ m.factorMultiset.count p := by rw [Multiset.le_count_iff_replicate_le, ← factorMultiset_le_iff, factorMultiset_pow, factorMultiset_ofPrime] congr! 2 apply Multiset.eq_replicate.mpr constructor · rw [Multiset.card_nsmul, PrimeMultiset.card_ofPrime, mul_one] · intro q h rw [PrimeMultiset.ofPrime, Multiset.nsmul_singleton _ k] at h exact Multiset.eq_of_mem_replicate h end PNat namespace PrimeMultiset theorem prod_inf (u v : PrimeMultiset) : (u ⊓ v).prod = PNat.gcd u.prod v.prod := by let n := u.prod let m := v.prod change (u ⊓ v).prod = PNat.gcd n m have : u = n.factorMultiset := u.factorMultiset_prod.symm; rw [this] have : v = m.factorMultiset := v.factorMultiset_prod.symm; rw [this] rw [← PNat.factorMultiset_gcd n m, PNat.prod_factorMultiset] theorem prod_sup (u v : PrimeMultiset) : (u ⊔ v).prod = PNat.lcm u.prod v.prod := by let n := u.prod let m := v.prod change (u ⊔ v).prod = PNat.lcm n m have : u = n.factorMultiset := u.factorMultiset_prod.symm; rw [this] have : v = m.factorMultiset := v.factorMultiset_prod.symm; rw [this] rw [← PNat.factorMultiset_lcm n m, PNat.prod_factorMultiset] end PrimeMultiset		Mathlib/Data/PNat/Factors.lean	414	420
/- 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 _ _)	Mathlib/SetTheory/Ordinal/Arithmetic.lean	1,137	1,139
/- Copyright (c) 2022 Yaël Dillies. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yaël Dillies -/ import Mathlib.Order.Filter.Prod /-! # N-ary maps of filter This file defines the binary and ternary maps of filters. This is mostly useful to define pointwise operations on filters. ## Main declarations * `Filter.map₂`: Binary map of filters. ## Notes This file is very similar to `Data.Set.NAry`, `Data.Finset.NAry` and `Data.Option.NAry`. Please keep them in sync. -/ open Function Set open Filter namespace Filter variable {α α' β β' γ γ' δ δ' ε ε' : Type*} {m : α → β → γ} {f f₁ f₂ : Filter α} {g g₁ g₂ : Filter β} {h : Filter γ} {s : Set α} {t : Set β} {u : Set γ} {a : α} {b : β} /-- The image of a binary function `m : α → β → γ` as a function `Filter α → Filter β → Filter γ`. Mathematically this should be thought of as the image of the corresponding function `α × β → γ`. -/ def map₂ (m : α → β → γ) (f : Filter α) (g : Filter β) : Filter γ := ((f ×ˢ g).map (uncurry m)).copy { s \| ∃ u ∈ f, ∃ v ∈ g, image2 m u v ⊆ s } fun _ ↦ by simp only [mem_map, mem_prod_iff, image2_subset_iff, prod_subset_iff]; rfl @[simp 900] theorem mem_map₂_iff : u ∈ map₂ m f g ↔ ∃ s ∈ f, ∃ t ∈ g, image2 m s t ⊆ u := Iff.rfl theorem image2_mem_map₂ (hs : s ∈ f) (ht : t ∈ g) : image2 m s t ∈ map₂ m f g := ⟨_, hs, _, ht, Subset.rfl⟩ theorem map_prod_eq_map₂ (m : α → β → γ) (f : Filter α) (g : Filter β) : Filter.map (fun p : α × β => m p.1 p.2) (f ×ˢ g) = map₂ m f g := by rw [map₂, copy_eq, uncurry_def] theorem map_prod_eq_map₂' (m : α × β → γ) (f : Filter α) (g : Filter β) : Filter.map m (f ×ˢ g) = map₂ (fun a b => m (a, b)) f g := map_prod_eq_map₂ m.curry f g @[simp] theorem map₂_mk_eq_prod (f : Filter α) (g : Filter β) : map₂ Prod.mk f g = f ×ˢ g := by simp only [← map_prod_eq_map₂, map_id'] -- lemma image2_mem_map₂_iff (hm : injective2 m) : image2 m s t ∈ map₂ m f g ↔ s ∈ f ∧ t ∈ g := -- ⟨by { rintro ⟨u, v, hu, hv, h⟩, rw image2_subset_image2_iff hm at h, -- exact ⟨mem_of_superset hu h.1, mem_of_superset hv h.2⟩ }, fun h ↦ image2_mem_map₂ h.1 h.2⟩ @[gcongr] theorem map₂_mono (hf : f₁ ≤ f₂) (hg : g₁ ≤ g₂) : map₂ m f₁ g₁ ≤ map₂ m f₂ g₂ := fun _ ⟨s, hs, t, ht, hst⟩ => ⟨s, hf hs, t, hg ht, hst⟩ @[gcongr] theorem map₂_mono_left (h : g₁ ≤ g₂) : map₂ m f g₁ ≤ map₂ m f g₂ := map₂_mono Subset.rfl h @[gcongr] theorem map₂_mono_right (h : f₁ ≤ f₂) : map₂ m f₁ g ≤ map₂ m f₂ g := map₂_mono h Subset.rfl @[simp] theorem le_map₂_iff {h : Filter γ} : h ≤ map₂ m f g ↔ ∀ ⦃s⦄, s ∈ f → ∀ ⦃t⦄, t ∈ g → image2 m s t ∈ h := ⟨fun H _ hs _ ht => H <\| image2_mem_map₂ hs ht, fun H _ ⟨_, hs, _, ht, hu⟩ => mem_of_superset (H hs ht) hu⟩ @[simp] theorem map₂_eq_bot_iff : map₂ m f g = ⊥ ↔ f = ⊥ ∨ g = ⊥ := by simp [← map_prod_eq_map₂] @[simp] theorem map₂_bot_left : map₂ m ⊥ g = ⊥ := map₂_eq_bot_iff.2 <\| .inl rfl @[simp] theorem map₂_bot_right : map₂ m f ⊥ = ⊥ := map₂_eq_bot_iff.2 <\| .inr rfl @[simp] theorem map₂_neBot_iff : (map₂ m f g).NeBot ↔ f.NeBot ∧ g.NeBot := by simp [neBot_iff, not_or] protected theorem NeBot.map₂ (hf : f.NeBot) (hg : g.NeBot) : (map₂ m f g).NeBot := map₂_neBot_iff.2 ⟨hf, hg⟩ instance map₂.neBot [NeBot f] [NeBot g] : NeBot (map₂ m f g) := .map₂ ‹_› ‹_› theorem NeBot.of_map₂_left (h : (map₂ m f g).NeBot) : f.NeBot := (map₂_neBot_iff.1 h).1 theorem NeBot.of_map₂_right (h : (map₂ m f g).NeBot) : g.NeBot := (map₂_neBot_iff.1 h).2 theorem map₂_sup_left : map₂ m (f₁ ⊔ f₂) g = map₂ m f₁ g ⊔ map₂ m f₂ g := by simp_rw [← map_prod_eq_map₂, sup_prod, map_sup] theorem map₂_sup_right : map₂ m f (g₁ ⊔ g₂) = map₂ m f g₁ ⊔ map₂ m f g₂ := by simp_rw [← map_prod_eq_map₂, prod_sup, map_sup] theorem map₂_inf_subset_left : map₂ m (f₁ ⊓ f₂) g ≤ map₂ m f₁ g ⊓ map₂ m f₂ g := Monotone.map_inf_le (fun _ _ ↦ map₂_mono_right) f₁ f₂ theorem map₂_inf_subset_right : map₂ m f (g₁ ⊓ g₂) ≤ map₂ m f g₁ ⊓ map₂ m f g₂ := Monotone.map_inf_le (fun _ _ ↦ map₂_mono_left) g₁ g₂ @[simp] theorem map₂_pure_left : map₂ m (pure a) g = g.map (m a) := by rw [← map_prod_eq_map₂, pure_prod, map_map]; rfl @[simp] theorem map₂_pure_right : map₂ m f (pure b) = f.map (m · b) := by rw [← map_prod_eq_map₂, prod_pure, map_map]; rfl theorem map₂_pure : map₂ m (pure a) (pure b) = pure (m a b) := by rw [map₂_pure_right, map_pure] theorem map₂_swap (m : α → β → γ) (f : Filter α) (g : Filter β) : map₂ m f g = map₂ (fun a b => m b a) g f := by rw [← map_prod_eq_map₂, prod_comm, map_map, ← map_prod_eq_map₂, Function.comp_def] @[simp] theorem map₂_left [NeBot g] : map₂ (fun x _ => x) f g = f := by rw [← map_prod_eq_map₂, map_fst_prod] @[simp] theorem map₂_right [NeBot f] : map₂ (fun _ y => y) f g = g := by rw [map₂_swap, map₂_left] theorem map_map₂ (m : α → β → γ) (n : γ → δ) : (map₂ m f g).map n = map₂ (fun a b => n (m a b)) f g := by rw [← map_prod_eq_map₂, ← map_prod_eq_map₂, map_map]; rfl theorem map₂_map_left (m : γ → β → δ) (n : α → γ) : map₂ m (f.map n) g = map₂ (fun a b => m (n a) b) f g := by rw [← map_prod_eq_map₂, ← map_prod_eq_map₂, ← @map_id _ g, prod_map_map_eq, map_map, map_id]; rfl theorem map₂_map_right (m : α → γ → δ) (n : β → γ) : map₂ m f (g.map n) = map₂ (fun a b => m a (n b)) f g := by rw [map₂_swap, map₂_map_left, map₂_swap]	@[simp] theorem map₂_curry (m : α × β → γ) (f : Filter α) (g : Filter β) : map₂ m.curry f g = (f ×ˢ g).map m :=	Mathlib/Order/Filter/NAry.lean	149	151
/- Copyright (c) 2020 Kim Morrison. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kim Morrison, Shing Tak Lam, Mario Carneiro -/ import Mathlib.Algebra.BigOperators.Intervals import Mathlib.Algebra.BigOperators.Ring.List import Mathlib.Data.Int.ModEq import Mathlib.Data.Nat.Bits import Mathlib.Data.Nat.Log import Mathlib.Data.List.Palindrome import Mathlib.Tactic.IntervalCases import Mathlib.Tactic.Linarith import Mathlib.Tactic.Ring /-! # Digits of a natural number This provides a basic API for extracting the digits of a natural number in a given base, and reconstructing numbers from their digits. We also prove some divisibility tests based on digits, in particular completing Theorem #85 from https://www.cs.ru.nl/~freek/100/. Also included is a bound on the length of `Nat.toDigits` from core. ## TODO A basic `norm_digits` tactic for proving goals of the form `Nat.digits a b = l` where `a` and `b` are numerals is not yet ported. -/ namespace Nat variable {n : ℕ} /-- (Impl.) An auxiliary definition for `digits`, to help get the desired definitional unfolding. -/ def digitsAux0 : ℕ → List ℕ \| 0 => [] \| n + 1 => [n + 1] /-- (Impl.) An auxiliary definition for `digits`, to help get the desired definitional unfolding. -/ def digitsAux1 (n : ℕ) : List ℕ := List.replicate n 1 /-- (Impl.) An auxiliary definition for `digits`, to help get the desired definitional unfolding. -/ def digitsAux (b : ℕ) (h : 2 ≤ b) : ℕ → List ℕ \| 0 => [] \| n + 1 => ((n + 1) % b) :: digitsAux b h ((n + 1) / b) decreasing_by exact Nat.div_lt_self (Nat.succ_pos _) h @[simp] theorem digitsAux_zero (b : ℕ) (h : 2 ≤ b) : digitsAux b h 0 = [] := by rw [digitsAux] theorem digitsAux_def (b : ℕ) (h : 2 ≤ b) (n : ℕ) (w : 0 < n) : digitsAux b h n = (n % b) :: digitsAux b h (n / b) := by cases n · cases w · rw [digitsAux] /-- `digits b n` gives the digits, in little-endian order, of a natural number `n` in a specified base `b`. In any base, we have `ofDigits b L = L.foldr (fun x y ↦ x + b * y) 0`. * For any `2 ≤ b`, we have `l < b` for any `l ∈ digits b n`, and the last digit is not zero. This uniquely specifies the behaviour of `digits b`. * For `b = 1`, we define `digits 1 n = List.replicate n 1`. * For `b = 0`, we define `digits 0 n = [n]`, except `digits 0 0 = []`. Note this differs from the existing `Nat.toDigits` in core, which is used for printing numerals. In particular, `Nat.toDigits b 0 = ['0']`, while `digits b 0 = []`. -/ def digits : ℕ → ℕ → List ℕ \| 0 => digitsAux0 \| 1 => digitsAux1 \| b + 2 => digitsAux (b + 2) (by norm_num) @[simp] theorem digits_zero (b : ℕ) : digits b 0 = [] := by rcases b with (_ \| ⟨_ \| ⟨_⟩⟩) <;> simp [digits, digitsAux0, digitsAux1] theorem digits_zero_zero : digits 0 0 = [] := rfl @[simp] theorem digits_zero_succ (n : ℕ) : digits 0 n.succ = [n + 1] := rfl theorem digits_zero_succ' : ∀ {n : ℕ}, n ≠ 0 → digits 0 n = [n] \| 0, h => (h rfl).elim \| _ + 1, _ => rfl @[simp] theorem digits_one (n : ℕ) : digits 1 n = List.replicate n 1 := rfl -- no `@[simp]`: dsimp can prove this theorem digits_one_succ (n : ℕ) : digits 1 (n + 1) = 1 :: digits 1 n := rfl theorem digits_add_two_add_one (b n : ℕ) : digits (b + 2) (n + 1) = ((n + 1) % (b + 2)) :: digits (b + 2) ((n + 1) / (b + 2)) := by simp [digits, digitsAux_def] @[simp] lemma digits_of_two_le_of_pos {b : ℕ} (hb : 2 ≤ b) (hn : 0 < n) : Nat.digits b n = n % b :: Nat.digits b (n / b) := by rw [Nat.eq_add_of_sub_eq hb rfl, Nat.eq_add_of_sub_eq hn rfl, Nat.digits_add_two_add_one] theorem digits_def' : ∀ {b : ℕ} (_ : 1 < b) {n : ℕ} (_ : 0 < n), digits b n = (n % b) :: digits b (n / b) \| 0, h => absurd h (by decide) \| 1, h => absurd h (by decide) \| b + 2, _ => digitsAux_def _ (by simp) _ @[simp] theorem digits_of_lt (b x : ℕ) (hx : x ≠ 0) (hxb : x < b) : digits b x = [x] := by rcases exists_eq_succ_of_ne_zero hx with ⟨x, rfl⟩ rcases Nat.exists_eq_add_of_le' ((Nat.le_add_left 1 x).trans_lt hxb) with ⟨b, rfl⟩ rw [digits_add_two_add_one, div_eq_of_lt hxb, digits_zero, mod_eq_of_lt hxb] theorem digits_add (b : ℕ) (h : 1 < b) (x y : ℕ) (hxb : x < b) (hxy : x ≠ 0 ∨ y ≠ 0) : digits b (x + b * y) = x :: digits b y := by rcases Nat.exists_eq_add_of_le' h with ⟨b, rfl : _ = _ + 2⟩ cases y · simp [hxb, hxy.resolve_right (absurd rfl)] dsimp [digits] rw [digitsAux_def] · congr · simp [Nat.add_mod, mod_eq_of_lt hxb] · simp [add_mul_div_left, div_eq_of_lt hxb] · apply Nat.succ_pos -- If we had a function converting a list into a polynomial, -- and appropriate lemmas about that function, -- we could rewrite this in terms of that. /-- `ofDigits b L` takes a list `L` of natural numbers, and interprets them as a number in semiring, as the little-endian digits in base `b`. -/ def ofDigits {α : Type} [Semiring α] (b : α) : List ℕ → α \| [] => 0 \| h :: t => h + b ofDigits b t theorem ofDigits_eq_foldr {α : Type} [Semiring α] (b : α) (L : List ℕ) : ofDigits b L = List.foldr (fun x y => ↑x + b y) 0 L := by induction' L with d L ih · rfl · dsimp [ofDigits] rw [ih] theorem ofDigits_eq_sum_mapIdx_aux (b : ℕ) (l : List ℕ) : (l.zipWith ((fun a i : ℕ => a * b ^ (i + 1))) (List.range l.length)).sum = b * (l.zipWith (fun a i => a * b ^ i) (List.range l.length)).sum := by suffices l.zipWith (fun a i : ℕ => a * b ^ (i + 1)) (List.range l.length) = l.zipWith (fun a i=> b * (a * b ^ i)) (List.range l.length) by simp [this] congr; ext; simp [pow_succ]; ring theorem ofDigits_eq_sum_mapIdx (b : ℕ) (L : List ℕ) : ofDigits b L = (L.mapIdx fun i a => a * b ^ i).sum := by rw [List.mapIdx_eq_zipIdx_map, List.zipIdx_eq_zip_range', List.map_zip_eq_zipWith, ofDigits_eq_foldr, ← List.range_eq_range'] induction' L with hd tl hl · simp · simpa [List.range_succ_eq_map, List.zipWith_map_right, ofDigits_eq_sum_mapIdx_aux] using Or.inl hl @[simp] theorem ofDigits_nil {b : ℕ} : ofDigits b [] = 0 := rfl @[simp] theorem ofDigits_singleton {b n : ℕ} : ofDigits b [n] = n := by simp [ofDigits] @[simp] theorem ofDigits_one_cons {α : Type} [Semiring α] (h : ℕ) (L : List ℕ) : ofDigits (1 : α) (h :: L) = h + ofDigits 1 L := by simp [ofDigits] theorem ofDigits_cons {b hd} {tl : List ℕ} : ofDigits b (hd :: tl) = hd + b ofDigits b tl := rfl theorem ofDigits_append {b : ℕ} {l1 l2 : List ℕ} : ofDigits b (l1 ++ l2) = ofDigits b l1 + b ^ l1.length * ofDigits b l2 := by induction' l1 with hd tl IH · simp [ofDigits] · rw [ofDigits, List.cons_append, ofDigits, IH, List.length_cons, pow_succ'] ring @[norm_cast] theorem coe_ofDigits (α : Type) [Semiring α] (b : ℕ) (L : List ℕ) : ((ofDigits b L : ℕ) : α) = ofDigits (b : α) L := by induction' L with d L ih · simp [ofDigits] · dsimp [ofDigits]; push_cast; rw [ih] @[norm_cast] theorem coe_int_ofDigits (b : ℕ) (L : List ℕ) : ((ofDigits b L : ℕ) : ℤ) = ofDigits (b : ℤ) L := by induction' L with d L _ · rfl · dsimp [ofDigits]; push_cast; simp only theorem digits_zero_of_eq_zero {b : ℕ} (h : b ≠ 0) : ∀ {L : List ℕ} (_ : ofDigits b L = 0), ∀ l ∈ L, l = 0 \| _ :: _, h0, _, List.Mem.head .. => Nat.eq_zero_of_add_eq_zero_right h0 \| _ :: _, h0, _, List.Mem.tail _ hL => digits_zero_of_eq_zero h (mul_right_injective₀ h (Nat.eq_zero_of_add_eq_zero_left h0)) _ hL theorem digits_ofDigits (b : ℕ) (h : 1 < b) (L : List ℕ) (w₁ : ∀ l ∈ L, l < b) (w₂ : ∀ h : L ≠ [], L.getLast h ≠ 0) : digits b (ofDigits b L) = L := by induction' L with d L ih · dsimp [ofDigits] simp · dsimp [ofDigits] replace w₂ := w₂ (by simp) rw [digits_add b h] · rw [ih] · intro l m apply w₁ exact List.mem_cons_of_mem _ m · intro h rw [List.getLast_cons h] at w₂ convert w₂ · exact w₁ d List.mem_cons_self · by_cases h' : L = [] · rcases h' with rfl left simpa using w₂ · right contrapose! w₂ refine digits_zero_of_eq_zero h.ne_bot w₂ _ ?_ rw [List.getLast_cons h'] exact List.getLast_mem h' theorem ofDigits_digits (b n : ℕ) : ofDigits b (digits b n) = n := by rcases b with - \| b · rcases n with - \| n · rfl · simp · rcases b with - \| b · induction' n with n ih · rfl · rw [Nat.zero_add] at ih ⊢ simp only [ih, add_comm 1, ofDigits_one_cons, Nat.cast_id, digits_one_succ] · induction n using Nat.strongRecOn with \| ind n h => ?_ cases n · rw [digits_zero] rfl · simp only [Nat.succ_eq_add_one, digits_add_two_add_one] dsimp [ofDigits] rw [h _ (Nat.div_lt_self' _ b)] rw [Nat.mod_add_div] theorem ofDigits_one (L : List ℕ) : ofDigits 1 L = L.sum := by induction L with \| nil => rfl \| cons _ _ ih => simp [ofDigits, List.sum_cons, ih] /-! ### Properties This section contains various lemmas of properties relating to `digits` and `ofDigits`. -/ theorem digits_eq_nil_iff_eq_zero {b n : ℕ} : digits b n = [] ↔ n = 0 := by constructor · intro h have : ofDigits b (digits b n) = ofDigits b [] := by rw [h] convert this rw [ofDigits_digits] · rintro rfl simp theorem digits_ne_nil_iff_ne_zero {b n : ℕ} : digits b n ≠ [] ↔ n ≠ 0 := not_congr digits_eq_nil_iff_eq_zero theorem digits_eq_cons_digits_div {b n : ℕ} (h : 1 < b) (w : n ≠ 0) : digits b n = (n % b) :: digits b (n / b) := by rcases b with (_ \| _ \| b) · rw [digits_zero_succ' w, Nat.mod_zero, Nat.div_zero, Nat.digits_zero_zero] · norm_num at h rcases n with (_ \| n) · norm_num at w · simp only [digits_add_two_add_one, ne_eq] theorem digits_getLast {b : ℕ} (m : ℕ) (h : 1 < b) (p q) : (digits b m).getLast p = (digits b (m / b)).getLast q := by by_cases hm : m = 0 · simp [hm] simp only [digits_eq_cons_digits_div h hm] rw [List.getLast_cons] theorem digits.injective (b : ℕ) : Function.Injective b.digits := Function.LeftInverse.injective (ofDigits_digits b) @[simp] theorem digits_inj_iff {b n m : ℕ} : b.digits n = b.digits m ↔ n = m := (digits.injective b).eq_iff theorem digits_len (b n : ℕ) (hb : 1 < b) (hn : n ≠ 0) : (b.digits n).length = b.log n + 1 := by induction' n using Nat.strong_induction_on with n IH rw [digits_eq_cons_digits_div hb hn, List.length] by_cases h : n / b = 0 · simp [IH, h] aesop · have : n / b < n := div_lt_self (Nat.pos_of_ne_zero hn) hb rw [IH _ this h, log_div_base, tsub_add_cancel_of_le] refine Nat.succ_le_of_lt (log_pos hb ?_) contrapose! h exact div_eq_of_lt h theorem getLast_digit_ne_zero (b : ℕ) {m : ℕ} (hm : m ≠ 0) : (digits b m).getLast (digits_ne_nil_iff_ne_zero.mpr hm) ≠ 0 := by rcases b with (_ \| _ \| b) · cases m · cases hm rfl · simp · cases m · cases hm rfl rename ℕ => m simp only [zero_add, digits_one, List.getLast_replicate_succ m 1] exact Nat.one_ne_zero revert hm induction m using Nat.strongRecOn with \| ind n IH => ?_ intro hn by_cases hnb : n < b + 2 · simpa only [digits_of_lt (b + 2) n hn hnb] · rw [digits_getLast n (le_add_left 2 b)] refine IH _ (Nat.div_lt_self hn.bot_lt (one_lt_succ_succ b)) ?_ rw [← pos_iff_ne_zero] exact Nat.div_pos (le_of_not_lt hnb) (zero_lt_succ (succ b)) theorem mul_ofDigits (n : ℕ) {b : ℕ} {l : List ℕ} : n ofDigits b l = ofDigits b (l.map (n * ·)) := by induction l with \| nil => rfl \| cons hd tl ih => rw [List.map_cons, ofDigits_cons, ofDigits_cons, ← ih] ring lemma ofDigits_inj_of_len_eq {b : ℕ} (hb : 1 < b) {L1 L2 : List ℕ} (len : L1.length = L2.length) (w1 : ∀ l ∈ L1, l < b) (w2 : ∀ l ∈ L2, l < b) (h : ofDigits b L1 = ofDigits b L2) : L1 = L2 := by induction' L1 with D L ih generalizing L2 · simp only [List.length_nil] at len exact (List.length_eq_zero_iff.mp len.symm).symm obtain ⟨d, l, rfl⟩ := List.exists_cons_of_length_eq_add_one len.symm simp only [List.length_cons, add_left_inj] at len simp only [ofDigits_cons] at h have eqd : D = d := by have H : (D + b * ofDigits b L) % b = (d + b * ofDigits b l) % b := by rw [h] simpa [mod_eq_of_lt (w2 d List.mem_cons_self), mod_eq_of_lt (w1 D List.mem_cons_self)] using H simp only [eqd, add_right_inj, mul_left_cancel_iff_of_pos (zero_lt_of_lt hb)] at h have := ih len (fun a ha ↦ w1 a <\| List.mem_cons_of_mem D ha) (fun a ha ↦ w2 a <\| List.mem_cons_of_mem d ha) h rw [eqd, this] /-- The addition of ofDigits of two lists is equal to ofDigits of digit-wise addition of them -/ theorem ofDigits_add_ofDigits_eq_ofDigits_zipWith_of_length_eq {b : ℕ} {l1 l2 : List ℕ} (h : l1.length = l2.length) : ofDigits b l1 + ofDigits b l2 = ofDigits b (l1.zipWith (· + ·) l2) := by induction l1 generalizing l2 with \| nil => simp_all [eq_comm, List.length_eq_zero_iff, ofDigits] \| cons hd₁ tl₁ ih₁ => induction l2 generalizing tl₁ with \| nil => simp_all \| cons hd₂ tl₂ ih₂ => simp_all only [List.length_cons, succ_eq_add_one, ofDigits_cons, add_left_inj, eq_comm, List.zipWith_cons_cons, add_eq] rw [← ih₁ h.symm, mul_add] ac_rfl /-- The digits in the base b+2 expansion of n are all less than b+2 -/ theorem digits_lt_base' {b m : ℕ} : ∀ {d}, d ∈ digits (b + 2) m → d < b + 2 := by induction m using Nat.strongRecOn with \| ind n IH => ?_ intro d hd rcases n with - \| n · rw [digits_zero] at hd cases hd -- base b+2 expansion of 0 has no digits rw [digits_add_two_add_one] at hd cases hd · exact n.succ.mod_lt (by linarith) · apply IH ((n + 1) / (b + 2)) · apply Nat.div_lt_self <;> omega · assumption /-- The digits in the base b expansion of n are all less than b, if b ≥ 2 -/ theorem digits_lt_base {b m d : ℕ} (hb : 1 < b) (hd : d ∈ digits b m) : d < b := by rcases b with (_ \| _ \| b) <;> try simp_all exact digits_lt_base' hd /-- an n-digit number in base b + 2 is less than (b + 2)^n -/ theorem ofDigits_lt_base_pow_length' {b : ℕ} {l : List ℕ} (hl : ∀ x ∈ l, x < b + 2) : ofDigits (b + 2) l < (b + 2) ^ l.length := by induction' l with hd tl IH · simp [ofDigits] · rw [ofDigits, List.length_cons, pow_succ] have : (ofDigits (b + 2) tl + 1) * (b + 2) ≤ (b + 2) ^ tl.length * (b + 2) := mul_le_mul (IH fun x hx => hl _ (List.mem_cons_of_mem _ hx)) (by rfl) (by simp only [zero_le]) (Nat.zero_le _) suffices ↑hd < b + 2 by linarith exact hl hd List.mem_cons_self /-- an n-digit number in base b is less than b^n if b > 1 -/ theorem ofDigits_lt_base_pow_length {b : ℕ} {l : List ℕ} (hb : 1 < b) (hl : ∀ x ∈ l, x < b) : ofDigits b l < b ^ l.length := by rcases b with (_ \| _ \| b) <;> try simp_all exact ofDigits_lt_base_pow_length' hl /-- Any number m is less than (b+2)^(number of digits in the base b + 2 representation of m) -/ theorem lt_base_pow_length_digits' {b m : ℕ} : m < (b + 2) ^ (digits (b + 2) m).length := by convert @ofDigits_lt_base_pow_length' b (digits (b + 2) m) fun _ => digits_lt_base' rw [ofDigits_digits (b + 2) m] /-- Any number m is less than b^(number of digits in the base b representation of m) -/ theorem lt_base_pow_length_digits {b m : ℕ} (hb : 1 < b) : m < b ^ (digits b m).length := by rcases b with (_ \| _ \| b) <;> try simp_all exact lt_base_pow_length_digits' theorem digits_base_pow_mul {b k m : ℕ} (hb : 1 < b) (hm : 0 < m) : digits b (b ^ k * m) = List.replicate k 0 ++ digits b m := by induction k generalizing m with \| zero => simp \| succ k ih => have hmb : 0 < m * b := lt_mul_of_lt_of_one_lt' hm hb let h1 := digits_def' hb hmb have h2 : m = m * b / b := Nat.eq_div_of_mul_eq_left (ne_zero_of_lt hb) rfl simp only [mul_mod_left, ← h2] at h1 rw [List.replicate_succ', List.append_assoc, List.singleton_append, ← h1, ← ih hmb] ring_nf theorem ofDigits_digits_append_digits {b m n : ℕ} : ofDigits b (digits b n ++ digits b m) = n + b ^ (digits b n).length * m := by rw [ofDigits_append, ofDigits_digits, ofDigits_digits] theorem digits_append_digits {b m n : ℕ} (hb : 0 < b) : digits b n ++ digits b m = digits b (n + b ^ (digits b n).length * m) := by rcases eq_or_lt_of_le (Nat.succ_le_of_lt hb) with (rfl \| hb) · simp rw [← ofDigits_digits_append_digits] refine (digits_ofDigits b hb _ (fun l hl => ?_) (fun h_append => ?_)).symm · rcases (List.mem_append.mp hl) with (h \| h) <;> exact digits_lt_base hb h · by_cases h : digits b m = [] · simp only [h, List.append_nil] at h_append ⊢ exact getLast_digit_ne_zero b <\| digits_ne_nil_iff_ne_zero.mp h_append · exact (List.getLast_append_of_right_ne_nil _ _ h) ▸ (getLast_digit_ne_zero _ <\| digits_ne_nil_iff_ne_zero.mp h) theorem digits_append_zeroes_append_digits {b k m n : ℕ} (hb : 1 < b) (hm : 0 < m) : digits b n ++ List.replicate k 0 ++ digits b m = digits b (n + b ^ ((digits b n).length + k) * m) := by rw [List.append_assoc, ← digits_base_pow_mul hb hm] simp only [digits_append_digits (zero_lt_of_lt hb), digits_inj_iff, add_right_inj] ring theorem digits_len_le_digits_len_succ (b n : ℕ) : (digits b n).length ≤ (digits b (n + 1)).length := by rcases Decidable.eq_or_ne n 0 with (rfl \| hn) · simp rcases le_or_lt b 1 with hb \| hb · interval_cases b <;> simp +arith [digits_zero_succ', hn] simpa [digits_len, hb, hn] using log_mono_right (le_succ _) theorem le_digits_len_le (b n m : ℕ) (h : n ≤ m) : (digits b n).length ≤ (digits b m).length := monotone_nat_of_le_succ (digits_len_le_digits_len_succ b) h @[mono] theorem ofDigits_monotone {p q : ℕ} (L : List ℕ) (h : p ≤ q) : ofDigits p L ≤ ofDigits q L := by induction L with \| nil => rfl \| cons _ _ hi => simp only [ofDigits, cast_id, add_le_add_iff_left] exact Nat.mul_le_mul h hi theorem sum_le_ofDigits {p : ℕ} (L : List ℕ) (h : 1 ≤ p) : L.sum ≤ ofDigits p L := (ofDigits_one L).symm ▸ ofDigits_monotone L h theorem digit_sum_le (p n : ℕ) : List.sum (digits p n) ≤ n := by induction' n with n · exact digits_zero _ ▸ Nat.le_refl (List.sum []) · induction' p with p · rw [digits_zero_succ, List.sum_cons, List.sum_nil, add_zero] · nth_rw 2 [← ofDigits_digits p.succ (n + 1)] rw [← ofDigits_one <\| digits p.succ n.succ] exact ofDigits_monotone (digits p.succ n.succ) <\| Nat.succ_pos p theorem pow_length_le_mul_ofDigits {b : ℕ} {l : List ℕ} (hl : l ≠ []) (hl2 : l.getLast hl ≠ 0) : (b + 2) ^ l.length ≤ (b + 2) * ofDigits (b + 2) l := by rw [← List.dropLast_append_getLast hl] simp only [List.length_append, List.length, zero_add, List.length_dropLast, ofDigits_append, List.length_dropLast, ofDigits_singleton, add_comm (l.length - 1), pow_add, pow_one] apply Nat.mul_le_mul_left refine le_trans ?_ (Nat.le_add_left _ _) have : 0 < l.getLast hl := by rwa [pos_iff_ne_zero] convert Nat.mul_le_mul_left ((b + 2) ^ (l.length - 1)) this using 1 rw [Nat.mul_one] /-- Any non-zero natural number `m` is greater than (b+2)^((number of digits in the base (b+2) representation of m) - 1) -/ theorem base_pow_length_digits_le' (b m : ℕ) (hm : m ≠ 0) : (b + 2) ^ (digits (b + 2) m).length ≤ (b + 2) * m := by have : digits (b + 2) m ≠ [] := digits_ne_nil_iff_ne_zero.mpr hm convert @pow_length_le_mul_ofDigits b (digits (b+2) m) this (getLast_digit_ne_zero _ hm) rw [ofDigits_digits] /-- Any non-zero natural number `m` is greater than b^((number of digits in the base b representation of m) - 1) -/ theorem base_pow_length_digits_le (b m : ℕ) (hb : 1 < b) : m ≠ 0 → b ^ (digits b m).length ≤ b * m := by rcases b with (_ \| _ \| b) <;> try simp_all exact base_pow_length_digits_le' b m /-- Interpreting as a base `p` number and dividing by `p` is the same as interpreting the tail. -/ lemma ofDigits_div_eq_ofDigits_tail {p : ℕ} (hpos : 0 < p) (digits : List ℕ) (w₁ : ∀ l ∈ digits, l < p) : ofDigits p digits / p = ofDigits p digits.tail := by induction' digits with hd tl · simp [ofDigits] · refine Eq.trans (add_mul_div_left hd _ hpos) ?_ rw [Nat.div_eq_of_lt <\| w₁ _ List.mem_cons_self, zero_add] rfl /-- Interpreting as a base `p` number and dividing by `p^i` is the same as dropping `i`. -/ lemma ofDigits_div_pow_eq_ofDigits_drop {p : ℕ} (i : ℕ) (hpos : 0 < p) (digits : List ℕ) (w₁ : ∀ l ∈ digits, l < p) : ofDigits p digits / p ^ i = ofDigits p (digits.drop i) := by induction' i with i hi · simp · rw [Nat.pow_succ, ← Nat.div_div_eq_div_mul, hi, ofDigits_div_eq_ofDigits_tail hpos (List.drop i digits) fun x hx ↦ w₁ x <\| List.mem_of_mem_drop hx, ← List.drop_one, List.drop_drop, add_comm] /-- Dividing `n` by `p^i` is like truncating the first `i` digits of `n` in base `p`. -/ lemma self_div_pow_eq_ofDigits_drop {p : ℕ} (i n : ℕ) (h : 2 ≤ p) : n / p ^ i = ofDigits p ((p.digits n).drop i) := by convert ofDigits_div_pow_eq_ofDigits_drop i (zero_lt_of_lt h) (p.digits n) (fun l hl ↦ digits_lt_base h hl) exact (ofDigits_digits p n).symm open Finset theorem sub_one_mul_sum_div_pow_eq_sub_sum_digits {p : ℕ} (L : List ℕ) {h_nonempty} (h_ne_zero : L.getLast h_nonempty ≠ 0) (h_lt : ∀ l ∈ L, l < p) : (p - 1) * ∑ i ∈ range L.length, (ofDigits p L) / p ^ i.succ = (ofDigits p L) - L.sum := by obtain h \| rfl \| h : 1 < p ∨ 1 = p ∨ p < 1 := trichotomous 1 p · induction' L with hd tl ih · simp [ofDigits] · simp only [List.length_cons, List.sum_cons, self_div_pow_eq_ofDigits_drop _ _ h, digits_ofDigits p h (hd :: tl) h_lt (fun _ => h_ne_zero)] simp only [ofDigits] rw [sum_range_succ, Nat.cast_id] simp only [List.drop, List.drop_length] obtain rfl \| h' := em <\| tl = [] · simp [ofDigits] · have w₁' := fun l hl ↦ h_lt l <\| List.mem_cons_of_mem hd hl have w₂' := fun (h : tl ≠ []) ↦ (List.getLast_cons h) ▸ h_ne_zero have ih := ih (w₂' h') w₁' simp only [self_div_pow_eq_ofDigits_drop _ _ h, digits_ofDigits p h tl w₁' w₂', ← Nat.one_add] at ih have := sum_singleton (fun x ↦ ofDigits p <\| tl.drop x) tl.length rw [← Ico_succ_singleton, List.drop_length, ofDigits] at this have h₁ : 1 ≤ tl.length := List.length_pos_iff.mpr h' rw [← sum_range_add_sum_Ico _ <\| h₁, ← add_zero (∑ x ∈ Ico _ _, ofDigits p (tl.drop x)), ← this, sum_Ico_consecutive _ h₁ <\| (le_add_right tl.length 1), ← sum_Ico_add _ 0 tl.length 1, Ico_zero_eq_range, mul_add, mul_add, ih, range_one, sum_singleton, List.drop, ofDigits, mul_zero, add_zero, ← Nat.add_sub_assoc <\| sum_le_ofDigits _ <\| Nat.le_of_lt h] nth_rw 2 [← one_mul <\| ofDigits p tl] rw [← add_mul, Nat.sub_add_cancel (one_le_of_lt h), Nat.add_sub_add_left] · simp [ofDigits_one] · simp [lt_one_iff.mp h] cases L · rfl · simp [ofDigits] theorem sub_one_mul_sum_log_div_pow_eq_sub_sum_digits {p : ℕ} (n : ℕ) : (p - 1) * ∑ i ∈ range (log p n).succ, n / p ^ i.succ = n - (p.digits n).sum := by obtain h \| rfl \| h : 1 < p ∨ 1 = p ∨ p < 1 := trichotomous 1 p · rcases eq_or_ne n 0 with rfl \| hn · simp · convert sub_one_mul_sum_div_pow_eq_sub_sum_digits (p.digits n) (getLast_digit_ne_zero p hn) <\| (fun l a ↦ digits_lt_base h a) · refine (digits_len p n h hn).symm all_goals exact (ofDigits_digits p n).symm · simp · simp [lt_one_iff.mp h] cases n all_goals simp /-! ### Binary -/ theorem digits_two_eq_bits (n : ℕ) : digits 2 n = n.bits.map fun b => cond b 1 0 := by induction' n using Nat.binaryRecFromOne with b n h ih · simp · simp rw [bits_append_bit _ _ fun hn => absurd hn h] cases b · rw [digits_def' one_lt_two] · simpa [Nat.bit] · simpa [Nat.bit, pos_iff_ne_zero] · simpa [Nat.bit, add_comm, digits_add 2 one_lt_two 1 n, Nat.add_mul_div_left] /-! ### Modular Arithmetic -/ -- This is really a theorem about polynomials. theorem dvd_ofDigits_sub_ofDigits {α : Type} [CommRing α] {a b k : α} (h : k ∣ a - b) (L : List ℕ) : k ∣ ofDigits a L - ofDigits b L := by induction' L with d L ih · change k ∣ 0 - 0 simp · simp only [ofDigits, add_sub_add_left_eq_sub] exact dvd_mul_sub_mul h ih theorem ofDigits_modEq' (b b' : ℕ) (k : ℕ) (h : b ≡ b' [MOD k]) (L : List ℕ) : ofDigits b L ≡ ofDigits b' L [MOD k] := by induction' L with d L ih · rfl · dsimp [ofDigits] dsimp [Nat.ModEq] at conv_lhs => rw [Nat.add_mod, Nat.mul_mod, h, ih] conv_rhs => rw [Nat.add_mod, Nat.mul_mod] theorem ofDigits_modEq (b k : ℕ) (L : List ℕ) : ofDigits b L ≡ ofDigits (b % k) L [MOD k] := ofDigits_modEq' b (b % k) k (b.mod_modEq k).symm L theorem ofDigits_mod (b k : ℕ) (L : List ℕ) : ofDigits b L % k = ofDigits (b % k) L % k := ofDigits_modEq b k L theorem ofDigits_mod_eq_head! (b : ℕ) (l : List ℕ) : ofDigits b l % b = l.head! % b := by induction l <;> simp [Nat.ofDigits, Int.ModEq] theorem head!_digits {b n : ℕ} (h : b ≠ 1) : (Nat.digits b n).head! = n % b := by by_cases hb : 1 < b · rcases n with _ \| n · simp · nth_rw 2 [← Nat.ofDigits_digits b (n + 1)] rw [Nat.ofDigits_mod_eq_head! _ _] exact (Nat.mod_eq_of_lt (Nat.digits_lt_base hb <\| List.head!_mem_self <\| Nat.digits_ne_nil_iff_ne_zero.mpr <\| Nat.succ_ne_zero n)).symm · rcases n with _ \| _ <;> simp_all [show b = 0 by omega] theorem ofDigits_zmodeq' (b b' : ℤ) (k : ℕ) (h : b ≡ b' [ZMOD k]) (L : List ℕ) : ofDigits b L ≡ ofDigits b' L [ZMOD k] := by induction' L with d L ih · rfl · dsimp [ofDigits] dsimp [Int.ModEq] at * conv_lhs => rw [Int.add_emod, Int.mul_emod, h, ih] conv_rhs => rw [Int.add_emod, Int.mul_emod] theorem ofDigits_zmodeq (b : ℤ) (k : ℕ) (L : List ℕ) : ofDigits b L ≡ ofDigits (b % k) L [ZMOD k] := ofDigits_zmodeq' b (b % k) k (b.mod_modEq ↑k).symm L theorem ofDigits_zmod (b : ℤ) (k : ℕ) (L : List ℕ) : ofDigits b L % k = ofDigits (b % k) L % k := ofDigits_zmodeq b k L theorem modEq_digits_sum (b b' : ℕ) (h : b' % b = 1) (n : ℕ) : n ≡ (digits b' n).sum [MOD b] := by rw [← ofDigits_one] conv => congr · skip · rw [← ofDigits_digits b' n] convert ofDigits_modEq b' b (digits b' n) exact h.symm theorem modEq_three_digits_sum (n : ℕ) : n ≡ (digits 10 n).sum [MOD 3] := modEq_digits_sum 3 10 (by norm_num) n theorem modEq_nine_digits_sum (n : ℕ) : n ≡ (digits 10 n).sum [MOD 9] := modEq_digits_sum 9 10 (by norm_num) n theorem zmodeq_ofDigits_digits (b b' : ℕ) (c : ℤ) (h : b' ≡ c [ZMOD b]) (n : ℕ) : n ≡ ofDigits c (digits b' n) [ZMOD b] := by conv => congr · skip · rw [← ofDigits_digits b' n] rw [coe_int_ofDigits] apply ofDigits_zmodeq' _ _ _ h theorem ofDigits_neg_one : ∀ L : List ℕ, ofDigits (-1 : ℤ) L = (L.map fun n : ℕ => (n : ℤ)).alternatingSum \| [] => rfl \| [n] => by simp [ofDigits, List.alternatingSum] \| a :: b :: t => by simp only [ofDigits, List.alternatingSum, List.map_cons, ofDigits_neg_one t] ring theorem modEq_eleven_digits_sum (n : ℕ) : n ≡ ((digits 10 n).map fun n : ℕ => (n : ℤ)).alternatingSum [ZMOD 11] := by have t := zmodeq_ofDigits_digits 11 10 (-1 : ℤ) (by unfold Int.ModEq; rfl) n rwa [ofDigits_neg_one] at t /-! ## Divisibility -/ theorem dvd_iff_dvd_digits_sum (b b' : ℕ) (h : b' % b = 1) (n : ℕ) : b ∣ n ↔ b ∣ (digits b' n).sum := by rw [← ofDigits_one] conv_lhs => rw [← ofDigits_digits b' n] rw [Nat.dvd_iff_mod_eq_zero, Nat.dvd_iff_mod_eq_zero, ofDigits_mod, h] /-- Divisibility by 3 Rule -/ theorem three_dvd_iff (n : ℕ) : 3 ∣ n ↔ 3 ∣ (digits 10 n).sum := dvd_iff_dvd_digits_sum 3 10 (by norm_num) n theorem nine_dvd_iff (n : ℕ) : 9 ∣ n ↔ 9 ∣ (digits 10 n).sum := dvd_iff_dvd_digits_sum 9 10 (by norm_num) n theorem dvd_iff_dvd_ofDigits (b b' : ℕ) (c : ℤ) (h : (b : ℤ) ∣ (b' : ℤ) - c) (n : ℕ) : b ∣ n ↔ (b : ℤ) ∣ ofDigits c (digits b' n) := by rw [← Int.natCast_dvd_natCast] exact dvd_iff_dvd_of_dvd_sub (zmodeq_ofDigits_digits b b' c (Int.modEq_iff_dvd.2 h).symm _).symm.dvd theorem eleven_dvd_iff : 11 ∣ n ↔ (11 : ℤ) ∣ ((digits 10 n).map fun n : ℕ => (n : ℤ)).alternatingSum := by have t := dvd_iff_dvd_ofDigits 11 10 (-1 : ℤ) (by norm_num) n rw [ofDigits_neg_one] at t exact t theorem eleven_dvd_of_palindrome (p : (digits 10 n).Palindrome) (h : Even (digits 10 n).length) : 11 ∣ n := by let dig := (digits 10 n).map fun n : ℕ => (n : ℤ) replace h : Even dig.length := by rwa [List.length_map] refine eleven_dvd_iff.2 ⟨0, (?_ : dig.alternatingSum = 0)⟩ have := dig.alternatingSum_reverse rw [(p.map _).reverse_eq, _root_.pow_succ', h.neg_one_pow, mul_one, neg_one_zsmul] at this exact eq_zero_of_neg_eq this.symm /-! ### `Nat.toDigits` length -/ lemma toDigitsCore_lens_eq_aux (b f : Nat) : ∀ (n : Nat) (l1 l2 : List Char), l1.length = l2.length → (Nat.toDigitsCore b f n l1).length = (Nat.toDigitsCore b f n l2).length := by induction f with (simp only [Nat.toDigitsCore, List.length]; intro n l1 l2 hlen) \| zero => assumption \| succ f ih => if hx : n / b = 0 then simp only [hx, if_true, List.length, congrArg (fun l ↦ l + 1) hlen] else simp only [hx, if_false] specialize ih (n / b) (Nat.digitChar (n % b) :: l1) (Nat.digitChar (n % b) :: l2) simp only [List.length, congrArg (fun l ↦ l + 1) hlen] at ih exact ih trivial	lemma toDigitsCore_lens_eq (b f : Nat) : ∀ (n : Nat) (c : Char) (tl : List Char), (Nat.toDigitsCore b f n (c :: tl)).length = (Nat.toDigitsCore b f n tl).length + 1 := by induction f with (intro n c tl; simp only [Nat.toDigitsCore, List.length]) \| succ f ih => if hnb : (n / b) = 0 then	Mathlib/Data/Nat/Digits.lean	759	763
/- Copyright (c) 2020 Simon Hudon. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Simon Hudon, Ira Fesefeldt -/ import Mathlib.Control.Monad.Basic import Mathlib.Dynamics.FixedPoints.Basic import Mathlib.Order.CompleteLattice.Basic import Mathlib.Order.Iterate import Mathlib.Order.Part import Mathlib.Order.Preorder.Chain import Mathlib.Order.ScottContinuity /-! # Omega Complete Partial Orders An omega-complete partial order is a partial order with a supremum operation on increasing sequences indexed by natural numbers (which we call `ωSup`). In this sense, it is strictly weaker than join complete semi-lattices as only ω-sized totally ordered sets have a supremum. The concept of an omega-complete partial order (ωCPO) is useful for the formalization of the semantics of programming languages. Its notion of supremum helps define the meaning of recursive procedures. ## Main definitions * class `OmegaCompletePartialOrder` * `ite`, `map`, `bind`, `seq` as continuous morphisms ## Instances of `OmegaCompletePartialOrder` * `Part` * every `CompleteLattice` * pi-types * product types * `OrderHom` * `ContinuousHom` (with notation →𝒄) * an instance of `OmegaCompletePartialOrder (α →𝒄 β)` * `ContinuousHom.ofFun` * `ContinuousHom.ofMono` * continuous functions: * `id` * `ite` * `const` * `Part.bind` * `Part.map` * `Part.seq` ## References * [Chain-complete posets and directed sets with applications][markowsky1976] * [Recursive definitions of partial functions and their computations][cadiou1972] * [Semantics of Programming Languages: Structures and Techniques][gunter1992] -/ assert_not_exists OrderedCommMonoid universe u v variable {ι : Sort} {α β γ δ : Type} namespace OmegaCompletePartialOrder /-- A chain is a monotone sequence. See the definition on page 114 of [gunter1992]. -/ def Chain (α : Type u) [Preorder α] := ℕ →o α namespace Chain variable [Preorder α] [Preorder β] [Preorder γ] instance : FunLike (Chain α) ℕ α := inferInstanceAs <\| FunLike (ℕ →o α) ℕ α instance : OrderHomClass (Chain α) ℕ α := inferInstanceAs <\| OrderHomClass (ℕ →o α) ℕ α instance [Inhabited α] : Inhabited (Chain α) := ⟨⟨default, fun _ _ _ => le_rfl⟩⟩ instance : Membership α (Chain α) := ⟨fun (c : ℕ →o α) a => ∃ i, a = c i⟩ variable (c c' : Chain α) variable (f : α →o β) variable (g : β →o γ) instance : LE (Chain α) where le x y := ∀ i, ∃ j, x i ≤ y j lemma isChain_range : IsChain (· ≤ ·) (Set.range c) := Monotone.isChain_range (OrderHomClass.mono c) lemma directed : Directed (· ≤ ·) c := directedOn_range.2 c.isChain_range.directedOn /-- `map` function for `Chain` -/ -- Porting note: `simps` doesn't work with type synonyms -- @[simps! -fullyApplied] def map : Chain β := f.comp c @[simp] theorem map_coe : ⇑(map c f) = f ∘ c := rfl variable {f} theorem mem_map (x : α) : x ∈ c → f x ∈ Chain.map c f := fun ⟨i, h⟩ => ⟨i, h.symm ▸ rfl⟩ theorem exists_of_mem_map {b : β} : b ∈ c.map f → ∃ a, a ∈ c ∧ f a = b := fun ⟨i, h⟩ => ⟨c i, ⟨i, rfl⟩, h.symm⟩ @[simp] theorem mem_map_iff {b : β} : b ∈ c.map f ↔ ∃ a, a ∈ c ∧ f a = b := ⟨exists_of_mem_map _, fun h => by rcases h with ⟨w, h, h'⟩ subst b apply mem_map c _ h⟩ @[simp] theorem map_id : c.map OrderHom.id = c := OrderHom.comp_id _ theorem map_comp : (c.map f).map g = c.map (g.comp f) := rfl @[mono] theorem map_le_map {g : α →o β} (h : f ≤ g) : c.map f ≤ c.map g := fun i => by simp only [map_coe, Function.comp_apply]; exists i; apply h /-- `OmegaCompletePartialOrder.Chain.zip` pairs up the elements of two chains that have the same index. -/ -- Porting note: `simps` doesn't work with type synonyms -- @[simps!] def zip (c₀ : Chain α) (c₁ : Chain β) : Chain (α × β) := OrderHom.prod c₀ c₁ @[simp] theorem zip_coe (c₀ : Chain α) (c₁ : Chain β) (n : ℕ) : c₀.zip c₁ n = (c₀ n, c₁ n) := rfl /-- An example of a `Chain` constructed from an ordered pair. -/ def pair (a b : α) (hab : a ≤ b) : Chain α where toFun \| 0 => a \| _ => b monotone' _ _ _ := by aesop @[simp] lemma pair_zero (a b : α) (hab) : pair a b hab 0 = a := rfl @[simp] lemma pair_succ (a b : α) (hab) (n : ℕ) : pair a b hab (n + 1) = b := rfl @[simp] lemma range_pair (a b : α) (hab) : Set.range (pair a b hab) = {a, b} := by ext; exact Nat.or_exists_add_one.symm.trans (by aesop) @[simp] lemma pair_zip_pair (a₁ a₂ : α) (b₁ b₂ : β) (ha hb) : (pair a₁ a₂ ha).zip (pair b₁ b₂ hb) = pair (a₁, b₁) (a₂, b₂) (Prod.le_def.2 ⟨ha, hb⟩) := by unfold Chain; ext n : 2; cases n <;> rfl end Chain end OmegaCompletePartialOrder open OmegaCompletePartialOrder /-- An omega-complete partial order is a partial order with a supremum operation on increasing sequences indexed by natural numbers (which we call `ωSup`). In this sense, it is strictly weaker than join complete semi-lattices as only ω-sized totally ordered sets have a supremum. See the definition on page 114 of [gunter1992]. -/ class OmegaCompletePartialOrder (α : Type) extends PartialOrder α where /-- The supremum of an increasing sequence -/ ωSup : Chain α → α /-- `ωSup` is an upper bound of the increasing sequence -/ le_ωSup : ∀ c : Chain α, ∀ i, c i ≤ ωSup c /-- `ωSup` is a lower bound of the set of upper bounds of the increasing sequence -/ ωSup_le : ∀ (c : Chain α) (x), (∀ i, c i ≤ x) → ωSup c ≤ x namespace OmegaCompletePartialOrder variable [OmegaCompletePartialOrder α] /-- Transfer an `OmegaCompletePartialOrder` on `β` to an `OmegaCompletePartialOrder` on `α` using a strictly monotone function `f : β →o α`, a definition of ωSup and a proof that `f` is continuous with regard to the provided `ωSup` and the ωCPO on `α`. -/ protected abbrev lift [PartialOrder β] (f : β →o α) (ωSup₀ : Chain β → β) (h : ∀ x y, f x ≤ f y → x ≤ y) (h' : ∀ c, f (ωSup₀ c) = ωSup (c.map f)) : OmegaCompletePartialOrder β where ωSup := ωSup₀ ωSup_le c x hx := h _ _ (by rw [h']; apply ωSup_le; intro i; apply f.monotone (hx i)) le_ωSup c i := h _ _ (by rw [h']; apply le_ωSup (c.map f)) theorem le_ωSup_of_le {c : Chain α} {x : α} (i : ℕ) (h : x ≤ c i) : x ≤ ωSup c := le_trans h (le_ωSup c _) theorem ωSup_total {c : Chain α} {x : α} (h : ∀ i, c i ≤ x ∨ x ≤ c i) : ωSup c ≤ x ∨ x ≤ ωSup c := by_cases (fun (this : ∀ i, c i ≤ x) => Or.inl (ωSup_le _ _ this)) (fun (this : ¬∀ i, c i ≤ x) => have : ∃ i, ¬c i ≤ x := by simp only [not_forall] at this ⊢; assumption let ⟨i, hx⟩ := this have : x ≤ c i := (h i).resolve_left hx Or.inr <\| le_ωSup_of_le _ this) @[mono] theorem ωSup_le_ωSup_of_le {c₀ c₁ : Chain α} (h : c₀ ≤ c₁) : ωSup c₀ ≤ ωSup c₁ := (ωSup_le _ _) fun i => by obtain ⟨_, h⟩ := h i exact le_trans h (le_ωSup _ _) @[simp] theorem ωSup_le_iff {c : Chain α} {x : α} : ωSup c ≤ x ↔ ∀ i, c i ≤ x := by constructor <;> intros · trans ωSup c · exact le_ωSup _ _ · assumption exact ωSup_le _ _ ‹_› lemma isLUB_range_ωSup (c : Chain α) : IsLUB (Set.range c) (ωSup c) := by constructor · simp only [upperBounds, Set.mem_range, forall_exists_index, forall_apply_eq_imp_iff, Set.mem_setOf_eq] exact fun a ↦ le_ωSup c a · simp only [lowerBounds, upperBounds, Set.mem_range, forall_exists_index, forall_apply_eq_imp_iff, Set.mem_setOf_eq] exact fun ⦃a⦄ a_1 ↦ ωSup_le c a a_1 lemma ωSup_eq_of_isLUB {c : Chain α} {a : α} (h : IsLUB (Set.range c) a) : a = ωSup c := by rw [le_antisymm_iff] simp only [IsLUB, IsLeast, upperBounds, lowerBounds, Set.mem_range, forall_exists_index, forall_apply_eq_imp_iff, Set.mem_setOf_eq] at h constructor · apply h.2 exact fun a ↦ le_ωSup c a · rw [ωSup_le_iff] apply h.1 /-- A subset `p : α → Prop` of the type closed under `ωSup` induces an `OmegaCompletePartialOrder` on the subtype `{a : α // p a}`. -/ def subtype {α : Type} [OmegaCompletePartialOrder α] (p : α → Prop) (hp : ∀ c : Chain α, (∀ i ∈ c, p i) → p (ωSup c)) : OmegaCompletePartialOrder (Subtype p) := OmegaCompletePartialOrder.lift (OrderHom.Subtype.val p) (fun c => ⟨ωSup _, hp (c.map (OrderHom.Subtype.val p)) fun _ ⟨n, q⟩ => q.symm ▸ (c n).2⟩) (fun _ _ h => h) (fun _ => rfl) section Continuity open Chain variable [OmegaCompletePartialOrder β] variable [OmegaCompletePartialOrder γ] variable {f : α → β} {g : β → γ} /-- A function `f` between `ω`-complete partial orders is `ωScottContinuous` if it is Scott continuous over chains. -/ def ωScottContinuous (f : α → β) : Prop := ScottContinuousOn (Set.range fun c : Chain α => Set.range c) f lemma _root_.ScottContinuous.ωScottContinuous (hf : ScottContinuous f) : ωScottContinuous f := hf.scottContinuousOn lemma ωScottContinuous.monotone (h : ωScottContinuous f) : Monotone f := ScottContinuousOn.monotone _ (fun a b hab => by use pair a b hab; exact range_pair a b hab) h lemma ωScottContinuous.isLUB {c : Chain α} (hf : ωScottContinuous f) : IsLUB (Set.range (c.map ⟨f, hf.monotone⟩)) (f (ωSup c)) := by simpa [map_coe, OrderHom.coe_mk, Set.range_comp] using hf (by simp) (Set.range_nonempty _) (isChain_range c).directedOn (isLUB_range_ωSup c) lemma ωScottContinuous.id : ωScottContinuous (id : α → α) := ScottContinuousOn.id lemma ωScottContinuous.map_ωSup (hf : ωScottContinuous f) (c : Chain α) : f (ωSup c) = ωSup (c.map ⟨f, hf.monotone⟩) := ωSup_eq_of_isLUB hf.isLUB /-- `ωScottContinuous f` asserts that `f` is both monotone and distributes over ωSup. -/ lemma ωScottContinuous_iff_monotone_map_ωSup : ωScottContinuous f ↔ ∃ hf : Monotone f, ∀ c : Chain α, f (ωSup c) = ωSup (c.map ⟨f, hf⟩) := by refine ⟨fun hf ↦ ⟨hf.monotone, hf.map_ωSup⟩, ?_⟩ intro hf _ ⟨c, hc⟩ _ _ _ hda convert isLUB_range_ωSup (c.map { toFun := f, monotone' := hf.1 }) · rw [map_coe, OrderHom.coe_mk, ← hc, ← (Set.range_comp f ⇑c)] · rw [← hc] at hda rw [← hf.2 c, ωSup_eq_of_isLUB hda] alias ⟨ωScottContinuous.monotone_map_ωSup, ωScottContinuous.of_monotone_map_ωSup⟩ := ωScottContinuous_iff_monotone_map_ωSup /- A monotone function `f : α →o β` is ωScott continuous if and only if it distributes over ωSup. -/ lemma ωScottContinuous_iff_map_ωSup_of_orderHom {f : α →o β} : ωScottContinuous f ↔ ∀ c : Chain α, f (ωSup c) = ωSup (c.map f) := by rw [ωScottContinuous_iff_monotone_map_ωSup] exact exists_prop_of_true f.monotone' alias ⟨ωScottContinuous.map_ωSup_of_orderHom, ωScottContinuous.of_map_ωSup_of_orderHom⟩ := ωScottContinuous_iff_map_ωSup_of_orderHom lemma ωScottContinuous.comp (hg : ωScottContinuous g) (hf : ωScottContinuous f) : ωScottContinuous (g.comp f) := ωScottContinuous.of_monotone_map_ωSup ⟨hg.monotone.comp hf.monotone, by simp [hf.map_ωSup, hg.map_ωSup, map_comp]⟩ lemma ωScottContinuous.const {x : β} : ωScottContinuous (Function.const α x) := by simp [ωScottContinuous, ScottContinuousOn, Set.range_nonempty] end Continuity end OmegaCompletePartialOrder namespace Part open OmegaCompletePartialOrder theorem eq_of_chain {c : Chain (Part α)} {a b : α} (ha : some a ∈ c) (hb : some b ∈ c) : a = b := by obtain ⟨i, ha⟩ := ha; replace ha := ha.symm obtain ⟨j, hb⟩ := hb; replace hb := hb.symm rw [eq_some_iff] at ha hb rcases le_total i j with hij \| hji · have := c.monotone hij _ ha; apply mem_unique this hb · have := c.monotone hji _ hb; apply Eq.symm; apply mem_unique this ha open Classical in /-- The (noncomputable) `ωSup` definition for the `ω`-CPO structure on `Part α`. -/ protected noncomputable def ωSup (c : Chain (Part α)) : Part α := if h : ∃ a, some a ∈ c then some (Classical.choose h) else none theorem ωSup_eq_some {c : Chain (Part α)} {a : α} (h : some a ∈ c) : Part.ωSup c = some a := have : ∃ a, some a ∈ c := ⟨a, h⟩ have a' : some (Classical.choose this) ∈ c := Classical.choose_spec this calc Part.ωSup c = some (Classical.choose this) := dif_pos this _ = some a := congr_arg _ (eq_of_chain a' h) theorem ωSup_eq_none {c : Chain (Part α)} (h : ¬∃ a, some a ∈ c) : Part.ωSup c = none := dif_neg h theorem mem_chain_of_mem_ωSup {c : Chain (Part α)} {a : α} (h : a ∈ Part.ωSup c) : some a ∈ c := by simp only [Part.ωSup] at h; split_ifs at h with h_1 · have h' := Classical.choose_spec h_1 rw [← eq_some_iff] at h rw [← h] exact h' · rcases h with ⟨⟨⟩⟩ noncomputable instance omegaCompletePartialOrder : OmegaCompletePartialOrder (Part α) where ωSup := Part.ωSup le_ωSup c i := by intro x hx rw [← eq_some_iff] at hx ⊢ rw [ωSup_eq_some] rw [← hx] exact ⟨i, rfl⟩ ωSup_le := by rintro c x hx a ha replace ha := mem_chain_of_mem_ωSup ha obtain ⟨i, ha⟩ := ha apply hx i rw [← ha] apply mem_some section Inst theorem mem_ωSup (x : α) (c : Chain (Part α)) : x ∈ ωSup c ↔ some x ∈ c := by simp only [ωSup, Part.ωSup] constructor · split_ifs with h swap · rintro ⟨⟨⟩⟩ intro h' have hh := Classical.choose_spec h simp only [mem_some_iff] at h' subst x exact hh · intro h have h' : ∃ a : α, some a ∈ c := ⟨_, h⟩ rw [dif_pos h'] have hh := Classical.choose_spec h' rw [eq_of_chain hh h] simp end Inst end Part section Pi variable {β : α → Type} open OmegaCompletePartialOrder OmegaCompletePartialOrder.Chain instance [∀ a, OmegaCompletePartialOrder (β a)] : OmegaCompletePartialOrder (∀ a, β a) where ωSup c a := ωSup (c.map (Pi.evalOrderHom a)) ωSup_le _ _ hf a := ωSup_le _ _ <\| by rintro i apply hf le_ωSup _ _ _ := le_ωSup_of_le _ <\| le_rfl namespace OmegaCompletePartialOrder variable [∀ x, OmegaCompletePartialOrder <\| β x] variable [OmegaCompletePartialOrder γ] variable {f : γ → ∀ x, β x} lemma ωScottContinuous.apply₂ (hf : ωScottContinuous f) (a : α) : ωScottContinuous (f · a) := ωScottContinuous.of_monotone_map_ωSup ⟨fun _ _ h ↦ hf.monotone h a, fun c ↦ congr_fun (hf.map_ωSup c) a⟩ lemma ωScottContinuous.of_apply₂ (hf : ∀ a, ωScottContinuous (f · a)) : ωScottContinuous f := ωScottContinuous.of_monotone_map_ωSup ⟨fun _ _ h a ↦ (hf a).monotone h, fun c ↦ by ext a; apply (hf a).map_ωSup c⟩ lemma ωScottContinuous_iff_apply₂ : ωScottContinuous f ↔ ∀ a, ωScottContinuous (f · a) := ⟨ωScottContinuous.apply₂, ωScottContinuous.of_apply₂⟩ end OmegaCompletePartialOrder end Pi namespace Prod open OmegaCompletePartialOrder variable [OmegaCompletePartialOrder α] variable [OmegaCompletePartialOrder β] variable [OmegaCompletePartialOrder γ] /-- The supremum of a chain in the product `ω`-CPO. -/ @[simps] protected def ωSup (c : Chain (α × β)) : α × β := (ωSup (c.map OrderHom.fst), ωSup (c.map OrderHom.snd)) @[simps! ωSup_fst ωSup_snd] instance : OmegaCompletePartialOrder (α × β) where ωSup := Prod.ωSup ωSup_le := fun _ _ h => ⟨ωSup_le _ _ fun i => (h i).1, ωSup_le _ _ fun i => (h i).2⟩ le_ωSup c i := ⟨le_ωSup (c.map OrderHom.fst) i, le_ωSup (c.map OrderHom.snd) i⟩ theorem ωSup_zip (c₀ : Chain α) (c₁ : Chain β) : ωSup (c₀.zip c₁) = (ωSup c₀, ωSup c₁) := by apply eq_of_forall_ge_iff; rintro ⟨z₁, z₂⟩ simp [ωSup_le_iff, forall_and] end Prod open OmegaCompletePartialOrder namespace CompleteLattice -- see Note [lower instance priority] /-- Any complete lattice has an `ω`-CPO structure where the countable supremum is a special case of arbitrary suprema. -/ instance (priority := 100) [CompleteLattice α] : OmegaCompletePartialOrder α where ωSup c := ⨆ i, c i ωSup_le := fun ⟨c, _⟩ s hs => by simp only [iSup_le_iff, OrderHom.coe_mk] at hs ⊢; intro i; apply hs i le_ωSup := fun ⟨c, _⟩ i => by apply le_iSup_of_le i; rfl variable [OmegaCompletePartialOrder α] [CompleteLattice β] {f g : α → β} -- TODO Prove this result for `ScottContinuousOn` and deduce this as a special case -- https://github.com/leanprover-community/mathlib4/pull/15412 open Chain in lemma ωScottContinuous.prodMk (hf : ωScottContinuous f) (hg : ωScottContinuous g) : ωScottContinuous fun x => (f x, g x) := ScottContinuousOn.prodMk (fun a b hab => by use pair a b hab; exact range_pair a b hab) hf hg lemma ωScottContinuous.iSup {f : ι → α → β} (hf : ∀ i, ωScottContinuous (f i)) : ωScottContinuous (⨆ i, f i) := by refine ωScottContinuous.of_monotone_map_ωSup ⟨Monotone.iSup fun i ↦ (hf i).monotone, fun c ↦ eq_of_forall_ge_iff fun a ↦ ?_⟩ simp +contextual [ωSup_le_iff, (hf _).map_ωSup, @forall_swap ι] lemma ωScottContinuous.sSup {s : Set (α → β)} (hs : ∀ f ∈ s, ωScottContinuous f) : ωScottContinuous (sSup s) := by rw [sSup_eq_iSup]; exact ωScottContinuous.iSup fun f ↦ ωScottContinuous.iSup <\| hs f lemma ωScottContinuous.sup (hf : ωScottContinuous f) (hg : ωScottContinuous g) : ωScottContinuous (f ⊔ g) := by rw [← sSup_pair] apply ωScottContinuous.sSup rintro f (rfl \| rfl \| _) <;> assumption lemma ωScottContinuous.top : ωScottContinuous (⊤ : α → β) := ωScottContinuous.of_monotone_map_ωSup ⟨monotone_const, fun c ↦ eq_of_forall_ge_iff fun a ↦ by simp⟩ lemma ωScottContinuous.bot : ωScottContinuous (⊥ : α → β) := by rw [← sSup_empty]; exact ωScottContinuous.sSup (by simp) end CompleteLattice namespace CompleteLattice variable [OmegaCompletePartialOrder α] [CompleteLinearOrder β] {f g : α → β} -- TODO Prove this result for `ScottContinuousOn` and deduce this as a special case -- Also consider if it holds in greater generality (e.g. finite sets) -- N.B. The Scott Topology coincides with the Upper Topology on a Complete Linear Order -- `Topology.IsScott.scott_eq_upper_of_completeLinearOrder` -- We have that the product topology coincides with the upper topology -- https://github.com/leanprover-community/mathlib4/pull/12133 lemma ωScottContinuous.inf (hf : ωScottContinuous f) (hg : ωScottContinuous g) : ωScottContinuous (f ⊓ g) := by refine ωScottContinuous.of_monotone_map_ωSup ⟨hf.monotone.inf hg.monotone, fun c ↦ eq_of_forall_ge_iff fun a ↦ ?_⟩ simp only [Pi.inf_apply, hf.map_ωSup c, hg.map_ωSup c, inf_le_iff, ωSup_le_iff, Chain.map_coe, Function.comp, OrderHom.coe_mk, ← forall_or_left, ← forall_or_right] exact ⟨fun h _ ↦ h _ _, fun h i j ↦ (h (max j i)).imp (le_trans <\| hf.monotone <\| c.mono <\| le_max_left _ _) (le_trans <\| hg.monotone <\| c.mono <\| le_max_right _ _)⟩ end CompleteLattice namespace OmegaCompletePartialOrder variable [OmegaCompletePartialOrder α] [OmegaCompletePartialOrder β] variable [OmegaCompletePartialOrder γ] [OmegaCompletePartialOrder δ] namespace OrderHom /-- The `ωSup` operator for monotone functions. -/ @[simps] protected def ωSup (c : Chain (α →o β)) : α →o β where toFun a := ωSup (c.map (OrderHom.apply a)) monotone' _ _ h := ωSup_le_ωSup_of_le ((Chain.map_le_map _) fun a => a.monotone h) @[simps! ωSup_coe] instance omegaCompletePartialOrder : OmegaCompletePartialOrder (α →o β) := OmegaCompletePartialOrder.lift OrderHom.coeFnHom OrderHom.ωSup (fun _ _ h => h) fun _ => rfl end OrderHom variable (α β) in /-- A monotone function on `ω`-continuous partial orders is said to be continuous if for every chain `c : chain α`, `f (⊔ i, c i) = ⊔ i, f (c i)`. This is just the bundled version of `OrderHom.continuous`. -/ structure ContinuousHom extends OrderHom α β where /-- The underlying function of a `ContinuousHom` is continuous, i.e. it preserves `ωSup` -/ protected map_ωSup' (c : Chain α) : toFun (ωSup c) = ωSup (c.map toOrderHom) attribute [nolint docBlame] ContinuousHom.toOrderHom @[inherit_doc] infixr:25 " →𝒄 " => ContinuousHom -- Input: \r\MIc instance : FunLike (α →𝒄 β) α β where coe f := f.toFun coe_injective' := by rintro ⟨⟩ ⟨⟩ h; congr; exact DFunLike.ext' h instance : OrderHomClass (α →𝒄 β) α β where map_rel f _ _ h := f.mono h instance : PartialOrder (α →𝒄 β) := (PartialOrder.lift fun f => f.toOrderHom.toFun) <\| by rintro ⟨⟨⟩⟩ ⟨⟨⟩⟩ h; congr namespace ContinuousHom protected lemma ωScottContinuous (f : α →𝒄 β) : ωScottContinuous f := ωScottContinuous.of_map_ωSup_of_orderHom f.map_ωSup' -- Not a `simp` lemma because in many cases projection is simpler than a generic coercion theorem toOrderHom_eq_coe (f : α →𝒄 β) : f.1 = f := rfl @[simp] theorem coe_mk (f : α →o β) (hf) : ⇑(mk f hf) = f := rfl @[simp] theorem coe_toOrderHom (f : α →𝒄 β) : ⇑f.1 = f := rfl /-- See Note [custom simps projection]. We specify this explicitly because we don't have a DFunLike instance. -/ def Simps.apply (h : α →𝒄 β) : α → β := h initialize_simps_projections ContinuousHom (toFun → apply) protected theorem congr_fun {f g : α →𝒄 β} (h : f = g) (x : α) : f x = g x := DFunLike.congr_fun h x protected theorem congr_arg (f : α →𝒄 β) {x y : α} (h : x = y) : f x = f y := congr_arg f h protected theorem monotone (f : α →𝒄 β) : Monotone f := f.monotone' @[mono] theorem apply_mono {f g : α →𝒄 β} {x y : α} (h₁ : f ≤ g) (h₂ : x ≤ y) : f x ≤ g y := OrderHom.apply_mono (show (f : α →o β) ≤ g from h₁) h₂ theorem ωSup_bind {β γ : Type v} (c : Chain α) (f : α →o Part β) (g : α →o β → Part γ) : ωSup (c.map (f.partBind g)) = ωSup (c.map f) >>= ωSup (c.map g) := by apply eq_of_forall_ge_iff; intro x simp only [ωSup_le_iff, Part.bind_le, Chain.mem_map_iff, and_imp, OrderHom.partBind_coe, exists_imp] constructor <;> intro h''' · intro b hb apply ωSup_le _ _ _ rintro i y hy simp only [Part.mem_ωSup] at hb rcases hb with ⟨j, hb⟩ replace hb := hb.symm simp only [Part.eq_some_iff, Chain.map_coe, Function.comp_apply, OrderHom.apply_coe] at hy hb replace hb : b ∈ f (c (max i j)) := f.mono (c.mono (le_max_right i j)) _ hb replace hy : y ∈ g (c (max i j)) b := g.mono (c.mono (le_max_left i j)) _ _ hy apply h''' (max i j) simp only [exists_prop, Part.bind_eq_bind, Part.mem_bind_iff, Chain.map_coe, Function.comp_apply, OrderHom.partBind_coe] exact ⟨_, hb, hy⟩ · intro i intro y hy simp only [exists_prop, Part.bind_eq_bind, Part.mem_bind_iff, Chain.map_coe, Function.comp_apply, OrderHom.partBind_coe] at hy rcases hy with ⟨b, hb₀, hb₁⟩ apply h''' b _ · apply le_ωSup (c.map g) _ _ _ hb₁ · apply le_ωSup (c.map f) i _ hb₀ -- TODO: We should move `ωScottContinuous` to the root namespace lemma ωScottContinuous.bind {β γ} {f : α → Part β} {g : α → β → Part γ} (hf : ωScottContinuous f) (hg : ωScottContinuous g) : ωScottContinuous fun x ↦ f x >>= g x := ωScottContinuous.of_monotone_map_ωSup ⟨hf.monotone.partBind hg.monotone, fun c ↦ by rw [hf.map_ωSup, hg.map_ωSup, ← ωSup_bind]; rfl⟩ lemma ωScottContinuous.map {β γ} {f : β → γ} {g : α → Part β} (hg : ωScottContinuous g) : ωScottContinuous fun x ↦ f <$> g x := by simpa only [map_eq_bind_pure_comp] using ωScottContinuous.bind hg ωScottContinuous.const lemma ωScottContinuous.seq {β γ} {f : α → Part (β → γ)} {g : α → Part β} (hf : ωScottContinuous f) (hg : ωScottContinuous g) : ωScottContinuous fun x ↦ f x <> g x := by simp only [seq_eq_bind_map] exact ωScottContinuous.bind hf <\| ωScottContinuous.of_apply₂ fun _ ↦ ωScottContinuous.map hg theorem continuous (F : α →𝒄 β) (C : Chain α) : F (ωSup C) = ωSup (C.map F) := F.ωScottContinuous.map_ωSup _ /-- Construct a continuous function from a bare function, a continuous function, and a proof that they are equal. -/ @[simps!] def copy (f : α → β) (g : α →𝒄 β) (h : f = g) : α →𝒄 β where toOrderHom := g.1.copy f h map_ωSup' := by rw [OrderHom.copy_eq]; exact g.map_ωSup' /-- The identity as a continuous function. -/ @[simps!] def id : α →𝒄 α := ⟨OrderHom.id, ωScottContinuous.id.map_ωSup⟩ /-- The composition of continuous functions. -/ @[simps!] def comp (f : β →𝒄 γ) (g : α →𝒄 β) : α →𝒄 γ := ⟨.comp f.1 g.1, (f.ωScottContinuous.comp g.ωScottContinuous).map_ωSup⟩ @[ext] protected theorem ext (f g : α →𝒄 β) (h : ∀ x, f x = g x) : f = g := DFunLike.ext f g h protected theorem coe_inj (f g : α →𝒄 β) (h : (f : α → β) = g) : f = g := DFunLike.ext' h @[simp] theorem comp_id (f : β →𝒄 γ) : f.comp id = f := rfl @[simp] theorem id_comp (f : β →𝒄 γ) : id.comp f = f := rfl @[simp] theorem comp_assoc (f : γ →𝒄 δ) (g : β →𝒄 γ) (h : α →𝒄 β) : f.comp (g.comp h) = (f.comp g).comp h := rfl @[simp] theorem coe_apply (a : α) (f : α →𝒄 β) : (f : α →o β) a = f a := rfl /-- `Function.const` is a continuous function. -/ @[simps!] def const (x : β) : α →𝒄 β := ⟨.const _ x, ωScottContinuous.const.map_ωSup⟩ instance [Inhabited β] : Inhabited (α →𝒄 β) := ⟨const default⟩ /-- The map from continuous functions to monotone functions is itself a monotone function. -/ @[simps] def toMono : (α →𝒄 β) →o α →o β where toFun f := f monotone' _ _ h := h /-- When proving that a chain of applications is below a bound `z`, it suffices to consider the functions and values being selected from the same index in the chains. This lemma is more specific than necessary, i.e. `c₀` only needs to be a chain of monotone functions, but it is only used with continuous functions. -/ @[simp] theorem forall_forall_merge (c₀ : Chain (α →𝒄 β)) (c₁ : Chain α) (z : β) : (∀ i j : ℕ, (c₀ i) (c₁ j) ≤ z) ↔ ∀ i : ℕ, (c₀ i) (c₁ i) ≤ z := by constructor <;> introv h · apply h · apply le_trans _ (h (max i j)) trans c₀ i (c₁ (max i j)) · apply (c₀ i).monotone apply c₁.monotone apply le_max_right · apply c₀.monotone apply le_max_left @[simp] theorem forall_forall_merge' (c₀ : Chain (α →𝒄 β)) (c₁ : Chain α) (z : β) : (∀ j i : ℕ, (c₀ i) (c₁ j) ≤ z) ↔ ∀ i : ℕ, (c₀ i) (c₁ i) ≤ z := by rw [forall_swap, forall_forall_merge] /-- The `ωSup` operator for continuous functions, which takes the pointwise countable supremum of the functions in the `ω`-chain. -/ @[simps!] protected def ωSup (c : Chain (α →𝒄 β)) : α →𝒄 β where toOrderHom := ωSup <\| c.map toMono map_ωSup' c' := eq_of_forall_ge_iff fun a ↦ by simp [(c _).ωScottContinuous.map_ωSup] @[simps ωSup] instance : OmegaCompletePartialOrder (α →𝒄 β) := OmegaCompletePartialOrder.lift ContinuousHom.toMono ContinuousHom.ωSup (fun _ _ h => h) (fun _ => rfl) namespace Prod /-- The application of continuous functions as a continuous function. -/ @[simps] def apply : (α →𝒄 β) × α →𝒄 β where toFun f := f.1 f.2 monotone' x y h := by dsimp trans y.fst x.snd <;> [apply h.1; apply y.1.monotone h.2] map_ωSup' c := by apply le_antisymm · apply ωSup_le intro i dsimp rw [(c _).fst.continuous] apply ωSup_le intro j apply le_ωSup_of_le (max i j) apply apply_mono · exact monotone_fst (OrderHom.mono _ (le_max_left _ _)) · exact monotone_snd (OrderHom.mono _ (le_max_right _ _)) · apply ωSup_le intro i apply le_ωSup_of_le i dsimp apply OrderHom.mono _ apply le_ωSup_of_le i rfl end Prod theorem ωSup_def (c : Chain (α →𝒄 β)) (x : α) : ωSup c x = ContinuousHom.ωSup c x := rfl theorem ωSup_apply_ωSup (c₀ : Chain (α →𝒄 β)) (c₁ : Chain α) : ωSup c₀ (ωSup c₁) = Prod.apply (ωSup (c₀.zip c₁)) := by simp [Prod.apply_apply, Prod.ωSup_zip] /-- A family of continuous functions yields a continuous family of functions. -/ @[simps] def flip {α : Type} (f : α → β →𝒄 γ) : β →𝒄 α → γ where toFun x y := f y x monotone' _ _ h a := (f a).monotone h map_ωSup' _ := by ext x; change f _ _ = _; rw [(f _).continuous]; rfl /-- `Part.bind` as a continuous function. -/ @[simps! apply] noncomputable def bind {β γ : Type v} (f : α →𝒄 Part β) (g : α →𝒄 β → Part γ) : α →𝒄 Part γ := .mk (OrderHom.partBind f g.toOrderHom) fun c => by rw [ωSup_bind, ← f.continuous, g.toOrderHom_eq_coe, ← g.continuous] rfl /-- `Part.map` as a continuous function. -/ @[simps! apply] noncomputable def map {β γ : Type v} (f : β → γ) (g : α →𝒄 Part β) : α →𝒄 Part γ := .copy (fun x => f <$> g x) (bind g (const (pure ∘ f))) <\| by ext1 simp only [map_eq_bind_pure_comp, bind, coe_mk, OrderHom.partBind_coe, coe_apply, coe_toOrderHom, const_apply, Part.bind_eq_bind] /-- `Part.seq` as a continuous function. -/ @[simps! apply] noncomputable def seq {β γ : Type v} (f : α →𝒄 Part (β → γ)) (g : α →𝒄 Part β) : α →𝒄 Part γ := .copy (fun x => f x <> g x) (bind f <\| flip <\| _root_.flip map g) <\| by ext simp only [seq_eq_bind_map, Part.bind_eq_bind, Part.mem_bind_iff, flip_apply, _root_.flip, map_apply, bind_apply, Part.map_eq_map] end ContinuousHom namespace fixedPoints open Function /-- Iteration of a function on an initial element interpreted as a chain. -/ def iterateChain (f : α →o α) (x : α) (h : x ≤ f x) : Chain α := ⟨fun n => f^[n] x, f.monotone.monotone_iterate_of_le_map h⟩ variable (f : α →𝒄 α) (x : α) /-- The supremum of iterating a function on x arbitrary often is a fixed point -/ theorem ωSup_iterate_mem_fixedPoint (h : x ≤ f x) : ωSup (iterateChain f x h) ∈ fixedPoints f := by rw [mem_fixedPoints, IsFixedPt, f.continuous] apply le_antisymm · apply ωSup_le intro n simp only [Chain.map_coe, OrderHomClass.coe_coe, comp_apply] have : iterateChain f x h (n.succ) = f (iterateChain f x h n) := Function.iterate_succ_apply' .. rw [← this] apply le_ωSup · apply ωSup_le	rintro (_ \| n) · apply le_trans h change ((iterateChain f x h).map f) 0 ≤ ωSup ((iterateChain f x h).map (f : α →o α)) apply le_ωSup · have : iterateChain f x h (n.succ) = (iterateChain f x h).map f n := Function.iterate_succ_apply' .. rw [this] apply le_ωSup /-- The supremum of iterating a function on x arbitrary often is smaller than any prefixed point.	Mathlib/Order/OmegaCompletePartialOrder.lean	802	812
/- Copyright (c) 2023 Rémy Degenne. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Rémy Degenne, Peter Pfaffelhuber -/ import Mathlib.Data.Nat.Lattice import Mathlib.Data.Set.Accumulate import Mathlib.Data.Set.Pairwise.Lattice import Mathlib.MeasureTheory.PiSystem /-! # Semirings and rings of sets A semi-ring of sets `C` (in the sense of measure theory) is a family of sets containing `∅`, stable by intersection and such that for all `s, t ∈ C`, `t \ s` is equal to a disjoint union of finitely many sets in `C`. Note that a semi-ring of sets may not contain unions. An important example of a semi-ring of sets is intervals in `ℝ`. The intersection of two intervals is an interval (possibly empty). The union of two intervals may not be an interval. The set difference of two intervals may not be an interval, but it will be a disjoint union of two intervals. A ring of sets is a set of sets containing `∅`, stable by union, set difference and intersection. ## Main definitions * `MeasureTheory.IsSetSemiring C`: property of being a semi-ring of sets. * `MeasureTheory.IsSetSemiring.disjointOfDiff hs ht`: for `s, t` in a semi-ring `C` (with `hC : IsSetSemiring C`) with `hs : s ∈ C`, `ht : t ∈ C`, this is a `Finset` of pairwise disjoint sets such that `s \ t = ⋃₀ hC.disjointOfDiff hs ht`. * `MeasureTheory.IsSetSemiring.disjointOfDiffUnion hs hI`: for `hs : s ∈ C` and a finset `I` of sets in `C` (with `hI : ↑I ⊆ C`), this is a `Finset` of pairwise disjoint sets such that `s \ ⋃₀ I = ⋃₀ hC.disjointOfDiffUnion hs hI`. * `MeasureTheory.IsSetSemiring.disjointOfUnion hJ`: for `hJ ⊆ C`, this is a `Finset` of pairwise disjoint sets such that `⋃₀ J = ⋃₀ hC.disjointOfUnion hJ`. * `MeasureTheory.IsSetRing`: property of being a ring of sets. ## Main statements * `MeasureTheory.IsSetSemiring.exists_disjoint_finset_diff_eq`: the existence of the `Finset` given by the definition `IsSetSemiring.disjointOfDiffUnion` (see above). * `MeasureTheory.IsSetSemiring.disjointOfUnion_props`: In a `hC : IsSetSemiring C`, for a `J : Finset (Set α)` with `J ⊆ C`, there is for every `x in J` some `K x ⊆ C` finite, such that * `⋃ x ∈ J, K x` are pairwise disjoint and do not contain ∅, * `⋃ s ∈ K x, s ⊆ x`, * `⋃ x ∈ J, x = ⋃ x ∈ J, ⋃ s ∈ K x, s`. -/ open Finset Set namespace MeasureTheory variable {α : Type*} {C : Set (Set α)} {s t : Set α} /-- A semi-ring of sets `C` is a family of sets containing `∅`, stable by intersection and such that for all `s, t ∈ C`, `s \ t` is equal to a disjoint union of finitely many sets in `C`. -/ structure IsSetSemiring (C : Set (Set α)) : Prop where empty_mem : ∅ ∈ C inter_mem : ∀ s ∈ C, ∀ t ∈ C, s ∩ t ∈ C diff_eq_sUnion' : ∀ s ∈ C, ∀ t ∈ C, ∃ I : Finset (Set α), ↑I ⊆ C ∧ PairwiseDisjoint (I : Set (Set α)) id ∧ s \ t = ⋃₀ I namespace IsSetSemiring lemma isPiSystem (hC : IsSetSemiring C) : IsPiSystem C := fun s hs t ht _ ↦ hC.inter_mem s hs t ht section disjointOfDiff open scoped Classical in /-- In a semi-ring of sets `C`, for all sets `s, t ∈ C`, `s \ t` is equal to a disjoint union of finitely many sets in `C`. The finite set of sets in the union is not unique, but this definition gives an arbitrary `Finset (Set α)` that satisfies the equality. We remove the empty set to ensure that `t ∉ hC.disjointOfDiff hs ht` even if `t = ∅`. -/ noncomputable def disjointOfDiff (hC : IsSetSemiring C) (hs : s ∈ C) (ht : t ∈ C) : Finset (Set α) := (hC.diff_eq_sUnion' s hs t ht).choose \ {∅} lemma empty_nmem_disjointOfDiff (hC : IsSetSemiring C) (hs : s ∈ C) (ht : t ∈ C) : ∅ ∉ hC.disjointOfDiff hs ht := by classical simp only [disjointOfDiff, mem_sdiff, Finset.mem_singleton, eq_self_iff_true, not_true, and_false, not_false_iff] lemma subset_disjointOfDiff (hC : IsSetSemiring C) (hs : s ∈ C) (ht : t ∈ C) : ↑(hC.disjointOfDiff hs ht) ⊆ C := by classical simp only [disjointOfDiff, coe_sdiff, coe_singleton, diff_singleton_subset_iff] exact (hC.diff_eq_sUnion' s hs t ht).choose_spec.1.trans (Set.subset_insert _ _) lemma pairwiseDisjoint_disjointOfDiff (hC : IsSetSemiring C) (hs : s ∈ C) (ht : t ∈ C) : PairwiseDisjoint (hC.disjointOfDiff hs ht : Set (Set α)) id := by classical simp only [disjointOfDiff, coe_sdiff, coe_singleton] exact Set.PairwiseDisjoint.subset (hC.diff_eq_sUnion' s hs t ht).choose_spec.2.1 diff_subset lemma sUnion_disjointOfDiff (hC : IsSetSemiring C) (hs : s ∈ C) (ht : t ∈ C) : ⋃₀ hC.disjointOfDiff hs ht = s \ t := by classical rw [(hC.diff_eq_sUnion' s hs t ht).choose_spec.2.2] simp only [disjointOfDiff, coe_sdiff, coe_singleton, diff_singleton_subset_iff] rw [sUnion_diff_singleton_empty] lemma nmem_disjointOfDiff (hC : IsSetSemiring C) (hs : s ∈ C) (ht : t ∈ C) : t ∉ hC.disjointOfDiff hs ht := by intro hs_mem suffices t ⊆ s \ t by have h := @disjoint_sdiff_self_right _ t s _ specialize h le_rfl this simp only [Set.bot_eq_empty, Set.le_eq_subset, subset_empty_iff] at h refine hC.empty_nmem_disjointOfDiff hs ht ?_ rwa [← h] rw [← hC.sUnion_disjointOfDiff hs ht] exact subset_sUnion_of_mem hs_mem lemma sUnion_insert_disjointOfDiff (hC : IsSetSemiring C) (hs : s ∈ C) (ht : t ∈ C) (hst : t ⊆ s) : ⋃₀ insert t (hC.disjointOfDiff hs ht) = s := by conv_rhs => rw [← union_diff_cancel hst, ← hC.sUnion_disjointOfDiff hs ht] simp only [mem_coe, sUnion_insert] lemma disjoint_sUnion_disjointOfDiff (hC : IsSetSemiring C) (hs : s ∈ C) (ht : t ∈ C) : Disjoint t (⋃₀ hC.disjointOfDiff hs ht) := by rw [hC.sUnion_disjointOfDiff] exact disjoint_sdiff_right lemma pairwiseDisjoint_insert_disjointOfDiff (hC : IsSetSemiring C) (hs : s ∈ C) (ht : t ∈ C) : PairwiseDisjoint (insert t (hC.disjointOfDiff hs ht) : Set (Set α)) id := by have h := hC.pairwiseDisjoint_disjointOfDiff hs ht refine PairwiseDisjoint.insert_of_not_mem h (hC.nmem_disjointOfDiff hs ht) fun u hu ↦ ?_ simp_rw [id] refine Disjoint.mono_right ?_ (hC.disjoint_sUnion_disjointOfDiff hs ht) simp only [Set.le_eq_subset] exact subset_sUnion_of_mem hu end disjointOfDiff section disjointOfDiffUnion variable {I : Finset (Set α)} /-- In a semiring of sets `C`, for all set `s ∈ C` and finite set of sets `I ⊆ C`, there is a finite set of sets in `C` whose union is `s \ ⋃₀ I`. See `IsSetSemiring.disjointOfDiffUnion` for a definition that gives such a set. -/ lemma exists_disjoint_finset_diff_eq (hC : IsSetSemiring C) (hs : s ∈ C) (hI : ↑I ⊆ C) : ∃ J : Finset (Set α), ↑J ⊆ C ∧ PairwiseDisjoint (J : Set (Set α)) id ∧ s \ ⋃₀ I = ⋃₀ J := by classical induction I using Finset.induction with \| empty => simp only [coe_empty, sUnion_empty, diff_empty, exists_prop] refine ⟨{s}, singleton_subset_set_iff.mpr hs, ?_⟩ simp only [coe_singleton, pairwiseDisjoint_singleton, sUnion_singleton, eq_self_iff_true, and_self_iff] \| insert t I' _ h => ?_ rw [coe_insert] at hI have ht : t ∈ C := hI (Set.mem_insert _ _) obtain ⟨J, h_ss, h_dis, h_eq⟩ := h ((Set.subset_insert _ _).trans hI) let Ju : ∀ u ∈ C, Finset (Set α) := fun u hu ↦ hC.disjointOfDiff hu ht have hJu_subset : ∀ (u) (hu : u ∈ C), ↑(Ju u hu) ⊆ C := by intro u hu x hx exact hC.subset_disjointOfDiff hu ht hx have hJu_disj : ∀ (u) (hu : u ∈ C), (Ju u hu : Set (Set α)).PairwiseDisjoint id := fun u hu ↦ hC.pairwiseDisjoint_disjointOfDiff hu ht have hJu_sUnion : ∀ (u) (hu : u ∈ C), ⋃₀ (Ju u hu : Set (Set α)) = u \ t := fun u hu ↦ hC.sUnion_disjointOfDiff hu ht have hJu_disj' : ∀ (u) (hu : u ∈ C) (v) (hv : v ∈ C) (_h_dis : Disjoint u v), Disjoint (⋃₀ (Ju u hu : Set (Set α))) (⋃₀ ↑(Ju v hv)) := by intro u hu v hv huv_disj rw [hJu_sUnion, hJu_sUnion] exact disjoint_of_subset Set.diff_subset Set.diff_subset huv_disj let J' : Finset (Set α) := Finset.biUnion (Finset.univ : Finset J) fun u ↦ Ju u (h_ss u.prop) have hJ'_subset : ↑J' ⊆ C := by intro u simp only [J' ,Subtype.coe_mk, univ_eq_attach, coe_biUnion, mem_coe, mem_attach, iUnion_true, mem_iUnion, Finset.exists_coe, exists₂_imp] intro v hv huvt exact hJu_subset v (h_ss hv) huvt refine ⟨J', hJ'_subset, ?_, ?_⟩ · rw [Finset.coe_biUnion] refine PairwiseDisjoint.biUnion ?_ ?_ · simp only [univ_eq_attach, mem_coe, id, iSup_eq_iUnion] simp_rw [PairwiseDisjoint, Set.Pairwise] intro x _ y _ hxy have hxy_disj : Disjoint (x : Set α) y := by by_contra h_contra refine hxy ?_ refine Subtype.ext ?_ exact h_dis.elim x.prop y.prop h_contra convert hJu_disj' (x : Set α) (h_ss x.prop) y (h_ss y.prop) hxy_disj · rw [sUnion_eq_biUnion] congr · rw [sUnion_eq_biUnion] congr · exact fun u _ ↦ hJu_disj _ _ · rw [coe_insert, sUnion_insert, Set.union_comm, ← Set.diff_diff, h_eq] simp_rw [J', sUnion_eq_biUnion, Set.iUnion_diff] simp only [Subtype.coe_mk, mem_coe, Finset.mem_biUnion, Finset.mem_univ, exists_true_left, Finset.exists_coe, iUnion_exists, true_and] rw [iUnion_comm] refine iUnion_congr fun i ↦ ?_ by_cases hi : i ∈ J · simp only [hi, iUnion_true, exists_prop] rw [← hJu_sUnion i (h_ss hi), sUnion_eq_biUnion] simp only [mem_coe] · simp only [hi, iUnion_of_empty, iUnion_empty] open scoped Classical in /-- In a semiring of sets `C`, for all set `s ∈ C` and finite set of sets `I ⊆ C`, `disjointOfDiffUnion` is a finite set of sets in `C` such that `s \ ⋃₀ I = ⋃₀ (hC.disjointOfDiffUnion hs I hI)`. `disjointOfDiff` is a special case of `disjointOfDiffUnion` where `I` is a singleton. -/ noncomputable def disjointOfDiffUnion (hC : IsSetSemiring C) (hs : s ∈ C) (hI : ↑I ⊆ C) : Finset (Set α) := (hC.exists_disjoint_finset_diff_eq hs hI).choose \ {∅} lemma empty_nmem_disjointOfDiffUnion (hC : IsSetSemiring C) (hs : s ∈ C) (hI : ↑I ⊆ C) : ∅ ∉ hC.disjointOfDiffUnion hs hI := by classical simp only [disjointOfDiffUnion, mem_sdiff, Finset.mem_singleton, eq_self_iff_true, not_true, and_false, not_false_iff] lemma disjointOfDiffUnion_subset (hC : IsSetSemiring C) (hs : s ∈ C) (hI : ↑I ⊆ C) : ↑(hC.disjointOfDiffUnion hs hI) ⊆ C := by classical simp only [disjointOfDiffUnion, coe_sdiff, coe_singleton, diff_singleton_subset_iff] exact (hC.exists_disjoint_finset_diff_eq hs hI).choose_spec.1.trans (Set.subset_insert _ _) lemma pairwiseDisjoint_disjointOfDiffUnion (hC : IsSetSemiring C) (hs : s ∈ C) (hI : ↑I ⊆ C) : PairwiseDisjoint (hC.disjointOfDiffUnion hs hI : Set (Set α)) id := by classical simp only [disjointOfDiffUnion, coe_sdiff, coe_singleton] exact Set.PairwiseDisjoint.subset (hC.exists_disjoint_finset_diff_eq hs hI).choose_spec.2.1 diff_subset	lemma diff_sUnion_eq_sUnion_disjointOfDiffUnion (hC : IsSetSemiring C) (hs : s ∈ C) (hI : ↑I ⊆ C) : s \ ⋃₀ I = ⋃₀ hC.disjointOfDiffUnion hs hI := by classical rw [(hC.exists_disjoint_finset_diff_eq hs hI).choose_spec.2.2] simp only [disjointOfDiffUnion, coe_sdiff, coe_singleton, diff_singleton_subset_iff] rw [sUnion_diff_singleton_empty] lemma sUnion_disjointOfDiffUnion_subset (hC : IsSetSemiring C) (hs : s ∈ C) (hI : ↑I ⊆ C) : ⋃₀ (hC.disjointOfDiffUnion hs hI : Set (Set α)) ⊆ s := by rw [← hC.diff_sUnion_eq_sUnion_disjointOfDiffUnion]	Mathlib/MeasureTheory/SetSemiring.lean	243	252
/- Copyright (c) 2018 Chris Hughes. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Chris Hughes, Johannes Hölzl, Kim Morrison, Jens Wagemaker -/ import Mathlib.Algebra.Group.Submonoid.Operations import Mathlib.Algebra.MonoidAlgebra.Defs import Mathlib.Algebra.Order.Monoid.Unbundled.WithTop import Mathlib.Algebra.Ring.Action.Rat import Mathlib.Data.Finset.Sort import Mathlib.Tactic.FastInstance /-! # Theory of univariate polynomials This file defines `Polynomial R`, the type of univariate polynomials over the semiring `R`, builds a semiring structure on it, and gives basic definitions that are expanded in other files in this directory. ## Main definitions * `monomial n a` is the polynomial `a X^n`. Note that `monomial n` is defined as an `R`-linear map. * `C a` is the constant polynomial `a`. Note that `C` is defined as a ring homomorphism. * `X` is the polynomial `X`, i.e., `monomial 1 1`. * `p.sum f` is `∑ n ∈ p.support, f n (p.coeff n)`, i.e., one sums the values of functions applied to coefficients of the polynomial `p`. * `p.erase n` is the polynomial `p` in which one removes the `c X^n` term. There are often two natural variants of lemmas involving sums, depending on whether one acts on the polynomials, or on the function. The naming convention is that one adds `index` when acting on the polynomials. For instance, * `sum_add_index` states that `(p + q).sum f = p.sum f + q.sum f`; * `sum_add` states that `p.sum (fun n x ↦ f n x + g n x) = p.sum f + p.sum g`. * Notation to refer to `Polynomial R`, as `R[X]` or `R[t]`. ## Implementation Polynomials are defined using `R[ℕ]`, where `R` is a semiring. The variable `X` commutes with every polynomial `p`: lemma `X_mul` proves the identity `X * p = p * X`. The relationship to `R[ℕ]` is through a structure to make polynomials irreducible from the point of view of the kernel. Most operations are irreducible since Lean can not compute anyway with `AddMonoidAlgebra`. There are two exceptions that we make semireducible: * The zero polynomial, so that its coefficients are definitionally equal to `0`. * The scalar action, to permit typeclass search to unfold it to resolve potential instance diamonds. The raw implementation of the equivalence between `R[X]` and `R[ℕ]` is done through `ofFinsupp` and `toFinsupp` (or, equivalently, `rcases p` when `p` is a polynomial gives an element `q` of `R[ℕ]`, and conversely `⟨q⟩` gives back `p`). The equivalence is also registered as a ring equiv in `Polynomial.toFinsuppIso`. These should in general not be used once the basic API for polynomials is constructed. -/ noncomputable section /-- `Polynomial R` is the type of univariate polynomials over `R`, denoted as `R[X]` within the `Polynomial` namespace. Polynomials should be seen as (semi-)rings with the additional constructor `X`. The embedding from `R` is called `C`. -/ structure Polynomial (R : Type) [Semiring R] where ofFinsupp :: toFinsupp : AddMonoidAlgebra R ℕ @[inherit_doc] scoped[Polynomial] notation:9000 R "[X]" => Polynomial R open AddMonoidAlgebra Finset open Finsupp hiding single open Function hiding Commute namespace Polynomial universe u variable {R : Type u} {a b : R} {m n : ℕ} section Semiring variable [Semiring R] {p q : R[X]} theorem forall_iff_forall_finsupp (P : R[X] → Prop) : (∀ p, P p) ↔ ∀ q : R[ℕ], P ⟨q⟩ := ⟨fun h q => h ⟨q⟩, fun h ⟨p⟩ => h p⟩ theorem exists_iff_exists_finsupp (P : R[X] → Prop) : (∃ p, P p) ↔ ∃ q : R[ℕ], P ⟨q⟩ := ⟨fun ⟨⟨p⟩, hp⟩ => ⟨p, hp⟩, fun ⟨q, hq⟩ => ⟨⟨q⟩, hq⟩⟩ @[simp] theorem eta (f : R[X]) : Polynomial.ofFinsupp f.toFinsupp = f := by cases f; rfl /-! ### Conversions to and from `AddMonoidAlgebra` Since `R[X]` is not defeq to `R[ℕ]`, but instead is a structure wrapping it, we have to copy across all the arithmetic operators manually, along with the lemmas about how they unfold around `Polynomial.ofFinsupp` and `Polynomial.toFinsupp`. -/ section AddMonoidAlgebra private irreducible_def add : R[X] → R[X] → R[X] \| ⟨a⟩, ⟨b⟩ => ⟨a + b⟩ private irreducible_def neg {R : Type u} [Ring R] : R[X] → R[X] \| ⟨a⟩ => ⟨-a⟩ private irreducible_def mul : R[X] → R[X] → R[X] \| ⟨a⟩, ⟨b⟩ => ⟨a b⟩ instance zero : Zero R[X] := ⟨⟨0⟩⟩ instance one : One R[X] := ⟨⟨1⟩⟩ instance add' : Add R[X] := ⟨add⟩ instance neg' {R : Type u} [Ring R] : Neg R[X] := ⟨neg⟩ instance sub {R : Type u} [Ring R] : Sub R[X] := ⟨fun a b => a + -b⟩ instance mul' : Mul R[X] := ⟨mul⟩ -- If the private definitions are accidentally exposed, simplify them away. @[simp] theorem add_eq_add : add p q = p + q := rfl @[simp] theorem mul_eq_mul : mul p q = p * q := rfl instance instNSMul : SMul ℕ R[X] where smul r p := ⟨r • p.toFinsupp⟩ instance smulZeroClass {S : Type} [SMulZeroClass S R] : SMulZeroClass S R[X] where smul r p := ⟨r • p.toFinsupp⟩ smul_zero a := congr_arg ofFinsupp (smul_zero a) instance {S : Type} [Zero S] [SMulZeroClass S R] [NoZeroSMulDivisors S R] : NoZeroSMulDivisors S R[X] where eq_zero_or_eq_zero_of_smul_eq_zero eq := (eq_zero_or_eq_zero_of_smul_eq_zero <\| congr_arg toFinsupp eq).imp id (congr_arg ofFinsupp) -- to avoid a bug in the `ring` tactic instance (priority := 1) pow : Pow R[X] ℕ where pow p n := npowRec n p @[simp] theorem ofFinsupp_zero : (⟨0⟩ : R[X]) = 0 := rfl @[simp] theorem ofFinsupp_one : (⟨1⟩ : R[X]) = 1 := rfl @[simp] theorem ofFinsupp_add {a b} : (⟨a + b⟩ : R[X]) = ⟨a⟩ + ⟨b⟩ := show _ = add _ _ by rw [add_def] @[simp] theorem ofFinsupp_neg {R : Type u} [Ring R] {a} : (⟨-a⟩ : R[X]) = -⟨a⟩ := show _ = neg _ by rw [neg_def] @[simp] theorem ofFinsupp_sub {R : Type u} [Ring R] {a b} : (⟨a - b⟩ : R[X]) = ⟨a⟩ - ⟨b⟩ := by rw [sub_eq_add_neg, ofFinsupp_add, ofFinsupp_neg] rfl @[simp] theorem ofFinsupp_mul (a b) : (⟨a * b⟩ : R[X]) = ⟨a⟩ * ⟨b⟩ := show _ = mul _ _ by rw [mul_def] @[simp] theorem ofFinsupp_nsmul (a : ℕ) (b) : (⟨a • b⟩ : R[X]) = (a • ⟨b⟩ : R[X]) := rfl @[simp] theorem ofFinsupp_smul {S : Type} [SMulZeroClass S R] (a : S) (b) : (⟨a • b⟩ : R[X]) = (a • ⟨b⟩ : R[X]) := rfl @[simp] theorem ofFinsupp_pow (a) (n : ℕ) : (⟨a ^ n⟩ : R[X]) = ⟨a⟩ ^ n := by change _ = npowRec n _ induction n with \| zero => simp [npowRec] \| succ n n_ih => simp [npowRec, n_ih, pow_succ] @[simp] theorem toFinsupp_zero : (0 : R[X]).toFinsupp = 0 := rfl @[simp] theorem toFinsupp_one : (1 : R[X]).toFinsupp = 1 := rfl @[simp] theorem toFinsupp_add (a b : R[X]) : (a + b).toFinsupp = a.toFinsupp + b.toFinsupp := by cases a cases b rw [← ofFinsupp_add] @[simp] theorem toFinsupp_neg {R : Type u} [Ring R] (a : R[X]) : (-a).toFinsupp = -a.toFinsupp := by cases a rw [← ofFinsupp_neg] @[simp] theorem toFinsupp_sub {R : Type u} [Ring R] (a b : R[X]) : (a - b).toFinsupp = a.toFinsupp - b.toFinsupp := by rw [sub_eq_add_neg, ← toFinsupp_neg, ← toFinsupp_add] rfl @[simp] theorem toFinsupp_mul (a b : R[X]) : (a b).toFinsupp = a.toFinsupp * b.toFinsupp := by cases a cases b rw [← ofFinsupp_mul] @[simp] theorem toFinsupp_nsmul (a : ℕ) (b : R[X]) : (a • b).toFinsupp = a • b.toFinsupp := rfl @[simp] theorem toFinsupp_smul {S : Type} [SMulZeroClass S R] (a : S) (b : R[X]) : (a • b).toFinsupp = a • b.toFinsupp := rfl @[simp] theorem toFinsupp_pow (a : R[X]) (n : ℕ) : (a ^ n).toFinsupp = a.toFinsupp ^ n := by cases a rw [← ofFinsupp_pow] theorem _root_.IsSMulRegular.polynomial {S : Type} [SMulZeroClass S R] {a : S} (ha : IsSMulRegular R a) : IsSMulRegular R[X] a \| ⟨_x⟩, ⟨_y⟩, h => congr_arg _ <\| ha.finsupp (Polynomial.ofFinsupp.inj h) theorem toFinsupp_injective : Function.Injective (toFinsupp : R[X] → AddMonoidAlgebra _ _) := fun ⟨_x⟩ ⟨_y⟩ => congr_arg _ @[simp] theorem toFinsupp_inj {a b : R[X]} : a.toFinsupp = b.toFinsupp ↔ a = b := toFinsupp_injective.eq_iff @[simp] theorem toFinsupp_eq_zero {a : R[X]} : a.toFinsupp = 0 ↔ a = 0 := by rw [← toFinsupp_zero, toFinsupp_inj] @[simp] theorem toFinsupp_eq_one {a : R[X]} : a.toFinsupp = 1 ↔ a = 1 := by rw [← toFinsupp_one, toFinsupp_inj] /-- A more convenient spelling of `Polynomial.ofFinsupp.injEq` in terms of `Iff`. -/ theorem ofFinsupp_inj {a b} : (⟨a⟩ : R[X]) = ⟨b⟩ ↔ a = b := iff_of_eq (ofFinsupp.injEq _ _) @[simp] theorem ofFinsupp_eq_zero {a} : (⟨a⟩ : R[X]) = 0 ↔ a = 0 := by rw [← ofFinsupp_zero, ofFinsupp_inj] @[simp] theorem ofFinsupp_eq_one {a} : (⟨a⟩ : R[X]) = 1 ↔ a = 1 := by rw [← ofFinsupp_one, ofFinsupp_inj] instance inhabited : Inhabited R[X] := ⟨0⟩ instance instNatCast : NatCast R[X] where natCast n := ofFinsupp n @[simp] theorem ofFinsupp_natCast (n : ℕ) : (⟨n⟩ : R[X]) = n := rfl @[simp] theorem toFinsupp_natCast (n : ℕ) : (n : R[X]).toFinsupp = n := rfl @[simp] theorem ofFinsupp_ofNat (n : ℕ) [n.AtLeastTwo] : (⟨ofNat(n)⟩ : R[X]) = ofNat(n) := rfl @[simp] theorem toFinsupp_ofNat (n : ℕ) [n.AtLeastTwo] : (ofNat(n) : R[X]).toFinsupp = ofNat(n) := rfl instance semiring : Semiring R[X] := fast_instance% Function.Injective.semiring toFinsupp toFinsupp_injective toFinsupp_zero toFinsupp_one toFinsupp_add toFinsupp_mul (fun _ _ => toFinsupp_nsmul _ _) toFinsupp_pow fun _ => rfl instance distribSMul {S} [DistribSMul S R] : DistribSMul S R[X] := fast_instance% Function.Injective.distribSMul ⟨⟨toFinsupp, toFinsupp_zero⟩, toFinsupp_add⟩ toFinsupp_injective toFinsupp_smul instance distribMulAction {S} [Monoid S] [DistribMulAction S R] : DistribMulAction S R[X] := fast_instance% Function.Injective.distribMulAction ⟨⟨toFinsupp, toFinsupp_zero (R := R)⟩, toFinsupp_add⟩ toFinsupp_injective toFinsupp_smul instance faithfulSMul {S} [SMulZeroClass S R] [FaithfulSMul S R] : FaithfulSMul S R[X] where eq_of_smul_eq_smul {_s₁ _s₂} h := eq_of_smul_eq_smul fun a : ℕ →₀ R => congr_arg toFinsupp (h ⟨a⟩) instance module {S} [Semiring S] [Module S R] : Module S R[X] := fast_instance% Function.Injective.module _ ⟨⟨toFinsupp, toFinsupp_zero⟩, toFinsupp_add⟩ toFinsupp_injective toFinsupp_smul instance smulCommClass {S₁ S₂} [SMulZeroClass S₁ R] [SMulZeroClass S₂ R] [SMulCommClass S₁ S₂ R] : SMulCommClass S₁ S₂ R[X] := ⟨by rintro m n ⟨f⟩ simp_rw [← ofFinsupp_smul, smul_comm m n f]⟩ instance isScalarTower {S₁ S₂} [SMul S₁ S₂] [SMulZeroClass S₁ R] [SMulZeroClass S₂ R] [IsScalarTower S₁ S₂ R] : IsScalarTower S₁ S₂ R[X] := ⟨by rintro _ _ ⟨⟩ simp_rw [← ofFinsupp_smul, smul_assoc]⟩ instance isScalarTower_right {α K : Type} [Semiring K] [DistribSMul α K] [IsScalarTower α K K] : IsScalarTower α K[X] K[X] := ⟨by rintro _ ⟨⟩ ⟨⟩ simp_rw [smul_eq_mul, ← ofFinsupp_smul, ← ofFinsupp_mul, ← ofFinsupp_smul, smul_mul_assoc]⟩ instance isCentralScalar {S} [SMulZeroClass S R] [SMulZeroClass Sᵐᵒᵖ R] [IsCentralScalar S R] : IsCentralScalar S R[X] := ⟨by rintro _ ⟨⟩ simp_rw [← ofFinsupp_smul, op_smul_eq_smul]⟩ instance unique [Subsingleton R] : Unique R[X] := { Polynomial.inhabited with uniq := by rintro ⟨x⟩ apply congr_arg ofFinsupp simp [eq_iff_true_of_subsingleton] } variable (R) /-- Ring isomorphism between `R[X]` and `R[ℕ]`. This is just an implementation detail, but it can be useful to transfer results from `Finsupp` to polynomials. -/ @[simps apply symm_apply] def toFinsuppIso : R[X] ≃+ R[ℕ] where toFun := toFinsupp invFun := ofFinsupp left_inv := fun ⟨_p⟩ => rfl right_inv _p := rfl map_mul' := toFinsupp_mul map_add' := toFinsupp_add instance [DecidableEq R] : DecidableEq R[X] := @Equiv.decidableEq R[X] _ (toFinsuppIso R).toEquiv (Finsupp.instDecidableEq) /-- Linear isomorphism between `R[X]` and `R[ℕ]`. This is just an implementation detail, but it can be useful to transfer results from `Finsupp` to polynomials. -/ @[simps!] def toFinsuppIsoLinear : R[X] ≃ₗ[R] R[ℕ] where __ := toFinsuppIso R map_smul' _ _ := rfl end AddMonoidAlgebra theorem ofFinsupp_sum {ι : Type} (s : Finset ι) (f : ι → R[ℕ]) : (⟨∑ i ∈ s, f i⟩ : R[X]) = ∑ i ∈ s, ⟨f i⟩ := map_sum (toFinsuppIso R).symm f s theorem toFinsupp_sum {ι : Type} (s : Finset ι) (f : ι → R[X]) : (∑ i ∈ s, f i : R[X]).toFinsupp = ∑ i ∈ s, (f i).toFinsupp := map_sum (toFinsuppIso R) f s /-- The set of all `n` such that `X^n` has a non-zero coefficient. -/ def support : R[X] → Finset ℕ \| ⟨p⟩ => p.support @[simp] theorem support_ofFinsupp (p) : support (⟨p⟩ : R[X]) = p.support := by rw [support] theorem support_toFinsupp (p : R[X]) : p.toFinsupp.support = p.support := by rw [support] @[simp] theorem support_zero : (0 : R[X]).support = ∅ := rfl @[simp] theorem support_eq_empty : p.support = ∅ ↔ p = 0 := by rcases p with ⟨⟩ simp [support] @[simp] lemma support_nonempty : p.support.Nonempty ↔ p ≠ 0 := Finset.nonempty_iff_ne_empty.trans support_eq_empty.not theorem card_support_eq_zero : #p.support = 0 ↔ p = 0 := by simp /-- `monomial s a` is the monomial `a * X^s` -/ def monomial (n : ℕ) : R →ₗ[R] R[X] where toFun t := ⟨Finsupp.single n t⟩ -- Porting note (https://github.com/leanprover-community/mathlib4/issues/10745): was `simp`. map_add' x y := by simp; rw [ofFinsupp_add] -- Porting note (https://github.com/leanprover-community/mathlib4/issues/10745): was `simp [← ofFinsupp_smul]`. map_smul' r x := by simp; rw [← ofFinsupp_smul, smul_single'] @[simp] theorem toFinsupp_monomial (n : ℕ) (r : R) : (monomial n r).toFinsupp = Finsupp.single n r := by simp [monomial] @[simp] theorem ofFinsupp_single (n : ℕ) (r : R) : (⟨Finsupp.single n r⟩ : R[X]) = monomial n r := by simp [monomial] @[simp] theorem monomial_zero_right (n : ℕ) : monomial n (0 : R) = 0 := (monomial n).map_zero -- This is not a `simp` lemma as `monomial_zero_left` is more general. theorem monomial_zero_one : monomial 0 (1 : R) = 1 := rfl -- TODO: can't we just delete this one? theorem monomial_add (n : ℕ) (r s : R) : monomial n (r + s) = monomial n r + monomial n s := (monomial n).map_add _ _ theorem monomial_mul_monomial (n m : ℕ) (r s : R) : monomial n r * monomial m s = monomial (n + m) (r * s) := toFinsupp_injective <\| by simp only [toFinsupp_monomial, toFinsupp_mul, AddMonoidAlgebra.single_mul_single] @[simp] theorem monomial_pow (n : ℕ) (r : R) (k : ℕ) : monomial n r ^ k = monomial (n * k) (r ^ k) := by induction k with \| zero => simp [pow_zero, monomial_zero_one] \| succ k ih => simp [pow_succ, ih, monomial_mul_monomial, mul_add, add_comm] theorem smul_monomial {S} [SMulZeroClass S R] (a : S) (n : ℕ) (b : R) : a • monomial n b = monomial n (a • b) := toFinsupp_injective <\| AddMonoidAlgebra.smul_single _ _ _ theorem monomial_injective (n : ℕ) : Function.Injective (monomial n : R → R[X]) := (toFinsuppIso R).symm.injective.comp (single_injective n) @[simp] theorem monomial_eq_zero_iff (t : R) (n : ℕ) : monomial n t = 0 ↔ t = 0 := LinearMap.map_eq_zero_iff _ (Polynomial.monomial_injective n) theorem monomial_eq_monomial_iff {m n : ℕ} {a b : R} : monomial m a = monomial n b ↔ m = n ∧ a = b ∨ a = 0 ∧ b = 0 := by rw [← toFinsupp_inj, toFinsupp_monomial, toFinsupp_monomial, Finsupp.single_eq_single_iff] theorem support_add : (p + q).support ⊆ p.support ∪ q.support := by simpa [support] using Finsupp.support_add /-- `C a` is the constant polynomial `a`. `C` is provided as a ring homomorphism. -/ def C : R →+* R[X] := { monomial 0 with map_one' := by simp [monomial_zero_one] map_mul' := by simp [monomial_mul_monomial] map_zero' := by simp } @[simp] theorem monomial_zero_left (a : R) : monomial 0 a = C a := rfl @[simp] theorem toFinsupp_C (a : R) : (C a).toFinsupp = single 0 a := rfl theorem C_0 : C (0 : R) = 0 := by simp theorem C_1 : C (1 : R) = 1 := rfl theorem C_mul : C (a * b) = C a * C b := C.map_mul a b theorem C_add : C (a + b) = C a + C b := C.map_add a b @[simp] theorem smul_C {S} [SMulZeroClass S R] (s : S) (r : R) : s • C r = C (s • r) := smul_monomial _ _ r theorem C_pow : C (a ^ n) = C a ^ n := C.map_pow a n theorem C_eq_natCast (n : ℕ) : C (n : R) = (n : R[X]) := map_natCast C n @[simp] theorem C_mul_monomial : C a * monomial n b = monomial n (a * b) := by simp only [← monomial_zero_left, monomial_mul_monomial, zero_add] @[simp] theorem monomial_mul_C : monomial n a * C b = monomial n (a * b) := by simp only [← monomial_zero_left, monomial_mul_monomial, add_zero] /-- `X` is the polynomial variable (aka indeterminate). -/ def X : R[X] := monomial 1 1 theorem monomial_one_one_eq_X : monomial 1 (1 : R) = X := rfl theorem monomial_one_right_eq_X_pow (n : ℕ) : monomial n (1 : R) = X ^ n := by induction n with \| zero => simp [monomial_zero_one] \| succ n ih => rw [pow_succ, ← ih, ← monomial_one_one_eq_X, monomial_mul_monomial, mul_one] @[simp] theorem toFinsupp_X : X.toFinsupp = Finsupp.single 1 (1 : R) := rfl theorem X_ne_C [Nontrivial R] (a : R) : X ≠ C a := by intro he simpa using monomial_eq_monomial_iff.1 he /-- `X` commutes with everything, even when the coefficients are noncommutative. -/ theorem X_mul : X * p = p * X := by rcases p with ⟨⟩ simp only [X, ← ofFinsupp_single, ← ofFinsupp_mul, LinearMap.coe_mk, ofFinsupp.injEq] ext simp [AddMonoidAlgebra.mul_apply, AddMonoidAlgebra.sum_single_index, add_comm] theorem X_pow_mul {n : ℕ} : X ^ n * p = p * X ^ n := by induction n with \| zero => simp \| succ n ih => conv_lhs => rw [pow_succ] rw [mul_assoc, X_mul, ← mul_assoc, ih, mul_assoc, ← pow_succ] /-- Prefer putting constants to the left of `X`. This lemma is the loop-avoiding `simp` version of `Polynomial.X_mul`. -/ @[simp] theorem X_mul_C (r : R) : X * C r = C r * X := X_mul /-- Prefer putting constants to the left of `X ^ n`. This lemma is the loop-avoiding `simp` version of `X_pow_mul`. -/ @[simp] theorem X_pow_mul_C (r : R) (n : ℕ) : X ^ n * C r = C r * X ^ n := X_pow_mul theorem X_pow_mul_assoc {n : ℕ} : p * X ^ n * q = p * q * X ^ n := by rw [mul_assoc, X_pow_mul, ← mul_assoc] /-- Prefer putting constants to the left of `X ^ n`. This lemma is the loop-avoiding `simp` version of `X_pow_mul_assoc`. -/ @[simp] theorem X_pow_mul_assoc_C {n : ℕ} (r : R) : p * X ^ n * C r = p * C r * X ^ n := X_pow_mul_assoc theorem commute_X (p : R[X]) : Commute X p := X_mul theorem commute_X_pow (p : R[X]) (n : ℕ) : Commute (X ^ n) p := X_pow_mul @[simp] theorem monomial_mul_X (n : ℕ) (r : R) : monomial n r * X = monomial (n + 1) r := by rw [X, monomial_mul_monomial, mul_one] @[simp] theorem monomial_mul_X_pow (n : ℕ) (r : R) (k : ℕ) : monomial n r * X ^ k = monomial (n + k) r := by induction k with \| zero => simp \| succ k ih => simp [ih, pow_succ, ← mul_assoc, add_assoc] @[simp] theorem X_mul_monomial (n : ℕ) (r : R) : X * monomial n r = monomial (n + 1) r := by rw [X_mul, monomial_mul_X] @[simp] theorem X_pow_mul_monomial (k n : ℕ) (r : R) : X ^ k * monomial n r = monomial (n + k) r := by rw [X_pow_mul, monomial_mul_X_pow] /-- `coeff p n` (often denoted `p.coeff n`) is the coefficient of `X^n` in `p`. -/ def coeff : R[X] → ℕ → R \| ⟨p⟩ => p @[simp] theorem coeff_ofFinsupp (p) : coeff (⟨p⟩ : R[X]) = p := by rw [coeff] theorem coeff_injective : Injective (coeff : R[X] → ℕ → R) := by rintro ⟨p⟩ ⟨q⟩ simp only [coeff, DFunLike.coe_fn_eq, imp_self, ofFinsupp.injEq] @[simp] theorem coeff_inj : p.coeff = q.coeff ↔ p = q := coeff_injective.eq_iff theorem toFinsupp_apply (f : R[X]) (i) : f.toFinsupp i = f.coeff i := by cases f; rfl theorem coeff_monomial : coeff (monomial n a) m = if n = m then a else 0 := by simp [coeff, Finsupp.single_apply] @[simp] theorem coeff_monomial_same (n : ℕ) (c : R) : (monomial n c).coeff n = c := Finsupp.single_eq_same theorem coeff_monomial_of_ne {m n : ℕ} (c : R) (h : n ≠ m) : (monomial n c).coeff m = 0 := Finsupp.single_eq_of_ne h @[simp] theorem coeff_zero (n : ℕ) : coeff (0 : R[X]) n = 0 := rfl theorem coeff_one {n : ℕ} : coeff (1 : R[X]) n = if n = 0 then 1 else 0 := by simp_rw [eq_comm (a := n) (b := 0)] exact coeff_monomial @[simp] theorem coeff_one_zero : coeff (1 : R[X]) 0 = 1 := by simp [coeff_one] @[simp] theorem coeff_X_one : coeff (X : R[X]) 1 = 1 := coeff_monomial @[simp] theorem coeff_X_zero : coeff (X : R[X]) 0 = 0 := coeff_monomial @[simp] theorem coeff_monomial_succ : coeff (monomial (n + 1) a) 0 = 0 := by simp [coeff_monomial] theorem coeff_X : coeff (X : R[X]) n = if 1 = n then 1 else 0 := coeff_monomial theorem coeff_X_of_ne_one {n : ℕ} (hn : n ≠ 1) : coeff (X : R[X]) n = 0 := by rw [coeff_X, if_neg hn.symm] @[simp] theorem mem_support_iff : n ∈ p.support ↔ p.coeff n ≠ 0 := by rcases p with ⟨⟩ simp theorem not_mem_support_iff : n ∉ p.support ↔ p.coeff n = 0 := by simp theorem coeff_C : coeff (C a) n = ite (n = 0) a 0 := by convert coeff_monomial (a := a) (m := n) (n := 0) using 2 simp [eq_comm] @[simp] theorem coeff_C_zero : coeff (C a) 0 = a := coeff_monomial theorem coeff_C_ne_zero (h : n ≠ 0) : (C a).coeff n = 0 := by rw [coeff_C, if_neg h] @[simp] lemma coeff_C_succ {r : R} {n : ℕ} : coeff (C r) (n + 1) = 0 := by simp [coeff_C] @[simp] theorem coeff_natCast_ite : (Nat.cast m : R[X]).coeff n = ite (n = 0) m 0 := by simp only [← C_eq_natCast, coeff_C, Nat.cast_ite, Nat.cast_zero] @[simp] theorem coeff_ofNat_zero (a : ℕ) [a.AtLeastTwo] : coeff (ofNat(a) : R[X]) 0 = ofNat(a) := coeff_monomial @[simp] theorem coeff_ofNat_succ (a n : ℕ) [h : a.AtLeastTwo] : coeff (ofNat(a) : R[X]) (n + 1) = 0 := by rw [← Nat.cast_ofNat] simp [-Nat.cast_ofNat] theorem C_mul_X_pow_eq_monomial : ∀ {n : ℕ}, C a * X ^ n = monomial n a \| 0 => mul_one _ \| n + 1 => by rw [pow_succ, ← mul_assoc, C_mul_X_pow_eq_monomial, X, monomial_mul_monomial, mul_one] @[simp high] theorem toFinsupp_C_mul_X_pow (a : R) (n : ℕ) : Polynomial.toFinsupp (C a * X ^ n) = Finsupp.single n a := by rw [C_mul_X_pow_eq_monomial, toFinsupp_monomial] theorem C_mul_X_eq_monomial : C a * X = monomial 1 a := by rw [← C_mul_X_pow_eq_monomial, pow_one] @[simp high] theorem toFinsupp_C_mul_X (a : R) : Polynomial.toFinsupp (C a * X) = Finsupp.single 1 a := by rw [C_mul_X_eq_monomial, toFinsupp_monomial] theorem C_injective : Injective (C : R → R[X]) := monomial_injective 0 @[simp] theorem C_inj : C a = C b ↔ a = b := C_injective.eq_iff @[simp] theorem C_eq_zero : C a = 0 ↔ a = 0 := C_injective.eq_iff' (map_zero C) theorem C_ne_zero : C a ≠ 0 ↔ a ≠ 0 := C_eq_zero.not theorem subsingleton_iff_subsingleton : Subsingleton R[X] ↔ Subsingleton R := ⟨@Injective.subsingleton _ _ _ C_injective, by intro infer_instance⟩ theorem Nontrivial.of_polynomial_ne (h : p ≠ q) : Nontrivial R := (subsingleton_or_nontrivial R).resolve_left fun _hI => h <\| Subsingleton.elim _ _ theorem forall_eq_iff_forall_eq : (∀ f g : R[X], f = g) ↔ ∀ a b : R, a = b := by simpa only [← subsingleton_iff] using subsingleton_iff_subsingleton theorem ext_iff {p q : R[X]} : p = q ↔ ∀ n, coeff p n = coeff q n := by rcases p with ⟨f : ℕ →₀ R⟩ rcases q with ⟨g : ℕ →₀ R⟩ simpa [coeff] using DFunLike.ext_iff (f := f) (g := g) @[ext] theorem ext {p q : R[X]} : (∀ n, coeff p n = coeff q n) → p = q := ext_iff.2 /-- Monomials generate the additive monoid of polynomials. -/ theorem addSubmonoid_closure_setOf_eq_monomial : AddSubmonoid.closure { p : R[X] \| ∃ n a, p = monomial n a } = ⊤ := by apply top_unique rw [← AddSubmonoid.map_equiv_top (toFinsuppIso R).symm.toAddEquiv, ← Finsupp.add_closure_setOf_eq_single, AddMonoidHom.map_mclosure] refine AddSubmonoid.closure_mono (Set.image_subset_iff.2 ?_) rintro _ ⟨n, a, rfl⟩ exact ⟨n, a, Polynomial.ofFinsupp_single _ _⟩ theorem addHom_ext {M : Type} [AddZeroClass M] {f g : R[X] →+ M} (h : ∀ n a, f (monomial n a) = g (monomial n a)) : f = g := AddMonoidHom.eq_of_eqOn_denseM addSubmonoid_closure_setOf_eq_monomial <\| by rintro p ⟨n, a, rfl⟩ exact h n a @[ext high] theorem addHom_ext' {M : Type} [AddZeroClass M] {f g : R[X] →+ M} (h : ∀ n, f.comp (monomial n).toAddMonoidHom = g.comp (monomial n).toAddMonoidHom) : f = g := addHom_ext fun n => DFunLike.congr_fun (h n) @[ext high] theorem lhom_ext' {M : Type} [AddCommMonoid M] [Module R M] {f g : R[X] →ₗ[R] M} (h : ∀ n, f.comp (monomial n) = g.comp (monomial n)) : f = g := LinearMap.toAddMonoidHom_injective <\| addHom_ext fun n => LinearMap.congr_fun (h n) -- this has the same content as the subsingleton theorem eq_zero_of_eq_zero (h : (0 : R) = (1 : R)) (p : R[X]) : p = 0 := by rw [← one_smul R p, ← h, zero_smul] section Fewnomials theorem support_monomial (n) {a : R} (H : a ≠ 0) : (monomial n a).support = singleton n := by rw [← ofFinsupp_single, support]; exact Finsupp.support_single_ne_zero _ H theorem support_monomial' (n) (a : R) : (monomial n a).support ⊆ singleton n := by rw [← ofFinsupp_single, support] exact Finsupp.support_single_subset theorem support_C {a : R} (h : a ≠ 0) : (C a).support = singleton 0 := support_monomial 0 h theorem support_C_subset (a : R) : (C a).support ⊆ singleton 0 := support_monomial' 0 a theorem support_C_mul_X {c : R} (h : c ≠ 0) : Polynomial.support (C c X) = singleton 1 := by rw [C_mul_X_eq_monomial, support_monomial 1 h] theorem support_C_mul_X' (c : R) : Polynomial.support (C c * X) ⊆ singleton 1 := by simpa only [C_mul_X_eq_monomial] using support_monomial' 1 c theorem support_C_mul_X_pow (n : ℕ) {c : R} (h : c ≠ 0) : Polynomial.support (C c * X ^ n) = singleton n := by rw [C_mul_X_pow_eq_monomial, support_monomial n h] theorem support_C_mul_X_pow' (n : ℕ) (c : R) : Polynomial.support (C c * X ^ n) ⊆ singleton n := by simpa only [C_mul_X_pow_eq_monomial] using support_monomial' n c open Finset theorem support_binomial' (k m : ℕ) (x y : R) : Polynomial.support (C x * X ^ k + C y * X ^ m) ⊆ {k, m} := support_add.trans (union_subset ((support_C_mul_X_pow' k x).trans (singleton_subset_iff.mpr (mem_insert_self k {m}))) ((support_C_mul_X_pow' m y).trans (singleton_subset_iff.mpr (mem_insert_of_mem (mem_singleton_self m))))) theorem support_trinomial' (k m n : ℕ) (x y z : R) : Polynomial.support (C x * X ^ k + C y * X ^ m + C z * X ^ n) ⊆ {k, m, n} := support_add.trans (union_subset (support_add.trans (union_subset ((support_C_mul_X_pow' k x).trans (singleton_subset_iff.mpr (mem_insert_self k {m, n}))) ((support_C_mul_X_pow' m y).trans (singleton_subset_iff.mpr (mem_insert_of_mem (mem_insert_self m {n})))))) ((support_C_mul_X_pow' n z).trans (singleton_subset_iff.mpr (mem_insert_of_mem (mem_insert_of_mem (mem_singleton_self n)))))) end Fewnomials theorem X_pow_eq_monomial (n) : X ^ n = monomial n (1 : R) := by induction n with \| zero => rw [pow_zero, monomial_zero_one] \| succ n hn => rw [pow_succ, hn, X, monomial_mul_monomial, one_mul] @[simp high] theorem toFinsupp_X_pow (n : ℕ) : (X ^ n).toFinsupp = Finsupp.single n (1 : R) := by rw [X_pow_eq_monomial, toFinsupp_monomial] theorem smul_X_eq_monomial {n} : a • X ^ n = monomial n (a : R) := by rw [X_pow_eq_monomial, smul_monomial, smul_eq_mul, mul_one] theorem support_X_pow (H : ¬(1 : R) = 0) (n : ℕ) : (X ^ n : R[X]).support = singleton n := by convert support_monomial n H exact X_pow_eq_monomial n theorem support_X_empty (H : (1 : R) = 0) : (X : R[X]).support = ∅ := by rw [X, H, monomial_zero_right, support_zero] theorem support_X (H : ¬(1 : R) = 0) : (X : R[X]).support = singleton 1 := by rw [← pow_one X, support_X_pow H 1] theorem monomial_left_inj {a : R} (ha : a ≠ 0) {i j : ℕ} : monomial i a = monomial j a ↔ i = j := by simp only [← ofFinsupp_single, ofFinsupp.injEq, Finsupp.single_left_inj ha] theorem binomial_eq_binomial {k l m n : ℕ} {u v : R} (hu : u ≠ 0) (hv : v ≠ 0) : C u * X ^ k + C v * X ^ l = C u * X ^ m + C v * X ^ n ↔ k = m ∧ l = n ∨ u = v ∧ k = n ∧ l = m ∨ u + v = 0 ∧ k = l ∧ m = n := by simp_rw [C_mul_X_pow_eq_monomial, ← toFinsupp_inj, toFinsupp_add, toFinsupp_monomial] exact Finsupp.single_add_single_eq_single_add_single hu hv theorem natCast_mul (n : ℕ) (p : R[X]) : (n : R[X]) * p = n • p := (nsmul_eq_mul _ _).symm /-- Summing the values of a function applied to the coefficients of a polynomial -/ def sum {S : Type} [AddCommMonoid S] (p : R[X]) (f : ℕ → R → S) : S := ∑ n ∈ p.support, f n (p.coeff n) theorem sum_def {S : Type} [AddCommMonoid S] (p : R[X]) (f : ℕ → R → S) : p.sum f = ∑ n ∈ p.support, f n (p.coeff n) := rfl theorem sum_eq_of_subset {S : Type} [AddCommMonoid S] {p : R[X]} (f : ℕ → R → S) (hf : ∀ i, f i 0 = 0) {s : Finset ℕ} (hs : p.support ⊆ s) : p.sum f = ∑ n ∈ s, f n (p.coeff n) := Finsupp.sum_of_support_subset _ hs f (fun i _ ↦ hf i) /-- Expressing the product of two polynomials as a double sum. -/ theorem mul_eq_sum_sum : p q = ∑ i ∈ p.support, q.sum fun j a => (monomial (i + j)) (p.coeff i * a) := by apply toFinsupp_injective rcases p with ⟨⟩; rcases q with ⟨⟩ simp_rw [sum, coeff, toFinsupp_sum, support, toFinsupp_mul, toFinsupp_monomial, AddMonoidAlgebra.mul_def, Finsupp.sum] @[simp] theorem sum_zero_index {S : Type} [AddCommMonoid S] (f : ℕ → R → S) : (0 : R[X]).sum f = 0 := by simp [sum] @[simp] theorem sum_monomial_index {S : Type} [AddCommMonoid S] {n : ℕ} (a : R) (f : ℕ → R → S) (hf : f n 0 = 0) : (monomial n a : R[X]).sum f = f n a := Finsupp.sum_single_index hf @[simp] theorem sum_C_index {a} {β} [AddCommMonoid β] {f : ℕ → R → β} (h : f 0 0 = 0) : (C a).sum f = f 0 a := sum_monomial_index a f h -- the assumption `hf` is only necessary when the ring is trivial @[simp] theorem sum_X_index {S : Type} [AddCommMonoid S] {f : ℕ → R → S} (hf : f 1 0 = 0) : (X : R[X]).sum f = f 1 1 := sum_monomial_index 1 f hf theorem sum_add_index {S : Type} [AddCommMonoid S] (p q : R[X]) (f : ℕ → R → S) (hf : ∀ i, f i 0 = 0) (h_add : ∀ a b₁ b₂, f a (b₁ + b₂) = f a b₁ + f a b₂) : (p + q).sum f = p.sum f + q.sum f := by rw [show p + q = ⟨p.toFinsupp + q.toFinsupp⟩ from add_def p q] exact Finsupp.sum_add_index (fun i _ ↦ hf i) (fun a _ b₁ b₂ ↦ h_add a b₁ b₂) theorem sum_add' {S : Type} [AddCommMonoid S] (p : R[X]) (f g : ℕ → R → S) : p.sum (f + g) = p.sum f + p.sum g := by simp [sum_def, Finset.sum_add_distrib] theorem sum_add {S : Type} [AddCommMonoid S] (p : R[X]) (f g : ℕ → R → S) : (p.sum fun n x => f n x + g n x) = p.sum f + p.sum g := sum_add' _ _ _ theorem sum_smul_index {S : Type} [AddCommMonoid S] (p : R[X]) (b : R) (f : ℕ → R → S) (hf : ∀ i, f i 0 = 0) : (b • p).sum f = p.sum fun n a => f n (b a) := Finsupp.sum_smul_index hf theorem sum_smul_index' {S T : Type} [DistribSMul T R] [AddCommMonoid S] (p : R[X]) (b : T) (f : ℕ → R → S) (hf : ∀ i, f i 0 = 0) : (b • p).sum f = p.sum fun n a => f n (b • a) := Finsupp.sum_smul_index' hf protected theorem smul_sum {S T : Type} [AddCommMonoid S] [DistribSMul T S] (p : R[X]) (b : T) (f : ℕ → R → S) : b • p.sum f = p.sum fun n a => b • f n a := Finsupp.smul_sum @[simp] theorem sum_monomial_eq : ∀ p : R[X], (p.sum fun n a => monomial n a) = p \| ⟨_p⟩ => (ofFinsupp_sum _ _).symm.trans (congr_arg _ <\| Finsupp.sum_single _) theorem sum_C_mul_X_pow_eq (p : R[X]) : (p.sum fun n a => C a * X ^ n) = p := by simp_rw [C_mul_X_pow_eq_monomial, sum_monomial_eq] @[elab_as_elim] protected theorem induction_on {motive : R[X] → Prop} (p : R[X]) (C : ∀ a, motive (C a)) (add : ∀ p q, motive p → motive q → motive (p + q)) (monomial : ∀ (n : ℕ) (a : R), motive (Polynomial.C a * X ^ n) → motive (Polynomial.C a * X ^ (n + 1))) : motive p := by have A : ∀ {n : ℕ} {a}, motive (Polynomial.C a * X ^ n) := by intro n a induction n with \| zero => rw [pow_zero, mul_one]; exact C a \| succ n ih => exact monomial _ _ ih have B : ∀ s : Finset ℕ, motive (s.sum fun n : ℕ => Polynomial.C (p.coeff n) * X ^ n) := by apply Finset.induction · convert C 0 exact C_0.symm · intro n s ns ih rw [sum_insert ns] exact add _ _ A ih rw [← sum_C_mul_X_pow_eq p, Polynomial.sum] exact B (support p) /-- To prove something about polynomials, it suffices to show the condition is closed under taking sums, and it holds for monomials. -/ @[elab_as_elim] protected theorem induction_on' {motive : R[X] → Prop} (p : R[X]) (add : ∀ p q, motive p → motive q → motive (p + q)) (monomial : ∀ (n : ℕ) (a : R), motive (monomial n a)) : motive p := Polynomial.induction_on p (monomial 0) add fun n a _h => by rw [C_mul_X_pow_eq_monomial]; exact monomial _ _ /-- `erase p n` is the polynomial `p` in which the `X^n` term has been erased. -/ irreducible_def erase (n : ℕ) : R[X] → R[X] \| ⟨p⟩ => ⟨p.erase n⟩ @[simp] theorem toFinsupp_erase (p : R[X]) (n : ℕ) : toFinsupp (p.erase n) = p.toFinsupp.erase n := by rcases p with ⟨⟩ simp only [erase_def] @[simp] theorem ofFinsupp_erase (p : R[ℕ]) (n : ℕ) : (⟨p.erase n⟩ : R[X]) = (⟨p⟩ : R[X]).erase n := by rcases p with ⟨⟩ simp only [erase_def] @[simp] theorem support_erase (p : R[X]) (n : ℕ) : support (p.erase n) = (support p).erase n := by rcases p with ⟨⟩ simp only [support, erase_def, Finsupp.support_erase] theorem monomial_add_erase (p : R[X]) (n : ℕ) : monomial n (coeff p n) + p.erase n = p := toFinsupp_injective <\| by rcases p with ⟨⟩ rw [toFinsupp_add, toFinsupp_monomial, toFinsupp_erase, coeff] exact Finsupp.single_add_erase _ _ theorem coeff_erase (p : R[X]) (n i : ℕ) : (p.erase n).coeff i = if i = n then 0 else p.coeff i := by rcases p with ⟨⟩ simp only [erase_def, coeff] exact ite_congr rfl (fun _ => rfl) (fun _ => rfl) @[simp] theorem erase_zero (n : ℕ) : (0 : R[X]).erase n = 0 := toFinsupp_injective <\| by simp @[simp] theorem erase_monomial {n : ℕ} {a : R} : erase n (monomial n a) = 0 := toFinsupp_injective <\| by simp @[simp] theorem erase_same (p : R[X]) (n : ℕ) : coeff (p.erase n) n = 0 := by simp [coeff_erase] @[simp] theorem erase_ne (p : R[X]) (n i : ℕ) (h : i ≠ n) : coeff (p.erase n) i = coeff p i := by simp [coeff_erase, h] section Update /-- Replace the coefficient of a `p : R[X]` at a given degree `n : ℕ` by a given value `a : R`. If `a = 0`, this is equal to `p.erase n` If `p.natDegree < n` and `a ≠ 0`, this increases the degree to `n`. -/ def update (p : R[X]) (n : ℕ) (a : R) : R[X] := Polynomial.ofFinsupp (p.toFinsupp.update n a) theorem coeff_update (p : R[X]) (n : ℕ) (a : R) : (p.update n a).coeff = Function.update p.coeff n a := by ext cases p simp only [coeff, update, Function.update_apply, coe_update] theorem coeff_update_apply (p : R[X]) (n : ℕ) (a : R) (i : ℕ) : (p.update n a).coeff i = if i = n then a else p.coeff i := by rw [coeff_update, Function.update_apply] @[simp] theorem coeff_update_same (p : R[X]) (n : ℕ) (a : R) : (p.update n a).coeff n = a := by rw [p.coeff_update_apply, if_pos rfl] theorem coeff_update_ne (p : R[X]) {n : ℕ} (a : R) {i : ℕ} (h : i ≠ n) : (p.update n a).coeff i = p.coeff i := by rw [p.coeff_update_apply, if_neg h] @[simp] theorem update_zero_eq_erase (p : R[X]) (n : ℕ) : p.update n 0 = p.erase n := by ext rw [coeff_update_apply, coeff_erase] theorem support_update (p : R[X]) (n : ℕ) (a : R) [Decidable (a = 0)] : support (p.update n a) = if a = 0 then p.support.erase n else insert n p.support := by classical cases p simp only [support, update, Finsupp.support_update] congr theorem support_update_zero (p : R[X]) (n : ℕ) : support (p.update n 0) = p.support.erase n := by rw [update_zero_eq_erase, support_erase] theorem support_update_ne_zero (p : R[X]) (n : ℕ) {a : R} (ha : a ≠ 0) : support (p.update n a) = insert n p.support := by classical rw [support_update, if_neg ha] end Update /-- The finset of nonzero coefficients of a polynomial. -/ def coeffs (p : R[X]) : Finset R := letI := Classical.decEq R Finset.image (fun n => p.coeff n) p.support @[simp] theorem coeffs_zero : coeffs (0 : R[X]) = ∅ := rfl theorem mem_coeffs_iff {p : R[X]} {c : R} : c ∈ p.coeffs ↔ ∃ n ∈ p.support, c = p.coeff n := by simp [coeffs, eq_comm, (Finset.mem_image)] theorem coeffs_one : coeffs (1 : R[X]) ⊆ {1} := by classical simp_rw [coeffs, Finset.image_subset_iff] simp_all [coeff_one] theorem coeff_mem_coeffs (p : R[X]) (n : ℕ) (h : p.coeff n ≠ 0) : p.coeff n ∈ p.coeffs := by classical simp only [coeffs, exists_prop, mem_support_iff, Finset.mem_image, Ne] exact ⟨n, h, rfl⟩ theorem coeffs_monomial (n : ℕ) {c : R} (hc : c ≠ 0) : (monomial n c).coeffs = {c} := by rw [coeffs, support_monomial n hc] simp end Semiring section CommSemiring variable [CommSemiring R] instance commSemiring : CommSemiring R[X] := fast_instance% { Function.Injective.commSemigroup toFinsupp toFinsupp_injective toFinsupp_mul with toSemiring := Polynomial.semiring } end CommSemiring section Ring variable [Ring R] instance instZSMul : SMul ℤ R[X] where smul r p := ⟨r • p.toFinsupp⟩ @[simp] theorem ofFinsupp_zsmul (a : ℤ) (b) : (⟨a • b⟩ : R[X]) = (a • ⟨b⟩ : R[X]) := rfl @[simp] theorem toFinsupp_zsmul (a : ℤ) (b : R[X]) : (a • b).toFinsupp = a • b.toFinsupp := rfl instance instIntCast : IntCast R[X] where intCast n := ofFinsupp n @[simp]	theorem ofFinsupp_intCast (z : ℤ) : (⟨z⟩ : R[X]) = z := rfl	Mathlib/Algebra/Polynomial/Basic.lean	1,089	1,090
/- 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.Logic.Equiv.PartialEquiv import Mathlib.Topology.Homeomorph.Lemmas import Mathlib.Topology.Sets.Opens /-! # Partial homeomorphisms This file defines homeomorphisms between open subsets of topological spaces. An element `e` of `PartialHomeomorph X Y` is an extension of `PartialEquiv X Y`, i.e., it is a pair of functions `e.toFun` and `e.invFun`, inverse of each other on the sets `e.source` and `e.target`. Additionally, we require that these sets are open, and that the functions are continuous on them. Equivalently, they are homeomorphisms there. As in equivs, we register a coercion to functions, and we use `e x` and `e.symm x` throughout instead of `e.toFun x` and `e.invFun x`. ## Main definitions * `Homeomorph.toPartialHomeomorph`: associating a partial homeomorphism to a homeomorphism, with `source = target = Set.univ`; * `PartialHomeomorph.symm`: the inverse of a partial homeomorphism * `PartialHomeomorph.trans`: the composition of two partial homeomorphisms * `PartialHomeomorph.refl`: the identity partial homeomorphism * `PartialHomeomorph.const`: a partial homeomorphism which is a constant map, whose source and target are necessarily singleton sets * `PartialHomeomorph.ofSet`: the identity on a set `s` * `PartialHomeomorph.restr s`: restrict a partial homeomorphism `e` to `e.source ∩ interior s` * `PartialHomeomorph.EqOnSource`: equivalence relation describing the "right" notion of equality for partial homeomorphisms * `PartialHomeomorph.prod`: the product of two partial homeomorphisms, as a partial homeomorphism on the product space * `PartialHomeomorph.pi`: the product of a finite family of partial homeomorphisms * `PartialHomeomorph.disjointUnion`: combine two partial homeomorphisms with disjoint sources and disjoint targets * `PartialHomeomorph.lift_openEmbedding`: extend a partial homeomorphism `X → Y` under an open embedding `X → X'`, to a partial homeomorphism `X' → Z`. (This is used to define the disjoint union of charted spaces.) ## Implementation notes Most statements are copied from their `PartialEquiv` versions, although some care is required especially when restricting to subsets, as these should be open subsets. For design notes, see `PartialEquiv.lean`. ### Local coding conventions If a lemma deals with the intersection of a set with either source or target of a `PartialEquiv`, then it should use `e.source ∩ s` or `e.target ∩ t`, not `s ∩ e.source` or `t ∩ e.target`. -/ open Function Set Filter Topology variable {X X' : Type} {Y Y' : Type} {Z Z' : Type} [TopologicalSpace X] [TopologicalSpace X'] [TopologicalSpace Y] [TopologicalSpace Y'] [TopologicalSpace Z] [TopologicalSpace Z'] /-- Partial homeomorphisms, defined on open subsets of the space -/ structure PartialHomeomorph (X : Type) (Y : Type*) [TopologicalSpace X] [TopologicalSpace Y] extends PartialEquiv X Y where open_source : IsOpen source open_target : IsOpen target continuousOn_toFun : ContinuousOn toFun source continuousOn_invFun : ContinuousOn invFun target namespace PartialHomeomorph variable (e : PartialHomeomorph X Y) /-! Basic properties; inverse (symm instance) -/ section Basic /-- Coercion of a partial homeomorphisms to a function. We don't use `e.toFun` because it is actually `e.toPartialEquiv.toFun`, so `simp` will apply lemmas about `toPartialEquiv`. While we may want to switch to this behavior later, doing it mid-port will break a lot of proofs. -/ @[coe] def toFun' : X → Y := e.toFun /-- Coercion of a `PartialHomeomorph` to function. Note that a `PartialHomeomorph` is not `DFunLike`. -/ instance : CoeFun (PartialHomeomorph X Y) fun _ => X → Y := ⟨fun e => e.toFun'⟩ /-- The inverse of a partial homeomorphism -/ @[symm] protected def symm : PartialHomeomorph Y X where toPartialEquiv := e.toPartialEquiv.symm open_source := e.open_target open_target := e.open_source continuousOn_toFun := e.continuousOn_invFun continuousOn_invFun := e.continuousOn_toFun /-- See Note [custom simps projection]. We need to specify this projection explicitly in this case, because it is a composition of multiple projections. -/ def Simps.apply (e : PartialHomeomorph X Y) : X → Y := e /-- See Note [custom simps projection] -/ def Simps.symm_apply (e : PartialHomeomorph X Y) : Y → X := e.symm initialize_simps_projections PartialHomeomorph (toFun → apply, invFun → symm_apply) protected theorem continuousOn : ContinuousOn e e.source := e.continuousOn_toFun theorem continuousOn_symm : ContinuousOn e.symm e.target := e.continuousOn_invFun @[simp, mfld_simps] theorem mk_coe (e : PartialEquiv X Y) (a b c d) : (PartialHomeomorph.mk e a b c d : X → Y) = e := rfl @[simp, mfld_simps] theorem mk_coe_symm (e : PartialEquiv X Y) (a b c d) : ((PartialHomeomorph.mk e a b c d).symm : Y → X) = e.symm := rfl theorem toPartialEquiv_injective : Injective (toPartialEquiv : PartialHomeomorph X Y → PartialEquiv X Y) \| ⟨_, _, _, _, _⟩, ⟨_, _, _, _, _⟩, rfl => rfl /- Register a few simp lemmas to make sure that `simp` puts the application of a local homeomorphism in its normal form, i.e., in terms of its coercion to a function. -/ @[simp, mfld_simps] theorem toFun_eq_coe (e : PartialHomeomorph X Y) : e.toFun = e := rfl @[simp, mfld_simps] theorem invFun_eq_coe (e : PartialHomeomorph X Y) : e.invFun = e.symm := rfl @[simp, mfld_simps] theorem coe_coe : (e.toPartialEquiv : X → Y) = e := rfl @[simp, mfld_simps] theorem coe_coe_symm : (e.toPartialEquiv.symm : Y → X) = e.symm := rfl @[simp, mfld_simps] theorem map_source {x : X} (h : x ∈ e.source) : e x ∈ e.target := e.map_source' h /-- Variant of `map_source`, stated for images of subsets of `source`. -/ lemma map_source'' : e '' e.source ⊆ e.target := fun _ ⟨_, hx, hex⟩ ↦ mem_of_eq_of_mem (id hex.symm) (e.map_source' hx) @[simp, mfld_simps] theorem map_target {x : Y} (h : x ∈ e.target) : e.symm x ∈ e.source := e.map_target' h @[simp, mfld_simps] theorem left_inv {x : X} (h : x ∈ e.source) : e.symm (e x) = x := e.left_inv' h @[simp, mfld_simps] theorem right_inv {x : Y} (h : x ∈ e.target) : e (e.symm x) = x := e.right_inv' h theorem eq_symm_apply {x : X} {y : Y} (hx : x ∈ e.source) (hy : y ∈ e.target) : x = e.symm y ↔ e x = y := e.toPartialEquiv.eq_symm_apply hx hy protected theorem mapsTo : MapsTo e e.source e.target := fun _ => e.map_source protected theorem symm_mapsTo : MapsTo e.symm e.target e.source := e.symm.mapsTo protected theorem leftInvOn : LeftInvOn e.symm e e.source := fun _ => e.left_inv protected theorem rightInvOn : RightInvOn e.symm e e.target := fun _ => e.right_inv protected theorem invOn : InvOn e.symm e e.source e.target := ⟨e.leftInvOn, e.rightInvOn⟩ protected theorem injOn : InjOn e e.source := e.leftInvOn.injOn protected theorem bijOn : BijOn e e.source e.target := e.invOn.bijOn e.mapsTo e.symm_mapsTo protected theorem surjOn : SurjOn e e.source e.target := e.bijOn.surjOn end Basic /-- Interpret a `Homeomorph` as a `PartialHomeomorph` by restricting it to an open set `s` in the domain and to `t` in the codomain. -/ @[simps! -fullyApplied apply symm_apply toPartialEquiv, simps! -isSimp source target] def _root_.Homeomorph.toPartialHomeomorphOfImageEq (e : X ≃ₜ Y) (s : Set X) (hs : IsOpen s) (t : Set Y) (h : e '' s = t) : PartialHomeomorph X Y where toPartialEquiv := e.toPartialEquivOfImageEq s t h open_source := hs open_target := by simpa [← h] continuousOn_toFun := e.continuous.continuousOn continuousOn_invFun := e.symm.continuous.continuousOn /-- A homeomorphism induces a partial homeomorphism on the whole space -/ @[simps! (config := mfld_cfg)] def _root_.Homeomorph.toPartialHomeomorph (e : X ≃ₜ Y) : PartialHomeomorph X Y := e.toPartialHomeomorphOfImageEq univ isOpen_univ univ <\| by rw [image_univ, e.surjective.range_eq] /-- Replace `toPartialEquiv` field to provide better definitional equalities. -/ def replaceEquiv (e : PartialHomeomorph X Y) (e' : PartialEquiv X Y) (h : e.toPartialEquiv = e') : PartialHomeomorph X Y where toPartialEquiv := e' open_source := h ▸ e.open_source open_target := h ▸ e.open_target continuousOn_toFun := h ▸ e.continuousOn_toFun continuousOn_invFun := h ▸ e.continuousOn_invFun theorem replaceEquiv_eq_self (e' : PartialEquiv X Y) (h : e.toPartialEquiv = e') : e.replaceEquiv e' h = e := by cases e subst e' rfl theorem source_preimage_target : e.source ⊆ e ⁻¹' e.target := e.mapsTo theorem eventually_left_inverse {x} (hx : x ∈ e.source) : ∀ᶠ y in 𝓝 x, e.symm (e y) = y := (e.open_source.eventually_mem hx).mono e.left_inv' theorem eventually_left_inverse' {x} (hx : x ∈ e.target) : ∀ᶠ y in 𝓝 (e.symm x), e.symm (e y) = y := e.eventually_left_inverse (e.map_target hx) theorem eventually_right_inverse {x} (hx : x ∈ e.target) : ∀ᶠ y in 𝓝 x, e (e.symm y) = y := (e.open_target.eventually_mem hx).mono e.right_inv' theorem eventually_right_inverse' {x} (hx : x ∈ e.source) : ∀ᶠ y in 𝓝 (e x), e (e.symm y) = y := e.eventually_right_inverse (e.map_source hx) theorem eventually_ne_nhdsWithin {x} (hx : x ∈ e.source) : ∀ᶠ x' in 𝓝[≠] x, e x' ≠ e x := eventually_nhdsWithin_iff.2 <\| (e.eventually_left_inverse hx).mono fun x' hx' => mt fun h => by rw [mem_singleton_iff, ← e.left_inv hx, ← h, hx'] theorem nhdsWithin_source_inter {x} (hx : x ∈ e.source) (s : Set X) : 𝓝[e.source ∩ s] x = 𝓝[s] x := nhdsWithin_inter_of_mem (mem_nhdsWithin_of_mem_nhds <\| IsOpen.mem_nhds e.open_source hx) theorem nhdsWithin_target_inter {x} (hx : x ∈ e.target) (s : Set Y) : 𝓝[e.target ∩ s] x = 𝓝[s] x := e.symm.nhdsWithin_source_inter hx s theorem image_eq_target_inter_inv_preimage {s : Set X} (h : s ⊆ e.source) : e '' s = e.target ∩ e.symm ⁻¹' s := e.toPartialEquiv.image_eq_target_inter_inv_preimage h theorem image_source_inter_eq' (s : Set X) : e '' (e.source ∩ s) = e.target ∩ e.symm ⁻¹' s := e.toPartialEquiv.image_source_inter_eq' s theorem image_source_inter_eq (s : Set X) : e '' (e.source ∩ s) = e.target ∩ e.symm ⁻¹' (e.source ∩ s) := e.toPartialEquiv.image_source_inter_eq s theorem symm_image_eq_source_inter_preimage {s : Set Y} (h : s ⊆ e.target) : e.symm '' s = e.source ∩ e ⁻¹' s := e.symm.image_eq_target_inter_inv_preimage h theorem symm_image_target_inter_eq (s : Set Y) : e.symm '' (e.target ∩ s) = e.source ∩ e ⁻¹' (e.target ∩ s) := e.symm.image_source_inter_eq _ theorem source_inter_preimage_inv_preimage (s : Set X) : e.source ∩ e ⁻¹' (e.symm ⁻¹' s) = e.source ∩ s := e.toPartialEquiv.source_inter_preimage_inv_preimage s theorem target_inter_inv_preimage_preimage (s : Set Y) : e.target ∩ e.symm ⁻¹' (e ⁻¹' s) = e.target ∩ s := e.symm.source_inter_preimage_inv_preimage _ theorem source_inter_preimage_target_inter (s : Set Y) : e.source ∩ e ⁻¹' (e.target ∩ s) = e.source ∩ e ⁻¹' s := e.toPartialEquiv.source_inter_preimage_target_inter s theorem image_source_eq_target : e '' e.source = e.target := e.toPartialEquiv.image_source_eq_target theorem symm_image_target_eq_source : e.symm '' e.target = e.source := e.symm.image_source_eq_target /-- Two partial homeomorphisms are equal when they have equal `toFun`, `invFun` and `source`. It is not sufficient to have equal `toFun` and `source`, as this only determines `invFun` on the target. This would only be true for a weaker notion of equality, arguably the right one, called `EqOnSource`. -/ @[ext] protected theorem ext (e' : PartialHomeomorph X Y) (h : ∀ x, e x = e' x) (hinv : ∀ x, e.symm x = e'.symm x) (hs : e.source = e'.source) : e = e' := toPartialEquiv_injective (PartialEquiv.ext h hinv hs) @[simp, mfld_simps] theorem symm_toPartialEquiv : e.symm.toPartialEquiv = e.toPartialEquiv.symm := rfl -- The following lemmas are already simp via `PartialEquiv` theorem symm_source : e.symm.source = e.target := rfl theorem symm_target : e.symm.target = e.source := rfl @[simp, mfld_simps] theorem symm_symm : e.symm.symm = e := rfl theorem symm_bijective : Function.Bijective (PartialHomeomorph.symm : PartialHomeomorph X Y → PartialHomeomorph Y X) := Function.bijective_iff_has_inverse.mpr ⟨_, symm_symm, symm_symm⟩ /-- A partial homeomorphism is continuous at any point of its source -/ protected theorem continuousAt {x : X} (h : x ∈ e.source) : ContinuousAt e x := (e.continuousOn x h).continuousAt (e.open_source.mem_nhds h) /-- A partial homeomorphism inverse is continuous at any point of its target -/ theorem continuousAt_symm {x : Y} (h : x ∈ e.target) : ContinuousAt e.symm x := e.symm.continuousAt h theorem tendsto_symm {x} (hx : x ∈ e.source) : Tendsto e.symm (𝓝 (e x)) (𝓝 x) := by simpa only [ContinuousAt, e.left_inv hx] using e.continuousAt_symm (e.map_source hx) theorem map_nhds_eq {x} (hx : x ∈ e.source) : map e (𝓝 x) = 𝓝 (e x) := le_antisymm (e.continuousAt hx) <\| le_map_of_right_inverse (e.eventually_right_inverse' hx) (e.tendsto_symm hx) theorem symm_map_nhds_eq {x} (hx : x ∈ e.source) : map e.symm (𝓝 (e x)) = 𝓝 x := (e.symm.map_nhds_eq <\| e.map_source hx).trans <\| by rw [e.left_inv hx] theorem image_mem_nhds {x} (hx : x ∈ e.source) {s : Set X} (hs : s ∈ 𝓝 x) : e '' s ∈ 𝓝 (e x) := e.map_nhds_eq hx ▸ Filter.image_mem_map hs theorem map_nhdsWithin_eq {x} (hx : x ∈ e.source) (s : Set X) : map e (𝓝[s] x) = 𝓝[e '' (e.source ∩ s)] e x := calc map e (𝓝[s] x) = map e (𝓝[e.source ∩ s] x) := congr_arg (map e) (e.nhdsWithin_source_inter hx _).symm _ = 𝓝[e '' (e.source ∩ s)] e x := (e.leftInvOn.mono inter_subset_left).map_nhdsWithin_eq (e.left_inv hx) (e.continuousAt_symm (e.map_source hx)).continuousWithinAt (e.continuousAt hx).continuousWithinAt theorem map_nhdsWithin_preimage_eq {x} (hx : x ∈ e.source) (s : Set Y) : map e (𝓝[e ⁻¹' s] x) = 𝓝[s] e x := by rw [e.map_nhdsWithin_eq hx, e.image_source_inter_eq', e.target_inter_inv_preimage_preimage, e.nhdsWithin_target_inter (e.map_source hx)] theorem eventually_nhds {x : X} (p : Y → Prop) (hx : x ∈ e.source) : (∀ᶠ y in 𝓝 (e x), p y) ↔ ∀ᶠ x in 𝓝 x, p (e x) := Iff.trans (by rw [e.map_nhds_eq hx]) eventually_map theorem eventually_nhds' {x : X} (p : X → Prop) (hx : x ∈ e.source) : (∀ᶠ y in 𝓝 (e x), p (e.symm y)) ↔ ∀ᶠ x in 𝓝 x, p x := by rw [e.eventually_nhds _ hx] refine eventually_congr ((e.eventually_left_inverse hx).mono fun y hy => ?_) rw [hy] theorem eventually_nhdsWithin {x : X} (p : Y → Prop) {s : Set X} (hx : x ∈ e.source) : (∀ᶠ y in 𝓝[e.symm ⁻¹' s] e x, p y) ↔ ∀ᶠ x in 𝓝[s] x, p (e x) := by refine Iff.trans ?_ eventually_map rw [e.map_nhdsWithin_eq hx, e.image_source_inter_eq', e.nhdsWithin_target_inter (e.mapsTo hx)] theorem eventually_nhdsWithin' {x : X} (p : X → Prop) {s : Set X} (hx : x ∈ e.source) : (∀ᶠ y in 𝓝[e.symm ⁻¹' s] e x, p (e.symm y)) ↔ ∀ᶠ x in 𝓝[s] x, p x := by rw [e.eventually_nhdsWithin _ hx] refine eventually_congr <\| (eventually_nhdsWithin_of_eventually_nhds <\| e.eventually_left_inverse hx).mono fun y hy => ?_ rw [hy] /-- This lemma is useful in the manifold library in the case that `e` is a chart. It states that locally around `e x` the set `e.symm ⁻¹' s` is the same as the set intersected with the target of `e` and some other neighborhood of `f x` (which will be the source of a chart on `Z`). -/ theorem preimage_eventuallyEq_target_inter_preimage_inter {e : PartialHomeomorph X Y} {s : Set X} {t : Set Z} {x : X} {f : X → Z} (hf : ContinuousWithinAt f s x) (hxe : x ∈ e.source) (ht : t ∈ 𝓝 (f x)) : e.symm ⁻¹' s =ᶠ[𝓝 (e x)] (e.target ∩ e.symm ⁻¹' (s ∩ f ⁻¹' t) : Set Y) := by rw [eventuallyEq_set, e.eventually_nhds _ hxe] filter_upwards [e.open_source.mem_nhds hxe, mem_nhdsWithin_iff_eventually.mp (hf.preimage_mem_nhdsWithin ht)] intro y hy hyu simp_rw [mem_inter_iff, mem_preimage, mem_inter_iff, e.mapsTo hy, true_and, iff_self_and, e.left_inv hy, iff_true_intro hyu] theorem isOpen_inter_preimage {s : Set Y} (hs : IsOpen s) : IsOpen (e.source ∩ e ⁻¹' s) := e.continuousOn.isOpen_inter_preimage e.open_source hs theorem isOpen_inter_preimage_symm {s : Set X} (hs : IsOpen s) : IsOpen (e.target ∩ e.symm ⁻¹' s) := e.symm.continuousOn.isOpen_inter_preimage e.open_target hs /-- A partial homeomorphism is an open map on its source: the image of an open subset of the source is open. -/ lemma isOpen_image_of_subset_source {s : Set X} (hs : IsOpen s) (hse : s ⊆ e.source) : IsOpen (e '' s) := by rw [(image_eq_target_inter_inv_preimage (e := e) hse)] exact e.continuousOn_invFun.isOpen_inter_preimage e.open_target hs /-- The image of the restriction of an open set to the source is open. -/ theorem isOpen_image_source_inter {s : Set X} (hs : IsOpen s) : IsOpen (e '' (e.source ∩ s)) := e.isOpen_image_of_subset_source (e.open_source.inter hs) inter_subset_left /-- The inverse of a partial homeomorphism `e` is an open map on `e.target`. -/ lemma isOpen_image_symm_of_subset_target {t : Set Y} (ht : IsOpen t) (hte : t ⊆ e.target) : IsOpen (e.symm '' t) := isOpen_image_of_subset_source e.symm ht (e.symm_source ▸ hte) lemma isOpen_symm_image_iff_of_subset_target {t : Set Y} (hs : t ⊆ e.target) : IsOpen (e.symm '' t) ↔ IsOpen t := by refine ⟨fun h ↦ ?_, fun h ↦ e.symm.isOpen_image_of_subset_source h hs⟩ have hs' : e.symm '' t ⊆ e.source := by rw [e.symm_image_eq_source_inter_preimage hs]	apply Set.inter_subset_left rw [← e.image_symm_image_of_subset_target hs] exact e.isOpen_image_of_subset_source h hs'	Mathlib/Topology/PartialHomeomorph.lean	415	417
/- Copyright (c) 2019 Sébastien Gouëzel. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Sébastien Gouëzel, Floris van Doorn -/ import Mathlib.Analysis.Calculus.ContDiff.Defs import Mathlib.Analysis.Calculus.ContDiff.FaaDiBruno import Mathlib.Analysis.Calculus.FDeriv.Add import Mathlib.Analysis.Calculus.FDeriv.Mul /-! # Higher differentiability of composition We prove that the composition of `C^n` functions is `C^n`. We also expand the API around `C^n` functions. ## Main results * `ContDiff.comp` states that the composition of two `C^n` functions is `C^n`. Similar results are given for `C^n` functions on domains. ## 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. In this file, we denote `(⊤ : ℕ∞) : WithTop ℕ∞` with `∞` and `⊤ : WithTop ℕ∞` with `ω`. ## Tags derivative, differentiability, higher derivative, `C^n`, multilinear, Taylor series, formal series -/ noncomputable section open scoped NNReal Nat ContDiff universe u uE uF uG attribute [local instance 1001] NormedAddCommGroup.toAddCommGroup AddCommGroup.toAddCommMonoid open Set Fin Filter Function open scoped Topology variable {𝕜 : Type} [NontriviallyNormedField 𝕜] {E : Type uE} [NormedAddCommGroup E] [NormedSpace 𝕜 E] {F : Type uF} [NormedAddCommGroup F] [NormedSpace 𝕜 F] {G : Type uG} [NormedAddCommGroup G] [NormedSpace 𝕜 G] {X : Type} [NormedAddCommGroup X] [NormedSpace 𝕜 X] {s t : Set E} {f : E → F} {g : F → G} {x x₀ : E} {b : E × F → G} {m n : WithTop ℕ∞} {p : E → FormalMultilinearSeries 𝕜 E F} /-! ### Constants -/ section constants theorem iteratedFDerivWithin_succ_const (n : ℕ) (c : F) : iteratedFDerivWithin 𝕜 (n + 1) (fun _ : E ↦ c) s = 0 := by induction n with \| zero => ext1 simp [iteratedFDerivWithin_succ_eq_comp_left, iteratedFDerivWithin_zero_eq_comp, comp_def] \| succ n IH => rw [iteratedFDerivWithin_succ_eq_comp_left, IH] simp only [Pi.zero_def, comp_def, fderivWithin_const, map_zero] @[simp] theorem iteratedFDerivWithin_zero_fun {i : ℕ} : iteratedFDerivWithin 𝕜 i (fun _ : E ↦ (0 : F)) s = 0 := by cases i with \| zero => ext; simp \| succ i => apply iteratedFDerivWithin_succ_const @[simp] theorem iteratedFDeriv_zero_fun {n : ℕ} : (iteratedFDeriv 𝕜 n fun _ : E ↦ (0 : F)) = 0 := funext fun x ↦ by simp only [← iteratedFDerivWithin_univ, iteratedFDerivWithin_zero_fun] theorem contDiff_zero_fun : ContDiff 𝕜 n fun _ : E => (0 : F) := analyticOnNhd_const.contDiff /-- Constants are `C^∞`. -/ theorem contDiff_const {c : F} : ContDiff 𝕜 n fun _ : E => c := analyticOnNhd_const.contDiff theorem contDiffOn_const {c : F} {s : Set E} : ContDiffOn 𝕜 n (fun _ : E => c) s := contDiff_const.contDiffOn theorem contDiffAt_const {c : F} : ContDiffAt 𝕜 n (fun _ : E => c) x := contDiff_const.contDiffAt theorem contDiffWithinAt_const {c : F} : ContDiffWithinAt 𝕜 n (fun _ : E => c) s x := contDiffAt_const.contDiffWithinAt @[nontriviality] theorem contDiff_of_subsingleton [Subsingleton F] : ContDiff 𝕜 n f := by rw [Subsingleton.elim f fun _ => 0]; exact contDiff_const @[nontriviality] theorem contDiffAt_of_subsingleton [Subsingleton F] : ContDiffAt 𝕜 n f x := by rw [Subsingleton.elim f fun _ => 0]; exact contDiffAt_const @[nontriviality] theorem contDiffWithinAt_of_subsingleton [Subsingleton F] : ContDiffWithinAt 𝕜 n f s x := by rw [Subsingleton.elim f fun _ => 0]; exact contDiffWithinAt_const @[nontriviality] theorem contDiffOn_of_subsingleton [Subsingleton F] : ContDiffOn 𝕜 n f s := by rw [Subsingleton.elim f fun _ => 0]; exact contDiffOn_const theorem iteratedFDerivWithin_const_of_ne {n : ℕ} (hn : n ≠ 0) (c : F) (s : Set E) : iteratedFDerivWithin 𝕜 n (fun _ : E ↦ c) s = 0 := by cases n with \| zero => contradiction \| succ n => exact iteratedFDerivWithin_succ_const n c theorem iteratedFDeriv_const_of_ne {n : ℕ} (hn : n ≠ 0) (c : F) :	(iteratedFDeriv 𝕜 n fun _ : E ↦ c) = 0 := by simp only [← iteratedFDerivWithin_univ, iteratedFDerivWithin_const_of_ne hn]	Mathlib/Analysis/Calculus/ContDiff/Basic.lean	117	118
/- Copyright (c) 2017 Mario Carneiro. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro, Johannes Hölzl, Patrick Massot -/ import Mathlib.Data.Set.Image import Mathlib.Data.SProd /-! # Sets in product and pi types This file proves basic properties of product of sets in `α × β` and in `Π i, α i`, and of the diagonal of a type. ## Main declarations This file contains basic results on the following notions, which are defined in `Set.Operations`. * `Set.prod`: Binary product of sets. For `s : Set α`, `t : Set β`, we have `s.prod t : Set (α × β)`. Denoted by `s ×ˢ t`. * `Set.diagonal`: Diagonal of a type. `Set.diagonal α = {(x, x) \| x : α}`. * `Set.offDiag`: Off-diagonal. `s ×ˢ s` without the diagonal. * `Set.pi`: Arbitrary product of sets. -/ open Function namespace Set /-! ### Cartesian binary product of sets -/ section Prod variable {α β γ δ : Type*} {s s₁ s₂ : Set α} {t t₁ t₂ : Set β} {a : α} {b : β} theorem Subsingleton.prod (hs : s.Subsingleton) (ht : t.Subsingleton) : (s ×ˢ t).Subsingleton := fun _x hx _y hy ↦ Prod.ext (hs hx.1 hy.1) (ht hx.2 hy.2) noncomputable instance decidableMemProd [DecidablePred (· ∈ s)] [DecidablePred (· ∈ t)] : DecidablePred (· ∈ s ×ˢ t) := fun x => inferInstanceAs (Decidable (x.1 ∈ s ∧ x.2 ∈ t)) @[gcongr] theorem prod_mono (hs : s₁ ⊆ s₂) (ht : t₁ ⊆ t₂) : s₁ ×ˢ t₁ ⊆ s₂ ×ˢ t₂ := fun _ ⟨h₁, h₂⟩ => ⟨hs h₁, ht h₂⟩ @[gcongr] theorem prod_mono_left (hs : s₁ ⊆ s₂) : s₁ ×ˢ t ⊆ s₂ ×ˢ t := prod_mono hs Subset.rfl @[gcongr] theorem prod_mono_right (ht : t₁ ⊆ t₂) : s ×ˢ t₁ ⊆ s ×ˢ t₂ := prod_mono Subset.rfl ht @[simp] theorem prod_self_subset_prod_self : s₁ ×ˢ s₁ ⊆ s₂ ×ˢ s₂ ↔ s₁ ⊆ s₂ := ⟨fun h _ hx => (h (mk_mem_prod hx hx)).1, fun h _ hx => ⟨h hx.1, h hx.2⟩⟩ @[simp] theorem prod_self_ssubset_prod_self : s₁ ×ˢ s₁ ⊂ s₂ ×ˢ s₂ ↔ s₁ ⊂ s₂ := and_congr prod_self_subset_prod_self <\| not_congr prod_self_subset_prod_self theorem prod_subset_iff {P : Set (α × β)} : s ×ˢ t ⊆ P ↔ ∀ x ∈ s, ∀ y ∈ t, (x, y) ∈ P := ⟨fun h _ hx _ hy => h (mk_mem_prod hx hy), fun h ⟨_, _⟩ hp => h _ hp.1 _ hp.2⟩ theorem forall_prod_set {p : α × β → Prop} : (∀ x ∈ s ×ˢ t, p x) ↔ ∀ x ∈ s, ∀ y ∈ t, p (x, y) := prod_subset_iff theorem exists_prod_set {p : α × β → Prop} : (∃ x ∈ s ×ˢ t, p x) ↔ ∃ x ∈ s, ∃ y ∈ t, p (x, y) := by simp [and_assoc] @[simp] theorem prod_empty : s ×ˢ (∅ : Set β) = ∅ := by ext exact iff_of_eq (and_false _) @[simp] theorem empty_prod : (∅ : Set α) ×ˢ t = ∅ := by ext exact iff_of_eq (false_and _) @[simp, mfld_simps] theorem univ_prod_univ : @univ α ×ˢ @univ β = univ := by ext exact iff_of_eq (true_and _) theorem univ_prod {t : Set β} : (univ : Set α) ×ˢ t = Prod.snd ⁻¹' t := by simp [prod_eq] theorem prod_univ {s : Set α} : s ×ˢ (univ : Set β) = Prod.fst ⁻¹' s := by simp [prod_eq] @[simp] lemma prod_eq_univ [Nonempty α] [Nonempty β] : s ×ˢ t = univ ↔ s = univ ∧ t = univ := by simp [eq_univ_iff_forall, forall_and] theorem singleton_prod : ({a} : Set α) ×ˢ t = Prod.mk a '' t := by ext ⟨x, y⟩ simp [and_left_comm, eq_comm] theorem prod_singleton : s ×ˢ ({b} : Set β) = (fun a => (a, b)) '' s := by ext ⟨x, y⟩ simp [and_left_comm, eq_comm] @[simp] theorem singleton_prod_singleton : ({a} : Set α) ×ˢ ({b} : Set β) = {(a, b)} := by ext ⟨c, d⟩; simp @[simp] theorem union_prod : (s₁ ∪ s₂) ×ˢ t = s₁ ×ˢ t ∪ s₂ ×ˢ t := by ext ⟨x, y⟩ simp [or_and_right] @[simp] theorem prod_union : s ×ˢ (t₁ ∪ t₂) = s ×ˢ t₁ ∪ s ×ˢ t₂ := by ext ⟨x, y⟩ simp [and_or_left]	theorem inter_prod : (s₁ ∩ s₂) ×ˢ t = s₁ ×ˢ t ∩ s₂ ×ˢ t := by ext ⟨x, y⟩ simp only [← and_and_right, mem_inter_iff, mem_prod]	Mathlib/Data/Set/Prod.lean	117	119
/- 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.LinearAlgebra.Dimension.LinearMap import Mathlib.LinearAlgebra.FreeModule.StrongRankCondition import Mathlib.LinearAlgebra.Matrix.ToLin /-! # Finite and free modules using matrices We provide some instances for finite and free modules involving matrices. ## Main results * `Module.Free.linearMap` : if `M` and `N` are finite and free, then `M →ₗ[R] N` is free. * `Module.Finite.ofBasis` : A free module with a basis indexed by a `Fintype` is finite. * `Module.Finite.linearMap` : if `M` and `N` are finite and free, then `M →ₗ[R] N` is finite. -/ universe u u' v w variable (R : Type u) (S : Type u') (M : Type v) (N : Type w) open Module.Free (chooseBasis ChooseBasisIndex) open Module (finrank) section Ring variable [Ring R] [Ring S] [AddCommGroup M] [Module R M] [Module.Free R M] [Module.Finite R M] variable [AddCommGroup N] [Module R N] [Module S N] [SMulCommClass R S N] private noncomputable def linearMapEquivFun : (M →ₗ[R] N) ≃ₗ[S] ChooseBasisIndex R M → N := (chooseBasis R M).repr.congrLeft N S ≪≫ₗ (Finsupp.lsum S).symm ≪≫ₗ LinearEquiv.piCongrRight fun _ ↦ LinearMap.ringLmapEquivSelf R S N instance Module.Free.linearMap [Module.Free S N] : Module.Free S (M →ₗ[R] N) := Module.Free.of_equiv (linearMapEquivFun R S M N).symm instance Module.Finite.linearMap [Module.Finite S N] : Module.Finite S (M →ₗ[R] N) := Module.Finite.equiv (linearMapEquivFun R S M N).symm variable [StrongRankCondition R] [StrongRankCondition S] [Module.Free S N] open Cardinal theorem Module.rank_linearMap : Module.rank S (M →ₗ[R] N) = lift.{w} (Module.rank R M) * lift.{v} (Module.rank S N) := by rw [(linearMapEquivFun R S M N).rank_eq, rank_fun_eq_lift_mul, ← finrank_eq_card_chooseBasisIndex, ← finrank_eq_rank R, lift_natCast] /-- The finrank of `M →ₗ[R] N` as an `S`-module is `(finrank R M) * (finrank S N)`. -/ theorem Module.finrank_linearMap : finrank S (M →ₗ[R] N) = finrank R M * finrank S N := by simp_rw [finrank, rank_linearMap, toNat_mul, toNat_lift] variable [Module R S] [SMulCommClass R S S] theorem Module.rank_linearMap_self : Module.rank S (M →ₗ[R] S) = lift.{u'} (Module.rank R M) := by rw [rank_linearMap, rank_self, lift_one, mul_one] theorem Module.finrank_linearMap_self : finrank S (M →ₗ[R] S) = finrank R M := by rw [finrank_linearMap, finrank_self, mul_one] end Ring section AlgHom variable (K M : Type*) (L : Type v) [CommRing K] [Ring M] [Algebra K M] [Module.Free K M] [Module.Finite K M] [CommRing L] [IsDomain L] [Algebra K L] instance Finite.algHom : Finite (M →ₐ[K] L) := (linearIndependent_algHom_toLinearMap K M L).finite open Cardinal theorem cardinalMk_algHom_le_rank : #(M →ₐ[K] L) ≤ lift.{v} (Module.rank K M) := by convert (linearIndependent_algHom_toLinearMap K M L).cardinal_lift_le_rank · rw [lift_id] · have := Module.nontrivial K L rw [lift_id, Module.rank_linearMap_self] @[deprecated (since := "2024-11-10")] alias cardinal_mk_algHom_le_rank := cardinalMk_algHom_le_rank @[stacks 09HS] theorem card_algHom_le_finrank : Nat.card (M →ₐ[K] L) ≤ finrank K M := by	convert toNat_le_toNat (cardinalMk_algHom_le_rank K M L) ?_ · rw [toNat_lift, finrank] · rw [lift_lt_aleph0]; have := Module.nontrivial K L; apply Module.rank_lt_aleph0	Mathlib/LinearAlgebra/FreeModule/Finite/Matrix.lean	91	94
/- Copyright (c) 2017 Mario Carneiro. 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.SetTheory.Cardinal.Arithmetic import Mathlib.SetTheory.Ordinal.FixedPoint /-! # Cofinality This file contains the definition of cofinality of an order and an ordinal number. ## Main Definitions * `Order.cof r` is the cofinality of a reflexive order. This is the smallest cardinality of a subset `s` that is cofinal, i.e. `∀ x, ∃ y ∈ s, r x y`. * `Ordinal.cof o` is the cofinality of the ordinal `o` when viewed as a linear order. ## Main Statements * `Cardinal.lt_power_cof`: A consequence of König's theorem stating that `c < c ^ c.ord.cof` for `c ≥ ℵ₀`. ## Implementation Notes * The cofinality is defined for ordinals. If `c` is a cardinal number, its cofinality is `c.ord.cof`. -/ noncomputable section open Function Cardinal Set Order open scoped Ordinal universe u v w variable {α : Type u} {β : Type v} {r : α → α → Prop} {s : β → β → Prop} /-! ### Cofinality of orders -/ attribute [local instance] IsRefl.swap namespace Order /-- Cofinality of a reflexive order `≼`. This is the smallest cardinality of a subset `S : Set α` such that `∀ a, ∃ b ∈ S, a ≼ b`. -/ def cof (r : α → α → Prop) : Cardinal := sInf { c \| ∃ S : Set α, (∀ a, ∃ b ∈ S, r a b) ∧ #S = c } /-- The set in the definition of `Order.cof` is nonempty. -/ private theorem cof_nonempty (r : α → α → Prop) [IsRefl α r] : { c \| ∃ S : Set α, (∀ a, ∃ b ∈ S, r a b) ∧ #S = c }.Nonempty := ⟨_, Set.univ, fun a => ⟨a, ⟨⟩, refl _⟩, rfl⟩ theorem cof_le (r : α → α → Prop) {S : Set α} (h : ∀ a, ∃ b ∈ S, r a b) : cof r ≤ #S := csInf_le' ⟨S, h, rfl⟩ theorem le_cof [IsRefl α r] (c : Cardinal) : c ≤ cof r ↔ ∀ {S : Set α}, (∀ a, ∃ b ∈ S, r a b) → c ≤ #S := by rw [cof, le_csInf_iff'' (cof_nonempty r)] use fun H S h => H _ ⟨S, h, rfl⟩ rintro H d ⟨S, h, rfl⟩ exact H h end Order namespace RelIso private theorem cof_le_lift [IsRefl β s] (f : r ≃r s) : Cardinal.lift.{v} (Order.cof r) ≤ Cardinal.lift.{u} (Order.cof s) := by rw [Order.cof, Order.cof, lift_sInf, lift_sInf, le_csInf_iff'' ((Order.cof_nonempty s).image _)] rintro - ⟨-, ⟨u, H, rfl⟩, rfl⟩ apply csInf_le' refine ⟨_, ⟨f.symm '' u, fun a => ?_, rfl⟩, lift_mk_eq'.2 ⟨(f.symm.toEquiv.image u).symm⟩⟩ rcases H (f a) with ⟨b, hb, hb'⟩ refine ⟨f.symm b, mem_image_of_mem _ hb, f.map_rel_iff.1 ?_⟩ rwa [RelIso.apply_symm_apply] theorem cof_eq_lift [IsRefl β s] (f : r ≃r s) : Cardinal.lift.{v} (Order.cof r) = Cardinal.lift.{u} (Order.cof s) := have := f.toRelEmbedding.isRefl (f.cof_le_lift).antisymm (f.symm.cof_le_lift) theorem cof_eq {α β : Type u} {r : α → α → Prop} {s} [IsRefl β s] (f : r ≃r s) : Order.cof r = Order.cof s := lift_inj.1 (f.cof_eq_lift) end RelIso /-! ### Cofinality of ordinals -/ namespace Ordinal /-- Cofinality of an ordinal. This is the smallest cardinal of a subset `S` of the ordinal which is unbounded, in the sense `∀ a, ∃ b ∈ S, a ≤ b`. In particular, `cof 0 = 0` and `cof (succ o) = 1`. -/ def cof (o : Ordinal.{u}) : Cardinal.{u} := o.liftOn (fun a ↦ Order.cof (swap a.rᶜ)) fun _ _ ⟨f⟩ ↦ f.compl.swap.cof_eq theorem cof_type (r : α → α → Prop) [IsWellOrder α r] : (type r).cof = Order.cof (swap rᶜ) := rfl theorem cof_type_lt [LinearOrder α] [IsWellOrder α (· < ·)] : (@type α (· < ·) _).cof = @Order.cof α (· ≤ ·) := by rw [cof_type, compl_lt, swap_ge] theorem cof_eq_cof_toType (o : Ordinal) : o.cof = @Order.cof o.toType (· ≤ ·) := by conv_lhs => rw [← type_toType o, cof_type_lt] theorem le_cof_type [IsWellOrder α r] {c} : c ≤ cof (type r) ↔ ∀ S, Unbounded r S → c ≤ #S := (le_csInf_iff'' (Order.cof_nonempty _)).trans ⟨fun H S h => H _ ⟨S, h, rfl⟩, by rintro H d ⟨S, h, rfl⟩ exact H _ h⟩ theorem cof_type_le [IsWellOrder α r] {S : Set α} (h : Unbounded r S) : cof (type r) ≤ #S := le_cof_type.1 le_rfl S h theorem lt_cof_type [IsWellOrder α r] {S : Set α} : #S < cof (type r) → Bounded r S := by simpa using not_imp_not.2 cof_type_le theorem cof_eq (r : α → α → Prop) [IsWellOrder α r] : ∃ S, Unbounded r S ∧ #S = cof (type r) := csInf_mem (Order.cof_nonempty (swap rᶜ)) theorem ord_cof_eq (r : α → α → Prop) [IsWellOrder α r] : ∃ S, Unbounded r S ∧ type (Subrel r (· ∈ S)) = (cof (type r)).ord := by let ⟨S, hS, e⟩ := cof_eq r let ⟨s, _, e'⟩ := Cardinal.ord_eq S let T : Set α := { a \| ∃ aS : a ∈ S, ∀ b : S, s b ⟨_, aS⟩ → r b a } suffices Unbounded r T by refine ⟨T, this, le_antisymm ?_ (Cardinal.ord_le.2 <\| cof_type_le this)⟩ rw [← e, e'] refine (RelEmbedding.ofMonotone (fun a : T => (⟨a, let ⟨aS, _⟩ := a.2 aS⟩ : S)) fun a b h => ?_).ordinal_type_le rcases a with ⟨a, aS, ha⟩ rcases b with ⟨b, bS, hb⟩ change s ⟨a, _⟩ ⟨b, _⟩ refine ((trichotomous_of s _ _).resolve_left fun hn => ?_).resolve_left ?_ · exact asymm h (ha _ hn) · intro e injection e with e subst b exact irrefl _ h intro a have : { b : S \| ¬r b a }.Nonempty := let ⟨b, bS, ba⟩ := hS a ⟨⟨b, bS⟩, ba⟩ let b := (IsWellFounded.wf : WellFounded s).min _ this have ba : ¬r b a := IsWellFounded.wf.min_mem _ this refine ⟨b, ⟨b.2, fun c => not_imp_not.1 fun h => ?_⟩, ba⟩ rw [show ∀ b : S, (⟨b, b.2⟩ : S) = b by intro b; cases b; rfl] exact IsWellFounded.wf.not_lt_min _ this (IsOrderConnected.neg_trans h ba) /-! ### Cofinality of suprema and least strict upper bounds -/ private theorem card_mem_cof {o} : ∃ (ι : _) (f : ι → Ordinal), lsub.{u, u} f = o ∧ #ι = o.card := ⟨_, _, lsub_typein o, mk_toType o⟩ /-- The set in the `lsub` characterization of `cof` is nonempty. -/ theorem cof_lsub_def_nonempty (o) : { a : Cardinal \| ∃ (ι : _) (f : ι → Ordinal), lsub.{u, u} f = o ∧ #ι = a }.Nonempty := ⟨_, card_mem_cof⟩ theorem cof_eq_sInf_lsub (o : Ordinal.{u}) : cof o = sInf { a : Cardinal \| ∃ (ι : Type u) (f : ι → Ordinal), lsub.{u, u} f = o ∧ #ι = a } := by refine le_antisymm (le_csInf (cof_lsub_def_nonempty o) ?_) (csInf_le' ?_) · rintro a ⟨ι, f, hf, rfl⟩ rw [← type_toType o] refine (cof_type_le fun a => ?_).trans (@mk_le_of_injective _ _ (fun s : typein ((· < ·) : o.toType → o.toType → Prop) ⁻¹' Set.range f => Classical.choose s.prop) fun s t hst => by let H := congr_arg f hst rwa [Classical.choose_spec s.prop, Classical.choose_spec t.prop, typein_inj, Subtype.coe_inj] at H) have := typein_lt_self a simp_rw [← hf, lt_lsub_iff] at this obtain ⟨i, hi⟩ := this refine ⟨enum (α := o.toType) (· < ·) ⟨f i, ?_⟩, ?_, ?_⟩ · rw [type_toType, ← hf] apply lt_lsub · rw [mem_preimage, typein_enum] exact mem_range_self i · rwa [← typein_le_typein, typein_enum] · rcases cof_eq (α := o.toType) (· < ·) with ⟨S, hS, hS'⟩ let f : S → Ordinal := fun s => typein LT.lt s.val refine ⟨S, f, le_antisymm (lsub_le fun i => typein_lt_self (o := o) i) (le_of_forall_lt fun a ha => ?_), by rwa [type_toType o] at hS'⟩ rw [← type_toType o] at ha rcases hS (enum (· < ·) ⟨a, ha⟩) with ⟨b, hb, hb'⟩ rw [← typein_le_typein, typein_enum] at hb' exact hb'.trans_lt (lt_lsub.{u, u} f ⟨b, hb⟩) @[simp] theorem lift_cof (o) : Cardinal.lift.{u, v} (cof o) = cof (Ordinal.lift.{u, v} o) := by refine inductionOn o fun α r _ ↦ ?_ rw [← type_uLift, cof_type, cof_type, ← Cardinal.lift_id'.{v, u} (Order.cof _), ← Cardinal.lift_umax] apply RelIso.cof_eq_lift ⟨Equiv.ulift.symm, _⟩ simp [swap] theorem cof_le_card (o) : cof o ≤ card o := by rw [cof_eq_sInf_lsub] exact csInf_le' card_mem_cof theorem cof_ord_le (c : Cardinal) : c.ord.cof ≤ c := by simpa using cof_le_card c.ord theorem ord_cof_le (o : Ordinal.{u}) : o.cof.ord ≤ o := (ord_le_ord.2 (cof_le_card o)).trans (ord_card_le o) theorem exists_lsub_cof (o : Ordinal) : ∃ (ι : _) (f : ι → Ordinal), lsub.{u, u} f = o ∧ #ι = cof o := by rw [cof_eq_sInf_lsub] exact csInf_mem (cof_lsub_def_nonempty o) theorem cof_lsub_le {ι} (f : ι → Ordinal) : cof (lsub.{u, u} f) ≤ #ι := by rw [cof_eq_sInf_lsub] exact csInf_le' ⟨ι, f, rfl, rfl⟩ theorem cof_lsub_le_lift {ι} (f : ι → Ordinal) : cof (lsub.{u, v} f) ≤ Cardinal.lift.{v, u} #ι := by rw [← mk_uLift.{u, v}] convert cof_lsub_le.{max u v} fun i : ULift.{v, u} ι => f i.down exact lsub_eq_of_range_eq.{u, max u v, max u v} (Set.ext fun x => ⟨fun ⟨i, hi⟩ => ⟨ULift.up.{v, u} i, hi⟩, fun ⟨i, hi⟩ => ⟨_, hi⟩⟩) theorem le_cof_iff_lsub {o : Ordinal} {a : Cardinal} : a ≤ cof o ↔ ∀ {ι} (f : ι → Ordinal), lsub.{u, u} f = o → a ≤ #ι := by rw [cof_eq_sInf_lsub] exact (le_csInf_iff'' (cof_lsub_def_nonempty o)).trans ⟨fun H ι f hf => H _ ⟨ι, f, hf, rfl⟩, fun H b ⟨ι, f, hf, hb⟩ => by rw [← hb] exact H _ hf⟩ theorem lsub_lt_ord_lift {ι} {f : ι → Ordinal} {c : Ordinal} (hι : Cardinal.lift.{v, u} #ι < c.cof) (hf : ∀ i, f i < c) : lsub.{u, v} f < c := lt_of_le_of_ne (lsub_le hf) fun h => by subst h exact (cof_lsub_le_lift.{u, v} f).not_lt hι theorem lsub_lt_ord {ι} {f : ι → Ordinal} {c : Ordinal} (hι : #ι < c.cof) : (∀ i, f i < c) → lsub.{u, u} f < c := lsub_lt_ord_lift (by rwa [(#ι).lift_id]) theorem cof_iSup_le_lift {ι} {f : ι → Ordinal} (H : ∀ i, f i < iSup f) : cof (iSup f) ≤ Cardinal.lift.{v, u} #ι := by rw [← Ordinal.sup] at * rw [← sup_eq_lsub_iff_lt_sup.{u, v}] at H rw [H] exact cof_lsub_le_lift f theorem cof_iSup_le {ι} {f : ι → Ordinal} (H : ∀ i, f i < iSup f) : cof (iSup f) ≤ #ι := by rw [← (#ι).lift_id] exact cof_iSup_le_lift H theorem iSup_lt_ord_lift {ι} {f : ι → Ordinal} {c : Ordinal} (hι : Cardinal.lift.{v, u} #ι < c.cof) (hf : ∀ i, f i < c) : iSup f < c := (sup_le_lsub.{u, v} f).trans_lt (lsub_lt_ord_lift hι hf) theorem iSup_lt_ord {ι} {f : ι → Ordinal} {c : Ordinal} (hι : #ι < c.cof) : (∀ i, f i < c) → iSup f < c := iSup_lt_ord_lift (by rwa [(#ι).lift_id]) theorem iSup_lt_lift {ι} {f : ι → Cardinal} {c : Cardinal} (hι : Cardinal.lift.{v, u} #ι < c.ord.cof) (hf : ∀ i, f i < c) : iSup f < c := by rw [← ord_lt_ord, iSup_ord (Cardinal.bddAbove_range _)] refine iSup_lt_ord_lift hι fun i => ?_ rw [ord_lt_ord] apply hf theorem iSup_lt {ι} {f : ι → Cardinal} {c : Cardinal} (hι : #ι < c.ord.cof) : (∀ i, f i < c) → iSup f < c := iSup_lt_lift (by rwa [(#ι).lift_id]) theorem nfpFamily_lt_ord_lift {ι} {f : ι → Ordinal → Ordinal} {c} (hc : ℵ₀ < cof c) (hc' : Cardinal.lift.{v, u} #ι < cof c) (hf : ∀ (i), ∀ b < c, f i b < c) {a} (ha : a < c) : nfpFamily f a < c := by refine iSup_lt_ord_lift ((Cardinal.lift_le.2 (mk_list_le_max ι)).trans_lt ?_) fun l => ?_ · rw [lift_max] apply max_lt _ hc' rwa [Cardinal.lift_aleph0] · induction' l with i l H · exact ha · exact hf _ _ H theorem nfpFamily_lt_ord {ι} {f : ι → Ordinal → Ordinal} {c} (hc : ℵ₀ < cof c) (hc' : #ι < cof c) (hf : ∀ (i), ∀ b < c, f i b < c) {a} : a < c → nfpFamily.{u, u} f a < c := nfpFamily_lt_ord_lift hc (by rwa [(#ι).lift_id]) hf theorem nfp_lt_ord {f : Ordinal → Ordinal} {c} (hc : ℵ₀ < cof c) (hf : ∀ i < c, f i < c) {a} : a < c → nfp f a < c := nfpFamily_lt_ord_lift hc (by simpa using Cardinal.one_lt_aleph0.trans hc) fun _ => hf theorem exists_blsub_cof (o : Ordinal) : ∃ f : ∀ a < (cof o).ord, Ordinal, blsub.{u, u} _ f = o := by rcases exists_lsub_cof o with ⟨ι, f, hf, hι⟩ rcases Cardinal.ord_eq ι with ⟨r, hr, hι'⟩ rw [← @blsub_eq_lsub' ι r hr] at hf rw [← hι, hι'] exact ⟨_, hf⟩ theorem le_cof_iff_blsub {b : Ordinal} {a : Cardinal} : a ≤ cof b ↔ ∀ {o} (f : ∀ a < o, Ordinal), blsub.{u, u} o f = b → a ≤ o.card := le_cof_iff_lsub.trans ⟨fun H o f hf => by simpa using H _ hf, fun H ι f hf => by rcases Cardinal.ord_eq ι with ⟨r, hr, hι'⟩ rw [← @blsub_eq_lsub' ι r hr] at hf simpa using H _ hf⟩ theorem cof_blsub_le_lift {o} (f : ∀ a < o, Ordinal) : cof (blsub.{u, v} o f) ≤ Cardinal.lift.{v, u} o.card := by rw [← mk_toType o] exact cof_lsub_le_lift _ theorem cof_blsub_le {o} (f : ∀ a < o, Ordinal) : cof (blsub.{u, u} o f) ≤ o.card := by rw [← o.card.lift_id] exact cof_blsub_le_lift f theorem blsub_lt_ord_lift {o : Ordinal.{u}} {f : ∀ a < o, Ordinal} {c : Ordinal} (ho : Cardinal.lift.{v, u} o.card < c.cof) (hf : ∀ i hi, f i hi < c) : blsub.{u, v} o f < c := lt_of_le_of_ne (blsub_le hf) fun h => ho.not_le (by simpa [← iSup_ord, hf, h] using cof_blsub_le_lift.{u, v} f) theorem blsub_lt_ord {o : Ordinal} {f : ∀ a < o, Ordinal} {c : Ordinal} (ho : o.card < c.cof) (hf : ∀ i hi, f i hi < c) : blsub.{u, u} o f < c := blsub_lt_ord_lift (by rwa [o.card.lift_id]) hf theorem cof_bsup_le_lift {o : Ordinal} {f : ∀ a < o, Ordinal} (H : ∀ i h, f i h < bsup.{u, v} o f) : cof (bsup.{u, v} o f) ≤ Cardinal.lift.{v, u} o.card := by rw [← bsup_eq_blsub_iff_lt_bsup.{u, v}] at H rw [H] exact cof_blsub_le_lift.{u, v} f theorem cof_bsup_le {o : Ordinal} {f : ∀ a < o, Ordinal} : (∀ i h, f i h < bsup.{u, u} o f) → cof (bsup.{u, u} o f) ≤ o.card := by rw [← o.card.lift_id] exact cof_bsup_le_lift theorem bsup_lt_ord_lift {o : Ordinal} {f : ∀ a < o, Ordinal} {c : Ordinal} (ho : Cardinal.lift.{v, u} o.card < c.cof) (hf : ∀ i hi, f i hi < c) : bsup.{u, v} o f < c := (bsup_le_blsub f).trans_lt (blsub_lt_ord_lift ho hf) theorem bsup_lt_ord {o : Ordinal} {f : ∀ a < o, Ordinal} {c : Ordinal} (ho : o.card < c.cof) : (∀ i hi, f i hi < c) → bsup.{u, u} o f < c := bsup_lt_ord_lift (by rwa [o.card.lift_id]) /-! ### Basic results -/ @[simp] theorem cof_zero : cof 0 = 0 := by refine LE.le.antisymm ?_ (Cardinal.zero_le _) rw [← card_zero] exact cof_le_card 0 @[simp] theorem cof_eq_zero {o} : cof o = 0 ↔ o = 0 := ⟨inductionOn o fun _ r _ z => let ⟨_, hl, e⟩ := cof_eq r type_eq_zero_iff_isEmpty.2 <\| ⟨fun a => let ⟨_, h, _⟩ := hl a (mk_eq_zero_iff.1 (e.trans z)).elim' ⟨_, h⟩⟩, fun e => by simp [e]⟩ theorem cof_ne_zero {o} : cof o ≠ 0 ↔ o ≠ 0 := cof_eq_zero.not @[simp] theorem cof_succ (o) : cof (succ o) = 1 := by apply le_antisymm · refine inductionOn o fun α r _ => ?_ change cof (type _) ≤ _ rw [← (_ : #_ = 1)] · apply cof_type_le refine fun a => ⟨Sum.inr PUnit.unit, Set.mem_singleton _, ?_⟩ rcases a with (a \| ⟨⟨⟨⟩⟩⟩) <;> simp [EmptyRelation] · rw [Cardinal.mk_fintype, Set.card_singleton] simp · rw [← Cardinal.succ_zero, succ_le_iff] simpa [lt_iff_le_and_ne, Cardinal.zero_le] using fun h => succ_ne_zero o (cof_eq_zero.1 (Eq.symm h)) @[simp] theorem cof_eq_one_iff_is_succ {o} : cof.{u} o = 1 ↔ ∃ a, o = succ a := ⟨inductionOn o fun α r _ z => by rcases cof_eq r with ⟨S, hl, e⟩; rw [z] at e obtain ⟨a⟩ := mk_ne_zero_iff.1 (by rw [e]; exact one_ne_zero) refine ⟨typein r a, Eq.symm <\| Quotient.sound ⟨RelIso.ofSurjective (RelEmbedding.ofMonotone ?_ fun x y => ?_) fun x => ?_⟩⟩ · apply Sum.rec <;> [exact Subtype.val; exact fun _ => a] · rcases x with (x \| ⟨⟨⟨⟩⟩⟩) <;> rcases y with (y \| ⟨⟨⟨⟩⟩⟩) <;> simp [Subrel, Order.Preimage, EmptyRelation] exact x.2 · suffices r x a ∨ ∃ _ : PUnit.{u}, ↑a = x by convert this dsimp [RelEmbedding.ofMonotone]; simp rcases trichotomous_of r x a with (h \| h \| h) · exact Or.inl h · exact Or.inr ⟨PUnit.unit, h.symm⟩ · rcases hl x with ⟨a', aS, hn⟩ refine absurd h ?_ convert hn change (a : α) = ↑(⟨a', aS⟩ : S) have := le_one_iff_subsingleton.1 (le_of_eq e) congr!, fun ⟨a, e⟩ => by simp [e]⟩ /-! ### Fundamental sequences -/ -- TODO: move stuff about fundamental sequences to their own file. /-- A fundamental sequence for `a` is an increasing sequence of length `o = cof a` that converges at `a`. We provide `o` explicitly in order to avoid type rewrites. -/ def IsFundamentalSequence (a o : Ordinal.{u}) (f : ∀ b < o, Ordinal.{u}) : Prop := o ≤ a.cof.ord ∧ (∀ {i j} (hi hj), i < j → f i hi < f j hj) ∧ blsub.{u, u} o f = a namespace IsFundamentalSequence variable {a o : Ordinal.{u}} {f : ∀ b < o, Ordinal.{u}} protected theorem cof_eq (hf : IsFundamentalSequence a o f) : a.cof.ord = o := hf.1.antisymm' <\| by rw [← hf.2.2] exact (ord_le_ord.2 (cof_blsub_le f)).trans (ord_card_le o) protected theorem strict_mono (hf : IsFundamentalSequence a o f) {i j} : ∀ hi hj, i < j → f i hi < f j hj := hf.2.1 theorem blsub_eq (hf : IsFundamentalSequence a o f) : blsub.{u, u} o f = a := hf.2.2 theorem ord_cof (hf : IsFundamentalSequence a o f) : IsFundamentalSequence a a.cof.ord fun i hi => f i (hi.trans_le (by rw [hf.cof_eq])) := by have H := hf.cof_eq subst H exact hf theorem id_of_le_cof (h : o ≤ o.cof.ord) : IsFundamentalSequence o o fun a _ => a := ⟨h, @fun _ _ _ _ => id, blsub_id o⟩ protected theorem zero {f : ∀ b < (0 : Ordinal), Ordinal} : IsFundamentalSequence 0 0 f := ⟨by rw [cof_zero, ord_zero], @fun i _ hi => (Ordinal.not_lt_zero i hi).elim, blsub_zero f⟩ protected theorem succ : IsFundamentalSequence (succ o) 1 fun _ _ => o := by refine ⟨?_, @fun i j hi hj h => ?_, blsub_const Ordinal.one_ne_zero o⟩ · rw [cof_succ, ord_one] · rw [lt_one_iff_zero] at hi hj rw [hi, hj] at h exact h.false.elim protected theorem monotone (hf : IsFundamentalSequence a o f) {i j : Ordinal} (hi : i < o) (hj : j < o) (hij : i ≤ j) : f i hi ≤ f j hj := by rcases lt_or_eq_of_le hij with (hij \| rfl) · exact (hf.2.1 hi hj hij).le · rfl theorem trans {a o o' : Ordinal.{u}} {f : ∀ b < o, Ordinal.{u}} (hf : IsFundamentalSequence a o f) {g : ∀ b < o', Ordinal.{u}} (hg : IsFundamentalSequence o o' g) : IsFundamentalSequence a o' fun i hi => f (g i hi) (by rw [← hg.2.2]; apply lt_blsub) := by refine ⟨?_, @fun i j _ _ h => hf.2.1 _ _ (hg.2.1 _ _ h), ?_⟩ · rw [hf.cof_eq] exact hg.1.trans (ord_cof_le o) · rw [@blsub_comp.{u, u, u} o _ f (@IsFundamentalSequence.monotone _ _ f hf)] · exact hf.2.2	· exact hg.2.2 protected theorem lt {a o : Ordinal} {s : Π p < o, Ordinal} (h : IsFundamentalSequence a o s) {p : Ordinal} (hp : p < o) : s p hp < a := h.blsub_eq ▸ lt_blsub s p hp end IsFundamentalSequence	Mathlib/SetTheory/Cardinal/Cofinality.lean	485	492
/- 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.Basic import Mathlib.Algebra.GroupWithZero.NeZero import Mathlib.Logic.Unique import Mathlib.Tactic.Conv /-! # Groups with an adjoined zero element This file describes structures that are not usually studied on their own right in mathematics, namely a special sort of monoid: apart from a distinguished “zero element” they form a group, or in other words, they are groups with an adjoined zero element. Examples are: * division rings; * the value monoid of a multiplicative valuation; * in particular, the non-negative real numbers. ## Main definitions Various lemmas about `GroupWithZero` and `CommGroupWithZero`. To reduce import dependencies, the type-classes themselves are in `Algebra.GroupWithZero.Defs`. ## Implementation details As is usual in mathlib, we extend the inverse function to the zero element, and require `0⁻¹ = 0`. -/ assert_not_exists DenselyOrdered open Function variable {M₀ G₀ : Type} section section MulZeroClass variable [MulZeroClass M₀] {a b : M₀} theorem left_ne_zero_of_mul : a b ≠ 0 → a ≠ 0 := mt fun h => mul_eq_zero_of_left h b theorem right_ne_zero_of_mul : a * b ≠ 0 → b ≠ 0 := mt (mul_eq_zero_of_right a) theorem ne_zero_and_ne_zero_of_mul (h : a * b ≠ 0) : a ≠ 0 ∧ b ≠ 0 := ⟨left_ne_zero_of_mul h, right_ne_zero_of_mul h⟩ theorem mul_eq_zero_of_ne_zero_imp_eq_zero {a b : M₀} (h : a ≠ 0 → b = 0) : a * b = 0 := by have : Decidable (a = 0) := Classical.propDecidable (a = 0) exact if ha : a = 0 then by rw [ha, zero_mul] else by rw [h ha, mul_zero] /-- To match `one_mul_eq_id`. -/ theorem zero_mul_eq_const : ((0 : M₀) * ·) = Function.const _ 0 := funext zero_mul /-- To match `mul_one_eq_id`. -/ theorem mul_zero_eq_const : (· * (0 : M₀)) = Function.const _ 0 := funext mul_zero end MulZeroClass section Mul variable [Mul M₀] [Zero M₀] [NoZeroDivisors M₀] {a b : M₀} theorem eq_zero_of_mul_self_eq_zero (h : a * a = 0) : a = 0 := (eq_zero_or_eq_zero_of_mul_eq_zero h).elim id id @[field_simps] theorem mul_ne_zero (ha : a ≠ 0) (hb : b ≠ 0) : a * b ≠ 0 := mt eq_zero_or_eq_zero_of_mul_eq_zero <\| not_or.mpr ⟨ha, hb⟩ end Mul namespace NeZero instance mul [Zero M₀] [Mul M₀] [NoZeroDivisors M₀] {x y : M₀} [NeZero x] [NeZero y] : NeZero (x * y) := ⟨mul_ne_zero out out⟩ end NeZero end section variable [MulZeroOneClass M₀] /-- In a monoid with zero, if zero equals one, then zero is the only element. -/ theorem eq_zero_of_zero_eq_one (h : (0 : M₀) = 1) (a : M₀) : a = 0 := by rw [← mul_one a, ← h, mul_zero] /-- In a monoid with zero, if zero equals one, then zero is the unique element. Somewhat arbitrarily, we define the default element to be `0`. All other elements will be provably equal to it, but not necessarily definitionally equal. -/ def uniqueOfZeroEqOne (h : (0 : M₀) = 1) : Unique M₀ where default := 0 uniq := eq_zero_of_zero_eq_one h /-- In a monoid with zero, zero equals one if and only if all elements of that semiring are equal. -/ theorem subsingleton_iff_zero_eq_one : (0 : M₀) = 1 ↔ Subsingleton M₀ := ⟨fun h => haveI := uniqueOfZeroEqOne h; inferInstance, fun h => @Subsingleton.elim _ h _ _⟩ alias ⟨subsingleton_of_zero_eq_one, _⟩ := subsingleton_iff_zero_eq_one theorem eq_of_zero_eq_one (h : (0 : M₀) = 1) (a b : M₀) : a = b := @Subsingleton.elim _ (subsingleton_of_zero_eq_one h) a b /-- In a monoid with zero, either zero and one are nonequal, or zero is the only element. -/ theorem zero_ne_one_or_forall_eq_0 : (0 : M₀) ≠ 1 ∨ ∀ a : M₀, a = 0 := not_or_of_imp eq_zero_of_zero_eq_one end section variable [MulZeroOneClass M₀] [Nontrivial M₀] {a b : M₀} theorem left_ne_zero_of_mul_eq_one (h : a * b = 1) : a ≠ 0 := left_ne_zero_of_mul <\| ne_zero_of_eq_one h theorem right_ne_zero_of_mul_eq_one (h : a * b = 1) : b ≠ 0 := right_ne_zero_of_mul <\| ne_zero_of_eq_one h end section MonoidWithZero variable [MonoidWithZero M₀] {a : M₀} {n : ℕ} @[simp] lemma zero_pow : ∀ {n : ℕ}, n ≠ 0 → (0 : M₀) ^ n = 0 \| n + 1, _ => by rw [pow_succ, mul_zero] lemma zero_pow_eq (n : ℕ) : (0 : M₀) ^ n = if n = 0 then 1 else 0 := by split_ifs with h · rw [h, pow_zero] · rw [zero_pow h] lemma zero_pow_eq_one₀ [Nontrivial M₀] : (0 : M₀) ^ n = 1 ↔ n = 0 := by rw [zero_pow_eq, one_ne_zero.ite_eq_left_iff] lemma pow_eq_zero_of_le : ∀ {m n}, m ≤ n → a ^ m = 0 → a ^ n = 0 \| _, _, Nat.le.refl, ha => ha \| _, _, Nat.le.step hmn, ha => by rw [pow_succ, pow_eq_zero_of_le hmn ha, zero_mul] lemma ne_zero_pow (hn : n ≠ 0) (ha : a ^ n ≠ 0) : a ≠ 0 := by rintro rfl; exact ha <\| zero_pow hn @[simp] lemma zero_pow_eq_zero [Nontrivial M₀] : (0 : M₀) ^ n = 0 ↔ n ≠ 0 := ⟨by rintro h rfl; simp at h, zero_pow⟩ lemma pow_mul_eq_zero_of_le {a b : M₀} {m n : ℕ} (hmn : m ≤ n) (h : a ^ m * b = 0) : a ^ n * b = 0 := by rw [show n = n - m + m by omega, pow_add, mul_assoc, h] simp variable [NoZeroDivisors M₀] lemma pow_eq_zero : ∀ {n}, a ^ n = 0 → a = 0 \| 0, ha => by simpa using congr_arg (a * ·) ha \| n + 1, ha => by rw [pow_succ, mul_eq_zero] at ha; exact ha.elim pow_eq_zero id @[simp] lemma pow_eq_zero_iff (hn : n ≠ 0) : a ^ n = 0 ↔ a = 0 := ⟨pow_eq_zero, by rintro rfl; exact zero_pow hn⟩ lemma pow_ne_zero_iff (hn : n ≠ 0) : a ^ n ≠ 0 ↔ a ≠ 0 := (pow_eq_zero_iff hn).not @[field_simps] lemma pow_ne_zero (n : ℕ) (h : a ≠ 0) : a ^ n ≠ 0 := mt pow_eq_zero h instance NeZero.pow [NeZero a] : NeZero (a ^ n) := ⟨pow_ne_zero n NeZero.out⟩ lemma sq_eq_zero_iff : a ^ 2 = 0 ↔ a = 0 := pow_eq_zero_iff two_ne_zero @[simp] lemma pow_eq_zero_iff' [Nontrivial M₀] : a ^ n = 0 ↔ a = 0 ∧ n ≠ 0 := by obtain rfl \| hn := eq_or_ne n 0 <;> simp [] theorem exists_right_inv_of_exists_left_inv {α} [MonoidWithZero α] (h : ∀ a : α, a ≠ 0 → ∃ b : α, b a = 1) {a : α} (ha : a ≠ 0) : ∃ b : α, a * b = 1 := by obtain _ \| _ := subsingleton_or_nontrivial α · exact ⟨a, Subsingleton.elim _ _⟩ obtain ⟨b, hb⟩ := h a ha obtain ⟨c, hc⟩ := h b (left_ne_zero_of_mul <\| hb.trans_ne one_ne_zero) refine ⟨b, ?_⟩ conv_lhs => rw [← one_mul (a * b), ← hc, mul_assoc, ← mul_assoc b, hb, one_mul, hc] end MonoidWithZero section CancelMonoidWithZero variable [CancelMonoidWithZero M₀] {a b c : M₀} -- see Note [lower instance priority] instance (priority := 10) CancelMonoidWithZero.to_noZeroDivisors : NoZeroDivisors M₀ := ⟨fun ab0 => or_iff_not_imp_left.mpr fun ha => mul_left_cancel₀ ha <\| ab0.trans (mul_zero _).symm⟩ @[simp] theorem mul_eq_mul_right_iff : a * c = b * c ↔ a = b ∨ c = 0 := by by_cases hc : c = 0 <;> [simp only [hc, mul_zero, or_true]; simp [mul_left_inj', hc]] @[simp] theorem mul_eq_mul_left_iff : a * b = a * c ↔ b = c ∨ a = 0 := by by_cases ha : a = 0 <;> [simp only [ha, zero_mul, or_true]; simp [mul_right_inj', ha]] theorem mul_right_eq_self₀ : a * b = a ↔ b = 1 ∨ a = 0 := calc a * b = a ↔ a * b = a * 1 := by rw [mul_one] _ ↔ b = 1 ∨ a = 0 := mul_eq_mul_left_iff theorem mul_left_eq_self₀ : a * b = b ↔ a = 1 ∨ b = 0 := calc a * b = b ↔ a * b = 1 * b := by rw [one_mul] _ ↔ a = 1 ∨ b = 0 := mul_eq_mul_right_iff @[simp] theorem mul_eq_left₀ (ha : a ≠ 0) : a * b = a ↔ b = 1 := by rw [Iff.comm, ← mul_right_inj' ha, mul_one] @[simp] theorem mul_eq_right₀ (hb : b ≠ 0) : a * b = b ↔ a = 1 := by rw [Iff.comm, ← mul_left_inj' hb, one_mul] @[simp] theorem left_eq_mul₀ (ha : a ≠ 0) : a = a * b ↔ b = 1 := by rw [eq_comm, mul_eq_left₀ ha] @[simp] theorem right_eq_mul₀ (hb : b ≠ 0) : b = a * b ↔ a = 1 := by rw [eq_comm, mul_eq_right₀ hb] /-- An element of a `CancelMonoidWithZero` fixed by right multiplication by an element other than one must be zero. -/ theorem eq_zero_of_mul_eq_self_right (h₁ : b ≠ 1) (h₂ : a * b = a) : a = 0 := Classical.byContradiction fun ha => h₁ <\| mul_left_cancel₀ ha <\| h₂.symm ▸ (mul_one a).symm /-- An element of a `CancelMonoidWithZero` fixed by left multiplication by an element other than one must be zero. -/ theorem eq_zero_of_mul_eq_self_left (h₁ : b ≠ 1) (h₂ : b * a = a) : a = 0 := Classical.byContradiction fun ha => h₁ <\| mul_right_cancel₀ ha <\| h₂.symm ▸ (one_mul a).symm end CancelMonoidWithZero section GroupWithZero variable [GroupWithZero G₀] {a b x : G₀} theorem GroupWithZero.mul_right_injective (h : x ≠ 0) : Function.Injective fun y => x * y := fun y y' w => by simpa only [← mul_assoc, inv_mul_cancel₀ h, one_mul] using congr_arg (fun y => x⁻¹ * y) w theorem GroupWithZero.mul_left_injective (h : x ≠ 0) : Function.Injective fun y => y * x := fun y y' w => by simpa only [mul_assoc, mul_inv_cancel₀ h, mul_one] using congr_arg (fun y => y * x⁻¹) w @[simp] theorem inv_mul_cancel_right₀ (h : b ≠ 0) (a : G₀) : a * b⁻¹ * b = a := calc a * b⁻¹ * b = a * (b⁻¹ * b) := mul_assoc _ _ _ _ = a := by simp [h] @[simp] theorem inv_mul_cancel_left₀ (h : a ≠ 0) (b : G₀) : a⁻¹ * (a * b) = b := calc a⁻¹ * (a * b) = a⁻¹ * a * b := (mul_assoc _ _ _).symm _ = b := by simp [h] private theorem inv_eq_of_mul (h : a * b = 1) : a⁻¹ = b := by rw [← inv_mul_cancel_left₀ (left_ne_zero_of_mul_eq_one h) b, h, mul_one] -- See note [lower instance priority]	instance (priority := 100) GroupWithZero.toDivisionMonoid : DivisionMonoid G₀ := { ‹GroupWithZero G₀› with inv := Inv.inv,	Mathlib/Algebra/GroupWithZero/Basic.lean	283	285
/- 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) :	Mathlib/Analysis/InnerProductSpace/Calculus.lean	218	223
/- 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.Analysis.SpecialFunctions.Trigonometric.Basic import Mathlib.Topology.Order.ProjIcc /-! # Inverse trigonometric functions. See also `Analysis.SpecialFunctions.Trigonometric.Arctan` for the inverse tan function. (This is delayed as it is easier to set up after developing complex trigonometric functions.) Basic inequalities on trigonometric functions. -/ noncomputable section open Topology Filter Set Filter Real namespace Real variable {x y : ℝ} /-- Inverse of the `sin` function, returns values in the range `-π / 2 ≤ arcsin x ≤ π / 2`. It defaults to `-π / 2` on `(-∞, -1)` and to `π / 2` to `(1, ∞)`. -/ @[pp_nodot] noncomputable def arcsin : ℝ → ℝ := Subtype.val ∘ IccExtend (neg_le_self zero_le_one) sinOrderIso.symm theorem arcsin_mem_Icc (x : ℝ) : arcsin x ∈ Icc (-(π / 2)) (π / 2) := Subtype.coe_prop _ @[simp] theorem range_arcsin : range arcsin = Icc (-(π / 2)) (π / 2) := by rw [arcsin, range_comp Subtype.val] simp [Icc] theorem arcsin_le_pi_div_two (x : ℝ) : arcsin x ≤ π / 2 := (arcsin_mem_Icc x).2 theorem neg_pi_div_two_le_arcsin (x : ℝ) : -(π / 2) ≤ arcsin x := (arcsin_mem_Icc x).1 theorem arcsin_projIcc (x : ℝ) : arcsin (projIcc (-1) 1 (neg_le_self zero_le_one) x) = arcsin x := by rw [arcsin, Function.comp_apply, IccExtend_val, Function.comp_apply, IccExtend, Function.comp_apply] theorem sin_arcsin' {x : ℝ} (hx : x ∈ Icc (-1 : ℝ) 1) : sin (arcsin x) = x := by simpa [arcsin, IccExtend_of_mem _ _ hx, -OrderIso.apply_symm_apply] using Subtype.ext_iff.1 (sinOrderIso.apply_symm_apply ⟨x, hx⟩) theorem sin_arcsin {x : ℝ} (hx₁ : -1 ≤ x) (hx₂ : x ≤ 1) : sin (arcsin x) = x := sin_arcsin' ⟨hx₁, hx₂⟩ theorem arcsin_sin' {x : ℝ} (hx : x ∈ Icc (-(π / 2)) (π / 2)) : arcsin (sin x) = x := injOn_sin (arcsin_mem_Icc _) hx <\| by rw [sin_arcsin (neg_one_le_sin _) (sin_le_one _)] theorem arcsin_sin {x : ℝ} (hx₁ : -(π / 2) ≤ x) (hx₂ : x ≤ π / 2) : arcsin (sin x) = x := arcsin_sin' ⟨hx₁, hx₂⟩ theorem strictMonoOn_arcsin : StrictMonoOn arcsin (Icc (-1) 1) := (Subtype.strictMono_coe _).comp_strictMonoOn <\| sinOrderIso.symm.strictMono.strictMonoOn_IccExtend _ @[gcongr] theorem arcsin_lt_arcsin {x y : ℝ} (hx : -1 ≤ x) (hlt : x < y) (hy : y ≤ 1) : arcsin x < arcsin y := strictMonoOn_arcsin ⟨hx, hlt.le.trans hy⟩ ⟨hx.trans hlt.le, hy⟩ hlt theorem monotone_arcsin : Monotone arcsin := (Subtype.mono_coe _).comp <\| sinOrderIso.symm.monotone.IccExtend _ @[gcongr] theorem arcsin_le_arcsin {x y : ℝ} (h : x ≤ y) : arcsin x ≤ arcsin y := monotone_arcsin h theorem injOn_arcsin : InjOn arcsin (Icc (-1) 1) := strictMonoOn_arcsin.injOn theorem arcsin_inj {x y : ℝ} (hx₁ : -1 ≤ x) (hx₂ : x ≤ 1) (hy₁ : -1 ≤ y) (hy₂ : y ≤ 1) : arcsin x = arcsin y ↔ x = y := injOn_arcsin.eq_iff ⟨hx₁, hx₂⟩ ⟨hy₁, hy₂⟩ @[continuity, fun_prop] theorem continuous_arcsin : Continuous arcsin := continuous_subtype_val.comp sinOrderIso.symm.continuous.Icc_extend' @[fun_prop] theorem continuousAt_arcsin {x : ℝ} : ContinuousAt arcsin x := continuous_arcsin.continuousAt theorem arcsin_eq_of_sin_eq {x y : ℝ} (h₁ : sin x = y) (h₂ : x ∈ Icc (-(π / 2)) (π / 2)) : arcsin y = x := by subst y exact injOn_sin (arcsin_mem_Icc _) h₂ (sin_arcsin' (sin_mem_Icc x)) @[simp] theorem arcsin_zero : arcsin 0 = 0 := arcsin_eq_of_sin_eq sin_zero ⟨neg_nonpos.2 pi_div_two_pos.le, pi_div_two_pos.le⟩ @[simp] theorem arcsin_one : arcsin 1 = π / 2 := arcsin_eq_of_sin_eq sin_pi_div_two <\| right_mem_Icc.2 (neg_le_self pi_div_two_pos.le) theorem arcsin_of_one_le {x : ℝ} (hx : 1 ≤ x) : arcsin x = π / 2 := by rw [← arcsin_projIcc, projIcc_of_right_le _ hx, Subtype.coe_mk, arcsin_one] theorem arcsin_neg_one : arcsin (-1) = -(π / 2) := arcsin_eq_of_sin_eq (by rw [sin_neg, sin_pi_div_two]) <\| left_mem_Icc.2 (neg_le_self pi_div_two_pos.le) theorem arcsin_of_le_neg_one {x : ℝ} (hx : x ≤ -1) : arcsin x = -(π / 2) := by rw [← arcsin_projIcc, projIcc_of_le_left _ hx, Subtype.coe_mk, arcsin_neg_one] @[simp] theorem arcsin_neg (x : ℝ) : arcsin (-x) = -arcsin x := by rcases le_total x (-1) with hx₁ \| hx₁ · rw [arcsin_of_le_neg_one hx₁, neg_neg, arcsin_of_one_le (le_neg.2 hx₁)] rcases le_total 1 x with hx₂ \| hx₂ · rw [arcsin_of_one_le hx₂, arcsin_of_le_neg_one (neg_le_neg hx₂)] refine arcsin_eq_of_sin_eq ?_ ?_ · rw [sin_neg, sin_arcsin hx₁ hx₂] · exact ⟨neg_le_neg (arcsin_le_pi_div_two _), neg_le.2 (neg_pi_div_two_le_arcsin _)⟩ theorem arcsin_le_iff_le_sin {x y : ℝ} (hx : x ∈ Icc (-1 : ℝ) 1) (hy : y ∈ Icc (-(π / 2)) (π / 2)) : arcsin x ≤ y ↔ x ≤ sin y := by rw [← arcsin_sin' hy, strictMonoOn_arcsin.le_iff_le hx (sin_mem_Icc _), arcsin_sin' hy] theorem arcsin_le_iff_le_sin' {x y : ℝ} (hy : y ∈ Ico (-(π / 2)) (π / 2)) : arcsin x ≤ y ↔ x ≤ sin y := by rcases le_total x (-1) with hx₁ \| hx₁ · simp [arcsin_of_le_neg_one hx₁, hy.1, hx₁.trans (neg_one_le_sin _)] rcases lt_or_le 1 x with hx₂ \| hx₂ · simp [arcsin_of_one_le hx₂.le, hy.2.not_le, (sin_le_one y).trans_lt hx₂] exact arcsin_le_iff_le_sin ⟨hx₁, hx₂⟩ (mem_Icc_of_Ico hy) theorem le_arcsin_iff_sin_le {x y : ℝ} (hx : x ∈ Icc (-(π / 2)) (π / 2)) (hy : y ∈ Icc (-1 : ℝ) 1) : x ≤ arcsin y ↔ sin x ≤ y := by rw [← neg_le_neg_iff, ← arcsin_neg, arcsin_le_iff_le_sin ⟨neg_le_neg hy.2, neg_le.2 hy.1⟩ ⟨neg_le_neg hx.2, neg_le.2 hx.1⟩, sin_neg, neg_le_neg_iff] theorem le_arcsin_iff_sin_le' {x y : ℝ} (hx : x ∈ Ioc (-(π / 2)) (π / 2)) : x ≤ arcsin y ↔ sin x ≤ y := by rw [← neg_le_neg_iff, ← arcsin_neg, arcsin_le_iff_le_sin' ⟨neg_le_neg hx.2, neg_lt.2 hx.1⟩, sin_neg, neg_le_neg_iff] theorem arcsin_lt_iff_lt_sin {x y : ℝ} (hx : x ∈ Icc (-1 : ℝ) 1) (hy : y ∈ Icc (-(π / 2)) (π / 2)) : arcsin x < y ↔ x < sin y := not_le.symm.trans <\| (not_congr <\| le_arcsin_iff_sin_le hy hx).trans not_le theorem arcsin_lt_iff_lt_sin' {x y : ℝ} (hy : y ∈ Ioc (-(π / 2)) (π / 2)) : arcsin x < y ↔ x < sin y := not_le.symm.trans <\| (not_congr <\| le_arcsin_iff_sin_le' hy).trans not_le theorem lt_arcsin_iff_sin_lt {x y : ℝ} (hx : x ∈ Icc (-(π / 2)) (π / 2)) (hy : y ∈ Icc (-1 : ℝ) 1) : x < arcsin y ↔ sin x < y := not_le.symm.trans <\| (not_congr <\| arcsin_le_iff_le_sin hy hx).trans not_le	theorem lt_arcsin_iff_sin_lt' {x y : ℝ} (hx : x ∈ Ico (-(π / 2)) (π / 2)) : x < arcsin y ↔ sin x < y := not_le.symm.trans <\| (not_congr <\| arcsin_le_iff_le_sin' hx).trans not_le theorem arcsin_eq_iff_eq_sin {x y : ℝ} (hy : y ∈ Ioo (-(π / 2)) (π / 2)) :	Mathlib/Analysis/SpecialFunctions/Trigonometric/Inverse.lean	162	166
/- Copyright (c) 2022 Yaël Dillies, Sara Rousta. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Yaël Dillies, Sara Rousta -/ import Mathlib.Logic.Equiv.Set import Mathlib.Order.Interval.Set.OrderEmbedding import Mathlib.Order.SetNotation /-! # Properties of unbundled upper/lower sets This file proves results on `IsUpperSet` and `IsLowerSet`, including their interactions with set operations, images, preimages and order duals, and properties that reflect stronger assumptions on the underlying order (such as `PartialOrder` and `LinearOrder`). ## TODO * Lattice structure on antichains. * Order equivalence between upper/lower sets and antichains. -/ open OrderDual Set variable {α β : Type} {ι : Sort} {κ : ι → Sort*} attribute [aesop norm unfold] IsUpperSet IsLowerSet section LE variable [LE α] {s t : Set α} {a : α} theorem isUpperSet_empty : IsUpperSet (∅ : Set α) := fun _ _ _ => id theorem isLowerSet_empty : IsLowerSet (∅ : Set α) := fun _ _ _ => id theorem isUpperSet_univ : IsUpperSet (univ : Set α) := fun _ _ _ => id theorem isLowerSet_univ : IsLowerSet (univ : Set α) := fun _ _ _ => id theorem IsUpperSet.compl (hs : IsUpperSet s) : IsLowerSet sᶜ := fun _a _b h hb ha => hb <\| hs h ha theorem IsLowerSet.compl (hs : IsLowerSet s) : IsUpperSet sᶜ := fun _a _b h hb ha => hb <\| hs h ha @[simp] theorem isUpperSet_compl : IsUpperSet sᶜ ↔ IsLowerSet s := ⟨fun h => by convert h.compl rw [compl_compl], IsLowerSet.compl⟩ @[simp] theorem isLowerSet_compl : IsLowerSet sᶜ ↔ IsUpperSet s := ⟨fun h => by convert h.compl rw [compl_compl], IsUpperSet.compl⟩ theorem IsUpperSet.union (hs : IsUpperSet s) (ht : IsUpperSet t) : IsUpperSet (s ∪ t) := fun _ _ h => Or.imp (hs h) (ht h) theorem IsLowerSet.union (hs : IsLowerSet s) (ht : IsLowerSet t) : IsLowerSet (s ∪ t) := fun _ _ h => Or.imp (hs h) (ht h) theorem IsUpperSet.inter (hs : IsUpperSet s) (ht : IsUpperSet t) : IsUpperSet (s ∩ t) := fun _ _ h => And.imp (hs h) (ht h) theorem IsLowerSet.inter (hs : IsLowerSet s) (ht : IsLowerSet t) : IsLowerSet (s ∩ t) := fun _ _ h => And.imp (hs h) (ht h) theorem isUpperSet_sUnion {S : Set (Set α)} (hf : ∀ s ∈ S, IsUpperSet s) : IsUpperSet (⋃₀ S) := fun _ _ h => Exists.imp fun _ hs => ⟨hs.1, hf _ hs.1 h hs.2⟩ theorem isLowerSet_sUnion {S : Set (Set α)} (hf : ∀ s ∈ S, IsLowerSet s) : IsLowerSet (⋃₀ S) := fun _ _ h => Exists.imp fun _ hs => ⟨hs.1, hf _ hs.1 h hs.2⟩ theorem isUpperSet_iUnion {f : ι → Set α} (hf : ∀ i, IsUpperSet (f i)) : IsUpperSet (⋃ i, f i) := isUpperSet_sUnion <\| forall_mem_range.2 hf theorem isLowerSet_iUnion {f : ι → Set α} (hf : ∀ i, IsLowerSet (f i)) : IsLowerSet (⋃ i, f i) := isLowerSet_sUnion <\| forall_mem_range.2 hf theorem isUpperSet_iUnion₂ {f : ∀ i, κ i → Set α} (hf : ∀ i j, IsUpperSet (f i j)) : IsUpperSet (⋃ (i) (j), f i j) := isUpperSet_iUnion fun i => isUpperSet_iUnion <\| hf i theorem isLowerSet_iUnion₂ {f : ∀ i, κ i → Set α} (hf : ∀ i j, IsLowerSet (f i j)) : IsLowerSet (⋃ (i) (j), f i j) := isLowerSet_iUnion fun i => isLowerSet_iUnion <\| hf i theorem isUpperSet_sInter {S : Set (Set α)} (hf : ∀ s ∈ S, IsUpperSet s) : IsUpperSet (⋂₀ S) := fun _ _ h => forall₂_imp fun s hs => hf s hs h theorem isLowerSet_sInter {S : Set (Set α)} (hf : ∀ s ∈ S, IsLowerSet s) : IsLowerSet (⋂₀ S) := fun _ _ h => forall₂_imp fun s hs => hf s hs h theorem isUpperSet_iInter {f : ι → Set α} (hf : ∀ i, IsUpperSet (f i)) : IsUpperSet (⋂ i, f i) := isUpperSet_sInter <\| forall_mem_range.2 hf theorem isLowerSet_iInter {f : ι → Set α} (hf : ∀ i, IsLowerSet (f i)) : IsLowerSet (⋂ i, f i) := isLowerSet_sInter <\| forall_mem_range.2 hf theorem isUpperSet_iInter₂ {f : ∀ i, κ i → Set α} (hf : ∀ i j, IsUpperSet (f i j)) : IsUpperSet (⋂ (i) (j), f i j) := isUpperSet_iInter fun i => isUpperSet_iInter <\| hf i theorem isLowerSet_iInter₂ {f : ∀ i, κ i → Set α} (hf : ∀ i j, IsLowerSet (f i j)) : IsLowerSet (⋂ (i) (j), f i j) := isLowerSet_iInter fun i => isLowerSet_iInter <\| hf i @[simp] theorem isLowerSet_preimage_ofDual_iff : IsLowerSet (ofDual ⁻¹' s) ↔ IsUpperSet s := Iff.rfl @[simp] theorem isUpperSet_preimage_ofDual_iff : IsUpperSet (ofDual ⁻¹' s) ↔ IsLowerSet s := Iff.rfl @[simp] theorem isLowerSet_preimage_toDual_iff {s : Set αᵒᵈ} : IsLowerSet (toDual ⁻¹' s) ↔ IsUpperSet s := Iff.rfl @[simp] theorem isUpperSet_preimage_toDual_iff {s : Set αᵒᵈ} : IsUpperSet (toDual ⁻¹' s) ↔ IsLowerSet s := Iff.rfl alias ⟨_, IsUpperSet.toDual⟩ := isLowerSet_preimage_ofDual_iff alias ⟨_, IsLowerSet.toDual⟩ := isUpperSet_preimage_ofDual_iff alias ⟨_, IsUpperSet.ofDual⟩ := isLowerSet_preimage_toDual_iff alias ⟨_, IsLowerSet.ofDual⟩ := isUpperSet_preimage_toDual_iff lemma IsUpperSet.isLowerSet_preimage_coe (hs : IsUpperSet s) : IsLowerSet ((↑) ⁻¹' t : Set s) ↔ ∀ b ∈ s, ∀ c ∈ t, b ≤ c → b ∈ t := by aesop lemma IsLowerSet.isUpperSet_preimage_coe (hs : IsLowerSet s) : IsUpperSet ((↑) ⁻¹' t : Set s) ↔ ∀ b ∈ s, ∀ c ∈ t, c ≤ b → b ∈ t := by aesop lemma IsUpperSet.sdiff (hs : IsUpperSet s) (ht : ∀ b ∈ s, ∀ c ∈ t, b ≤ c → b ∈ t) : IsUpperSet (s \ t) := fun _b _c hbc hb ↦ ⟨hs hbc hb.1, fun hc ↦ hb.2 <\| ht _ hb.1 _ hc hbc⟩ lemma IsLowerSet.sdiff (hs : IsLowerSet s) (ht : ∀ b ∈ s, ∀ c ∈ t, c ≤ b → b ∈ t) : IsLowerSet (s \ t) := fun _b _c hcb hb ↦ ⟨hs hcb hb.1, fun hc ↦ hb.2 <\| ht _ hb.1 _ hc hcb⟩ lemma IsUpperSet.sdiff_of_isLowerSet (hs : IsUpperSet s) (ht : IsLowerSet t) : IsUpperSet (s \ t) := hs.sdiff <\| by aesop lemma IsLowerSet.sdiff_of_isUpperSet (hs : IsLowerSet s) (ht : IsUpperSet t) : IsLowerSet (s \ t) := hs.sdiff <\| by aesop lemma IsUpperSet.erase (hs : IsUpperSet s) (has : ∀ b ∈ s, b ≤ a → b = a) : IsUpperSet (s \ {a}) := hs.sdiff <\| by simpa using has lemma IsLowerSet.erase (hs : IsLowerSet s) (has : ∀ b ∈ s, a ≤ b → b = a) : IsLowerSet (s \ {a}) := hs.sdiff <\| by simpa using has end LE section Preorder variable [Preorder α] [Preorder β] {s : Set α} {p : α → Prop} (a : α) theorem isUpperSet_Ici : IsUpperSet (Ici a) := fun _ _ => ge_trans theorem isLowerSet_Iic : IsLowerSet (Iic a) := fun _ _ => le_trans theorem isUpperSet_Ioi : IsUpperSet (Ioi a) := fun _ _ => flip lt_of_lt_of_le theorem isLowerSet_Iio : IsLowerSet (Iio a) := fun _ _ => lt_of_le_of_lt theorem isUpperSet_iff_Ici_subset : IsUpperSet s ↔ ∀ ⦃a⦄, a ∈ s → Ici a ⊆ s := by simp [IsUpperSet, subset_def, @forall_swap (_ ∈ s)] theorem isLowerSet_iff_Iic_subset : IsLowerSet s ↔ ∀ ⦃a⦄, a ∈ s → Iic a ⊆ s := by simp [IsLowerSet, subset_def, @forall_swap (_ ∈ s)] alias ⟨IsUpperSet.Ici_subset, _⟩ := isUpperSet_iff_Ici_subset alias ⟨IsLowerSet.Iic_subset, _⟩ := isLowerSet_iff_Iic_subset theorem IsUpperSet.Ioi_subset (h : IsUpperSet s) ⦃a⦄ (ha : a ∈ s) : Ioi a ⊆ s := Ioi_subset_Ici_self.trans <\| h.Ici_subset ha theorem IsLowerSet.Iio_subset (h : IsLowerSet s) ⦃a⦄ (ha : a ∈ s) : Iio a ⊆ s := h.toDual.Ioi_subset ha theorem IsUpperSet.ordConnected (h : IsUpperSet s) : s.OrdConnected := ⟨fun _ ha _ _ => Icc_subset_Ici_self.trans <\| h.Ici_subset ha⟩ theorem IsLowerSet.ordConnected (h : IsLowerSet s) : s.OrdConnected := ⟨fun _ _ _ hb => Icc_subset_Iic_self.trans <\| h.Iic_subset hb⟩ theorem IsUpperSet.preimage (hs : IsUpperSet s) {f : β → α} (hf : Monotone f) : IsUpperSet (f ⁻¹' s : Set β) := fun _ _ h => hs <\| hf h theorem IsLowerSet.preimage (hs : IsLowerSet s) {f : β → α} (hf : Monotone f) : IsLowerSet (f ⁻¹' s : Set β) := fun _ _ h => hs <\| hf h theorem IsUpperSet.image (hs : IsUpperSet s) (f : α ≃o β) : IsUpperSet (f '' s : Set β) := by change IsUpperSet ((f : α ≃ β) '' s) rw [Set.image_equiv_eq_preimage_symm] exact hs.preimage f.symm.monotone theorem IsLowerSet.image (hs : IsLowerSet s) (f : α ≃o β) : IsLowerSet (f '' s : Set β) := by change IsLowerSet ((f : α ≃ β) '' s) rw [Set.image_equiv_eq_preimage_symm] exact hs.preimage f.symm.monotone theorem OrderEmbedding.image_Ici (e : α ↪o β) (he : IsUpperSet (range e)) (a : α) : e '' Ici a = Ici (e a) := by rw [← e.preimage_Ici, image_preimage_eq_inter_range, inter_eq_left.2 <\| he.Ici_subset (mem_range_self _)] theorem OrderEmbedding.image_Iic (e : α ↪o β) (he : IsLowerSet (range e)) (a : α) : e '' Iic a = Iic (e a) := e.dual.image_Ici he a theorem OrderEmbedding.image_Ioi (e : α ↪o β) (he : IsUpperSet (range e)) (a : α) : e '' Ioi a = Ioi (e a) := by rw [← e.preimage_Ioi, image_preimage_eq_inter_range, inter_eq_left.2 <\| he.Ioi_subset (mem_range_self _)] theorem OrderEmbedding.image_Iio (e : α ↪o β) (he : IsLowerSet (range e)) (a : α) : e '' Iio a = Iio (e a) := e.dual.image_Ioi he a @[simp] theorem Set.monotone_mem : Monotone (· ∈ s) ↔ IsUpperSet s := Iff.rfl @[simp] theorem Set.antitone_mem : Antitone (· ∈ s) ↔ IsLowerSet s := forall_swap @[simp] theorem isUpperSet_setOf : IsUpperSet { a \| p a } ↔ Monotone p := Iff.rfl @[simp] theorem isLowerSet_setOf : IsLowerSet { a \| p a } ↔ Antitone p := forall_swap lemma IsUpperSet.upperBounds_subset (hs : IsUpperSet s) : s.Nonempty → upperBounds s ⊆ s := fun ⟨_a, ha⟩ _b hb ↦ hs (hb ha) ha lemma IsLowerSet.lowerBounds_subset (hs : IsLowerSet s) : s.Nonempty → lowerBounds s ⊆ s := fun ⟨_a, ha⟩ _b hb ↦ hs (hb ha) ha section OrderTop variable [OrderTop α] theorem IsLowerSet.top_mem (hs : IsLowerSet s) : ⊤ ∈ s ↔ s = univ := ⟨fun h => eq_univ_of_forall fun _ => hs le_top h, fun h => h.symm ▸ mem_univ _⟩ theorem IsUpperSet.top_mem (hs : IsUpperSet s) : ⊤ ∈ s ↔ s.Nonempty := ⟨fun h => ⟨_, h⟩, fun ⟨_a, ha⟩ => hs le_top ha⟩ theorem IsUpperSet.not_top_mem (hs : IsUpperSet s) : ⊤ ∉ s ↔ s = ∅ := hs.top_mem.not.trans not_nonempty_iff_eq_empty end OrderTop section OrderBot variable [OrderBot α] theorem IsUpperSet.bot_mem (hs : IsUpperSet s) : ⊥ ∈ s ↔ s = univ := ⟨fun h => eq_univ_of_forall fun _ => hs bot_le h, fun h => h.symm ▸ mem_univ _⟩ theorem IsLowerSet.bot_mem (hs : IsLowerSet s) : ⊥ ∈ s ↔ s.Nonempty := ⟨fun h => ⟨_, h⟩, fun ⟨_a, ha⟩ => hs bot_le ha⟩ theorem IsLowerSet.not_bot_mem (hs : IsLowerSet s) : ⊥ ∉ s ↔ s = ∅ := hs.bot_mem.not.trans not_nonempty_iff_eq_empty end OrderBot section NoMaxOrder variable [NoMaxOrder α] theorem IsUpperSet.not_bddAbove (hs : IsUpperSet s) : s.Nonempty → ¬BddAbove s := by rintro ⟨a, ha⟩ ⟨b, hb⟩ obtain ⟨c, hc⟩ := exists_gt b exact hc.not_le (hb <\| hs ((hb ha).trans hc.le) ha) theorem not_bddAbove_Ici : ¬BddAbove (Ici a) := (isUpperSet_Ici _).not_bddAbove nonempty_Ici theorem not_bddAbove_Ioi : ¬BddAbove (Ioi a) := (isUpperSet_Ioi _).not_bddAbove nonempty_Ioi end NoMaxOrder section NoMinOrder variable [NoMinOrder α] theorem IsLowerSet.not_bddBelow (hs : IsLowerSet s) : s.Nonempty → ¬BddBelow s := by rintro ⟨a, ha⟩ ⟨b, hb⟩ obtain ⟨c, hc⟩ := exists_lt b exact hc.not_le (hb <\| hs (hc.le.trans <\| hb ha) ha) theorem not_bddBelow_Iic : ¬BddBelow (Iic a) := (isLowerSet_Iic _).not_bddBelow nonempty_Iic theorem not_bddBelow_Iio : ¬BddBelow (Iio a) := (isLowerSet_Iio _).not_bddBelow nonempty_Iio end NoMinOrder end Preorder section PartialOrder variable [PartialOrder α] {s : Set α} theorem isUpperSet_iff_forall_lt : IsUpperSet s ↔ ∀ ⦃a b : α⦄, a < b → a ∈ s → b ∈ s := forall_congr' fun a => by simp [le_iff_eq_or_lt, or_imp, forall_and] theorem isLowerSet_iff_forall_lt : IsLowerSet s ↔ ∀ ⦃a b : α⦄, b < a → a ∈ s → b ∈ s := forall_congr' fun a => by simp [le_iff_eq_or_lt, or_imp, forall_and] theorem isUpperSet_iff_Ioi_subset : IsUpperSet s ↔ ∀ ⦃a⦄, a ∈ s → Ioi a ⊆ s := by simp [isUpperSet_iff_forall_lt, subset_def, @forall_swap (_ ∈ s)] theorem isLowerSet_iff_Iio_subset : IsLowerSet s ↔ ∀ ⦃a⦄, a ∈ s → Iio a ⊆ s := by simp [isLowerSet_iff_forall_lt, subset_def, @forall_swap (_ ∈ s)] end PartialOrder section LinearOrder variable [LinearOrder α] {s t : Set α} theorem IsUpperSet.total (hs : IsUpperSet s) (ht : IsUpperSet t) : s ⊆ t ∨ t ⊆ s := by by_contra! h simp_rw [Set.not_subset] at h obtain ⟨⟨a, has, hat⟩, b, hbt, hbs⟩ := h obtain hab \| hba := le_total a b · exact hbs (hs hab has) · exact hat (ht hba hbt) theorem IsLowerSet.total (hs : IsLowerSet s) (ht : IsLowerSet t) : s ⊆ t ∨ t ⊆ s := hs.toDual.total ht.toDual end LinearOrder		Mathlib/Order/UpperLower/Basic.lean	1,765	1,772
/- Copyright (c) 2021 Anatole Dedecker. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Anatole Dedecker, Bhavik Mehta -/ import Mathlib.Analysis.Calculus.Deriv.Support import Mathlib.Analysis.SpecialFunctions.Pow.Deriv import Mathlib.MeasureTheory.Function.Jacobian import Mathlib.MeasureTheory.Integral.IntervalIntegral.IntegrationByParts import Mathlib.MeasureTheory.Measure.Haar.NormedSpace import Mathlib.MeasureTheory.Measure.Haar.Unique /-! # Links between an integral and its "improper" version In its current state, mathlib only knows how to talk about definite ("proper") integrals, in the sense that it treats integrals over `[x, +∞)` the same as it treats integrals over `[y, z]`. For example, the integral over `[1, +∞)` is not defined to be the limit of the integral over `[1, x]` as `x` tends to `+∞`, which is known as an improper integral. Indeed, the "proper" definition is stronger than the "improper" one. The usual counterexample is `x ↦ sin(x)/x`, which has an improper integral over `[1, +∞)` but no definite integral. Although definite integrals have better properties, they are hardly usable when it comes to computing integrals on unbounded sets, which is much easier using limits. Thus, in this file, we prove various ways of studying the proper integral by studying the improper one. ## Definitions The main definition of this file is `MeasureTheory.AECover`. It is a rather technical definition whose sole purpose is generalizing and factoring proofs. Given an index type `ι`, a countably generated filter `l` over `ι`, and an `ι`-indexed family `φ` of subsets of a measurable space `α` equipped with a measure `μ`, one should think of a hypothesis `hφ : MeasureTheory.AECover μ l φ` as a sufficient condition for being able to interpret `∫ x, f x ∂μ` (if it exists) as the limit of `∫ x in φ i, f x ∂μ` as `i` tends to `l`. When using this definition with a measure restricted to a set `s`, which happens fairly often, one should not try too hard to use a `MeasureTheory.AECover` of subsets of `s`, as it often makes proofs more complicated than necessary. See for example the proof of `MeasureTheory.integrableOn_Iic_of_intervalIntegral_norm_tendsto` where we use `(fun x ↦ oi x)` as a `MeasureTheory.AECover` w.r.t. `μ.restrict (Iic b)`, instead of using `(fun x ↦ Ioc x b)`. ## Main statements - `MeasureTheory.AECover.lintegral_tendsto_of_countably_generated` : if `φ` is a `MeasureTheory.AECover μ l`, where `l` is a countably generated filter, and if `f` is a measurable `ENNReal`-valued function, then `∫⁻ x in φ n, f x ∂μ` tends to `∫⁻ x, f x ∂μ` as `n` tends to `l` - `MeasureTheory.AECover.integrable_of_integral_norm_tendsto` : if `φ` is a `MeasureTheory.AECover μ l`, where `l` is a countably generated filter, if `f` is measurable and integrable on each `φ n`, and if `∫ x in φ n, ‖f x‖ ∂μ` tends to some `I : ℝ` as n tends to `l`, then `f` is integrable - `MeasureTheory.AECover.integral_tendsto_of_countably_generated` : if `φ` is a `MeasureTheory.AECover μ l`, where `l` is a countably generated filter, and if `f` is measurable and integrable (globally), then `∫ x in φ n, f x ∂μ` tends to `∫ x, f x ∂μ` as `n` tends to `+∞`. We then specialize these lemmas to various use cases involving intervals, which are frequent in analysis. In particular, - `MeasureTheory.integral_Ioi_of_hasDerivAt_of_tendsto` is a version of FTC-2 on the interval `(a, +∞)`, giving the formula `∫ x in (a, +∞), g' x = l - g a` if `g'` is integrable and `g` tends to `l` at `+∞`. - `MeasureTheory.integral_Ioi_of_hasDerivAt_of_nonneg` gives the same result assuming that `g'` is nonnegative instead of integrable. Its automatic integrability in this context is proved in `MeasureTheory.integrableOn_Ioi_deriv_of_nonneg`. - `MeasureTheory.integral_comp_smul_deriv_Ioi` is a version of the change of variables formula on semi-infinite intervals. - `MeasureTheory.tendsto_limUnder_of_hasDerivAt_of_integrableOn_Ioi` shows that a function whose derivative is integrable on `(a, +∞)` has a limit at `+∞`. - `MeasureTheory.tendsto_zero_of_hasDerivAt_of_integrableOn_Ioi` shows that an integrable function whose derivative is integrable on `(a, +∞)` tends to `0` at `+∞`. Versions of these results are also given on the intervals `(-∞, a]` and `(-∞, +∞)`, as well as the corresponding versions of integration by parts. -/ open MeasureTheory Filter Set TopologicalSpace Topology open scoped ENNReal NNReal namespace MeasureTheory section AECover variable {α ι : Type} [MeasurableSpace α] (μ : Measure α) (l : Filter ι) /-- A sequence `φ` of subsets of `α` is a `MeasureTheory.AECover` w.r.t. a measure `μ` and a filter `l` if almost every point (w.r.t. `μ`) of `α` eventually belongs to `φ n` (w.r.t. `l`), and if each `φ n` is measurable. This definition is a technical way to avoid duplicating a lot of proofs. It should be thought of as a sufficient condition for being able to interpret `∫ x, f x ∂μ` (if it exists) as the limit of `∫ x in φ n, f x ∂μ` as `n` tends to `l`. See for example `MeasureTheory.AECover.lintegral_tendsto_of_countably_generated`, `MeasureTheory.AECover.integrable_of_integral_norm_tendsto` and `MeasureTheory.AECover.integral_tendsto_of_countably_generated`. -/ structure AECover (φ : ι → Set α) : Prop where ae_eventually_mem : ∀ᵐ x ∂μ, ∀ᶠ i in l, x ∈ φ i protected measurableSet : ∀ i, MeasurableSet <\| φ i variable {μ} {l} namespace AECover /-! ## Operations on `AECover`s -/ /-- Elementwise intersection of two `AECover`s is an `AECover`. -/ theorem inter {φ ψ : ι → Set α} (hφ : AECover μ l φ) (hψ : AECover μ l ψ) : AECover μ l (fun i ↦ φ i ∩ ψ i) where ae_eventually_mem := hψ.1.mp <\| hφ.1.mono fun _ ↦ Eventually.and measurableSet _ := (hφ.2 _).inter (hψ.2 _) theorem superset {φ ψ : ι → Set α} (hφ : AECover μ l φ) (hsub : ∀ i, φ i ⊆ ψ i) (hmeas : ∀ i, MeasurableSet (ψ i)) : AECover μ l ψ := ⟨hφ.1.mono fun _x hx ↦ hx.mono fun i hi ↦ hsub i hi, hmeas⟩ theorem mono_ac {ν : Measure α} {φ : ι → Set α} (hφ : AECover μ l φ) (hle : ν ≪ μ) : AECover ν l φ := ⟨hle hφ.1, hφ.2⟩ theorem mono {ν : Measure α} {φ : ι → Set α} (hφ : AECover μ l φ) (hle : ν ≤ μ) : AECover ν l φ := hφ.mono_ac hle.absolutelyContinuous end AECover section MetricSpace variable [PseudoMetricSpace α] [OpensMeasurableSpace α] theorem aecover_ball {x : α} {r : ι → ℝ} (hr : Tendsto r l atTop) : AECover μ l (fun i ↦ Metric.ball x (r i)) where measurableSet _ := Metric.isOpen_ball.measurableSet ae_eventually_mem := by filter_upwards with y filter_upwards [hr (Ioi_mem_atTop (dist x y))] with a ha using by simpa [dist_comm] using ha theorem aecover_closedBall {x : α} {r : ι → ℝ} (hr : Tendsto r l atTop) : AECover μ l (fun i ↦ Metric.closedBall x (r i)) where measurableSet _ := Metric.isClosed_closedBall.measurableSet ae_eventually_mem := by filter_upwards with y filter_upwards [hr (Ici_mem_atTop (dist x y))] with a ha using by simpa [dist_comm] using ha end MetricSpace section Preorderα variable [Preorder α] [TopologicalSpace α] [OrderClosedTopology α] [OpensMeasurableSpace α] {a b : ι → α} theorem aecover_Ici (ha : Tendsto a l atBot) : AECover μ l fun i => Ici (a i) where ae_eventually_mem := ae_of_all μ ha.eventually_le_atBot measurableSet _ := measurableSet_Ici theorem aecover_Iic (hb : Tendsto b l atTop) : AECover μ l fun i => Iic <\| b i := aecover_Ici (α := αᵒᵈ) hb theorem aecover_Icc (ha : Tendsto a l atBot) (hb : Tendsto b l atTop) : AECover μ l fun i => Icc (a i) (b i) := (aecover_Ici ha).inter (aecover_Iic hb) end Preorderα section LinearOrderα variable [LinearOrder α] [TopologicalSpace α] [OrderClosedTopology α] [OpensMeasurableSpace α] {a b : ι → α} (ha : Tendsto a l atBot) (hb : Tendsto b l atTop) include ha in theorem aecover_Ioi [NoMinOrder α] : AECover μ l fun i => Ioi (a i) where ae_eventually_mem := ae_of_all μ ha.eventually_lt_atBot measurableSet _ := measurableSet_Ioi include hb in theorem aecover_Iio [NoMaxOrder α] : AECover μ l fun i => Iio (b i) := aecover_Ioi (α := αᵒᵈ) hb include ha hb theorem aecover_Ioo [NoMinOrder α] [NoMaxOrder α] : AECover μ l fun i => Ioo (a i) (b i) := (aecover_Ioi ha).inter (aecover_Iio hb) theorem aecover_Ioc [NoMinOrder α] : AECover μ l fun i => Ioc (a i) (b i) := (aecover_Ioi ha).inter (aecover_Iic hb) theorem aecover_Ico [NoMaxOrder α] : AECover μ l fun i => Ico (a i) (b i) := (aecover_Ici ha).inter (aecover_Iio hb) end LinearOrderα section FiniteIntervals variable [LinearOrder α] [TopologicalSpace α] [OrderClosedTopology α] [OpensMeasurableSpace α] {a b : ι → α} {A B : α} (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) include ha in theorem aecover_Ioi_of_Ioi : AECover (μ.restrict (Ioi A)) l fun i ↦ Ioi (a i) where ae_eventually_mem := (ae_restrict_mem measurableSet_Ioi).mono fun _x hx ↦ ha.eventually <\| eventually_lt_nhds hx measurableSet _ := measurableSet_Ioi include hb in theorem aecover_Iio_of_Iio : AECover (μ.restrict (Iio B)) l fun i ↦ Iio (b i) := aecover_Ioi_of_Ioi (α := αᵒᵈ) hb include ha in theorem aecover_Ioi_of_Ici : AECover (μ.restrict (Ioi A)) l fun i ↦ Ici (a i) := (aecover_Ioi_of_Ioi ha).superset (fun _ ↦ Ioi_subset_Ici_self) fun _ ↦ measurableSet_Ici include hb in theorem aecover_Iio_of_Iic : AECover (μ.restrict (Iio B)) l fun i ↦ Iic (b i) := aecover_Ioi_of_Ici (α := αᵒᵈ) hb include ha hb in theorem aecover_Ioo_of_Ioo : AECover (μ.restrict <\| Ioo A B) l fun i => Ioo (a i) (b i) := ((aecover_Ioi_of_Ioi ha).mono <\| Measure.restrict_mono Ioo_subset_Ioi_self le_rfl).inter ((aecover_Iio_of_Iio hb).mono <\| Measure.restrict_mono Ioo_subset_Iio_self le_rfl) include ha hb in theorem aecover_Ioo_of_Icc : AECover (μ.restrict <\| Ioo A B) l fun i => Icc (a i) (b i) := (aecover_Ioo_of_Ioo ha hb).superset (fun _ ↦ Ioo_subset_Icc_self) fun _ ↦ measurableSet_Icc include ha hb in theorem aecover_Ioo_of_Ico : AECover (μ.restrict <\| Ioo A B) l fun i => Ico (a i) (b i) := (aecover_Ioo_of_Ioo ha hb).superset (fun _ ↦ Ioo_subset_Ico_self) fun _ ↦ measurableSet_Ico include ha hb in theorem aecover_Ioo_of_Ioc : AECover (μ.restrict <\| Ioo A B) l fun i => Ioc (a i) (b i) := (aecover_Ioo_of_Ioo ha hb).superset (fun _ ↦ Ioo_subset_Ioc_self) fun _ ↦ measurableSet_Ioc variable [NoAtoms μ] theorem aecover_Ioc_of_Icc (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Ioc A B) l fun i => Icc (a i) (b i) := (aecover_Ioo_of_Icc ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Ioc).ge theorem aecover_Ioc_of_Ico (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Ioc A B) l fun i => Ico (a i) (b i) := (aecover_Ioo_of_Ico ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Ioc).ge theorem aecover_Ioc_of_Ioc (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Ioc A B) l fun i => Ioc (a i) (b i) := (aecover_Ioo_of_Ioc ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Ioc).ge theorem aecover_Ioc_of_Ioo (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Ioc A B) l fun i => Ioo (a i) (b i) := (aecover_Ioo_of_Ioo ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Ioc).ge theorem aecover_Ico_of_Icc (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Ico A B) l fun i => Icc (a i) (b i) := (aecover_Ioo_of_Icc ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Ico).ge theorem aecover_Ico_of_Ico (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Ico A B) l fun i => Ico (a i) (b i) := (aecover_Ioo_of_Ico ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Ico).ge theorem aecover_Ico_of_Ioc (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Ico A B) l fun i => Ioc (a i) (b i) := (aecover_Ioo_of_Ioc ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Ico).ge theorem aecover_Ico_of_Ioo (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Ico A B) l fun i => Ioo (a i) (b i) := (aecover_Ioo_of_Ioo ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Ico).ge theorem aecover_Icc_of_Icc (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Icc A B) l fun i => Icc (a i) (b i) := (aecover_Ioo_of_Icc ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Icc).ge theorem aecover_Icc_of_Ico (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Icc A B) l fun i => Ico (a i) (b i) := (aecover_Ioo_of_Ico ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Icc).ge theorem aecover_Icc_of_Ioc (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Icc A B) l fun i => Ioc (a i) (b i) := (aecover_Ioo_of_Ioc ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Icc).ge theorem aecover_Icc_of_Ioo (ha : Tendsto a l (𝓝 A)) (hb : Tendsto b l (𝓝 B)) : AECover (μ.restrict <\| Icc A B) l fun i => Ioo (a i) (b i) := (aecover_Ioo_of_Ioo ha hb).mono (Measure.restrict_congr_set Ioo_ae_eq_Icc).ge end FiniteIntervals protected theorem AECover.restrict {φ : ι → Set α} (hφ : AECover μ l φ) {s : Set α} : AECover (μ.restrict s) l φ := hφ.mono Measure.restrict_le_self theorem aecover_restrict_of_ae_imp {s : Set α} {φ : ι → Set α} (hs : MeasurableSet s) (ae_eventually_mem : ∀ᵐ x ∂μ, x ∈ s → ∀ᶠ n in l, x ∈ φ n) (measurable : ∀ n, MeasurableSet <\| φ n) : AECover (μ.restrict s) l φ where ae_eventually_mem := by rwa [ae_restrict_iff' hs] measurableSet := measurable theorem AECover.inter_restrict {φ : ι → Set α} (hφ : AECover μ l φ) {s : Set α} (hs : MeasurableSet s) : AECover (μ.restrict s) l fun i => φ i ∩ s := aecover_restrict_of_ae_imp hs (hφ.ae_eventually_mem.mono fun _x hx hxs => hx.mono fun _i hi => ⟨hi, hxs⟩) fun i => (hφ.measurableSet i).inter hs theorem AECover.ae_tendsto_indicator {β : Type} [Zero β] [TopologicalSpace β] (f : α → β) {φ : ι → Set α} (hφ : AECover μ l φ) : ∀ᵐ x ∂μ, Tendsto (fun i => (φ i).indicator f x) l (𝓝 <\| f x) := hφ.ae_eventually_mem.mono fun _x hx => tendsto_const_nhds.congr' <\| hx.mono fun _n hn => (indicator_of_mem hn _).symm theorem AECover.aemeasurable {β : Type} [MeasurableSpace β] [l.IsCountablyGenerated] [l.NeBot] {f : α → β} {φ : ι → Set α} (hφ : AECover μ l φ) (hfm : ∀ i, AEMeasurable f (μ.restrict <\| φ i)) : AEMeasurable f μ := by obtain ⟨u, hu⟩ := l.exists_seq_tendsto have := aemeasurable_iUnion_iff.mpr fun n : ℕ => hfm (u n) rwa [Measure.restrict_eq_self_of_ae_mem] at this filter_upwards [hφ.ae_eventually_mem] with x hx using mem_iUnion.mpr (hu.eventually hx).exists theorem AECover.aestronglyMeasurable {β : Type} [TopologicalSpace β] [PseudoMetrizableSpace β] [l.IsCountablyGenerated] [l.NeBot] {f : α → β} {φ : ι → Set α} (hφ : AECover μ l φ) (hfm : ∀ i, AEStronglyMeasurable f (μ.restrict <\| φ i)) : AEStronglyMeasurable f μ := by obtain ⟨u, hu⟩ := l.exists_seq_tendsto have := aestronglyMeasurable_iUnion_iff.mpr fun n : ℕ => hfm (u n) rwa [Measure.restrict_eq_self_of_ae_mem] at this filter_upwards [hφ.ae_eventually_mem] with x hx using mem_iUnion.mpr (hu.eventually hx).exists end AECover theorem AECover.comp_tendsto {α ι ι' : Type} [MeasurableSpace α] {μ : Measure α} {l : Filter ι} {l' : Filter ι'} {φ : ι → Set α} (hφ : AECover μ l φ) {u : ι' → ι} (hu : Tendsto u l' l) : AECover μ l' (φ ∘ u) where ae_eventually_mem := hφ.ae_eventually_mem.mono fun _x hx => hu.eventually hx measurableSet i := hφ.measurableSet (u i) section AECoverUnionInterCountable variable {α ι : Type} [Countable ι] [MeasurableSpace α] {μ : Measure α} theorem AECover.biUnion_Iic_aecover [Preorder ι] {φ : ι → Set α} (hφ : AECover μ atTop φ) : AECover μ atTop fun n : ι => ⋃ (k) (_h : k ∈ Iic n), φ k := hφ.superset (fun _ ↦ subset_biUnion_of_mem right_mem_Iic) fun _ ↦ .biUnion (to_countable _) fun _ _ ↦ (hφ.2 _) theorem AECover.biInter_Ici_aecover [Preorder ι] {φ : ι → Set α} (hφ : AECover μ atTop φ) : AECover μ atTop fun n : ι => ⋂ (k) (_h : k ∈ Ici n), φ k where ae_eventually_mem := hφ.ae_eventually_mem.mono fun x h ↦ by simpa only [mem_iInter, mem_Ici, eventually_forall_ge_atTop] measurableSet _ := .biInter (to_countable _) fun n _ => hφ.measurableSet n end AECoverUnionInterCountable section Lintegral variable {α ι : Type} [MeasurableSpace α] {μ : Measure α} {l : Filter ι} private theorem lintegral_tendsto_of_monotone_of_nat {φ : ℕ → Set α} (hφ : AECover μ atTop φ) (hmono : Monotone φ) {f : α → ℝ≥0∞} (hfm : AEMeasurable f μ) : Tendsto (fun i => ∫⁻ x in φ i, f x ∂μ) atTop (𝓝 <\| ∫⁻ x, f x ∂μ) := let F n := (φ n).indicator f have key₁ : ∀ n, AEMeasurable (F n) μ := fun n => hfm.indicator (hφ.measurableSet n) have key₂ : ∀ᵐ x : α ∂μ, Monotone fun n => F n x := ae_of_all _ fun x _i _j hij => indicator_le_indicator_of_subset (hmono hij) (fun x => zero_le <\| f x) x have key₃ : ∀ᵐ x : α ∂μ, Tendsto (fun n => F n x) atTop (𝓝 (f x)) := hφ.ae_tendsto_indicator f (lintegral_tendsto_of_tendsto_of_monotone key₁ key₂ key₃).congr fun n => lintegral_indicator (hφ.measurableSet n) _ theorem AECover.lintegral_tendsto_of_nat {φ : ℕ → Set α} (hφ : AECover μ atTop φ) {f : α → ℝ≥0∞} (hfm : AEMeasurable f μ) : Tendsto (∫⁻ x in φ ·, f x ∂μ) atTop (𝓝 <\| ∫⁻ x, f x ∂μ) := by have lim₁ := lintegral_tendsto_of_monotone_of_nat hφ.biInter_Ici_aecover (fun i j hij => biInter_subset_biInter_left (Ici_subset_Ici.mpr hij)) hfm have lim₂ := lintegral_tendsto_of_monotone_of_nat hφ.biUnion_Iic_aecover (fun i j hij => biUnion_subset_biUnion_left (Iic_subset_Iic.mpr hij)) hfm refine tendsto_of_tendsto_of_tendsto_of_le_of_le lim₁ lim₂ (fun n ↦ ?_) fun n ↦ ?_ exacts [lintegral_mono_set (biInter_subset_of_mem left_mem_Ici), lintegral_mono_set (subset_biUnion_of_mem right_mem_Iic)] theorem AECover.lintegral_tendsto_of_countably_generated [l.IsCountablyGenerated] {φ : ι → Set α} (hφ : AECover μ l φ) {f : α → ℝ≥0∞} (hfm : AEMeasurable f μ) : Tendsto (fun i => ∫⁻ x in φ i, f x ∂μ) l (𝓝 <\| ∫⁻ x, f x ∂μ) := tendsto_of_seq_tendsto fun _u hu => (hφ.comp_tendsto hu).lintegral_tendsto_of_nat hfm theorem AECover.lintegral_eq_of_tendsto [l.NeBot] [l.IsCountablyGenerated] {φ : ι → Set α} (hφ : AECover μ l φ) {f : α → ℝ≥0∞} (I : ℝ≥0∞) (hfm : AEMeasurable f μ) (htendsto : Tendsto (fun i => ∫⁻ x in φ i, f x ∂μ) l (𝓝 I)) : ∫⁻ x, f x ∂μ = I := tendsto_nhds_unique (hφ.lintegral_tendsto_of_countably_generated hfm) htendsto theorem AECover.iSup_lintegral_eq_of_countably_generated [Nonempty ι] [l.NeBot] [l.IsCountablyGenerated] {φ : ι → Set α} (hφ : AECover μ l φ) {f : α → ℝ≥0∞} (hfm : AEMeasurable f μ) : ⨆ i : ι, ∫⁻ x in φ i, f x ∂μ = ∫⁻ x, f x ∂μ := by have := hφ.lintegral_tendsto_of_countably_generated hfm refine ciSup_eq_of_forall_le_of_forall_lt_exists_gt (fun i => lintegral_mono' Measure.restrict_le_self le_rfl) fun w hw => ?_ exact (this.eventually_const_lt hw).exists end Lintegral section Integrable variable {α ι E : Type} [MeasurableSpace α] {μ : Measure α} {l : Filter ι} [NormedAddCommGroup E] theorem AECover.integrable_of_lintegral_enorm_bounded [l.NeBot] [l.IsCountablyGenerated] {φ : ι → Set α} (hφ : AECover μ l φ) {f : α → E} (I : ℝ) (hfm : AEStronglyMeasurable f μ) (hbounded : ∀ᶠ i in l, ∫⁻ x in φ i, ‖f x‖ₑ ∂μ ≤ ENNReal.ofReal I) : Integrable f μ := by refine ⟨hfm, (le_of_tendsto ?_ hbounded).trans_lt ENNReal.ofReal_lt_top⟩ exact hφ.lintegral_tendsto_of_countably_generated hfm.enorm @[deprecated (since := "2025-01-22")] alias AECover.integrable_of_lintegral_nnnorm_bounded := AECover.integrable_of_lintegral_enorm_bounded theorem AECover.integrable_of_lintegral_enorm_tendsto [l.NeBot] [l.IsCountablyGenerated] {φ : ι → Set α} (hφ : AECover μ l φ) {f : α → E} (I : ℝ) (hfm : AEStronglyMeasurable f μ) (htendsto : Tendsto (fun i => ∫⁻ x in φ i, ‖f x‖ₑ ∂μ) l (𝓝 <\| .ofReal I)) : Integrable f μ := by refine hφ.integrable_of_lintegral_enorm_bounded (max 1 (I + 1)) hfm ?_ refine htendsto.eventually (ge_mem_nhds ?_) refine (ENNReal.ofReal_lt_ofReal_iff (lt_max_of_lt_left zero_lt_one)).2 ?_ exact lt_max_of_lt_right (lt_add_one I)	@[deprecated (since := "2025-01-22")] alias AECover.integrable_of_lintegral_nnnorm_tendsto := AECover.integrable_of_lintegral_enorm_tendsto theorem AECover.integrable_of_lintegral_enorm_bounded' [l.NeBot] [l.IsCountablyGenerated] {φ : ι → Set α} (hφ : AECover μ l φ) {f : α → E} (I : ℝ≥0) (hfm : AEStronglyMeasurable f μ) (hbounded : ∀ᶠ i in l, ∫⁻ x in φ i, ‖f x‖ₑ ∂μ ≤ I) : Integrable f μ := hφ.integrable_of_lintegral_enorm_bounded I hfm	Mathlib/MeasureTheory/Integral/IntegralEqImproper.lean	413	421
/- Copyright (c) 2019 Floris van Doorn. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Floris van Doorn, Yury Kudryashov, Sébastien Gouëzel, Chris Hughes -/ import Mathlib.Data.Fin.Rev import Mathlib.Data.Nat.Find /-! # Operation on tuples We interpret maps `∀ i : Fin n, α i` as `n`-tuples of elements of possibly varying type `α i`, `(α 0, …, α (n-1))`. A particular case is `Fin n → α` of elements with all the same type. In this case when `α i` is a constant map, then tuples are isomorphic (but not definitionally equal) to `Vector`s. ## Main declarations There are three (main) ways to consider `Fin n` as a subtype of `Fin (n + 1)`, hence three (main) ways to move between tuples of length `n` and of length `n + 1` by adding/removing an entry. ### Adding at the start * `Fin.succ`: Send `i : Fin n` to `i + 1 : Fin (n + 1)`. This is defined in Core. * `Fin.cases`: Induction/recursion principle for `Fin`: To prove a property/define a function for all `Fin (n + 1)`, it is enough to prove/define it for `0` and for `i.succ` for all `i : Fin n`. This is defined in Core. * `Fin.cons`: Turn a tuple `f : Fin n → α` and an entry `a : α` into a tuple `Fin.cons a f : Fin (n + 1) → α` by adding `a` at the start. In general, tuples can be dependent functions, in which case `f : ∀ i : Fin n, α i.succ` and `a : α 0`. This is a special case of `Fin.cases`. * `Fin.tail`: Turn a tuple `f : Fin (n + 1) → α` into a tuple `Fin.tail f : Fin n → α` by forgetting the start. In general, tuples can be dependent functions, in which case `Fin.tail f : ∀ i : Fin n, α i.succ`. ### Adding at the end * `Fin.castSucc`: Send `i : Fin n` to `i : Fin (n + 1)`. This is defined in Core. * `Fin.lastCases`: Induction/recursion principle for `Fin`: To prove a property/define a function for all `Fin (n + 1)`, it is enough to prove/define it for `last n` and for `i.castSucc` for all `i : Fin n`. This is defined in Core. * `Fin.snoc`: Turn a tuple `f : Fin n → α` and an entry `a : α` into a tuple `Fin.snoc f a : Fin (n + 1) → α` by adding `a` at the end. In general, tuples can be dependent functions, in which case `f : ∀ i : Fin n, α i.castSucc` and `a : α (last n)`. This is a special case of `Fin.lastCases`. * `Fin.init`: Turn a tuple `f : Fin (n + 1) → α` into a tuple `Fin.init f : Fin n → α` by forgetting the start. In general, tuples can be dependent functions, in which case `Fin.init f : ∀ i : Fin n, α i.castSucc`. ### Adding in the middle For a pivot `p : Fin (n + 1)`, * `Fin.succAbove`: Send `i : Fin n` to * `i : Fin (n + 1)` if `i < p`, * `i + 1 : Fin (n + 1)` if `p ≤ i`. * `Fin.succAboveCases`: Induction/recursion principle for `Fin`: To prove a property/define a function for all `Fin (n + 1)`, it is enough to prove/define it for `p` and for `p.succAbove i` for all `i : Fin n`. * `Fin.insertNth`: Turn a tuple `f : Fin n → α` and an entry `a : α` into a tuple `Fin.insertNth f a : Fin (n + 1) → α` by adding `a` in position `p`. In general, tuples can be dependent functions, in which case `f : ∀ i : Fin n, α (p.succAbove i)` and `a : α p`. This is a special case of `Fin.succAboveCases`. * `Fin.removeNth`: Turn a tuple `f : Fin (n + 1) → α` into a tuple `Fin.removeNth p f : Fin n → α` by forgetting the `p`-th value. In general, tuples can be dependent functions, in which case `Fin.removeNth f : ∀ i : Fin n, α (succAbove p i)`. `p = 0` means we add at the start. `p = last n` means we add at the end. ### Miscellaneous * `Fin.find p` : returns the first index `n` where `p n` is satisfied, and `none` if it is never satisfied. * `Fin.append a b` : append two tuples. * `Fin.repeat n a` : repeat a tuple `n` times. -/ assert_not_exists Monoid universe u v namespace Fin variable {m n : ℕ} open Function section Tuple /-- There is exactly one tuple of size zero. -/ example (α : Fin 0 → Sort u) : Unique (∀ i : Fin 0, α i) := by infer_instance theorem tuple0_le {α : Fin 0 → Type} [∀ i, Preorder (α i)] (f g : ∀ i, α i) : f ≤ g := finZeroElim variable {α : Fin (n + 1) → Sort u} (x : α 0) (q : ∀ i, α i) (p : ∀ i : Fin n, α i.succ) (i : Fin n) (y : α i.succ) (z : α 0) /-- The tail of an `n+1` tuple, i.e., its last `n` entries. -/ def tail (q : ∀ i, α i) : ∀ i : Fin n, α i.succ := fun i ↦ q i.succ theorem tail_def {n : ℕ} {α : Fin (n + 1) → Sort} {q : ∀ i, α i} : (tail fun k : Fin (n + 1) ↦ q k) = fun k : Fin n ↦ q k.succ := rfl /-- Adding an element at the beginning of an `n`-tuple, to get an `n+1`-tuple. -/ def cons (x : α 0) (p : ∀ i : Fin n, α i.succ) : ∀ i, α i := fun j ↦ Fin.cases x p j @[simp] theorem tail_cons : tail (cons x p) = p := by simp +unfoldPartialApp [tail, cons] @[simp] theorem cons_succ : cons x p i.succ = p i := by simp [cons] @[simp] theorem cons_zero : cons x p 0 = x := by simp [cons] @[simp] theorem cons_one {α : Fin (n + 2) → Sort} (x : α 0) (p : ∀ i : Fin n.succ, α i.succ) : cons x p 1 = p 0 := by rw [← cons_succ x p]; rfl /-- Updating a tuple and adding an element at the beginning commute. -/ @[simp] theorem cons_update : cons x (update p i y) = update (cons x p) i.succ y := by ext j by_cases h : j = 0 · rw [h] simp [Ne.symm (succ_ne_zero i)] · let j' := pred j h have : j'.succ = j := succ_pred j h rw [← this, cons_succ] by_cases h' : j' = i · rw [h'] simp · have : j'.succ ≠ i.succ := by rwa [Ne, succ_inj] rw [update_of_ne h', update_of_ne this, cons_succ] /-- As a binary function, `Fin.cons` is injective. -/ theorem cons_injective2 : Function.Injective2 (@cons n α) := fun x₀ y₀ x y h ↦ ⟨congr_fun h 0, funext fun i ↦ by simpa using congr_fun h (Fin.succ i)⟩ @[simp] theorem cons_inj {x₀ y₀ : α 0} {x y : ∀ i : Fin n, α i.succ} : cons x₀ x = cons y₀ y ↔ x₀ = y₀ ∧ x = y := cons_injective2.eq_iff theorem cons_left_injective (x : ∀ i : Fin n, α i.succ) : Function.Injective fun x₀ ↦ cons x₀ x := cons_injective2.left _ theorem cons_right_injective (x₀ : α 0) : Function.Injective (cons x₀) := cons_injective2.right _ /-- Adding an element at the beginning of a tuple and then updating it amounts to adding it directly. -/ theorem update_cons_zero : update (cons x p) 0 z = cons z p := by ext j by_cases h : j = 0 · rw [h] simp · simp only [h, update_of_ne, Ne, not_false_iff] let j' := pred j h have : j'.succ = j := succ_pred j h rw [← this, cons_succ, cons_succ] /-- Concatenating the first element of a tuple with its tail gives back the original tuple -/ @[simp] theorem cons_self_tail : cons (q 0) (tail q) = q := by ext j by_cases h : j = 0 · rw [h] simp · let j' := pred j h have : j'.succ = j := succ_pred j h rw [← this] unfold tail rw [cons_succ] /-- Equivalence between tuples of length `n + 1` and pairs of an element and a tuple of length `n` given by separating out the first element of the tuple. This is `Fin.cons` as an `Equiv`. -/ @[simps] def consEquiv (α : Fin (n + 1) → Type) : α 0 × (∀ i, α (succ i)) ≃ ∀ i, α i where toFun f := cons f.1 f.2 invFun f := (f 0, tail f) left_inv f := by simp right_inv f := by simp /-- Recurse on an `n+1`-tuple by splitting it into a single element and an `n`-tuple. -/ @[elab_as_elim] def consCases {P : (∀ i : Fin n.succ, α i) → Sort v} (h : ∀ x₀ x, P (Fin.cons x₀ x)) (x : ∀ i : Fin n.succ, α i) : P x := _root_.cast (by rw [cons_self_tail]) <\| h (x 0) (tail x) @[simp] theorem consCases_cons {P : (∀ i : Fin n.succ, α i) → Sort v} (h : ∀ x₀ x, P (Fin.cons x₀ x)) (x₀ : α 0) (x : ∀ i : Fin n, α i.succ) : @consCases _ _ _ h (cons x₀ x) = h x₀ x := by rw [consCases, cast_eq] congr /-- Recurse on a tuple by splitting into `Fin.elim0` and `Fin.cons`. -/ @[elab_as_elim] def consInduction {α : Sort} {P : ∀ {n : ℕ}, (Fin n → α) → Sort v} (h0 : P Fin.elim0) (h : ∀ {n} (x₀) (x : Fin n → α), P x → P (Fin.cons x₀ x)) : ∀ {n : ℕ} (x : Fin n → α), P x \| 0, x => by convert h0 \| _ + 1, x => consCases (fun _ _ ↦ h _ _ <\| consInduction h0 h _) x theorem cons_injective_of_injective {α} {x₀ : α} {x : Fin n → α} (hx₀ : x₀ ∉ Set.range x) (hx : Function.Injective x) : Function.Injective (cons x₀ x : Fin n.succ → α) := by refine Fin.cases ?_ ?_ · refine Fin.cases ?_ ?_ · intro rfl · intro j h rw [cons_zero, cons_succ] at h exact hx₀.elim ⟨_, h.symm⟩ · intro i refine Fin.cases ?_ ?_ · intro h rw [cons_zero, cons_succ] at h exact hx₀.elim ⟨_, h⟩ · intro j h rw [cons_succ, cons_succ] at h exact congr_arg _ (hx h) theorem cons_injective_iff {α} {x₀ : α} {x : Fin n → α} : Function.Injective (cons x₀ x : Fin n.succ → α) ↔ x₀ ∉ Set.range x ∧ Function.Injective x := by refine ⟨fun h ↦ ⟨?_, ?_⟩, fun h ↦ cons_injective_of_injective h.1 h.2⟩ · rintro ⟨i, hi⟩ replace h := @h i.succ 0 simp [hi] at h · simpa [Function.comp] using h.comp (Fin.succ_injective _) @[simp] theorem forall_fin_zero_pi {α : Fin 0 → Sort} {P : (∀ i, α i) → Prop} : (∀ x, P x) ↔ P finZeroElim := ⟨fun h ↦ h _, fun h x ↦ Subsingleton.elim finZeroElim x ▸ h⟩ @[simp] theorem exists_fin_zero_pi {α : Fin 0 → Sort} {P : (∀ i, α i) → Prop} : (∃ x, P x) ↔ P finZeroElim := ⟨fun ⟨x, h⟩ ↦ Subsingleton.elim x finZeroElim ▸ h, fun h ↦ ⟨_, h⟩⟩ theorem forall_fin_succ_pi {P : (∀ i, α i) → Prop} : (∀ x, P x) ↔ ∀ a v, P (Fin.cons a v) := ⟨fun h a v ↦ h (Fin.cons a v), consCases⟩ theorem exists_fin_succ_pi {P : (∀ i, α i) → Prop} : (∃ x, P x) ↔ ∃ a v, P (Fin.cons a v) := ⟨fun ⟨x, h⟩ ↦ ⟨x 0, tail x, (cons_self_tail x).symm ▸ h⟩, fun ⟨_, _, h⟩ ↦ ⟨_, h⟩⟩ /-- Updating the first element of a tuple does not change the tail. -/ @[simp] theorem tail_update_zero : tail (update q 0 z) = tail q := by ext j simp [tail] /-- Updating a nonzero element and taking the tail commute. -/ @[simp] theorem tail_update_succ : tail (update q i.succ y) = update (tail q) i y := by ext j by_cases h : j = i · rw [h] simp [tail] · simp [tail, (Fin.succ_injective n).ne h, h] theorem comp_cons {α : Sort} {β : Sort} (g : α → β) (y : α) (q : Fin n → α) : g ∘ cons y q = cons (g y) (g ∘ q) := by ext j by_cases h : j = 0 · rw [h] rfl · let j' := pred j h have : j'.succ = j := succ_pred j h rw [← this, cons_succ, comp_apply, comp_apply, cons_succ] theorem comp_tail {α : Sort} {β : Sort} (g : α → β) (q : Fin n.succ → α) : g ∘ tail q = tail (g ∘ q) := by ext j simp [tail] section Preorder variable {α : Fin (n + 1) → Type} theorem le_cons [∀ i, Preorder (α i)] {x : α 0} {q : ∀ i, α i} {p : ∀ i : Fin n, α i.succ} : q ≤ cons x p ↔ q 0 ≤ x ∧ tail q ≤ p := forall_fin_succ.trans <\| and_congr Iff.rfl <\| forall_congr' fun j ↦ by simp [tail] theorem cons_le [∀ i, Preorder (α i)] {x : α 0} {q : ∀ i, α i} {p : ∀ i : Fin n, α i.succ} : cons x p ≤ q ↔ x ≤ q 0 ∧ p ≤ tail q := @le_cons _ (fun i ↦ (α i)ᵒᵈ) _ x q p theorem cons_le_cons [∀ i, Preorder (α i)] {x₀ y₀ : α 0} {x y : ∀ i : Fin n, α i.succ} : cons x₀ x ≤ cons y₀ y ↔ x₀ ≤ y₀ ∧ x ≤ y := forall_fin_succ.trans <\| and_congr_right' <\| by simp only [cons_succ, Pi.le_def] end Preorder theorem range_fin_succ {α} (f : Fin (n + 1) → α) : Set.range f = insert (f 0) (Set.range (Fin.tail f)) := Set.ext fun _ ↦ exists_fin_succ.trans <\| eq_comm.or Iff.rfl @[simp] theorem range_cons {α} {n : ℕ} (x : α) (b : Fin n → α) : Set.range (Fin.cons x b : Fin n.succ → α) = insert x (Set.range b) := by rw [range_fin_succ, cons_zero, tail_cons] section Append variable {α : Sort} /-- Append a tuple of length `m` to a tuple of length `n` to get a tuple of length `m + n`. This is a non-dependent version of `Fin.add_cases`. -/ def append (a : Fin m → α) (b : Fin n → α) : Fin (m + n) → α := @Fin.addCases _ _ (fun _ => α) a b @[simp] theorem append_left (u : Fin m → α) (v : Fin n → α) (i : Fin m) : append u v (Fin.castAdd n i) = u i := addCases_left _ @[simp] theorem append_right (u : Fin m → α) (v : Fin n → α) (i : Fin n) : append u v (natAdd m i) = v i := addCases_right _ theorem append_right_nil (u : Fin m → α) (v : Fin n → α) (hv : n = 0) : append u v = u ∘ Fin.cast (by rw [hv, Nat.add_zero]) := by refine funext (Fin.addCases (fun l => ?_) fun r => ?_) · rw [append_left, Function.comp_apply] refine congr_arg u (Fin.ext ?_) simp · exact (Fin.cast hv r).elim0 @[simp] theorem append_elim0 (u : Fin m → α) : append u Fin.elim0 = u ∘ Fin.cast (Nat.add_zero _) := append_right_nil _ _ rfl theorem append_left_nil (u : Fin m → α) (v : Fin n → α) (hu : m = 0) : append u v = v ∘ Fin.cast (by rw [hu, Nat.zero_add]) := by refine funext (Fin.addCases (fun l => ?_) fun r => ?_) · exact (Fin.cast hu l).elim0 · rw [append_right, Function.comp_apply] refine congr_arg v (Fin.ext ?_) simp [hu] @[simp] theorem elim0_append (v : Fin n → α) : append Fin.elim0 v = v ∘ Fin.cast (Nat.zero_add _) := append_left_nil _ _ rfl theorem append_assoc {p : ℕ} (a : Fin m → α) (b : Fin n → α) (c : Fin p → α) : append (append a b) c = append a (append b c) ∘ Fin.cast (Nat.add_assoc ..) := by ext i rw [Function.comp_apply] refine Fin.addCases (fun l => ?_) (fun r => ?_) i · rw [append_left] refine Fin.addCases (fun ll => ?_) (fun lr => ?_) l · rw [append_left] simp [castAdd_castAdd] · rw [append_right] simp [castAdd_natAdd] · rw [append_right] simp [← natAdd_natAdd] /-- Appending a one-tuple to the left is the same as `Fin.cons`. -/ theorem append_left_eq_cons {n : ℕ} (x₀ : Fin 1 → α) (x : Fin n → α) : Fin.append x₀ x = Fin.cons (x₀ 0) x ∘ Fin.cast (Nat.add_comm ..) := by ext i refine Fin.addCases ?_ ?_ i <;> clear i · intro i rw [Subsingleton.elim i 0, Fin.append_left, Function.comp_apply, eq_comm] exact Fin.cons_zero _ _ · intro i rw [Fin.append_right, Function.comp_apply, Fin.cast_natAdd, eq_comm, Fin.addNat_one] exact Fin.cons_succ _ _ _ /-- `Fin.cons` is the same as appending a one-tuple to the left. -/ theorem cons_eq_append (x : α) (xs : Fin n → α) : cons x xs = append (cons x Fin.elim0) xs ∘ Fin.cast (Nat.add_comm ..) := by funext i; simp [append_left_eq_cons] @[simp] lemma append_cast_left {n m} (xs : Fin n → α) (ys : Fin m → α) (n' : ℕ) (h : n' = n) : Fin.append (xs ∘ Fin.cast h) ys = Fin.append xs ys ∘ (Fin.cast <\| by rw [h]) := by subst h; simp @[simp] lemma append_cast_right {n m} (xs : Fin n → α) (ys : Fin m → α) (m' : ℕ) (h : m' = m) : Fin.append xs (ys ∘ Fin.cast h) = Fin.append xs ys ∘ (Fin.cast <\| by rw [h]) := by subst h; simp lemma append_rev {m n} (xs : Fin m → α) (ys : Fin n → α) (i : Fin (m + n)) : append xs ys (rev i) = append (ys ∘ rev) (xs ∘ rev) (i.cast (Nat.add_comm ..)) := by rcases rev_surjective i with ⟨i, rfl⟩ rw [rev_rev] induction i using Fin.addCases · simp [rev_castAdd] · simp [cast_rev, rev_addNat] lemma append_comp_rev {m n} (xs : Fin m → α) (ys : Fin n → α) : append xs ys ∘ rev = append (ys ∘ rev) (xs ∘ rev) ∘ Fin.cast (Nat.add_comm ..) := funext <\| append_rev xs ys theorem append_castAdd_natAdd {f : Fin (m + n) → α} : append (fun i ↦ f (castAdd n i)) (fun i ↦ f (natAdd m i)) = f := by unfold append addCases simp end Append section Repeat variable {α : Sort} /-- Repeat `a` `m` times. For example `Fin.repeat 2 ![0, 3, 7] = ![0, 3, 7, 0, 3, 7]`. -/ def «repeat» (m : ℕ) (a : Fin n → α) : Fin (m * n) → α \| i => a i.modNat @[simp] theorem repeat_apply (a : Fin n → α) (i : Fin (m * n)) : Fin.repeat m a i = a i.modNat := rfl @[simp] theorem repeat_zero (a : Fin n → α) : Fin.repeat 0 a = Fin.elim0 ∘ Fin.cast (Nat.zero_mul _) := funext fun x => (x.cast (Nat.zero_mul _)).elim0 @[simp] theorem repeat_one (a : Fin n → α) : Fin.repeat 1 a = a ∘ Fin.cast (Nat.one_mul _) := by generalize_proofs h apply funext rw [(Fin.rightInverse_cast h.symm).surjective.forall] intro i simp [modNat, Nat.mod_eq_of_lt i.is_lt] theorem repeat_succ (a : Fin n → α) (m : ℕ) : Fin.repeat m.succ a = append a (Fin.repeat m a) ∘ Fin.cast ((Nat.succ_mul _ _).trans (Nat.add_comm ..)) := by generalize_proofs h apply funext rw [(Fin.rightInverse_cast h.symm).surjective.forall] refine Fin.addCases (fun l => ?_) fun r => ?_ · simp [modNat, Nat.mod_eq_of_lt l.is_lt] · simp [modNat] @[simp] theorem repeat_add (a : Fin n → α) (m₁ m₂ : ℕ) : Fin.repeat (m₁ + m₂) a = append (Fin.repeat m₁ a) (Fin.repeat m₂ a) ∘ Fin.cast (Nat.add_mul ..) := by generalize_proofs h apply funext rw [(Fin.rightInverse_cast h.symm).surjective.forall] refine Fin.addCases (fun l => ?_) fun r => ?_ · simp [modNat, Nat.mod_eq_of_lt l.is_lt] · simp [modNat, Nat.add_mod] theorem repeat_rev (a : Fin n → α) (k : Fin (m * n)) : Fin.repeat m a k.rev = Fin.repeat m (a ∘ Fin.rev) k := congr_arg a k.modNat_rev theorem repeat_comp_rev (a : Fin n → α) : Fin.repeat m a ∘ Fin.rev = Fin.repeat m (a ∘ Fin.rev) := funext <\| repeat_rev a end Repeat end Tuple section TupleRight /-! In the previous section, we have discussed inserting or removing elements on the left of a tuple. In this section, we do the same on the right. A difference is that `Fin (n+1)` is constructed inductively from `Fin n` starting from the left, not from the right. This implies that Lean needs more help to realize that elements belong to the right types, i.e., we need to insert casts at several places. -/ variable {α : Fin (n + 1) → Sort} (x : α (last n)) (q : ∀ i, α i) (p : ∀ i : Fin n, α i.castSucc) (i : Fin n) (y : α i.castSucc) (z : α (last n)) /-- The beginning of an `n+1` tuple, i.e., its first `n` entries -/ def init (q : ∀ i, α i) (i : Fin n) : α i.castSucc := q i.castSucc theorem init_def {q : ∀ i, α i} : (init fun k : Fin (n + 1) ↦ q k) = fun k : Fin n ↦ q k.castSucc := rfl /-- Adding an element at the end of an `n`-tuple, to get an `n+1`-tuple. The name `snoc` comes from `cons` (i.e., adding an element to the left of a tuple) read in reverse order. -/ def snoc (p : ∀ i : Fin n, α i.castSucc) (x : α (last n)) (i : Fin (n + 1)) : α i := if h : i.val < n then _root_.cast (by rw [Fin.castSucc_castLT i h]) (p (castLT i h)) else _root_.cast (by rw [eq_last_of_not_lt h]) x @[simp] theorem init_snoc : init (snoc p x) = p := by ext i simp only [init, snoc, coe_castSucc, is_lt, cast_eq, dite_true] convert cast_eq rfl (p i) @[simp] theorem snoc_castSucc : snoc p x i.castSucc = p i := by simp only [snoc, coe_castSucc, is_lt, cast_eq, dite_true] convert cast_eq rfl (p i) @[simp] theorem snoc_comp_castSucc {α : Sort} {a : α} {f : Fin n → α} : (snoc f a : Fin (n + 1) → α) ∘ castSucc = f := funext fun i ↦ by rw [Function.comp_apply, snoc_castSucc] @[simp] theorem snoc_last : snoc p x (last n) = x := by simp [snoc] lemma snoc_zero {α : Sort} (p : Fin 0 → α) (x : α) : Fin.snoc p x = fun _ ↦ x := by ext y have : Subsingleton (Fin (0 + 1)) := Fin.subsingleton_one simp only [Subsingleton.elim y (Fin.last 0), snoc_last] @[simp] theorem snoc_comp_nat_add {n m : ℕ} {α : Sort} (f : Fin (m + n) → α) (a : α) : (snoc f a : Fin _ → α) ∘ (natAdd m : Fin (n + 1) → Fin (m + n + 1)) = snoc (f ∘ natAdd m) a := by ext i refine Fin.lastCases ?_ (fun i ↦ ?_) i · simp only [Function.comp_apply] rw [snoc_last, natAdd_last, snoc_last] · simp only [comp_apply, snoc_castSucc] rw [natAdd_castSucc, snoc_castSucc] @[simp] theorem snoc_cast_add {α : Fin (n + m + 1) → Sort} (f : ∀ i : Fin (n + m), α i.castSucc) (a : α (last (n + m))) (i : Fin n) : (snoc f a) (castAdd (m + 1) i) = f (castAdd m i) := dif_pos _ @[simp] theorem snoc_comp_cast_add {n m : ℕ} {α : Sort} (f : Fin (n + m) → α) (a : α) : (snoc f a : Fin _ → α) ∘ castAdd (m + 1) = f ∘ castAdd m := funext (snoc_cast_add _ _) /-- Updating a tuple and adding an element at the end commute. -/ @[simp] theorem snoc_update : snoc (update p i y) x = update (snoc p x) i.castSucc y := by ext j cases j using lastCases with \| cast j => rcases eq_or_ne j i with rfl \| hne <;> simp [] \| last => simp [Ne.symm] /-- Adding an element at the beginning of a tuple and then updating it amounts to adding it directly. -/ theorem update_snoc_last : update (snoc p x) (last n) z = snoc p z := by ext j cases j using lastCases <;> simp /-- As a binary function, `Fin.snoc` is injective. -/ theorem snoc_injective2 : Function.Injective2 (@snoc n α) := fun x y xₙ yₙ h ↦ ⟨funext fun i ↦ by simpa using congr_fun h (castSucc i), by simpa using congr_fun h (last n)⟩ @[simp] theorem snoc_inj {x y : ∀ i : Fin n, α i.castSucc} {xₙ yₙ : α (last n)} : snoc x xₙ = snoc y yₙ ↔ x = y ∧ xₙ = yₙ := snoc_injective2.eq_iff theorem snoc_right_injective (x : ∀ i : Fin n, α i.castSucc) : Function.Injective (snoc x) := snoc_injective2.right _ theorem snoc_left_injective (xₙ : α (last n)) : Function.Injective (snoc · xₙ) := snoc_injective2.left _ /-- Concatenating the first element of a tuple with its tail gives back the original tuple -/ @[simp] theorem snoc_init_self : snoc (init q) (q (last n)) = q := by ext j by_cases h : j.val < n · simp only [init, snoc, h, cast_eq, dite_true, castSucc_castLT] · rw [eq_last_of_not_lt h] simp /-- Updating the last element of a tuple does not change the beginning. -/ @[simp] theorem init_update_last : init (update q (last n) z) = init q := by ext j simp [init, Fin.ne_of_lt] /-- Updating an element and taking the beginning commute. -/ @[simp] theorem init_update_castSucc : init (update q i.castSucc y) = update (init q) i y := by ext j by_cases h : j = i · rw [h] simp [init] · simp [init, h, castSucc_inj] /-- `tail` and `init` commute. We state this lemma in a non-dependent setting, as otherwise it would involve a cast to convince Lean that the two types are equal, making it harder to use. -/ theorem tail_init_eq_init_tail {β : Sort} (q : Fin (n + 2) → β) : tail (init q) = init (tail q) := by ext i simp [tail, init, castSucc_fin_succ] /-- `cons` and `snoc` commute. We state this lemma in a non-dependent setting, as otherwise it would involve a cast to convince Lean that the two types are equal, making it harder to use. -/ theorem cons_snoc_eq_snoc_cons {β : Sort} (a : β) (q : Fin n → β) (b : β) : @cons n.succ (fun _ ↦ β) a (snoc q b) = snoc (cons a q) b := by ext i by_cases h : i = 0 · simp [h, snoc, castLT] set j := pred i h with ji have : i = j.succ := by rw [ji, succ_pred] rw [this, cons_succ] by_cases h' : j.val < n · set k := castLT j h' with jk have : j = castSucc k := by rw [jk, castSucc_castLT] rw [this, ← castSucc_fin_succ, snoc] simp [pred, snoc, cons] rw [eq_last_of_not_lt h', succ_last] simp theorem comp_snoc {α : Sort} {β : Sort} (g : α → β) (q : Fin n → α) (y : α) : g ∘ snoc q y = snoc (g ∘ q) (g y) := by ext j by_cases h : j.val < n · simp [h, snoc, castSucc_castLT] · rw [eq_last_of_not_lt h] simp /-- Appending a one-tuple to the right is the same as `Fin.snoc`. -/ theorem append_right_eq_snoc {α : Sort} {n : ℕ} (x : Fin n → α) (x₀ : Fin 1 → α) : Fin.append x x₀ = Fin.snoc x (x₀ 0) := by ext i refine Fin.addCases ?_ ?_ i <;> clear i · intro i rw [Fin.append_left] exact (@snoc_castSucc _ (fun _ => α) _ _ i).symm · intro i rw [Subsingleton.elim i 0, Fin.append_right] exact (@snoc_last _ (fun _ => α) _ _).symm /-- `Fin.snoc` is the same as appending a one-tuple -/ theorem snoc_eq_append {α : Sort} (xs : Fin n → α) (x : α) : snoc xs x = append xs (cons x Fin.elim0) := (append_right_eq_snoc xs (cons x Fin.elim0)).symm theorem append_left_snoc {n m} {α : Sort} (xs : Fin n → α) (x : α) (ys : Fin m → α) : Fin.append (Fin.snoc xs x) ys = Fin.append xs (Fin.cons x ys) ∘ Fin.cast (Nat.succ_add_eq_add_succ ..) := by rw [snoc_eq_append, append_assoc, append_left_eq_cons, append_cast_right]; rfl theorem append_right_cons {n m} {α : Sort} (xs : Fin n → α) (y : α) (ys : Fin m → α) : Fin.append xs (Fin.cons y ys) = Fin.append (Fin.snoc xs y) ys ∘ Fin.cast (Nat.succ_add_eq_add_succ ..).symm := by rw [append_left_snoc]; rfl theorem append_cons {α : Sort} (a : α) (as : Fin n → α) (bs : Fin m → α) : Fin.append (cons a as) bs = cons a (Fin.append as bs) ∘ (Fin.cast <\| Nat.add_right_comm n 1 m) := by funext i rcases i with ⟨i, -⟩ simp only [append, addCases, cons, castLT, cast, comp_apply] rcases i with - \| i · simp · split_ifs with h · have : i < n := Nat.lt_of_succ_lt_succ h simp [addCases, this] · have : ¬i < n := Nat.not_le.mpr <\| Nat.lt_succ.mp <\| Nat.not_le.mp h simp [addCases, this] theorem append_snoc {α : Sort} (as : Fin n → α) (bs : Fin m → α) (b : α) : Fin.append as (snoc bs b) = snoc (Fin.append as bs) b := by funext i rcases i with ⟨i, isLt⟩ simp only [append, addCases, castLT, cast_mk, subNat_mk, natAdd_mk, cast, snoc.eq_1, cast_eq, eq_rec_constant, Nat.add_eq, Nat.add_zero, castLT_mk] split_ifs with lt_n lt_add sub_lt nlt_add lt_add <;> (try rfl) · have := Nat.lt_add_right m lt_n contradiction · obtain rfl := Nat.eq_of_le_of_lt_succ (Nat.not_lt.mp nlt_add) isLt simp [Nat.add_comm n m] at sub_lt · have := Nat.sub_lt_left_of_lt_add (Nat.not_lt.mp lt_n) lt_add contradiction theorem comp_init {α : Sort} {β : Sort} (g : α → β) (q : Fin n.succ → α) : g ∘ init q = init (g ∘ q) := by ext j simp [init] /-- Equivalence between tuples of length `n + 1` and pairs of an element and a tuple of length `n` given by separating out the last element of the tuple. This is `Fin.snoc` as an `Equiv`. -/ @[simps] def snocEquiv (α : Fin (n + 1) → Type) : α (last n) × (∀ i, α (castSucc i)) ≃ ∀ i, α i where toFun f _ := Fin.snoc f.2 f.1 _ invFun f := ⟨f _, Fin.init f⟩ left_inv f := by simp right_inv f := by simp /-- Recurse on an `n+1`-tuple by splitting it its initial `n`-tuple and its last element. -/ @[elab_as_elim, inline] def snocCases {P : (∀ i : Fin n.succ, α i) → Sort} (h : ∀ xs x, P (Fin.snoc xs x)) (x : ∀ i : Fin n.succ, α i) : P x := _root_.cast (by rw [Fin.snoc_init_self]) <\| h (Fin.init x) (x <\| Fin.last _) @[simp] lemma snocCases_snoc {P : (∀ i : Fin (n+1), α i) → Sort} (h : ∀ x x₀, P (Fin.snoc x x₀)) (x : ∀ i : Fin n, (Fin.init α) i) (x₀ : α (Fin.last _)) : snocCases h (Fin.snoc x x₀) = h x x₀ := by rw [snocCases, cast_eq_iff_heq, Fin.init_snoc, Fin.snoc_last] /-- Recurse on a tuple by splitting into `Fin.elim0` and `Fin.snoc`. -/ @[elab_as_elim] def snocInduction {α : Sort} {P : ∀ {n : ℕ}, (Fin n → α) → Sort} (h0 : P Fin.elim0) (h : ∀ {n} (x : Fin n → α) (x₀), P x → P (Fin.snoc x x₀)) : ∀ {n : ℕ} (x : Fin n → α), P x \| 0, x => by convert h0 \| _ + 1, x => snocCases (fun _ _ ↦ h _ _ <\| snocInduction h0 h _) x end TupleRight section InsertNth variable {α : Fin (n + 1) → Sort} {β : Sort} /- Porting note: Lean told me `(fun x x_1 ↦ α x)` was an invalid motive, but disabling automatic insertion and specifying that motive seems to work. -/ /-- Define a function on `Fin (n + 1)` from a value on `i : Fin (n + 1)` and values on each `Fin.succAbove i j`, `j : Fin n`. This version is elaborated as eliminator and works for propositions, see also `Fin.insertNth` for a version without an `@[elab_as_elim]` attribute. -/ @[elab_as_elim] def succAboveCases {α : Fin (n + 1) → Sort u} (i : Fin (n + 1)) (x : α i) (p : ∀ j : Fin n, α (i.succAbove j)) (j : Fin (n + 1)) : α j := if hj : j = i then Eq.rec x hj.symm else if hlt : j < i then @Eq.recOn _ _ (fun x _ ↦ α x) _ (succAbove_castPred_of_lt _ _ hlt) (p _) else @Eq.recOn _ _ (fun x _ ↦ α x) _ (succAbove_pred_of_lt _ _ <\| (Fin.lt_or_lt_of_ne hj).resolve_left hlt) (p _) -- This is a duplicate of `Fin.exists_fin_succ` in Core. We should upstream the name change. alias forall_iff_succ := forall_fin_succ -- This is a duplicate of `Fin.exists_fin_succ` in Core. We should upstream the name change. alias exists_iff_succ := exists_fin_succ lemma forall_iff_castSucc {P : Fin (n + 1) → Prop} : (∀ i, P i) ↔ P (last n) ∧ ∀ i : Fin n, P i.castSucc := ⟨fun h ↦ ⟨h _, fun _ ↦ h _⟩, fun h ↦ lastCases h.1 h.2⟩ lemma exists_iff_castSucc {P : Fin (n + 1) → Prop} : (∃ i, P i) ↔ P (last n) ∨ ∃ i : Fin n, P i.castSucc where mp := by rintro ⟨i, hi⟩ induction' i using lastCases · exact .inl hi · exact .inr ⟨_, hi⟩ mpr := by rintro (h \| ⟨i, hi⟩) <;> exact ⟨_, ‹_›⟩ theorem forall_iff_succAbove {P : Fin (n + 1) → Prop} (p : Fin (n + 1)) : (∀ i, P i) ↔ P p ∧ ∀ i, P (p.succAbove i) := ⟨fun h ↦ ⟨h _, fun _ ↦ h _⟩, fun h ↦ succAboveCases p h.1 h.2⟩ lemma exists_iff_succAbove {P : Fin (n + 1) → Prop} (p : Fin (n + 1)) : (∃ i, P i) ↔ P p ∨ ∃ i, P (p.succAbove i) where mp := by rintro ⟨i, hi⟩ induction' i using p.succAboveCases · exact .inl hi · exact .inr ⟨_, hi⟩ mpr := by rintro (h \| ⟨i, hi⟩) <;> exact ⟨_, ‹_›⟩ /-- Analogue of `Fin.eq_zero_or_eq_succ` for `succAbove`. -/ theorem eq_self_or_eq_succAbove (p i : Fin (n + 1)) : i = p ∨ ∃ j, i = p.succAbove j := succAboveCases p (.inl rfl) (fun j => .inr ⟨j, rfl⟩) i /-- Remove the `p`-th entry of a tuple. -/ def removeNth (p : Fin (n + 1)) (f : ∀ i, α i) : ∀ i, α (p.succAbove i) := fun i ↦ f (p.succAbove i) /-- Insert an element into a tuple at a given position. For `i = 0` see `Fin.cons`, for `i = Fin.last n` see `Fin.snoc`. See also `Fin.succAboveCases` for a version elaborated as an eliminator. -/ def insertNth (i : Fin (n + 1)) (x : α i) (p : ∀ j : Fin n, α (i.succAbove j)) (j : Fin (n + 1)) : α j := succAboveCases i x p j @[simp] theorem insertNth_apply_same (i : Fin (n + 1)) (x : α i) (p : ∀ j, α (i.succAbove j)) : insertNth i x p i = x := by simp [insertNth, succAboveCases] @[simp] theorem insertNth_apply_succAbove (i : Fin (n + 1)) (x : α i) (p : ∀ j, α (i.succAbove j)) (j : Fin n) : insertNth i x p (i.succAbove j) = p j := by simp only [insertNth, succAboveCases, dif_neg (succAbove_ne _ _), succAbove_lt_iff_castSucc_lt] split_ifs with hlt · generalize_proofs H₁ H₂; revert H₂ generalize hk : castPred ((succAbove i) j) H₁ = k rw [castPred_succAbove _ _ hlt] at hk; cases hk intro; rfl · generalize_proofs H₀ H₁ H₂; revert H₂ generalize hk : pred (succAbove i j) H₁ = k rw [pred_succAbove _ _ (Fin.not_lt.1 hlt)] at hk; cases hk intro; rfl @[simp] theorem succAbove_cases_eq_insertNth : @succAboveCases = @insertNth := rfl @[simp] lemma removeNth_insertNth (p : Fin (n + 1)) (a : α p) (f : ∀ i, α (succAbove p i)) : removeNth p (insertNth p a f) = f := by ext; unfold removeNth; simp @[simp] lemma removeNth_zero (f : ∀ i, α i) : removeNth 0 f = tail f := by ext; simp [tail, removeNth] @[simp] lemma removeNth_last {α : Type*} (f : Fin (n + 1) → α) : removeNth (last n) f = init f := by ext; simp [init, removeNth] @[simp] theorem insertNth_comp_succAbove (i : Fin (n + 1)) (x : β) (p : Fin n → β) : insertNth i x p ∘ i.succAbove = p := funext (insertNth_apply_succAbove i _ _) theorem insertNth_eq_iff {p : Fin (n + 1)} {a : α p} {f : ∀ i, α (p.succAbove i)} {g : ∀ j, α j} : insertNth p a f = g ↔ a = g p ∧ f = removeNth p g := by simp [funext_iff, forall_iff_succAbove p, removeNth] theorem eq_insertNth_iff {p : Fin (n + 1)} {a : α p} {f : ∀ i, α (p.succAbove i)} {g : ∀ j, α j} : g = insertNth p a f ↔ g p = a ∧ removeNth p g = f := by simpa [eq_comm] using insertNth_eq_iff /-- As a binary function, `Fin.insertNth` is injective. -/ theorem insertNth_injective2 {p : Fin (n + 1)} : Function.Injective2 (@insertNth n α p) := fun xₚ yₚ x y h ↦ ⟨by simpa using congr_fun h p, funext fun i ↦ by simpa using congr_fun h (succAbove p i)⟩ @[simp] theorem insertNth_inj {p : Fin (n + 1)} {x y : ∀ i, α (succAbove p i)} {xₚ yₚ : α p} : insertNth p xₚ x = insertNth p yₚ y ↔ xₚ = yₚ ∧ x = y := insertNth_injective2.eq_iff	theorem insertNth_left_injective {p : Fin (n + 1)} (x : ∀ i, α (succAbove p i)) : Function.Injective (insertNth p · x) := insertNth_injective2.left _	Mathlib/Data/Fin/Tuple/Basic.lean	845	847
/- Copyright (c) 2018 Mario Carneiro. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro -/ import Mathlib.Algebra.Order.Ring.Nat import Mathlib.Logic.Encodable.Pi import Mathlib.Logic.Function.Iterate /-! # The primitive recursive functions The primitive recursive functions are the least collection of functions `ℕ → ℕ` which are closed under projections (using the `pair` pairing function), composition, zero, successor, and primitive recursion (i.e. `Nat.rec` where the motive is `C n := ℕ`). We can extend this definition to a large class of basic types by using canonical encodings of types as natural numbers (Gödel numbering), which we implement through the type class `Encodable`. (More precisely, we need that the composition of encode with decode yields a primitive recursive function, so we have the `Primcodable` type class for this.) In the above, the pairing function is primitive recursive by definition. This deviates from the textbook definition of primitive recursive functions, which instead work with `n`-ary functions. We formalize the textbook definition in `Nat.Primrec'`. `Nat.Primrec'.prim_iff` then proves it is equivalent to our chosen formulation. For more discussionn of this and other design choices in this formalization, see [carneiro2019]. ## Main definitions - `Nat.Primrec f`: `f` is primitive recursive, for functions `f : ℕ → ℕ` - `Primrec f`: `f` is primitive recursive, for functions between `Primcodable` types - `Primcodable α`: well-behaved encoding of `α` into `ℕ`, i.e. one such that roundtripping through the encoding functions adds no computational power ## References * [Mario Carneiro, Formalizing computability theory via partial recursive functions][carneiro2019] -/ open List (Vector) open Denumerable Encodable Function namespace Nat /-- Calls the given function on a pair of entries `n`, encoded via the pairing function. -/ @[simp, reducible] def unpaired {α} (f : ℕ → ℕ → α) (n : ℕ) : α := f n.unpair.1 n.unpair.2 /-- The primitive recursive functions `ℕ → ℕ`. -/ protected inductive Primrec : (ℕ → ℕ) → Prop \| zero : Nat.Primrec fun _ => 0 \| protected succ : Nat.Primrec succ \| left : Nat.Primrec fun n => n.unpair.1 \| right : Nat.Primrec fun n => n.unpair.2 \| pair {f g} : Nat.Primrec f → Nat.Primrec g → Nat.Primrec fun n => pair (f n) (g n) \| comp {f g} : Nat.Primrec f → Nat.Primrec g → Nat.Primrec fun n => f (g n) \| prec {f g} : Nat.Primrec f → Nat.Primrec g → Nat.Primrec (unpaired fun z n => n.rec (f z) fun y IH => g <\| pair z <\| pair y IH) namespace Primrec theorem of_eq {f g : ℕ → ℕ} (hf : Nat.Primrec f) (H : ∀ n, f n = g n) : Nat.Primrec g := (funext H : f = g) ▸ hf theorem const : ∀ n : ℕ, Nat.Primrec fun _ => n \| 0 => zero \| n + 1 => Primrec.succ.comp (const n) protected theorem id : Nat.Primrec id := (left.pair right).of_eq fun n => by simp theorem prec1 {f} (m : ℕ) (hf : Nat.Primrec f) : Nat.Primrec fun n => n.rec m fun y IH => f <\| Nat.pair y IH := ((prec (const m) (hf.comp right)).comp (zero.pair Primrec.id)).of_eq fun n => by simp theorem casesOn1 {f} (m : ℕ) (hf : Nat.Primrec f) : Nat.Primrec (Nat.casesOn · m f) := (prec1 m (hf.comp left)).of_eq <\| by simp -- Porting note: `Nat.Primrec.casesOn` is already declared as a recursor. theorem casesOn' {f g} (hf : Nat.Primrec f) (hg : Nat.Primrec g) : Nat.Primrec (unpaired fun z n => n.casesOn (f z) fun y => g <\| Nat.pair z y) := (prec hf (hg.comp (pair left (left.comp right)))).of_eq fun n => by simp protected theorem swap : Nat.Primrec (unpaired (swap Nat.pair)) := (pair right left).of_eq fun n => by simp theorem swap' {f} (hf : Nat.Primrec (unpaired f)) : Nat.Primrec (unpaired (swap f)) := (hf.comp .swap).of_eq fun n => by simp theorem pred : Nat.Primrec pred := (casesOn1 0 Primrec.id).of_eq fun n => by cases n <;> simp [] theorem add : Nat.Primrec (unpaired (· + ·)) := (prec .id ((Primrec.succ.comp right).comp right)).of_eq fun p => by simp; induction p.unpair.2 <;> simp [, Nat.add_assoc] theorem sub : Nat.Primrec (unpaired (· - ·)) := (prec .id ((pred.comp right).comp right)).of_eq fun p => by simp; induction p.unpair.2 <;> simp [, Nat.sub_add_eq] theorem mul : Nat.Primrec (unpaired (· ·)) := (prec zero (add.comp (pair left (right.comp right)))).of_eq fun p => by simp; induction p.unpair.2 <;> simp [, mul_succ, add_comm _ (unpair p).fst] theorem pow : Nat.Primrec (unpaired (· ^ ·)) := (prec (const 1) (mul.comp (pair (right.comp right) left))).of_eq fun p => by simp; induction p.unpair.2 <;> simp [, Nat.pow_succ] end Primrec end Nat /-- A `Primcodable` type is, essentially, an `Encodable` type for which the encode/decode functions are primitive recursive. However, such a definition is circular. Instead, we ask that the composition of `decode : ℕ → Option α` with `encode : Option α → ℕ` is primitive recursive. Said composition is the identity function, restricted to the image of `encode`. Thus, in a way, the added requirement ensures that no predicates can be smuggled in through a cunning choice of the subset of `ℕ` into which the type is encoded. -/ class Primcodable (α : Type) extends Encodable α where -- Porting note: was `prim [] `. -- This means that `prim` does not take the type explicitly in Lean 4 prim : Nat.Primrec fun n => Encodable.encode (decode n) namespace Primcodable open Nat.Primrec instance (priority := 10) ofDenumerable (α) [Denumerable α] : Primcodable α := ⟨Nat.Primrec.succ.of_eq <\| by simp⟩ /-- Builds a `Primcodable` instance from an equivalence to a `Primcodable` type. -/ def ofEquiv (α) {β} [Primcodable α] (e : β ≃ α) : Primcodable β := { __ := Encodable.ofEquiv α e prim := (@Primcodable.prim α _).of_eq fun n => by rw [decode_ofEquiv] cases (@decode α _ n) <;> simp [encode_ofEquiv] } instance empty : Primcodable Empty := ⟨zero⟩ instance unit : Primcodable PUnit := ⟨(casesOn1 1 zero).of_eq fun n => by cases n <;> simp⟩ instance option {α : Type} [h : Primcodable α] : Primcodable (Option α) := ⟨(casesOn1 1 ((casesOn1 0 (.comp .succ .succ)).comp (@Primcodable.prim α _))).of_eq fun n => by cases n with \| zero => rfl \| succ n => rw [decode_option_succ] cases H : @decode α _ n <;> simp [H]⟩ instance bool : Primcodable Bool := ⟨(casesOn1 1 (casesOn1 2 zero)).of_eq fun n => match n with \| 0 => rfl \| 1 => rfl \| (n + 2) => by rw [decode_ge_two] <;> simp⟩ end Primcodable /-- `Primrec f` means `f` is primitive recursive (after encoding its input and output as natural numbers). -/ def Primrec {α β} [Primcodable α] [Primcodable β] (f : α → β) : Prop := Nat.Primrec fun n => encode ((@decode α _ n).map f) namespace Primrec variable {α : Type} {β : Type} {σ : Type} variable [Primcodable α] [Primcodable β] [Primcodable σ] open Nat.Primrec protected theorem encode : Primrec (@encode α _) := (@Primcodable.prim α _).of_eq fun n => by cases @decode α _ n <;> rfl protected theorem decode : Primrec (@decode α _) := Nat.Primrec.succ.comp (@Primcodable.prim α _) theorem dom_denumerable {α β} [Denumerable α] [Primcodable β] {f : α → β} : Primrec f ↔ Nat.Primrec fun n => encode (f (ofNat α n)) := ⟨fun h => (pred.comp h).of_eq fun n => by simp, fun h => (Nat.Primrec.succ.comp h).of_eq fun n => by simp⟩ theorem nat_iff {f : ℕ → ℕ} : Primrec f ↔ Nat.Primrec f := dom_denumerable theorem encdec : Primrec fun n => encode (@decode α _ n) := nat_iff.2 Primcodable.prim theorem option_some : Primrec (@some α) := ((casesOn1 0 (Nat.Primrec.succ.comp .succ)).comp (@Primcodable.prim α _)).of_eq fun n => by cases @decode α _ n <;> simp theorem of_eq {f g : α → σ} (hf : Primrec f) (H : ∀ n, f n = g n) : Primrec g := (funext H : f = g) ▸ hf theorem const (x : σ) : Primrec fun _ : α => x := ((casesOn1 0 (.const (encode x).succ)).comp (@Primcodable.prim α _)).of_eq fun n => by cases @decode α _ n <;> rfl protected theorem id : Primrec (@id α) := (@Primcodable.prim α).of_eq <\| by simp theorem comp {f : β → σ} {g : α → β} (hf : Primrec f) (hg : Primrec g) : Primrec fun a => f (g a) := ((casesOn1 0 (.comp hf (pred.comp hg))).comp (@Primcodable.prim α _)).of_eq fun n => by cases @decode α _ n <;> simp [encodek] theorem succ : Primrec Nat.succ := nat_iff.2 Nat.Primrec.succ theorem pred : Primrec Nat.pred := nat_iff.2 Nat.Primrec.pred theorem encode_iff {f : α → σ} : (Primrec fun a => encode (f a)) ↔ Primrec f := ⟨fun h => Nat.Primrec.of_eq h fun n => by cases @decode α _ n <;> rfl, Primrec.encode.comp⟩ theorem ofNat_iff {α β} [Denumerable α] [Primcodable β] {f : α → β} : Primrec f ↔ Primrec fun n => f (ofNat α n) := dom_denumerable.trans <\| nat_iff.symm.trans encode_iff protected theorem ofNat (α) [Denumerable α] : Primrec (ofNat α) := ofNat_iff.1 Primrec.id theorem option_some_iff {f : α → σ} : (Primrec fun a => some (f a)) ↔ Primrec f := ⟨fun h => encode_iff.1 <\| pred.comp <\| encode_iff.2 h, option_some.comp⟩ theorem of_equiv {β} {e : β ≃ α} : haveI := Primcodable.ofEquiv α e Primrec e := letI : Primcodable β := Primcodable.ofEquiv α e encode_iff.1 Primrec.encode theorem of_equiv_symm {β} {e : β ≃ α} : haveI := Primcodable.ofEquiv α e Primrec e.symm := letI := Primcodable.ofEquiv α e encode_iff.1 (show Primrec fun a => encode (e (e.symm a)) by simp [Primrec.encode]) theorem of_equiv_iff {β} (e : β ≃ α) {f : σ → β} : haveI := Primcodable.ofEquiv α e (Primrec fun a => e (f a)) ↔ Primrec f := letI := Primcodable.ofEquiv α e ⟨fun h => (of_equiv_symm.comp h).of_eq fun a => by simp, of_equiv.comp⟩ theorem of_equiv_symm_iff {β} (e : β ≃ α) {f : σ → α} : haveI := Primcodable.ofEquiv α e (Primrec fun a => e.symm (f a)) ↔ Primrec f := letI := Primcodable.ofEquiv α e ⟨fun h => (of_equiv.comp h).of_eq fun a => by simp, of_equiv_symm.comp⟩ end Primrec namespace Primcodable open Nat.Primrec instance prod {α β} [Primcodable α] [Primcodable β] : Primcodable (α × β) := ⟨((casesOn' zero ((casesOn' zero .succ).comp (pair right ((@Primcodable.prim β).comp left)))).comp (pair right ((@Primcodable.prim α).comp left))).of_eq fun n => by simp only [Nat.unpaired, Nat.unpair_pair, decode_prod_val] cases @decode α _ n.unpair.1; · simp cases @decode β _ n.unpair.2 <;> simp⟩ end Primcodable namespace Primrec variable {α : Type} [Primcodable α] open Nat.Primrec theorem fst {α β} [Primcodable α] [Primcodable β] : Primrec (@Prod.fst α β) := ((casesOn' zero ((casesOn' zero (Nat.Primrec.succ.comp left)).comp (pair right ((@Primcodable.prim β).comp left)))).comp (pair right ((@Primcodable.prim α).comp left))).of_eq fun n => by simp only [Nat.unpaired, Nat.unpair_pair, decode_prod_val] cases @decode α _ n.unpair.1 <;> simp cases @decode β _ n.unpair.2 <;> simp theorem snd {α β} [Primcodable α] [Primcodable β] : Primrec (@Prod.snd α β) := ((casesOn' zero ((casesOn' zero (Nat.Primrec.succ.comp right)).comp (pair right ((@Primcodable.prim β).comp left)))).comp (pair right ((@Primcodable.prim α).comp left))).of_eq fun n => by simp only [Nat.unpaired, Nat.unpair_pair, decode_prod_val] cases @decode α _ n.unpair.1 <;> simp cases @decode β _ n.unpair.2 <;> simp theorem pair {α β γ} [Primcodable α] [Primcodable β] [Primcodable γ] {f : α → β} {g : α → γ} (hf : Primrec f) (hg : Primrec g) : Primrec fun a => (f a, g a) := ((casesOn1 0 (Nat.Primrec.succ.comp <\| .pair (Nat.Primrec.pred.comp hf) (Nat.Primrec.pred.comp hg))).comp (@Primcodable.prim α _)).of_eq fun n => by cases @decode α _ n <;> simp [encodek] theorem unpair : Primrec Nat.unpair := (pair (nat_iff.2 .left) (nat_iff.2 .right)).of_eq fun n => by simp theorem list_getElem?₁ : ∀ l : List α, Primrec (l[·]? : ℕ → Option α) \| [] => dom_denumerable.2 zero \| a :: l => dom_denumerable.2 <\| (casesOn1 (encode a).succ <\| dom_denumerable.1 <\| list_getElem?₁ l).of_eq fun n => by cases n <;> simp @[deprecated (since := "2025-02-14")] alias list_get?₁ := list_getElem?₁ end Primrec /-- `Primrec₂ f` means `f` is a binary primitive recursive function. This is technically unnecessary since we can always curry all the arguments together, but there are enough natural two-arg functions that it is convenient to express this directly. -/ def Primrec₂ {α β σ} [Primcodable α] [Primcodable β] [Primcodable σ] (f : α → β → σ) := Primrec fun p : α × β => f p.1 p.2 /-- `PrimrecPred p` means `p : α → Prop` is a (decidable) primitive recursive predicate, which is to say that `decide ∘ p : α → Bool` is primitive recursive. -/ def PrimrecPred {α} [Primcodable α] (p : α → Prop) [DecidablePred p] := Primrec fun a => decide (p a) /-- `PrimrecRel p` means `p : α → β → Prop` is a (decidable) primitive recursive relation, which is to say that `decide ∘ p : α → β → Bool` is primitive recursive. -/ def PrimrecRel {α β} [Primcodable α] [Primcodable β] (s : α → β → Prop) [∀ a b, Decidable (s a b)] := Primrec₂ fun a b => decide (s a b) namespace Primrec₂ variable {α : Type} {β : Type} {σ : Type} variable [Primcodable α] [Primcodable β] [Primcodable σ] theorem mk {f : α → β → σ} (hf : Primrec fun p : α × β => f p.1 p.2) : Primrec₂ f := hf theorem of_eq {f g : α → β → σ} (hg : Primrec₂ f) (H : ∀ a b, f a b = g a b) : Primrec₂ g := (by funext a b; apply H : f = g) ▸ hg theorem const (x : σ) : Primrec₂ fun (_ : α) (_ : β) => x := Primrec.const _ protected theorem pair : Primrec₂ (@Prod.mk α β) := Primrec.pair .fst .snd theorem left : Primrec₂ fun (a : α) (_ : β) => a := .fst theorem right : Primrec₂ fun (_ : α) (b : β) => b := .snd theorem natPair : Primrec₂ Nat.pair := by simp [Primrec₂, Primrec]; constructor theorem unpaired {f : ℕ → ℕ → α} : Primrec (Nat.unpaired f) ↔ Primrec₂ f := ⟨fun h => by simpa using h.comp natPair, fun h => h.comp Primrec.unpair⟩ theorem unpaired' {f : ℕ → ℕ → ℕ} : Nat.Primrec (Nat.unpaired f) ↔ Primrec₂ f := Primrec.nat_iff.symm.trans unpaired theorem encode_iff {f : α → β → σ} : (Primrec₂ fun a b => encode (f a b)) ↔ Primrec₂ f := Primrec.encode_iff theorem option_some_iff {f : α → β → σ} : (Primrec₂ fun a b => some (f a b)) ↔ Primrec₂ f := Primrec.option_some_iff theorem ofNat_iff {α β σ} [Denumerable α] [Denumerable β] [Primcodable σ] {f : α → β → σ} : Primrec₂ f ↔ Primrec₂ fun m n : ℕ => f (ofNat α m) (ofNat β n) := (Primrec.ofNat_iff.trans <\| by simp).trans unpaired theorem uncurry {f : α → β → σ} : Primrec (Function.uncurry f) ↔ Primrec₂ f := by rw [show Function.uncurry f = fun p : α × β => f p.1 p.2 from funext fun ⟨a, b⟩ => rfl]; rfl theorem curry {f : α × β → σ} : Primrec₂ (Function.curry f) ↔ Primrec f := by rw [← uncurry, Function.uncurry_curry] end Primrec₂ section Comp variable {α : Type} {β : Type} {γ : Type} {δ : Type} {σ : Type} variable [Primcodable α] [Primcodable β] [Primcodable γ] [Primcodable δ] [Primcodable σ] theorem Primrec.comp₂ {f : γ → σ} {g : α → β → γ} (hf : Primrec f) (hg : Primrec₂ g) : Primrec₂ fun a b => f (g a b) := hf.comp hg theorem Primrec₂.comp {f : β → γ → σ} {g : α → β} {h : α → γ} (hf : Primrec₂ f) (hg : Primrec g) (hh : Primrec h) : Primrec fun a => f (g a) (h a) := Primrec.comp hf (hg.pair hh) theorem Primrec₂.comp₂ {f : γ → δ → σ} {g : α → β → γ} {h : α → β → δ} (hf : Primrec₂ f) (hg : Primrec₂ g) (hh : Primrec₂ h) : Primrec₂ fun a b => f (g a b) (h a b) := hf.comp hg hh theorem PrimrecPred.comp {p : β → Prop} [DecidablePred p] {f : α → β} : PrimrecPred p → Primrec f → PrimrecPred fun a => p (f a) := Primrec.comp theorem PrimrecRel.comp {R : β → γ → Prop} [∀ a b, Decidable (R a b)] {f : α → β} {g : α → γ} : PrimrecRel R → Primrec f → Primrec g → PrimrecPred fun a => R (f a) (g a) := Primrec₂.comp theorem PrimrecRel.comp₂ {R : γ → δ → Prop} [∀ a b, Decidable (R a b)] {f : α → β → γ} {g : α → β → δ} : PrimrecRel R → Primrec₂ f → Primrec₂ g → PrimrecRel fun a b => R (f a b) (g a b) := PrimrecRel.comp end Comp theorem PrimrecPred.of_eq {α} [Primcodable α] {p q : α → Prop} [DecidablePred p] [DecidablePred q] (hp : PrimrecPred p) (H : ∀ a, p a ↔ q a) : PrimrecPred q := Primrec.of_eq hp fun a => Bool.decide_congr (H a) theorem PrimrecRel.of_eq {α β} [Primcodable α] [Primcodable β] {r s : α → β → Prop} [∀ a b, Decidable (r a b)] [∀ a b, Decidable (s a b)] (hr : PrimrecRel r) (H : ∀ a b, r a b ↔ s a b) : PrimrecRel s := Primrec₂.of_eq hr fun a b => Bool.decide_congr (H a b) namespace Primrec₂ variable {α : Type} {β : Type} {σ : Type} variable [Primcodable α] [Primcodable β] [Primcodable σ] open Nat.Primrec theorem swap {f : α → β → σ} (h : Primrec₂ f) : Primrec₂ (swap f) := h.comp₂ Primrec₂.right Primrec₂.left theorem nat_iff {f : α → β → σ} : Primrec₂ f ↔ Nat.Primrec (.unpaired fun m n => encode <\| (@decode α _ m).bind fun a => (@decode β _ n).map (f a)) := by have : ∀ (a : Option α) (b : Option β), Option.map (fun p : α × β => f p.1 p.2) (Option.bind a fun a : α => Option.map (Prod.mk a) b) = Option.bind a fun a => Option.map (f a) b := fun a b => by cases a <;> cases b <;> rfl simp [Primrec₂, Primrec, this] theorem nat_iff' {f : α → β → σ} : Primrec₂ f ↔ Primrec₂ fun m n : ℕ => (@decode α _ m).bind fun a => Option.map (f a) (@decode β _ n) := nat_iff.trans <\| unpaired'.trans encode_iff end Primrec₂ namespace Primrec variable {α : Type} {β : Type} {σ : Type} variable [Primcodable α] [Primcodable β] [Primcodable σ] theorem to₂ {f : α × β → σ} (hf : Primrec f) : Primrec₂ fun a b => f (a, b) := hf.of_eq fun _ => rfl theorem nat_rec {f : α → β} {g : α → ℕ × β → β} (hf : Primrec f) (hg : Primrec₂ g) : Primrec₂ fun a (n : ℕ) => n.rec (motive := fun _ => β) (f a) fun n IH => g a (n, IH) := Primrec₂.nat_iff.2 <\| ((Nat.Primrec.casesOn' .zero <\| (Nat.Primrec.prec hf <\| .comp hg <\| Nat.Primrec.left.pair <\| (Nat.Primrec.left.comp .right).pair <\| Nat.Primrec.pred.comp <\| Nat.Primrec.right.comp .right).comp <\| Nat.Primrec.right.pair <\| Nat.Primrec.right.comp Nat.Primrec.left).comp <\| Nat.Primrec.id.pair <\| (@Primcodable.prim α).comp Nat.Primrec.left).of_eq fun n => by simp only [Nat.unpaired, id_eq, Nat.unpair_pair, decode_prod_val, decode_nat, Option.some_bind, Option.map_map, Option.map_some'] rcases @decode α _ n.unpair.1 with - \| a; · rfl simp only [Nat.pred_eq_sub_one, encode_some, Nat.succ_eq_add_one, encodek, Option.map_some', Option.some_bind, Option.map_map] induction' n.unpair.2 with m <;> simp [encodek] simp [, encodek] theorem nat_rec' {f : α → ℕ} {g : α → β} {h : α → ℕ × β → β} (hf : Primrec f) (hg : Primrec g) (hh : Primrec₂ h) : Primrec fun a => (f a).rec (motive := fun _ => β) (g a) fun n IH => h a (n, IH) := (nat_rec hg hh).comp .id hf theorem nat_rec₁ {f : ℕ → α → α} (a : α) (hf : Primrec₂ f) : Primrec (Nat.rec a f) := nat_rec' .id (const a) <\| comp₂ hf Primrec₂.right theorem nat_casesOn' {f : α → β} {g : α → ℕ → β} (hf : Primrec f) (hg : Primrec₂ g) : Primrec₂ fun a (n : ℕ) => (n.casesOn (f a) (g a) : β) := nat_rec hf <\| hg.comp₂ Primrec₂.left <\| comp₂ fst Primrec₂.right theorem nat_casesOn {f : α → ℕ} {g : α → β} {h : α → ℕ → β} (hf : Primrec f) (hg : Primrec g) (hh : Primrec₂ h) : Primrec fun a => ((f a).casesOn (g a) (h a) : β) := (nat_casesOn' hg hh).comp .id hf theorem nat_casesOn₁ {f : ℕ → α} (a : α) (hf : Primrec f) : Primrec (fun (n : ℕ) => (n.casesOn a f : α)) := nat_casesOn .id (const a) (comp₂ hf .right) theorem nat_iterate {f : α → ℕ} {g : α → β} {h : α → β → β} (hf : Primrec f) (hg : Primrec g) (hh : Primrec₂ h) : Primrec fun a => (h a)^[f a] (g a) := (nat_rec' hf hg (hh.comp₂ Primrec₂.left <\| snd.comp₂ Primrec₂.right)).of_eq fun a => by induction f a <;> simp [, -Function.iterate_succ, Function.iterate_succ'] theorem option_casesOn {o : α → Option β} {f : α → σ} {g : α → β → σ} (ho : Primrec o) (hf : Primrec f) (hg : Primrec₂ g) : @Primrec _ σ _ _ fun a => Option.casesOn (o a) (f a) (g a) := encode_iff.1 <\| (nat_casesOn (encode_iff.2 ho) (encode_iff.2 hf) <\| pred.comp₂ <\| Primrec₂.encode_iff.2 <\| (Primrec₂.nat_iff'.1 hg).comp₂ ((@Primrec.encode α _).comp fst).to₂ Primrec₂.right).of_eq fun a => by rcases o a with - \| b <;> simp [encodek] theorem option_bind {f : α → Option β} {g : α → β → Option σ} (hf : Primrec f) (hg : Primrec₂ g) : Primrec fun a => (f a).bind (g a) := (option_casesOn hf (const none) hg).of_eq fun a => by cases f a <;> rfl theorem option_bind₁ {f : α → Option σ} (hf : Primrec f) : Primrec fun o => Option.bind o f := option_bind .id (hf.comp snd).to₂ theorem option_map {f : α → Option β} {g : α → β → σ} (hf : Primrec f) (hg : Primrec₂ g) : Primrec fun a => (f a).map (g a) := (option_bind hf (option_some.comp₂ hg)).of_eq fun x => by cases f x <;> rfl theorem option_map₁ {f : α → σ} (hf : Primrec f) : Primrec (Option.map f) := option_map .id (hf.comp snd).to₂ theorem option_iget [Inhabited α] : Primrec (@Option.iget α _) := (option_casesOn .id (const <\| @default α _) .right).of_eq fun o => by cases o <;> rfl theorem option_isSome : Primrec (@Option.isSome α) := (option_casesOn .id (const false) (const true).to₂).of_eq fun o => by cases o <;> rfl theorem option_getD : Primrec₂ (@Option.getD α) := Primrec.of_eq (option_casesOn Primrec₂.left Primrec₂.right .right) fun ⟨o, a⟩ => by cases o <;> rfl theorem bind_decode_iff {f : α → β → Option σ} : (Primrec₂ fun a n => (@decode β _ n).bind (f a)) ↔ Primrec₂ f := ⟨fun h => by simpa [encodek] using h.comp fst ((@Primrec.encode β _).comp snd), fun h => option_bind (Primrec.decode.comp snd) <\| h.comp (fst.comp fst) snd⟩ theorem map_decode_iff {f : α → β → σ} : (Primrec₂ fun a n => (@decode β _ n).map (f a)) ↔ Primrec₂ f := by simp only [Option.map_eq_bind] exact bind_decode_iff.trans Primrec₂.option_some_iff theorem nat_add : Primrec₂ ((· + ·) : ℕ → ℕ → ℕ) := Primrec₂.unpaired'.1 Nat.Primrec.add theorem nat_sub : Primrec₂ ((· - ·) : ℕ → ℕ → ℕ) := Primrec₂.unpaired'.1 Nat.Primrec.sub theorem nat_mul : Primrec₂ ((· * ·) : ℕ → ℕ → ℕ) := Primrec₂.unpaired'.1 Nat.Primrec.mul theorem cond {c : α → Bool} {f : α → σ} {g : α → σ} (hc : Primrec c) (hf : Primrec f) (hg : Primrec g) : Primrec fun a => bif (c a) then (f a) else (g a) := (nat_casesOn (encode_iff.2 hc) hg (hf.comp fst).to₂).of_eq fun a => by cases c a <;> rfl theorem ite {c : α → Prop} [DecidablePred c] {f : α → σ} {g : α → σ} (hc : PrimrecPred c) (hf : Primrec f) (hg : Primrec g) : Primrec fun a => if c a then f a else g a := by simpa [Bool.cond_decide] using cond hc hf hg theorem nat_le : PrimrecRel ((· ≤ ·) : ℕ → ℕ → Prop) := (nat_casesOn nat_sub (const true) (const false).to₂).of_eq fun p => by dsimp [swap] rcases e : p.1 - p.2 with - \| n · simp [Nat.sub_eq_zero_iff_le.1 e] · simp [not_le.2 (Nat.lt_of_sub_eq_succ e)] theorem nat_min : Primrec₂ (@min ℕ _) := ite nat_le fst snd theorem nat_max : Primrec₂ (@max ℕ _) := ite (nat_le.comp fst snd) snd fst theorem dom_bool (f : Bool → α) : Primrec f := (cond .id (const (f true)) (const (f false))).of_eq fun b => by cases b <;> rfl theorem dom_bool₂ (f : Bool → Bool → α) : Primrec₂ f := (cond fst ((dom_bool (f true)).comp snd) ((dom_bool (f false)).comp snd)).of_eq fun ⟨a, b⟩ => by cases a <;> rfl protected theorem not : Primrec not := dom_bool _ protected theorem and : Primrec₂ and := dom_bool₂ _ protected theorem or : Primrec₂ or := dom_bool₂ _ theorem _root_.PrimrecPred.not {p : α → Prop} [DecidablePred p] (hp : PrimrecPred p) : PrimrecPred fun a => ¬p a := (Primrec.not.comp hp).of_eq fun n => by simp theorem _root_.PrimrecPred.and {p q : α → Prop} [DecidablePred p] [DecidablePred q] (hp : PrimrecPred p) (hq : PrimrecPred q) : PrimrecPred fun a => p a ∧ q a := (Primrec.and.comp hp hq).of_eq fun n => by simp theorem _root_.PrimrecPred.or {p q : α → Prop} [DecidablePred p] [DecidablePred q] (hp : PrimrecPred p) (hq : PrimrecPred q) : PrimrecPred fun a => p a ∨ q a := (Primrec.or.comp hp hq).of_eq fun n => by simp protected theorem beq [DecidableEq α] : Primrec₂ (@BEq.beq α _) := have : PrimrecRel fun a b : ℕ => a = b := (PrimrecPred.and nat_le nat_le.swap).of_eq fun a => by simp [le_antisymm_iff] (this.comp₂ (Primrec.encode.comp₂ Primrec₂.left) (Primrec.encode.comp₂ Primrec₂.right)).of_eq fun _ _ => encode_injective.eq_iff protected theorem eq [DecidableEq α] : PrimrecRel (@Eq α) := Primrec.beq theorem nat_lt : PrimrecRel ((· < ·) : ℕ → ℕ → Prop) := (nat_le.comp snd fst).not.of_eq fun p => by simp theorem option_guard {p : α → β → Prop} [∀ a b, Decidable (p a b)] (hp : PrimrecRel p) {f : α → β} (hf : Primrec f) : Primrec fun a => Option.guard (p a) (f a) := ite (hp.comp Primrec.id hf) (option_some_iff.2 hf) (const none) theorem option_orElse : Primrec₂ ((· <\|> ·) : Option α → Option α → Option α) := (option_casesOn fst snd (fst.comp fst).to₂).of_eq fun ⟨o₁, o₂⟩ => by cases o₁ <;> cases o₂ <;> rfl protected theorem decode₂ : Primrec (decode₂ α) := option_bind .decode <\| option_guard (Primrec.beq.comp₂ (by exact encode_iff.mpr snd) (by exact fst.comp fst)) snd theorem list_findIdx₁ {p : α → β → Bool} (hp : Primrec₂ p) : ∀ l : List β, Primrec fun a => l.findIdx (p a) \| [] => const 0 \| a :: l => (cond (hp.comp .id (const a)) (const 0) (succ.comp (list_findIdx₁ hp l))).of_eq fun n => by simp [List.findIdx_cons] theorem list_idxOf₁ [DecidableEq α] (l : List α) : Primrec fun a => l.idxOf a := list_findIdx₁ (.swap .beq) l @[deprecated (since := "2025-01-30")] alias list_indexOf₁ := list_idxOf₁ theorem dom_fintype [Finite α] (f : α → σ) : Primrec f := let ⟨l, _, m⟩ := Finite.exists_univ_list α option_some_iff.1 <\| by haveI := decidableEqOfEncodable α refine ((list_getElem?₁ (l.map f)).comp (list_idxOf₁ l)).of_eq fun a => ?_ rw [List.getElem?_map, List.getElem?_idxOf (m a), Option.map_some'] -- Porting note: These are new lemmas -- I added it because it actually simplified the proofs -- and because I couldn't understand the original proof /-- A function is `PrimrecBounded` if its size is bounded by a primitive recursive function -/ def PrimrecBounded (f : α → β) : Prop := ∃ g : α → ℕ, Primrec g ∧ ∀ x, encode (f x) ≤ g x theorem nat_findGreatest {f : α → ℕ} {p : α → ℕ → Prop} [∀ x n, Decidable (p x n)] (hf : Primrec f) (hp : PrimrecRel p) : Primrec fun x => (f x).findGreatest (p x) := (nat_rec' (h := fun x nih => if p x (nih.1 + 1) then nih.1 + 1 else nih.2) hf (const 0) (ite (hp.comp fst (snd \|> fst.comp \|> succ.comp)) (snd \|> fst.comp \|> succ.comp) (snd.comp snd))).of_eq fun x => by induction f x <;> simp [Nat.findGreatest, ] /-- To show a function `f : α → ℕ` is primitive recursive, it is enough to show that the function is bounded by a primitive recursive function and that its graph is primitive recursive -/ theorem of_graph {f : α → ℕ} (h₁ : PrimrecBounded f) (h₂ : PrimrecRel fun a b => f a = b) : Primrec f := by rcases h₁ with ⟨g, pg, hg : ∀ x, f x ≤ g x⟩ refine (nat_findGreatest pg h₂).of_eq fun n => ?_ exact (Nat.findGreatest_spec (P := fun b => f n = b) (hg n) rfl).symm -- We show that division is primitive recursive by showing that the graph is theorem nat_div : Primrec₂ ((· / ·) : ℕ → ℕ → ℕ) := by refine of_graph ⟨_, fst, fun p => Nat.div_le_self _ _⟩ ?_ have : PrimrecRel fun (a : ℕ × ℕ) (b : ℕ) => (a.2 = 0 ∧ b = 0) ∨ (0 < a.2 ∧ b a.2 ≤ a.1 ∧ a.1 < (b + 1) * a.2) := PrimrecPred.or (.and (const 0 \|> Primrec.eq.comp (fst \|> snd.comp)) (const 0 \|> Primrec.eq.comp snd)) (.and (nat_lt.comp (const 0) (fst \|> snd.comp)) <\| .and (nat_le.comp (nat_mul.comp snd (fst \|> snd.comp)) (fst \|> fst.comp)) (nat_lt.comp (fst.comp fst) (nat_mul.comp (Primrec.succ.comp snd) (snd.comp fst)))) refine this.of_eq ?_ rintro ⟨a, k⟩ q if H : k = 0 then simp [H, eq_comm] else have : q * k ≤ a ∧ a < (q + 1) * k ↔ q = a / k := by rw [le_antisymm_iff, ← (@Nat.lt_succ _ q), Nat.le_div_iff_mul_le (Nat.pos_of_ne_zero H), Nat.div_lt_iff_lt_mul (Nat.pos_of_ne_zero H)] simpa [H, zero_lt_iff, eq_comm (b := q)] theorem nat_mod : Primrec₂ ((· % ·) : ℕ → ℕ → ℕ) := (nat_sub.comp fst (nat_mul.comp snd nat_div)).to₂.of_eq fun m n => by apply Nat.sub_eq_of_eq_add simp [add_comm (m % n), Nat.div_add_mod] theorem nat_bodd : Primrec Nat.bodd := (Primrec.beq.comp (nat_mod.comp .id (const 2)) (const 1)).of_eq fun n => by cases H : n.bodd <;> simp [Nat.mod_two_of_bodd, H] theorem nat_div2 : Primrec Nat.div2 := (nat_div.comp .id (const 2)).of_eq fun n => n.div2_val.symm theorem nat_double : Primrec (fun n : ℕ => 2 * n) := nat_mul.comp (const _) Primrec.id theorem nat_double_succ : Primrec (fun n : ℕ => 2 * n + 1) := nat_double \|> Primrec.succ.comp end Primrec section variable {α : Type} {β : Type} {σ : Type*} variable [Primcodable α] [Primcodable β] [Primcodable σ] variable (H : Nat.Primrec fun n => Encodable.encode (@decode (List β) _ n)) open Primrec private def prim : Primcodable (List β) := ⟨H⟩ private theorem list_casesOn' {f : α → List β} {g : α → σ} {h : α → β × List β → σ} (hf : haveI := prim H; Primrec f) (hg : Primrec g) (hh : haveI := prim H; Primrec₂ h) : @Primrec _ σ _ _ fun a => List.casesOn (f a) (g a) fun b l => h a (b, l) := letI := prim H have : @Primrec _ (Option σ) _ _ fun a => (@decode (Option (β × List β)) _ (encode (f a))).map fun o => Option.casesOn o (g a) (h a) := ((@map_decode_iff _ (Option (β × List β)) _ _ _ _ _).2 <\| to₂ <\| option_casesOn snd (hg.comp fst) (hh.comp₂ (fst.comp₂ Primrec₂.left) Primrec₂.right)).comp .id (encode_iff.2 hf) option_some_iff.1 <\| this.of_eq fun a => by rcases f a with - \| ⟨b, l⟩ <;> simp [encodek] private theorem list_foldl' {f : α → List β} {g : α → σ} {h : α → σ × β → σ} (hf : haveI := prim H; Primrec f) (hg : Primrec g) (hh : haveI := prim H; Primrec₂ h) :	Primrec fun a => (f a).foldl (fun s b => h a (s, b)) (g a) := by letI := prim H let G (a : α) (IH : σ × List β) : σ × List β := List.casesOn IH.2 IH fun b l => (h a (IH.1, b), l) have hG : Primrec₂ G := list_casesOn' H (snd.comp snd) snd <\| to₂ <\|	Mathlib/Computability/Primrec.lean	744	748
/- Copyright (c) 2018 Patrick Massot. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Patrick Massot, Chris Hughes, Michael Howes -/ import Mathlib.Algebra.Group.End import Mathlib.Algebra.Group.Semiconj.Units /-! # Conjugacy of group elements See also `MulAut.conj` and `Quandle.conj`. -/ assert_not_exists MonoidWithZero Multiset MulAction universe u v variable {α : Type u} {β : Type v} section Monoid variable [Monoid α] [Monoid β] /-- We say that `a` is conjugate to `b` if for some unit `c` we have `c * a * c⁻¹ = b`. -/ def IsConj (a b : α) := ∃ c : αˣ, SemiconjBy (↑c) a b @[refl] theorem IsConj.refl (a : α) : IsConj a a := ⟨1, SemiconjBy.one_left a⟩ @[symm] theorem IsConj.symm {a b : α} : IsConj a b → IsConj b a \| ⟨c, hc⟩ => ⟨c⁻¹, hc.units_inv_symm_left⟩ theorem isConj_comm {g h : α} : IsConj g h ↔ IsConj h g := ⟨IsConj.symm, IsConj.symm⟩ @[trans] theorem IsConj.trans {a b c : α} : IsConj a b → IsConj b c → IsConj a c \| ⟨c₁, hc₁⟩, ⟨c₂, hc₂⟩ => ⟨c₂ * c₁, hc₂.mul_left hc₁⟩ theorem IsConj.pow {a b : α} (n : ℕ) : IsConj a b → IsConj (a^n) (b^n) \| ⟨c, hc⟩ => ⟨c, hc.pow_right n⟩ @[simp] theorem isConj_iff_eq {α : Type} [CommMonoid α] {a b : α} : IsConj a b ↔ a = b := ⟨fun ⟨c, hc⟩ => by rw [SemiconjBy, mul_comm, ← Units.mul_inv_eq_iff_eq_mul, mul_assoc, c.mul_inv, mul_one] at hc exact hc, fun h => by rw [h]⟩ protected theorem MonoidHom.map_isConj (f : α → β) {a b : α} : IsConj a b → IsConj (f a) (f b) \| ⟨c, hc⟩ => ⟨Units.map f c, by rw [Units.coe_map, SemiconjBy, ← f.map_mul, hc.eq, f.map_mul]⟩ @[simp] theorem isConj_one_right {a : α} : IsConj 1 a ↔ a = 1 := by refine ⟨fun ⟨c, h⟩ => ?_, fun h => by rw [h]⟩ rw [SemiconjBy, mul_one] at h exact c.isUnit.mul_eq_right.mp h.symm @[simp] theorem isConj_one_left {a : α} : IsConj a 1 ↔ a = 1 := calc IsConj a 1 ↔ IsConj 1 a := ⟨IsConj.symm, IsConj.symm⟩ _ ↔ a = 1 := isConj_one_right end Monoid section Group variable [Group α] @[simp] theorem isConj_iff {a b : α} : IsConj a b ↔ ∃ c : α, c * a * c⁻¹ = b := ⟨fun ⟨c, hc⟩ => ⟨c, mul_inv_eq_iff_eq_mul.2 hc⟩, fun ⟨c, hc⟩ => ⟨⟨c, c⁻¹, mul_inv_cancel c, inv_mul_cancel c⟩, mul_inv_eq_iff_eq_mul.1 hc⟩⟩ theorem conj_inv {a b : α} : (b * a * b⁻¹)⁻¹ = b * a⁻¹ * b⁻¹ := (map_inv (MulAut.conj b) a).symm @[simp] theorem conj_mul {a b c : α} : b * a * b⁻¹ * (b * c * b⁻¹) = b * (a * c) * b⁻¹ := (map_mul (MulAut.conj b) a c).symm @[simp] theorem conj_pow {i : ℕ} {a b : α} : (a * b * a⁻¹) ^ i = a * b ^ i * a⁻¹ := by induction' i with i hi · simp · simp [pow_succ, hi] @[simp] theorem conj_zpow {i : ℤ} {a b : α} : (a * b * a⁻¹) ^ i = a * b ^ i * a⁻¹ := by cases i · simp · simp only [zpow_negSucc, conj_pow, mul_inv_rev, inv_inv] rw [mul_assoc] theorem conj_injective {x : α} : Function.Injective fun g : α => x * g * x⁻¹ := (MulAut.conj x).injective end Group namespace IsConj /- This small quotient API is largely copied from the API of `Associates`; where possible, try to keep them in sync -/ /-- The setoid of the relation `IsConj` iff there is a unit `u` such that `u * x = y * u` -/ protected def setoid (α : Type) [Monoid α] : Setoid α where r := IsConj iseqv := ⟨IsConj.refl, IsConj.symm, IsConj.trans⟩ end IsConj attribute [local instance] IsConj.setoid /-- The quotient type of conjugacy classes of a group. -/ def ConjClasses (α : Type) [Monoid α] : Type _ := Quotient (IsConj.setoid α) namespace ConjClasses section Monoid variable [Monoid α] [Monoid β] /-- The canonical quotient map from a monoid `α` into the `ConjClasses` of `α` -/ protected def mk {α : Type} [Monoid α] (a : α) : ConjClasses α := ⟦a⟧ instance : Inhabited (ConjClasses α) := ⟨⟦1⟧⟩ theorem mk_eq_mk_iff_isConj {a b : α} : ConjClasses.mk a = ConjClasses.mk b ↔ IsConj a b := Iff.intro Quotient.exact Quot.sound theorem quotient_mk_eq_mk (a : α) : ⟦a⟧ = ConjClasses.mk a := rfl theorem quot_mk_eq_mk (a : α) : Quot.mk Setoid.r a = ConjClasses.mk a := rfl theorem forall_isConj {p : ConjClasses α → Prop} : (∀ a, p a) ↔ ∀ a, p (ConjClasses.mk a) := Iff.intro (fun h _ => h _) fun h a => Quotient.inductionOn a h theorem mk_surjective : Function.Surjective (@ConjClasses.mk α _) := forall_isConj.2 fun a => ⟨a, rfl⟩ instance : One (ConjClasses α) := ⟨⟦1⟧⟩ theorem one_eq_mk_one : (1 : ConjClasses α) = ConjClasses.mk 1 := rfl theorem exists_rep (a : ConjClasses α) : ∃ a0 : α, ConjClasses.mk a0 = a := Quot.exists_rep a /-- A `MonoidHom` maps conjugacy classes of one group to conjugacy classes of another. -/ def map (f : α → β) : ConjClasses α → ConjClasses β := Quotient.lift (ConjClasses.mk ∘ f) fun _ _ ab => mk_eq_mk_iff_isConj.2 (f.map_isConj ab) theorem map_surjective {f : α →* β} (hf : Function.Surjective f) : Function.Surjective (ConjClasses.map f) := by intro b obtain ⟨b, rfl⟩ := ConjClasses.mk_surjective b obtain ⟨a, rfl⟩ := hf b exact ⟨ConjClasses.mk a, rfl⟩ -- Porting note: This has not been adapted to mathlib4, is it still accurate? library_note "slow-failing instance priority"/-- Certain instances trigger further searches when they are considered as candidate instances; these instances should be assigned a priority lower than the default of 1000 (for example, 900). The conditions for this rule are as follows: * a class `C` has instances `instT : C T` and `instT' : C T'` * types `T` and `T'` are both specializations of another type `S` * the parameters supplied to `S` to produce `T` are not (fully) determined by `instT`, instead they have to be found by instance search If those conditions hold, the instance `instT` should be assigned lower priority. For example, suppose the search for an instance of `DecidableEq (Multiset α)` tries the candidate instance `Con.quotient.decidableEq (c : Con M) : decidableEq c.quotient`. Since `Multiset` and `Con.quotient` are both quotient types, unification will check that the relations `List.perm` and `c.toSetoid.r` unify. However, `c.toSetoid` depends on a `Mul M` instance, so this unification triggers a search for `Mul (List α)`; this will traverse all subclasses of `Mul` before failing. On the other hand, the search for an instance of `DecidableEq (Con.quotient c)` for `c : Con M` can quickly reject the candidate instance `Multiset.decidableEq` because the type of `List.perm : List ?m_1 → List ?m_1 → Prop` does not unify with `M → M → Prop`. Therefore, we should assign `Con.quotient.decidableEq` a lower priority because it fails slowly. (In terms of the rules above, `C := DecidableEq`, `T := Con.quotient`, `instT := Con.quotient.decidableEq`, `T' := Multiset`, `instT' := Multiset.decidableEq`, and `S := Quot`.) If the type involved is a free variable (rather than an instantiation of some type `S`), the instance priority should be even lower, see Note [lower instance priority]. -/ -- see Note [slow-failing instance priority] instance (priority := 900) [DecidableRel (IsConj : α → α → Prop)] : DecidableEq (ConjClasses α) := inferInstanceAs <\| DecidableEq <\| Quotient (IsConj.setoid α) end Monoid section CommMonoid variable [CommMonoid α] theorem mk_injective : Function.Injective (@ConjClasses.mk α _) := fun _ _ => (mk_eq_mk_iff_isConj.trans isConj_iff_eq).1 theorem mk_bijective : Function.Bijective (@ConjClasses.mk α _) := ⟨mk_injective, mk_surjective⟩ /-- The bijection between a `CommGroup` and its `ConjClasses`. -/ def mkEquiv : α ≃ ConjClasses α := ⟨ConjClasses.mk, Quotient.lift id fun (_ : α) _ => isConj_iff_eq.1, Quotient.lift_mk _ _, by rw [Function.RightInverse, Function.LeftInverse, forall_isConj] intro x rw [← quotient_mk_eq_mk, ← quotient_mk_eq_mk, Quotient.lift_mk, id]⟩ end CommMonoid end ConjClasses section Monoid variable [Monoid α] /-- Given an element `a`, `conjugatesOf a` is the set of conjugates. -/ def conjugatesOf (a : α) : Set α := { b \| IsConj a b } theorem mem_conjugatesOf_self {a : α} : a ∈ conjugatesOf a := IsConj.refl _ theorem IsConj.conjugatesOf_eq {a b : α} (ab : IsConj a b) : conjugatesOf a = conjugatesOf b := Set.ext fun _ => ⟨fun ag => ab.symm.trans ag, fun bg => ab.trans bg⟩ theorem isConj_iff_conjugatesOf_eq {a b : α} : IsConj a b ↔ conjugatesOf a = conjugatesOf b := ⟨IsConj.conjugatesOf_eq, fun h => by have ha := mem_conjugatesOf_self (a := b) rwa [← h] at ha⟩ end Monoid namespace ConjClasses variable [Monoid α] attribute [local instance] IsConj.setoid /-- Given a conjugacy class `a`, `carrier a` is the set it represents. -/ def carrier : ConjClasses α → Set α := Quotient.lift conjugatesOf fun (_ : α) _ ab => IsConj.conjugatesOf_eq ab theorem mem_carrier_mk {a : α} : a ∈ carrier (ConjClasses.mk a) := IsConj.refl _ theorem mem_carrier_iff_mk_eq {a : α} {b : ConjClasses α} : a ∈ carrier b ↔ ConjClasses.mk a = b := by revert b rw [forall_isConj] intro b rw [carrier, eq_comm, mk_eq_mk_iff_isConj, ← quotient_mk_eq_mk, Quotient.lift_mk] rfl theorem carrier_eq_preimage_mk {a : ConjClasses α} : a.carrier = ConjClasses.mk ⁻¹' {a} := Set.ext fun _ => mem_carrier_iff_mk_eq end ConjClasses		Mathlib/Algebra/Group/Conj.lean	307	313
/- Copyright (c) 2018 Chris Hughes. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Chris Hughes, Johannes Hölzl, Kim Morrison, Jens Wagemaker -/ import Mathlib.Algebra.Field.IsField import Mathlib.Algebra.Polynomial.Inductions import Mathlib.Algebra.Polynomial.Monic import Mathlib.Algebra.Ring.Regular import Mathlib.RingTheory.Multiplicity import Mathlib.Data.Nat.Lattice /-! # Division of univariate polynomials The main defs are `divByMonic` and `modByMonic`. The compatibility between these is given by `modByMonic_add_div`. We also define `rootMultiplicity`. -/ noncomputable section open Polynomial open Finset namespace Polynomial universe u v w z variable {R : Type u} {S : Type v} {T : Type w} {A : Type z} {a b : R} {n : ℕ} section Semiring variable [Semiring R] theorem X_dvd_iff {f : R[X]} : X ∣ f ↔ f.coeff 0 = 0 := ⟨fun ⟨g, hfg⟩ => by rw [hfg, coeff_X_mul_zero], fun hf => ⟨f.divX, by rw [← add_zero (X * f.divX), ← C_0, ← hf, X_mul_divX_add]⟩⟩ theorem X_pow_dvd_iff {f : R[X]} {n : ℕ} : X ^ n ∣ f ↔ ∀ d < n, f.coeff d = 0 := ⟨fun ⟨g, hgf⟩ d hd => by simp only [hgf, coeff_X_pow_mul', ite_eq_right_iff, not_le_of_lt hd, IsEmpty.forall_iff], fun hd => by induction n with \| zero => simp [pow_zero, one_dvd] \| succ n hn => obtain ⟨g, hgf⟩ := hn fun d : ℕ => fun H : d < n => hd _ (Nat.lt_succ_of_lt H) have := coeff_X_pow_mul g n 0 rw [zero_add, ← hgf, hd n (Nat.lt_succ_self n)] at this obtain ⟨k, hgk⟩ := Polynomial.X_dvd_iff.mpr this.symm use k rwa [pow_succ, mul_assoc, ← hgk]⟩ variable {p q : R[X]} theorem finiteMultiplicity_of_degree_pos_of_monic (hp : (0 : WithBot ℕ) < degree p) (hmp : Monic p) (hq : q ≠ 0) : FiniteMultiplicity p q := have zn0 : (0 : R) ≠ 1 := haveI := Nontrivial.of_polynomial_ne hq zero_ne_one ⟨natDegree q, fun ⟨r, hr⟩ => by have hp0 : p ≠ 0 := fun hp0 => by simp [hp0] at hp have hr0 : r ≠ 0 := fun hr0 => by subst hr0; simp [hq] at hr have hpn1 : leadingCoeff p ^ (natDegree q + 1) = 1 := by simp [show _ = _ from hmp] have hpn0' : leadingCoeff p ^ (natDegree q + 1) ≠ 0 := hpn1.symm ▸ zn0.symm have hpnr0 : leadingCoeff (p ^ (natDegree q + 1)) * leadingCoeff r ≠ 0 := by simp only [leadingCoeff_pow' hpn0', leadingCoeff_eq_zero, hpn1, one_pow, one_mul, Ne, hr0, not_false_eq_true] have hnp : 0 < natDegree p := Nat.cast_lt.1 <\| by rw [← degree_eq_natDegree hp0]; exact hp have := congr_arg natDegree hr rw [natDegree_mul' hpnr0, natDegree_pow' hpn0', add_mul, add_assoc] at this exact ne_of_lt (lt_add_of_le_of_pos (le_mul_of_one_le_right (Nat.zero_le _) hnp) (add_pos_of_pos_of_nonneg (by rwa [one_mul]) (Nat.zero_le _))) this⟩ @[deprecated (since := "2024-11-30")] alias multiplicity_finite_of_degree_pos_of_monic := finiteMultiplicity_of_degree_pos_of_monic end Semiring section Ring variable [Ring R] {p q : R[X]} theorem div_wf_lemma (h : degree q ≤ degree p ∧ p ≠ 0) (hq : Monic q) : degree (p - q * (C (leadingCoeff p) * X ^ (natDegree p - natDegree q))) < degree p := have hp : leadingCoeff p ≠ 0 := mt leadingCoeff_eq_zero.1 h.2 have hq0 : q ≠ 0 := hq.ne_zero_of_polynomial_ne h.2 have hlt : natDegree q ≤ natDegree p := (Nat.cast_le (α := WithBot ℕ)).1 (by rw [← degree_eq_natDegree h.2, ← degree_eq_natDegree hq0]; exact h.1) degree_sub_lt (by rw [hq.degree_mul_comm, hq.degree_mul, degree_C_mul_X_pow _ hp, degree_eq_natDegree h.2, degree_eq_natDegree hq0, ← Nat.cast_add, tsub_add_cancel_of_le hlt]) h.2 (by rw [leadingCoeff_monic_mul hq, leadingCoeff_mul_X_pow, leadingCoeff_C]) /-- See `divByMonic`. -/ noncomputable def divModByMonicAux : ∀ (_p : R[X]) {q : R[X]}, Monic q → R[X] × R[X] \| p, q, hq => letI := Classical.decEq R if h : degree q ≤ degree p ∧ p ≠ 0 then let z := C (leadingCoeff p) * X ^ (natDegree p - natDegree q) have _wf := div_wf_lemma h hq let dm := divModByMonicAux (p - q * z) hq ⟨z + dm.1, dm.2⟩ else ⟨0, p⟩ termination_by p => p /-- `divByMonic`, denoted as `p /ₘ q`, gives the quotient of `p` by a monic polynomial `q`. -/ def divByMonic (p q : R[X]) : R[X] := letI := Classical.decEq R if hq : Monic q then (divModByMonicAux p hq).1 else 0 /-- `modByMonic`, denoted as `p %ₘ q`, gives the remainder of `p` by a monic polynomial `q`. -/ def modByMonic (p q : R[X]) : R[X] := letI := Classical.decEq R if hq : Monic q then (divModByMonicAux p hq).2 else p @[inherit_doc] infixl:70 " /ₘ " => divByMonic @[inherit_doc] infixl:70 " %ₘ " => modByMonic theorem degree_modByMonic_lt [Nontrivial R] : ∀ (p : R[X]) {q : R[X]} (_hq : Monic q), degree (p %ₘ q) < degree q \| p, q, hq => letI := Classical.decEq R if h : degree q ≤ degree p ∧ p ≠ 0 then by have _wf := div_wf_lemma ⟨h.1, h.2⟩ hq have := degree_modByMonic_lt (p - q * (C (leadingCoeff p) * X ^ (natDegree p - natDegree q))) hq unfold modByMonic at this ⊢ unfold divModByMonicAux dsimp rw [dif_pos hq] at this ⊢ rw [if_pos h] exact this else Or.casesOn (not_and_or.1 h) (by unfold modByMonic divModByMonicAux dsimp rw [dif_pos hq, if_neg h] exact lt_of_not_ge) (by intro hp unfold modByMonic divModByMonicAux dsimp rw [dif_pos hq, if_neg h, Classical.not_not.1 hp] exact lt_of_le_of_ne bot_le (Ne.symm (mt degree_eq_bot.1 hq.ne_zero))) termination_by p => p theorem natDegree_modByMonic_lt (p : R[X]) {q : R[X]} (hmq : Monic q) (hq : q ≠ 1) : natDegree (p %ₘ q) < q.natDegree := by by_cases hpq : p %ₘ q = 0 · rw [hpq, natDegree_zero, Nat.pos_iff_ne_zero] contrapose! hq exact eq_one_of_monic_natDegree_zero hmq hq · haveI := Nontrivial.of_polynomial_ne hpq exact natDegree_lt_natDegree hpq (degree_modByMonic_lt p hmq) @[simp] theorem zero_modByMonic (p : R[X]) : 0 %ₘ p = 0 := by classical unfold modByMonic divModByMonicAux dsimp by_cases hp : Monic p · rw [dif_pos hp, if_neg (mt And.right (not_not_intro rfl)), Prod.snd_zero] · rw [dif_neg hp] @[simp] theorem zero_divByMonic (p : R[X]) : 0 /ₘ p = 0 := by classical unfold divByMonic divModByMonicAux dsimp by_cases hp : Monic p · rw [dif_pos hp, if_neg (mt And.right (not_not_intro rfl)), Prod.fst_zero] · rw [dif_neg hp] @[simp] theorem modByMonic_zero (p : R[X]) : p %ₘ 0 = p := letI := Classical.decEq R if h : Monic (0 : R[X]) then by haveI := monic_zero_iff_subsingleton.mp h simp [eq_iff_true_of_subsingleton] else by unfold modByMonic divModByMonicAux; rw [dif_neg h] @[simp] theorem divByMonic_zero (p : R[X]) : p /ₘ 0 = 0 := letI := Classical.decEq R if h : Monic (0 : R[X]) then by haveI := monic_zero_iff_subsingleton.mp h simp [eq_iff_true_of_subsingleton] else by unfold divByMonic divModByMonicAux; rw [dif_neg h] theorem divByMonic_eq_of_not_monic (p : R[X]) (hq : ¬Monic q) : p /ₘ q = 0 := dif_neg hq theorem modByMonic_eq_of_not_monic (p : R[X]) (hq : ¬Monic q) : p %ₘ q = p := dif_neg hq theorem modByMonic_eq_self_iff [Nontrivial R] (hq : Monic q) : p %ₘ q = p ↔ degree p < degree q := ⟨fun h => h ▸ degree_modByMonic_lt _ hq, fun h => by classical have : ¬degree q ≤ degree p := not_le_of_gt h unfold modByMonic divModByMonicAux; dsimp; rw [dif_pos hq, if_neg (mt And.left this)]⟩ theorem degree_modByMonic_le (p : R[X]) {q : R[X]} (hq : Monic q) : degree (p %ₘ q) ≤ degree q := by nontriviality R exact (degree_modByMonic_lt _ hq).le theorem degree_modByMonic_le_left : degree (p %ₘ q) ≤ degree p := by nontriviality R by_cases hq : q.Monic · cases lt_or_ge (degree p) (degree q) · rw [(modByMonic_eq_self_iff hq).mpr ‹_›] · exact (degree_modByMonic_le p hq).trans ‹_› · rw [modByMonic_eq_of_not_monic p hq] theorem natDegree_modByMonic_le (p : Polynomial R) {g : Polynomial R} (hg : g.Monic) : natDegree (p %ₘ g) ≤ g.natDegree := natDegree_le_natDegree (degree_modByMonic_le p hg) theorem natDegree_modByMonic_le_left : natDegree (p %ₘ q) ≤ natDegree p := natDegree_le_natDegree degree_modByMonic_le_left theorem X_dvd_sub_C : X ∣ p - C (p.coeff 0) := by simp [X_dvd_iff, coeff_C] theorem modByMonic_eq_sub_mul_div : ∀ (p : R[X]) {q : R[X]} (_hq : Monic q), p %ₘ q = p - q * (p /ₘ q) \| p, q, hq => letI := Classical.decEq R if h : degree q ≤ degree p ∧ p ≠ 0 then by have _wf := div_wf_lemma h hq have ih := modByMonic_eq_sub_mul_div (p - q * (C (leadingCoeff p) * X ^ (natDegree p - natDegree q))) hq unfold modByMonic divByMonic divModByMonicAux dsimp rw [dif_pos hq, if_pos h] rw [modByMonic, dif_pos hq] at ih refine ih.trans ?_ unfold divByMonic rw [dif_pos hq, dif_pos hq, if_pos h, mul_add, sub_add_eq_sub_sub] else by unfold modByMonic divByMonic divModByMonicAux dsimp rw [dif_pos hq, if_neg h, dif_pos hq, if_neg h, mul_zero, sub_zero] termination_by p => p theorem modByMonic_add_div (p : R[X]) {q : R[X]} (hq : Monic q) : p %ₘ q + q * (p /ₘ q) = p := eq_sub_iff_add_eq.1 (modByMonic_eq_sub_mul_div p hq) theorem divByMonic_eq_zero_iff [Nontrivial R] (hq : Monic q) : p /ₘ q = 0 ↔ degree p < degree q := ⟨fun h => by have := modByMonic_add_div p hq rwa [h, mul_zero, add_zero, modByMonic_eq_self_iff hq] at this, fun h => by classical have : ¬degree q ≤ degree p := not_le_of_gt h unfold divByMonic divModByMonicAux; dsimp; rw [dif_pos hq, if_neg (mt And.left this)]⟩ theorem degree_add_divByMonic (hq : Monic q) (h : degree q ≤ degree p) : degree q + degree (p /ₘ q) = degree p := by nontriviality R have hdiv0 : p /ₘ q ≠ 0 := by rwa [Ne, divByMonic_eq_zero_iff hq, not_lt] have hlc : leadingCoeff q * leadingCoeff (p /ₘ q) ≠ 0 := by rwa [Monic.def.1 hq, one_mul, Ne, leadingCoeff_eq_zero] have hmod : degree (p %ₘ q) < degree (q * (p /ₘ q)) := calc degree (p %ₘ q) < degree q := degree_modByMonic_lt _ hq _ ≤ _ := by rw [degree_mul' hlc, degree_eq_natDegree hq.ne_zero, degree_eq_natDegree hdiv0, ← Nat.cast_add, Nat.cast_le] exact Nat.le_add_right _ _ calc degree q + degree (p /ₘ q) = degree (q * (p /ₘ q)) := Eq.symm (degree_mul' hlc) _ = degree (p %ₘ q + q * (p /ₘ q)) := (degree_add_eq_right_of_degree_lt hmod).symm _ = _ := congr_arg _ (modByMonic_add_div _ hq) theorem degree_divByMonic_le (p q : R[X]) : degree (p /ₘ q) ≤ degree p := letI := Classical.decEq R if hp0 : p = 0 then by simp only [hp0, zero_divByMonic, le_refl] else if hq : Monic q then if h : degree q ≤ degree p then by haveI := Nontrivial.of_polynomial_ne hp0 rw [← degree_add_divByMonic hq h, degree_eq_natDegree hq.ne_zero, degree_eq_natDegree (mt (divByMonic_eq_zero_iff hq).1 (not_lt.2 h))] exact WithBot.coe_le_coe.2 (Nat.le_add_left _ _) else by unfold divByMonic divModByMonicAux simp [dif_pos hq, h, if_false, degree_zero, bot_le] else (divByMonic_eq_of_not_monic p hq).symm ▸ bot_le theorem degree_divByMonic_lt (p : R[X]) {q : R[X]} (hq : Monic q) (hp0 : p ≠ 0) (h0q : 0 < degree q) : degree (p /ₘ q) < degree p := if hpq : degree p < degree q then by haveI := Nontrivial.of_polynomial_ne hp0 rw [(divByMonic_eq_zero_iff hq).2 hpq, degree_eq_natDegree hp0] exact WithBot.bot_lt_coe _ else by haveI := Nontrivial.of_polynomial_ne hp0 rw [← degree_add_divByMonic hq (not_lt.1 hpq), degree_eq_natDegree hq.ne_zero, degree_eq_natDegree (mt (divByMonic_eq_zero_iff hq).1 hpq)] exact Nat.cast_lt.2 (Nat.lt_add_of_pos_left (Nat.cast_lt.1 <\| by simpa [degree_eq_natDegree hq.ne_zero] using h0q)) theorem natDegree_divByMonic (f : R[X]) {g : R[X]} (hg : g.Monic) : natDegree (f /ₘ g) = natDegree f - natDegree g := by nontriviality R by_cases hfg : f /ₘ g = 0 · rw [hfg, natDegree_zero] rw [divByMonic_eq_zero_iff hg] at hfg rw [tsub_eq_zero_iff_le.mpr (natDegree_le_natDegree <\| le_of_lt hfg)] have hgf := hfg rw [divByMonic_eq_zero_iff hg] at hgf push_neg at hgf have := degree_add_divByMonic hg hgf have hf : f ≠ 0 := by intro hf apply hfg rw [hf, zero_divByMonic] rw [degree_eq_natDegree hf, degree_eq_natDegree hg.ne_zero, degree_eq_natDegree hfg, ← Nat.cast_add, Nat.cast_inj] at this rw [← this, add_tsub_cancel_left] theorem div_modByMonic_unique {f g} (q r : R[X]) (hg : Monic g) (h : r + g * q = f ∧ degree r < degree g) : f /ₘ g = q ∧ f %ₘ g = r := by nontriviality R have h₁ : r - f %ₘ g = -g * (q - f /ₘ g) := eq_of_sub_eq_zero (by rw [← sub_eq_zero_of_eq (h.1.trans (modByMonic_add_div f hg).symm)] simp [mul_add, mul_comm, sub_eq_add_neg, add_comm, add_left_comm, add_assoc]) have h₂ : degree (r - f %ₘ g) = degree (g * (q - f /ₘ g)) := by simp [h₁] have h₄ : degree (r - f %ₘ g) < degree g := calc	degree (r - f %ₘ g) ≤ max (degree r) (degree (f %ₘ g)) := degree_sub_le _ _ _ < degree g := max_lt_iff.2 ⟨h.2, degree_modByMonic_lt _ hg⟩ have h₅ : q - f /ₘ g = 0 := _root_.by_contradiction fun hqf => not_le_of_gt h₄ <\| calc degree g ≤ degree g + degree (q - f /ₘ g) := by rw [degree_eq_natDegree hg.ne_zero, degree_eq_natDegree hqf] norm_cast exact Nat.le_add_right _ _ _ = degree (r - f %ₘ g) := by rw [h₂, degree_mul']; simpa [Monic.def.1 hg] exact ⟨Eq.symm <\| eq_of_sub_eq_zero h₅, Eq.symm <\| eq_of_sub_eq_zero <\| by simpa [h₅] using h₁⟩ theorem map_mod_divByMonic [Ring S] (f : R →+* S) (hq : Monic q) : (p /ₘ q).map f = p.map f /ₘ q.map f ∧ (p %ₘ q).map f = p.map f %ₘ q.map f := by nontriviality S haveI : Nontrivial R := f.domain_nontrivial have : map f p /ₘ map f q = map f (p /ₘ q) ∧ map f p %ₘ map f q = map f (p %ₘ q) := div_modByMonic_unique ((p /ₘ q).map f) _ (hq.map f) ⟨Eq.symm <\| by rw [← Polynomial.map_mul, ← Polynomial.map_add, modByMonic_add_div _ hq], calc _ ≤ degree (p %ₘ q) := degree_map_le	Mathlib/Algebra/Polynomial/Div.lean	347	368
/- Copyright (c) 2022 Eric Wieser. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Eric Wieser -/ import Mathlib.Data.DFinsupp.BigOperators import Mathlib.Data.DFinsupp.Order /-! # Equivalence between `Multiset` and `ℕ`-valued finitely supported functions This defines `DFinsupp.toMultiset` the equivalence between `Π₀ a : α, ℕ` and `Multiset α`, along with `Multiset.toDFinsupp` the reverse equivalence. -/ open Function variable {α : Type*} namespace DFinsupp /-- Non-dependent special case of `DFinsupp.addZeroClass` to help typeclass search. -/ instance addZeroClass' {β} [AddZeroClass β] : AddZeroClass (Π₀ _ : α, β) := @DFinsupp.addZeroClass α (fun _ ↦ β) _ variable [DecidableEq α] /-- A DFinsupp version of `Finsupp.toMultiset`. -/ def toMultiset : (Π₀ _ : α, ℕ) →+ Multiset α := DFinsupp.sumAddHom fun a : α ↦ Multiset.replicateAddMonoidHom a @[simp] theorem toMultiset_single (a : α) (n : ℕ) : toMultiset (DFinsupp.single a n) = Multiset.replicate n a := DFinsupp.sumAddHom_single _ _ _ end DFinsupp namespace Multiset variable [DecidableEq α] {s t : Multiset α} /-- A DFinsupp version of `Multiset.toFinsupp`. -/ def toDFinsupp : Multiset α →+ Π₀ _ : α, ℕ where toFun s := { toFun := fun n ↦ s.count n support' := Trunc.mk ⟨s, fun i ↦ (em (i ∈ s)).imp_right Multiset.count_eq_zero_of_not_mem⟩ } map_zero' := rfl map_add' _ _ := DFinsupp.ext fun _ ↦ Multiset.count_add _ _ _ @[simp] theorem toDFinsupp_apply (s : Multiset α) (a : α) : Multiset.toDFinsupp s a = s.count a := rfl @[simp] theorem toDFinsupp_support (s : Multiset α) : s.toDFinsupp.support = s.toFinset := Finset.filter_true_of_mem fun _ hx ↦ count_ne_zero.mpr <\| Multiset.mem_toFinset.1 hx @[simp] theorem toDFinsupp_replicate (a : α) (n : ℕ) : toDFinsupp (Multiset.replicate n a) = DFinsupp.single a n := by ext i dsimp [toDFinsupp] simp [count_replicate, eq_comm] @[simp] theorem toDFinsupp_singleton (a : α) : toDFinsupp {a} = DFinsupp.single a 1 := by rw [← replicate_one, toDFinsupp_replicate] /-- `Multiset.toDFinsupp` as an `AddEquiv`. -/ @[simps! apply symm_apply] def equivDFinsupp : Multiset α ≃+ Π₀ _ : α, ℕ := AddMonoidHom.toAddEquiv Multiset.toDFinsupp DFinsupp.toMultiset (by ext; simp) (by ext; simp) @[simp] theorem toDFinsupp_toMultiset (s : Multiset α) : DFinsupp.toMultiset (Multiset.toDFinsupp s) = s := equivDFinsupp.symm_apply_apply s theorem toDFinsupp_injective : Injective (toDFinsupp : Multiset α → Π₀ _a, ℕ) := equivDFinsupp.injective @[simp] theorem toDFinsupp_inj : toDFinsupp s = toDFinsupp t ↔ s = t := toDFinsupp_injective.eq_iff @[simp] theorem toDFinsupp_le_toDFinsupp : toDFinsupp s ≤ toDFinsupp t ↔ s ≤ t := by simp [Multiset.le_iff_count, DFinsupp.le_def] @[simp] theorem toDFinsupp_lt_toDFinsupp : toDFinsupp s < toDFinsupp t ↔ s < t := lt_iff_lt_of_le_iff_le' toDFinsupp_le_toDFinsupp toDFinsupp_le_toDFinsupp @[simp] theorem toDFinsupp_inter (s t : Multiset α) : toDFinsupp (s ∩ t) = toDFinsupp s ⊓ toDFinsupp t := by ext i; simp @[simp] theorem toDFinsupp_union (s t : Multiset α) : toDFinsupp (s ∪ t) = toDFinsupp s ⊔ toDFinsupp t := by	ext i; simp	Mathlib/Data/DFinsupp/Multiset.lean	100	101
/- Copyright (c) 2020 Bhavik Mehta. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Bhavik Mehta, Thomas Read, Andrew Yang, Dagur Asgeirsson, Joël Riou -/ import Mathlib.CategoryTheory.Adjunction.Mates /-! # Uniqueness of adjoints This file shows that adjoints are unique up to natural isomorphism. ## Main results * `Adjunction.leftAdjointUniq` : If `F` and `F'` are both left adjoint to `G`, then they are naturally isomorphic. * `Adjunction.rightAdjointUniq` : If `G` and `G'` are both right adjoint to `F`, then they are naturally isomorphic. -/ open CategoryTheory variable {C D : Type*} [Category C] [Category D] namespace CategoryTheory.Adjunction attribute [local simp] homEquiv_unit homEquiv_counit /-- If `F` and `F'` are both left adjoint to `G`, then they are naturally isomorphic. -/ def leftAdjointUniq {F F' : C ⥤ D} {G : D ⥤ C} (adj1 : F ⊣ G) (adj2 : F' ⊣ G) : F ≅ F' := ((conjugateIsoEquiv adj1 adj2).symm (Iso.refl G)).symm theorem homEquiv_leftAdjointUniq_hom_app {F F' : C ⥤ D} {G : D ⥤ C} (adj1 : F ⊣ G) (adj2 : F' ⊣ G) (x : C) : adj1.homEquiv _ _ ((leftAdjointUniq adj1 adj2).hom.app x) = adj2.unit.app x := by simp [leftAdjointUniq] @[reassoc (attr := simp)] theorem unit_leftAdjointUniq_hom {F F' : C ⥤ D} {G : D ⥤ C} (adj1 : F ⊣ G) (adj2 : F' ⊣ G) : adj1.unit ≫ whiskerRight (leftAdjointUniq adj1 adj2).hom G = adj2.unit := by ext x rw [NatTrans.comp_app, ← homEquiv_leftAdjointUniq_hom_app adj1 adj2] simp [← G.map_comp] @[reassoc (attr := simp)] theorem unit_leftAdjointUniq_hom_app {F F' : C ⥤ D} {G : D ⥤ C} (adj1 : F ⊣ G) (adj2 : F' ⊣ G) (x : C) : adj1.unit.app x ≫ G.map ((leftAdjointUniq adj1 adj2).hom.app x) = adj2.unit.app x := by rw [← unit_leftAdjointUniq_hom adj1 adj2]; rfl @[reassoc (attr := simp)] theorem leftAdjointUniq_hom_counit {F F' : C ⥤ D} {G : D ⥤ C} (adj1 : F ⊣ G) (adj2 : F' ⊣ G) : whiskerLeft G (leftAdjointUniq adj1 adj2).hom ≫ adj2.counit = adj1.counit := by ext x simp only [Functor.comp_obj, Functor.id_obj, leftAdjointUniq, Iso.symm_hom, conjugateIsoEquiv_symm_apply_inv, Iso.refl_inv, NatTrans.comp_app, whiskerLeft_app, conjugateEquiv_symm_apply_app, NatTrans.id_app, Functor.map_id, Category.id_comp, Category.assoc] rw [← adj1.counit_naturality, ← Category.assoc, ← F.map_comp] simp @[reassoc (attr := simp)] theorem leftAdjointUniq_hom_app_counit {F F' : C ⥤ D} {G : D ⥤ C} (adj1 : F ⊣ G) (adj2 : F' ⊣ G) (x : D) : (leftAdjointUniq adj1 adj2).hom.app (G.obj x) ≫ adj2.counit.app x = adj1.counit.app x := by rw [← leftAdjointUniq_hom_counit adj1 adj2] rfl theorem leftAdjointUniq_inv_app {F F' : C ⥤ D} {G : D ⥤ C} (adj1 : F ⊣ G) (adj2 : F' ⊣ G) (x : C) : (leftAdjointUniq adj1 adj2).inv.app x = (leftAdjointUniq adj2 adj1).hom.app x :=	rfl @[reassoc (attr := simp)] theorem leftAdjointUniq_trans {F F' F'' : C ⥤ D} {G : D ⥤ C} (adj1 : F ⊣ G) (adj2 : F' ⊣ G) (adj3 : F'' ⊣ G) : (leftAdjointUniq adj1 adj2).hom ≫ (leftAdjointUniq adj2 adj3).hom = (leftAdjointUniq adj1 adj3).hom := by simp [leftAdjointUniq] @[reassoc (attr := simp)] theorem leftAdjointUniq_trans_app {F F' F'' : C ⥤ D} {G : D ⥤ C} (adj1 : F ⊣ G) (adj2 : F' ⊣ G) (adj3 : F'' ⊣ G) (x : C) :	Mathlib/CategoryTheory/Adjunction/Unique.lean	72	83
/- 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.Sites.LocallySurjective import Mathlib.CategoryTheory.Sites.Localization /-! # Locally bijective morphisms of presheaves Let `C` a be category equipped with a Grothendieck topology `J`. Let `A` be a concrete category. In this file, we introduce a type-class `J.WEqualsLocallyBijective A` which says that the class `J.W` (of morphisms of presheaves which become isomorphisms after sheafification) is the class of morphisms that are both locally injective and locally surjective (i.e. locally bijective). We prove that this holds iff for any presheaf `P : Cᵒᵖ ⥤ A`, the sheafification map `toSheafify J P` is locally bijective. We show that this holds under certain universe assumptions. -/ universe w' w v' v u' u namespace CategoryTheory variable {C : Type u} [Category.{v} C] {J : GrothendieckTopology C} variable {A : Type u'} [Category.{v'} A] {FA : A → A → Type*} {CA : A → Type w'} variable [∀ X Y, FunLike (FA X Y) (CA X) (CA Y)] [ConcreteCategory.{w'} A FA] namespace Sheaf section variable {F G : Sheaf J (Type w)} (f : F ⟶ G) attribute [local instance] Types.instFunLike Types.instConcreteCategory in /-- A morphism of sheaves of types is locally bijective iff it is an isomorphism. (This is generalized below as `isLocallyBijective_iff_isIso`.) -/ private lemma isLocallyBijective_iff_isIso' : IsLocallyInjective f ∧ IsLocallySurjective f ↔ IsIso f := by constructor · rintro ⟨h₁, _⟩ rw [isLocallyInjective_iff_injective] at h₁ suffices ∀ (X : Cᵒᵖ), Function.Surjective (f.val.app X) by rw [← isIso_iff_of_reflects_iso _ (sheafToPresheaf _ _), NatTrans.isIso_iff_isIso_app] intro X rw [isIso_iff_bijective] exact ⟨h₁ X, this X⟩ intro X s have H := (isSheaf_iff_isSheaf_of_type J F.val).1 F.cond _ (Presheaf.imageSieve_mem J f.val s) let t : Presieve.FamilyOfElements F.val (Presheaf.imageSieve f.val s).arrows := fun Y g hg => Presheaf.localPreimage f.val s g hg have ht : t.Compatible := by intro Y₁ Y₂ W g₁ g₂ f₁ f₂ hf₁ hf₂ w apply h₁ have eq₁ := FunctorToTypes.naturality _ _ f.val g₁.op (t f₁ hf₁) have eq₂ := FunctorToTypes.naturality _ _ f.val g₂.op (t f₂ hf₂) have eq₃ := congr_arg (G.val.map g₁.op) (Presheaf.app_localPreimage f.val s _ hf₁) have eq₄ := congr_arg (G.val.map g₂.op) (Presheaf.app_localPreimage f.val s _ hf₂) refine eq₁.trans (eq₃.trans (Eq.trans ?_ (eq₄.symm.trans eq₂.symm))) erw [← FunctorToTypes.map_comp_apply, ← FunctorToTypes.map_comp_apply] simp only [← op_comp, w] refine ⟨H.amalgamate t ht, ?_⟩ · apply (Presieve.isSeparated_of_isSheaf _ _ ((isSheaf_iff_isSheaf_of_type J G.val).1 G.cond) _ (Presheaf.imageSieve_mem J f.val s)).ext intro Y g hg rw [← FunctorToTypes.naturality, H.valid_glue ht] exact Presheaf.app_localPreimage f.val s g hg · intro constructor <;> infer_instance end section	variable {F G : Sheaf J A} (f : F ⟶ G) [(forget A).ReflectsIsomorphisms] [J.HasSheafCompose (forget A)] lemma isLocallyBijective_iff_isIso : IsLocallyInjective f ∧ IsLocallySurjective f ↔ IsIso f := by constructor · rintro ⟨_, _⟩ rw [← isIso_iff_of_reflects_iso f (sheafCompose J (forget A)), ← isLocallyBijective_iff_isIso']	Mathlib/CategoryTheory/Sites/LocallyBijective.lean	78	86
/- 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] @[simp] theorem emptyOn_dual_eq : (emptyOn α)✶ = emptyOn α := by rw [← ground_eq_empty_iff]; rfl @[simp] theorem restrict_empty (M : Matroid α) : M ↾ (∅ : Set α) = emptyOn α := by simp [← ground_eq_empty_iff] theorem eq_emptyOn_or_nonempty (M : Matroid α) : M = emptyOn α ∨ Matroid.Nonempty M := by rw [← ground_eq_empty_iff] exact M.E.eq_empty_or_nonempty.elim Or.inl (fun h ↦ Or.inr ⟨h⟩) theorem eq_emptyOn [IsEmpty α] (M : Matroid α) : M = emptyOn α := by rw [← ground_eq_empty_iff] exact M.E.eq_empty_of_isEmpty instance finite_emptyOn (α : Type*) : (emptyOn α).Finite := ⟨finite_empty⟩ end EmptyOn section LoopyOn /-- The `Matroid α` with ground set `E` whose only base is `∅`. The elements are all 'loops' - see `Matroid.IsLoop` and `Matroid.loopyOn_isLoop_iff`. -/ def loopyOn (E : Set α) : Matroid α := emptyOn α ↾ E @[simp] theorem loopyOn_ground (E : Set α) : (loopyOn E).E = E := rfl	@[simp] theorem loopyOn_empty (α : Type*) : loopyOn (∅ : Set α) = emptyOn α := by rw [← ground_eq_empty_iff, loopyOn_ground]	Mathlib/Data/Matroid/Constructions.lean	90	92
/- Copyright (c) 2023 Adam Topaz. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Adam Topaz, Dagur Asgeirsson -/ import Mathlib.Topology.Category.CompHaus.Basic import Mathlib.Topology.Category.CompHausLike.Limits /-! # Explicit limits and colimits This file applies the general API for explicit limits and colimits in `CompHausLike P` (see the file `Mathlib.Topology.Category.CompHausLike.Limits`) to the special case of `CompHaus`. -/ namespace CompHaus universe u w open CategoryTheory Limits CompHausLike instance : HasExplicitPullbacks (fun _ ↦ True) where hasProp _ _ := inferInstance instance : HasExplicitFiniteCoproducts.{w, u} (fun _ ↦ True) where hasProp _ := inferInstance example : FinitaryExtensive CompHaus.{u} := inferInstance /-- A one-element space is terminal in `CompHaus` -/ abbrev isTerminalPUnit : IsTerminal (CompHaus.of PUnit.{u + 1}) := CompHausLike.isTerminalPUnit /-- The isomorphism from an arbitrary terminal object of `CompHaus` to a one-element space. -/ noncomputable def terminalIsoPUnit : ⊤_ CompHaus.{u} ≅ CompHaus.of PUnit := terminalIsTerminal.uniqueUpToIso CompHaus.isTerminalPUnit noncomputable example : PreservesFiniteCoproducts compHausToTop := inferInstance end CompHaus		Mathlib/Topology/Category/CompHaus/Limits.lean	223	227
/- Copyright (c) 2018 Mario Carneiro. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Mario Carneiro, Johannes Hölzl, Sander Dahmen, Kim Morrison -/ import Mathlib.Algebra.Algebra.Tower import Mathlib.LinearAlgebra.LinearIndependent.Basic import Mathlib.Data.Set.Card /-! # Dimension of modules and vector spaces ## Main definitions * The rank of a module is defined as `Module.rank : Cardinal`. This is defined as the supremum of the cardinalities of linearly independent subsets. ## Main statements * `LinearMap.rank_le_of_injective`: the source of an injective linear map has dimension at most that of the target. * `LinearMap.rank_le_of_surjective`: the target of a surjective linear map has dimension at most that of that source. ## Implementation notes Many theorems in this file are not universe-generic when they relate dimensions in different universes. They should be as general as they can be without inserting `lift`s. The types `M`, `M'`, ... all live in different universes, and `M₁`, `M₂`, ... all live in the same universe. -/ noncomputable section universe w w' u u' v v' variable {R : Type u} {R' : Type u'} {M M₁ : Type v} {M' : Type v'} open Cardinal Submodule Function Set section Module section variable [Semiring R] [AddCommMonoid M] [Module R M] variable (R M) /-- The rank of a module, defined as a term of type `Cardinal`. We define this as the supremum of the cardinalities of linearly independent subsets. The supremum may not be attained, see https://mathoverflow.net/a/263053. For a free module over any ring satisfying the strong rank condition (e.g. left-noetherian rings, commutative rings, and in particular division rings and fields), this is the same as the dimension of the space (i.e. the cardinality of any basis). In particular this agrees with the usual notion of the dimension of a vector space. See also `Module.finrank` for a `ℕ`-valued function which returns the correct value for a finite-dimensional vector space (but 0 for an infinite-dimensional vector space). -/ @[stacks 09G3 "first part"] protected irreducible_def Module.rank : Cardinal := ⨆ ι : { s : Set M // LinearIndepOn R id s }, (#ι.1) theorem rank_le_card : Module.rank R M ≤ #M := (Module.rank_def _ _).trans_le (ciSup_le' fun _ ↦ mk_set_le _) lemma nonempty_linearIndependent_set : Nonempty {s : Set M // LinearIndepOn R id s } := ⟨⟨∅, linearIndepOn_empty _ _⟩⟩ end namespace LinearIndependent variable [Semiring R] [AddCommMonoid M] [Module R M] variable [Nontrivial R] theorem cardinal_lift_le_rank {ι : Type w} {v : ι → M} (hv : LinearIndependent R v) : Cardinal.lift.{v} #ι ≤ Cardinal.lift.{w} (Module.rank R M) := by rw [Module.rank] refine le_trans ?_ (lift_le.mpr <\| le_ciSup (bddAbove_range _) ⟨_, hv.linearIndepOn_id⟩) exact lift_mk_le'.mpr ⟨(Equiv.ofInjective _ hv.injective).toEmbedding⟩ lemma aleph0_le_rank {ι : Type w} [Infinite ι] {v : ι → M} (hv : LinearIndependent R v) : ℵ₀ ≤ Module.rank R M := aleph0_le_lift.mp <\| (aleph0_le_lift.mpr <\| aleph0_le_mk ι).trans hv.cardinal_lift_le_rank theorem cardinal_le_rank {ι : Type v} {v : ι → M} (hv : LinearIndependent R v) : #ι ≤ Module.rank R M := by simpa using hv.cardinal_lift_le_rank theorem cardinal_le_rank' {s : Set M} (hs : LinearIndependent R (fun x => x : s → M)) : #s ≤ Module.rank R M := hs.cardinal_le_rank theorem _root_.LinearIndepOn.encard_le_toENat_rank {ι : Type} {v : ι → M} {s : Set ι} (hs : LinearIndepOn R v s) : s.encard ≤ (Module.rank R M).toENat := by simpa using OrderHom.mono (β := ℕ∞) Cardinal.toENat hs.linearIndependent.cardinal_lift_le_rank end LinearIndependent section SurjectiveInjective section Semiring variable [Semiring R] [AddCommMonoid M] [Module R M] [Semiring R'] section variable [AddCommMonoid M'] [Module R' M'] /-- If `M / R` and `M' / R'` are modules, `i : R' → R` is an injective map non-zero elements, `j : M →+ M'` is an injective monoid homomorphism, such that the scalar multiplications on `M` and `M'` are compatible, then the rank of `M / R` is smaller than or equal to the rank of `M' / R'`. As a special case, taking `R = R'` it is `LinearMap.lift_rank_le_of_injective`. -/ theorem lift_rank_le_of_injective_injectiveₛ (i : R' → R) (j : M →+ M') (hi : Injective i) (hj : Injective j) (hc : ∀ (r : R') (m : M), j (i r • m) = r • j m) : lift.{v'} (Module.rank R M) ≤ lift.{v} (Module.rank R' M') := by simp_rw [Module.rank, lift_iSup (bddAbove_range _)] exact ciSup_mono' (bddAbove_range _) fun ⟨s, h⟩ ↦ ⟨⟨j '' s, LinearIndepOn.id_image (h.linearIndependent.map_of_injective_injectiveₛ i j hi hj hc)⟩, lift_mk_le'.mpr ⟨(Equiv.Set.image j s hj).toEmbedding⟩⟩ /-- If `M / R` and `M' / R'` are modules, `i : R → R'` is a surjective map, and `j : M →+ M'` is an injective monoid homomorphism, such that the scalar multiplications on `M` and `M'` are compatible, then the rank of `M / R` is smaller than or equal to the rank of `M' / R'`. As a special case, taking `R = R'` it is `LinearMap.lift_rank_le_of_injective`. -/ theorem lift_rank_le_of_surjective_injective (i : R → R') (j : M →+ M') (hi : Surjective i) (hj : Injective j) (hc : ∀ (r : R) (m : M), j (r • m) = i r • j m) : lift.{v'} (Module.rank R M) ≤ lift.{v} (Module.rank R' M') := by obtain ⟨i', hi'⟩ := hi.hasRightInverse refine lift_rank_le_of_injective_injectiveₛ i' j (fun _ _ h ↦ ?_) hj fun r m ↦ ?_ · apply_fun i at h rwa [hi', hi'] at h rw [hc (i' r) m, hi'] /-- If `M / R` and `M' / R'` are modules, `i : R → R'` is a bijective map which maps zero to zero, `j : M ≃+ M'` is a group isomorphism, such that the scalar multiplications on `M` and `M'` are compatible, then the rank of `M / R` is equal to the rank of `M' / R'`. As a special case, taking `R = R'` it is `LinearEquiv.lift_rank_eq`. -/ theorem lift_rank_eq_of_equiv_equiv (i : R → R') (j : M ≃+ M') (hi : Bijective i) (hc : ∀ (r : R) (m : M), j (r • m) = i r • j m) : lift.{v'} (Module.rank R M) = lift.{v} (Module.rank R' M') := (lift_rank_le_of_surjective_injective i j hi.2 j.injective hc).antisymm <\| lift_rank_le_of_injective_injectiveₛ i j.symm hi.1 j.symm.injective fun _ _ ↦ j.symm_apply_eq.2 <\| by erw [hc, j.apply_symm_apply] end section variable [AddCommMonoid M₁] [Module R' M₁] /-- The same-universe version of `lift_rank_le_of_injective_injective`. -/ theorem rank_le_of_injective_injectiveₛ (i : R' → R) (j : M →+ M₁) (hi : Injective i) (hj : Injective j) (hc : ∀ (r : R') (m : M), j (i r • m) = r • j m) : Module.rank R M ≤ Module.rank R' M₁ := by simpa only [lift_id] using lift_rank_le_of_injective_injectiveₛ i j hi hj hc /-- The same-universe version of `lift_rank_le_of_surjective_injective`. -/ theorem rank_le_of_surjective_injective (i : R → R') (j : M →+ M₁) (hi : Surjective i) (hj : Injective j) (hc : ∀ (r : R) (m : M), j (r • m) = i r • j m) : Module.rank R M ≤ Module.rank R' M₁ := by simpa only [lift_id] using lift_rank_le_of_surjective_injective i j hi hj hc /-- The same-universe version of `lift_rank_eq_of_equiv_equiv`. -/ theorem rank_eq_of_equiv_equiv (i : R → R') (j : M ≃+ M₁) (hi : Bijective i) (hc : ∀ (r : R) (m : M), j (r • m) = i r • j m) : Module.rank R M = Module.rank R' M₁ := by simpa only [lift_id] using lift_rank_eq_of_equiv_equiv i j hi hc end end Semiring section Ring variable [Ring R] [AddCommGroup M] [Module R M] [Ring R'] /-- If `M / R` and `M' / R'` are modules, `i : R' → R` is a map which sends non-zero elements to non-zero elements, `j : M →+ M'` is an injective group homomorphism, such that the scalar multiplications on `M` and `M'` are compatible, then the rank of `M / R` is smaller than or equal to the rank of `M' / R'`. As a special case, taking `R = R'` it is `LinearMap.lift_rank_le_of_injective`. -/ theorem lift_rank_le_of_injective_injective [AddCommGroup M'] [Module R' M'] (i : R' → R) (j : M →+ M') (hi : ∀ r, i r = 0 → r = 0) (hj : Injective j) (hc : ∀ (r : R') (m : M), j (i r • m) = r • j m) : lift.{v'} (Module.rank R M) ≤ lift.{v} (Module.rank R' M') := by simp_rw [Module.rank, lift_iSup (bddAbove_range _)] exact ciSup_mono' (bddAbove_range _) fun ⟨s, h⟩ ↦ ⟨⟨j '' s, LinearIndepOn.id_image <\| h.linearIndependent.map_of_injective_injective i j hi (fun _ _ ↦ hj <\| by rwa [j.map_zero]) hc⟩, lift_mk_le'.mpr ⟨(Equiv.Set.image j s hj).toEmbedding⟩⟩ /-- The same-universe version of `lift_rank_le_of_injective_injective`. -/ theorem rank_le_of_injective_injective [AddCommGroup M₁] [Module R' M₁] (i : R' → R) (j : M →+ M₁) (hi : ∀ r, i r = 0 → r = 0) (hj : Injective j) (hc : ∀ (r : R') (m : M), j (i r • m) = r • j m) : Module.rank R M ≤ Module.rank R' M₁ := by simpa only [lift_id] using lift_rank_le_of_injective_injective i j hi hj hc end Ring namespace Algebra variable {R : Type w} {S : Type v} [CommSemiring R] [Semiring S] [Algebra R S] {R' : Type w'} {S' : Type v'} [CommSemiring R'] [Semiring S'] [Algebra R' S'] /-- If `S / R` and `S' / R'` are algebras, `i : R' →+ R` and `j : S →+* S'` are injective ring homomorphisms, such that `R' → R → S → S'` and `R' → S'` commute, then the rank of `S / R` is smaller than or equal to the rank of `S' / R'`. -/ theorem lift_rank_le_of_injective_injective (i : R' →+* R) (j : S →+* S') (hi : Injective i) (hj : Injective j) (hc : (j.comp (algebraMap R S)).comp i = algebraMap R' S') : lift.{v'} (Module.rank R S) ≤ lift.{v} (Module.rank R' S') := by refine _root_.lift_rank_le_of_injective_injectiveₛ i j hi hj fun r _ ↦ ?_ have := congr($hc r) simp only [RingHom.coe_comp, comp_apply] at this simp_rw [smul_def, AddMonoidHom.coe_coe, map_mul, this] /-- If `S / R` and `S' / R'` are algebras, `i : R →+* R'` is a surjective ring homomorphism, `j : S →+* S'` is an injective ring homomorphism, such that `R → R' → S'` and `R → S → S'` commute, then the rank of `S / R` is smaller than or equal to the rank of `S' / R'`. -/ theorem lift_rank_le_of_surjective_injective (i : R →+* R') (j : S →+* S') (hi : Surjective i) (hj : Injective j) (hc : (algebraMap R' S').comp i = j.comp (algebraMap R S)) : lift.{v'} (Module.rank R S) ≤ lift.{v} (Module.rank R' S') := by refine _root_.lift_rank_le_of_surjective_injective i j hi hj fun r _ ↦ ?_ have := congr($hc r) simp only [RingHom.coe_comp, comp_apply] at this simp only [smul_def, AddMonoidHom.coe_coe, map_mul, ZeroHom.coe_coe, this] /-- If `S / R` and `S' / R'` are algebras, `i : R ≃+* R'` and `j : S ≃+* S'` are ring isomorphisms, such that `R → R' → S'` and `R → S → S'` commute, then the rank of `S / R` is equal to the rank of `S' / R'`. -/ theorem lift_rank_eq_of_equiv_equiv (i : R ≃+* R') (j : S ≃+* S') (hc : (algebraMap R' S').comp i.toRingHom = j.toRingHom.comp (algebraMap R S)) : lift.{v'} (Module.rank R S) = lift.{v} (Module.rank R' S') := by refine _root_.lift_rank_eq_of_equiv_equiv i j i.bijective fun r _ ↦ ?_ have := congr($hc r) simp only [RingEquiv.toRingHom_eq_coe, RingHom.coe_comp, RingHom.coe_coe, comp_apply] at this simp only [smul_def, RingEquiv.coe_toAddEquiv, map_mul, ZeroHom.coe_coe, this] variable {S' : Type v} [Semiring S'] [Algebra R' S'] /-- The same-universe version of `Algebra.lift_rank_le_of_injective_injective`. -/ theorem rank_le_of_injective_injective (i : R' →+* R) (j : S →+* S') (hi : Injective i) (hj : Injective j) (hc : (j.comp (algebraMap R S)).comp i = algebraMap R' S') : Module.rank R S ≤ Module.rank R' S' := by simpa only [lift_id] using lift_rank_le_of_injective_injective i j hi hj hc /-- The same-universe version of `Algebra.lift_rank_le_of_surjective_injective`. -/ theorem rank_le_of_surjective_injective (i : R →+* R') (j : S →+* S') (hi : Surjective i) (hj : Injective j) (hc : (algebraMap R' S').comp i = j.comp (algebraMap R S)) : Module.rank R S ≤ Module.rank R' S' := by simpa only [lift_id] using lift_rank_le_of_surjective_injective i j hi hj hc /-- The same-universe version of `Algebra.lift_rank_eq_of_equiv_equiv`. -/ theorem rank_eq_of_equiv_equiv (i : R ≃+* R') (j : S ≃+* S') (hc : (algebraMap R' S').comp i.toRingHom = j.toRingHom.comp (algebraMap R S)) : Module.rank R S = Module.rank R' S' := by simpa only [lift_id] using lift_rank_eq_of_equiv_equiv i j hc end Algebra end SurjectiveInjective variable [Semiring R] [AddCommMonoid M] [Module R M] [Semiring R'] [AddCommMonoid M'] [AddCommMonoid M₁] [Module R M'] [Module R M₁] [Module R' M'] [Module R' M₁]	section	Mathlib/LinearAlgebra/Dimension/Basic.lean	274	275
/- Copyright (c) 2022 Siddhartha Prasad, Yaël Dillies. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Siddhartha Prasad, Yaël Dillies -/ import Mathlib.Algebra.Order.Monoid.Canonical.Defs import Mathlib.Algebra.Ring.InjSurj import Mathlib.Algebra.Ring.Pi import Mathlib.Algebra.Ring.Prod import Mathlib.Tactic.Monotonicity.Attr /-! # Kleene Algebras This file defines idempotent semirings and Kleene algebras, which are used extensively in the theory of computation. An idempotent semiring is a semiring whose addition is idempotent. An idempotent semiring is naturally a semilattice by setting `a ≤ b` if `a + b = b`. A Kleene algebra is an idempotent semiring equipped with an additional unary operator `∗`, the Kleene star. ## Main declarations * `IdemSemiring`: Idempotent semiring * `IdemCommSemiring`: Idempotent commutative semiring * `KleeneAlgebra`: Kleene algebra ## Notation `a∗` is notation for `kstar a` in locale `Computability`. ## References * [D. Kozen, A completeness theorem for Kleene algebras and the algebra of regular events] [kozen1994] * https://planetmath.org/idempotentsemiring * https://encyclopediaofmath.org/wiki/Idempotent_semi-ring * https://planetmath.org/kleene_algebra ## TODO Instances for `AddOpposite`, `MulOpposite`, `ULift`, `Subsemiring`, `Subring`, `Subalgebra`. ## Tags kleene algebra, idempotent semiring -/ open Function universe u variable {α β ι : Type} {π : ι → Type} /-- An idempotent semiring is a semiring with the additional property that addition is idempotent. -/ class IdemSemiring (α : Type u) extends Semiring α, SemilatticeSup α where protected sup := (· + ·) protected add_eq_sup : ∀ a b : α, a + b = a ⊔ b := by intros rfl /-- The bottom element of an idempotent semiring: `0` by default -/ protected bot : α := 0 protected bot_le : ∀ a, bot ≤ a /-- An idempotent commutative semiring is a commutative semiring with the additional property that addition is idempotent. -/ class IdemCommSemiring (α : Type u) extends CommSemiring α, IdemSemiring α /-- Notation typeclass for the Kleene star `∗`. -/ class KStar (α : Type) where /-- The Kleene star operator on a Kleene algebra -/ protected kstar : α → α @[inherit_doc] scoped[Computability] postfix:1024 "∗" => KStar.kstar open Computability /-- A Kleene Algebra is an idempotent semiring with an additional unary operator `kstar` (for Kleene star) that satisfies the following properties: `1 + a * a∗ ≤ a∗` * `1 + a∗ * a ≤ a∗` * If `a * c + b ≤ c`, then `a∗ * b ≤ c` * If `c * a + b ≤ c`, then `b * a∗ ≤ c` -/ class KleeneAlgebra (α : Type) extends IdemSemiring α, KStar α where protected one_le_kstar : ∀ a : α, 1 ≤ a∗ protected mul_kstar_le_kstar : ∀ a : α, a a∗ ≤ a∗ protected kstar_mul_le_kstar : ∀ a : α, a∗ * a ≤ a∗ protected mul_kstar_le_self : ∀ a b : α, b * a ≤ b → b * a∗ ≤ b protected kstar_mul_le_self : ∀ a b : α, a * b ≤ b → a∗ * b ≤ b -- See note [lower instance priority] instance (priority := 100) IdemSemiring.toOrderBot [IdemSemiring α] : OrderBot α := { ‹IdemSemiring α› with } -- See note [reducible non-instances] /-- Construct an idempotent semiring from an idempotent addition. -/ abbrev IdemSemiring.ofSemiring [Semiring α] (h : ∀ a : α, a + a = a) : IdemSemiring α := { ‹Semiring α› with le := fun a b ↦ a + b = b le_refl := h le_trans := fun a b c hab hbc ↦ by rw [← hbc, ← add_assoc, hab] le_antisymm := fun a b hab hba ↦ by rwa [← hba, add_comm] sup := (· + ·) le_sup_left := fun a b ↦ by rw [← add_assoc, h] le_sup_right := fun a b ↦ by rw [add_comm, add_assoc, h] sup_le := fun a b c hab hbc ↦ by rwa [add_assoc, hbc] bot := 0 bot_le := zero_add } section IdemSemiring variable [IdemSemiring α] {a b c : α} theorem add_eq_sup (a b : α) : a + b = a ⊔ b := IdemSemiring.add_eq_sup _ _ scoped[Computability] attribute [simp] add_eq_sup theorem add_idem (a : α) : a + a = a := by simp lemma natCast_eq_one {n : ℕ} (nezero : n ≠ 0) : (n : α) = 1 := by rw [← Nat.one_le_iff_ne_zero] at nezero induction n, nezero using Nat.le_induction with \| base => exact Nat.cast_one \| succ x _ hx => rw [Nat.cast_add, hx, Nat.cast_one, add_idem 1] lemma ofNat_eq_one {n : ℕ} [n.AtLeastTwo] : (ofNat(n) : α) = 1 := natCast_eq_one <\| Nat.ne_zero_of_lt Nat.AtLeastTwo.prop theorem nsmul_eq_self : ∀ {n : ℕ} (_ : n ≠ 0) (a : α), n • a = a \| 0, h => (h rfl).elim \| 1, _ => one_nsmul \| n + 2, _ => fun a ↦ by rw [succ_nsmul, nsmul_eq_self n.succ_ne_zero, add_idem] theorem add_eq_left_iff_le : a + b = a ↔ b ≤ a := by simp	theorem add_eq_right_iff_le : a + b = b ↔ a ≤ b := by simp alias ⟨_, LE.le.add_eq_left⟩ := add_eq_left_iff_le	Mathlib/Algebra/Order/Kleene.lean	145	148
/- Copyright (c) 2024 Rémy Degenne. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Rémy Degenne -/ import Mathlib.Probability.Kernel.Composition.MapComap import Mathlib.Probability.Martingale.Convergence import Mathlib.Probability.Process.PartitionFiltration /-! # Kernel density Let `κ : Kernel α (γ × β)` and `ν : Kernel α γ` be two finite kernels with `Kernel.fst κ ≤ ν`, where `γ` has a countably generated σ-algebra (true in particular for standard Borel spaces). We build a function `density κ ν : α → γ → Set β → ℝ` jointly measurable in the first two arguments such that for all `a : α` and all measurable sets `s : Set β` and `A : Set γ`, `∫ x in A, density κ ν a x s ∂(ν a) = (κ a).real (A ×ˢ s)`. There are two main applications of this construction. * Disintegration of kernels: for `κ : Kernel α (γ × β)`, we want to build a kernel `η : Kernel (α × γ) β` such that `κ = fst κ ⊗ₖ η`. For `β = ℝ`, we can use the density of `κ` with respect to `fst κ` for intervals to build a kernel cumulative distribution function for `η`. The construction can then be extended to `β` standard Borel. * Radon-Nikodym theorem for kernels: for `κ ν : Kernel α γ`, we can use the density to build a Radon-Nikodym derivative of `κ` with respect to `ν`. We don't need `β` here but we can apply the density construction to `β = Unit`. The derivative construction will use `density` but will not be exactly equal to it because we will want to remove the `fst κ ≤ ν` assumption. ## Main definitions * `ProbabilityTheory.Kernel.density`: for `κ : Kernel α (γ × β)` and `ν : Kernel α γ` two finite kernels, `Kernel.density κ ν` is a function `α → γ → Set β → ℝ`. ## Main statements * `ProbabilityTheory.Kernel.setIntegral_density`: for all measurable sets `A : Set γ` and `s : Set β`, `∫ x in A, Kernel.density κ ν a x s ∂(ν a) = (κ a).real (A ×ˢ s)`. * `ProbabilityTheory.Kernel.measurable_density`: the function `p : α × γ ↦ Kernel.density κ ν p.1 p.2 s` is measurable. ## Construction of the density If we were interested only in a fixed `a : α`, then we could use the Radon-Nikodym derivative to build the density function `density κ ν`, as follows. ``` def density' (κ : Kernel α (γ × β)) (ν : kernel a γ) (a : α) (x : γ) (s : Set β) : ℝ := (((κ a).restrict (univ ×ˢ s)).fst.rnDeriv (ν a) x).toReal ``` However, we can't turn those functions for each `a` into a measurable function of the pair `(a, x)`. In order to obtain measurability through countability, we use the fact that the measurable space `γ` is countably generated. For each `n : ℕ`, we define (in the file `Mathlib.Probability.Process.PartitionFiltration`) a finite partition of `γ`, such that those partitions are finer as `n` grows, and the σ-algebra generated by the union of all partitions is the σ-algebra of `γ`. For `x : γ`, `countablePartitionSet n x` denotes the set in the partition such that `x ∈ countablePartitionSet n x`. For a given `n`, the function `densityProcess κ ν n : α → γ → Set β → ℝ` defined by `fun a x s ↦ (κ a (countablePartitionSet n x ×ˢ s) / ν a (countablePartitionSet n x)).toReal` has the desired property that `∫ x in A, densityProcess κ ν n a x s ∂(ν a) = (κ a (A ×ˢ s)).toReal` for all `A` in the σ-algebra generated by the partition at scale `n` and is measurable in `(a, x)`. `countableFiltration γ` is the filtration of those σ-algebras for all `n : ℕ`. The functions `densityProcess κ ν n` described here are a bounded `ν`-martingale for the filtration `countableFiltration γ`. By Doob's martingale L1 convergence theorem, that martingale converges to a limit, which has a product-measurable version and satisfies the integral equality for all `A` in `⨆ n, countableFiltration γ n`. Finally, the partitions were chosen such that that supremum is equal to the σ-algebra on `γ`, hence the equality holds for all measurable sets. We have obtained the desired density function. ## References The construction of the density process in this file follows the proof of Theorem 9.27 in [O. Kallenberg, Foundations of modern probability][kallenberg2021], adapted to use a countably generated hypothesis instead of specializing to `ℝ`. -/ open MeasureTheory Set Filter MeasurableSpace open scoped NNReal ENNReal MeasureTheory Topology ProbabilityTheory namespace ProbabilityTheory.Kernel variable {α β γ : Type*} {mα : MeasurableSpace α} {mβ : MeasurableSpace β} {mγ : MeasurableSpace γ} [CountablyGenerated γ] {κ : Kernel α (γ × β)} {ν : Kernel α γ} section DensityProcess /-- An `ℕ`-indexed martingale that is a density for `κ` with respect to `ν` on the sets in `countablePartition γ n`. Used to define its limit `ProbabilityTheory.Kernel.density`, which is a density for those kernels for all measurable sets. -/ noncomputable def densityProcess (κ : Kernel α (γ × β)) (ν : Kernel α γ) (n : ℕ) (a : α) (x : γ) (s : Set β) : ℝ := (κ a (countablePartitionSet n x ×ˢ s) / ν a (countablePartitionSet n x)).toReal lemma densityProcess_def (κ : Kernel α (γ × β)) (ν : Kernel α γ) (n : ℕ) (a : α) (s : Set β) : (fun t ↦ densityProcess κ ν n a t s) = fun t ↦ (κ a (countablePartitionSet n t ×ˢ s) / ν a (countablePartitionSet n t)).toReal := rfl lemma measurable_densityProcess_countableFiltration_aux (κ : Kernel α (γ × β)) (ν : Kernel α γ) (n : ℕ) {s : Set β} (hs : MeasurableSet s) : Measurable[mα.prod (countableFiltration γ n)] (fun (p : α × γ) ↦ κ p.1 (countablePartitionSet n p.2 ×ˢ s) / ν p.1 (countablePartitionSet n p.2)) := by change Measurable[mα.prod (countableFiltration γ n)] ((fun (p : α × countablePartition γ n) ↦ κ p.1 (↑p.2 ×ˢ s) / ν p.1 p.2) ∘ (fun (p : α × γ) ↦ (p.1, ⟨countablePartitionSet n p.2, countablePartitionSet_mem n p.2⟩))) have h1 : @Measurable _ _ (mα.prod ⊤) _ (fun p : α × countablePartition γ n ↦ κ p.1 (↑p.2 ×ˢ s) / ν p.1 p.2) := by refine Measurable.div ?_ ?_ · refine measurable_from_prod_countable (fun t ↦ ?_) exact Kernel.measurable_coe _ ((measurableSet_countablePartition _ t.prop).prod hs) · refine measurable_from_prod_countable ?_ rintro ⟨t, ht⟩ exact Kernel.measurable_coe _ (measurableSet_countablePartition _ ht) refine h1.comp (measurable_fst.prodMk ?_) change @Measurable (α × γ) (countablePartition γ n) (mα.prod (countableFiltration γ n)) ⊤ ((fun c ↦ ⟨countablePartitionSet n c, countablePartitionSet_mem n c⟩) ∘ (fun p : α × γ ↦ p.2)) exact (measurable_countablePartitionSet_subtype n ⊤).comp measurable_snd lemma measurable_densityProcess_aux (κ : Kernel α (γ × β)) (ν : Kernel α γ) (n : ℕ) {s : Set β} (hs : MeasurableSet s) : Measurable (fun (p : α × γ) ↦ κ p.1 (countablePartitionSet n p.2 ×ˢ s) / ν p.1 (countablePartitionSet n p.2)) := by refine Measurable.mono (measurable_densityProcess_countableFiltration_aux κ ν n hs) ?_ le_rfl exact sup_le_sup le_rfl (comap_mono ((countableFiltration γ).le _)) lemma measurable_densityProcess (κ : Kernel α (γ × β)) (ν : Kernel α γ) (n : ℕ) {s : Set β} (hs : MeasurableSet s) : Measurable (fun (p : α × γ) ↦ densityProcess κ ν n p.1 p.2 s) := (measurable_densityProcess_aux κ ν n hs).ennreal_toReal -- The following two lemmas also work without the `( :)`, but they are slow. lemma measurable_densityProcess_left (κ : Kernel α (γ × β)) (ν : Kernel α γ) (n : ℕ) (x : γ) {s : Set β} (hs : MeasurableSet s) : Measurable (fun a ↦ densityProcess κ ν n a x s) := ((measurable_densityProcess κ ν n hs).comp (measurable_id.prodMk measurable_const):) lemma measurable_densityProcess_right (κ : Kernel α (γ × β)) (ν : Kernel α γ) (n : ℕ) {s : Set β} (a : α) (hs : MeasurableSet s) : Measurable (fun x ↦ densityProcess κ ν n a x s) := ((measurable_densityProcess κ ν n hs).comp (measurable_const.prodMk measurable_id):) lemma measurable_countableFiltration_densityProcess (κ : Kernel α (γ × β)) (ν : Kernel α γ) (n : ℕ) (a : α) {s : Set β} (hs : MeasurableSet s) : Measurable[countableFiltration γ n] (fun x ↦ densityProcess κ ν n a x s) := by refine @Measurable.ennreal_toReal _ (countableFiltration γ n) _ ?_ exact (measurable_densityProcess_countableFiltration_aux κ ν n hs).comp measurable_prodMk_left lemma stronglyMeasurable_countableFiltration_densityProcess (κ : Kernel α (γ × β)) (ν : Kernel α γ) (n : ℕ) (a : α) {s : Set β} (hs : MeasurableSet s) : StronglyMeasurable[countableFiltration γ n] (fun x ↦ densityProcess κ ν n a x s) := (measurable_countableFiltration_densityProcess κ ν n a hs).stronglyMeasurable lemma adapted_densityProcess (κ : Kernel α (γ × β)) (ν : Kernel α γ) (a : α) {s : Set β} (hs : MeasurableSet s) : Adapted (countableFiltration γ) (fun n x ↦ densityProcess κ ν n a x s) := fun n ↦ stronglyMeasurable_countableFiltration_densityProcess κ ν n a hs lemma densityProcess_nonneg (κ : Kernel α (γ × β)) (ν : Kernel α γ) (n : ℕ) (a : α) (x : γ) (s : Set β) : 0 ≤ densityProcess κ ν n a x s := ENNReal.toReal_nonneg lemma meas_countablePartitionSet_le_of_fst_le (hκν : fst κ ≤ ν) (n : ℕ) (a : α) (x : γ) (s : Set β) : κ a (countablePartitionSet n x ×ˢ s) ≤ ν a (countablePartitionSet n x) := by calc κ a (countablePartitionSet n x ×ˢ s) ≤ fst κ a (countablePartitionSet n x) := by rw [fst_apply' _ _ (measurableSet_countablePartitionSet _ _)] refine measure_mono (fun x ↦ ?_) simp only [mem_prod, mem_setOf_eq, and_imp] exact fun h _ ↦ h _ ≤ ν a (countablePartitionSet n x) := hκν a _ lemma densityProcess_le_one (hκν : fst κ ≤ ν) (n : ℕ) (a : α) (x : γ) (s : Set β) : densityProcess κ ν n a x s ≤ 1 := by refine ENNReal.toReal_le_of_le_ofReal zero_le_one (ENNReal.div_le_of_le_mul ?_) rw [ENNReal.ofReal_one, one_mul] exact meas_countablePartitionSet_le_of_fst_le hκν n a x s lemma eLpNorm_densityProcess_le (hκν : fst κ ≤ ν) (n : ℕ) (a : α) (s : Set β) : eLpNorm (fun x ↦ densityProcess κ ν n a x s) 1 (ν a) ≤ ν a univ := by refine (eLpNorm_le_of_ae_bound (C := 1) (ae_of_all _ (fun x ↦ ?_))).trans ?_ · simp only [Real.norm_eq_abs, abs_of_nonneg (densityProcess_nonneg κ ν n a x s), densityProcess_le_one hκν n a x s] · simp lemma integrable_densityProcess (hκν : fst κ ≤ ν) [IsFiniteKernel ν] (n : ℕ) (a : α) {s : Set β} (hs : MeasurableSet s) : Integrable (fun x ↦ densityProcess κ ν n a x s) (ν a) := by rw [← memLp_one_iff_integrable] refine ⟨Measurable.aestronglyMeasurable ?_, ?_⟩ · exact measurable_densityProcess_right κ ν n a hs · exact (eLpNorm_densityProcess_le hκν n a s).trans_lt (measure_lt_top _ _) lemma setIntegral_densityProcess_of_mem (hκν : fst κ ≤ ν) [hν : IsFiniteKernel ν] (n : ℕ) (a : α) {s : Set β} (hs : MeasurableSet s) {u : Set γ} (hu : u ∈ countablePartition γ n) : ∫ x in u, densityProcess κ ν n a x s ∂(ν a) = (κ a).real (u ×ˢ s) := by have : IsFiniteKernel κ := isFiniteKernel_of_isFiniteKernel_fst (h := isFiniteKernel_of_le hκν) have hu_meas : MeasurableSet u := measurableSet_countablePartition n hu simp_rw [densityProcess] rw [integral_toReal] rotate_left · refine Measurable.aemeasurable ?_ change Measurable ((fun (p : α × _) ↦ κ p.1 (countablePartitionSet n p.2 ×ˢ s) / ν p.1 (countablePartitionSet n p.2)) ∘ (fun x ↦ (a, x))) exact (measurable_densityProcess_aux κ ν n hs).comp measurable_prodMk_left · refine ae_of_all _ (fun x ↦ ?_) by_cases h0 : ν a (countablePartitionSet n x) = 0 · suffices κ a (countablePartitionSet n x ×ˢ s) = 0 by simp [h0, this] have h0' : fst κ a (countablePartitionSet n x) = 0 := le_antisymm ((hκν a _).trans h0.le) zero_le' rw [fst_apply' _ _ (measurableSet_countablePartitionSet _ _)] at h0' refine measure_mono_null (fun x ↦ ?_) h0' simp only [mem_prod, mem_setOf_eq, and_imp] exact fun h _ ↦ h · exact ENNReal.div_lt_top (measure_ne_top _ _) h0 congr have : ∫⁻ x in u, κ a (countablePartitionSet n x ×ˢ s) / ν a (countablePartitionSet n x) ∂(ν a) = ∫⁻ _ in u, κ a (u ×ˢ s) / ν a u ∂(ν a) := by refine setLIntegral_congr_fun hu_meas (ae_of_all _ (fun t ht ↦ ?_)) rw [countablePartitionSet_of_mem hu ht] rw [this] simp only [MeasureTheory.lintegral_const, MeasurableSet.univ, Measure.restrict_apply, univ_inter] by_cases h0 : ν a u = 0 · simp only [h0, mul_zero] have h0' : fst κ a u = 0 := le_antisymm ((hκν a _).trans h0.le) zero_le' rw [fst_apply' _ _ hu_meas] at h0' refine (measure_mono_null ?_ h0').symm intro p simp only [mem_prod, mem_setOf_eq, and_imp] exact fun h _ ↦ h rw [div_eq_mul_inv, mul_assoc, ENNReal.inv_mul_cancel h0, mul_one] exact measure_ne_top _ _ open scoped Function in -- required for scoped `on` notation lemma setIntegral_densityProcess (hκν : fst κ ≤ ν) [IsFiniteKernel ν] (n : ℕ) (a : α) {s : Set β} (hs : MeasurableSet s) {A : Set γ} (hA : MeasurableSet[countableFiltration γ n] A) : ∫ x in A, densityProcess κ ν n a x s ∂(ν a) = (κ a).real (A ×ˢ s) := by have : IsFiniteKernel κ := isFiniteKernel_of_isFiniteKernel_fst (h := isFiniteKernel_of_le hκν) obtain ⟨S, hS_subset, rfl⟩ := (measurableSet_generateFrom_countablePartition_iff _ _).mp hA simp_rw [sUnion_eq_iUnion] have h_disj : Pairwise (Disjoint on fun i : S ↦ (i : Set γ)) := by intro u v huv #adaptation_note /-- nightly-2024-03-16 Previously `Function.onFun` unfolded in the following `simp only`, but now needs a `rw`. This may be a bug: a no import minimization may be required. simp only [Finset.coe_sort_coe, Function.onFun] -/ rw [Function.onFun] refine disjoint_countablePartition (hS_subset (by simp)) (hS_subset (by simp)) ?_ rwa [ne_eq, ← Subtype.ext_iff] rw [integral_iUnion, iUnion_prod_const, measureReal_def, measure_iUnion, ENNReal.tsum_toReal_eq (fun _ ↦ measure_ne_top _ _)] · congr with u rw [setIntegral_densityProcess_of_mem hκν _ _ hs (hS_subset (by simp))] rfl · intro u v huv simp only [Finset.coe_sort_coe, Set.disjoint_prod, disjoint_self, bot_eq_empty] exact Or.inl (h_disj huv) · exact fun _ ↦ (measurableSet_countablePartition n (hS_subset (by simp))).prod hs · exact fun _ ↦ measurableSet_countablePartition n (hS_subset (by simp)) · exact h_disj · exact (integrable_densityProcess hκν _ _ hs).integrableOn lemma integral_densityProcess (hκν : fst κ ≤ ν) [IsFiniteKernel ν] (n : ℕ) (a : α) {s : Set β} (hs : MeasurableSet s) : ∫ x, densityProcess κ ν n a x s ∂(ν a) = (κ a).real (univ ×ˢ s) := by rw [← setIntegral_univ, setIntegral_densityProcess hκν _ _ hs MeasurableSet.univ] lemma setIntegral_densityProcess_of_le (hκν : fst κ ≤ ν) [IsFiniteKernel ν] {n m : ℕ} (hnm : n ≤ m) (a : α) {s : Set β} (hs : MeasurableSet s) {A : Set γ} (hA : MeasurableSet[countableFiltration γ n] A) : ∫ x in A, densityProcess κ ν m a x s ∂(ν a) = (κ a).real (A ×ˢ s) := setIntegral_densityProcess hκν m a hs ((countableFiltration γ).mono hnm A hA) lemma condExp_densityProcess (hκν : fst κ ≤ ν) [IsFiniteKernel ν] {i j : ℕ} (hij : i ≤ j) (a : α) {s : Set β} (hs : MeasurableSet s) : (ν a)[fun x ↦ densityProcess κ ν j a x s \| countableFiltration γ i] =ᵐ[ν a] fun x ↦ densityProcess κ ν i a x s := by refine (ae_eq_condExp_of_forall_setIntegral_eq ?_ ?_ ?_ ?_ ?_).symm · exact integrable_densityProcess hκν j a hs · exact fun _ _ _ ↦ (integrable_densityProcess hκν _ _ hs).integrableOn · intro x hx _ rw [setIntegral_densityProcess hκν i a hs hx, setIntegral_densityProcess_of_le hκν hij a hs hx] · exact StronglyMeasurable.aestronglyMeasurable (stronglyMeasurable_countableFiltration_densityProcess κ ν i a hs) @[deprecated (since := "2025-01-21")] alias condexp_densityProcess := condExp_densityProcess lemma martingale_densityProcess (hκν : fst κ ≤ ν) [IsFiniteKernel ν] (a : α) {s : Set β} (hs : MeasurableSet s) : Martingale (fun n x ↦ densityProcess κ ν n a x s) (countableFiltration γ) (ν a) := ⟨adapted_densityProcess κ ν a hs, fun _ _ h ↦ condExp_densityProcess hκν h a hs⟩ lemma densityProcess_mono_set (hκν : fst κ ≤ ν) (n : ℕ) (a : α) (x : γ) {s s' : Set β} (h : s ⊆ s') : densityProcess κ ν n a x s ≤ densityProcess κ ν n a x s' := by unfold densityProcess obtain h₀ \| h₀ := eq_or_ne (ν a (countablePartitionSet n x)) 0 · simp [h₀] · gcongr simp only [ne_eq, ENNReal.div_eq_top, h₀, and_false, false_or, not_and, not_not] exact eq_top_mono (meas_countablePartitionSet_le_of_fst_le hκν n a x s') lemma densityProcess_mono_kernel_left {κ' : Kernel α (γ × β)} (hκκ' : κ ≤ κ') (hκ'ν : fst κ' ≤ ν) (n : ℕ) (a : α) (x : γ) (s : Set β) : densityProcess κ ν n a x s ≤ densityProcess κ' ν n a x s := by unfold densityProcess by_cases h0 : ν a (countablePartitionSet n x) = 0 · rw [h0, ENNReal.toReal_div, ENNReal.toReal_div] simp have h_le : κ' a (countablePartitionSet n x ×ˢ s) ≤ ν a (countablePartitionSet n x) := meas_countablePartitionSet_le_of_fst_le hκ'ν n a x s gcongr · simp only [ne_eq, ENNReal.div_eq_top, h0, and_false, false_or, not_and, not_not] exact fun h_top ↦ eq_top_mono h_le h_top · apply hκκ' lemma densityProcess_antitone_kernel_right {ν' : Kernel α γ} (hνν' : ν ≤ ν') (hκν : fst κ ≤ ν) (n : ℕ) (a : α) (x : γ) (s : Set β) : densityProcess κ ν' n a x s ≤ densityProcess κ ν n a x s := by unfold densityProcess have h_le : κ a (countablePartitionSet n x ×ˢ s) ≤ ν a (countablePartitionSet n x) := meas_countablePartitionSet_le_of_fst_le hκν n a x s by_cases h0 : ν a (countablePartitionSet n x) = 0 · simp [le_antisymm (h_le.trans h0.le) zero_le', h0] gcongr · simp only [ne_eq, ENNReal.div_eq_top, h0, and_false, false_or, not_and, not_not] exact fun h_top ↦ eq_top_mono h_le h_top · apply hνν' @[simp] lemma densityProcess_empty (κ : Kernel α (γ × β)) (ν : Kernel α γ) (n : ℕ) (a : α) (x : γ) : densityProcess κ ν n a x ∅ = 0 := by simp [densityProcess] lemma tendsto_densityProcess_atTop_empty_of_antitone (κ : Kernel α (γ × β)) (ν : Kernel α γ) [IsFiniteKernel κ] (n : ℕ) (a : α) (x : γ) (seq : ℕ → Set β) (hseq : Antitone seq) (hseq_iInter : ⋂ i, seq i = ∅) (hseq_meas : ∀ m, MeasurableSet (seq m)) : Tendsto (fun m ↦ densityProcess κ ν n a x (seq m)) atTop (𝓝 (densityProcess κ ν n a x ∅)) := by simp_rw [densityProcess] by_cases h0 : ν a (countablePartitionSet n x) = 0 · simp_rw [h0, ENNReal.toReal_div] simp refine (ENNReal.tendsto_toReal ?_).comp ?_ · rw [ne_eq, ENNReal.div_eq_top] push_neg simp refine ENNReal.Tendsto.div_const ?_ (.inr h0) have : Tendsto (fun m ↦ κ a (countablePartitionSet n x ×ˢ seq m)) atTop (𝓝 ((κ a) (⋂ n_1, countablePartitionSet n x ×ˢ seq n_1))) := by apply tendsto_measure_iInter_atTop · measurability · exact fun _ _ h ↦ prod_mono_right <\| hseq h · exact ⟨0, measure_ne_top _ _⟩ simpa only [← prod_iInter, hseq_iInter] using this lemma tendsto_densityProcess_atTop_of_antitone (κ : Kernel α (γ × β)) (ν : Kernel α γ) [IsFiniteKernel κ] (n : ℕ) (a : α) (x : γ) (seq : ℕ → Set β) (hseq : Antitone seq) (hseq_iInter : ⋂ i, seq i = ∅) (hseq_meas : ∀ m, MeasurableSet (seq m)) : Tendsto (fun m ↦ densityProcess κ ν n a x (seq m)) atTop (𝓝 0) := by rw [← densityProcess_empty κ ν n a x] exact tendsto_densityProcess_atTop_empty_of_antitone κ ν n a x seq hseq hseq_iInter hseq_meas lemma tendsto_densityProcess_limitProcess (hκν : fst κ ≤ ν) [IsFiniteKernel ν] (a : α) {s : Set β} (hs : MeasurableSet s) : ∀ᵐ x ∂(ν a), Tendsto (fun n ↦ densityProcess κ ν n a x s) atTop (𝓝 ((countableFiltration γ).limitProcess (fun n x ↦ densityProcess κ ν n a x s) (ν a) x)) := by refine Submartingale.ae_tendsto_limitProcess (martingale_densityProcess hκν a hs).submartingale (R := (ν a univ).toNNReal) (fun n ↦ ?_) refine (eLpNorm_densityProcess_le hκν n a s).trans_eq ?_ rw [ENNReal.coe_toNNReal] exact measure_ne_top _ _ lemma memL1_limitProcess_densityProcess (hκν : fst κ ≤ ν) [IsFiniteKernel ν] (a : α) {s : Set β} (hs : MeasurableSet s) : MemLp ((countableFiltration γ).limitProcess (fun n x ↦ densityProcess κ ν n a x s) (ν a)) 1 (ν a) := by refine Submartingale.memLp_limitProcess (martingale_densityProcess hκν a hs).submartingale (R := (ν a univ).toNNReal) (fun n ↦ ?_) refine (eLpNorm_densityProcess_le hκν n a s).trans_eq ?_ rw [ENNReal.coe_toNNReal] exact measure_ne_top _ _ lemma tendsto_eLpNorm_one_densityProcess_limitProcess (hκν : fst κ ≤ ν) [IsFiniteKernel ν] (a : α) {s : Set β} (hs : MeasurableSet s) : Tendsto (fun n ↦ eLpNorm ((fun x ↦ densityProcess κ ν n a x s) - (countableFiltration γ).limitProcess (fun n x ↦ densityProcess κ ν n a x s) (ν a)) 1 (ν a)) atTop (𝓝 0) := by refine Submartingale.tendsto_eLpNorm_one_limitProcess ?_ ?_ · exact (martingale_densityProcess hκν a hs).submartingale · refine uniformIntegrable_of le_rfl ENNReal.one_ne_top ?_ ?_ · exact fun n ↦ (measurable_densityProcess_right κ ν n a hs).aestronglyMeasurable · refine fun ε _ ↦ ⟨2, fun n ↦ le_of_eq_of_le ?_ (?_ : 0 ≤ ENNReal.ofReal ε)⟩ · suffices {x \| 2 ≤ ‖densityProcess κ ν n a x s‖₊} = ∅ by simp [this] ext x simp only [mem_setOf_eq, mem_empty_iff_false, iff_false, not_le] refine (?_ : _ ≤ (1 : ℝ≥0)).trans_lt one_lt_two rw [Real.nnnorm_of_nonneg (densityProcess_nonneg _ _ _ _ _ _)] exact mod_cast (densityProcess_le_one hκν _ _ _ _) · simp lemma tendsto_eLpNorm_one_restrict_densityProcess_limitProcess [IsFiniteKernel ν] (hκν : fst κ ≤ ν) (a : α) {s : Set β} (hs : MeasurableSet s) (A : Set γ) : Tendsto (fun n ↦ eLpNorm ((fun x ↦ densityProcess κ ν n a x s) - (countableFiltration γ).limitProcess (fun n x ↦ densityProcess κ ν n a x s) (ν a)) 1 ((ν a).restrict A)) atTop (𝓝 0) := tendsto_of_tendsto_of_tendsto_of_le_of_le tendsto_const_nhds (tendsto_eLpNorm_one_densityProcess_limitProcess hκν a hs) (fun _ ↦ zero_le') (fun _ ↦ eLpNorm_restrict_le _ _ _ _)	end DensityProcess section Density /-- Density of the kernel `κ` with respect to `ν`. This is a function `α → γ → Set β → ℝ` which is measurable on `α × γ` for all measurable sets `s : Set β` and satisfies that `∫ x in A, density κ ν a x s ∂(ν a) = (κ a).real (A ×ˢ s)` for all measurable `A : Set γ`. -/ noncomputable def density (κ : Kernel α (γ × β)) (ν : Kernel α γ) (a : α) (x : γ) (s : Set β) : ℝ := limsup (fun n ↦ densityProcess κ ν n a x s) atTop lemma density_ae_eq_limitProcess (hκν : fst κ ≤ ν) [IsFiniteKernel ν] (a : α) {s : Set β} (hs : MeasurableSet s) : (fun x ↦ density κ ν a x s) =ᵐ[ν a] (countableFiltration γ).limitProcess (fun n x ↦ densityProcess κ ν n a x s) (ν a) := by	Mathlib/Probability/Kernel/Disintegration/Density.lean	421	437
/- 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.Sites.LeftExact import Mathlib.CategoryTheory.Sites.PreservesSheafification import Mathlib.CategoryTheory.Sites.Subsheaf import Mathlib.CategoryTheory.Sites.Whiskering /-! # Locally injective morphisms of (pre)sheaves Let `C` be a category equipped with a Grothendieck topology `J`, and let `D` be a concrete category. In this file, we introduce the typeclass `Presheaf.IsLocallyInjective J φ` for a morphism `φ : F₁ ⟶ F₂` in the category `Cᵒᵖ ⥤ D`. This means that `φ` is locally injective. More precisely, if `x` and `y` are two elements of some `F₁.obj U` such the images of `x` and `y` in `F₂.obj U` coincide, then the equality `x = y` must hold locally, i.e. after restriction by the maps of a covering sieve. -/ universe w v' v u' u namespace CategoryTheory open Opposite Limits variable {C : Type u} [Category.{v} C] {D : Type u'} [Category.{v'} D] {FD : D → D → Type*} {CD : D → Type w} [∀ X Y, FunLike (FD X Y) (CD X) (CD Y)] [ConcreteCategory.{w} D FD] (J : GrothendieckTopology C) namespace Presheaf /-- If `F : Cᵒᵖ ⥤ D` is a presheaf with values in a concrete category, if `x` and `y` are elements in `F.obj X`, this is the sieve of `X.unop` consisting of morphisms `f` such that `F.map f.op x = F.map f.op y`. -/ @[simps] def equalizerSieve {F : Cᵒᵖ ⥤ D} {X : Cᵒᵖ} (x y : ToType (F.obj X)) : Sieve X.unop where arrows _ f := F.map f.op x = F.map f.op y downward_closed {X Y} f hf g := by dsimp at hf ⊢ simp [hf] @[simp] lemma equalizerSieve_self_eq_top {F : Cᵒᵖ ⥤ D} {X : Cᵒᵖ} (x : ToType (F.obj X)) : equalizerSieve x x = ⊤ := by aesop @[simp] lemma equalizerSieve_eq_top_iff {F : Cᵒᵖ ⥤ D} {X : Cᵒᵖ} (x y : ToType (F.obj X)) : equalizerSieve x y = ⊤ ↔ x = y := by constructor · intro h simpa using (show equalizerSieve x y (𝟙 _) by simp [h]) · rintro rfl apply equalizerSieve_self_eq_top variable {F₁ F₂ F₃ : Cᵒᵖ ⥤ D} (φ : F₁ ⟶ F₂) (ψ : F₂ ⟶ F₃) /-- A morphism `φ : F₁ ⟶ F₂` of presheaves `Cᵒᵖ ⥤ D` (with `D` a concrete category) is locally injective for a Grothendieck topology `J` on `C` if whenever two sections of `F₁` are sent to the same section of `F₂`, then these two sections coincide locally. -/ class IsLocallyInjective : Prop where equalizerSieve_mem {X : Cᵒᵖ} (x y : ToType (F₁.obj X)) (h : φ.app X x = φ.app X y) : equalizerSieve x y ∈ J X.unop lemma equalizerSieve_mem [IsLocallyInjective J φ] {X : Cᵒᵖ} (x y : ToType (F₁.obj X)) (h : φ.app X x = φ.app X y) : equalizerSieve x y ∈ J X.unop := IsLocallyInjective.equalizerSieve_mem x y h lemma isLocallyInjective_of_injective (hφ : ∀ (X : Cᵒᵖ), Function.Injective (φ.app X)) : IsLocallyInjective J φ where equalizerSieve_mem {X} x y h := by convert J.top_mem X.unop ext Y f simp only [equalizerSieve_apply, op_unop, Sieve.top_apply, iff_true] apply hφ simp [h] instance [IsIso φ] : IsLocallyInjective J φ := isLocallyInjective_of_injective J φ (fun X => Function.Bijective.injective (by rw [← isIso_iff_bijective] change IsIso ((forget D).map (φ.app X)) infer_instance)) attribute [local instance] Types.instFunLike Types.instConcreteCategory in instance isLocallyInjective_forget [IsLocallyInjective J φ] : IsLocallyInjective J (whiskerRight φ (forget D)) where equalizerSieve_mem x y h := equalizerSieve_mem J φ x y h attribute [local instance] Types.instFunLike Types.instConcreteCategory in lemma isLocallyInjective_forget_iff : IsLocallyInjective J (whiskerRight φ (forget D)) ↔ IsLocallyInjective J φ := by constructor · intro exact ⟨fun x y h => equalizerSieve_mem J (whiskerRight φ (forget D)) x y h⟩ · intro infer_instance lemma isLocallyInjective_iff_equalizerSieve_mem_imp : IsLocallyInjective J φ ↔ ∀ ⦃X : Cᵒᵖ⦄ (x y : ToType (F₁.obj X)), equalizerSieve (φ.app _ x) (φ.app _ y) ∈ J X.unop → equalizerSieve x y ∈ J X.unop := by constructor · intro _ X x y h let S := equalizerSieve (φ.app _ x) (φ.app _ y) let T : ∀ ⦃Y : C⦄ ⦃f : Y ⟶ X.unop⦄ (_ : S f), Sieve Y := fun Y f _ => equalizerSieve (F₁.map f.op x) ((F₁.map f.op y)) refine J.superset_covering ?_ (J.transitive h (Sieve.bind S.1 T) ?_) · rintro Y f ⟨Z, a, g, hg, ha, rfl⟩ simpa using ha · intro Y f hf refine J.superset_covering (Sieve.le_pullback_bind S.1 T _ hf) (equalizerSieve_mem J φ _ _ ?_) rw [NatTrans.naturality_apply, NatTrans.naturality_apply] exact hf · intro hφ exact ⟨fun {X} x y h => hφ x y (by simp [h])⟩ lemma equalizerSieve_mem_of_equalizerSieve_app_mem {X : Cᵒᵖ} (x y : ToType (F₁.obj X)) (h : equalizerSieve (φ.app _ x) (φ.app _ y) ∈ J X.unop) [IsLocallyInjective J φ] : equalizerSieve x y ∈ J X.unop := (isLocallyInjective_iff_equalizerSieve_mem_imp J φ).1 inferInstance x y h instance isLocallyInjective_comp [IsLocallyInjective J φ] [IsLocallyInjective J ψ] : IsLocallyInjective J (φ ≫ ψ) where equalizerSieve_mem {X} x y h := by apply equalizerSieve_mem_of_equalizerSieve_app_mem J φ exact equalizerSieve_mem J ψ _ _ (by simpa using h) lemma isLocallyInjective_of_isLocallyInjective [IsLocallyInjective J (φ ≫ ψ)] : IsLocallyInjective J φ where equalizerSieve_mem {X} x y h := equalizerSieve_mem J (φ ≫ ψ) x y (by simp [h]) variable {φ ψ} lemma isLocallyInjective_of_isLocallyInjective_fac {φψ : F₁ ⟶ F₃} (fac : φ ≫ ψ = φψ) [IsLocallyInjective J φψ] : IsLocallyInjective J φ := by subst fac exact isLocallyInjective_of_isLocallyInjective J φ ψ lemma isLocallyInjective_iff_of_fac {φψ : F₁ ⟶ F₃} (fac : φ ≫ ψ = φψ) [IsLocallyInjective J ψ] : IsLocallyInjective J φψ ↔ IsLocallyInjective J φ := by constructor · intro exact isLocallyInjective_of_isLocallyInjective_fac J fac · intro rw [← fac] infer_instance variable (φ ψ) lemma isLocallyInjective_comp_iff [IsLocallyInjective J ψ] : IsLocallyInjective J (φ ≫ ψ) ↔ IsLocallyInjective J φ := isLocallyInjective_iff_of_fac J rfl lemma isLocallyInjective_iff_injective_of_separated (hsep : Presieve.IsSeparated J (F₁ ⋙ forget D)) : IsLocallyInjective J φ ↔ ∀ (X : Cᵒᵖ), Function.Injective (φ.app X) := by constructor · intro _ X x y h exact (hsep _ (equalizerSieve_mem J φ x y h)).ext (fun _ _ hf => hf) · apply isLocallyInjective_of_injective attribute [local instance] Types.instFunLike Types.instConcreteCategory in instance (F : Cᵒᵖ ⥤ Type w) (G : Subpresheaf F) : IsLocallyInjective J G.ι := isLocallyInjective_of_injective _ _ (fun X => by intro ⟨x, _⟩ ⟨y, _⟩ h exact Subtype.ext h) section open GrothendieckTopology.Plus attribute [local instance] Types.instFunLike Types.instConcreteCategory instance isLocallyInjective_toPlus (P : Cᵒᵖ ⥤ Type max u v) : IsLocallyInjective J (J.toPlus P) where equalizerSieve_mem {X} x y h := by rw [toPlus_eq_mk, toPlus_eq_mk, eq_mk_iff_exists] at h obtain ⟨W, h₁, h₂, eq⟩ := h exact J.superset_covering (fun Y f hf => congr_fun (congr_arg Subtype.val eq) ⟨Y, f, hf⟩) W.2 instance isLocallyInjective_toSheafify (P : Cᵒᵖ ⥤ Type max u v) : IsLocallyInjective J (J.toSheafify P) := by dsimp [GrothendieckTopology.toSheafify] rw [GrothendieckTopology.plusMap_toPlus] infer_instance instance isLocallyInjective_toSheafify' {CD : D → Type (max u v)} [∀ X Y, FunLike (FD X Y) (CD X) (CD Y)] [ConcreteCategory.{max u v} D FD] (P : Cᵒᵖ ⥤ D) [HasWeakSheafify J D] [J.HasSheafCompose (forget D)] [J.PreservesSheafification (forget D)] : IsLocallyInjective J (toSheafify J P) := by rw [← isLocallyInjective_forget_iff, ← sheafComposeIso_hom_fac, ← toSheafify_plusPlusIsoSheafify_hom] infer_instance end end Presheaf namespace Sheaf variable {J} variable {F₁ F₂ : Sheaf J D} (φ : F₁ ⟶ F₂) /-- If `φ : F₁ ⟶ F₂` is a morphism of sheaves, this is an abbreviation for `Presheaf.IsLocallyInjective J φ.val`. Under suitable assumptions, it is equivalent to the injectivity of all maps `φ.val.app X`, see `isLocallyInjective_iff_injective`. -/ abbrev IsLocallyInjective := Presheaf.IsLocallyInjective J φ.val lemma isLocallyInjective_sheafToPresheaf_map_iff : Presheaf.IsLocallyInjective J ((sheafToPresheaf J D).map φ) ↔ IsLocallyInjective φ := by rfl instance isLocallyInjective_of_iso [IsIso φ] : IsLocallyInjective φ := by change Presheaf.IsLocallyInjective J ((sheafToPresheaf _ _).map φ) infer_instance lemma mono_of_injective	(hφ : ∀ (X : Cᵒᵖ), Function.Injective (φ.val.app X)) : Mono φ := have : ∀ X, Mono (φ.val.app X) := fun X ↦ ConcreteCategory.mono_of_injective _ (hφ X) (sheafToPresheaf _ _).mono_of_mono_map (NatTrans.mono_of_mono_app φ.1) variable [J.HasSheafCompose (forget D)]	Mathlib/CategoryTheory/Sites/LocallyInjective.lean	228	233
/- Copyright (c) 2015 Nathaniel Thomas. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Nathaniel Thomas, Jeremy Avigad, Johannes Hölzl, Mario Carneiro -/ import Mathlib.Algebra.Field.Defs import Mathlib.Algebra.Group.Action.Pi import Mathlib.Algebra.Group.Indicator import Mathlib.Algebra.GroupWithZero.Action.Units import Mathlib.Algebra.Module.NatInt import Mathlib.Algebra.NoZeroSMulDivisors.Defs import Mathlib.Algebra.Ring.Invertible /-! # Further basic results about modules. -/ assert_not_exists Nonneg.inv Multiset open Function Set universe u v variable {α R M M₂ : Type*} @[simp] theorem Units.neg_smul [Ring R] [AddCommGroup M] [Module R M] (u : Rˣ) (x : M) : -u • x = -(u • x) := by rw [Units.smul_def, Units.val_neg, _root_.neg_smul, Units.smul_def]	@[simp] theorem invOf_two_smul_add_invOf_two_smul (R) [Semiring R] [AddCommMonoid M] [Module R M] [Invertible (2 : R)] (x : M) : (⅟ 2 : R) • x + (⅟ 2 : R) • x = x := Convex.combo_self invOf_two_add_invOf_two _ theorem map_inv_natCast_smul [AddCommMonoid M] [AddCommMonoid M₂] {F : Type} [FunLike F M M₂] [AddMonoidHomClass F M M₂] (f : F) (R S : Type) [DivisionSemiring R] [DivisionSemiring S] [Module R M] [Module S M₂] (n : ℕ) (x : M) : f ((n⁻¹ : R) • x) = (n⁻¹ : S) • f x := by by_cases hR : (n : R) = 0 <;> by_cases hS : (n : S) = 0 · simp [hR, hS, map_zero f] · suffices ∀ y, f y = 0 by rw [this, this, smul_zero] clear x intro x	Mathlib/Algebra/Module/Basic.lean	31	46
/- Copyright (c) 2021 Kexing Ying. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kexing Ying -/ import Mathlib.MeasureTheory.Measure.Decomposition.RadonNikodym import Mathlib.MeasureTheory.Measure.Haar.OfBasis import Mathlib.Probability.Independence.Basic /-! # Probability density function This file defines the probability density function of random variables, by which we mean measurable functions taking values in a Borel space. The probability density function is defined as the Radon–Nikodym derivative of the law of `X`. In particular, a measurable function `f` is said to the probability density function of a random variable `X` if for all measurable sets `S`, `ℙ(X ∈ S) = ∫ x in S, f x dx`. Probability density functions are one way of describing the distribution of a random variable, and are useful for calculating probabilities and finding moments (although the latter is better achieved with moment generating functions). This file also defines the continuous uniform distribution and proves some properties about random variables with this distribution. ## Main definitions * `MeasureTheory.HasPDF` : A random variable `X : Ω → E` is said to `HasPDF` with respect to the measure `ℙ` on `Ω` and `μ` on `E` if the push-forward measure of `ℙ` along `X` is absolutely continuous with respect to `μ` and they `HaveLebesgueDecomposition`. * `MeasureTheory.pdf` : If `X` is a random variable that `HasPDF X ℙ μ`, then `pdf X` is the Radon–Nikodym derivative of the push-forward measure of `ℙ` along `X` with respect to `μ`. * `MeasureTheory.pdf.IsUniform` : A random variable `X` is said to follow the uniform distribution if it has a constant probability density function with a compact, non-null support. ## Main results * `MeasureTheory.pdf.integral_pdf_smul` : Law of the unconscious statistician, i.e. if a random variable `X : Ω → E` has pdf `f`, then `𝔼(g(X)) = ∫ x, f x • g x dx` for all measurable `g : E → F`. * `MeasureTheory.pdf.integral_mul_eq_integral` : A real-valued random variable `X` with pdf `f` has expectation `∫ x, x * f x dx`. * `MeasureTheory.pdf.IsUniform.integral_eq` : If `X` follows the uniform distribution with its pdf having support `s`, then `X` has expectation `(λ s)⁻¹ * ∫ x in s, x dx` where `λ` is the Lebesgue measure. ## TODO Ultimately, we would also like to define characteristic functions to describe distributions as it exists for all random variables. However, to define this, we will need Fourier transforms which we currently do not have. -/ open scoped MeasureTheory NNReal ENNReal open TopologicalSpace MeasureTheory.Measure noncomputable section namespace MeasureTheory variable {Ω E : Type*} [MeasurableSpace E] /-- A random variable `X : Ω → E` is said to have a probability density function (`HasPDF`) with respect to the measure `ℙ` on `Ω` and `μ` on `E` if the push-forward measure of `ℙ` along `X` is absolutely continuous with respect to `μ` and they have a Lebesgue decomposition (`HaveLebesgueDecomposition`). -/ class HasPDF {m : MeasurableSpace Ω} (X : Ω → E) (ℙ : Measure Ω) (μ : Measure E := by volume_tac) : Prop where protected aemeasurable' : AEMeasurable X ℙ protected haveLebesgueDecomposition' : (map X ℙ).HaveLebesgueDecomposition μ protected absolutelyContinuous' : map X ℙ ≪ μ section HasPDF variable {_ : MeasurableSpace Ω} {X Y : Ω → E} {ℙ : Measure Ω} {μ : Measure E} theorem hasPDF_iff : HasPDF X ℙ μ ↔ AEMeasurable X ℙ ∧ (map X ℙ).HaveLebesgueDecomposition μ ∧ map X ℙ ≪ μ := ⟨fun ⟨h₁, h₂, h₃⟩ ↦ ⟨h₁, h₂, h₃⟩, fun ⟨h₁, h₂, h₃⟩ ↦ ⟨h₁, h₂, h₃⟩⟩ theorem hasPDF_iff_of_aemeasurable (hX : AEMeasurable X ℙ) : HasPDF X ℙ μ ↔ (map X ℙ).HaveLebesgueDecomposition μ ∧ map X ℙ ≪ μ := by rw [hasPDF_iff] simp only [hX, true_and] variable (X ℙ μ) in @[measurability] theorem HasPDF.aemeasurable [HasPDF X ℙ μ] : AEMeasurable X ℙ := HasPDF.aemeasurable' μ instance HasPDF.haveLebesgueDecomposition [HasPDF X ℙ μ] : (map X ℙ).HaveLebesgueDecomposition μ := HasPDF.haveLebesgueDecomposition' theorem HasPDF.absolutelyContinuous [HasPDF X ℙ μ] : map X ℙ ≪ μ := HasPDF.absolutelyContinuous' /-- A random variable that `HasPDF` is quasi-measure preserving. -/ theorem HasPDF.quasiMeasurePreserving_of_measurable (X : Ω → E) (ℙ : Measure Ω) (μ : Measure E) [HasPDF X ℙ μ] (h : Measurable X) : QuasiMeasurePreserving X ℙ μ := { measurable := h absolutelyContinuous := HasPDF.absolutelyContinuous .. } theorem HasPDF.congr (hXY : X =ᵐ[ℙ] Y) [hX : HasPDF X ℙ μ] : HasPDF Y ℙ μ := ⟨(HasPDF.aemeasurable X ℙ μ).congr hXY, ℙ.map_congr hXY ▸ hX.haveLebesgueDecomposition, ℙ.map_congr hXY ▸ hX.absolutelyContinuous⟩ theorem HasPDF.congr_iff (hXY : X =ᵐ[ℙ] Y) : HasPDF X ℙ μ ↔ HasPDF Y ℙ μ := ⟨fun _ ↦ HasPDF.congr hXY, fun _ ↦ HasPDF.congr hXY.symm⟩ @[deprecated (since := "2024-10-28")] alias HasPDF.congr' := HasPDF.congr_iff /-- X `HasPDF` if there is a pdf `f` such that `map X ℙ = μ.withDensity f`. -/ theorem hasPDF_of_map_eq_withDensity (hX : AEMeasurable X ℙ) (f : E → ℝ≥0∞) (hf : AEMeasurable f μ) (h : map X ℙ = μ.withDensity f) : HasPDF X ℙ μ := by refine ⟨hX, ?_, ?_⟩ <;> rw [h] · rw [withDensity_congr_ae hf.ae_eq_mk] exact haveLebesgueDecomposition_withDensity μ hf.measurable_mk · exact withDensity_absolutelyContinuous μ f end HasPDF /-- If `X` is a random variable, then `pdf X ℙ μ` is the Radon–Nikodym derivative of the push-forward measure of `ℙ` along `X` with respect to `μ`. -/ def pdf {_ : MeasurableSpace Ω} (X : Ω → E) (ℙ : Measure Ω) (μ : Measure E := by volume_tac) : E → ℝ≥0∞ := (map X ℙ).rnDeriv μ theorem pdf_def {_ : MeasurableSpace Ω} {ℙ : Measure Ω} {μ : Measure E} {X : Ω → E} : pdf X ℙ μ = (map X ℙ).rnDeriv μ := rfl theorem pdf_of_not_aemeasurable {_ : MeasurableSpace Ω} {ℙ : Measure Ω} {μ : Measure E} {X : Ω → E} (hX : ¬AEMeasurable X ℙ) : pdf X ℙ μ =ᵐ[μ] 0 := by rw [pdf_def, map_of_not_aemeasurable hX] exact rnDeriv_zero μ theorem pdf_of_not_haveLebesgueDecomposition {_ : MeasurableSpace Ω} {ℙ : Measure Ω} {μ : Measure E} {X : Ω → E} (h : ¬(map X ℙ).HaveLebesgueDecomposition μ) : pdf X ℙ μ = 0 := rnDeriv_of_not_haveLebesgueDecomposition h theorem aemeasurable_of_pdf_ne_zero {m : MeasurableSpace Ω} {ℙ : Measure Ω} {μ : Measure E} (X : Ω → E) (h : ¬pdf X ℙ μ =ᵐ[μ] 0) : AEMeasurable X ℙ := by contrapose! h exact pdf_of_not_aemeasurable h	theorem hasPDF_of_pdf_ne_zero {m : MeasurableSpace Ω} {ℙ : Measure Ω} {μ : Measure E} {X : Ω → E} (hac : map X ℙ ≪ μ) (hpdf : ¬pdf X ℙ μ =ᵐ[μ] 0) : HasPDF X ℙ μ := by refine ⟨?_, ?_, hac⟩	Mathlib/Probability/Density.lean	142	145
/- 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.Algebra.BigOperators.Ring.Finset import Mathlib.Combinatorics.SimpleGraph.Density import Mathlib.Data.Nat.Cast.Order.Field import Mathlib.Order.Partition.Equipartition import Mathlib.SetTheory.Cardinal.Order /-! # Graph uniformity and uniform partitions In this file we define uniformity of a pair of vertices in a graph and uniformity of a partition of vertices of a graph. Both are also known as ε-regularity. Finsets of vertices `s` and `t` are `ε`-uniform in a graph `G` if their edge density is at most `ε`-far from the density of any big enough `s'` and `t'` where `s' ⊆ s`, `t' ⊆ t`. The definition is pretty technical, but it amounts to the edges between `s` and `t` being "random" The literature contains several definitions which are equivalent up to scaling `ε` by some constant when the partition is equitable. A partition `P` of the vertices is `ε`-uniform if the proportion of non `ε`-uniform pairs of parts is less than `ε`. ## Main declarations * `SimpleGraph.IsUniform`: Graph uniformity of a pair of finsets of vertices. * `SimpleGraph.nonuniformWitness`: `G.nonuniformWitness ε s t` and `G.nonuniformWitness ε t s` together witness the non-uniformity of `s` and `t`. * `Finpartition.nonUniforms`: Non uniform pairs of parts of a partition. * `Finpartition.IsUniform`: Uniformity of a partition. * `Finpartition.nonuniformWitnesses`: For each non-uniform pair of parts of a partition, pick witnesses of non-uniformity and dump them all together. ## References [Yaël Dillies, Bhavik Mehta, Formalising Szemerédi’s Regularity Lemma in Lean][srl_itp] -/ open Finset variable {α 𝕜 : Type} [Field 𝕜] [LinearOrder 𝕜] [IsStrictOrderedRing 𝕜] /-! ### Graph uniformity -/ namespace SimpleGraph variable (G : SimpleGraph α) [DecidableRel G.Adj] (ε : 𝕜) {s t : Finset α} {a b : α} /-- A pair of finsets of vertices is `ε`-uniform (aka `ε`-regular) iff their edge density is close to the density of any big enough pair of subsets. Intuitively, the edges between them are random-like. -/ def IsUniform (s t : Finset α) : Prop := ∀ ⦃s'⦄, s' ⊆ s → ∀ ⦃t'⦄, t' ⊆ t → (#s : 𝕜) ε ≤ #s' → (#t : 𝕜) * ε ≤ #t' → \|(G.edgeDensity s' t' : 𝕜) - (G.edgeDensity s t : 𝕜)\| < ε variable {G ε} instance IsUniform.instDecidableRel : DecidableRel (G.IsUniform ε) := by unfold IsUniform; infer_instance theorem IsUniform.mono {ε' : 𝕜} (h : ε ≤ ε') (hε : IsUniform G ε s t) : IsUniform G ε' s t := fun s' hs' t' ht' hs ht => by refine (hε hs' ht' (le_trans ?_ hs) (le_trans ?_ ht)).trans_le h <;> gcongr omit [IsStrictOrderedRing 𝕜] in theorem IsUniform.symm : Symmetric (IsUniform G ε) := fun s t h t' ht' s' hs' ht hs => by rw [edgeDensity_comm _ t', edgeDensity_comm _ t] exact h hs' ht' hs ht variable (G) omit [IsStrictOrderedRing 𝕜] in theorem isUniform_comm : IsUniform G ε s t ↔ IsUniform G ε t s := ⟨fun h => h.symm, fun h => h.symm⟩ lemma isUniform_one : G.IsUniform (1 : 𝕜) s t := by intro s' hs' t' ht' hs ht rw [mul_one] at hs ht rw [eq_of_subset_of_card_le hs' (Nat.cast_le.1 hs), eq_of_subset_of_card_le ht' (Nat.cast_le.1 ht), sub_self, abs_zero] exact zero_lt_one variable {G} lemma IsUniform.pos (hG : G.IsUniform ε s t) : 0 < ε := not_le.1 fun hε ↦ (hε.trans <\| abs_nonneg _).not_lt <\| hG (empty_subset _) (empty_subset _) (by simpa using mul_nonpos_of_nonneg_of_nonpos (Nat.cast_nonneg _) hε) (by simpa using mul_nonpos_of_nonneg_of_nonpos (Nat.cast_nonneg _) hε) @[simp] lemma isUniform_singleton : G.IsUniform ε {a} {b} ↔ 0 < ε := by refine ⟨IsUniform.pos, fun hε s' hs' t' ht' hs ht ↦ ?_⟩ rw [card_singleton, Nat.cast_one, one_mul] at hs ht obtain rfl \| rfl := Finset.subset_singleton_iff.1 hs' · replace hs : ε ≤ 0 := by simpa using hs exact (hε.not_le hs).elim obtain rfl \| rfl := Finset.subset_singleton_iff.1 ht' · replace ht : ε ≤ 0 := by simpa using ht exact (hε.not_le ht).elim · rwa [sub_self, abs_zero] theorem not_isUniform_zero : ¬G.IsUniform (0 : 𝕜) s t := fun h => (abs_nonneg _).not_lt <\| h (empty_subset _) (empty_subset _) (by simp) (by simp) theorem not_isUniform_iff : ¬G.IsUniform ε s t ↔ ∃ s', s' ⊆ s ∧ ∃ t', t' ⊆ t ∧ #s * ε ≤ #s' ∧ #t * ε ≤ #t' ∧ ε ≤ \|G.edgeDensity s' t' - G.edgeDensity s t\| := by	unfold IsUniform simp only [not_forall, not_lt, exists_prop, exists_and_left, Rat.cast_abs, Rat.cast_sub]	Mathlib/Combinatorics/SimpleGraph/Regularity/Uniform.lean	112	113
/- Copyright (c) 2022 Siddhartha Prasad, Yaël Dillies. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Siddhartha Prasad, Yaël Dillies -/ import Mathlib.Algebra.Order.Monoid.Canonical.Defs import Mathlib.Algebra.Ring.InjSurj import Mathlib.Algebra.Ring.Pi import Mathlib.Algebra.Ring.Prod import Mathlib.Tactic.Monotonicity.Attr /-! # Kleene Algebras This file defines idempotent semirings and Kleene algebras, which are used extensively in the theory of computation. An idempotent semiring is a semiring whose addition is idempotent. An idempotent semiring is naturally a semilattice by setting `a ≤ b` if `a + b = b`. A Kleene algebra is an idempotent semiring equipped with an additional unary operator `∗`, the Kleene star. ## Main declarations * `IdemSemiring`: Idempotent semiring * `IdemCommSemiring`: Idempotent commutative semiring * `KleeneAlgebra`: Kleene algebra ## Notation `a∗` is notation for `kstar a` in locale `Computability`. ## References * [D. Kozen, A completeness theorem for Kleene algebras and the algebra of regular events] [kozen1994] * https://planetmath.org/idempotentsemiring * https://encyclopediaofmath.org/wiki/Idempotent_semi-ring * https://planetmath.org/kleene_algebra ## TODO Instances for `AddOpposite`, `MulOpposite`, `ULift`, `Subsemiring`, `Subring`, `Subalgebra`. ## Tags kleene algebra, idempotent semiring -/ open Function universe u variable {α β ι : Type} {π : ι → Type} /-- An idempotent semiring is a semiring with the additional property that addition is idempotent. -/ class IdemSemiring (α : Type u) extends Semiring α, SemilatticeSup α where protected sup := (· + ·) protected add_eq_sup : ∀ a b : α, a + b = a ⊔ b := by intros rfl /-- The bottom element of an idempotent semiring: `0` by default -/ protected bot : α := 0 protected bot_le : ∀ a, bot ≤ a /-- An idempotent commutative semiring is a commutative semiring with the additional property that addition is idempotent. -/ class IdemCommSemiring (α : Type u) extends CommSemiring α, IdemSemiring α /-- Notation typeclass for the Kleene star `∗`. -/ class KStar (α : Type) where /-- The Kleene star operator on a Kleene algebra -/ protected kstar : α → α @[inherit_doc] scoped[Computability] postfix:1024 "∗" => KStar.kstar open Computability /-- A Kleene Algebra is an idempotent semiring with an additional unary operator `kstar` (for Kleene star) that satisfies the following properties: `1 + a * a∗ ≤ a∗` * `1 + a∗ * a ≤ a∗` * If `a * c + b ≤ c`, then `a∗ * b ≤ c` * If `c * a + b ≤ c`, then `b * a∗ ≤ c` -/ class KleeneAlgebra (α : Type) extends IdemSemiring α, KStar α where protected one_le_kstar : ∀ a : α, 1 ≤ a∗ protected mul_kstar_le_kstar : ∀ a : α, a a∗ ≤ a∗ protected kstar_mul_le_kstar : ∀ a : α, a∗ * a ≤ a∗ protected mul_kstar_le_self : ∀ a b : α, b * a ≤ b → b * a∗ ≤ b protected kstar_mul_le_self : ∀ a b : α, a * b ≤ b → a∗ * b ≤ b -- See note [lower instance priority] instance (priority := 100) IdemSemiring.toOrderBot [IdemSemiring α] : OrderBot α := { ‹IdemSemiring α› with } -- See note [reducible non-instances] /-- Construct an idempotent semiring from an idempotent addition. -/ abbrev IdemSemiring.ofSemiring [Semiring α] (h : ∀ a : α, a + a = a) : IdemSemiring α := { ‹Semiring α› with le := fun a b ↦ a + b = b le_refl := h le_trans := fun a b c hab hbc ↦ by rw [← hbc, ← add_assoc, hab] le_antisymm := fun a b hab hba ↦ by rwa [← hba, add_comm] sup := (· + ·) le_sup_left := fun a b ↦ by rw [← add_assoc, h] le_sup_right := fun a b ↦ by rw [add_comm, add_assoc, h] sup_le := fun a b c hab hbc ↦ by rwa [add_assoc, hbc] bot := 0 bot_le := zero_add } section IdemSemiring variable [IdemSemiring α] {a b c : α} theorem add_eq_sup (a b : α) : a + b = a ⊔ b := IdemSemiring.add_eq_sup _ _ scoped[Computability] attribute [simp] add_eq_sup theorem add_idem (a : α) : a + a = a := by simp lemma natCast_eq_one {n : ℕ} (nezero : n ≠ 0) : (n : α) = 1 := by rw [← Nat.one_le_iff_ne_zero] at nezero induction n, nezero using Nat.le_induction with \| base => exact Nat.cast_one \| succ x _ hx => rw [Nat.cast_add, hx, Nat.cast_one, add_idem 1] lemma ofNat_eq_one {n : ℕ} [n.AtLeastTwo] : (ofNat(n) : α) = 1 := natCast_eq_one <\| Nat.ne_zero_of_lt Nat.AtLeastTwo.prop theorem nsmul_eq_self : ∀ {n : ℕ} (_ : n ≠ 0) (a : α), n • a = a \| 0, h => (h rfl).elim \| 1, _ => one_nsmul \| n + 2, _ => fun a ↦ by rw [succ_nsmul, nsmul_eq_self n.succ_ne_zero, add_idem] theorem add_eq_left_iff_le : a + b = a ↔ b ≤ a := by simp theorem add_eq_right_iff_le : a + b = b ↔ a ≤ b := by simp alias ⟨_, LE.le.add_eq_left⟩ := add_eq_left_iff_le alias ⟨_, LE.le.add_eq_right⟩ := add_eq_right_iff_le theorem add_le_iff : a + b ≤ c ↔ a ≤ c ∧ b ≤ c := by simp theorem add_le (ha : a ≤ c) (hb : b ≤ c) : a + b ≤ c := add_le_iff.2 ⟨ha, hb⟩ -- See note [lower instance priority] instance (priority := 100) IdemSemiring.toIsOrderedAddMonoid : IsOrderedAddMonoid α := { add_le_add_left := fun a b hbc c ↦ by simp_rw [add_eq_sup] exact sup_le_sup_left hbc _ } -- See note [lower instance priority] instance (priority := 100) IdemSemiring.toCanonicallyOrderedAdd : CanonicallyOrderedAdd α := { exists_add_of_le := fun h ↦ ⟨_, h.add_eq_right.symm⟩ le_self_add := fun a b ↦ add_eq_right_iff_le.1 <\| by rw [← add_assoc, add_idem] } -- See note [lower instance priority] instance (priority := 100) IdemSemiring.toMulLeftMono : MulLeftMono α := ⟨fun a b c hbc ↦ add_eq_left_iff_le.1 <\| by rw [← mul_add, hbc.add_eq_left]⟩ -- See note [lower instance priority] instance (priority := 100) IdemSemiring.toMulRightMono : MulRightMono α := ⟨fun a b c hbc ↦ add_eq_left_iff_le.1 <\| by rw [← add_mul, hbc.add_eq_left]⟩ end IdemSemiring section KleeneAlgebra variable [KleeneAlgebra α] {a b c : α} @[simp] theorem one_le_kstar : 1 ≤ a∗ := KleeneAlgebra.one_le_kstar _ theorem mul_kstar_le_kstar : a * a∗ ≤ a∗ := KleeneAlgebra.mul_kstar_le_kstar _ theorem kstar_mul_le_kstar : a∗ * a ≤ a∗ := KleeneAlgebra.kstar_mul_le_kstar _ theorem mul_kstar_le_self : b * a ≤ b → b * a∗ ≤ b := KleeneAlgebra.mul_kstar_le_self _ _ theorem kstar_mul_le_self : a * b ≤ b → a∗ * b ≤ b := KleeneAlgebra.kstar_mul_le_self _ _ theorem mul_kstar_le (hb : b ≤ c) (ha : c * a ≤ c) : b * a∗ ≤ c := (mul_le_mul_right' hb _).trans <\| mul_kstar_le_self ha theorem kstar_mul_le (hb : b ≤ c) (ha : a * c ≤ c) : a∗ * b ≤ c := (mul_le_mul_left' hb _).trans <\| kstar_mul_le_self ha theorem kstar_le_of_mul_le_left (hb : 1 ≤ b) : b * a ≤ b → a∗ ≤ b := by simpa using mul_kstar_le hb theorem kstar_le_of_mul_le_right (hb : 1 ≤ b) : a * b ≤ b → a∗ ≤ b := by simpa using kstar_mul_le hb @[simp] theorem le_kstar : a ≤ a∗ := le_trans (le_mul_of_one_le_left' one_le_kstar) kstar_mul_le_kstar @[mono] theorem kstar_mono : Monotone (KStar.kstar : α → α) := fun _ _ h ↦ kstar_le_of_mul_le_left one_le_kstar <\| kstar_mul_le (h.trans le_kstar) <\| mul_kstar_le_kstar @[simp] theorem kstar_eq_one : a∗ = 1 ↔ a ≤ 1 := ⟨le_kstar.trans_eq, fun h ↦ one_le_kstar.antisymm' <\| kstar_le_of_mul_le_left le_rfl <\| by rwa [one_mul]⟩ @[simp] lemma kstar_zero : (0 : α)∗ = 1 := kstar_eq_one.2 (zero_le _) @[simp] theorem kstar_one : (1 : α)∗ = 1 := kstar_eq_one.2 le_rfl	@[simp] theorem kstar_mul_kstar (a : α) : a∗ * a∗ = a∗ :=	Mathlib/Algebra/Order/Kleene.lean	232	233
/- Copyright (c) 2023 Frédéric Dupuis. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Frédéric Dupuis -/ import Mathlib.Analysis.Convex.SpecificFunctions.Basic import Mathlib.Analysis.SpecialFunctions.Pow.NNReal /-! # Convexity properties of `rpow` We prove basic convexity properties of the `rpow` function. The proofs are elementary and do not require calculus, and as such this file has only moderate dependencies. ## Main declarations * `NNReal.strictConcaveOn_rpow`, `Real.strictConcaveOn_rpow`: strict concavity of `fun x ↦ x ^ p` for p ∈ (0,1) * `NNReal.concaveOn_rpow`, `Real.concaveOn_rpow`: concavity of `fun x ↦ x ^ p` for p ∈ [0,1] Note that convexity for `p > 1` can be found in `Analysis.Convex.SpecificFunctions.Basic`, which requires slightly less imports. ## TODO * Prove convexity for negative powers. -/ open Set namespace NNReal lemma strictConcaveOn_rpow {p : ℝ} (hp₀ : 0 < p) (hp₁ : p < 1) : StrictConcaveOn ℝ≥0 univ fun x : ℝ≥0 ↦ x ^ p := by have hp₀' : 0 < 1 / p := div_pos zero_lt_one hp₀ have hp₁' : 1 < 1 / p := by rw [one_lt_div hp₀]; exact hp₁ let f := NNReal.orderIsoRpow (1 / p) hp₀' have h₁ : StrictConvexOn ℝ≥0 univ f := by refine ⟨convex_univ, fun x _ y _ hxy a b ha hb hab => ?_⟩ exact (strictConvexOn_rpow hp₁').2 x.2 y.2 (by simp [hxy]) ha hb (by simp; norm_cast) have h₂ : ∀ x, f.symm x = x ^ p := by simp [f, NNReal.orderIsoRpow_symm_eq] refine ⟨convex_univ, fun x mx y my hxy a b ha hb hab => ?_⟩ simp only [← h₂] exact (f.strictConcaveOn_symm h₁).2 mx my hxy ha hb hab	lemma concaveOn_rpow {p : ℝ} (hp₀ : 0 ≤ p) (hp₁ : p ≤ 1) : ConcaveOn ℝ≥0 univ fun x : ℝ≥0 ↦ x ^ p := by rcases eq_or_lt_of_le hp₀ with (rfl \| hp₀) · simpa only [rpow_zero] using concaveOn_const (c := 1) convex_univ rcases eq_or_lt_of_le hp₁ with (rfl \| hp₁) · simpa only [rpow_one] using concaveOn_id convex_univ exact (strictConcaveOn_rpow hp₀ hp₁).concaveOn	Mathlib/Analysis/Convex/SpecificFunctions/Pow.lean	47	53
/- Copyright (c) 2022 Jireh Loreaux. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jireh Loreaux -/ import Mathlib.Order.Filter.Cofinite /-! # Basic theory of bornology We develop the basic theory of bornologies. Instead of axiomatizing bounded sets and defining bornologies in terms of those, we recognize that the cobounded sets form a filter and define a bornology as a filter of cobounded sets which contains the cofinite filter. This allows us to make use of the extensive library for filters, but we also provide the relevant connecting results for bounded sets. The specification of a bornology in terms of the cobounded filter is equivalent to the standard one (e.g., see [Bourbaki, Topological Vector Spaces][bourbaki1987], covering bornology, now often called simply bornology) in terms of bounded sets (see `Bornology.ofBounded`, `IsBounded.union`, `IsBounded.subset`), except that we do not allow the empty bornology (that is, we require that some set must be bounded; equivalently, `∅` is bounded). In the literature the cobounded filter is generally referred to as the filter at infinity. ## Main definitions - `Bornology α`: a class consisting of `cobounded : Filter α` and a proof that this filter contains the `cofinite` filter. - `Bornology.IsCobounded`: the predicate that a set is a member of the `cobounded α` filter. For `s : Set α`, one should prefer `Bornology.IsCobounded s` over `s ∈ cobounded α`. - `bornology.IsBounded`: the predicate that states a set is bounded (i.e., the complement of a cobounded set). One should prefer `Bornology.IsBounded s` over `sᶜ ∈ cobounded α`. - `BoundedSpace α`: a class extending `Bornology α` with the condition `Bornology.IsBounded (Set.univ : Set α)` Although use of `cobounded α` is discouraged for indicating the (co)boundedness of individual sets, it is intended for regular use as a filter on `α`. -/ open Set Filter variable {ι α β : Type} /-- A bornology* on a type `α` is a filter of cobounded sets which contains the cofinite filter. Such spaces are equivalently specified by their bounded sets, see `Bornology.ofBounded` and `Bornology.ext_iff_isBounded` -/ class Bornology (α : Type) where /-- The filter of cobounded sets in a bornology. This is a field of the structure, but one should always prefer `Bornology.cobounded` because it makes the `α` argument explicit. -/ cobounded' : Filter α /-- The cobounded filter in a bornology is smaller than the cofinite filter. This is a field of the structure, but one should always prefer `Bornology.le_cofinite` because it makes the `α` argument explicit. -/ le_cofinite' : cobounded' ≤ cofinite /- porting note: Because Lean 4 doesn't accept the `[]` syntax to make arguments of structure fields explicit, we have to define these separately, prove the `ext` lemmas manually, and initialize new `simps` projections. -/ /-- The filter of cobounded sets in a bornology. -/ def Bornology.cobounded (α : Type) [Bornology α] : Filter α := Bornology.cobounded' alias Bornology.Simps.cobounded := Bornology.cobounded lemma Bornology.le_cofinite (α : Type) [Bornology α] : cobounded α ≤ cofinite := Bornology.le_cofinite' initialize_simps_projections Bornology (cobounded' → cobounded) @[ext] lemma Bornology.ext (t t' : Bornology α) (h_cobounded : @Bornology.cobounded α t = @Bornology.cobounded α t') : t = t' := by cases t cases t' congr /-- A constructor for bornologies by specifying the bounded sets, and showing that they satisfy the appropriate conditions. -/ @[simps] def Bornology.ofBounded {α : Type} (B : Set (Set α)) (empty_mem : ∅ ∈ B) (subset_mem : ∀ s₁ ∈ B, ∀ s₂ ⊆ s₁, s₂ ∈ B) (union_mem : ∀ s₁ ∈ B, ∀ s₂ ∈ B, s₁ ∪ s₂ ∈ B) (singleton_mem : ∀ x, {x} ∈ B) : Bornology α where cobounded' := comk (· ∈ B) empty_mem subset_mem union_mem le_cofinite' := by simpa [le_cofinite_iff_compl_singleton_mem] /-- A constructor for bornologies by specifying the bounded sets, and showing that they satisfy the appropriate conditions. -/ @[simps! cobounded] def Bornology.ofBounded' {α : Type*} (B : Set (Set α)) (empty_mem : ∅ ∈ B) (subset_mem : ∀ s₁ ∈ B, ∀ s₂ ⊆ s₁, s₂ ∈ B) (union_mem : ∀ s₁ ∈ B, ∀ s₂ ∈ B, s₁ ∪ s₂ ∈ B) (sUnion_univ : ⋃₀ B = univ) : Bornology α := Bornology.ofBounded B empty_mem subset_mem union_mem fun x => by rw [sUnion_eq_univ_iff] at sUnion_univ rcases sUnion_univ x with ⟨s, hs, hxs⟩ exact subset_mem s hs {x} (singleton_subset_iff.mpr hxs) namespace Bornology section /-- `IsCobounded` is the predicate that `s` is in the filter of cobounded sets in the ambient bornology on `α` -/ def IsCobounded [Bornology α] (s : Set α) : Prop := s ∈ cobounded α /-- `IsBounded` is the predicate that `s` is bounded relative to the ambient bornology on `α`. -/ def IsBounded [Bornology α] (s : Set α) : Prop := IsCobounded sᶜ variable {_ : Bornology α} {s t : Set α} {x : α} theorem isCobounded_def {s : Set α} : IsCobounded s ↔ s ∈ cobounded α := Iff.rfl theorem isBounded_def {s : Set α} : IsBounded s ↔ sᶜ ∈ cobounded α := Iff.rfl @[simp] theorem isBounded_compl_iff : IsBounded sᶜ ↔ IsCobounded s := by rw [isBounded_def, isCobounded_def, compl_compl] @[simp] theorem isCobounded_compl_iff : IsCobounded sᶜ ↔ IsBounded s := Iff.rfl alias ⟨IsBounded.of_compl, IsCobounded.compl⟩ := isBounded_compl_iff alias ⟨IsCobounded.of_compl, IsBounded.compl⟩ := isCobounded_compl_iff @[simp] theorem isBounded_empty : IsBounded (∅ : Set α) := by rw [isBounded_def, compl_empty] exact univ_mem theorem nonempty_of_not_isBounded (h : ¬IsBounded s) : s.Nonempty := by rw [nonempty_iff_ne_empty] rintro rfl exact h isBounded_empty @[simp] theorem isBounded_singleton : IsBounded ({x} : Set α) := by rw [isBounded_def] exact le_cofinite _ (finite_singleton x).compl_mem_cofinite theorem isBounded_iff_forall_mem : IsBounded s ↔ ∀ x ∈ s, IsBounded s := ⟨fun h _ _ ↦ h, fun h ↦ by rcases s.eq_empty_or_nonempty with rfl \| ⟨x, hx⟩ exacts [isBounded_empty, h x hx]⟩ @[simp] theorem isCobounded_univ : IsCobounded (univ : Set α) := univ_mem @[simp] theorem isCobounded_inter : IsCobounded (s ∩ t) ↔ IsCobounded s ∧ IsCobounded t := inter_mem_iff theorem IsCobounded.inter (hs : IsCobounded s) (ht : IsCobounded t) : IsCobounded (s ∩ t) := isCobounded_inter.2 ⟨hs, ht⟩ @[simp] theorem isBounded_union : IsBounded (s ∪ t) ↔ IsBounded s ∧ IsBounded t := by simp only [← isCobounded_compl_iff, compl_union, isCobounded_inter] theorem IsBounded.union (hs : IsBounded s) (ht : IsBounded t) : IsBounded (s ∪ t) := isBounded_union.2 ⟨hs, ht⟩ theorem IsCobounded.superset (hs : IsCobounded s) (ht : s ⊆ t) : IsCobounded t := mem_of_superset hs ht theorem IsBounded.subset (ht : IsBounded t) (hs : s ⊆ t) : IsBounded s := ht.superset (compl_subset_compl.mpr hs)	@[simp] theorem sUnion_bounded_univ : ⋃₀ { s : Set α \| IsBounded s } = univ := sUnion_eq_univ_iff.2 fun a => ⟨{a}, isBounded_singleton, mem_singleton a⟩	Mathlib/Topology/Bornology/Basic.lean	178	181
/- Copyright (c) 2019 Kevin Buzzard. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Kevin Buzzard -/ import Mathlib.Data.EReal.Basic deprecated_module (since := "2025-04-13")		Mathlib/Data/Real/EReal.lean	1,697	1,701
/- 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.HomotopyCategory.Shift /-! Shifting cochains Let `C` be a preadditive category. Given two cochain complexes (indexed by `ℤ`), the type of cochains `HomComplex.Cochain K L n` of degree `n` was introduced in `Mathlib.Algebra.Homology.HomotopyCategory.HomComplex`. In this file, we study how these cochains behave with respect to the shift on the complexes `K` and `L`. When `n`, `a`, `n'` are integers such that `h : n' + a = n`, we obtain `rightShiftAddEquiv K L n a n' h : Cochain K L n ≃+ Cochain K (L⟦a⟧) n'`. This definition does not involve signs, but the analogous definition of `leftShiftAddEquiv K L n a n' h' : Cochain K L n ≃+ Cochain (K⟦a⟧) L n'` when `h' : n + a = n'` does involve signs, as we follow the conventions appearing in the introduction of [Brian Conrad's book Grothendieck duality and base change][conrad2000]. ## References * [Brian Conrad, Grothendieck duality and base change][conrad2000] -/ assert_not_exists TwoSidedIdeal open CategoryTheory Category Limits Preadditive universe v u variable {C : Type u} [Category.{v} C] [Preadditive C] {R : Type} [Ring R] [Linear R C] {K L M : CochainComplex C ℤ} {n : ℤ} namespace CochainComplex.HomComplex namespace Cochain variable (γ γ₁ γ₂ : Cochain K L n) /-- The map `Cochain K L n → Cochain K (L⟦a⟧) n'` when `n' + a = n`. -/ def rightShift (a n' : ℤ) (hn' : n' + a = n) : Cochain K (L⟦a⟧) n' := Cochain.mk (fun p q hpq => γ.v p (p + n) rfl ≫ (L.shiftFunctorObjXIso a q (p + n) (by omega)).inv) lemma rightShift_v (a n' : ℤ) (hn' : n' + a = n) (p q : ℤ) (hpq : p + n' = q) (p' : ℤ) (hp' : p + n = p') : (γ.rightShift a n' hn').v p q hpq = γ.v p p' hp' ≫ (L.shiftFunctorObjXIso a q p' (by rw [← hp', ← hpq, ← hn', add_assoc])).inv := by subst hp' dsimp only [rightShift] simp only [mk_v] /-- The map `Cochain K L n → Cochain (K⟦a⟧) L n'` when `n + a = n'`. -/ def leftShift (a n' : ℤ) (hn' : n + a = n') : Cochain (K⟦a⟧) L n' := Cochain.mk (fun p q hpq => (a n' + ((a * (a-1))/2)).negOnePow • (K.shiftFunctorObjXIso a p (p + a) rfl).hom ≫ γ.v (p+a) q (by omega)) lemma leftShift_v (a n' : ℤ) (hn' : n + a = n') (p q : ℤ) (hpq : p + n' = q) (p' : ℤ) (hp' : p' + n = q) : (γ.leftShift a n' hn').v p q hpq = (a * n' + ((a * (a - 1))/2)).negOnePow • (K.shiftFunctorObjXIso a p p' (by rw [← add_left_inj n, hp', add_assoc, add_comm a, hn', hpq])).hom ≫ γ.v p' q hp' := by obtain rfl : p' = p + a := by omega dsimp only [leftShift] simp only [mk_v] /-- The map `Cochain K (L⟦a⟧) n' → Cochain K L n` when `n' + a = n`. -/ def rightUnshift {n' a : ℤ} (γ : Cochain K (L⟦a⟧) n') (n : ℤ) (hn : n' + a = n) : Cochain K L n := Cochain.mk (fun p q hpq => γ.v p (p + n') rfl ≫ (L.shiftFunctorObjXIso a (p + n') q (by rw [← hpq, add_assoc, hn])).hom) lemma rightUnshift_v {n' a : ℤ} (γ : Cochain K (L⟦a⟧) n') (n : ℤ) (hn : n' + a = n) (p q : ℤ) (hpq : p + n = q) (p' : ℤ) (hp' : p + n' = p') : (γ.rightUnshift n hn).v p q hpq = γ.v p p' hp' ≫ (L.shiftFunctorObjXIso a p' q (by rw [← hpq, ← hn, ← add_assoc, hp'])).hom := by subst hp' dsimp only [rightUnshift] simp only [mk_v] /-- The map `Cochain (K⟦a⟧) L n' → Cochain K L n` when `n + a = n'`. -/ def leftUnshift {n' a : ℤ} (γ : Cochain (K⟦a⟧) L n') (n : ℤ) (hn : n + a = n') : Cochain K L n := Cochain.mk (fun p q hpq => (a * n' + ((a * (a-1))/2)).negOnePow •	(K.shiftFunctorObjXIso a (p - a) p (by omega)).inv ≫ γ.v (p-a) q (by omega)) lemma leftUnshift_v {n' a : ℤ} (γ : Cochain (K⟦a⟧) L n') (n : ℤ) (hn : n + a = n') (p q : ℤ) (hpq : p + n = q) (p' : ℤ) (hp' : p' + n' = q) : (γ.leftUnshift n hn).v p q hpq = (a * n' + ((a * (a-1))/2)).negOnePow • (K.shiftFunctorObjXIso a p' p (by omega)).inv ≫ γ.v p' q (by omega) := by	Mathlib/Algebra/Homology/HomotopyCategory/HomComplexShift.lean	90	95
/- 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.Card import Mathlib.Data.Fintype.Basic /-! # Cardinalities of finite types This file defines the cardinality `Fintype.card α` as the number of elements in `(univ : Finset α)`. We also include some elementary results on the values of `Fintype.card` on specific types. ## Main declarations * `Fintype.card α`: Cardinality of a fintype. Equal to `Finset.univ.card`. * `Finite.surjective_of_injective`: an injective function from a finite type to itself is also surjective. -/ assert_not_exists Monoid open Function universe u v variable {α β γ : Type} open Finset Function namespace Fintype /-- `card α` is the number of elements in `α`, defined when `α` is a fintype. -/ def card (α) [Fintype α] : ℕ := (@univ α _).card theorem subtype_card {p : α → Prop} (s : Finset α) (H : ∀ x : α, x ∈ s ↔ p x) : @card { x // p x } (Fintype.subtype s H) = #s := Multiset.card_pmap _ _ _ theorem card_of_subtype {p : α → Prop} (s : Finset α) (H : ∀ x : α, x ∈ s ↔ p x) [Fintype { x // p x }] : card { x // p x } = #s := by rw [← subtype_card s H] congr! @[simp] theorem card_ofFinset {p : Set α} (s : Finset α) (H : ∀ x, x ∈ s ↔ x ∈ p) : @Fintype.card p (ofFinset s H) = #s := Fintype.subtype_card s H theorem card_of_finset' {p : Set α} (s : Finset α) (H : ∀ x, x ∈ s ↔ x ∈ p) [Fintype p] : Fintype.card p = #s := by rw [← card_ofFinset s H]; congr! end Fintype namespace Fintype theorem ofEquiv_card [Fintype α] (f : α ≃ β) : @card β (ofEquiv α f) = card α := Multiset.card_map _ _ theorem card_congr {α β} [Fintype α] [Fintype β] (f : α ≃ β) : card α = card β := by rw [← ofEquiv_card f]; congr! @[congr] theorem card_congr' {α β} [Fintype α] [Fintype β] (h : α = β) : card α = card β := card_congr (by rw [h]) /-- Note: this lemma is specifically about `Fintype.ofSubsingleton`. For a statement about arbitrary `Fintype` instances, use either `Fintype.card_le_one_iff_subsingleton` or `Fintype.card_unique`. -/ theorem card_ofSubsingleton (a : α) [Subsingleton α] : @Fintype.card _ (ofSubsingleton a) = 1 := rfl @[simp] theorem card_unique [Unique α] [h : Fintype α] : Fintype.card α = 1 := Subsingleton.elim (ofSubsingleton default) h ▸ card_ofSubsingleton _ /-- Note: this lemma is specifically about `Fintype.ofIsEmpty`. For a statement about arbitrary `Fintype` instances, use `Fintype.card_eq_zero`. -/ theorem card_ofIsEmpty [IsEmpty α] : @Fintype.card α Fintype.ofIsEmpty = 0 := rfl end Fintype namespace Set variable {s t : Set α} -- We use an arbitrary `[Fintype s]` instance here, -- not necessarily coming from a `[Fintype α]`. @[simp] theorem toFinset_card {α : Type} (s : Set α) [Fintype s] : s.toFinset.card = Fintype.card s := Multiset.card_map Subtype.val Finset.univ.val end Set @[simp] theorem Finset.card_univ [Fintype α] : #(univ : Finset α) = Fintype.card α := rfl theorem Finset.eq_univ_of_card [Fintype α] (s : Finset α) (hs : #s = Fintype.card α) : s = univ := eq_of_subset_of_card_le (subset_univ _) <\| by rw [hs, Finset.card_univ] theorem Finset.card_eq_iff_eq_univ [Fintype α] (s : Finset α) : #s = Fintype.card α ↔ s = univ := ⟨s.eq_univ_of_card, by rintro rfl exact Finset.card_univ⟩ theorem Finset.card_le_univ [Fintype α] (s : Finset α) : #s ≤ Fintype.card α := card_le_card (subset_univ s) theorem Finset.card_lt_univ_of_not_mem [Fintype α] {s : Finset α} {x : α} (hx : x ∉ s) : #s < Fintype.card α := card_lt_card ⟨subset_univ s, not_forall.2 ⟨x, fun hx' => hx (hx' <\| mem_univ x)⟩⟩ theorem Finset.card_lt_iff_ne_univ [Fintype α] (s : Finset α) : #s < Fintype.card α ↔ s ≠ Finset.univ := s.card_le_univ.lt_iff_ne.trans (not_congr s.card_eq_iff_eq_univ) theorem Finset.card_compl_lt_iff_nonempty [Fintype α] [DecidableEq α] (s : Finset α) : #sᶜ < Fintype.card α ↔ s.Nonempty := sᶜ.card_lt_iff_ne_univ.trans s.compl_ne_univ_iff_nonempty theorem Finset.card_univ_diff [DecidableEq α] [Fintype α] (s : Finset α) : #(univ \ s) = Fintype.card α - #s := Finset.card_sdiff (subset_univ s) theorem Finset.card_compl [DecidableEq α] [Fintype α] (s : Finset α) : #sᶜ = Fintype.card α - #s := Finset.card_univ_diff s @[simp] theorem Finset.card_add_card_compl [DecidableEq α] [Fintype α] (s : Finset α) : #s + #sᶜ = Fintype.card α := by rw [Finset.card_compl, ← Nat.add_sub_assoc (card_le_univ s), Nat.add_sub_cancel_left] @[simp] theorem Finset.card_compl_add_card [DecidableEq α] [Fintype α] (s : Finset α) : #sᶜ + #s = Fintype.card α := by rw [Nat.add_comm, card_add_card_compl] theorem Fintype.card_compl_set [Fintype α] (s : Set α) [Fintype s] [Fintype (↥sᶜ : Sort _)] : Fintype.card (↥sᶜ : Sort _) = Fintype.card α - Fintype.card s := by classical rw [← Set.toFinset_card, ← Set.toFinset_card, ← Finset.card_compl, Set.toFinset_compl] theorem Fintype.card_subtype_eq (y : α) [Fintype { x // x = y }] : Fintype.card { x // x = y } = 1 := Fintype.card_unique theorem Fintype.card_subtype_eq' (y : α) [Fintype { x // y = x }] : Fintype.card { x // y = x } = 1 := Fintype.card_unique theorem Fintype.card_empty : Fintype.card Empty = 0 := rfl theorem Fintype.card_pempty : Fintype.card PEmpty = 0 := rfl theorem Fintype.card_unit : Fintype.card Unit = 1 := rfl @[simp] theorem Fintype.card_punit : Fintype.card PUnit = 1 := rfl @[simp] theorem Fintype.card_bool : Fintype.card Bool = 2 := rfl @[simp] theorem Fintype.card_ulift (α : Type) [Fintype α] : Fintype.card (ULift α) = Fintype.card α := Fintype.ofEquiv_card _ @[simp] theorem Fintype.card_plift (α : Type) [Fintype α] : Fintype.card (PLift α) = Fintype.card α := Fintype.ofEquiv_card _ @[simp] theorem Fintype.card_orderDual (α : Type) [Fintype α] : Fintype.card αᵒᵈ = Fintype.card α := rfl @[simp] theorem Fintype.card_lex (α : Type) [Fintype α] : Fintype.card (Lex α) = Fintype.card α := rfl -- Note: The extra hypothesis `h` is there so that the rewrite lemma applies, -- no matter what instance of `Fintype (Set.univ : Set α)` is used. @[simp] theorem Fintype.card_setUniv [Fintype α] {h : Fintype (Set.univ : Set α)} : Fintype.card (Set.univ : Set α) = Fintype.card α := by apply Fintype.card_of_finset' simp @[simp] theorem Fintype.card_subtype_true [Fintype α] {h : Fintype {_a : α // True}} : @Fintype.card {_a // True} h = Fintype.card α := by apply Fintype.card_of_subtype simp /-- Given that `α ⊕ β` is a fintype, `α` is also a fintype. This is non-computable as it uses that `Sum.inl` is an injection, but there's no clear inverse if `α` is empty. -/ noncomputable def Fintype.sumLeft {α β} [Fintype (α ⊕ β)] : Fintype α := Fintype.ofInjective (Sum.inl : α → α ⊕ β) Sum.inl_injective /-- Given that `α ⊕ β` is a fintype, `β` is also a fintype. This is non-computable as it uses that `Sum.inr` is an injection, but there's no clear inverse if `β` is empty. -/ noncomputable def Fintype.sumRight {α β} [Fintype (α ⊕ β)] : Fintype β := Fintype.ofInjective (Sum.inr : β → α ⊕ β) Sum.inr_injective theorem Finite.exists_univ_list (α) [Finite α] : ∃ l : List α, l.Nodup ∧ ∀ x : α, x ∈ l := by cases nonempty_fintype α obtain ⟨l, e⟩ := Quotient.exists_rep (@univ α _).1 have := And.intro (@univ α _).2 (@mem_univ_val α _) exact ⟨_, by rwa [← e] at this⟩ theorem List.Nodup.length_le_card {α : Type} [Fintype α] {l : List α} (h : l.Nodup) : l.length ≤ Fintype.card α := by classical exact List.toFinset_card_of_nodup h ▸ l.toFinset.card_le_univ namespace Fintype variable [Fintype α] [Fintype β] theorem card_le_of_injective (f : α → β) (hf : Function.Injective f) : card α ≤ card β := Finset.card_le_card_of_injOn f (fun _ _ => Finset.mem_univ _) fun _ _ _ _ h => hf h theorem card_le_of_embedding (f : α ↪ β) : card α ≤ card β := card_le_of_injective f f.2 theorem card_lt_of_injective_of_not_mem (f : α → β) (h : Function.Injective f) {b : β} (w : b ∉ Set.range f) : card α < card β := calc card α = (univ.map ⟨f, h⟩).card := (card_map _).symm _ < card β := Finset.card_lt_univ_of_not_mem (x := b) <\| by rwa [← mem_coe, coe_map, coe_univ, Set.image_univ] theorem card_lt_of_injective_not_surjective (f : α → β) (h : Function.Injective f) (h' : ¬Function.Surjective f) : card α < card β := let ⟨_y, hy⟩ := not_forall.1 h' card_lt_of_injective_of_not_mem f h hy theorem card_le_of_surjective (f : α → β) (h : Function.Surjective f) : card β ≤ card α := card_le_of_injective _ (Function.injective_surjInv h) theorem card_range_le {α β : Type} (f : α → β) [Fintype α] [Fintype (Set.range f)] : Fintype.card (Set.range f) ≤ Fintype.card α := Fintype.card_le_of_surjective (fun a => ⟨f a, by simp⟩) fun ⟨_, a, ha⟩ => ⟨a, by simpa using ha⟩ theorem card_range {α β F : Type} [FunLike F α β] [EmbeddingLike F α β] (f : F) [Fintype α] [Fintype (Set.range f)] : Fintype.card (Set.range f) = Fintype.card α := Eq.symm <\| Fintype.card_congr <\| Equiv.ofInjective _ <\| EmbeddingLike.injective f theorem card_eq_zero_iff : card α = 0 ↔ IsEmpty α := by rw [card, Finset.card_eq_zero, univ_eq_empty_iff] @[simp] theorem card_eq_zero [IsEmpty α] : card α = 0 := card_eq_zero_iff.2 ‹_› alias card_of_isEmpty := card_eq_zero /-- A `Fintype` with cardinality zero is equivalent to `Empty`. -/ def cardEqZeroEquivEquivEmpty : card α = 0 ≃ (α ≃ Empty) := (Equiv.ofIff card_eq_zero_iff).trans (Equiv.equivEmptyEquiv α).symm theorem card_pos_iff : 0 < card α ↔ Nonempty α := Nat.pos_iff_ne_zero.trans <\| not_iff_comm.mp <\| not_nonempty_iff.trans card_eq_zero_iff.symm theorem card_pos [h : Nonempty α] : 0 < card α := card_pos_iff.mpr h @[simp] theorem card_ne_zero [Nonempty α] : card α ≠ 0 := _root_.ne_of_gt card_pos instance [Nonempty α] : NeZero (card α) := ⟨card_ne_zero⟩ theorem existsUnique_iff_card_one {α} [Fintype α] (p : α → Prop) [DecidablePred p] : (∃! a : α, p a) ↔ #{x \| p x} = 1 := by rw [Finset.card_eq_one] refine exists_congr fun x => ?_ simp only [forall_true_left, Subset.antisymm_iff, subset_singleton_iff', singleton_subset_iff, true_and, and_comm, mem_univ, mem_filter] @[deprecated (since := "2024-12-17")] alias exists_unique_iff_card_one := existsUnique_iff_card_one nonrec theorem two_lt_card_iff : 2 < card α ↔ ∃ a b c : α, a ≠ b ∧ a ≠ c ∧ b ≠ c := by simp_rw [← Finset.card_univ, two_lt_card_iff, mem_univ, true_and] theorem card_of_bijective {f : α → β} (hf : Bijective f) : card α = card β := card_congr (Equiv.ofBijective f hf) end Fintype namespace Finite variable [Finite α] theorem surjective_of_injective {f : α → α} (hinj : Injective f) : Surjective f := by intro x have := Classical.propDecidable cases nonempty_fintype α have h₁ : image f univ = univ := eq_of_subset_of_card_le (subset_univ _) ((card_image_of_injective univ hinj).symm ▸ le_rfl) have h₂ : x ∈ image f univ := h₁.symm ▸ mem_univ x obtain ⟨y, h⟩ := mem_image.1 h₂ exact ⟨y, h.2⟩ theorem injective_iff_surjective {f : α → α} : Injective f ↔ Surjective f := ⟨surjective_of_injective, fun hsurj => HasLeftInverse.injective ⟨surjInv hsurj, leftInverse_of_surjective_of_rightInverse (surjective_of_injective (injective_surjInv _)) (rightInverse_surjInv _)⟩⟩ theorem injective_iff_bijective {f : α → α} : Injective f ↔ Bijective f := by simp [Bijective, injective_iff_surjective] theorem surjective_iff_bijective {f : α → α} : Surjective f ↔ Bijective f := by simp [Bijective, injective_iff_surjective] theorem injective_iff_surjective_of_equiv {f : α → β} (e : α ≃ β) : Injective f ↔ Surjective f := have : Injective (e.symm ∘ f) ↔ Surjective (e.symm ∘ f) := injective_iff_surjective ⟨fun hinj => by simpa [Function.comp] using e.surjective.comp (this.1 (e.symm.injective.comp hinj)), fun hsurj => by simpa [Function.comp] using e.injective.comp (this.2 (e.symm.surjective.comp hsurj))⟩ alias ⟨_root_.Function.Injective.bijective_of_finite, _⟩ := injective_iff_bijective alias ⟨_root_.Function.Surjective.bijective_of_finite, _⟩ := surjective_iff_bijective alias ⟨_root_.Function.Injective.surjective_of_fintype, _root_.Function.Surjective.injective_of_fintype⟩ := injective_iff_surjective_of_equiv end Finite @[simp] theorem Fintype.card_coe (s : Finset α) [Fintype s] : Fintype.card s = #s := @Fintype.card_of_finset' _ _ _ (fun _ => Iff.rfl) (id _) /-- We can inflate a set `s` to any bigger size. -/ lemma Finset.exists_superset_card_eq [Fintype α] {n : ℕ} {s : Finset α} (hsn : #s ≤ n) (hnα : n ≤ Fintype.card α) : ∃ t, s ⊆ t ∧ #t = n := by simpa using exists_subsuperset_card_eq s.subset_univ hsn hnα @[simp] theorem Fintype.card_prop : Fintype.card Prop = 2 := rfl theorem set_fintype_card_le_univ [Fintype α] (s : Set α) [Fintype s] : Fintype.card s ≤ Fintype.card α := Fintype.card_le_of_embedding (Function.Embedding.subtype s) theorem set_fintype_card_eq_univ_iff [Fintype α] (s : Set α) [Fintype s] : Fintype.card s = Fintype.card α ↔ s = Set.univ := by rw [← Set.toFinset_card, Finset.card_eq_iff_eq_univ, ← Set.toFinset_univ, Set.toFinset_inj] theorem Fintype.card_subtype_le [Fintype α] (p : α → Prop) [Fintype {a // p a}] : Fintype.card { x // p x } ≤ Fintype.card α := Fintype.card_le_of_embedding (Function.Embedding.subtype _) lemma Fintype.card_subtype_lt [Fintype α] {p : α → Prop} [Fintype {a // p a}] {x : α} (hx : ¬p x) : Fintype.card { x // p x } < Fintype.card α := Fintype.card_lt_of_injective_of_not_mem (b := x) (↑) Subtype.coe_injective <\| by rwa [Subtype.range_coe_subtype] theorem Fintype.card_subtype [Fintype α] (p : α → Prop) [Fintype {a // p a}] [DecidablePred p] : Fintype.card { x // p x } = #{x \| p x} := by refine Fintype.card_of_subtype _ ?_ simp @[simp] theorem Fintype.card_subtype_compl [Fintype α] (p : α → Prop) [Fintype { x // p x }] [Fintype { x // ¬p x }] : Fintype.card { x // ¬p x } = Fintype.card α - Fintype.card { x // p x } := by classical rw [Fintype.card_of_subtype (Set.toFinset { x \| p x }ᶜ), Set.toFinset_compl, Finset.card_compl, Fintype.card_of_subtype] <;> · intro simp only [Set.mem_toFinset, Set.mem_compl_iff, Set.mem_setOf] theorem Fintype.card_subtype_mono (p q : α → Prop) (h : p ≤ q) [Fintype { x // p x }] [Fintype { x // q x }] : Fintype.card { x // p x } ≤ Fintype.card { x // q x } := Fintype.card_le_of_embedding (Subtype.impEmbedding _ _ h) /-- If two subtypes of a fintype have equal cardinality, so do their complements. -/ theorem Fintype.card_compl_eq_card_compl [Finite α] (p q : α → Prop) [Fintype { x // p x }] [Fintype { x // ¬p x }] [Fintype { x // q x }] [Fintype { x // ¬q x }] (h : Fintype.card { x // p x } = Fintype.card { x // q x }) : Fintype.card { x // ¬p x } = Fintype.card { x // ¬q x } := by cases nonempty_fintype α simp only [Fintype.card_subtype_compl, h] theorem Fintype.card_quotient_le [Fintype α] (s : Setoid α) [DecidableRel ((· ≈ ·) : α → α → Prop)] : Fintype.card (Quotient s) ≤ Fintype.card α := Fintype.card_le_of_surjective _ Quotient.mk'_surjective theorem univ_eq_singleton_of_card_one {α} [Fintype α] (x : α) (h : Fintype.card α = 1) : (univ : Finset α) = {x} := by symm apply eq_of_subset_of_card_le (subset_univ {x}) apply le_of_eq simp [h, Finset.card_univ] namespace Finite variable [Finite α] theorem wellFounded_of_trans_of_irrefl (r : α → α → Prop) [IsTrans α r] [IsIrrefl α r] : WellFounded r := by classical cases nonempty_fintype α have (x y) (hxy : r x y) : #{z \| r z x} < #{z \| r z y} := Finset.card_lt_card <\| by simp only [Finset.lt_iff_ssubset.symm, lt_iff_le_not_le, Finset.le_iff_subset, Finset.subset_iff, mem_filter, true_and, mem_univ, hxy] exact ⟨fun z hzx => _root_.trans hzx hxy, not_forall_of_exists_not ⟨x, Classical.not_imp.2 ⟨hxy, irrefl x⟩⟩⟩ exact Subrelation.wf (this _ _) (measure _).wf -- See note [lower instance priority] instance (priority := 100) to_wellFoundedLT [Preorder α] : WellFoundedLT α := ⟨wellFounded_of_trans_of_irrefl _⟩ -- See note [lower instance priority] instance (priority := 100) to_wellFoundedGT [Preorder α] : WellFoundedGT α := ⟨wellFounded_of_trans_of_irrefl _⟩ end Finite -- Shortcut instances to make sure those are found even in the presence of other instances -- See https://leanprover.zulipchat.com/#narrow/channel/287929-mathlib4/topic/WellFoundedLT.20Prop.20is.20not.20found.20when.20importing.20too.20much instance Bool.instWellFoundedLT : WellFoundedLT Bool := inferInstance instance Bool.instWellFoundedGT : WellFoundedGT Bool := inferInstance instance Prop.instWellFoundedLT : WellFoundedLT Prop := inferInstance instance Prop.instWellFoundedGT : WellFoundedGT Prop := inferInstance section Trunc /-- A `Fintype` with positive cardinality constructively contains an element. -/ def truncOfCardPos {α} [Fintype α] (h : 0 < Fintype.card α) : Trunc α := letI := Fintype.card_pos_iff.mp h truncOfNonemptyFintype α end Trunc /-- A custom induction principle for fintypes. The base case is a subsingleton type, and the induction step is for non-trivial types, and one can assume the hypothesis for smaller types (via `Fintype.card`). The major premise is `Fintype α`, so to use this with the `induction` tactic you have to give a name to that instance and use that name. -/ @[elab_as_elim] theorem Fintype.induction_subsingleton_or_nontrivial {P : ∀ (α) [Fintype α], Prop} (α : Type) [Fintype α] (hbase : ∀ (α) [Fintype α] [Subsingleton α], P α) (hstep : ∀ (α) [Fintype α] [Nontrivial α], (∀ (β) [Fintype β], Fintype.card β < Fintype.card α → P β) → P α) : P α := by obtain ⟨n, hn⟩ : ∃ n, Fintype.card α = n := ⟨Fintype.card α, rfl⟩ induction' n using Nat.strong_induction_on with n ih generalizing α rcases subsingleton_or_nontrivial α with hsing \| hnontriv · apply hbase · apply hstep intro β _ hlt rw [hn] at hlt exact ih (Fintype.card β) hlt _ rfl section Fin @[simp] theorem Fintype.card_fin (n : ℕ) : Fintype.card (Fin n) = n := List.length_finRange theorem Fintype.card_fin_lt_of_le {m n : ℕ} (h : m ≤ n) : Fintype.card {i : Fin n // i < m} = m := by conv_rhs => rw [← Fintype.card_fin m] apply Fintype.card_congr exact { toFun := fun ⟨⟨i, _⟩, hi⟩ ↦ ⟨i, hi⟩ invFun := fun ⟨i, hi⟩ ↦ ⟨⟨i, lt_of_lt_of_le hi h⟩, hi⟩ left_inv := fun i ↦ rfl right_inv := fun i ↦ rfl } theorem Finset.card_fin (n : ℕ) : #(univ : Finset (Fin n)) = n := by simp /-- `Fin` as a map from `ℕ` to `Type` is injective. Note that since this is a statement about equality of types, using it should be avoided if possible. -/ theorem fin_injective : Function.Injective Fin := fun m n h => (Fintype.card_fin m).symm.trans <\| (Fintype.card_congr <\| Equiv.cast h).trans (Fintype.card_fin n) theorem Fin.val_eq_val_of_heq {k l : ℕ} {i : Fin k} {j : Fin l} (h : HEq i j) : (i : ℕ) = (j : ℕ) := (Fin.heq_ext_iff (fin_injective (type_eq_of_heq h))).1 h /-- A reversed version of `Fin.cast_eq_cast` that is easier to rewrite with. -/ theorem Fin.cast_eq_cast' {n m : ℕ} (h : Fin n = Fin m) : _root_.cast h = Fin.cast (fin_injective h) := by cases fin_injective h rfl theorem card_finset_fin_le {n : ℕ} (s : Finset (Fin n)) : #s ≤ n := by simpa only [Fintype.card_fin] using s.card_le_univ end Fin		Mathlib/Data/Fintype/Card.lean	1,122	1,134
/- Copyright (c) 2018 Chris Hughes. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Chris Hughes -/ import Mathlib.Algebra.Group.Equiv.Basic import Mathlib.Data.ENat.Lattice import Mathlib.Data.Part import Mathlib.Tactic.NormNum /-! # Natural numbers with infinity The natural numbers and an extra `top` element `⊤`. This implementation uses `Part ℕ` as an implementation. Use `ℕ∞` instead unless you care about computability. ## Main definitions The following instances are defined: * `OrderedAddCommMonoid PartENat` * `CanonicallyOrderedAdd PartENat` * `CompleteLinearOrder PartENat` There is no additive analogue of `MonoidWithZero`; if there were then `PartENat` could be an `AddMonoidWithTop`. * `toWithTop` : the map from `PartENat` to `ℕ∞`, with theorems that it plays well with `+` and `≤`. * `withTopAddEquiv : PartENat ≃+ ℕ∞` * `withTopOrderIso : PartENat ≃o ℕ∞` ## Implementation details `PartENat` is defined to be `Part ℕ`. `+` and `≤` are defined on `PartENat`, but there is an issue with `` because it's not clear what `0 ⊤` should be. `mul` is hence left undefined. Similarly `⊤ - ⊤` is ambiguous so there is no `-` defined on `PartENat`. Before the `open scoped Classical` line, various proofs are made with decidability assumptions. This can cause issues -- see for example the non-simp lemma `toWithTopZero` proved by `rfl`, followed by `@[simp] lemma toWithTopZero'` whose proof uses `convert`. ## Tags PartENat, ℕ∞ -/ open Part hiding some /-- Type of natural numbers with infinity (`⊤`) -/ def PartENat : Type := Part ℕ namespace PartENat /-- The computable embedding `ℕ → PartENat`. This coincides with the coercion `coe : ℕ → PartENat`, see `PartENat.some_eq_natCast`. -/ @[coe] def some : ℕ → PartENat := Part.some instance : Zero PartENat := ⟨some 0⟩ instance : Inhabited PartENat := ⟨0⟩ instance : One PartENat := ⟨some 1⟩ instance : Add PartENat := ⟨fun x y => ⟨x.Dom ∧ y.Dom, fun h => get x h.1 + get y h.2⟩⟩ instance (n : ℕ) : Decidable (some n).Dom := isTrue trivial @[simp] theorem dom_some (x : ℕ) : (some x).Dom := trivial instance addCommMonoid : AddCommMonoid PartENat where add := (· + ·) zero := 0 add_comm _ _ := Part.ext' and_comm fun _ _ => add_comm _ _ zero_add _ := Part.ext' (iff_of_eq (true_and _)) fun _ _ => zero_add _ add_zero _ := Part.ext' (iff_of_eq (and_true _)) fun _ _ => add_zero _ add_assoc _ _ _ := Part.ext' and_assoc fun _ _ => add_assoc _ _ _ nsmul := nsmulRec instance : AddCommMonoidWithOne PartENat := { PartENat.addCommMonoid with one := 1 natCast := some natCast_zero := rfl natCast_succ := fun _ => Part.ext' (iff_of_eq (true_and _)).symm fun _ _ => rfl } theorem some_eq_natCast (n : ℕ) : some n = n := rfl instance : CharZero PartENat where cast_injective := Part.some_injective /-- Alias of `Nat.cast_inj` specialized to `PartENat` -/ theorem natCast_inj {x y : ℕ} : (x : PartENat) = y ↔ x = y := Nat.cast_inj @[simp] theorem dom_natCast (x : ℕ) : (x : PartENat).Dom := trivial @[simp] theorem dom_ofNat (x : ℕ) [x.AtLeastTwo] : (ofNat(x) : PartENat).Dom := trivial @[simp] theorem dom_zero : (0 : PartENat).Dom := trivial @[simp] theorem dom_one : (1 : PartENat).Dom := trivial instance : CanLift PartENat ℕ (↑) Dom := ⟨fun n hn => ⟨n.get hn, Part.some_get _⟩⟩ instance : LE PartENat := ⟨fun x y => ∃ h : y.Dom → x.Dom, ∀ hy : y.Dom, x.get (h hy) ≤ y.get hy⟩ instance : Top PartENat := ⟨none⟩ instance : Bot PartENat := ⟨0⟩ instance : Max PartENat := ⟨fun x y => ⟨x.Dom ∧ y.Dom, fun h => x.get h.1 ⊔ y.get h.2⟩⟩ theorem le_def (x y : PartENat) : x ≤ y ↔ ∃ h : y.Dom → x.Dom, ∀ hy : y.Dom, x.get (h hy) ≤ y.get hy := Iff.rfl @[elab_as_elim] protected theorem casesOn' {P : PartENat → Prop} : ∀ a : PartENat, P ⊤ → (∀ n : ℕ, P (some n)) → P a := Part.induction_on @[elab_as_elim] protected theorem casesOn {P : PartENat → Prop} : ∀ a : PartENat, P ⊤ → (∀ n : ℕ, P n) → P a := by exact PartENat.casesOn' -- not a simp lemma as we will provide a `LinearOrderedAddCommMonoidWithTop` instance later theorem top_add (x : PartENat) : ⊤ + x = ⊤ := Part.ext' (iff_of_eq (false_and _)) fun h => h.left.elim -- not a simp lemma as we will provide a `LinearOrderedAddCommMonoidWithTop` instance later theorem add_top (x : PartENat) : x + ⊤ = ⊤ := by rw [add_comm, top_add] @[simp] theorem natCast_get {x : PartENat} (h : x.Dom) : (x.get h : PartENat) = x := by exact Part.ext' (iff_of_true trivial h) fun _ _ => rfl @[simp, norm_cast] theorem get_natCast' (x : ℕ) (h : (x : PartENat).Dom) : get (x : PartENat) h = x := by rw [← natCast_inj, natCast_get] theorem get_natCast {x : ℕ} : get (x : PartENat) (dom_natCast x) = x := get_natCast' _ _ theorem coe_add_get {x : ℕ} {y : PartENat} (h : ((x : PartENat) + y).Dom) : get ((x : PartENat) + y) h = x + get y h.2 := by rfl @[simp] theorem get_add {x y : PartENat} (h : (x + y).Dom) : get (x + y) h = x.get h.1 + y.get h.2 := rfl @[simp] theorem get_zero (h : (0 : PartENat).Dom) : (0 : PartENat).get h = 0 := rfl @[simp] theorem get_one (h : (1 : PartENat).Dom) : (1 : PartENat).get h = 1 := rfl @[simp] theorem get_ofNat' (x : ℕ) [x.AtLeastTwo] (h : (ofNat(x) : PartENat).Dom) : Part.get (ofNat(x) : PartENat) h = ofNat(x) := get_natCast' x h nonrec theorem get_eq_iff_eq_some {a : PartENat} {ha : a.Dom} {b : ℕ} : a.get ha = b ↔ a = some b := get_eq_iff_eq_some theorem get_eq_iff_eq_coe {a : PartENat} {ha : a.Dom} {b : ℕ} : a.get ha = b ↔ a = b := by rw [get_eq_iff_eq_some] rfl theorem dom_of_le_of_dom {x y : PartENat} : x ≤ y → y.Dom → x.Dom := fun ⟨h, _⟩ => h theorem dom_of_le_some {x : PartENat} {y : ℕ} (h : x ≤ some y) : x.Dom := dom_of_le_of_dom h trivial theorem dom_of_le_natCast {x : PartENat} {y : ℕ} (h : x ≤ y) : x.Dom := by exact dom_of_le_some h instance decidableLe (x y : PartENat) [Decidable x.Dom] [Decidable y.Dom] : Decidable (x ≤ y) := if hx : x.Dom then decidable_of_decidable_of_iff (le_def x y).symm else if hy : y.Dom then isFalse fun h => hx <\| dom_of_le_of_dom h hy else isTrue ⟨fun h => (hy h).elim, fun h => (hy h).elim⟩ instance partialOrder : PartialOrder PartENat where le := (· ≤ ·) le_refl _ := ⟨id, fun _ => le_rfl⟩ le_trans := fun _ _ _ ⟨hxy₁, hxy₂⟩ ⟨hyz₁, hyz₂⟩ => ⟨hxy₁ ∘ hyz₁, fun _ => le_trans (hxy₂ _) (hyz₂ _)⟩ lt_iff_le_not_le _ _ := Iff.rfl le_antisymm := fun _ _ ⟨hxy₁, hxy₂⟩ ⟨hyx₁, hyx₂⟩ => Part.ext' ⟨hyx₁, hxy₁⟩ fun _ _ => le_antisymm (hxy₂ _) (hyx₂ _) theorem lt_def (x y : PartENat) : x < y ↔ ∃ hx : x.Dom, ∀ hy : y.Dom, x.get hx < y.get hy := by rw [lt_iff_le_not_le, le_def, le_def, not_exists] constructor · rintro ⟨⟨hyx, H⟩, h⟩ by_cases hx : x.Dom · use hx intro hy specialize H hy specialize h fun _ => hy rw [not_forall] at h obtain ⟨hx', h⟩ := h rw [not_le] at h exact h · specialize h fun hx' => (hx hx').elim rw [not_forall] at h obtain ⟨hx', h⟩ := h exact (hx hx').elim · rintro ⟨hx, H⟩ exact ⟨⟨fun _ => hx, fun hy => (H hy).le⟩, fun hxy h => not_lt_of_le (h _) (H _)⟩ noncomputable instance isOrderedAddMonoid : IsOrderedAddMonoid PartENat := { add_le_add_left := fun a b ⟨h₁, h₂⟩ c => PartENat.casesOn c (by simp [top_add]) fun c => ⟨fun h => And.intro (dom_natCast _) (h₁ h.2), fun h => by simpa only [coe_add_get] using add_le_add_left (h₂ _) c⟩ } instance semilatticeSup : SemilatticeSup PartENat := { PartENat.partialOrder with sup := (· ⊔ ·) le_sup_left := fun _ _ => ⟨And.left, fun _ => le_sup_left⟩ le_sup_right := fun _ _ => ⟨And.right, fun _ => le_sup_right⟩ sup_le := fun _ _ _ ⟨hx₁, hx₂⟩ ⟨hy₁, hy₂⟩ => ⟨fun hz => ⟨hx₁ hz, hy₁ hz⟩, fun _ => sup_le (hx₂ _) (hy₂ _)⟩ } instance orderBot : OrderBot PartENat where bot := ⊥ bot_le _ := ⟨fun _ => trivial, fun _ => Nat.zero_le _⟩ instance orderTop : OrderTop PartENat where top := ⊤ le_top _ := ⟨fun h => False.elim h, fun hy => False.elim hy⟩ instance : ZeroLEOneClass PartENat where zero_le_one := bot_le /-- Alias of `Nat.cast_le` specialized to `PartENat` -/ theorem coe_le_coe {x y : ℕ} : (x : PartENat) ≤ y ↔ x ≤ y := Nat.cast_le /-- Alias of `Nat.cast_lt` specialized to `PartENat` -/ theorem coe_lt_coe {x y : ℕ} : (x : PartENat) < y ↔ x < y := Nat.cast_lt @[simp] theorem get_le_get {x y : PartENat} {hx : x.Dom} {hy : y.Dom} : x.get hx ≤ y.get hy ↔ x ≤ y := by conv => lhs rw [← coe_le_coe, natCast_get, natCast_get] theorem le_coe_iff (x : PartENat) (n : ℕ) : x ≤ n ↔ ∃ h : x.Dom, x.get h ≤ n := by show (∃ h : True → x.Dom, _) ↔ ∃ h : x.Dom, x.get h ≤ n simp only [forall_prop_of_true, dom_natCast, get_natCast'] theorem lt_coe_iff (x : PartENat) (n : ℕ) : x < n ↔ ∃ h : x.Dom, x.get h < n := by simp only [lt_def, forall_prop_of_true, get_natCast', dom_natCast] theorem coe_le_iff (n : ℕ) (x : PartENat) : (n : PartENat) ≤ x ↔ ∀ h : x.Dom, n ≤ x.get h := by rw [← some_eq_natCast] simp only [le_def, exists_prop_of_true, dom_some, forall_true_iff] rfl theorem coe_lt_iff (n : ℕ) (x : PartENat) : (n : PartENat) < x ↔ ∀ h : x.Dom, n < x.get h := by rw [← some_eq_natCast] simp only [lt_def, exists_prop_of_true, dom_some, forall_true_iff] rfl nonrec theorem eq_zero_iff {x : PartENat} : x = 0 ↔ x ≤ 0 := eq_bot_iff theorem ne_zero_iff {x : PartENat} : x ≠ 0 ↔ ⊥ < x := bot_lt_iff_ne_bot.symm theorem dom_of_lt {x y : PartENat} : x < y → x.Dom := PartENat.casesOn x not_top_lt fun _ _ => dom_natCast _ theorem top_eq_none : (⊤ : PartENat) = Part.none := rfl @[simp] theorem natCast_lt_top (x : ℕ) : (x : PartENat) < ⊤ := Ne.lt_top fun h => absurd (congr_arg Dom h) <\| by simp only [dom_natCast]; exact true_ne_false @[simp] theorem zero_lt_top : (0 : PartENat) < ⊤ := natCast_lt_top 0 @[simp] theorem one_lt_top : (1 : PartENat) < ⊤ := natCast_lt_top 1 @[simp] theorem ofNat_lt_top (x : ℕ) [x.AtLeastTwo] : (ofNat(x) : PartENat) < ⊤ := natCast_lt_top x @[simp] theorem natCast_ne_top (x : ℕ) : (x : PartENat) ≠ ⊤ := ne_of_lt (natCast_lt_top x) @[simp] theorem zero_ne_top : (0 : PartENat) ≠ ⊤ := natCast_ne_top 0 @[simp] theorem one_ne_top : (1 : PartENat) ≠ ⊤ := natCast_ne_top 1 @[simp] theorem ofNat_ne_top (x : ℕ) [x.AtLeastTwo] : (ofNat(x) : PartENat) ≠ ⊤ := natCast_ne_top x theorem not_isMax_natCast (x : ℕ) : ¬IsMax (x : PartENat) := not_isMax_of_lt (natCast_lt_top x) theorem ne_top_iff {x : PartENat} : x ≠ ⊤ ↔ ∃ n : ℕ, x = n := by simpa only [← some_eq_natCast] using Part.ne_none_iff theorem ne_top_iff_dom {x : PartENat} : x ≠ ⊤ ↔ x.Dom := by classical exact not_iff_comm.1 Part.eq_none_iff'.symm theorem not_dom_iff_eq_top {x : PartENat} : ¬x.Dom ↔ x = ⊤ := Iff.not_left ne_top_iff_dom.symm theorem ne_top_of_lt {x y : PartENat} (h : x < y) : x ≠ ⊤ := ne_of_lt <\| lt_of_lt_of_le h le_top theorem eq_top_iff_forall_lt (x : PartENat) : x = ⊤ ↔ ∀ n : ℕ, (n : PartENat) < x := by constructor · rintro rfl n exact natCast_lt_top _ · contrapose! rw [ne_top_iff] rintro ⟨n, rfl⟩ exact ⟨n, irrefl _⟩ theorem eq_top_iff_forall_le (x : PartENat) : x = ⊤ ↔ ∀ n : ℕ, (n : PartENat) ≤ x := (eq_top_iff_forall_lt x).trans ⟨fun h n => (h n).le, fun h n => lt_of_lt_of_le (coe_lt_coe.mpr n.lt_succ_self) (h (n + 1))⟩ theorem pos_iff_one_le {x : PartENat} : 0 < x ↔ 1 ≤ x := PartENat.casesOn x (by simp only [le_top, natCast_lt_top, ← @Nat.cast_zero PartENat]) fun n => by rw [← Nat.cast_zero, ← Nat.cast_one, PartENat.coe_lt_coe, PartENat.coe_le_coe] rfl instance isTotal : IsTotal PartENat (· ≤ ·) where total x y := PartENat.casesOn (P := fun z => z ≤ y ∨ y ≤ z) x (Or.inr le_top) (PartENat.casesOn y (fun _ => Or.inl le_top) fun x y => (le_total x y).elim (Or.inr ∘ coe_le_coe.2) (Or.inl ∘ coe_le_coe.2)) noncomputable instance linearOrder : LinearOrder PartENat := { PartENat.partialOrder with le_total := IsTotal.total toDecidableLE := Classical.decRel _ max := (· ⊔ ·) max_def a b := congr_fun₂ (@sup_eq_maxDefault PartENat _ (_) _) _ _ } instance boundedOrder : BoundedOrder PartENat := { PartENat.orderTop, PartENat.orderBot with } noncomputable instance lattice : Lattice PartENat := { PartENat.semilatticeSup with inf := min inf_le_left := min_le_left inf_le_right := min_le_right	le_inf := fun _ _ _ => le_min }	Mathlib/Data/Nat/PartENat.lean	401	402
/- 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))	Mathlib/CategoryTheory/Limits/VanKampen.lean	182	192
/- 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.	Mathlib/Data/Set/Image.lean	532	534
/- Copyright (c) 2020 Jujian Zhang. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Jujian Zhang, Johan Commelin -/ import Mathlib.RingTheory.GradedAlgebra.Homogeneous.Ideal import Mathlib.Topology.Category.TopCat.Basic import Mathlib.Topology.Sets.Opens import Mathlib.Data.Set.Subsingleton /-! # Projective spectrum of a graded ring The projective spectrum of a graded commutative ring is the subtype of all homogeneous ideals that are prime and do not contain the irrelevant ideal. It is naturally endowed with a topology: the Zariski topology. ## Notation - `R` is a commutative semiring; - `A` is a commutative ring and an `R`-algebra; - `𝒜 : ℕ → Submodule R A` is the grading of `A`; ## Main definitions * `ProjectiveSpectrum 𝒜`: The projective spectrum of a graded ring `A`, or equivalently, the set of all homogeneous ideals of `A` that is both prime and relevant i.e. not containing irrelevant ideal. Henceforth, we call elements of projective spectrum relevant homogeneous prime ideals. * `ProjectiveSpectrum.zeroLocus 𝒜 s`: The zero locus of a subset `s` of `A` is the subset of `ProjectiveSpectrum 𝒜` consisting of all relevant homogeneous prime ideals that contain `s`. * `ProjectiveSpectrum.vanishingIdeal t`: The vanishing ideal of a subset `t` of `ProjectiveSpectrum 𝒜` is the intersection of points in `t` (viewed as relevant homogeneous prime ideals). * `ProjectiveSpectrum.Top`: the topological space of `ProjectiveSpectrum 𝒜` endowed with the Zariski topology. -/ noncomputable section open DirectSum Pointwise SetLike TopCat TopologicalSpace CategoryTheory Opposite variable {R A : Type*} variable [CommSemiring R] [CommRing A] [Algebra R A] variable (𝒜 : ℕ → Submodule R A) [GradedAlgebra 𝒜] /-- The projective spectrum of a graded commutative ring is the subtype of all homogeneous ideals that are prime and do not contain the irrelevant ideal. -/ @[ext] structure ProjectiveSpectrum where asHomogeneousIdeal : HomogeneousIdeal 𝒜 isPrime : asHomogeneousIdeal.toIdeal.IsPrime not_irrelevant_le : ¬HomogeneousIdeal.irrelevant 𝒜 ≤ asHomogeneousIdeal attribute [instance] ProjectiveSpectrum.isPrime namespace ProjectiveSpectrum instance (x : ProjectiveSpectrum 𝒜) : Ideal.IsPrime x.asHomogeneousIdeal.toIdeal := x.isPrime /-- The zero locus of a set `s` of elements of a commutative ring `A` is the set of all relevant homogeneous prime ideals of the ring that contain the set `s`. An element `f` of `A` can be thought of as a dependent function on the projective spectrum of `𝒜`. At a point `x` (a homogeneous prime ideal) the function (i.e., element) `f` takes values in the quotient ring `A` modulo the prime ideal `x`. In this manner, `zeroLocus s` is exactly the subset of `ProjectiveSpectrum 𝒜` where all "functions" in `s` vanish simultaneously. -/ def zeroLocus (s : Set A) : Set (ProjectiveSpectrum 𝒜) := { x \| s ⊆ x.asHomogeneousIdeal } @[simp] theorem mem_zeroLocus (x : ProjectiveSpectrum 𝒜) (s : Set A) : x ∈ zeroLocus 𝒜 s ↔ s ⊆ x.asHomogeneousIdeal := Iff.rfl @[simp] theorem zeroLocus_span (s : Set A) : zeroLocus 𝒜 (Ideal.span s) = zeroLocus 𝒜 s := by ext x exact (Submodule.gi _ _).gc s x.asHomogeneousIdeal.toIdeal variable {𝒜} /-- The vanishing ideal of a set `t` of points of the projective spectrum of a commutative ring `R` is the intersection of all the relevant homogeneous prime ideals in the set `t`. An element `f` of `A` can be thought of as a dependent function on the projective spectrum of `𝒜`. At a point `x` (a homogeneous prime ideal) the function (i.e., element) `f` takes values in the quotient ring `A` modulo the prime ideal `x`. In this manner, `vanishingIdeal t` is exactly the ideal of `A` consisting of all "functions" that vanish on all of `t`. -/ def vanishingIdeal (t : Set (ProjectiveSpectrum 𝒜)) : HomogeneousIdeal 𝒜 := ⨅ (x : ProjectiveSpectrum 𝒜) (_ : x ∈ t), x.asHomogeneousIdeal theorem coe_vanishingIdeal (t : Set (ProjectiveSpectrum 𝒜)) : (vanishingIdeal t : Set A) = { f \| ∀ x : ProjectiveSpectrum 𝒜, x ∈ t → f ∈ x.asHomogeneousIdeal } := by ext f rw [vanishingIdeal, SetLike.mem_coe, ← HomogeneousIdeal.mem_iff, HomogeneousIdeal.toIdeal_iInf, Submodule.mem_iInf] refine forall_congr' fun x => ?_ rw [HomogeneousIdeal.toIdeal_iInf, Submodule.mem_iInf, HomogeneousIdeal.mem_iff] theorem mem_vanishingIdeal (t : Set (ProjectiveSpectrum 𝒜)) (f : A) : f ∈ vanishingIdeal t ↔ ∀ x : ProjectiveSpectrum 𝒜, x ∈ t → f ∈ x.asHomogeneousIdeal := by rw [← SetLike.mem_coe, coe_vanishingIdeal, Set.mem_setOf_eq] @[simp] theorem vanishingIdeal_singleton (x : ProjectiveSpectrum 𝒜) : vanishingIdeal ({x} : Set (ProjectiveSpectrum 𝒜)) = x.asHomogeneousIdeal := by	simp [vanishingIdeal] theorem subset_zeroLocus_iff_le_vanishingIdeal (t : Set (ProjectiveSpectrum 𝒜)) (I : Ideal A) :	Mathlib/AlgebraicGeometry/ProjectiveSpectrum/Topology.lean	109	111

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